freebsd-skq/sys/dev/bnxt/hsi_struct_def.h
shurd 52b656c3e0 bnxt: Update firmware header file with the latest one
hsi_struct_def.h file contains all firmware (HWRM) data struct's, updated
that with the latest one which was released on 30'th Aug.

After this upgrade, HWRM version will be 1.8.1.5 (earlier it was 1.4.0).

Submitted by:	Bhargava Chenna Marreddy <bhargava.marreddy@broadcom.com>
Reviewed by:	shurd, sbruno
Approved by:	sbruno (mentor)
Sponsored by:	Broadcom Limited
Differential Revision:	https://reviews.freebsd.org/D12203
2017-09-06 20:19:30 +00:00

30386 lines
1.1 MiB

/*-
* BSD LICENSE
*
* Copyright (c) 2016 Broadcom, All Rights Reserved.
* The term Broadcom refers to Broadcom Limited and/or its subsidiaries
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include <sys/cdefs.h>
__FBSDID("$FreeBSD$");
/****************************************************************************
*
* Description: Definition of HSI data structures
*
* Date: 08/31/17 17:55:46
*
* Note: This file is scripted generated by hsi_decode.py.
* DO NOT modify this file manually !!!!
*
****************************************************************************/
#ifndef _HSI_STRUCT_DEF_EXTERNAL_H_
#define _HSI_STRUCT_DEF_EXTERNAL_H_
/* HSI and HWRM Specification 1.8.1 */
#define HWRM_VERSION_MAJOR 1
#define HWRM_VERSION_MINOR 8
#define HWRM_VERSION_UPDATE 1
#define HWRM_VERSION_RSVD 7
#define HWRM_VERSION_STR "1.8.1.7"
/*
* Following is the signature for HWRM message field that indicates not
* applicable (All F's). Need to cast it the size of the field if needed.
*/
#define HWRM_NA_SIGNATURE ((uint32_t)(-1))
#define HWRM_MAX_REQ_LEN (128) /* hwrm_func_buf_rgtr */
#define HWRM_MAX_RESP_LEN (272) /* hwrm_selftest_qlist */
#define HW_HASH_INDEX_SIZE 0x80 /* 7 bit indirection table index. */
#define HW_HASH_KEY_SIZE 40
#define HWRM_RESP_VALID_KEY 1 /* valid key for HWRM response */
#define ROCE_SP_HSI_VERSION_MAJOR 1
#define ROCE_SP_HSI_VERSION_MINOR 8
#define ROCE_SP_HSI_VERSION_UPDATE 1
#define ROCE_SP_HSI_VERSION_STR "1.8.1"
/*
* Following is the signature for ROCE_SP_HSI message field that indicates not
* applicable (All F's). Need to cast it the size of the field if needed.
*/
#define ROCE_SP_HSI_NA_SIGNATURE ((uint32_t)(-1))
/*
* Note: The Host Software Interface (HSI) and Hardware Resource Manager (HWRM)
* specification describes the data structures used in Ethernet packet or RDMA
* message data transfers as well as an abstract interface for managing Ethernet
* NIC hardware resources.
*/
/* Ethernet Data path Host Structures */
/*
* Description: The following three sections document the host structures used
* between device and software drivers for communicating Ethernet packets.
*/
/* BD Ring Structures */
/*
* Description: This structure is used to inform the NIC of a location for and
* an aggregation buffer that will be used for packet data that is received. An
* aggregation buffer creates a different kind of completion operation for a
* packet where a variable number of BDs may be used to place the packet in the
* host. RX Rings that have aggregation buffers are known as aggregation rings
* and must contain only aggregation buffers.
*/
/*
* Note: BD Ring structures are written by the driver to TX Rings and RX Rings
* to indicate to the chip there is more buffer space in the host that needs to
* be transmitted or is available for receive data.
*/
/* BD Base (8 bytes) */
struct bd_base {
uint8_t type;
/* This value identifies the type of buffer descriptor. */
#define BD_BASE_TYPE_MASK UINT32_C(0x3f)
#define BD_BASE_TYPE_SFT 0
/*
* Indicates that this BD is 16B long and is used for normal L2
* packet transmission.
*/
#define BD_BASE_TYPE_TX_BD_SHORT UINT32_C(0x0)
/*
* Indicates that this BD is 1BB long and is an empty TX BD. Not
* valid for use by the driver.
*/
#define BD_BASE_TYPE_TX_BD_EMPTY UINT32_C(0x1)
/*
* Indicates that this BD is 16B long and is an RX Producer (ie.
* empty) buffer descriptor.
*/
#define BD_BASE_TYPE_RX_PROD_PKT UINT32_C(0x4)
/*
* Indicates that this BD is 16B long and is an RX Producer
* Buffer BD.
*/
#define BD_BASE_TYPE_RX_PROD_BFR UINT32_C(0x5)
/*
* Indicates that this BD is 16B long and is an RX Producer
* Assembly Buffer Descriptor.
*/
#define BD_BASE_TYPE_RX_PROD_AGG UINT32_C(0x6)
/*
* Indicates that this BD is 32B long and is used for normal L2
* packet transmission.
*/
#define BD_BASE_TYPE_TX_BD_LONG UINT32_C(0x10)
uint8_t unused_1[7];
} __attribute__((packed));
/* Short TX BD (16 bytes) */
struct tx_bd_short {
uint16_t flags_type;
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
/* This value identifies the type of buffer descriptor. */
#define TX_BD_SHORT_TYPE_MASK UINT32_C(0x3f)
#define TX_BD_SHORT_TYPE_SFT 0
/*
* Indicates that this BD is 16B long and is used for normal L2
* packet transmission.
*/
#define TX_BD_SHORT_TYPE_TX_BD_SHORT UINT32_C(0x0)
/*
* If set to 1, the packet ends with the data in the buffer pointed to
* by this descriptor. This flag must be valid on every BD.
*/
#define TX_BD_SHORT_FLAGS_PACKET_END UINT32_C(0x40)
/*
* If set to 1, the device will not generate a completion for this
* transmit packet unless there is an error in it's processing. If this
* bit is set to 0, then the packet will be completed normally. This bit
* must be valid only on the first BD of a packet.
*/
#define TX_BD_SHORT_FLAGS_NO_CMPL UINT32_C(0x80)
/*
* This value indicates how many 16B BD locations are consumed in the
* ring by this packet. A value of 1 indicates that this BD is the only
* BD (and that the it is a short BD). A value of 3 indicates either 3
* short BDs or 1 long BD and one short BD in the packet. A value of 0
* indicates that there are 32 BD locations in the packet (the maximum).
* This field is valid only on the first BD of a packet.
*/
#define TX_BD_SHORT_FLAGS_BD_CNT_MASK UINT32_C(0x1f00)
#define TX_BD_SHORT_FLAGS_BD_CNT_SFT 8
/*
* This value is a hint for the length of the entire packet. It is used
* by the chip to optimize internal processing. The packet will be
* dropped if the hint is too short. This field is valid only on the
* first BD of a packet.
*/
#define TX_BD_SHORT_FLAGS_LHINT_MASK UINT32_C(0x6000)
#define TX_BD_SHORT_FLAGS_LHINT_SFT 13
/* indicates packet length < 512B */
#define TX_BD_SHORT_FLAGS_LHINT_LT512 (UINT32_C(0x0) << 13)
/* indicates 512 <= packet length < 1KB */
#define TX_BD_SHORT_FLAGS_LHINT_LT1K (UINT32_C(0x1) << 13)
/* indicates 1KB <= packet length < 2KB */
#define TX_BD_SHORT_FLAGS_LHINT_LT2K (UINT32_C(0x2) << 13)
/* indicates packet length >= 2KB */
#define TX_BD_SHORT_FLAGS_LHINT_GTE2K (UINT32_C(0x3) << 13)
#define TX_BD_SHORT_FLAGS_LHINT_LAST TX_BD_SHORT_FLAGS_LHINT_GTE2K
/*
* If set to 1, the device immediately updates the Send Consumer Index
* after the buffer associated with this descriptor has been transferred
* via DMA to NIC memory from host memory. An interrupt may or may not
* be generated according to the state of the interrupt avoidance
* mechanisms. If this bit is set to 0, then the Consumer Index is only
* updated as soon as one of the host interrupt coalescing conditions
* has been met. This bit must be valid on the first BD of a packet.
*/
#define TX_BD_SHORT_FLAGS_COAL_NOW UINT32_C(0x8000)
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
#define TX_BD_SHORT_FLAGS_MASK UINT32_C(0xffc0)
#define TX_BD_SHORT_FLAGS_SFT 6
uint16_t len;
/*
* This is the length of the host physical buffer this BD describes in
* bytes. This field must be valid on all BDs of a packet.
*/
uint32_t opaque;
/*
* The opaque data field is pass through to the completion and can be
* used for any data that the driver wants to associate with the
* transmit BD. This field must be valid on the first BD of a packet.
*/
uint64_t addr;
/*
* This is the host physical address for the portion of the packet
* described by this TX BD. This value must be valid on all BDs of a
* packet.
*/
} __attribute__((packed));
/* Long TX BD (32 bytes split to 2 16-byte struct) */
struct tx_bd_long {
uint16_t flags_type;
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
/* This value identifies the type of buffer descriptor. */
#define TX_BD_LONG_TYPE_MASK UINT32_C(0x3f)
#define TX_BD_LONG_TYPE_SFT 0
/*
* Indicates that this BD is 32B long and is used for normal L2
* packet transmission.
*/
#define TX_BD_LONG_TYPE_TX_BD_LONG UINT32_C(0x10)
/*
* If set to 1, the packet ends with the data in the buffer pointed to
* by this descriptor. This flag must be valid on every BD.
*/
#define TX_BD_LONG_FLAGS_PACKET_END UINT32_C(0x40)
/*
* If set to 1, the device will not generate a completion for this
* transmit packet unless there is an error in it's processing. If this
* bit is set to 0, then the packet will be completed normally. This bit
* must be valid only on the first BD of a packet.
*/
#define TX_BD_LONG_FLAGS_NO_CMPL UINT32_C(0x80)
/*
* This value indicates how many 16B BD locations are consumed in the
* ring by this packet. A value of 1 indicates that this BD is the only
* BD (and that the it is a short BD). A value of 3 indicates either 3
* short BDs or 1 long BD and one short BD in the packet. A value of 0
* indicates that there are 32 BD locations in the packet (the maximum).
* This field is valid only on the first BD of a packet.
*/
#define TX_BD_LONG_FLAGS_BD_CNT_MASK UINT32_C(0x1f00)
#define TX_BD_LONG_FLAGS_BD_CNT_SFT 8
/*
* This value is a hint for the length of the entire packet. It is used
* by the chip to optimize internal processing. The packet will be
* dropped if the hint is too short. This field is valid only on the
* first BD of a packet.
*/
#define TX_BD_LONG_FLAGS_LHINT_MASK UINT32_C(0x6000)
#define TX_BD_LONG_FLAGS_LHINT_SFT 13
/* indicates packet length < 512B */
#define TX_BD_LONG_FLAGS_LHINT_LT512 (UINT32_C(0x0) << 13)
/* indicates 512 <= packet length < 1KB */
#define TX_BD_LONG_FLAGS_LHINT_LT1K (UINT32_C(0x1) << 13)
/* indicates 1KB <= packet length < 2KB */
#define TX_BD_LONG_FLAGS_LHINT_LT2K (UINT32_C(0x2) << 13)
/* indicates packet length >= 2KB */
#define TX_BD_LONG_FLAGS_LHINT_GTE2K (UINT32_C(0x3) << 13)
#define TX_BD_LONG_FLAGS_LHINT_LAST TX_BD_LONG_FLAGS_LHINT_GTE2K
/*
* If set to 1, the device immediately updates the Send Consumer Index
* after the buffer associated with this descriptor has been transferred
* via DMA to NIC memory from host memory. An interrupt may or may not
* be generated according to the state of the interrupt avoidance
* mechanisms. If this bit is set to 0, then the Consumer Index is only
* updated as soon as one of the host interrupt coalescing conditions
* has been met. This bit must be valid on the first BD of a packet.
*/
#define TX_BD_LONG_FLAGS_COAL_NOW UINT32_C(0x8000)
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
#define TX_BD_LONG_FLAGS_MASK UINT32_C(0xffc0)
#define TX_BD_LONG_FLAGS_SFT 6
uint16_t len;
/*
* This is the length of the host physical buffer this BD describes in
* bytes. This field must be valid on all BDs of a packet.
*/
uint32_t opaque;
/*
* The opaque data field is pass through to the completion and can be
* used for any data that the driver wants to associate with the
* transmit BD. This field must be valid on the first BD of a packet.
*/
uint64_t addr;
/*
* This is the host physical address for the portion of the packet
* described by this TX BD. This value must be valid on all BDs of a
* packet.
*/
} __attribute__((packed));
/* last 16 bytes of Long TX BD */
struct tx_bd_long_hi {
uint16_t lflags;
/*
* All bits in this field must be valid on the first BD of a packet.
* Their value on other BDs of the packet will be ignored.
*/
/*
* If set to 1, the controller replaces the TCP/UPD checksum fields of
* normal TCP/UPD checksum, or the inner TCP/UDP checksum field of the
* encapsulated TCP/UDP packets with the hardware calculated TCP/UDP
* checksum for the packet associated with this descriptor. The flag is
* ignored if the LSO flag is set. This bit must be valid on the first
* BD of a packet.
*/
#define TX_BD_LONG_LFLAGS_TCP_UDP_CHKSUM UINT32_C(0x1)
/*
* If set to 1, the controller replaces the IP checksum of the normal
* packets, or the inner IP checksum of the encapsulated packets with
* the hardware calculated IP checksum for the packet associated with
* this descriptor. This bit must be valid on the first BD of a packet.
*/
#define TX_BD_LONG_LFLAGS_IP_CHKSUM UINT32_C(0x2)
/*
* If set to 1, the controller will not append an Ethernet CRC to the
* end of the frame. This bit must be valid on the first BD of a packet.
* Packet must be 64B or longer when this flag is set. It is not useful
* to use this bit with any form of TX offload such as CSO or LSO. The
* intent is that the packet from the host already has a valid Ethernet
* CRC on the packet.
*/
#define TX_BD_LONG_LFLAGS_NOCRC UINT32_C(0x4)
/*
* If set to 1, the device will record the time at which the packet was
* actually transmitted at the TX MAC. This bit must be valid on the
* first BD of a packet.
*/
#define TX_BD_LONG_LFLAGS_STAMP UINT32_C(0x8)
/*
* If set to 1, The controller replaces the tunnel IP checksum field
* with hardware calculated IP checksum for the IP header of the packet
* associated with this descriptor. For outer UDP checksum, global outer
* UDP checksum TE_NIC register needs to be enabled. If the global outer
* UDP checksum TE_NIC register bit is set, outer UDP checksum will be
* calculated for the following cases: 1. Packets with tcp_udp_chksum
* flag set to offload checksum for inner packet AND the inner packet is
* TCP/UDP. If the inner packet is ICMP for example (non-TCP/UDP), even
* if the tcp_udp_chksum is set, the outer UDP checksum will not be
* calculated. 2. Packets with lso flag set which implies inner TCP
* checksum calculation as part of LSO operation.
*/
#define TX_BD_LONG_LFLAGS_T_IP_CHKSUM UINT32_C(0x10)
/*
* If set to 1, the device will treat this packet with LSO(Large Send
* Offload) processing for both normal or encapsulated packets, which is
* a form of TCP segmentation. When this bit is 1, the hdr_size and mss
* fields must be valid. The driver doesn't need to set t_ip_chksum,
* ip_chksum, and tcp_udp_chksum flags since the controller will replace
* the appropriate checksum fields for segmented packets. When this bit
* is 1, the hdr_size and mss fields must be valid.
*/
#define TX_BD_LONG_LFLAGS_LSO UINT32_C(0x20)
/*
* If set to zero when LSO is '1', then the IPID will be treated as a
* 16b number and will be wrapped if it exceeds a value of 0xffff. If
* set to one when LSO is '1', then the IPID will be treated as a 15b
* number and will be wrapped if it exceeds a value 0f 0x7fff.
*/
#define TX_BD_LONG_LFLAGS_IPID_FMT UINT32_C(0x40)
/*
* If set to zero when LSO is '1', then the IPID of the tunnel IP header
* will not be modified during LSO operations. If set to one when LSO is
* '1', then the IPID of the tunnel IP header will be incremented for
* each subsequent segment of an LSO operation. The flag is ignored if
* the LSO packet is a normal (non-tunneled) TCP packet.
*/
#define TX_BD_LONG_LFLAGS_T_IPID UINT32_C(0x80)
/*
* If set to '1', then the RoCE ICRC will be appended to the packet.
* Packet must be a valid RoCE format packet.
*/
#define TX_BD_LONG_LFLAGS_ROCE_CRC UINT32_C(0x100)
/*
* If set to '1', then the FCoE CRC will be appended to the packet.
* Packet must be a valid FCoE format packet.
*/
#define TX_BD_LONG_LFLAGS_FCOE_CRC UINT32_C(0x200)
uint16_t hdr_size;
/*
* When LSO is '1', this field must contain the offset of the TCP
* payload from the beginning of the packet in as 16b words. In case of
* encapsulated/tunneling packet, this field contains the offset of the
* inner TCP payload from beginning of the packet as 16-bit words. This
* value must be valid on the first BD of a packet.
*/
#define TX_BD_LONG_HDR_SIZE_MASK UINT32_C(0x1ff)
#define TX_BD_LONG_HDR_SIZE_SFT 0
uint32_t mss;
/*
* This is the MSS value that will be used to do the LSO processing. The
* value is the length in bytes of the TCP payload for each segment
* generated by the LSO operation. This value must be valid on the first
* BD of a packet.
*/
#define TX_BD_LONG_MSS_MASK UINT32_C(0x7fff)
#define TX_BD_LONG_MSS_SFT 0
uint16_t unused_2;
uint16_t cfa_action;
/*
* This value selects a CFA action to perform on the packet. Set this
* value to zero if no CFA action is desired. This value must be valid
* on the first BD of a packet.
*/
uint32_t cfa_meta;
/*
* This value is action meta-data that defines CFA edit operations that
* are done in addition to any action editing.
*/
/* When key=1, This is the VLAN tag VID value. */
#define TX_BD_LONG_CFA_META_VLAN_VID_MASK UINT32_C(0xfff)
#define TX_BD_LONG_CFA_META_VLAN_VID_SFT 0
/* When key=1, This is the VLAN tag DE value. */
#define TX_BD_LONG_CFA_META_VLAN_DE UINT32_C(0x1000)
/* When key=1, This is the VLAN tag PRI value. */
#define TX_BD_LONG_CFA_META_VLAN_PRI_MASK UINT32_C(0xe000)
#define TX_BD_LONG_CFA_META_VLAN_PRI_SFT 13
/* When key=1, This is the VLAN tag TPID select value. */
#define TX_BD_LONG_CFA_META_VLAN_TPID_MASK UINT32_C(0x70000)
#define TX_BD_LONG_CFA_META_VLAN_TPID_SFT 16
/* 0x88a8 */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPID88A8 (UINT32_C(0x0) << 16)
/* 0x8100 */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPID8100 (UINT32_C(0x1) << 16)
/* 0x9100 */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPID9100 (UINT32_C(0x2) << 16)
/* 0x9200 */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPID9200 (UINT32_C(0x3) << 16)
/* 0x9300 */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPID9300 (UINT32_C(0x4) << 16)
/* Value programmed in CFA VLANTPID register. */
#define TX_BD_LONG_CFA_META_VLAN_TPID_TPIDCFG (UINT32_C(0x5) << 16)
#define TX_BD_LONG_CFA_META_VLAN_TPID_LAST TX_BD_LONG_CFA_META_VLAN_TPID_TPIDCFG
/* When key=1, This is the VLAN tag TPID select value. */
#define TX_BD_LONG_CFA_META_VLAN_RESERVED_MASK UINT32_C(0xff80000)
#define TX_BD_LONG_CFA_META_VLAN_RESERVED_SFT 19
/*
* This field identifies the type of edit to be performed on the packet.
* This value must be valid on the first BD of a packet.
*/
#define TX_BD_LONG_CFA_META_KEY_MASK UINT32_C(0xf0000000)
#define TX_BD_LONG_CFA_META_KEY_SFT 28
/* No editing */
#define TX_BD_LONG_CFA_META_KEY_NONE (UINT32_C(0x0) << 28)
/*
* - meta[17:16] - TPID select value (0 = 0x8100). - meta[15:12]
* - PRI/DE value. - meta[11:0] - VID value.
*/
#define TX_BD_LONG_CFA_META_KEY_VLAN_TAG (UINT32_C(0x1) << 28)
#define TX_BD_LONG_CFA_META_KEY_LAST TX_BD_LONG_CFA_META_KEY_VLAN_TAG
} __attribute__((packed));
/* Empty TX BD (16 bytes) */
struct tx_bd_empty {
uint8_t type;
/* This value identifies the type of buffer descriptor. */
#define TX_BD_EMPTY_TYPE_MASK UINT32_C(0x3f)
#define TX_BD_EMPTY_TYPE_SFT 0
/*
* Indicates that this BD is 1BB long and is an empty TX BD. Not
* valid for use by the driver.
*/
#define TX_BD_EMPTY_TYPE_TX_BD_EMPTY UINT32_C(0x1)
uint8_t unused_1[3];
uint8_t unused_2;
uint8_t unused_3[3];
uint64_t unused_4;
} __attribute__((packed));
/* RX Producer Packet BD (16 bytes) */
struct rx_prod_pkt_bd {
uint16_t flags_type;
/* This value identifies the type of buffer descriptor. */
#define RX_PROD_PKT_BD_TYPE_MASK UINT32_C(0x3f)
#define RX_PROD_PKT_BD_TYPE_SFT 0
/*
* Indicates that this BD is 16B long and is an RX Producer (ie.
* empty) buffer descriptor.
*/
#define RX_PROD_PKT_BD_TYPE_RX_PROD_PKT UINT32_C(0x4)
/*
* If set to 1, the packet will be placed at the address plus 2B. The 2
* Bytes of padding will be written as zero.
*/
/*
* This is intended to be used when the host buffer is cache-line
* aligned to produce packets that are easy to parse in host memory
* while still allowing writes to be cache line aligned.
*/
#define RX_PROD_PKT_BD_FLAGS_SOP_PAD UINT32_C(0x40)
/*
* If set to 1, the packet write will be padded out to the nearest
* cache-line with zero value padding.
*/
/*
* If receive buffers start/end on cache-line boundaries, this feature
* will ensure that all data writes on the PCI bus start/end on cache
* line boundaries.
*/
#define RX_PROD_PKT_BD_FLAGS_EOP_PAD UINT32_C(0x80)
/*
* This value is the number of additional buffers in the ring that
* describe the buffer space to be consumed for the this packet. If the
* value is zero, then the packet must fit within the space described by
* this BD. If this value is 1 or more, it indicates how many additional
* "buffer" BDs are in the ring immediately following this BD to be used
* for the same network packet. Even if the packet to be placed does not
* need all the additional buffers, they will be consumed anyway.
*/
#define RX_PROD_PKT_BD_FLAGS_BUFFERS_MASK UINT32_C(0x300)
#define RX_PROD_PKT_BD_FLAGS_BUFFERS_SFT 8
#define RX_PROD_PKT_BD_FLAGS_MASK UINT32_C(0xffc0)
#define RX_PROD_PKT_BD_FLAGS_SFT 6
uint16_t len;
/*
* This is the length in Bytes of the host physical buffer where data
* for the packet may be placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provided end on a host cache line.
*/
uint32_t opaque;
/*
* The opaque data field is pass through to the completion and can be
* used for any data that the driver wants to associate with this
* receive buffer set.
*/
uint64_t addr;
/*
* This is the host physical address where data for the packet may by
* placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provide start on a host cache line.
*/
} __attribute__((packed));
/* RX Producer Buffer BD (16 bytes) */
struct rx_prod_bfr_bd {
uint16_t flags_type;
/* This value identifies the type of buffer descriptor. */
#define RX_PROD_BFR_BD_TYPE_MASK UINT32_C(0x3f)
#define RX_PROD_BFR_BD_TYPE_SFT 0
/*
* Indicates that this BD is 16B long and is an RX Producer
* Buffer BD.
*/
#define RX_PROD_BFR_BD_TYPE_RX_PROD_BFR UINT32_C(0x5)
#define RX_PROD_BFR_BD_FLAGS_MASK UINT32_C(0xffc0)
#define RX_PROD_BFR_BD_FLAGS_SFT 6
uint16_t len;
/*
* This is the length in Bytes of the host physical buffer where data
* for the packet may be placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provided end on a host cache line.
*/
uint32_t opaque;
/* This field is not used. */
uint64_t addr;
/*
* This is the host physical address where data for the packet may by
* placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provide start on a host cache line.
*/
} __attribute__((packed));
/* RX Producer Aggregation BD (16 bytes) */
struct rx_prod_agg_bd {
uint16_t flags_type;
/* This value identifies the type of buffer descriptor. */
#define RX_PROD_AGG_BD_TYPE_MASK UINT32_C(0x3f)
#define RX_PROD_AGG_BD_TYPE_SFT 0
/*
* Indicates that this BD is 16B long and is an RX Producer
* Assembly Buffer Descriptor.
*/
#define RX_PROD_AGG_BD_TYPE_RX_PROD_AGG UINT32_C(0x6)
/*
* If set to 1, the packet write will be padded out to the nearest
* cache-line with zero value padding.
*/
/*
* If receive buffers start/end on cache-line boundaries, this feature
* will ensure that all data writes on the PCI bus end on cache line
* boundaries.
*/
#define RX_PROD_AGG_BD_FLAGS_EOP_PAD UINT32_C(0x40)
#define RX_PROD_AGG_BD_FLAGS_MASK UINT32_C(0xffc0)
#define RX_PROD_AGG_BD_FLAGS_SFT 6
uint16_t len;
/*
* This is the length in Bytes of the host physical buffer where data
* for the packet may be placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provided end on a host cache line.
*/
uint32_t opaque;
/*
* The opaque data field is pass through to the completion and can be
* used for any data that the driver wants to associate with this
* receive assembly buffer.
*/
uint64_t addr;
/*
* This is the host physical address where data for the packet may by
* placed in host memory.
*/
/*
* While this is a Byte resolution value, it is often advantageous to
* ensure that the buffers provide start on a host cache line.
*/
} __attribute__((packed));
/* Completion Ring Structures */
/* Note: This structure is used by the HWRM to communicate HWRM Error. */
/* Base Completion Record (16 bytes) */
struct cmpl_base {
uint16_t type;
/* unused is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CMPL_BASE_TYPE_MASK UINT32_C(0x3f)
#define CMPL_BASE_TYPE_SFT 0
/* TX L2 completion: Completion of TX packet. Length = 16B */
#define CMPL_BASE_TYPE_TX_L2 UINT32_C(0x0)
/* RX L2 completion: Completion of and L2 RX packet. Length = 32B */
#define CMPL_BASE_TYPE_RX_L2 UINT32_C(0x11)
/*
* RX Aggregation Buffer completion : Completion of an L2
* aggregation buffer in support of TPA, HDS, or Jumbo packet
* completion. Length = 16B
*/
#define CMPL_BASE_TYPE_RX_AGG UINT32_C(0x12)
/*
* RX L2 TPA Start Completion: Completion at the beginning of a
* TPA operation. Length = 32B
*/
#define CMPL_BASE_TYPE_RX_TPA_START UINT32_C(0x13)
/*
* RX L2 TPA End Completion: Completion at the end of a TPA
* operation. Length = 32B
*/
#define CMPL_BASE_TYPE_RX_TPA_END UINT32_C(0x15)
/*
* Statistics Ejection Completion: Completion of statistics data
* ejection buffer. Length = 16B
*/
#define CMPL_BASE_TYPE_STAT_EJECT UINT32_C(0x1a)
/* HWRM Command Completion: Completion of an HWRM command. */
#define CMPL_BASE_TYPE_HWRM_DONE UINT32_C(0x20)
/* Forwarded HWRM Request */
#define CMPL_BASE_TYPE_HWRM_FWD_REQ UINT32_C(0x22)
/* Forwarded HWRM Response */
#define CMPL_BASE_TYPE_HWRM_FWD_RESP UINT32_C(0x24)
/* HWRM Asynchronous Event Information */
#define CMPL_BASE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* CQ Notification */
#define CMPL_BASE_TYPE_CQ_NOTIFICATION UINT32_C(0x30)
/* SRQ Threshold Event */
#define CMPL_BASE_TYPE_SRQ_EVENT UINT32_C(0x32)
/* DBQ Threshold Event */
#define CMPL_BASE_TYPE_DBQ_EVENT UINT32_C(0x34)
/* QP Async Notification */
#define CMPL_BASE_TYPE_QP_EVENT UINT32_C(0x38)
/* Function Async Notification */
#define CMPL_BASE_TYPE_FUNC_EVENT UINT32_C(0x3a)
/* unused is 10 b */
uint16_t info1;
/* info1 is 16 b */
uint32_t info2;
/* info2 is 32 b */
uint32_t info3_v;
/* info3 is 31 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CMPL_BASE_V UINT32_C(0x1)
/* info3 is 31 b */
#define CMPL_BASE_INFO3_MASK UINT32_C(0xfffffffe)
#define CMPL_BASE_INFO3_SFT 1
uint32_t info4;
/* info4 is 32 b */
} __attribute__((packed));
/* TX Completion Record (16 bytes) */
struct tx_cmpl {
uint16_t flags_type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define TX_CMPL_TYPE_MASK UINT32_C(0x3f)
#define TX_CMPL_TYPE_SFT 0
/* TX L2 completion: Completion of TX packet. Length = 16B */
#define TX_CMPL_TYPE_TX_L2 UINT32_C(0x0)
/*
* When this bit is '1', it indicates a packet that has an error of some
* type. Type of error is indicated in error_flags.
*/
#define TX_CMPL_FLAGS_ERROR UINT32_C(0x40)
/*
* When this bit is '1', it indicates that the packet completed was
* transmitted using the push acceleration data provided by the driver.
* When this bit is '0', it indicates that the packet had not push
* acceleration data written or was executed as a normal packet even
* though push data was provided.
*/
#define TX_CMPL_FLAGS_PUSH UINT32_C(0x80)
#define TX_CMPL_FLAGS_MASK UINT32_C(0xffc0)
#define TX_CMPL_FLAGS_SFT 6
uint16_t unused_0;
/* unused1 is 16 b */
uint32_t opaque;
/*
* This is a copy of the opaque field from the first TX BD of this
* transmitted packet.
*/
uint16_t errors_v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define TX_CMPL_V UINT32_C(0x1)
/*
* This error indicates that there was some sort of problem with the BDs
* for the packet.
*/
#define TX_CMPL_ERRORS_BUFFER_ERROR_MASK UINT32_C(0xe)
#define TX_CMPL_ERRORS_BUFFER_ERROR_SFT 1
/* No error */
#define TX_CMPL_ERRORS_BUFFER_ERROR_NO_ERROR (UINT32_C(0x0) << 1)
/* Bad Format: BDs were not formatted correctly. */
#define TX_CMPL_ERRORS_BUFFER_ERROR_BAD_FMT (UINT32_C(0x2) << 1)
#define TX_CMPL_ERRORS_BUFFER_ERROR_LAST TX_CMPL_ERRORS_BUFFER_ERROR_BAD_FMT
/*
* When this bit is '1', it indicates that the length of the packet was
* zero. No packet was transmitted.
*/
#define TX_CMPL_ERRORS_ZERO_LENGTH_PKT UINT32_C(0x10)
/*
* When this bit is '1', it indicates that the packet was longer than
* the programmed limit in TDI. No packet was transmitted.
*/
#define TX_CMPL_ERRORS_EXCESSIVE_BD_LENGTH UINT32_C(0x20)
/*
* When this bit is '1', it indicates that one or more of the BDs
* associated with this packet generated a PCI error. This probably
* means the address was not valid.
*/
#define TX_CMPL_ERRORS_DMA_ERROR UINT32_C(0x40)
/*
* When this bit is '1', it indicates that the packet was longer than
* indicated by the hint. No packet was transmitted.
*/
#define TX_CMPL_ERRORS_HINT_TOO_SHORT UINT32_C(0x80)
/*
* When this bit is '1', it indicates that the packet was dropped due to
* Poison TLP error on one or more of the TLPs in the PXP completion.
*/
#define TX_CMPL_ERRORS_POISON_TLP_ERROR UINT32_C(0x100)
#define TX_CMPL_ERRORS_MASK UINT32_C(0xfffe)
#define TX_CMPL_ERRORS_SFT 1
uint16_t unused_1;
/* unused2 is 16 b */
uint32_t unused_2;
/* unused3 is 32 b */
} __attribute__((packed));
/* RX Packet Completion Record (32 bytes split to 2 16-byte struct) */
struct rx_pkt_cmpl {
uint16_t flags_type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define RX_PKT_CMPL_TYPE_MASK UINT32_C(0x3f)
#define RX_PKT_CMPL_TYPE_SFT 0
/* RX L2 completion: Completion of and L2 RX packet. Length = 32B */
#define RX_PKT_CMPL_TYPE_RX_L2 UINT32_C(0x11)
/*
* When this bit is '1', it indicates a packet that has an error of some
* type. Type of error is indicated in error_flags.
*/
#define RX_PKT_CMPL_FLAGS_ERROR UINT32_C(0x40)
/* This field indicates how the packet was placed in the buffer. */
#define RX_PKT_CMPL_FLAGS_PLACEMENT_MASK UINT32_C(0x380)
#define RX_PKT_CMPL_FLAGS_PLACEMENT_SFT 7
/* Normal: Packet was placed using normal algorithm. */
#define RX_PKT_CMPL_FLAGS_PLACEMENT_NORMAL (UINT32_C(0x0) << 7)
/* Jumbo: Packet was placed using jumbo algorithm. */
#define RX_PKT_CMPL_FLAGS_PLACEMENT_JUMBO (UINT32_C(0x1) << 7)
/*
* Header/Data Separation: Packet was placed using Header/Data
* separation algorithm. The separation location is indicated by
* the itype field.
*/
#define RX_PKT_CMPL_FLAGS_PLACEMENT_HDS (UINT32_C(0x2) << 7)
#define RX_PKT_CMPL_FLAGS_PLACEMENT_LAST RX_PKT_CMPL_FLAGS_PLACEMENT_HDS
/* This bit is '1' if the RSS field in this completion is valid. */
#define RX_PKT_CMPL_FLAGS_RSS_VALID UINT32_C(0x400)
/* unused is 1 b */
#define RX_PKT_CMPL_FLAGS_UNUSED UINT32_C(0x800)
/*
* This value indicates what the inner packet determined for the packet
* was.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_MASK UINT32_C(0xf000)
#define RX_PKT_CMPL_FLAGS_ITYPE_SFT 12
/* Not Known: Indicates that the packet type was not known. */
#define RX_PKT_CMPL_FLAGS_ITYPE_NOT_KNOWN (UINT32_C(0x0) << 12)
/*
* IP Packet: Indicates that the packet was an IP packet, but
* further classification was not possible.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_IP (UINT32_C(0x1) << 12)
/*
* TCP Packet: Indicates that the packet was IP and TCP. This
* indicates that the payload_offset field is valid.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_TCP (UINT32_C(0x2) << 12)
/*
* UDP Packet: Indicates that the packet was IP and UDP. This
* indicates that the payload_offset field is valid.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_UDP (UINT32_C(0x3) << 12)
/*
* FCoE Packet: Indicates that the packet was recognized as a
* FCoE. This also indicates that the payload_offset field is
* valid.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_FCOE (UINT32_C(0x4) << 12)
/*
* RoCE Packet: Indicates that the packet was recognized as a
* RoCE. This also indicates that the payload_offset field is
* valid.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_ROCE (UINT32_C(0x5) << 12)
/*
* ICMP Packet: Indicates that the packet was recognized as
* ICMP. This indicates that the payload_offset field is valid.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_ICMP (UINT32_C(0x7) << 12)
/*
* PtP packet wo/timestamp: Indicates that the packet was
* recognized as a PtP packet.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_PTP_WO_TIMESTAMP (UINT32_C(0x8) << 12)
/*
* PtP packet w/timestamp: Indicates that the packet was
* recognized as a PtP packet and that a timestamp was taken for
* the packet.
*/
#define RX_PKT_CMPL_FLAGS_ITYPE_PTP_W_TIMESTAMP (UINT32_C(0x9) << 12)
#define RX_PKT_CMPL_FLAGS_ITYPE_LAST RX_PKT_CMPL_FLAGS_ITYPE_PTP_W_TIMESTAMP
#define RX_PKT_CMPL_FLAGS_MASK UINT32_C(0xffc0)
#define RX_PKT_CMPL_FLAGS_SFT 6
uint16_t len;
/*
* This is the length of the data for the packet stored in the buffer(s)
* identified by the opaque value. This includes the packet BD and any
* associated buffer BDs. This does not include the the length of any
* data places in aggregation BDs.
*/
uint32_t opaque;
/*
* This is a copy of the opaque field from the RX BD this completion
* corresponds to.
*/
uint8_t agg_bufs_v1;
/* unused1 is 2 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_PKT_CMPL_V1 UINT32_C(0x1)
/*
* This value is the number of aggregation buffers that follow this
* entry in the completion ring that are a part of this packet. If the
* value is zero, then the packet is completely contained in the buffer
* space provided for the packet in the RX ring.
*/
#define RX_PKT_CMPL_AGG_BUFS_MASK UINT32_C(0x3e)
#define RX_PKT_CMPL_AGG_BUFS_SFT 1
/* unused1 is 2 b */
uint8_t rss_hash_type;
/*
* This is the RSS hash type for the packet. The value is packed
* {tuple_extrac_op[1:0],rss_profile_id[4:0],tuple_extrac_op[2]}. The
* value of tuple_extrac_op provides the information about what fields
* the hash was computed on. * 0: The RSS hash was computed over source
* IP address, destination IP address, source port, and destination port
* of inner IP and TCP or UDP headers. Note: For non-tunneled packets,
* the packet headers are considered inner packet headers for the RSS
* hash computation purpose. * 1: The RSS hash was computed over source
* IP address and destination IP address of inner IP header. Note: For
* non-tunneled packets, the packet headers are considered inner packet
* headers for the RSS hash computation purpose. * 2: The RSS hash was
* computed over source IP address, destination IP address, source port,
* and destination port of IP and TCP or UDP headers of outer tunnel
* headers. Note: For non-tunneled packets, this value is not
* applicable. * 3: The RSS hash was computed over source IP address and
* destination IP address of IP header of outer tunnel headers. Note:
* For non-tunneled packets, this value is not applicable. Note that
* 4-tuples values listed above are applicable for layer 4 protocols
* supported and enabled for RSS in the hardware, HWRM firmware, and
* drivers. For example, if RSS hash is supported and enabled for TCP
* traffic only, then the values of tuple_extract_op corresponding to
* 4-tuples are only valid for TCP traffic.
*/
uint8_t payload_offset;
/*
* This value indicates the offset in bytes from the beginning of the
* packet where the inner payload starts. This value is valid for TCP,
* UDP, FCoE, and RoCE packets. A value of zero indicates that header is
* 256B into the packet.
*/
uint8_t unused_1;
/* unused2 is 8 b */
uint32_t rss_hash;
/*
* This value is the RSS hash value calculated for the packet based on
* the mode bits and key value in the VNIC.
*/
} __attribute__((packed));
/* last 16 bytes of RX Packet Completion Record */
struct rx_pkt_cmpl_hi {
uint32_t flags2;
/*
* This indicates that the ip checksum was calculated for the inner
* packet and that the ip_cs_error field indicates if there was an
* error.
*/
#define RX_PKT_CMPL_FLAGS2_IP_CS_CALC UINT32_C(0x1)
/*
* This indicates that the TCP, UDP or ICMP checksum was calculated for
* the inner packet and that the l4_cs_error field indicates if there
* was an error.
*/
#define RX_PKT_CMPL_FLAGS2_L4_CS_CALC UINT32_C(0x2)
/*
* This indicates that the ip checksum was calculated for the tunnel
* header and that the t_ip_cs_error field indicates if there was an
* error.
*/
#define RX_PKT_CMPL_FLAGS2_T_IP_CS_CALC UINT32_C(0x4)
/*
* This indicates that the UDP checksum was calculated for the tunnel
* packet and that the t_l4_cs_error field indicates if there was an
* error.
*/
#define RX_PKT_CMPL_FLAGS2_T_L4_CS_CALC UINT32_C(0x8)
/* This value indicates what format the metadata field is. */
#define RX_PKT_CMPL_FLAGS2_META_FORMAT_MASK UINT32_C(0xf0)
#define RX_PKT_CMPL_FLAGS2_META_FORMAT_SFT 4
/* No metadata informtaion. Value is zero. */
#define RX_PKT_CMPL_FLAGS2_META_FORMAT_NONE (UINT32_C(0x0) << 4)
/*
* The metadata field contains the VLAN tag and TPID value. -
* metadata[11:0] contains the vlan VID value. - metadata[12]
* contains the vlan DE value. - metadata[15:13] contains the
* vlan PRI value. - metadata[31:16] contains the vlan TPID
* value.
*/
#define RX_PKT_CMPL_FLAGS2_META_FORMAT_VLAN (UINT32_C(0x1) << 4)
#define RX_PKT_CMPL_FLAGS2_META_FORMAT_LAST RX_PKT_CMPL_FLAGS2_META_FORMAT_VLAN
/*
* This field indicates the IP type for the inner-most IP header. A
* value of '0' indicates IPv4. A value of '1' indicates IPv6. This
* value is only valid if itype indicates a packet with an IP header.
*/
#define RX_PKT_CMPL_FLAGS2_IP_TYPE UINT32_C(0x100)
uint32_t metadata;
/*
* This is data from the CFA block as indicated by the meta_format
* field.
*/
/* When meta_format=1, this value is the VLAN VID. */
#define RX_PKT_CMPL_METADATA_VID_MASK UINT32_C(0xfff)
#define RX_PKT_CMPL_METADATA_VID_SFT 0
/* When meta_format=1, this value is the VLAN DE. */
#define RX_PKT_CMPL_METADATA_DE UINT32_C(0x1000)
/* When meta_format=1, this value is the VLAN PRI. */
#define RX_PKT_CMPL_METADATA_PRI_MASK UINT32_C(0xe000)
#define RX_PKT_CMPL_METADATA_PRI_SFT 13
/* When meta_format=1, this value is the VLAN TPID. */
#define RX_PKT_CMPL_METADATA_TPID_MASK UINT32_C(0xffff0000)
#define RX_PKT_CMPL_METADATA_TPID_SFT 16
uint16_t errors_v2;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_PKT_CMPL_V2 UINT32_C(0x1)
/*
* This error indicates that there was some sort of problem with the BDs
* for the packet that was found after part of the packet was already
* placed. The packet should be treated as invalid.
*/
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_MASK UINT32_C(0xe)
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_SFT 1
/* No buffer error */
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_NO_BUFFER (UINT32_C(0x0) << 1)
/*
* Did Not Fit: Packet did not fit into packet buffer provided.
* For regular placement, this means the packet did not fit in
* the buffer provided. For HDS and jumbo placement, this means
* that the packet could not be placed into 7 physical buffers
* or less.
*/
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_DID_NOT_FIT (UINT32_C(0x1) << 1)
/*
* Not On Chip: All BDs needed for the packet were not on-chip
* when the packet arrived.
*/
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_NOT_ON_CHIP (UINT32_C(0x2) << 1)
/* Bad Format: BDs were not formatted correctly. */
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_BAD_FORMAT (UINT32_C(0x3) << 1)
#define RX_PKT_CMPL_ERRORS_BUFFER_ERROR_LAST RX_PKT_CMPL_ERRORS_BUFFER_ERROR_BAD_FORMAT
/* This indicates that there was an error in the IP header checksum. */
#define RX_PKT_CMPL_ERRORS_IP_CS_ERROR UINT32_C(0x10)
/*
* This indicates that there was an error in the TCP, UDP or ICMP
* checksum.
*/
#define RX_PKT_CMPL_ERRORS_L4_CS_ERROR UINT32_C(0x20)
/*
* This indicates that there was an error in the tunnel IP header
* checksum.
*/
#define RX_PKT_CMPL_ERRORS_T_IP_CS_ERROR UINT32_C(0x40)
/* This indicates that there was an error in the tunnel UDP checksum. */
#define RX_PKT_CMPL_ERRORS_T_L4_CS_ERROR UINT32_C(0x80)
/*
* This indicates that there was a CRC error on either an FCoE or RoCE
* packet. The itype indicates the packet type.
*/
#define RX_PKT_CMPL_ERRORS_CRC_ERROR UINT32_C(0x100)
/*
* This indicates that there was an error in the tunnel portion of the
* packet when this field is non-zero.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_MASK UINT32_C(0xe00)
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_SFT 9
/*
* No additional error occurred on the tunnel portion of the
* packet of the packet does not have a tunnel.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_NO_ERROR (UINT32_C(0x0) << 9)
/*
* Indicates that IP header version does not match expectation
* from L2 Ethertype for IPv4 and IPv6 in the tunnel header.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_L3_BAD_VERSION (UINT32_C(0x1) << 9)
/*
* Indicates that header length is out of range in the tunnel
* header. Valid for IPv4.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_L3_BAD_HDR_LEN (UINT32_C(0x2) << 9)
/*
* Indicates that the physical packet is shorter than that
* claimed by the PPPoE header length for a tunnel PPPoE packet.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_TUNNEL_TOTAL_ERROR (UINT32_C(0x3) << 9)
/*
* Indicates that physical packet is shorter than that claimed
* by the tunnel l3 header length. Valid for IPv4, or IPv6
* tunnel packet packets.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_IP_TOTAL_ERROR (UINT32_C(0x4) << 9)
/*
* Indicates that the physical packet is shorter than that
* claimed by the tunnel UDP header length for a tunnel UDP
* packet that is not fragmented.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_UDP_TOTAL_ERROR (UINT32_C(0x5) << 9)
/*
* indicates that the IPv4 TTL or IPv6 hop limit check have
* failed (e.g. TTL = 0) in the tunnel header. Valid for IPv4,
* and IPv6.
*/
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_L3_BAD_TTL (UINT32_C(0x6) << 9)
#define RX_PKT_CMPL_ERRORS_T_PKT_ERROR_LAST RX_PKT_CMPL_ERRORS_T_PKT_ERROR_T_L3_BAD_TTL
/*
* This indicates that there was an error in the inner portion of the
* packet when this field is non-zero.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_MASK UINT32_C(0xf000)
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_SFT 12
/*
* No additional error occurred on the tunnel portion of the
* packet of the packet does not have a tunnel.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_NO_ERROR (UINT32_C(0x0) << 12)
/*
* Indicates that IP header version does not match expectation
* from L2 Ethertype for IPv4 and IPv6 or that option other than
* VFT was parsed on FCoE packet.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L3_BAD_VERSION (UINT32_C(0x1) << 12)
/*
* indicates that header length is out of range. Valid for IPv4
* and RoCE
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L3_BAD_HDR_LEN (UINT32_C(0x2) << 12)
/*
* indicates that the IPv4 TTL or IPv6 hop limit check have
* failed (e.g. TTL = 0). Valid for IPv4, and IPv6
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L3_BAD_TTL (UINT32_C(0x3) << 12)
/*
* Indicates that physical packet is shorter than that claimed
* by the l3 header length. Valid for IPv4, IPv6 packet or RoCE
* packets.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_IP_TOTAL_ERROR (UINT32_C(0x4) << 12)
/*
* Indicates that the physical packet is shorter than that
* claimed by the UDP header length for a UDP packet that is not
* fragmented.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_UDP_TOTAL_ERROR (UINT32_C(0x5) << 12)
/*
* Indicates that TCP header length > IP payload. Valid for TCP
* packets only.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L4_BAD_HDR_LEN (UINT32_C(0x6) << 12)
/* Indicates that TCP header length < 5. Valid for TCP. */
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L4_BAD_HDR_LEN_TOO_SMALL (UINT32_C(0x7) << 12)
/*
* Indicates that TCP option headers result in a TCP header size
* that does not match data offset in TCP header. Valid for TCP.
*/
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_L4_BAD_OPT_LEN (UINT32_C(0x8) << 12)
#define RX_PKT_CMPL_ERRORS_PKT_ERROR_LAST RX_PKT_CMPL_ERRORS_PKT_ERROR_L4_BAD_OPT_LEN
#define RX_PKT_CMPL_ERRORS_MASK UINT32_C(0xfffe)
#define RX_PKT_CMPL_ERRORS_SFT 1
uint16_t cfa_code;
/*
* This field identifies the CFA action rule that was used for this
* packet.
*/
uint32_t reorder;
/*
* This value holds the reordering sequence number for the packet. If
* the reordering sequence is not valid, then this value is zero. The
* reordering domain for the packet is in the bottom 8 to 10b of the
* rss_hash value. The bottom 20b of this value contain the ordering
* domain value for the packet.
*/
#define RX_PKT_CMPL_REORDER_MASK UINT32_C(0xffffff)
#define RX_PKT_CMPL_REORDER_SFT 0
} __attribute__((packed));
/* RX L2 TPA Start Completion Record (32 bytes split to 2 16-byte struct) */
struct rx_tpa_start_cmpl {
uint16_t flags_type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define RX_TPA_START_CMPL_TYPE_MASK UINT32_C(0x3f)
#define RX_TPA_START_CMPL_TYPE_SFT 0
/*
* RX L2 TPA Start Completion: Completion at the beginning of a
* TPA operation. Length = 32B
*/
#define RX_TPA_START_CMPL_TYPE_RX_TPA_START UINT32_C(0x13)
/* This bit will always be '0' for TPA start completions. */
#define RX_TPA_START_CMPL_FLAGS_ERROR UINT32_C(0x40)
/* This field indicates how the packet was placed in the buffer. */
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_MASK UINT32_C(0x380)
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_SFT 7
/*
* Jumbo: TPA Packet was placed using jumbo algorithm. This
* means that the first buffer will be filled with data before
* moving to aggregation buffers. Each aggregation buffer will
* be filled before moving to the next aggregation buffer.
*/
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_JUMBO (UINT32_C(0x1) << 7)
/*
* Header/Data Separation: Packet was placed using Header/Data
* separation algorithm. The separation location is indicated by
* the itype field.
*/
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_HDS (UINT32_C(0x2) << 7)
/*
* GRO/Jumbo: Packet will be placed using GRO/Jumbo where the
* first packet is filled with data. Subsequent packets will be
* placed such that any one packet does not span two aggregation
* buffers unless it starts at the beginning of an aggregation
* buffer.
*/
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_GRO_JUMBO (UINT32_C(0x5) << 7)
/*
* GRO/Header-Data Separation: Packet will be placed using
* GRO/HDS where the header is in the first packet. Payload of
* each packet will be placed such that any one packet does not
* span two aggregation buffers unless it starts at the
* beginning of an aggregation buffer.
*/
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_GRO_HDS (UINT32_C(0x6) << 7)
#define RX_TPA_START_CMPL_FLAGS_PLACEMENT_LAST RX_TPA_START_CMPL_FLAGS_PLACEMENT_GRO_HDS
/* This bit is '1' if the RSS field in this completion is valid. */
#define RX_TPA_START_CMPL_FLAGS_RSS_VALID UINT32_C(0x400)
/* unused is 1 b */
#define RX_TPA_START_CMPL_FLAGS_UNUSED UINT32_C(0x800)
/*
* This value indicates what the inner packet determined for the packet
* was.
*/
#define RX_TPA_START_CMPL_FLAGS_ITYPE_MASK UINT32_C(0xf000)
#define RX_TPA_START_CMPL_FLAGS_ITYPE_SFT 12
/* TCP Packet: Indicates that the packet was IP and TCP. */
#define RX_TPA_START_CMPL_FLAGS_ITYPE_TCP (UINT32_C(0x2) << 12)
#define RX_TPA_START_CMPL_FLAGS_ITYPE_LAST RX_TPA_START_CMPL_FLAGS_ITYPE_TCP
#define RX_TPA_START_CMPL_FLAGS_MASK UINT32_C(0xffc0)
#define RX_TPA_START_CMPL_FLAGS_SFT 6
uint16_t len;
/*
* This value indicates the amount of packet data written to the buffer
* the opaque field in this completion corresponds to.
*/
uint32_t opaque;
/*
* This is a copy of the opaque field from the RX BD this completion
* corresponds to.
*/
uint8_t v1;
/* unused1 is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_TPA_START_CMPL_V1 UINT32_C(0x1)
/* unused1 is 7 b */
uint8_t rss_hash_type;
/*
* This is the RSS hash type for the packet. The value is packed
* {tuple_extrac_op[1:0],rss_profile_id[4:0],tuple_extrac_op[2]}. The
* value of tuple_extrac_op provides the information about what fields
* the hash was computed on. * 0: The RSS hash was computed over source
* IP address, destination IP address, source port, and destination port
* of inner IP and TCP or UDP headers. Note: For non-tunneled packets,
* the packet headers are considered inner packet headers for the RSS
* hash computation purpose. * 1: The RSS hash was computed over source
* IP address and destination IP address of inner IP header. Note: For
* non-tunneled packets, the packet headers are considered inner packet
* headers for the RSS hash computation purpose. * 2: The RSS hash was
* computed over source IP address, destination IP address, source port,
* and destination port of IP and TCP or UDP headers of outer tunnel
* headers. Note: For non-tunneled packets, this value is not
* applicable. * 3: The RSS hash was computed over source IP address and
* destination IP address of IP header of outer tunnel headers. Note:
* For non-tunneled packets, this value is not applicable. Note that
* 4-tuples values listed above are applicable for layer 4 protocols
* supported and enabled for RSS in the hardware, HWRM firmware, and
* drivers. For example, if RSS hash is supported and enabled for TCP
* traffic only, then the values of tuple_extract_op corresponding to
* 4-tuples are only valid for TCP traffic.
*/
uint16_t agg_id;
/*
* This is the aggregation ID that the completion is associated with.
* Use this number to correlate the TPA start completion with the TPA
* end completion.
*/
/* unused2 is 9 b */
/*
* This is the aggregation ID that the completion is associated with.
* Use this number to correlate the TPA start completion with the TPA
* end completion.
*/
#define RX_TPA_START_CMPL_AGG_ID_MASK UINT32_C(0xfe00)
#define RX_TPA_START_CMPL_AGG_ID_SFT 9
uint32_t rss_hash;
/*
* This value is the RSS hash value calculated for the packet based on
* the mode bits and key value in the VNIC.
*/
} __attribute__((packed));
/* last 16 bytes of RX L2 TPA Start Completion Record */
struct rx_tpa_start_cmpl_hi {
uint32_t flags2;
/*
* This indicates that the ip checksum was calculated for the inner
* packet and that the sum passed for all segments included in the
* aggregation.
*/
#define RX_TPA_START_CMPL_FLAGS2_IP_CS_CALC UINT32_C(0x1)
/*
* This indicates that the TCP, UDP or ICMP checksum was calculated for
* the inner packet and that the sum passed for all segments included in
* the aggregation.
*/
#define RX_TPA_START_CMPL_FLAGS2_L4_CS_CALC UINT32_C(0x2)
/*
* This indicates that the ip checksum was calculated for the tunnel
* header and that the sum passed for all segments included in the
* aggregation.
*/
#define RX_TPA_START_CMPL_FLAGS2_T_IP_CS_CALC UINT32_C(0x4)
/*
* This indicates that the UDP checksum was calculated for the tunnel
* packet and that the sum passed for all segments included in the
* aggregation.
*/
#define RX_TPA_START_CMPL_FLAGS2_T_L4_CS_CALC UINT32_C(0x8)
/* This value indicates what format the metadata field is. */
#define RX_TPA_START_CMPL_FLAGS2_META_FORMAT_MASK UINT32_C(0xf0)
#define RX_TPA_START_CMPL_FLAGS2_META_FORMAT_SFT 4
/* No metadata informtaion. Value is zero. */
#define RX_TPA_START_CMPL_FLAGS2_META_FORMAT_NONE (UINT32_C(0x0) << 4)
/*
* The metadata field contains the VLAN tag and TPID value. -
* metadata[11:0] contains the vlan VID value. - metadata[12]
* contains the vlan DE value. - metadata[15:13] contains the
* vlan PRI value. - metadata[31:16] contains the vlan TPID
* value.
*/
#define RX_TPA_START_CMPL_FLAGS2_META_FORMAT_VLAN (UINT32_C(0x1) << 4)
#define RX_TPA_START_CMPL_FLAGS2_META_FORMAT_LAST RX_TPA_START_CMPL_FLAGS2_META_FORMAT_VLAN
/*
* This field indicates the IP type for the inner-most IP header. A
* value of '0' indicates IPv4. A value of '1' indicates IPv6.
*/
#define RX_TPA_START_CMPL_FLAGS2_IP_TYPE UINT32_C(0x100)
uint32_t metadata;
/*
* This is data from the CFA block as indicated by the meta_format
* field.
*/
/* When meta_format=1, this value is the VLAN VID. */
#define RX_TPA_START_CMPL_METADATA_VID_MASK UINT32_C(0xfff)
#define RX_TPA_START_CMPL_METADATA_VID_SFT 0
/* When meta_format=1, this value is the VLAN DE. */
#define RX_TPA_START_CMPL_METADATA_DE UINT32_C(0x1000)
/* When meta_format=1, this value is the VLAN PRI. */
#define RX_TPA_START_CMPL_METADATA_PRI_MASK UINT32_C(0xe000)
#define RX_TPA_START_CMPL_METADATA_PRI_SFT 13
/* When meta_format=1, this value is the VLAN TPID. */
#define RX_TPA_START_CMPL_METADATA_TPID_MASK UINT32_C(0xffff0000)
#define RX_TPA_START_CMPL_METADATA_TPID_SFT 16
uint16_t v2;
/* unused4 is 15 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_TPA_START_CMPL_V2 UINT32_C(0x1)
/* unused4 is 15 b */
uint16_t cfa_code;
/*
* This field identifies the CFA action rule that was used for this
* packet.
*/
uint32_t inner_l4_size_inner_l3_offset_inner_l2_offset_outer_l3_offset;
/*
* This is the size in bytes of the inner most L4 header. This can be
* subtracted from the payload_offset to determine the start of the
* inner most L4 header.
*/
/*
* This is the offset from the beginning of the packet in bytes for the
* outer L3 header. If there is no outer L3 header, then this value is
* zero.
*/
#define RX_TPA_START_CMPL_OUTER_L3_OFFSET_MASK UINT32_C(0x1ff)
#define RX_TPA_START_CMPL_OUTER_L3_OFFSET_SFT 0
/*
* This is the offset from the beginning of the packet in bytes for the
* inner most L2 header.
*/
#define RX_TPA_START_CMPL_INNER_L2_OFFSET_MASK UINT32_C(0x3fe00)
#define RX_TPA_START_CMPL_INNER_L2_OFFSET_SFT 9
/*
* This is the offset from the beginning of the packet in bytes for the
* inner most L3 header.
*/
#define RX_TPA_START_CMPL_INNER_L3_OFFSET_MASK UINT32_C(0x7fc0000)
#define RX_TPA_START_CMPL_INNER_L3_OFFSET_SFT 18
/*
* This is the size in bytes of the inner most L4 header. This can be
* subtracted from the payload_offset to determine the start of the
* inner most L4 header.
*/
#define RX_TPA_START_CMPL_INNER_L4_SIZE_MASK UINT32_C(0xf8000000)
#define RX_TPA_START_CMPL_INNER_L4_SIZE_SFT 27
} __attribute__((packed));
/* RX TPA End Completion Record (32 bytes split to 2 16-byte struct) */
struct rx_tpa_end_cmpl {
uint16_t flags_type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define RX_TPA_END_CMPL_TYPE_MASK UINT32_C(0x3f)
#define RX_TPA_END_CMPL_TYPE_SFT 0
/*
* RX L2 TPA End Completion: Completion at the end of a TPA
* operation. Length = 32B
*/
#define RX_TPA_END_CMPL_TYPE_RX_TPA_END UINT32_C(0x15)
/*
* When this bit is '1', it indicates a packet that has an error of some
* type. Type of error is indicated in error_flags.
*/
#define RX_TPA_END_CMPL_FLAGS_ERROR UINT32_C(0x40)
/* This field indicates how the packet was placed in the buffer. */
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_MASK UINT32_C(0x380)
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_SFT 7
/*
* Jumbo: TPA Packet was placed using jumbo algorithm. This
* means that the first buffer will be filled with data before
* moving to aggregation buffers. Each aggregation buffer will
* be filled before moving to the next aggregation buffer.
*/
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_JUMBO (UINT32_C(0x1) << 7)
/*
* Header/Data Separation: Packet was placed using Header/Data
* separation algorithm. The separation location is indicated by
* the itype field.
*/
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_HDS (UINT32_C(0x2) << 7)
/*
* GRO/Jumbo: Packet will be placed using GRO/Jumbo where the
* first packet is filled with data. Subsequent packets will be
* placed such that any one packet does not span two aggregation
* buffers unless it starts at the beginning of an aggregation
* buffer.
*/
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_GRO_JUMBO (UINT32_C(0x5) << 7)
/*
* GRO/Header-Data Separation: Packet will be placed using
* GRO/HDS where the header is in the first packet. Payload of
* each packet will be placed such that any one packet does not
* span two aggregation buffers unless it starts at the
* beginning of an aggregation buffer.
*/
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_GRO_HDS (UINT32_C(0x6) << 7)
#define RX_TPA_END_CMPL_FLAGS_PLACEMENT_LAST RX_TPA_END_CMPL_FLAGS_PLACEMENT_GRO_HDS
/* unused is 2 b */
#define RX_TPA_END_CMPL_FLAGS_UNUSED_MASK UINT32_C(0xc00)
#define RX_TPA_END_CMPL_FLAGS_UNUSED_SFT 10
/*
* This value indicates what the inner packet determined for the packet
* was. - 2 TCP Packet Indicates that the packet was IP and TCP. This
* indicates that the ip_cs field is valid and that the tcp_udp_cs field
* is valid and contains the TCP checksum. This also indicates that the
* payload_offset field is valid.
*/
#define RX_TPA_END_CMPL_FLAGS_ITYPE_MASK UINT32_C(0xf000)
#define RX_TPA_END_CMPL_FLAGS_ITYPE_SFT 12
#define RX_TPA_END_CMPL_FLAGS_MASK UINT32_C(0xffc0)
#define RX_TPA_END_CMPL_FLAGS_SFT 6
uint16_t len;
/*
* This value is zero for TPA End completions. There is no data in the
* buffer that corresponds to the opaque value in this completion.
*/
uint32_t opaque;
/*
* This is a copy of the opaque field from the RX BD this completion
* corresponds to.
*/
uint8_t agg_bufs_v1;
/* unused1 is 1 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_TPA_END_CMPL_V1 UINT32_C(0x1)
/*
* This value is the number of aggregation buffers that follow this
* entry in the completion ring that are a part of this aggregation
* packet. If the value is zero, then the packet is completely contained
* in the buffer space provided in the aggregation start completion.
*/
#define RX_TPA_END_CMPL_AGG_BUFS_MASK UINT32_C(0x7e)
#define RX_TPA_END_CMPL_AGG_BUFS_SFT 1
/* unused1 is 1 b */
uint8_t tpa_segs;
/* This value is the number of segments in the TPA operation. */
uint8_t payload_offset;
/*
* This value indicates the offset in bytes from the beginning of the
* packet where the inner payload starts. This value is valid for TCP,
* UDP, FCoE, and RoCE packets. A value of zero indicates an offset of
* 256 bytes.
*/
uint8_t agg_id;
/*
* This is the aggregation ID that the completion is associated with.
* Use this number to correlate the TPA start completion with the TPA
* end completion.
*/
/* unused2 is 1 b */
/*
* This is the aggregation ID that the completion is associated with.
* Use this number to correlate the TPA start completion with the TPA
* end completion.
*/
#define RX_TPA_END_CMPL_AGG_ID_MASK UINT32_C(0xfe)
#define RX_TPA_END_CMPL_AGG_ID_SFT 1
uint32_t tsdelta;
/*
* For non-GRO packets, this value is the timestamp delta between
* earliest and latest timestamp values for TPA packet. If packets were
* not time stamped, then delta will be zero. For GRO packets, this
* field is zero except for the following sub-fields. - tsdelta[31]
* Timestamp present indication. When '0', no Timestamp option is in the
* packet. When '1', then a Timestamp option is present in the packet.
*/
} __attribute__((packed));
/* last 16 bytes of RX TPA End Completion Record */
struct rx_tpa_end_cmpl_hi {
uint32_t tpa_dup_acks;
/* unused3 is 28 b */
/*
* This value is the number of duplicate ACKs that have been received as
* part of the TPA operation.
*/
#define RX_TPA_END_CMPL_TPA_DUP_ACKS_MASK UINT32_C(0xf)
#define RX_TPA_END_CMPL_TPA_DUP_ACKS_SFT 0
/* unused3 is 28 b */
uint16_t tpa_seg_len;
/*
* This value is the valid when TPA completion is active. It indicates
* the length of the longest segment of the TPA operation for LRO mode
* and the length of the first segment in GRO mode. This value may be
* used by GRO software to re-construct the original packet stream from
* the TPA packet. This is the length of all but the last segment for
* GRO. In LRO mode this value may be used to indicate MSS size to the
* stack.
*/
uint16_t unused_3;
/* unused4 is 16 b */
uint16_t errors_v2;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_TPA_END_CMPL_V2 UINT32_C(0x1)
/*
* This error indicates that there was some sort of problem with the BDs
* for the packet that was found after part of the packet was already
* placed. The packet should be treated as invalid.
*/
#define RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_MASK UINT32_C(0xe)
#define RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_SFT 1
/*
* This error occurs when there is a fatal HW problem in the
* chip only. It indicates that there were not BDs on chip but
* that there was adequate reservation. provided by the TPA
* block.
*/
#define RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_NOT_ON_CHIP (UINT32_C(0x2) << 1)
/*
* This error occurs when TPA block was not configured to
* reserve adequate BDs for TPA operations on this RX ring. All
* data for the TPA operation was not placed. This error can
* also be generated when the number of segments is not
* programmed correctly in TPA and the 33 total aggregation
* buffers allowed for the TPA operation has been exceeded.
*/
#define RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_RSV_ERROR (UINT32_C(0x4) << 1)
#define RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_LAST RX_TPA_END_CMPL_ERRORS_BUFFER_ERROR_RSV_ERROR
#define RX_TPA_END_CMPL_ERRORS_MASK UINT32_C(0xfffe)
#define RX_TPA_END_CMPL_ERRORS_SFT 1
uint16_t unused_4;
/* unused5 is 16 b */
uint32_t start_opaque;
/*
* This is the opaque value that was completed for the TPA start
* completion that corresponds to this TPA end completion.
*/
} __attribute__((packed));
/* RX Aggregation Buffer Completion Record (16 bytes) */
struct rx_abuf_cmpl {
uint16_t type;
/* unused is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define RX_ABUF_CMPL_TYPE_MASK UINT32_C(0x3f)
#define RX_ABUF_CMPL_TYPE_SFT 0
/*
* RX Aggregation Buffer completion : Completion of an L2
* aggregation buffer in support of TPA, HDS, or Jumbo packet
* completion. Length = 16B
*/
#define RX_ABUF_CMPL_TYPE_RX_AGG UINT32_C(0x12)
/* unused is 10 b */
uint16_t len;
/*
* This is the length of the data for the packet stored in this
* aggregation buffer identified by the opaque value. This does not
* include the length of any data placed in other aggregation BDs or in
* the packet or buffer BDs. This length does not include any space
* added due to hdr_offset register during HDS placement mode.
*/
uint32_t opaque;
/*
* This is a copy of the opaque field from the RX BD this aggregation
* buffer corresponds to.
*/
uint32_t v;
/* unused2 is 31 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define RX_ABUF_CMPL_V UINT32_C(0x1)
/* unused2 is 31 b */
uint32_t unused_2;
/* unused3 is 32 b */
} __attribute__((packed));
/* Statistics Ejection Buffer Completion Record (16 bytes) */
struct eject_cmpl {
uint16_t type;
/* unused is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define EJECT_CMPL_TYPE_MASK UINT32_C(0x3f)
#define EJECT_CMPL_TYPE_SFT 0
/*
* Statistics Ejection Completion: Completion of statistics data
* ejection buffer. Length = 16B
*/
#define EJECT_CMPL_TYPE_STAT_EJECT UINT32_C(0x1a)
/* unused is 10 b */
uint16_t len;
/* This is the length of the statistics data stored in this buffer. */
uint32_t opaque;
/*
* This is a copy of the opaque field from the RX BD this ejection
* buffer corresponds to.
*/
uint32_t v;
/* unused2 is 31 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define EJECT_CMPL_V UINT32_C(0x1)
/* unused2 is 31 b */
uint32_t unused_2;
/* unused3 is 32 b */
} __attribute__((packed));
/* HWRM Completion Record (16 bytes) */
struct hwrm_cmpl {
uint16_t type;
/* unused is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_CMPL_TYPE_MASK UINT32_C(0x3f)
#define HWRM_CMPL_TYPE_SFT 0
/* HWRM Command Completion: Completion of an HWRM command. */
#define HWRM_CMPL_TYPE_HWRM_DONE UINT32_C(0x20)
/* unused is 10 b */
uint16_t sequence_id;
/* This is the sequence_id of the HWRM command that has completed. */
uint32_t unused_1;
/* unused2 is 32 b */
uint32_t v;
/* unused3 is 31 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_CMPL_V UINT32_C(0x1)
/* unused3 is 31 b */
uint32_t unused_3;
/* unused4 is 32 b */
} __attribute__((packed));
/* HWRM Forwarded Request (16 bytes) */
struct hwrm_fwd_req_cmpl {
uint16_t req_len_type;
/* Length of forwarded request in bytes. */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_FWD_REQ_CMPL_TYPE_MASK UINT32_C(0x3f)
#define HWRM_FWD_REQ_CMPL_TYPE_SFT 0
/* Forwarded HWRM Request */
#define HWRM_FWD_REQ_CMPL_TYPE_HWRM_FWD_REQ UINT32_C(0x22)
/* Length of forwarded request in bytes. */
#define HWRM_FWD_REQ_CMPL_REQ_LEN_MASK UINT32_C(0xffc0)
#define HWRM_FWD_REQ_CMPL_REQ_LEN_SFT 6
uint16_t source_id;
/*
* Source ID of this request. Typically used in forwarding requests and
* responses. 0x0 - 0xFFF8 - Used for function ids 0xFFF8 - 0xFFFE -
* Reserved for internal processors 0xFFFF - HWRM
*/
uint32_t unused_0;
/* unused1 is 32 b */
uint64_t req_buf_addr_v;
/* Address of forwarded request. */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_FWD_REQ_CMPL_V UINT32_C(0x1)
/* Address of forwarded request. */
#define HWRM_FWD_REQ_CMPL_REQ_BUF_ADDR_MASK UINT32_C(0xfffffffe)
#define HWRM_FWD_REQ_CMPL_REQ_BUF_ADDR_SFT 1
} __attribute__((packed));
/* HWRM Forwarded Response (16 bytes) */
struct hwrm_fwd_resp_cmpl {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_FWD_RESP_CMPL_TYPE_MASK UINT32_C(0x3f)
#define HWRM_FWD_RESP_CMPL_TYPE_SFT 0
/* Forwarded HWRM Response */
#define HWRM_FWD_RESP_CMPL_TYPE_HWRM_FWD_RESP UINT32_C(0x24)
/* unused1 is 10 b */
uint16_t source_id;
/*
* Source ID of this response. Typically used in forwarding requests and
* responses. 0x0 - 0xFFF8 - Used for function ids 0xFFF8 - 0xFFFE -
* Reserved for internal processors 0xFFFF - HWRM
*/
uint16_t resp_len;
/* Length of forwarded response in bytes. */
uint16_t unused_1;
/* unused2 is 16 b */
uint64_t resp_buf_addr_v;
/* Address of forwarded response. */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_FWD_RESP_CMPL_V UINT32_C(0x1)
/* Address of forwarded response. */
#define HWRM_FWD_RESP_CMPL_RESP_BUF_ADDR_MASK UINT32_C(0xfffffffe)
#define HWRM_FWD_RESP_CMPL_RESP_BUF_ADDR_SFT 1
} __attribute__((packed));
#define GET_EVENT_ID(x) \
((x) == 0x30 ? "VF_FLR": \
((x) == 0x20 ? "PF_DRVR_UNLOAD": \
((x) == 0x10 ? "FUNC_DRVR_UNLOAD": \
((x) == 0xff ? "HWRM_ERROR": \
((x) == 0x32 ? "PF_VF_COMM_STATUS_CHANGE": \
((x) == 0x33 ? "VF_CFG_CHANGE": \
((x) == 0x11 ? "FUNC_DRVR_LOAD": \
((x) == 0x31 ? "VF_MAC_ADDR_CHANGE": \
((x) == 0x34 ? "LLFC_PFC_CHANGE": \
((x) == 0x4 ? "PORT_CONN_NOT_ALLOWED": \
((x) == 0x5 ? "LINK_SPEED_CFG_NOT_ALLOWED": \
((x) == 0x6 ? "LINK_SPEED_CFG_CHANGE": \
((x) == 0x7 ? "PORT_PHY_CFG_CHANGE": \
((x) == 0x0 ? "LINK_STATUS_CHANGE": \
((x) == 0x1 ? "LINK_MTU_CHANGE": \
((x) == 0x2 ? "LINK_SPEED_CHANGE": \
((x) == 0x3 ? "DCB_CONFIG_CHANGE": \
((x) == 0x12 ? "FUNC_FLR_PROC_CMPLT": \
((x) == 0x21 ? "PF_DRVR_LOAD": \
"Unknown event_id")))))))))))))))))))
/* HWRM Asynchronous Event Completion Record (16 bytes) */
struct hwrm_async_event_cmpl {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link status changed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LINK_STATUS_CHANGE UINT32_C(0x0)
/* Link MTU changed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LINK_MTU_CHANGE UINT32_C(0x1)
/* Link speed changed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LINK_SPEED_CHANGE UINT32_C(0x2)
/* DCB Configuration changed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_DCB_CONFIG_CHANGE UINT32_C(0x3)
/* Port connection not allowed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_PORT_CONN_NOT_ALLOWED UINT32_C(0x4)
/* Link speed configuration was not allowed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LINK_SPEED_CFG_NOT_ALLOWED UINT32_C(0x5)
/* Link speed configuration change */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LINK_SPEED_CFG_CHANGE UINT32_C(0x6)
/* Port PHY configuration change */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_PORT_PHY_CFG_CHANGE UINT32_C(0x7)
/* Function driver unloaded */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_FUNC_DRVR_UNLOAD UINT32_C(0x10)
/* Function driver loaded */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_FUNC_DRVR_LOAD UINT32_C(0x11)
/* Function FLR related processing has completed */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_FUNC_FLR_PROC_CMPLT UINT32_C(0x12)
/* PF driver unloaded */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_PF_DRVR_UNLOAD UINT32_C(0x20)
/* PF driver loaded */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_PF_DRVR_LOAD UINT32_C(0x21)
/* VF Function Level Reset (FLR) */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_VF_FLR UINT32_C(0x30)
/* VF MAC Address Change */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_VF_MAC_ADDR_CHANGE UINT32_C(0x31)
/* PF-VF communication channel status change. */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_PF_VF_COMM_STATUS_CHANGE UINT32_C(0x32)
/* VF Configuration Change */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_VF_CFG_CHANGE UINT32_C(0x33)
/* LLFC/PFC Configuration Change */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_LLFC_PFC_CHANGE UINT32_C(0x34)
/* HWRM Error */
#define HWRM_ASYNC_EVENT_CMPL_EVENT_ID_HWRM_ERROR UINT32_C(0xff)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for link status change (16 bytes) */
struct hwrm_async_event_cmpl_link_status_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link status changed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_ID_LINK_STATUS_CHANGE UINT32_C(0x0)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Indicates link status change */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_LINK_CHANGE UINT32_C(0x1)
/*
* If this bit set to 0, then it indicates that the link was up
* and it went down.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_LINK_CHANGE_DOWN (UINT32_C(0x0) << 0)
/*
* If this bit is set to 1, then it indicates that the link was
* down and it went up.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_LINK_CHANGE_UP (UINT32_C(0x1) << 0)
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_LINK_CHANGE_LAST HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_LINK_CHANGE_UP
/* Indicates the physical port this link status change occur */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_PORT_MASK UINT32_C(0xe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_PORT_SFT 1
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff0)
#define HWRM_ASYNC_EVENT_CMPL_LINK_STATUS_CHANGE_EVENT_DATA1_PORT_ID_SFT 4
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for link MTU change (16 bytes) */
struct hwrm_async_event_cmpl_link_mtu_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link MTU changed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_EVENT_ID_LINK_MTU_CHANGE UINT32_C(0x1)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* The new MTU of the link in bytes. */
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_EVENT_DATA1_NEW_MTU_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_LINK_MTU_CHANGE_EVENT_DATA1_NEW_MTU_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for link speed change (16 bytes) */
struct hwrm_async_event_cmpl_link_speed_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link speed changed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_ID_LINK_SPEED_CHANGE UINT32_C(0x2)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/*
* When this bit is '1', the link was forced to the force_link_speed
* value.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_FORCE UINT32_C(0x1)
/* The new link speed in 100 Mbps units. */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_MASK UINT32_C(0xfffe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_SFT 1
/* 100Mb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_100MB (UINT32_C(0x1) << 1)
/* 1Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_1GB (UINT32_C(0xa) << 1)
/* 2Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_2GB (UINT32_C(0x14) << 1)
/* 2.5Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_2_5GB (UINT32_C(0x19) << 1)
/* 10Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_10GB (UINT32_C(0x64) << 1)
/* 20Mb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_20GB (UINT32_C(0xc8) << 1)
/* 25Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_25GB (UINT32_C(0xfa) << 1)
/* 40Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_40GB (UINT32_C(0x190) << 1)
/* 50Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_50GB (UINT32_C(0x1f4) << 1)
/* 100Gb link speed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_100GB (UINT32_C(0x3e8) << 1)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_LAST HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_NEW_LINK_SPEED_100MBPS_100GB
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff0000)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CHANGE_EVENT_DATA1_PORT_ID_SFT 16
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for DCB Config change (16 bytes) */
struct hwrm_async_event_cmpl_dcb_config_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* DCB Configuration changed */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_ID_DCB_CONFIG_CHANGE UINT32_C(0x3)
uint32_t event_data2;
/* Event specific data */
/* ETS configuration change */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA2_ETS UINT32_C(0x1)
/* PFC configuration change */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA2_PFC UINT32_C(0x2)
/* APP configuration change */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA2_APP UINT32_C(0x4)
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_PORT_ID_SFT 0
/* Priority recommended for RoCE traffic */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_ROCE_PRIORITY_MASK UINT32_C(0xff0000)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_ROCE_PRIORITY_SFT 16
/* none is 255 */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_ROCE_PRIORITY_NONE (UINT32_C(0xff) << 16)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_ROCE_PRIORITY_LAST HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_ROCE_PRIORITY_NONE
/* Priority recommended for L2 traffic */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_L2_PRIORITY_MASK UINT32_C(0xff000000)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_L2_PRIORITY_SFT 24
/* none is 255 */
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_L2_PRIORITY_NONE (UINT32_C(0xff) << 24)
#define HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_L2_PRIORITY_LAST HWRM_ASYNC_EVENT_CMPL_DCB_CONFIG_CHANGE_EVENT_DATA1_RECOMMEND_L2_PRIORITY_NONE
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for port connection not allowed (16 bytes) */
struct hwrm_async_event_cmpl_port_conn_not_allowed {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Port connection not allowed */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_ID_PORT_CONN_NOT_ALLOWED UINT32_C(0x4)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_PORT_ID_SFT 0
/*
* This value indicates the current port level enforcement policy for
* the optics module when there is an optical module mismatch and port
* is not connected.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_MASK UINT32_C(0xff0000)
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_SFT 16
/* No enforcement */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_NONE (UINT32_C(0x0) << 16)
/* Disable Transmit side Laser. */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_DISABLETX (UINT32_C(0x1) << 16)
/* Raise a warning message. */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_WARNINGMSG (UINT32_C(0x2) << 16)
/* Power down the module. */
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_PWRDOWN (UINT32_C(0x3) << 16)
#define HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_LAST HWRM_ASYNC_EVENT_CMPL_PORT_CONN_NOT_ALLOWED_EVENT_DATA1_ENFORCEMENT_POLICY_PWRDOWN
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for link speed config not allowed (16 bytes) */
struct hwrm_async_event_cmpl_link_speed_cfg_not_allowed {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link speed configuration was not allowed */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_EVENT_ID_LINK_SPEED_CFG_NOT_ALLOWED UINT32_C(0x5)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_NOT_ALLOWED_EVENT_DATA1_PORT_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for link speed configuration change (16 bytes) */
struct hwrm_async_event_cmpl_link_speed_cfg_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Link speed configuration change */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_EVENT_ID_LINK_SPEED_CFG_CHANGE UINT32_C(0x6)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_EVENT_DATA1_PORT_ID_SFT 0
/*
* If set to 1, it indicates that the supported link speeds
* configuration on the port has changed. If set to 0, then there is no
* change in supported link speeds configuration.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_EVENT_DATA1_SUPPORTED_LINK_SPEEDS_CHANGE UINT32_C(0x10000)
/*
* If set to 1, it indicates that the link speed configuration on the
* port has become illegal or invalid. If set to 0, then the link speed
* configuration on the port is legal or valid.
*/
#define HWRM_ASYNC_EVENT_CMPL_LINK_SPEED_CFG_CHANGE_EVENT_DATA1_ILLEGAL_LINK_SPEED_CFG UINT32_C(0x20000)
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for port PHY configuration change (16 bytes) */
struct hwrm_async_event_cmpl_port_phy_cfg_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Port PHY configuration change */
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_ID_PORT_PHY_CFG_CHANGE UINT32_C(0x7)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_DATA1_PORT_ID_SFT 0
/*
* If set to 1, it indicates that the FEC configuration on the port has
* changed. If set to 0, then there is no change in FEC configuration.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_DATA1_FEC_CFG_CHANGE UINT32_C(0x10000)
/*
* If set to 1, it indicates that the EEE configuration on the port has
* changed. If set to 0, then there is no change in EEE configuration on
* the port.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_DATA1_EEE_CFG_CHANGE UINT32_C(0x20000)
/*
* If set to 1, it indicates that the pause configuration on the PHY has
* changed. If set to 0, then there is no change in the pause
* configuration on the PHY.
*/
#define HWRM_ASYNC_EVENT_CMPL_PORT_PHY_CFG_CHANGE_EVENT_DATA1_PAUSE_CFG_CHANGE UINT32_C(0x40000)
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for Function Driver Unload (16 bytes) */
struct hwrm_async_event_cmpl_func_drvr_unload {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Function driver unloaded */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_EVENT_ID_FUNC_DRVR_UNLOAD UINT32_C(0x10)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Function ID */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_EVENT_DATA1_FUNC_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_UNLOAD_EVENT_DATA1_FUNC_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for Function Driver load (16 bytes) */
struct hwrm_async_event_cmpl_func_drvr_load {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Function driver loaded */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_EVENT_ID_FUNC_DRVR_LOAD UINT32_C(0x11)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Function ID */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_EVENT_DATA1_FUNC_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_DRVR_LOAD_EVENT_DATA1_FUNC_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record to indicate completion of FLR related processing (16 bytes) */
struct hwrm_async_event_cmpl_func_flr_proc_cmplt {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* Function FLR related processing has completed */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_EVENT_ID_FUNC_FLR_PROC_CMPLT UINT32_C(0x12)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Function ID */
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_EVENT_DATA1_FUNC_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_FUNC_FLR_PROC_CMPLT_EVENT_DATA1_FUNC_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for PF Driver Unload (16 bytes) */
struct hwrm_async_event_cmpl_pf_drvr_unload {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* PF driver unloaded */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_EVENT_ID_PF_DRVR_UNLOAD UINT32_C(0x20)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PF ID */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_EVENT_DATA1_FUNC_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_EVENT_DATA1_FUNC_ID_SFT 0
/* Indicates the physical port this pf belongs to */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_EVENT_DATA1_PORT_MASK UINT32_C(0x70000)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_UNLOAD_EVENT_DATA1_PORT_SFT 16
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for PF Driver load (16 bytes) */
struct hwrm_async_event_cmpl_pf_drvr_load {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* PF driver loaded */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_EVENT_ID_PF_DRVR_LOAD UINT32_C(0x21)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* PF ID */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_EVENT_DATA1_FUNC_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_EVENT_DATA1_FUNC_ID_SFT 0
/* Indicates the physical port this pf belongs to */
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_EVENT_DATA1_PORT_MASK UINT32_C(0x70000)
#define HWRM_ASYNC_EVENT_CMPL_PF_DRVR_LOAD_EVENT_DATA1_PORT_SFT 16
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for VF FLR (16 bytes) */
struct hwrm_async_event_cmpl_vf_flr {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* VF Function Level Reset (FLR) */
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_EVENT_ID_VF_FLR UINT32_C(0x30)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* VF ID */
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_EVENT_DATA1_VF_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_VF_FLR_EVENT_DATA1_VF_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for VF MAC Addr change (16 bytes) */
struct hwrm_async_event_cmpl_vf_mac_addr_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* VF MAC Address Change */
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_EVENT_ID_VF_MAC_ADDR_CHANGE UINT32_C(0x31)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* VF ID */
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_EVENT_DATA1_VF_ID_MASK UINT32_C(0xffff)
#define HWRM_ASYNC_EVENT_CMPL_VF_MAC_ADDR_CHANGE_EVENT_DATA1_VF_ID_SFT 0
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for PF-VF communication status change (16 bytes) */
struct hwrm_async_event_cmpl_pf_vf_comm_status_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* PF-VF communication channel status change. */
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_EVENT_ID_PF_VF_COMM_STATUS_CHANGE UINT32_C(0x32)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/*
* If this bit is set to 1, then it indicates that the PF-VF
* communication was lost and it is established. If this bit set to 0,
* then it indicates that the PF-VF communication was established and it
* is lost.
*/
#define HWRM_ASYNC_EVENT_CMPL_PF_VF_COMM_STATUS_CHANGE_EVENT_DATA1_COMM_ESTABLISHED UINT32_C(0x1)
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for VF configuration change (16 bytes) */
struct hwrm_async_event_cmpl_vf_cfg_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* VF Configuration Change */
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_EVENT_ID_VF_CFG_CHANGE UINT32_C(0x33)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/*
* Each flag provided in this field indicates a specific VF
* configuration change. At least one of these flags shall be set to 1
* when an asynchronous event completion of this type is provided by the
* HWRM.
*/
/*
* If this bit is set to 1, then the value of MTU was changed on this
* VF. If set to 0, then this bit should be ignored.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_EVENT_DATA1_MTU_CHANGE UINT32_C(0x1)
/*
* If this bit is set to 1, then the value of MRU was changed on this
* VF. If set to 0, then this bit should be ignored.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_EVENT_DATA1_MRU_CHANGE UINT32_C(0x2)
/*
* If this bit is set to 1, then the value of default MAC address was
* changed on this VF. If set to 0, then this bit should be ignored.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_EVENT_DATA1_DFLT_MAC_ADDR_CHANGE UINT32_C(0x4)
/*
* If this bit is set to 1, then the value of default VLAN was changed
* on this VF. If set to 0, then this bit should be ignored.
*/
#define HWRM_ASYNC_EVENT_CMPL_VF_CFG_CHANGE_EVENT_DATA1_DFLT_VLAN_CHANGE UINT32_C(0x8)
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for llfc pfc status change (16 bytes) */
struct hwrm_async_event_cmpl_llfc_pfc_change {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* LLFC/PFC Configuration Change */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_ID_LLFC_PFC_CHANGE UINT32_C(0x34)
uint32_t event_data2;
/* Event specific data */
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Indicates llfc pfc status change */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_MASK UINT32_C(0x3)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_SFT 0
/* If this field set to 1, then it indicates that llfc is enabled. */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_LLFC (UINT32_C(0x1) << 0)
/* If this field is set to 2, then it indicates that pfc is enabled. */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_PFC (UINT32_C(0x2) << 0)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_LAST HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_LLFC_PFC_PFC
/* Indicates the physical port this llfc pfc change occur */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_PORT_MASK UINT32_C(0x1c)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_PORT_SFT 2
/* PORT ID */
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_PORT_ID_MASK UINT32_C(0x1fffe0)
#define HWRM_ASYNC_EVENT_CMPL_LLFC_PFC_CHANGE_EVENT_DATA1_PORT_ID_SFT 5
} __attribute__((packed));
/* HWRM Asynchronous Event Completion Record for HWRM Error (16 bytes) */
struct hwrm_async_event_cmpl_hwrm_error {
uint16_t type;
/* unused1 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_TYPE_MASK UINT32_C(0x3f)
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_TYPE_SFT 0
/* HWRM Asynchronous Event Information */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_TYPE_HWRM_ASYNC_EVENT UINT32_C(0x2e)
/* unused1 is 10 b */
uint16_t event_id;
/* Identifiers of events. */
/* HWRM Error */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_ID_HWRM_ERROR UINT32_C(0xff)
uint32_t event_data2;
/* Event specific data */
/* Severity of HWRM Error */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_MASK UINT32_C(0xff)
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_SFT 0
/* Warning */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_WARNING UINT32_C(0x0)
/* Non-fatal Error */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_NONFATAL UINT32_C(0x1)
/* Fatal Error */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_FATAL UINT32_C(0x2)
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_LAST HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA2_SEVERITY_FATAL
uint8_t opaque_v;
/* opaque is 7 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_V UINT32_C(0x1)
/* opaque is 7 b */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_OPAQUE_MASK UINT32_C(0xfe)
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_OPAQUE_SFT 1
uint8_t timestamp_lo;
/* 8-lsb timestamp from POR (100-msec resolution) */
uint16_t timestamp_hi;
/* 16-lsb timestamp from POR (100-msec resolution) */
uint32_t event_data1;
/* Event specific data */
/* Time stamp for error event */
#define HWRM_ASYNC_EVENT_CMPL_HWRM_ERROR_EVENT_DATA1_TIMESTAMP UINT32_C(0x1)
} __attribute__((packed));
/* Door Bell Formats */
/*
* Description: The backup version of the packet must be valid in the TX ring
* before the push doorbell is written to the chip. The first 32b and the BD
* portion of the push doorbell must be written in multiples of 32b units on the
* PCI interface. The data portion of the push doorbell may be written in
* multiples of 8b units on the PCI interface. A push update must contain
* exactly one push packet. The backup version of the packet must start with a
* long (32B) BD and the BDs must be less than or equal to 16x16B units long.
*/
/*
* Note: This door bell format is used by the driver when it wants to push a
* packet into the chip for super-fast transmission. This pushes a partial BD
* and the packet data into the chip. If the chip has room, it will transmit the
* packet. If the chip dosn't have room, it will read the BD and packet data
* from host memory as a normal packet.
*/
/* TX Door Bell Format (4 bytes) */
struct tx_doorbell {
uint32_t key_idx;
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '0' for TX door bell operations.
*/
/*
* BD Index of next BD that will be used to transmit data on the TX ring
* mapped to this door bell. NIC may read and process all BDs up to, but
* not including this index.
*/
#define TX_DOORBELL_IDX_MASK UINT32_C(0xffffff)
#define TX_DOORBELL_IDX_SFT 0
/* reserved is 4 b */
#define TX_DOORBELL_RESERVED_MASK UINT32_C(0xf000000)
#define TX_DOORBELL_RESERVED_SFT 24
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '0' for TX door bell operations.
*/
#define TX_DOORBELL_KEY_MASK UINT32_C(0xf0000000)
#define TX_DOORBELL_KEY_SFT 28
/* TX Operation */
#define TX_DOORBELL_KEY_TX (UINT32_C(0x0) << 28)
} __attribute__((packed));
/* RX Door Bell Format (4 bytes) */
struct rx_doorbell {
uint32_t key_idx;
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '1' for RX door bell operations.
*/
/*
* BD Index of next BD that will be used for an empty receive buffer on
* the RX ring mapped to this door bell. NIC may read and process all
* BDs up to, but not including this index.
*/
#define RX_DOORBELL_IDX_MASK UINT32_C(0xffffff)
#define RX_DOORBELL_IDX_SFT 0
/* reserved is 4 b */
#define RX_DOORBELL_RESERVED_MASK UINT32_C(0xf000000)
#define RX_DOORBELL_RESERVED_SFT 24
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '1' for RX door bell operations.
*/
#define RX_DOORBELL_KEY_MASK UINT32_C(0xf0000000)
#define RX_DOORBELL_KEY_SFT 28
/* RX Operation */
#define RX_DOORBELL_KEY_RX (UINT32_C(0x1) << 28)
} __attribute__((packed));
/* CMP Door Bell Format (4 bytes) */
struct cmpl_doorbell {
uint32_t key_mask_valid_idx;
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '2' for CMP door bell operations.
*/
/*
* BD Index of the most recently handed completion record on the
* completion ring mapped to this door bell. NIC may write this location
* again with a new completion.
*/
#define CMPL_DOORBELL_IDX_MASK UINT32_C(0xffffff)
#define CMPL_DOORBELL_IDX_SFT 0
/* reserved is 2 b */
#define CMPL_DOORBELL_RESERVED_MASK UINT32_C(0x3000000)
#define CMPL_DOORBELL_RESERVED_SFT 24
/*
* This indicates if the BDIDX value is valid for this update when it is
* '1'. When it is '0', the BDIDX value should be ignored.
*/
#define CMPL_DOORBELL_IDX_VALID UINT32_C(0x4000000)
/*
* This bit indicates the new interrupt mask state for the interrupt
* associated with the BDIDX. A '1', means the interrupt is to be
* masked. A '0' indicates the interrupt is to be unmasked.
*/
#define CMPL_DOORBELL_MASK UINT32_C(0x8000000)
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '2' for CMP door bell operations.
*/
#define CMPL_DOORBELL_KEY_MASK UINT32_C(0xf0000000)
#define CMPL_DOORBELL_KEY_SFT 28
/* Completion Operation */
#define CMPL_DOORBELL_KEY_CMPL (UINT32_C(0x2) << 28)
} __attribute__((packed));
/* Status Door Bell Format (4 bytes) */
struct status_doorbell {
uint32_t key_idx;
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '3' for Status door bell operations.
*/
/*
* BD Index of the status record for which space is now available to the
* NIC.
*/
/*
* While there is no actual BD associated with the index, the similar
* scheme is being used to communicate to the NIC that space is
* available for status completions.
*/
#define STATUS_DOORBELL_IDX_MASK UINT32_C(0xffffff)
#define STATUS_DOORBELL_IDX_SFT 0
/* reserved is 4 b */
#define STATUS_DOORBELL_RESERVED_MASK UINT32_C(0xf000000)
#define STATUS_DOORBELL_RESERVED_SFT 24
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is '3' for Status door bell operations.
*/
#define STATUS_DOORBELL_KEY_MASK UINT32_C(0xf0000000)
#define STATUS_DOORBELL_KEY_SFT 28
/* Status Operation */
#define STATUS_DOORBELL_KEY_STAT (UINT32_C(0x3) << 28)
} __attribute__((packed));
/* Push w/32B BD Door Bell Format (32 bytes) */
struct push32_doorbell {
uint32_t key_sz_idx;
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is 4 for push door bell operations.
*/
/*
* This is the BD Index of last BD of the push packet that will be used
* to transmit data on the TX ring mapped to this door bell.
*/
#define PUSH32_DOORBELL_IDX_MASK UINT32_C(0xffffff)
#define PUSH32_DOORBELL_IDX_SFT 0
/*
* This is the number of 16B BDs spaces consumed in the TX Ring by the
* "backup" version of the packet being pushed. A value of 1 is invalid
* since backup must start with a long 32B BE. A value of 2 indicates
* just the first 32B BE. A value of 3 indicates 32B+16B BD. etc. A
* value of 0 indicates 16x16B BD spaces are consumed.
*/
#define PUSH32_DOORBELL_SZ_MASK UINT32_C(0xf000000)
#define PUSH32_DOORBELL_SZ_SFT 24
/*
* This value indicates the type of door bell operation that is begin
* requested. This value is 4 for push door bell operations.
*/
#define PUSH32_DOORBELL_KEY_MASK UINT32_C(0xf0000000)
#define PUSH32_DOORBELL_KEY_SFT 28
/* Push Operation */
#define PUSH32_DOORBELL_KEY_PUSH (UINT32_C(0x4) << 28)
uint16_t flags_type;
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
/* This value identifies the type of buffer descriptor. */
#define PUSH32_DOORBELL_TYPE_MASK UINT32_C(0x3f)
#define PUSH32_DOORBELL_TYPE_SFT 0
/*
* Indicates that this BD is 32B long and is used for normal L2
* packet transmission.
*/
#define PUSH32_DOORBELL_TYPE_TX_BD_LONG UINT32_C(0x10)
/*
* If set to 1, the packet ends with the data in the buffer pointed to
* by this descriptor. This flag must be valid on every BD. This bit
* must be set on all push doorbells.
*/
#define PUSH32_DOORBELL_FLAGS_PACKET_END UINT32_C(0x40)
/*
* If set to 1, the device will not generate a completion for this
* transmit packet unless there is an error in it's processing. If this
* bit is set to 0, then the packet will be completed normally. This bit
* must be valid only on the first BD of a packet.
*/
#define PUSH32_DOORBELL_FLAGS_NO_CMPL UINT32_C(0x80)
/*
* This value must match the sz field in the first 32b of the push
* operation except that if 16x16B BD locations are consumed in the ring
* by this packet, then this value must be 16 (not zero).
*/
#define PUSH32_DOORBELL_FLAGS_BD_CNT_MASK UINT32_C(0x1f00)
#define PUSH32_DOORBELL_FLAGS_BD_CNT_SFT 8
/*
* This value is a hint for the length of the entire packet. It is used
* by the chip to optimize internal processing. The packet will be
* dropped if the hint is too short. This field is valid only on the
* first BD of a packet.
*/
#define PUSH32_DOORBELL_FLAGS_LHINT_MASK UINT32_C(0x6000)
#define PUSH32_DOORBELL_FLAGS_LHINT_SFT 13
/* indicates packet length < 512B */
#define PUSH32_DOORBELL_FLAGS_LHINT_LT512 (UINT32_C(0x0) << 13)
/* indicates 512 <= packet length < 1KB */
#define PUSH32_DOORBELL_FLAGS_LHINT_LT1K (UINT32_C(0x1) << 13)
/* indicates 1KB <= packet length < 2KB */
#define PUSH32_DOORBELL_FLAGS_LHINT_LT2K (UINT32_C(0x2) << 13)
/* indicates packet length >= 2KB */
#define PUSH32_DOORBELL_FLAGS_LHINT_GTE2K (UINT32_C(0x3) << 13)
#define PUSH32_DOORBELL_FLAGS_LHINT_LAST PUSH32_DOORBELL_FLAGS_LHINT_GTE2K
/*
* If set to 1, the device immediately updates the Send Consumer Index
* after the buffer associated with this descriptor has been transferred
* via DMA to NIC memory from host memory. An interrupt may or may not
* be generated according to the state of the interrupt avoidance
* mechanisms. If this bit is set to 0, then the Consumer Index is only
* updated as soon as one of the host interrupt coalescing conditions
* has been met. This bit must be valid on the first BD of a packet.
*/
#define PUSH32_DOORBELL_FLAGS_COAL_NOW UINT32_C(0x8000)
/*
* All bits in this field must be valid on the first BD of a packet.
* Only the packet_end bit must be valid for the remaining BDs of a
* packet.
*/
#define PUSH32_DOORBELL_FLAGS_MASK UINT32_C(0xffc0)
#define PUSH32_DOORBELL_FLAGS_SFT 6
uint16_t len;
/*
* This is the length of the host physical buffer this BD describes in
* bytes. This field must be valid on all BDs of a packet.
*/
uint32_t opaque;
/*
* The opaque data field is pass through to the completion and can be
* used for any data that the driver wants to associate with the
* transmit BD. This field must be valid on the first BD of a packet.
*/
uint16_t lflags;
/*
* All bits in this field must be valid on the first BD of a packet.
* Their value on other BDs of the packet will be ignored.
*/
/*
* If set to 1, the controller replaces the TCP/UPD checksum fields of
* normal TCP/UPD checksum, or the inner TCP/UDP checksum field of the
* encapsulated TCP/UDP packets with the hardware calculated TCP/UDP
* checksum for the packet associated with this descriptor. The flag is
* ignored if the LSO flag is set. This bit must be valid on the first
* BD of a packet.
*/
#define PUSH32_DOORBELL_LFLAGS_TCP_UDP_CHKSUM UINT32_C(0x1)
/*
* If set to 1, the controller replaces the IP checksum of the normal
* packets, or the inner IP checksum of the encapsulated packets with
* the hardware calculated IP checksum for the packet associated with
* this descriptor. This bit must be valid on the first BD of a packet.
*/
#define PUSH32_DOORBELL_LFLAGS_IP_CHKSUM UINT32_C(0x2)
/*
* If set to 1, the controller will not append an Ethernet CRC to the
* end of the frame. This bit must be valid on the first BD of a packet.
* Packet must be 64B or longer when this flag is set. It is not useful
* to use this bit with any form of TX offload such as CSO or LSO. The
* intent is that the packet from the host already has a valid Ethernet
* CRC on the packet.
*/
#define PUSH32_DOORBELL_LFLAGS_NOCRC UINT32_C(0x4)
/*
* If set to 1, the device will record the time at which the packet was
* actually transmitted at the TX MAC. This bit must be valid on the
* first BD of a packet.
*/
#define PUSH32_DOORBELL_LFLAGS_STAMP UINT32_C(0x8)
/*
* If set to 1, The controller replaces the tunnel IP checksum field
* with hardware calculated IP checksum for the IP header of the packet
* associated with this descriptor. For outer UDP checksum, global outer
* UDP checksum TE_NIC register needs to be enabled. If the global outer
* UDP checksum TE_NIC register bit is set, outer UDP checksum will be
* calculated for the following cases: 1. Packets with tcp_udp_chksum
* flag set to offload checksum for inner packet AND the inner packet is
* TCP/UDP. If the inner packet is ICMP for example (non-TCP/UDP), even
* if the tcp_udp_chksum is set, the outer UDP checksum will not be
* calculated. 2. Packets with lso flag set which implies inner TCP
* checksum calculation as part of LSO operation.
*/
#define PUSH32_DOORBELL_LFLAGS_T_IP_CHKSUM UINT32_C(0x10)
/*
* If set to 1, the device will treat this packet with LSO(Large Send
* Offload) processing for both normal or encapsulated packets, which is
* a form of TCP segmentation. When this bit is 1, the hdr_size and mss
* fields must be valid. The driver doesn't need to set t_ip_chksum,
* ip_chksum, and tcp_udp_chksum flags since the controller will replace
* the appropriate checksum fields for segmented packets. When this bit
* is 1, the hdr_size and mss fields must be valid.
*/
#define PUSH32_DOORBELL_LFLAGS_LSO UINT32_C(0x20)
/*
* If set to zero when LSO is '1', then the IPID will be treated as a
* 16b number and will be wrapped if it exceeds a value of 0xffff. If
* set to one when LSO is '1', then the IPID will be treated as a 15b
* number and will be wrapped if it exceeds a value 0f 0x7fff.
*/
#define PUSH32_DOORBELL_LFLAGS_IPID_FMT UINT32_C(0x40)
/*
* If set to zero when LSO is '1', then the IPID of the tunnel IP header
* will not be modified during LSO operations. If set to one when LSO is
* '1', then the IPID of the tunnel IP header will be incremented for
* each subsequent segment of an LSO operation. The flag is ignored if
* the LSO packet is a normal (non-tunneled) TCP packet.
*/
#define PUSH32_DOORBELL_LFLAGS_T_IPID UINT32_C(0x80)
/*
* If set to '1', then the RoCE ICRC will be appended to the packet.
* Packet must be a valid RoCE format packet.
*/
#define PUSH32_DOORBELL_LFLAGS_ROCE_CRC UINT32_C(0x100)
/*
* If set to '1', then the FCoE CRC will be appended to the packet.
* Packet must be a valid FCoE format packet.
*/
#define PUSH32_DOORBELL_LFLAGS_FCOE_CRC UINT32_C(0x200)
uint16_t hdr_size;
/*
* When LSO is '1', this field must contain the offset of the TCP
* payload from the beginning of the packet in as 16b words. In case of
* encapsulated/tunneling packet, this field contains the offset of the
* inner TCP payload from beginning of the packet as 16-bit words. This
* value must be valid on the first BD of a packet.
*/
#define PUSH32_DOORBELL_HDR_SIZE_MASK UINT32_C(0x1ff)
#define PUSH32_DOORBELL_HDR_SIZE_SFT 0
uint32_t mss;
/*
* This is the MSS value that will be used to do the LSO processing. The
* value is the length in bytes of the TCP payload for each segment
* generated by the LSO operation. This value must be valid on the first
* BD of a packet.
*/
#define PUSH32_DOORBELL_MSS_MASK UINT32_C(0x7fff)
#define PUSH32_DOORBELL_MSS_SFT 0
uint16_t unused_2;
uint16_t cfa_action;
/*
* This value selects a CFA action to perform on the packet. Set this
* value to zero if no CFA action is desired. This value must be valid
* on the first BD of a packet.
*/
uint32_t cfa_meta;
/*
* This value is action meta-data that defines CFA edit operations that
* are done in addition to any action editing.
*/
/* When key=1, This is the VLAN tag VID value. */
#define PUSH32_DOORBELL_CFA_META_VLAN_VID_MASK UINT32_C(0xfff)
#define PUSH32_DOORBELL_CFA_META_VLAN_VID_SFT 0
/* When key=1, This is the VLAN tag DE value. */
#define PUSH32_DOORBELL_CFA_META_VLAN_DE UINT32_C(0x1000)
/* When key=1, This is the VLAN tag PRI value. */
#define PUSH32_DOORBELL_CFA_META_VLAN_PRI_MASK UINT32_C(0xe000)
#define PUSH32_DOORBELL_CFA_META_VLAN_PRI_SFT 13
/* When key=1, This is the VLAN tag TPID select value. */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_MASK UINT32_C(0x70000)
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_SFT 16
/* 0x88a8 */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPID88A8 (UINT32_C(0x0) << 16)
/* 0x8100 */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPID8100 (UINT32_C(0x1) << 16)
/* 0x9100 */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPID9100 (UINT32_C(0x2) << 16)
/* 0x9200 */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPID9200 (UINT32_C(0x3) << 16)
/* 0x9300 */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPID9300 (UINT32_C(0x4) << 16)
/* Value programmed in CFA VLANTPID register. */
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPIDCFG (UINT32_C(0x5) << 16)
#define PUSH32_DOORBELL_CFA_META_VLAN_TPID_LAST PUSH32_DOORBELL_CFA_META_VLAN_TPID_TPIDCFG
/* When key=1, This is the VLAN tag TPID select value. */
#define PUSH32_DOORBELL_CFA_META_VLAN_RESERVED_MASK UINT32_C(0xff80000)
#define PUSH32_DOORBELL_CFA_META_VLAN_RESERVED_SFT 19
/*
* This field identifies the type of edit to be performed on the packet.
* This value must be valid on the first BD of a packet.
*/
#define PUSH32_DOORBELL_CFA_META_KEY_MASK UINT32_C(0xf0000000)
#define PUSH32_DOORBELL_CFA_META_KEY_SFT 28
/* No editing */
#define PUSH32_DOORBELL_CFA_META_KEY_NONE (UINT32_C(0x0) << 28)
/*
* - meta[17:16] - TPID select value (0 = 0x8100). - meta[15:12]
* - PRI/DE value. - meta[11:0] - VID value.
*/
#define PUSH32_DOORBELL_CFA_META_KEY_VLAN_TAG (UINT32_C(0x1) << 28)
#define PUSH32_DOORBELL_CFA_META_KEY_LAST PUSH32_DOORBELL_CFA_META_KEY_VLAN_TAG
uint32_t data[25];
/*
* This is the data for the push packet. If the packet data does not fit
* in the first pass, data writing can continue at offset 4 of the
* doorbell for up to 4 additional passes for a total data size of 512B
* maximum.
*/
} __attribute__((packed));
/* Doorbell Structures */
/*
* Description: This is the RoCE 32b Doorbell format. The host writes this
* message format directly to byte offset 8 of the appropriate doorbell page.
*/
/* 64b Doorbell Format (8 bytes) */
struct dbr_dbr {
uint32_t index;
/*
* This value is the index being written. For SQ, RQ, SRQ, this is the
* producer index and should be the queue index of the last WQE written
* plus 1. For CQ, this is the consumer index and should be the index of
* the last CQE processed plus 1.
*/
#define DBR_DBR_INDEX_MASK UINT32_C(0xfffff)
#define DBR_DBR_INDEX_SFT 0
#define DBR_DBR_RESERVED12_MASK UINT32_C(0xfff00000)
#define DBR_DBR_RESERVED12_SFT 20
uint32_t type_xid;
/* This value identifies the type of doorbell being written. */
/*
* This value identifies the resource that the doorbell is intended to
* notify. For SQ and RQ, this is the QPID. For SRQ, this is the SID.
* For CQ, this is the CID. Bits [19:16] of this values must be zero for
* a SID value.
*/
#define DBR_DBR_XID_MASK UINT32_C(0xfffff)
#define DBR_DBR_XID_SFT 0
#define DBR_DBR_RESERVED8_MASK UINT32_C(0xff00000)
#define DBR_DBR_RESERVED8_SFT 20
/* This value identifies the type of doorbell being written. */
#define DBR_DBR_TYPE_MASK UINT32_C(0xf0000000)
#define DBR_DBR_TYPE_SFT 28
/*
* This is a SQ producer index update. It indicates one or more
* new entries have been written to the SQ for the QPID
* indicated on the xID field.
*/
#define DBR_DBR_TYPE_SQ (UINT32_C(0x0) << 28)
/*
* This is a RQ producer index update. It indicates one or more
* new entries have been written to the RQ for the QPID
* indicated on the xID field.
*/
#define DBR_DBR_TYPE_RQ (UINT32_C(0x1) << 28)
/*
* This is a SRQ producer index update. It indicates one or more
* new entries have been written to the SRQ for the SID
* indicated on the xID field.
*/
#define DBR_DBR_TYPE_SRQ (UINT32_C(0x2) << 28)
/*
* This doorbell command arms the SRQ async event. The xID field
* must identify the SID that is begin armed. The index field is
* will set the arm threshold such that a notification will be
* generated if less than that number or SRQ entries are posted.
*/
#define DBR_DBR_TYPE_SRQ_ARM (UINT32_C(0x3) << 28)
/*
* This is a CQ consumer index update. It indicates one or more
* entries have been processed off the CQ indicated on the xID
* field.
*/
#define DBR_DBR_TYPE_CQ (UINT32_C(0x4) << 28)
/*
* this is a CQ consumer index update that also arms the CQ for
* solicited events.
*/
#define DBR_DBR_TYPE_CQ_ARMSE (UINT32_C(0x5) << 28)
/*
* This is a CQ consumer index update that also arms the CQ for
* any new CQE.
*/
#define DBR_DBR_TYPE_CQ_ARMALL (UINT32_C(0x6) << 28)
/*
* This is a CQ arm enable message. This message must be sent
* from the privileged driver before a new CQ_ARMSE or CQ_ARMALL
* message will be accepted. This doorbell can only be sent from
* the privileged (first) doorbell page of a function.
*/
#define DBR_DBR_TYPE_CQ_ARMENA (UINT32_C(0x7) << 28)
/*
* This doorbell command enables the SRQ async event to be
* armed. This message must be setn from the privileged driver
* before a new SRQ_ARM message will be accepted. The xID field
* must identify the SID that is begin enabled for arm. This
* doorbell can only be sent from the privileged (first)
* doorbell page of a function.
*/
#define DBR_DBR_TYPE_SRQ_ARMENA (UINT32_C(0x8) << 28)
/*
* This doorbell command indicates that the cutoff CQE has been
* processed and the driver is now processing completions from
* the new CQ. The index field for this doorbell type must be
* zero.
*/
#define DBR_DBR_TYPE_CQ_CUTOFF_ACK (UINT32_C(0x9) << 28)
/*
* This doorbell command is used during doorbell moderation to
* consume system BW and help prevent doorbell FIFO overflow.
* All other fields should be zero for NULL doorbell.
*/
#define DBR_DBR_TYPE_NULL (UINT32_C(0xf) << 28)
} __attribute__((packed));
/* 32b Doorbell Format (4 bytes) */
struct dbr_dbr32 {
uint32_t type_abs_incr_xid;
/* This value identifies the type of doorbell being written. */
/*
* This value identifies the resource that the doorbell is intended to
* notify. For SQ and RQ, this is the QPID. For SRQ, this is the SID.
* For CQ, this is the CID. Bits [19:16] of this values must be zero for
* a SID value.
*/
#define DBR_DBR32_XID_MASK UINT32_C(0xfffff)
#define DBR_DBR32_XID_SFT 0
#define DBR_DBR32_RESERVED4_MASK UINT32_C(0xf00000)
#define DBR_DBR32_RESERVED4_SFT 20
/*
* When abs=0, this value is the value to add to the appropriate index
* value. When abs=1, this value is the new value for the index.
* Absolute value is used when the queue is being wrapped. When abs=1,
* the incr value follows the same rules as the index value in the 64b
* doorbell.
*/
#define DBR_DBR32_INCR_MASK UINT32_C(0xf000000)
#define DBR_DBR32_INCR_SFT 24
/* This value defines how the incr value will be interpreted. */
#define DBR_DBR32_ABS UINT32_C(0x10000000)
/* This value identifies the type of doorbell being written. */
#define DBR_DBR32_TYPE_MASK UINT32_C(0xe0000000)
#define DBR_DBR32_TYPE_SFT 29
/*
* This is a SQ producer index update. It indicates one or more
* new entries have been written to the SQ for the QPID
* indicated on the xID field.
*/
#define DBR_DBR32_TYPE_SQ (UINT32_C(0x0) << 29)
} __attribute__((packed));
/* SQ WQE Structures */
/*
* Description: This is the Bind WQE structure. This WQE can perform either: *
* type1 "bind memory window", if mw_type==Type1 * type2 "post send bind memory
* window", if mw_type==Type2
*/
/* Base SQ WQE (8 bytes) */
struct sq_base {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* Send */
#define SQ_BASE_WQE_TYPE_SEND UINT32_C(0x0)
/*
* Send with Immediate Allowed only on reliable connection (RC)
* and unreliable datagram (UD) SQ's.
*/
#define SQ_BASE_WQE_TYPE_SEND_W_IMMEAD UINT32_C(0x1)
/*
* Send with Invalidate. Allowed only on reliable connection
* (RC) SQ's.
*/
#define SQ_BASE_WQE_TYPE_SEND_W_INVALID UINT32_C(0x2)
/* RDMA Write. Allowed only on reliable connection (RC) SQ's. */
#define SQ_BASE_WQE_TYPE_WRITE_WQE UINT32_C(0x4)
/*
* RDMA Write with Immediate. Allowed only on reliable
* connection (RC) SQ's.
*/
#define SQ_BASE_WQE_TYPE_WRITE_W_IMMEAD UINT32_C(0x5)
/* RDMA Read. Allowed only on reliable connection (RC) SQ's. */
#define SQ_BASE_WQE_TYPE_READ_WQE UINT32_C(0x6)
/*
* Atomic Compare/Swap. Allowed only on reliable connection (RC)
* SQ's.
*/
#define SQ_BASE_WQE_TYPE_ATOMIC_CS UINT32_C(0x8)
/* Atomic Fetch/Add. Allowed only on reliable connection (RC) SQ's. */
#define SQ_BASE_WQE_TYPE_ATOMIC_FA UINT32_C(0xb)
/* Local Invalidate. Allowed only on reliable connection (RC) SQ's. */
#define SQ_BASE_WQE_TYPE_LOCAL_INVALID UINT32_C(0xc)
/*
* FR-PMR (Fast Register Physical Memory Region) Allowed only on
* reliable connection (RC) SQ's.
*/
#define SQ_BASE_WQE_TYPE_FR_PMR UINT32_C(0xd)
/* Memory Bind Allowed only on reliable connection (RC) SQ's. */
#define SQ_BASE_WQE_TYPE_BIND UINT32_C(0xe)
uint8_t unused_0[7];
} __attribute__((packed));
/* WQE SGE (16 bytes) */
struct sq_sge {
uint64_t va_or_pa;
/*
* The virtual address in local memory or a physical address when l_key
* value is a reserved value of a physical address. Driver configures
* this value in the chip and the chip compares l_key in SGEs with that
* reserved value, if equal it access the physical address specified.
* The chip however MUST verify that the QP allows the use reserved key.
*/
uint32_t l_key;
/*
* Local Key associated with this registered MR; The 24 msb of the key
* used to index the MRW Table and the 8 lsb are compared with the 8
* bits key part stored in the MRWC. The PBL in the MRW Context is used
* to translate the above VA to physical address.
*/
uint32_t size;
/*
* Size of SGE in bytes; Based on page size of the system the chip knows
* how many entries are in the PBL
*/
} __attribute__((packed));
/* PSN Search Structure (8 bytes) */
struct sq_psn_search {
uint32_t opcode_start_psn;
/* The opcodes are software defined. */
/* Start PSN. */
#define SQ_PSN_SEARCH_START_PSN_MASK UINT32_C(0xffffff)
#define SQ_PSN_SEARCH_START_PSN_SFT 0
/* The opcodes are software defined. */
#define SQ_PSN_SEARCH_OPCODE_MASK UINT32_C(0xff000000)
#define SQ_PSN_SEARCH_OPCODE_SFT 24
uint32_t flags_next_psn;
/* Opcode specific flags. */
/* Next PSN. Equal to the start PSN of the next WQE. */
#define SQ_PSN_SEARCH_NEXT_PSN_MASK UINT32_C(0xffffff)
#define SQ_PSN_SEARCH_NEXT_PSN_SFT 0
/* Opcode specific flags. */
#define SQ_PSN_SEARCH_FLAGS_MASK UINT32_C(0xff000000)
#define SQ_PSN_SEARCH_FLAGS_SFT 24
} __attribute__((packed));
/* Send SQ WQE (40 bytes) */
struct sq_send {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* Send */
#define SQ_SEND_WQE_TYPE_SEND UINT32_C(0x0)
/*
* Send with Immediate Allowed only on reliable connection (RC)
* and unreliable datagram (UD) SQ's.
*/
#define SQ_SEND_WQE_TYPE_SEND_W_IMMEAD UINT32_C(0x1)
/*
* Send with Invalidate. Allowed only on reliable connection
* (RC) SQ's.
*/
#define SQ_SEND_WQE_TYPE_SEND_W_INVALID UINT32_C(0x2)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refers to
* the CQE on the sender side. (The se flag refers to the receiver
* side).
*/
#define SQ_SEND_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE. This flag must be zero for a UD send.
*/
#define SQ_SEND_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* For local invalidate request. Indicate to complete all previous SQ's
* WQEs before executing this WQE. This flag must be zero for a UD send.
*/
#define SQ_SEND_FLAGS_UC_FENCE UINT32_C(0x4)
/*
* Solicit event flag. Indication sent in BTH header to the receiver to
* generate a Completion Event Notification, i.e. CNQE. This bit should
* be set only in the last (or only) packet of the message.
*/
#define SQ_SEND_FLAGS_SE UINT32_C(0x8)
/*
* Indicate that inline data is posted to the SQ in the data area of
* this WQE.
*/
#define SQ_SEND_FLAGS_INLINE UINT32_C(0x10)
uint8_t wqe_size;
/*
* The number of 16 bytes chunks of data including this first word of
* the request that are a valid part of the request. The valid 16 bytes
* units other than the WQE structure can be SGEs (Scatter Gather
* Elements) OR inline data. While this field defines the valid WQE
* size. The actual total WQE size is always 128B.
*/
uint8_t reserved8_1;
uint32_t inv_key_or_imm_data;
/*
* Either invalidate key (R_Key of the remote host) that will be send
* with IETH (Invalidate ETH) if wqe_type is of Send with Invalidate, or
* immediate value that will be sent with ImmDt header if wqe_type is
* Send with Immediate.
*/
uint32_t length;
/* This field represents a 32-bit total data length, in bytes. */
uint32_t q_key;
/*
* When in the SQ of a UD QP, indicates the q_key to be used in the
* transmitted packet. However, if the most significant bit of this
* field is set, then the q_key will be taken from QP context, rather
* than from this field. When in the SQ of a non-UD QP, this field is
* reserved and should be filled with zeros.
*/
uint32_t dst_qp;
/*
* When in the SQ of a UD QP, indicates the destination QP to be used in
* the transmitted packet. When in the SQ of a non-UD QP, this field is
* reserved and should be filled with zeros.
*/
#define SQ_SEND_DST_QP_MASK UINT32_C(0xffffff)
#define SQ_SEND_DST_QP_SFT 0
#define SQ_SEND_RESERVED8_2_MASK UINT32_C(0xff000000)
#define SQ_SEND_RESERVED8_2_SFT 24
uint32_t avid;
/* This field is reserved for future expansion of the AVID. */
/*
* If the serv_type is 'UD', then this field supplies the AVID (Address
* Vector ID).
*/
#define SQ_SEND_AVID_MASK UINT32_C(0xfffff)
#define SQ_SEND_AVID_SFT 0
/* This field is reserved for future expansion of the AVID. */
#define SQ_SEND_RESERVED_AVID_MASK UINT32_C(0xfff00000)
#define SQ_SEND_RESERVED_AVID_SFT 20
uint64_t reserved64;
uint32_t data[24];
/*
* When inline=0, then this area is filled with from 1 to 6 SGEs based
* on the wqe_size field. When inline=1, this area is filled with
* payload data for the send based on the length_or_AVID field. Bits
* [7:0] of word 0 hold the first byte to go out on the wire.
*/
} __attribute__((packed));
/* Send Raw Ethernet and QP1 SQ WQE (40 bytes) */
struct sq_send_raweth_qp1 {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* Send */
#define SQ_SEND_RAWETH_QP1_WQE_TYPE_SEND UINT32_C(0x0)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refers to
* the CQE on the sender side. (The se flag refers to the receiver
* side).
*/
#define SQ_SEND_RAWETH_QP1_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/* This flag must be zero for a Raweth or QP1 send. */
#define SQ_SEND_RAWETH_QP1_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/* This flag must be zero for a Raweth or QP1 send. */
#define SQ_SEND_RAWETH_QP1_FLAGS_UC_FENCE UINT32_C(0x4)
/* This flag must be zero for a Raweth or QP1 send. */
#define SQ_SEND_RAWETH_QP1_FLAGS_SE UINT32_C(0x8)
/*
* Indicate that inline data is posted to the SQ in the data area of
* this WQE.
*/
#define SQ_SEND_RAWETH_QP1_FLAGS_INLINE UINT32_C(0x10)
uint8_t wqe_size;
/*
* The number of 16 bytes chunks of data including this first word of
* the request that are a valid part of the request. The valid 16 bytes
* units other than the WQE structure can be SGEs (Scatter Gather
* Elements) OR inline data. While this field defines the valid WQE
* size. The actual total WQE size is always 128B.
*/
uint8_t reserved8;
uint16_t lflags;
/*
* All bits in this field must be valid on the first BD of a packet.
* Their value on other BDs of the packet will be ignored.
*/
/*
* If set to 1, the controller replaces the TCP/UPD checksum fields of
* normal TCP/UPD checksum, or the inner TCP/UDP checksum field of the
* encapsulated TCP/UDP packets with the hardware calculated TCP/UDP
* checksum for the packet associated with this descriptor. This bit
* must be valid on the first BD of a packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_TCP_UDP_CHKSUM UINT32_C(0x1)
/*
* If set to 1, the controller replaces the IP checksum of the normal
* packets, or the inner IP checksum of the encapsulated packets with
* the hardware calculated IP checksum for the packet associated with
* this descriptor. This bit must be valid on the first BD of a packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_IP_CHKSUM UINT32_C(0x2)
/*
* If set to 1, the controller will not append an Ethernet CRC to the
* end of the frame. This bit must be valid on the first BD of a packet.
* Packet must be 64B or longer when this flag is set. It is not usefull
* to use this bit with any form of TX offload such as CSO or LSO. The
* intent is that the packet from the host already has a valid Ethernet
* CRC on the packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_NOCRC UINT32_C(0x4)
/*
* If set to 1, the device will record the time at which the packet was
* actually transmitted at the TX MAC. This bit must be valid on the
* first BD of a packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_STAMP UINT32_C(0x8)
/*
* If set to 1, The controller replaces the tunnel IP checksum field
* with hardware calculated IP checksum for the IP header of the packet
* associated with this descriptor. In case of VXLAN, the controller
* also replaces the outer header UDP checksum with hardware calculated
* UDP checksum for the packet associated with this descriptor.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_T_IP_CHKSUM UINT32_C(0x10)
/* This bit is reserved and should be zero. */
#define SQ_SEND_RAWETH_QP1_LFLAGS_RESERVED1_1 UINT32_C(0x20)
/* This bit is reserved and should be zero. */
#define SQ_SEND_RAWETH_QP1_LFLAGS_RESERVED1_2 UINT32_C(0x40)
/* This bit is reserved and should be zero. */
#define SQ_SEND_RAWETH_QP1_LFLAGS_RESERVED1_3 UINT32_C(0x80)
/*
* If set to '1', then the RoCE ICRC will be appended to the packet.
* Packet must be a valid RoCE format packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_ROCE_CRC UINT32_C(0x100)
/*
* If set to '1', then the FCoE CRC will be appended to the packet.
* Packet must be a valid FCoE format packet.
*/
#define SQ_SEND_RAWETH_QP1_LFLAGS_FCOE_CRC UINT32_C(0x200)
uint16_t cfa_action;
/*
* This value selects a CFA action to perform on the packet. Set this
* value to zero if no CFA action is desired. This value must be valid
* on the first BD of a packet.
*/
uint32_t length;
/*
* This field represents a 32-bit total data length, in bytes. Note,
* however, that the length cannot exceed the MTU.
*/
uint32_t reserved32_1;
uint32_t cfa_meta;
/*
* This value is action meta-data that defines CFA edit operations that
* are done in addition to any action editing.
*/
/* When key=1, This is the VLAN tag VID value. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_VID_MASK UINT32_C(0xfff)
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_VID_SFT 0
/* When key=1, This is the VLAN tag DE value. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_DE UINT32_C(0x1000)
/* When key=1, This is the VLAN tag PRI value. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_PRI_MASK UINT32_C(0xe000)
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_PRI_SFT 13
/* When key=1, This is the VLAN tag TPID select value. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_MASK UINT32_C(0x70000)
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_SFT 16
/* 0x88a8 */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPID88A8 (UINT32_C(0x0) << 16)
/* 0x8100 */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPID8100 (UINT32_C(0x1) << 16)
/* 0x9100 */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPID9100 (UINT32_C(0x2) << 16)
/* 0x9200 */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPID9200 (UINT32_C(0x3) << 16)
/* 0x9300 */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPID9300 (UINT32_C(0x4) << 16)
/* Value programmed in CFA VLANTPID register. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPIDCFG (UINT32_C(0x5) << 16)
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_LAST SQ_SEND_RAWETH_QP1_CFA_META_VLAN_TPID_TPIDCFG
/* When key=1, This is the VLAN tag TPID select value. */
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_RESERVED_MASK UINT32_C(0xff80000)
#define SQ_SEND_RAWETH_QP1_CFA_META_VLAN_RESERVED_SFT 19
/*
* This field identifies the type of edit to be performed on the packet.
* This value must be valid on the first BD of a packet.
*/
#define SQ_SEND_RAWETH_QP1_CFA_META_KEY_MASK UINT32_C(0xf0000000)
#define SQ_SEND_RAWETH_QP1_CFA_META_KEY_SFT 28
/* No editing */
#define SQ_SEND_RAWETH_QP1_CFA_META_KEY_NONE (UINT32_C(0x0) << 28)
/*
* - meta[17:16] - TPID select value (0 = 0x8100). - meta[15:12]
* - PRI/DE value. - meta[11:0] - VID value.
*/
#define SQ_SEND_RAWETH_QP1_CFA_META_KEY_VLAN_TAG (UINT32_C(0x1) << 28)
#define SQ_SEND_RAWETH_QP1_CFA_META_KEY_LAST SQ_SEND_RAWETH_QP1_CFA_META_KEY_VLAN_TAG
uint32_t reserved32_2;
uint64_t reserved64;
uint32_t data[24];
/*
* When inline=0, then this area is filled with from 1 to 6 SGEs based
* on the wqe_size field. When inline=1, this area is filled with
* payload data for the send based on the length_or_AVID field. Bits
* [7:0] of word 0 hold the first byte to go out on the wire.
*/
} __attribute__((packed));
/* RDMA SQ WQE (40 bytes) */
struct sq_rdma {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* RDMA Write. Allowed only on reliable connection (RC) SQ's. */
#define SQ_RDMA_WQE_TYPE_WRITE_WQE UINT32_C(0x4)
/*
* RDMA Write with Immediate. Allowed only on reliable
* connection (RC) SQ's.
*/
#define SQ_RDMA_WQE_TYPE_WRITE_W_IMMEAD UINT32_C(0x5)
/* RDMA Read. Allowed only on reliable connection (RC) SQ's. */
#define SQ_RDMA_WQE_TYPE_READ_WQE UINT32_C(0x6)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refer to
* CQE on the sender side (se_flag refer to the receiver side)
*/
#define SQ_RDMA_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE
*/
#define SQ_RDMA_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* Unconditional fence. Indicate to complete all previous SQ's WQEs
* before executing this WQE.
*/
#define SQ_RDMA_FLAGS_UC_FENCE UINT32_C(0x4)
/*
* Solicit event. Indication sent in BTH header to the receiver to
* generate a Completion Event Notification, i.e. CNQE. This bit should
* be set only in the last (or only) packet of the message.
*/
#define SQ_RDMA_FLAGS_SE UINT32_C(0x8)
/*
* Indicate that inline data is posted to the SQ following this WQE.
* This bit may be 1 only for write operations.
*/
#define SQ_RDMA_FLAGS_INLINE UINT32_C(0x10)
uint8_t wqe_size;
/*
* The number of 16 bytes chunks of data including this first wqe of the
* request that are a valid part of the request. The valid 16 bytes
* units other than the WQE structure can be SGEs (Scatter Gather
* Elements) OR inline data. While this field defines the valid WQE
* size. The actual total WQE size is always 128B.
*/
uint8_t reserved8;
uint32_t imm_data;
/*
* Immediate data - valid for RDMA Write with immediate and causes the
* controller to add immDt header with this value
*/
uint32_t length;
/* Total data length in bytes */
uint32_t reserved32_1;
uint64_t remote_va;
/* Remote VA sent to the destination QP */
uint32_t remote_key;
/*
* R_Key provided by remote node when the connection was established and
* placed in the RETH header. It identify the MRW on the remote host
*/
uint32_t reserved32_2;
uint32_t data[24];
/*
* When inline=0, then this area is filled with from 1 to 6 SGEs based
* on the wqe_size field. When inline=1, this area is filled with
* payload data for the write based on the length field. Bits [7:0] of
* word 0 hold the first byte to go out on the wire.
*/
} __attribute__((packed));
/* Atomic SQ WQE (40 bytes) */
struct sq_atomic {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/*
* Atomic Compare/Swap. Allowed only on reliable connection (RC)
* SQ's.
*/
#define SQ_ATOMIC_WQE_TYPE_ATOMIC_CS UINT32_C(0x8)
/* Atomic Fetch/Add. Allowed only on reliable connection (RC) SQ's. */
#define SQ_ATOMIC_WQE_TYPE_ATOMIC_FA UINT32_C(0xb)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refer to
* CQE on the sender side (se_flag refer to the receiver side)
*/
#define SQ_ATOMIC_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE
*/
#define SQ_ATOMIC_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* Unconditional fence. Indicate to complete all previous SQ's WQEs
* before executing this WQE.
*/
#define SQ_ATOMIC_FLAGS_UC_FENCE UINT32_C(0x4)
/*
* Solicit event. Indication sent in BTH header to the receiver to
* generate a Completion Event Notification, i.e. CNQE. This bit should
* be set only in the last (or only) packet of the message.
*/
#define SQ_ATOMIC_FLAGS_SE UINT32_C(0x8)
/* NA for this WQE. */
#define SQ_ATOMIC_FLAGS_INLINE UINT32_C(0x10)
uint16_t reserved16;
uint32_t remote_key;
/*
* R_Key provided by remote node when the connection was established and
* placed in the AETH header. It identify the MRW on the remote host
*/
uint64_t remote_va;
/* Remote VA sent to the destination QP */
uint64_t swap_data;
/* Data value to be placed in remote host specified address */
uint64_t cmp_data;
/*
* Data value to be compared with the value in the remote host specified
* address
*/
uint32_t data[24];
/*
* The first 16B of the data field must be filled with a single SGE.
* This will be used to store the return value from the Atomic Ack
* response. The size of the single SGE must be 8B.
*/
} __attribute__((packed));
/* Local Invalidate SQ WQE (40 bytes) */
struct sq_localinvalidate {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* Local Invalidate. Allowed only on reliable connection (RC) SQ's. */
#define SQ_LOCALINVALIDATE_WQE_TYPE_LOCAL_INVALID UINT32_C(0xc)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refer to
* CQE on the sender side (se_flag refer to the receiver side)
*/
#define SQ_LOCALINVALIDATE_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE
*/
#define SQ_LOCALINVALIDATE_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* Unconditional fence. Indicate to complete all previous SQ's WQEs
* before executing this WQE.
*/
#define SQ_LOCALINVALIDATE_FLAGS_UC_FENCE UINT32_C(0x4)
/*
* Solicit event. Indication sent in BTH header to the receiver to
* generate a Completion Event Notification, i.e. CNQE. This bit should
* be set only in the last (or only) packet of the message.
*/
#define SQ_LOCALINVALIDATE_FLAGS_SE UINT32_C(0x8)
/* NA for this WQE */
#define SQ_LOCALINVALIDATE_FLAGS_INLINE UINT32_C(0x10)
uint16_t reserved16;
uint32_t inv_l_key;
/*
* The local key for the MR/W to invalidate; 24 msb of the key are used
* to index the MRW table, 8 lsb are compared with the 8 bit key in the
* MRWC
*/
uint64_t reserved64;
uint32_t reserved128[4];
uint32_t data[24];
/* The data field for local invalidate is not used. */
} __attribute__((packed));
/* FR-PMR SQ WQE (40 bytes) */
struct sq_fr_pmr {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/*
* FR-PMR (Fast Register Physical Memory Region) Allowed only on
* reliable connection (RC) SQ's.
*/
#define SQ_FR_PMR_WQE_TYPE_FR_PMR UINT32_C(0xd)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refer to
* CQE on the sender side (se_flag refer to the receiver side)
*/
#define SQ_FR_PMR_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE
*/
#define SQ_FR_PMR_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* Unconditional fence. Indicate to complete all previous SQ's WQEs
* before executing this WQE.
*/
#define SQ_FR_PMR_FLAGS_UC_FENCE UINT32_C(0x4)
/* Not Applicable for FR_PMR. Nothing is sent */
#define SQ_FR_PMR_FLAGS_SE UINT32_C(0x8)
/* NA. */
#define SQ_FR_PMR_FLAGS_INLINE UINT32_C(0x10)
uint8_t access_cntl;
/*
* This is the new access control for the MR. '1' means the operation is
* allowed. '0' means operation is not allowed.
*/
/* Local Write Access */
#define SQ_FR_PMR_ACCESS_CNTL_LOCAL_WRITE UINT32_C(0x1)
/* Remote Read Access */
#define SQ_FR_PMR_ACCESS_CNTL_REMOTE_READ UINT32_C(0x2)
/* Remote Write Access */
#define SQ_FR_PMR_ACCESS_CNTL_REMOTE_WRITE UINT32_C(0x4)
/* Remote Atomic Access */
#define SQ_FR_PMR_ACCESS_CNTL_REMOTE_ATOMIC UINT32_C(0x8)
/* Window Binding Allowed */
#define SQ_FR_PMR_ACCESS_CNTL_WINDOW_BIND UINT32_C(0x10)
uint8_t zero_based_page_size_log;
/* 0 for 4KB page size, ... to 8GB */
#define SQ_FR_PMR_PAGE_SIZE_LOG_MASK UINT32_C(0x1f)
#define SQ_FR_PMR_PAGE_SIZE_LOG_SFT 0
/* Page size is 4KB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_4K UINT32_C(0x0)
/* Page size is 8KB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_8K UINT32_C(0x1)
/* Page size is 64KB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_64K UINT32_C(0x4)
/* Page size is 256KB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_256K UINT32_C(0x6)
/* Page size is 1MB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_1M UINT32_C(0x8)
/* Page size is 2MB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_2M UINT32_C(0x9)
/* Page size is 4MB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_4M UINT32_C(0xa)
/* Page size is 1GB. */
#define SQ_FR_PMR_PAGE_SIZE_LOG_PGSZ_1G UINT32_C(0x12)
/* Indicate the MR is ZBVA (Zero Base VA) */
#define SQ_FR_PMR_ZERO_BASED UINT32_C(0x20)
#define SQ_FR_PMR_RESERVED2_MASK UINT32_C(0xc0)
#define SQ_FR_PMR_RESERVED2_SFT 6
uint32_t l_key;
/*
* Local Key; 24 msb of the key are used to index the MRW table, 8 lsb
* are assigned to the 8 bit key_lsb field in the MRWC.
*/
uint8_t length[5];
/* Length in bytes of registered MR */
uint8_t reserved8_1;
uint8_t reserved8_2;
uint8_t numlevels_pbl_page_size_log;
/* Number of levels of PBL for translation */
/* PBL page size. 0 for 4KB page size. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_MASK UINT32_C(0x1f)
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_SFT 0
/* Page size is 4KB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_4K UINT32_C(0x0)
/* Page size is 8KB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_8K UINT32_C(0x1)
/* Page size is 64KB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_64K UINT32_C(0x4)
/* Page size is 256KB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_256K UINT32_C(0x6)
/* Page size is 1MB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_1M UINT32_C(0x8)
/* Page size is 2MB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_2M UINT32_C(0x9)
/* Page size is 4MB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_4M UINT32_C(0xa)
/* Page size is 1GB. */
#define SQ_FR_PMR_PBL_PAGE_SIZE_LOG_PGSZ_1G UINT32_C(0x12)
#define SQ_FR_PMR_RESERVED1 UINT32_C(0x20)
/* Number of levels of PBL for translation */
#define SQ_FR_PMR_NUMLEVELS_MASK UINT32_C(0xc0)
#define SQ_FR_PMR_NUMLEVELS_SFT 6
/*
* A zero level PBL means that the VA is the physical address
* used for the operation. No translation is done by the PTU.
*/
#define SQ_FR_PMR_NUMLEVELS_PHYSICAL (UINT32_C(0x0) << 6)
/*
* A one layer translation is provided between the logical and
* physical address. The PBL points to a physical page that
* contains PBE values that point to actual pg_size physical
* pages.
*/
#define SQ_FR_PMR_NUMLEVELS_LAYER1 (UINT32_C(0x1) << 6)
/*
* A two layer translation is provided between the logical and
* physical address. The PBL points to a physical page that
* contains PDE values that in turn point to pbl_pg_size
* physical pages that contain PBE values that point to actual
* physical pages.
*/
#define SQ_FR_PMR_NUMLEVELS_LAYER2 (UINT32_C(0x2) << 6)
uint64_t pblptr;
/* Pointer to the PBL, or PDL depending on number of levels */
uint64_t va;
/* Local Virtual Address */
uint32_t data[24];
/* The data field for FR-PRM is not used. */
} __attribute__((packed));
/* Bind SQ WQE (40 bytes) */
struct sq_bind {
uint8_t wqe_type;
/* This field defines the type of SQ WQE. */
/* Memory Bind Allowed only on reliable connection (RC) SQ's. */
#define SQ_BIND_WQE_TYPE_BIND UINT32_C(0xe)
uint8_t flags;
/*
* Set if completion signaling is requested. If this bit is 0, and the
* SQ is configured to support Unsignaled completion the controller
* should not generate a CQE unless there was an error. This refer to
* CQE on the sender side (se_flag refer to the receiver side)
*/
#define SQ_BIND_FLAGS_SIGNAL_COMP UINT32_C(0x1)
/*
* Indication to complete all previous RDMA Read or Atomic WQEs on the
* SQ before executing this WQE
*/
#define SQ_BIND_FLAGS_RD_OR_ATOMIC_FENCE UINT32_C(0x2)
/*
* Unconditional fence. Indicate to complete all previous SQ's WQEs
* before executing this WQE.
*/
#define SQ_BIND_FLAGS_UC_FENCE UINT32_C(0x4)
/* NA, nothing is sent. */
#define SQ_BIND_FLAGS_SE UINT32_C(0x8)
/* NA */
#define SQ_BIND_FLAGS_INLINE UINT32_C(0x10)
uint8_t access_cntl;
/*
* This is the new access control for the MR. '1' means the operation is
* allowed. '0' means operation is not allowed.
*/
/*
* Local Write Access. Local accesses are never allowed for memory
* windows, so this bit must always be zero in a bind WQE. If this bit
* is ever set, the bind will fail with an errored completion.
*/
#define SQ_BIND_ACCESS_CNTL_LOCAL_WRITE UINT32_C(0x1)
/* Remote Read Access */
#define SQ_BIND_ACCESS_CNTL_REMOTE_READ UINT32_C(0x2)
/*
* Remote Write Access. Note that, if this bit is set, then the parent
* region to which the window is being bound must allow local writes. If
* this is not the case, then the bind will fail with an errored
* completion.
*/
#define SQ_BIND_ACCESS_CNTL_REMOTE_WRITE UINT32_C(0x4)
/*
* Remote Atomic Access. Note that, if this bit is set, then the parent
* region to which the window is being bound must allow local writes. If
* this is not the case, then the bind will fail with an errored
* completion.
*/
#define SQ_BIND_ACCESS_CNTL_REMOTE_ATOMIC UINT32_C(0x8)
/*
* Window Binding Allowed. It is never allowed to bind windows to
* windows, so this bit must always be zero in a bind WQE. If this bit
* is ever set, the bind will fail with an errored completion.
*/
#define SQ_BIND_ACCESS_CNTL_WINDOW_BIND UINT32_C(0x10)
uint8_t reserved8_1;
/* reserved8_1 is 8 b */
uint8_t mw_type_zero_based;
/*
* If this bit is set, then the newly-bound memory window will be zero-
* based. If clear, then the newly-bound memory window will be non-zero-
* based.
*/
#define SQ_BIND_ZERO_BASED UINT32_C(0x1)
/*
* If type1 is specified, then this WQE performs a "bind memory window"
* operation on a type1 window. If type2 is specified, then this WQE
* performs a "post send bind memory window" operation on a type2
* window. Note that the bind WQE cannot change the type of the memory
* window. If a "bind memory window" operation is attempted on a memory
* window that was allocated as type2, then the bind will fail with an
* errored completion, as "bind memory window" is allowed only on type1
* memory windows. Similarly, if a "post send bind memory window"
* operation is attempted on a memory window that was allocated as
* type1, then the bind will fail with an errored completions, as "post
* send bind memory window" is allowed only on type2 memory windows.
*/
#define SQ_BIND_MW_TYPE UINT32_C(0x2)
/* Type 1 Bind Memory Window */
#define SQ_BIND_MW_TYPE_TYPE1 (UINT32_C(0x0) << 1)
/* Type 2 Post Send Bind Memory Window */
#define SQ_BIND_MW_TYPE_TYPE2 (UINT32_C(0x1) << 1)
#define SQ_BIND_RESERVED6_MASK UINT32_C(0xfc)
#define SQ_BIND_RESERVED6_SFT 2
uint8_t reserved8_2;
uint16_t reserved16;
uint32_t parent_l_key;
/*
* The L_Key of the parent MR; 24 msb of the key are used to index the
* MRW table, 8 lsb are compared with the 8 bit key in the MRWC.
*/
uint32_t l_key;
/*
* Local Key; 24 msb of the key are used to index the memory window
* being bound in the MRW table, 8 lsb are assign to the 8 bit key_lsb
* field in the MRWC.
*/
uint64_t va;
/* Local Virtual Address */
uint8_t length[5];
/*
* Length in bytes of registered MW; 40 bits as this is the max size of
* an MR/W
*/
uint8_t data_reserved24[99];
/* The data field for Bind is not used. */
#define SQ_BIND_RESERVED24_MASK UINT32_C(0xffffff00)
#define SQ_BIND_RESERVED24_SFT 8
/* The data field for Bind is not used. */
#define SQ_BIND_DATA_MASK UINT32_C(0xffffffff)
#define SQ_BIND_DATA_SFT 0
} __attribute__((packed));
/* RQ/SRQ WQE Structures */
/* Description: This is the RQ/SRQ WQE structure. */
/* RQ/SRQ WQE (40 bytes) */
struct rq_wqe {
uint8_t wqe_type;
/* wqe_type is 8 b */
/* RQ/SRQ WQE. This WQE is used for posting buffers on an RQ or SRQ. */
#define RQ_WQE_WQE_TYPE_RCV UINT32_C(0x80)
uint8_t flags;
/* No flags supported for this WQE type. */
uint8_t wqe_size;
/*
* Specify the total number 16B chunks that make up the valid portion of
* the WQE. This includes the first chunk that is the WQE structure and
* up to 6 SGE structures. While the valid area is defined by the
* wqe_size field, the actual WQE size is fixed at 128B.
*/
uint8_t reserved8;
uint32_t reserved32;
uint64_t wr_id;
/*
* Opaque value used by upper layer SW to identify the id of the WR
* which generated the WQE. Used in CQE. Valid in the first SGE of an
* SRQ WQE.
*/
#define RQ_WQE_WR_ID_MASK UINT32_C(0xfffff)
#define RQ_WQE_WR_ID_SFT 0
#define RQ_WQE_RESERVED44_MASK UINT32_C(0xfff00000)
#define RQ_WQE_RESERVED44_SFT 20
uint32_t reserved128[4];
uint32_t data[24];
/*
* The data field for RQ WQE is filled with from 1 to 6 SGE structures
* as defined by the wqe_size field.
*/
} __attribute__((packed));
/* CQ CQE Structures */
/* Description: This is the Cutoff CQE structure. */
/* Base CQE (32 bytes) */
struct cq_base {
uint64_t reserved64_1;
uint64_t reserved64_2;
uint64_t reserved64_3;
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_BASE_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_BASE_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_BASE_CQE_TYPE_SFT 1
/*
* Requester completion - This is used for both RC and UD SQ
* completions.
*/
#define CQ_BASE_CQE_TYPE_REQ (UINT32_C(0x0) << 1)
/*
* Responder RC Completion - This is used for both RQ and SRQ
* completions for RC service QPs.
*/
#define CQ_BASE_CQE_TYPE_RES_RC (UINT32_C(0x1) << 1)
/*
* Responder UD Completion - This is used for both RQ and SRQ
* completion for UD service QPs.
*/
#define CQ_BASE_CQE_TYPE_RES_UD (UINT32_C(0x2) << 1)
/*
* Responder RawEth and QP1 Completion - This is used for RQ
* completion for RawEth service and QP1 service QPs.
*/
#define CQ_BASE_CQE_TYPE_RES_RAWETH_QP1 (UINT32_C(0x3) << 1)
/*
* Terminal completion - This is used to indicate that no
* further completions will be made for this QP on this CQ.
*/
#define CQ_BASE_CQE_TYPE_TERMINAL (UINT32_C(0xe) << 1)
/* Cut off CQE; for CQ resize see CQ and SRQ Resize */
#define CQ_BASE_CQE_TYPE_CUT_OFF (UINT32_C(0xf) << 1)
#define CQ_BASE_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_BASE_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
uint16_t reserved16;
uint32_t reserved32;
} __attribute__((packed));
/* Requester CQ CQE (32 bytes) */
struct cq_req {
uint64_t qp_handle;
/*
* This is an application level ID used to identify the QP and its SQ
* and RQ.
*/
uint16_t sq_cons_idx;
/*
* SQ Consumer Index - points to the entry just past the last WQE that
* has been completed by the chip. Wraps around at QPC.sq_size (i.e. the
* valid range of the SQ Consumer Index is 0 to (QPC.sq_size - 1)).
*/
uint16_t reserved16_1;
uint32_t reserved32_2;
uint64_t reserved64;
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_REQ_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_REQ_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_REQ_CQE_TYPE_SFT 1
/*
* Requester completion - This is used for both RC and UD SQ
* completions.
*/
#define CQ_REQ_CQE_TYPE_REQ (UINT32_C(0x0) << 1)
#define CQ_REQ_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_REQ_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/* OK is 0 */
#define CQ_REQ_STATUS_OK UINT32_C(0x0)
/* BAD_RESPONSE_ERR is 1 */
#define CQ_REQ_STATUS_BAD_RESPONSE_ERR UINT32_C(0x1)
/* LOCAL_LENGTH_ERR is 2 */
#define CQ_REQ_STATUS_LOCAL_LENGTH_ERR UINT32_C(0x2)
/* LOCAL_QP_OPERATION_ERR is 3 */
#define CQ_REQ_STATUS_LOCAL_QP_OPERATION_ERR UINT32_C(0x3)
/* LOCAL_PROTECTION_ERR is 4 */
#define CQ_REQ_STATUS_LOCAL_PROTECTION_ERR UINT32_C(0x4)
/* MEMORY_MGT_OPERATION_ERR is 5 */
#define CQ_REQ_STATUS_MEMORY_MGT_OPERATION_ERR UINT32_C(0x5)
/* REMOTE_INVALID_REQUEST_ERR is 6 */
#define CQ_REQ_STATUS_REMOTE_INVALID_REQUEST_ERR UINT32_C(0x6)
/* REMOTE_ACCESS_ERR is 7 */
#define CQ_REQ_STATUS_REMOTE_ACCESS_ERR UINT32_C(0x7)
/* REMOTE_OPERATION_ERR is 8 */
#define CQ_REQ_STATUS_REMOTE_OPERATION_ERR UINT32_C(0x8)
/* RNR_NAK_RETRY_CNT_ERR is 9 */
#define CQ_REQ_STATUS_RNR_NAK_RETRY_CNT_ERR UINT32_C(0x9)
/* TRANSPORT_RETRY_CNT_ERR is 10 */
#define CQ_REQ_STATUS_TRANSPORT_RETRY_CNT_ERR UINT32_C(0xa)
/* WORK_REQUEST_FLUSHED_ERR is 11 */
#define CQ_REQ_STATUS_WORK_REQUEST_FLUSHED_ERR UINT32_C(0xb)
uint16_t reserved16_2;
uint32_t reserved32_1;
} __attribute__((packed));
/* Responder RC CQE (32 bytes) */
struct cq_res_rc {
uint32_t length;
/* The length of the message's payload in bytes, stored in the SGEs */
uint32_t imm_data_or_inv_r_key;
/*
* Immediate data in case the imm_flag set, R_Key to be invalidated in
* case inv_flag is set.
*/
uint64_t qp_handle;
/*
* This is an application level ID used to identify the QP and its SQ
* and RQ.
*/
uint64_t mr_handle;
/*
* Opaque value - valid when inv_flag is set. Used by driver to
* reference the buffer used to store PBL when the MR was fast
* registered. The driver can reclaim this buffer after an MR was
* remotely invalidated. The controller take that value from the MR
* referenced by R_Key
*/
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_RES_RC_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_RES_RC_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_RES_RC_CQE_TYPE_SFT 1
/*
* Responder RC Completion - This is used for both RQ and SRQ
* completions for RC service QPs.
*/
#define CQ_RES_RC_CQE_TYPE_RES_RC (UINT32_C(0x1) << 1)
#define CQ_RES_RC_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_RES_RC_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/* OK is 0 */
#define CQ_RES_RC_STATUS_OK UINT32_C(0x0)
/* LOCAL_ACCESS_ERROR is 1 */
#define CQ_RES_RC_STATUS_LOCAL_ACCESS_ERROR UINT32_C(0x1)
/* LOCAL_LENGTH_ERR is 2 */
#define CQ_RES_RC_STATUS_LOCAL_LENGTH_ERR UINT32_C(0x2)
/* LOCAL_PROTECTION_ERR is 3 */
#define CQ_RES_RC_STATUS_LOCAL_PROTECTION_ERR UINT32_C(0x3)
/* LOCAL_QP_OPERATION_ERR is 4 */
#define CQ_RES_RC_STATUS_LOCAL_QP_OPERATION_ERR UINT32_C(0x4)
/* MEMORY_MGT_OPERATION_ERR is 5 */
#define CQ_RES_RC_STATUS_MEMORY_MGT_OPERATION_ERR UINT32_C(0x5)
/* REMOTE_INVALID_REQUEST_ERR is 6 */
#define CQ_RES_RC_STATUS_REMOTE_INVALID_REQUEST_ERR UINT32_C(0x6)
/* WORK_REQUEST_FLUSHED_ERR is 7 */
#define CQ_RES_RC_STATUS_WORK_REQUEST_FLUSHED_ERR UINT32_C(0x7)
/* HW_FLUSH_ERR is 8 */
#define CQ_RES_RC_STATUS_HW_FLUSH_ERR UINT32_C(0x8)
uint16_t flags;
/*
* This flag indicates that the completion is for a SRQ entry rather
* than for an RQ entry.
*/
#define CQ_RES_RC_FLAGS_SRQ UINT32_C(0x1)
/* CQE relates to RQ WQE. */
#define CQ_RES_RC_FLAGS_SRQ_RQ (UINT32_C(0x0) << 0)
/* CQE relates to SRQ WQE. */
#define CQ_RES_RC_FLAGS_SRQ_SRQ (UINT32_C(0x1) << 0)
#define CQ_RES_RC_FLAGS_SRQ_LAST CQ_RES_RC_FLAGS_SRQ_SRQ
/* Immediate data indicator */
#define CQ_RES_RC_FLAGS_IMM UINT32_C(0x2)
/* R_Key invalidate indicator */
#define CQ_RES_RC_FLAGS_INV UINT32_C(0x4)
#define CQ_RES_RC_FLAGS_RDMA UINT32_C(0x8)
/* CQE relates to an incoming Send request */
#define CQ_RES_RC_FLAGS_RDMA_SEND (UINT32_C(0x0) << 3)
/* CQE relates to incoming RDMA Write request */
#define CQ_RES_RC_FLAGS_RDMA_RDMA_WRITE (UINT32_C(0x1) << 3)
#define CQ_RES_RC_FLAGS_RDMA_LAST CQ_RES_RC_FLAGS_RDMA_RDMA_WRITE
uint32_t srq_or_rq_wr_id;
/*
* Opaque value from RQ or SRQ WQE. Used by driver/lib to reference the
* WQE in order to claim the received data and reuse the WQE space
*/
#define CQ_RES_RC_SRQ_OR_RQ_WR_ID_MASK UINT32_C(0xfffff)
#define CQ_RES_RC_SRQ_OR_RQ_WR_ID_SFT 0
#define CQ_RES_RC_RESERVED12_MASK UINT32_C(0xfff00000)
#define CQ_RES_RC_RESERVED12_SFT 20
} __attribute__((packed));
/* Responder UD CQE (32 bytes) */
struct cq_res_ud {
uint32_t length;
/* The length of the message's payload in bytes, stored in the SGEs */
#define CQ_RES_UD_LENGTH_MASK UINT32_C(0x3fff)
#define CQ_RES_UD_LENGTH_SFT 0
#define CQ_RES_UD_RESERVED18_MASK UINT32_C(0xffffc000)
#define CQ_RES_UD_RESERVED18_SFT 14
uint32_t imm_data;
/* Immediate data in case the imm_flag set. */
uint64_t qp_handle;
/*
* This is an application level ID used to identify the QP and its SQ
* and RQ.
*/
uint16_t src_mac[3];
/*
* Source MAC address for the UD message placed in the WQE that is
* completed by this CQE.
*/
uint16_t src_qp_low;
/* Lower 16b of the Source QP value from the DETH header. */
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_RES_UD_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_RES_UD_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_RES_UD_CQE_TYPE_SFT 1
/*
* Responder UD Completion - This is used for both RQ and SRQ
* completion for UD service QPs.
*/
#define CQ_RES_UD_CQE_TYPE_RES_UD (UINT32_C(0x2) << 1)
#define CQ_RES_UD_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_RES_UD_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/*
* This indicates that the completion is without error. All
* fields are valid.
*/
#define CQ_RES_UD_STATUS_OK UINT32_C(0x0)
/*
* This indicates that write access was not allowed for at least
* one of the SGEs in the WQE. This is a fatal error. Only the
* srq_or_rq_wr_id is field is valid.
*/
#define CQ_RES_UD_STATUS_LOCAL_ACCESS_ERROR UINT32_C(0x1)
/*
* This indicates that the packet was too long for the WQE
* provided on the SRQ/RQ. This is not a fatal error. All the
* fields are valid.
*/
#define CQ_RES_UD_STATUS_HW_LOCAL_LENGTH_ERR UINT32_C(0x2)
/* LOCAL_PROTECTION_ERR is 3 */
#define CQ_RES_UD_STATUS_LOCAL_PROTECTION_ERR UINT32_C(0x3)
/* LOCAL_QP_OPERATION_ERR is 4 */
#define CQ_RES_UD_STATUS_LOCAL_QP_OPERATION_ERR UINT32_C(0x4)
/* MEMORY_MGT_OPERATION_ERR is 5 */
#define CQ_RES_UD_STATUS_MEMORY_MGT_OPERATION_ERR UINT32_C(0x5)
/* WORK_REQUEST_FLUSHED_ERR is 7 */
#define CQ_RES_UD_STATUS_WORK_REQUEST_FLUSHED_ERR UINT32_C(0x7)
/* HW_FLUSH_ERR is 8 */
#define CQ_RES_UD_STATUS_HW_FLUSH_ERR UINT32_C(0x8)
uint16_t flags;
/*
* This flag indicates that the completion is for a SRQ entry rather
* than for an RQ entry.
*/
#define CQ_RES_UD_FLAGS_SRQ UINT32_C(0x1)
/* CQE relates to RQ WQE. */
#define CQ_RES_UD_FLAGS_SRQ_RQ (UINT32_C(0x0) << 0)
/* CQE relates to SRQ WQE. */
#define CQ_RES_UD_FLAGS_SRQ_SRQ (UINT32_C(0x1) << 0)
#define CQ_RES_UD_FLAGS_SRQ_LAST CQ_RES_UD_FLAGS_SRQ_SRQ
/* Immediate data indicator */
#define CQ_RES_UD_FLAGS_IMM UINT32_C(0x2)
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_MASK UINT32_C(0xc)
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_SFT 2
/* RoCEv1 Message */
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_V1 (UINT32_C(0x0) << 2)
/* RoCEv2 IPv4 Message */
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_V2IPV4 (UINT32_C(0x2) << 2)
/* RoCEv2 IPv6 Message */
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_V2IPV6 (UINT32_C(0x3) << 2)
#define CQ_RES_UD_FLAGS_ROCE_IP_VER_LAST CQ_RES_UD_FLAGS_ROCE_IP_VER_V2IPV6
uint32_t src_qp_high_srq_or_rq_wr_id;
/* Upper 8b of the Source QP value from the DETH header. */
/*
* Opaque value from RQ or SRQ WQE. Used by driver/lib to reference the
* WQE in order to claim the received data and reuse the WQE space
*/
#define CQ_RES_UD_SRQ_OR_RQ_WR_ID_MASK UINT32_C(0xfffff)
#define CQ_RES_UD_SRQ_OR_RQ_WR_ID_SFT 0
#define CQ_RES_UD_RESERVED4_MASK UINT32_C(0xf00000)
#define CQ_RES_UD_RESERVED4_SFT 20
/* Upper 8b of the Source QP value from the DETH header. */
#define CQ_RES_UD_SRC_QP_HIGH_MASK UINT32_C(0xff000000)
#define CQ_RES_UD_SRC_QP_HIGH_SFT 24
} __attribute__((packed));
/* Responder RawEth and QP1 CQE (32 bytes) */
struct cq_res_raweth_qp1 {
uint16_t length;
/* The length of the message's payload in bytes, stored in the SGEs */
#define CQ_RES_RAWETH_QP1_LENGTH_MASK UINT32_C(0x3fff)
#define CQ_RES_RAWETH_QP1_LENGTH_SFT 0
#define CQ_RES_RAWETH_QP1_RESERVED2_MASK UINT32_C(0xc000)
#define CQ_RES_RAWETH_QP1_RESERVED2_SFT 14
uint16_t raweth_qp1_flags;
/*
* When this bit is '1', it indicates a packet that has an error of some
* type. Type of error is indicated in raweth_qp1_errors.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ERROR UINT32_C(0x1)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_RESERVED5_1_MASK UINT32_C(0x3e)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_RESERVED5_1_SFT 1
/*
* This value indicates what the inner packet determined for the packet
* was.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_MASK UINT32_C(0x3c0)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_SFT 6
/* Not Known: Indicates that the packet type was not known. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_NOT_KNOWN (UINT32_C(0x0) << 6)
/*
* IP Packet: Indicates that the packet was an IP packet, but
* further classification was not possible.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_IP (UINT32_C(0x1) << 6)
/*
* TCP Packet: Indicates that the packet was IP and TCP. This
* indicates that the raweth_qp1_payload_offset field is valid.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_TCP (UINT32_C(0x2) << 6)
/*
* UDP Packet: Indicates that the packet was IP and UDP. This
* indicates that the raweth_qp1_payload_offset field is valid.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_UDP (UINT32_C(0x3) << 6)
/*
* FCoE Packet: Indicates that the packet was recognized as a
* FCoE. This also indicates that the raweth_qp1_payload_offset
* field is valid.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_FCOE (UINT32_C(0x4) << 6)
/*
* RoCE Packet: Indicates that the packet was recognized as a
* RoCE. This also indicates that the raweth_qp1_payload_offset
* field is valid.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_ROCE (UINT32_C(0x5) << 6)
/*
* ICMP Packet: Indicates that the packet was recognized as
* ICMP. This indicates that the raweth_qp1_payload_offset field
* is valid.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_ICMP (UINT32_C(0x7) << 6)
/*
* PtP packet wo/timestamp: Indicates that the packet was
* recognized as a PtP packet.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_PTP_WO_TIMESTAMP (UINT32_C(0x8) << 6)
/*
* PtP packet w/timestamp: Indicates that the packet was
* recognized as a PtP packet and that a timestamp was taken for
* the packet.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_PTP_W_TIMESTAMP (UINT32_C(0x9) << 6)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_LAST CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_ITYPE_PTP_W_TIMESTAMP
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_MASK UINT32_C(0x3ff)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS_SFT 0
#define CQ_RES_RAWETH_QP1_RESERVED6_MASK UINT32_C(0xfc00)
#define CQ_RES_RAWETH_QP1_RESERVED6_SFT 10
uint16_t raweth_qp1_errors;
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_RESERVED4_MASK UINT32_C(0xf)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_RESERVED4_SFT 0
/* This indicates that there was an error in the IP header checksum. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_IP_CS_ERROR UINT32_C(0x10)
/*
* This indicates that there was an error in the TCP, UDP or ICMP
* checksum.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_L4_CS_ERROR UINT32_C(0x20)
/*
* This indicates that there was an error in the tunnel IP header
* checksum.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_IP_CS_ERROR UINT32_C(0x40)
/* This indicates that there was an error in the tunnel UDP checksum. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_L4_CS_ERROR UINT32_C(0x80)
/*
* This indicates that there was a CRC error on either an FCoE or RoCE
* packet. The itype indicates the packet type.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_CRC_ERROR UINT32_C(0x100)
/*
* This indicates that there was an error in the tunnel portion of the
* packet when this field is non-zero.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_MASK UINT32_C(0xe00)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_SFT 9
/*
* No additional error occurred on the tunnel portion of the
* packet of the packet does not have a tunnel.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_NO_ERROR (UINT32_C(0x0) << 9)
/*
* Indicates that IP header version does not match expectation
* from L2 Ethertype for IPv4 and IPv6 in the tunnel header.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_L3_BAD_VERSION (UINT32_C(0x1) << 9)
/*
* Indicates that header length is out of range in the tunnel
* header. Valid for IPv4.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_L3_BAD_HDR_LEN (UINT32_C(0x2) << 9)
/*
* Indicates that the physical packet is shorter than that
* claimed by the PPPoE header length for a tunnel PPPoE packet.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_TUNNEL_TOTAL_ERROR (UINT32_C(0x3) << 9)
/*
* Indicates that physical packet is shorter than that claimed
* by the tunnel l3 header length. Valid for IPv4, or IPv6
* tunnel packet packets.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_IP_TOTAL_ERROR (UINT32_C(0x4) << 9)
/*
* Indicates that the physical packet is shorter than that
* claimed by the tunnel UDP header length for a tunnel UDP
* packet that is not fragmented.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_UDP_TOTAL_ERROR (UINT32_C(0x5) << 9)
/*
* indicates that the IPv4 TTL or IPv6 hop limit check have
* failed (e.g. TTL = 0) in the tunnel header. Valid for IPv4,
* and IPv6.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_L3_BAD_TTL (UINT32_C(0x6) << 9)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_LAST CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_T_PKT_ERROR_T_L3_BAD_TTL
/*
* This indicates that there was an error in the inner portion of the
* packet when this field is non-zero.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_MASK UINT32_C(0xf000)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_SFT 12
/*
* No additional error occurred on the tunnel portion of the
* packet of the packet does not have a tunnel.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_NO_ERROR (UINT32_C(0x0) << 12)
/*
* Indicates that IP header version does not match expectation
* from L2 Ethertype for IPv4 and IPv6 or that option other than
* VFT was parsed on FCoE packet.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L3_BAD_VERSION (UINT32_C(0x1) << 12)
/*
* indicates that header length is out of range. Valid for IPv4
* and RoCE
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L3_BAD_HDR_LEN (UINT32_C(0x2) << 12)
/*
* indicates that the IPv4 TTL or IPv6 hop limit check have
* failed (e.g. TTL = 0). Valid for IPv4, and IPv6
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L3_BAD_TTL (UINT32_C(0x3) << 12)
/*
* Indicates that physical packet is shorter than that claimed
* by the l3 header length. Valid for IPv4, IPv6 packet or RoCE
* packets.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_IP_TOTAL_ERROR (UINT32_C(0x4) << 12)
/*
* Indicates that the physical packet is shorter than that
* claimed by the UDP header length for a UDP packet that is not
* fragmented.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_UDP_TOTAL_ERROR (UINT32_C(0x5) << 12)
/*
* Indicates that TCP header length > IP payload. Valid for TCP
* packets only.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L4_BAD_HDR_LEN (UINT32_C(0x6) << 12)
/* Indicates that TCP header length < 5. Valid for TCP. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L4_BAD_HDR_LEN_TOO_SMALL (UINT32_C(0x7) << 12)
/*
* Indicates that TCP option headers result in a TCP header size
* that does not match data offset in TCP header. Valid for TCP.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L4_BAD_OPT_LEN (UINT32_C(0x8) << 12)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_LAST CQ_RES_RAWETH_QP1_RAWETH_QP1_ERRORS_PKT_ERROR_L4_BAD_OPT_LEN
uint16_t raweth_qp1_cfa_code;
/*
* This field identifies the CFA action rule that was used for this
* packet.
*/
uint64_t qp_handle;
/*
* This is an application level ID used to identify the QP and its SQ
* and RQ.
*/
uint32_t raweth_qp1_flags2;
/*
* This indicates that the ip checksum was calculated for the inner
* packet and that the ip_cs_error field indicates if there was an
* error.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_IP_CS_CALC UINT32_C(0x1)
/*
* This indicates that the TCP, UDP or ICMP checksum was calculated for
* the inner packet and that the l4_cs_error field indicates if there
* was an error.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_L4_CS_CALC UINT32_C(0x2)
/*
* This indicates that the ip checksum was calculated for the tunnel
* header and that the t_ip_cs_error field indicates if there was an
* error.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_T_IP_CS_CALC UINT32_C(0x4)
/*
* This indicates that the UDP checksum was calculated for the tunnel
* packet and that the t_l4_cs_error field indicates if there was an
* error.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_T_L4_CS_CALC UINT32_C(0x8)
/* This value indicates what format the raweth_qp1_metadata field is. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_MASK UINT32_C(0xf0)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_SFT 4
/* No metadata information. Value is zero. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_NONE (UINT32_C(0x0) << 4)
/*
* The raweth_qp1_metadata field contains the VLAN tag and TPID
* value. - raweth_qp1_metadata[11:0] contains the vlan VID
* value. - raweth_qp1_metadata[12] contains the vlan DE value.
* - raweth_qp1_metadata[15:13] contains the vlan PRI value. -
* raweth_qp1_metadata[31:16] contains the vlan TPID value.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_VLAN (UINT32_C(0x1) << 4)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_LAST CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_META_FORMAT_VLAN
/*
* This field indicates the IP type for the inner-most IP header. A
* value of '0' indicates IPv4. A value of '1' indicates IPv6. This
* value is only valid if itype indicates a packet with an IP header.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_FLAGS2_IP_TYPE UINT32_C(0x100)
uint32_t raweth_qp1_metadata;
/*
* This is data from the CFA block as indicated by the meta_format
* field.
*/
/* When meta_format=1, this value is the VLAN VID. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_VID_MASK UINT32_C(0xfff)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_VID_SFT 0
/* When meta_format=1, this value is the VLAN DE. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_DE UINT32_C(0x1000)
/* When meta_format=1, this value is the VLAN PRI. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_PRI_MASK UINT32_C(0xe000)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_PRI_SFT 13
/* When meta_format=1, this value is the VLAN TPID. */
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_TPID_MASK UINT32_C(0xffff0000)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_METADATA_TPID_SFT 16
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_RES_RAWETH_QP1_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_RES_RAWETH_QP1_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_RES_RAWETH_QP1_CQE_TYPE_SFT 1
/*
* Responder RawEth and QP1 Completion - This is used for RQ
* completion for RawEth service and QP1 service QPs.
*/
#define CQ_RES_RAWETH_QP1_CQE_TYPE_RES_RAWETH_QP1 (UINT32_C(0x3) << 1)
#define CQ_RES_RAWETH_QP1_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_RES_RAWETH_QP1_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/*
* This indicates that the completion is without error. All
* fields are valid.
*/
#define CQ_RES_RAWETH_QP1_STATUS_OK UINT32_C(0x0)
/*
* This indicates that write access was not allowed for at least
* one of the SGEs in the WQE. This is a fatal error. Only the
* srq_or_rq_wr_id is field is valid.
*/
#define CQ_RES_RAWETH_QP1_STATUS_LOCAL_ACCESS_ERROR UINT32_C(0x1)
/*
* This indicates that the packet was too long for the WQE
* provided on the RQ. This is not a fatal error. All the fields
* are valid.
*/
#define CQ_RES_RAWETH_QP1_STATUS_HW_LOCAL_LENGTH_ERR UINT32_C(0x2)
/* LOCAL_PROTECTION_ERR is 3 */
#define CQ_RES_RAWETH_QP1_STATUS_LOCAL_PROTECTION_ERR UINT32_C(0x3)
/* LOCAL_QP_OPERATION_ERR is 4 */
#define CQ_RES_RAWETH_QP1_STATUS_LOCAL_QP_OPERATION_ERR UINT32_C(0x4)
/* MEMORY_MGT_OPERATION_ERR is 5 */
#define CQ_RES_RAWETH_QP1_STATUS_MEMORY_MGT_OPERATION_ERR UINT32_C(0x5)
/* WORK_REQUEST_FLUSHED_ERR is 7 */
#define CQ_RES_RAWETH_QP1_STATUS_WORK_REQUEST_FLUSHED_ERR UINT32_C(0x7)
/* HW_FLUSH_ERR is 8 */
#define CQ_RES_RAWETH_QP1_STATUS_HW_FLUSH_ERR UINT32_C(0x8)
uint16_t flags;
/*
* This flag indicates that the completion is for a SRQ entry rather
* than for an RQ entry.
*/
#define CQ_RES_RAWETH_QP1_FLAGS_SRQ UINT32_C(0x1)
/* CQE relates to RQ WQE. */
#define CQ_RES_RAWETH_QP1_FLAGS_SRQ_RQ UINT32_C(0x0)
/* CQE relates to SRQ WQE. */
#define CQ_RES_RAWETH_QP1_FLAGS_SRQ_SRQ UINT32_C(0x1)
#define CQ_RES_RAWETH_QP1_FLAGS_SRQ_LAST CQ_RES_RAWETH_QP1_FLAGS_SRQ_SRQ
uint32_t raweth_qp1_payload_offset_srq_or_rq_wr_id;
/*
* This value indicates the offset in bytes from the beginning of the
* packet where the inner payload starts. This value is valid for TCP,
* UDP, FCoE, and RoCE packets. A value of zero indicates an offset of
* 256 bytes.
*/
/*
* Opaque value from RQ or SRQ WQE. Used by driver/lib to reference the
* WQE in order to claim the received data and reuse the WQE space
*/
#define CQ_RES_RAWETH_QP1_SRQ_OR_RQ_WR_ID_MASK UINT32_C(0xfffff)
#define CQ_RES_RAWETH_QP1_SRQ_OR_RQ_WR_ID_SFT 0
#define CQ_RES_RAWETH_QP1_RESERVED4_MASK UINT32_C(0xf00000)
#define CQ_RES_RAWETH_QP1_RESERVED4_SFT 20
/*
* This value indicates the offset in bytes from the beginning of the
* packet where the inner payload starts. This value is valid for TCP,
* UDP, FCoE, and RoCE packets. A value of zero indicates an offset of
* 256 bytes.
*/
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_PAYLOAD_OFFSET_MASK UINT32_C(0xff000000)
#define CQ_RES_RAWETH_QP1_RAWETH_QP1_PAYLOAD_OFFSET_SFT 24
} __attribute__((packed));
/* Terminal CQE (32 bytes) */
struct cq_terminal {
uint64_t qp_handle;
/*
* This is an application level ID used to identify the QP and its SQ
* and RQ.
*/
uint16_t sq_cons_idx;
/*
* Final SQ Consumer Index value. Any additional SQ WQEs will have to be
* completed by the user provider.
*/
uint16_t rq_cons_idx;
/*
* Final RQ Consumer Index value. Any additional RQ WQEs will have to be
* completed by the user provider.
*/
uint32_t reserved32_1;
uint64_t reserved64_3;
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_TERMINAL_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_TERMINAL_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_TERMINAL_CQE_TYPE_SFT 1
/*
* Terminal completion - This is used to indicate that no
* further completions will be made for this QP on this CQ.
*/
#define CQ_TERMINAL_CQE_TYPE_TERMINAL (UINT32_C(0xe) << 1)
#define CQ_TERMINAL_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_TERMINAL_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/* OK is 0 */
#define CQ_TERMINAL_STATUS_OK UINT32_C(0x0)
uint16_t reserved16;
uint32_t reserved32_2;
} __attribute__((packed));
/* Cutoff CQE (32 bytes) */
struct cq_cutoff {
uint64_t reserved64_1;
uint64_t reserved64_2;
uint64_t reserved64_3;
uint8_t cqe_type_toggle;
/*
* Indicate valid completion - written by the chip. Cumulus toggle this
* bit each time it finished consuming all PBL entries
*/
#define CQ_CUTOFF_TOGGLE UINT32_C(0x1)
/* This field defines the type of SQ WQE. */
#define CQ_CUTOFF_CQE_TYPE_MASK UINT32_C(0x1e)
#define CQ_CUTOFF_CQE_TYPE_SFT 1
/* Cut off CQE; for CQ resize see CQ and SRQ Resize */
#define CQ_CUTOFF_CQE_TYPE_CUT_OFF (UINT32_C(0xf) << 1)
#define CQ_CUTOFF_RESERVED3_MASK UINT32_C(0xe0)
#define CQ_CUTOFF_RESERVED3_SFT 5
uint8_t status;
/* This field indicates the status for the CQE. */
/* OK is 0 */
#define CQ_CUTOFF_STATUS_OK UINT32_C(0x0)
uint16_t reserved16;
uint32_t reserved32;
} __attribute__((packed));
/* Notification Queue (NQ) Structures */
/*
* Description: This completion indicates that the DBQ has reached the
* programmed threshold value.
*/
/* Base NQ Record (16 bytes) */
struct nq_base {
uint16_t info10_type;
/* info10 is 10 b */
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define NQ_BASE_TYPE_MASK UINT32_C(0x3f)
#define NQ_BASE_TYPE_SFT 0
/* CQ Notification */
#define NQ_BASE_TYPE_CQ_NOTIFICATION UINT32_C(0x30)
/* SRQ Threshold Event */
#define NQ_BASE_TYPE_SRQ_EVENT UINT32_C(0x32)
/* DBQ Threshold Event */
#define NQ_BASE_TYPE_DBQ_EVENT UINT32_C(0x34)
/* QP Async Notification */
#define NQ_BASE_TYPE_QP_EVENT UINT32_C(0x38)
/* Function Async Notification */
#define NQ_BASE_TYPE_FUNC_EVENT UINT32_C(0x3a)
/* info10 is 10 b */
#define NQ_BASE_INFO10_MASK UINT32_C(0xffc0)
#define NQ_BASE_INFO10_SFT 6
uint16_t info16;
/* info16 is 16 b */
uint32_t info32;
/* info32 is 32 b */
uint64_t info63_v;
/* info63 is 63 b */
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define NQ_BASE_V UINT32_C(0x1)
/* info63 is 63 b */
#define NQ_BASE_INFO63_MASK UINT32_C(0xfffffffe)
#define NQ_BASE_INFO63_SFT 1
} __attribute__((packed));
/* Completion Queue Notification (16 bytes) */
struct nq_cn {
uint16_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define NQ_CN_TYPE_MASK UINT32_C(0x3f)
#define NQ_CN_TYPE_SFT 0
/* CQ Notification */
#define NQ_CN_TYPE_CQ_NOTIFICATION UINT32_C(0x30)
#define NQ_CN_RESERVED9_MASK UINT32_C(0xffc0)
#define NQ_CN_RESERVED9_SFT 6
uint16_t reserved16;
uint32_t cq_handle_low;
/*
* This is an application level ID used to identify the CQ. This field
* carries the lower 32b of the value.
*/
uint32_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define NQ_CN_V UINT32_C(0x1)
#define NQ_CN_RESERVED31_MASK UINT32_C(0xfffffffe)
#define NQ_CN_RESERVED31_SFT 1
uint32_t cq_handle_high;
/*
* This is an application level ID used to identify the CQ. This field
* carries the upper 32b of the value.
*/
} __attribute__((packed));
/* SRQ Event Notification (16 bytes) */
struct nq_srq_event {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define NQ_SRQ_EVENT_TYPE_MASK UINT32_C(0x3f)
#define NQ_SRQ_EVENT_TYPE_SFT 0
/* SRQ Threshold Event */
#define NQ_SRQ_EVENT_TYPE_SRQ_EVENT UINT32_C(0x32)
#define NQ_SRQ_EVENT_RESERVED1_MASK UINT32_C(0xc0)
#define NQ_SRQ_EVENT_RESERVED1_SFT 6
uint8_t event;
/* This value define what type of async event has occurred on the SRQ. */
/* The threshold event has occurred on the specified SRQ. */
#define NQ_SRQ_EVENT_EVENT_SRQ_THRESHOLD_EVENT UINT32_C(0x1)
uint16_t reserved16;
uint32_t srq_handle_low;
/*
* This is the SRQ handle value for the queue that has reached it's
* event threshold. This field carries the lower 32b of the value.
*/
uint32_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define NQ_SRQ_EVENT_V UINT32_C(0x1)
#define NQ_SRQ_EVENT_RESERVED31_MASK UINT32_C(0xfffffffe)
#define NQ_SRQ_EVENT_RESERVED31_SFT 1
uint32_t srq_handle_high;
/*
* This is the SRQ handle value for the queue that has reached it's
* event threshold. This field carries the upper 32b of the value.
*/
} __attribute__((packed));
/* DBQ Async Event Notification (16 bytes) */
struct nq_dbq_event {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define NQ_DBQ_EVENT_TYPE_MASK UINT32_C(0x3f)
#define NQ_DBQ_EVENT_TYPE_SFT 0
/* DBQ Threshold Event */
#define NQ_DBQ_EVENT_TYPE_DBQ_EVENT UINT32_C(0x34)
#define NQ_DBQ_EVENT_RESERVED1_MASK UINT32_C(0xc0)
#define NQ_DBQ_EVENT_RESERVED1_SFT 6
uint8_t event;
/* This value define what type of action the driver should take. */
/*
* The driver should start writing dummy values to the the
* doorbell in an attempt to consume all the PCIE posted write
* resources and prevent doorbell overflow.
*/
#define NQ_DBQ_EVENT_EVENT_DBQ_THRESHOLD_EVENT UINT32_C(0x1)
uint16_t db_pfid;
/*
* This is the PFID of function that wrote the doorbell that crossed the
* async event threshold.
*/
#define NQ_DBQ_EVENT_DB_PFID_MASK UINT32_C(0xf)
#define NQ_DBQ_EVENT_DB_PFID_SFT 0
#define NQ_DBQ_EVENT_RESERVED12_MASK UINT32_C(0xfff0)
#define NQ_DBQ_EVENT_RESERVED12_SFT 4
uint32_t db_dpi;
/*
* This is the DPI of the doorbell write that crossed the async event
* threshold.
*/
#define NQ_DBQ_EVENT_DB_DPI_MASK UINT32_C(0xfffff)
#define NQ_DBQ_EVENT_DB_DPI_SFT 0
#define NQ_DBQ_EVENT_RESERVED12_2_MASK UINT32_C(0xfff00000)
#define NQ_DBQ_EVENT_RESERVED12_2_SFT 20
uint32_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define NQ_DBQ_EVENT_V UINT32_C(0x1)
#define NQ_DBQ_EVENT_RESERVED32_MASK UINT32_C(0xfffffffe)
#define NQ_DBQ_EVENT_RESERVED32_SFT 1
uint32_t db_type_db_xid;
/* DB 'type' field from doorbell that crossed the async event threshold. */
/*
* DB 'XID' field from doorbell that crossed the async event threshold.
* This is a QPID, SID, or CID, depending on the db_type field.
*/
#define NQ_DBQ_EVENT_DB_XID_MASK UINT32_C(0xfffff)
#define NQ_DBQ_EVENT_DB_XID_SFT 0
#define NQ_DBQ_EVENT_RESERVED8_MASK UINT32_C(0xff00000)
#define NQ_DBQ_EVENT_RESERVED8_SFT 20
/* DB 'type' field from doorbell that crossed the async event threshold. */
#define NQ_DBQ_EVENT_DB_TYPE_MASK UINT32_C(0xf0000000)
#define NQ_DBQ_EVENT_DB_TYPE_SFT 28
} __attribute__((packed));
/* Read Request/Response Queue Structures */
/*
* Description: This queue messages is used on the ORRQ to indicate output read
* requests to the RX side of the chip.
*/
/* Input Read Request Queue (IRRQ) Message (32 bytes) */
struct xrrq_irrq {
uint16_t credits_type;
/*
* The credit code calculated by Rx path when receiving the request. It
* will be placed in the syndrome credit code with the acks on first and
* last response.
*/
/* Type indication */
#define XRRQ_IRRQ_TYPE UINT32_C(0x1)
/* RDMA Read */
#define XRRQ_IRRQ_TYPE_READ_REQ UINT32_C(0x0)
/* Atomic */
#define XRRQ_IRRQ_TYPE_ATOMIC_REQ UINT32_C(0x1)
#define XRRQ_IRRQ_RESERVED10_MASK UINT32_C(0x7fe)
#define XRRQ_IRRQ_RESERVED10_SFT 1
/*
* The credit code calculated by Rx path when receiving the request. It
* will be placed in the syndrome credit code with the acks on first and
* last response.
*/
#define XRRQ_IRRQ_CREDITS_MASK UINT32_C(0xf800)
#define XRRQ_IRRQ_CREDITS_SFT 11
uint16_t reserved16;
uint32_t reserved32;
uint32_t psn;
/* The PSN of the outstanding incoming request */
#define XRRQ_IRRQ_PSN_MASK UINT32_C(0xffffff)
#define XRRQ_IRRQ_PSN_SFT 0
#define XRRQ_IRRQ_RESERVED8_1_MASK UINT32_C(0xff000000)
#define XRRQ_IRRQ_RESERVED8_1_SFT 24
uint32_t msn;
/*
* The value of QPC.pending_ack_msn after it is incremented as a result
* of receiving the read/atomic request. IRRQ.msn-1 will be placed in
* the MSN field of the first response and IRRQ.msn will placed in the
* MSN field of the last or only response.
*/
#define XRRQ_IRRQ_MSN_MASK UINT32_C(0xffffff)
#define XRRQ_IRRQ_MSN_SFT 0
#define XRRQ_IRRQ_RESERVED8_2_MASK UINT32_C(0xff000000)
#define XRRQ_IRRQ_RESERVED8_2_SFT 24
uint64_t va_or_atomic_result;
/*
* Virtual address on local host for RDMA READ In case of duplicate
* Atomic, the VA is not required to be validated, only the PSN is, thus
* this field is used to store the value returned in the Ack to the
* atomic request, and if duplicate arrives, this value is used again
* for resending the ack.
*/
uint32_t rdma_r_key;
/* The key to the MR/W in the request */
uint32_t length;
/*
* Length in bytes of the data requested. Length must be 8 if type is
* atomic.
*/
} __attribute__((packed));
/* Output Read Request Queue (ORRQ) Message (32 bytes) */
struct xrrq_orrq {
uint16_t num_sges_type;
/*
* Up to 6 SGEs. This value is 1 if type is atomic as one SGE is
* required to store Atomic response result field. 2 more bits allocated
* for future growth. Note that, if num_sges is 1 for an RDMA Read
* request, then the first_sge_phy_or_sing_sge_va, single_sge_l_key, and
* single_sge_size fields will be populated from the single SGE. If
* num_sges is 2 or more for an RDMA Read request, then the
* first_sge_phy_or_sing_sge_va field carries the physical address in
* host memory where the first sge is stored. The single_sge_l_key and
* single_sge_size fields are unused in this case. A special case is a
* zero-length, zero-sge RDMA read request WQE. In this situation,
* num_sges will be 1. However, first_sge_phy_or_sing_sge_va,
* single_sge_l_key, and single_sge_size will all be populated with
* zeros.
*/
/* Type indication */
#define XRRQ_ORRQ_TYPE UINT32_C(0x1)
/* RDMA Read */
#define XRRQ_ORRQ_TYPE_READ_REQ UINT32_C(0x0)
/* Atomic */
#define XRRQ_ORRQ_TYPE_ATOMIC_REQ UINT32_C(0x1)
#define XRRQ_ORRQ_RESERVED10_MASK UINT32_C(0x7fe)
#define XRRQ_ORRQ_RESERVED10_SFT 1
/*
* Up to 6 SGEs. This value is 1 if type is atomic as one SGE is
* required to store Atomic response result field. 2 more bits allocated
* for future growth. Note that, if num_sges is 1 for an RDMA Read
* request, then the first_sge_phy_or_sing_sge_va, single_sge_l_key, and
* single_sge_size fields will be populated from the single SGE. If
* num_sges is 2 or more for an RDMA Read request, then the
* first_sge_phy_or_sing_sge_va field carries the physical address in
* host memory where the first sge is stored. The single_sge_l_key and
* single_sge_size fields are unused in this case. A special case is a
* zero-length, zero-sge RDMA read request WQE. In this situation,
* num_sges will be 1. However, first_sge_phy_or_sing_sge_va,
* single_sge_l_key, and single_sge_size will all be populated with
* zeros.
*/
#define XRRQ_ORRQ_NUM_SGES_MASK UINT32_C(0xf800)
#define XRRQ_ORRQ_NUM_SGES_SFT 11
uint16_t reserved16;
uint32_t length;
/*
* Length in bytes of the data requested. Length must be 8 if type is
* atomic.
*/
uint32_t psn;
/* The PSN of the outstanding outgoing request */
#define XRRQ_ORRQ_PSN_MASK UINT32_C(0xffffff)
#define XRRQ_ORRQ_PSN_SFT 0
#define XRRQ_ORRQ_RESERVED8_1_MASK UINT32_C(0xff000000)
#define XRRQ_ORRQ_RESERVED8_1_SFT 24
uint32_t end_psn;
/*
* The expected last PSN on a response to this request where an ack with
* response, rather than just response, should arrive. If ack arrive
* with smaller PSN than end_psn then it is considered a NAK.
*/
#define XRRQ_ORRQ_END_PSN_MASK UINT32_C(0xffffff)
#define XRRQ_ORRQ_END_PSN_SFT 0
#define XRRQ_ORRQ_RESERVED8_2_MASK UINT32_C(0xff000000)
#define XRRQ_ORRQ_RESERVED8_2_SFT 24
uint64_t first_sge_phy_or_sing_sge_va;
/*
* If num_sges == 1 this is the va of that SGE. Otherwise, physical
* address to the first SGE specified by the WQE. Points to the first
* SGE in the Request's WQE in the SQ. It is assumed that WQE does not
* cross page boundaries! Driver is responsible to enforce that. SGEs
* are 16B aligned 0b0000 lsb added to get 64 bit address.
*/
uint32_t single_sge_l_key;
/* The L_Key of a single SGE if used */
uint32_t single_sge_size;
/* The size in bytes of the single SGE if used */
} __attribute__((packed));
/* Page Buffer List Memory Structures (PBL) */
/*
* Description: Page directory entries point to a page directories made up of
* PTE values.
*/
/* Page Table Entry (PTE) (8 bytes) */
struct ptu_pte {
uint64_t page_next_to_last_last_valid;
/*
* This is the upper bits of the physical page controlled by this PTE.
* If the page is larger than 4KB, then the unused lower bits of the
* page address should be zero.
*/
/*
* This field indicates if the PTE is valid. A value of '0' indicates
* that the page is not valid. A value of '1' indicates that the page is
* valid. A reference to an invalid page will return a PTU error.
*/
#define PTU_PTE_VALID UINT32_C(0x1)
/*
* This field is used only for "ring" PBLs that are used for SQ, RQ,
* SRQ, or CQ structures. For all other PBL structures, this bit should
* be zero. When this bit is '1', it indicates that the page pointed to
* by this PTE is the last page in the ring. A prefetch for the ring
* should use the first PTE in the PBL.
*/
#define PTU_PTE_LAST UINT32_C(0x2)
/*
* This field is used only for "ring" PBLs that are used for SQ, RQ,
* SRQ, or CQ structures. For all other PBL structures, this bit should
* be zero. When this bit is '1', it indicates that this is the next-to-
* last page of the PBL.
*/
#define PTU_PTE_NEXT_TO_LAST UINT32_C(0x4)
/* These bits should be programmed to zero. */
/*
* This is the upper bits of the physical page controlled by this PTE.
* If the page is larger than 4KB, then the unused lower bits of the
* page address should be zero.
*/
#define PTU_PTE_PAGE_MASK UINT32_C(0xfffff000)
#define PTU_PTE_PAGE_SFT 12
} __attribute__((packed));
/* Page Directory Entry (PDE) (8 bytes) */
struct ptu_pde {
uint64_t page_valid;
/*
* This is the upper bits of the physical page controlled by this PTE.
* If the page is larger than 4KB, then the unused lower bits of the
* page address should be zero.
*/
/*
* This field indicates if the PTE is valid. A value of '0' indicates
* that the page is not valid. A value of '1' indicates that the page is
* valid. A reference to an invalid page will return a PTU error.
*/
#define PTU_PDE_VALID UINT32_C(0x1)
/* These bits should be programmed to zero. */
/*
* This is the upper bits of the physical page controlled by this PTE.
* If the page is larger than 4KB, then the unused lower bits of the
* page address should be zero.
*/
#define PTU_PDE_PAGE_MASK UINT32_C(0xfffff000)
#define PTU_PDE_PAGE_SFT 12
} __attribute__((packed));
/* RoCE Fastpath Host Structures */
/*
* Note: This section documents the host structures used between RoCE state
* machines and RoCE drivers/libraries.
*/
/* hwrm_ver_get */
/*
* Description: This function is called by a driver to determine the HWRM
* interface version supported by the HWRM firmware, the version of HWRM
* firmware implementation, the name of HWRM firmware, the versions of other
* embedded firmwares, and the names of other embedded firmwares, etc. Any
* interface or firmware version with major = 0, minor = 0, and update = 0 shall
* be considered an invalid version.
*/
/* Input (24 bytes) */
struct hwrm_ver_get_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t hwrm_intf_maj;
/*
* This field represents the major version of HWRM interface
* specification supported by the driver HWRM implementation. The
* interface major version is intended to change only when non backward
* compatible changes are made to the HWRM interface specification.
*/
uint8_t hwrm_intf_min;
/*
* This field represents the minor version of HWRM interface
* specification supported by the driver HWRM implementation. A change
* in interface minor version is used to reflect significant backward
* compatible modification to HWRM interface specification. This can be
* due to addition or removal of functionality. HWRM interface
* specifications with the same major version but different minor
* versions are compatible.
*/
uint8_t hwrm_intf_upd;
/*
* This field represents the update version of HWRM interface
* specification supported by the driver HWRM implementation. The
* interface update version is used to reflect minor changes or bug
* fixes to a released HWRM interface specification.
*/
uint8_t unused_0[5];
} __attribute__((packed));
/* Output (128 bytes) */
struct hwrm_ver_get_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t hwrm_intf_maj;
/*
* This field represents the major version of HWRM interface
* specification supported by the HWRM implementation. The interface
* major version is intended to change only when non backward compatible
* changes are made to the HWRM interface specification. A HWRM
* implementation that is compliant with this specification shall
* provide value of 1 in this field.
*/
uint8_t hwrm_intf_min;
/*
* This field represents the minor version of HWRM interface
* specification supported by the HWRM implementation. A change in
* interface minor version is used to reflect significant backward
* compatible modification to HWRM interface specification. This can be
* due to addition or removal of functionality. HWRM interface
* specifications with the same major version but different minor
* versions are compatible. A HWRM implementation that is compliant with
* this specification shall provide value of 2 in this field.
*/
uint8_t hwrm_intf_upd;
/*
* This field represents the update version of HWRM interface
* specification supported by the HWRM implementation. The interface
* update version is used to reflect minor changes or bug fixes to a
* released HWRM interface specification. A HWRM implementation that is
* compliant with this specification shall provide value of 2 in this
* field.
*/
uint8_t hwrm_intf_rsvd;
uint8_t hwrm_fw_maj;
/*
* This field represents the major version of HWRM firmware. A change in
* firmware major version represents a major firmware release.
*/
uint8_t hwrm_fw_min;
/*
* This field represents the minor version of HWRM firmware. A change in
* firmware minor version represents significant firmware functionality
* changes.
*/
uint8_t hwrm_fw_bld;
/*
* This field represents the build version of HWRM firmware. A change in
* firmware build version represents bug fixes to a released firmware.
*/
uint8_t hwrm_fw_rsvd;
/*
* This field is a reserved field. This field can be used to represent
* firmware branches or customer specific releases tied to a specific
* (major,minor,update) version of the HWRM firmware.
*/
uint8_t mgmt_fw_maj;
/*
* This field represents the major version of mgmt firmware. A change in
* major version represents a major release.
*/
uint8_t mgmt_fw_min;
/*
* This field represents the minor version of mgmt firmware. A change in
* minor version represents significant functionality changes.
*/
uint8_t mgmt_fw_bld;
/*
* This field represents the build version of mgmt firmware. A change in
* update version represents bug fixes.
*/
uint8_t mgmt_fw_rsvd;
/*
* This field is a reserved field. This field can be used to represent
* firmware branches or customer specific releases tied to a specific
* (major,minor,update) version
*/
uint8_t netctrl_fw_maj;
/*
* This field represents the major version of network control firmware.
* A change in major version represents a major release.
*/
uint8_t netctrl_fw_min;
/*
* This field represents the minor version of network control firmware.
* A change in minor version represents significant functionality
* changes.
*/
uint8_t netctrl_fw_bld;
/*
* This field represents the build version of network control firmware.
* A change in update version represents bug fixes.
*/
uint8_t netctrl_fw_rsvd;
/*
* This field is a reserved field. This field can be used to represent
* firmware branches or customer specific releases tied to a specific
* (major,minor,update) version
*/
uint32_t dev_caps_cfg;
/*
* This field is used to indicate device's capabilities and
* configurations.
*/
/*
* If set to 1, then secure firmware update behavior is supported. If
* set to 0, then secure firmware update behavior is not supported.
*/
#define HWRM_VER_GET_OUTPUT_DEV_CAPS_CFG_SECURE_FW_UPD_SUPPORTED UINT32_C(0x1)
/*
* If set to 1, then firmware based DCBX agent is supported. If set to
* 0, then firmware based DCBX agent capability is not supported on this
* device.
*/
#define HWRM_VER_GET_OUTPUT_DEV_CAPS_CFG_FW_DCBX_AGENT_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, then HWRM short command format is supported. If set to
* 0, then HWRM short command format is not supported.
*/
#define HWRM_VER_GET_OUTPUT_DEV_CAPS_CFG_SHORT_CMD_SUPPORTED UINT32_C(0x4)
/*
* If set to 1, then HWRM short command format is required. If set to 0,
* then HWRM short command format is not required.
*/
#define HWRM_VER_GET_OUTPUT_DEV_CAPS_CFG_SHORT_CMD_REQUIRED UINT32_C(0x8)
uint8_t roce_fw_maj;
/*
* This field represents the major version of RoCE firmware. A change in
* major version represents a major release.
*/
uint8_t roce_fw_min;
/*
* This field represents the minor version of RoCE firmware. A change in
* minor version represents significant functionality changes.
*/
uint8_t roce_fw_bld;
/*
* This field represents the build version of RoCE firmware. A change in
* update version represents bug fixes.
*/
uint8_t roce_fw_rsvd;
/*
* This field is a reserved field. This field can be used to represent
* firmware branches or customer specific releases tied to a specific
* (major,minor,update) version
*/
char hwrm_fw_name[16];
/*
* This field represents the name of HWRM FW (ASCII chars with NULL at
* the end).
*/
char mgmt_fw_name[16];
/*
* This field represents the name of mgmt FW (ASCII chars with NULL at
* the end).
*/
char netctrl_fw_name[16];
/*
* This field represents the name of network control firmware (ASCII
* chars with NULL at the end).
*/
uint32_t reserved2[4];
/*
* This field is reserved for future use. The responder should set it to
* 0. The requester should ignore this field.
*/
char roce_fw_name[16];
/*
* This field represents the name of RoCE FW (ASCII chars with NULL at
* the end).
*/
uint16_t chip_num;
/* This field returns the chip number. */
uint8_t chip_rev;
/* This field returns the revision of chip. */
uint8_t chip_metal;
/* This field returns the chip metal number. */
uint8_t chip_bond_id;
/* This field returns the bond id of the chip. */
uint8_t chip_platform_type;
/*
* This value indicates the type of platform used for chip
* implementation.
*/
/* ASIC */
#define HWRM_VER_GET_OUTPUT_CHIP_PLATFORM_TYPE_ASIC UINT32_C(0x0)
/* FPGA platform of the chip. */
#define HWRM_VER_GET_OUTPUT_CHIP_PLATFORM_TYPE_FPGA UINT32_C(0x1)
/* Palladium platform of the chip. */
#define HWRM_VER_GET_OUTPUT_CHIP_PLATFORM_TYPE_PALLADIUM UINT32_C(0x2)
uint16_t max_req_win_len;
/*
* This field returns the maximum value of request window that is
* supported by the HWRM. The request window is mapped into device
* address space using MMIO.
*/
uint16_t max_resp_len;
/* This field returns the maximum value of response buffer in bytes. */
uint16_t def_req_timeout;
/* This field returns the default request timeout value in milliseconds. */
uint8_t init_pending;
/* This field will indicate if any subsystems is not fully initialized. */
/*
* If set to 1, device is not ready. If set to 0, device is ready to
* accept all HWRM commands.
*/
#define HWRM_VER_GET_OUTPUT_INIT_PENDING_DEV_NOT_RDY UINT32_C(0x1)
uint8_t unused_0;
uint8_t unused_1;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_reset */
/*
* Description: This command resets a hardware function (PCIe function) and
* frees any resources used by the function. This command shall be initiated by
* the driver after an FLR has occurred to prepare the function for re-use. This
* command may also be initiated by a driver prior to doing it's own
* configuration. This command puts the function into the reset state. In the
* reset state, global and port related features of the chip are not available.
*/
/*
* Note: This command will reset a function that has already been disabled or
* idled. The command returns all the resources owned by the function so a new
* driver may allocate and configure resources normally.
*/
/* Input (24 bytes) */
struct hwrm_func_reset_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the vf_id_valid field to be configured. */
#define HWRM_FUNC_RESET_INPUT_ENABLES_VF_ID_VALID UINT32_C(0x1)
uint16_t vf_id;
/*
* The ID of the VF that this PF is trying to reset. Only the parent PF
* shall be allowed to reset a child VF. A parent PF driver shall use
* this field only when a specific child VF is requested to be reset.
*/
uint8_t func_reset_level;
/* This value indicates the level of a function reset. */
/*
* Reset the caller function and its children VFs (if any). If
* no children functions exist, then reset the caller function
* only.
*/
#define HWRM_FUNC_RESET_INPUT_FUNC_RESET_LEVEL_RESETALL UINT32_C(0x0)
/* Reset the caller function only */
#define HWRM_FUNC_RESET_INPUT_FUNC_RESET_LEVEL_RESETME UINT32_C(0x1)
/*
* Reset all children VFs of the caller function driver if the
* caller is a PF driver. It is an error to specify this level
* by a VF driver. It is an error to specify this level by a PF
* driver with no children VFs.
*/
#define HWRM_FUNC_RESET_INPUT_FUNC_RESET_LEVEL_RESETCHILDREN UINT32_C(0x2)
/*
* Reset a specific VF of the caller function driver if the
* caller is the parent PF driver. It is an error to specify
* this level by a VF driver. It is an error to specify this
* level by a PF driver that is not the parent of the VF that is
* being requested to reset.
*/
#define HWRM_FUNC_RESET_INPUT_FUNC_RESET_LEVEL_RESETVF UINT32_C(0x3)
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_reset_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_getfid */
/*
* Description: This command returns the FID value for the function. If a valid
* pci_id is provided, then this function returns fid for that PCI function.
* Otherwise, it returns FID of the requesting function. This value is needed to
* configure Rings and MSI-X vectors so their DMA operations appear correctly on
* the PCI bus. For PF-HWRM commands, there is no need for FID. Similarly there
* is no need for FID for VF-HWRM commands. In the PF-VF communication, only PF
* needs to know FIDs.
*/
/* Input (24 bytes) */
struct hwrm_func_getfid_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the pci_id field to be configured. */
#define HWRM_FUNC_GETFID_INPUT_ENABLES_PCI_ID UINT32_C(0x1)
uint16_t pci_id;
/*
* This value is the PCI ID of the queried function. If ARI is enabled,
* then it is Bus Number (8b):Function Number(8b). Otherwise, it is Bus
* Number (8b):Device Number (5b):Function Number(3b).
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_getfid_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t fid;
/*
* FID value. This value is used to identify operations on the PCI bus
* as belonging to a particular PCI function.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vf_alloc */
/*
* Description: This command is used to allocate requested number of virtual
* functions on a physical function. It will return the FID value of the first
* virtual function. The FIDs of the remaining virtual functions can be derived
* by sequentially incrementing the FID value of the first VF. This command
* supports the following models for VF allocation: # Allocation of one or more
* VFs from a PF without specifying the first VF ID # Allocation of multiple VFs
* from a PF starting with a specific VF # Allocation of a specific VF from a PF
* If this command is called on a virtual function or a physical function that
* is not enabled for SR-IOV, the HWRM shall return an error. The VF IDs
* returned by this function remain valid after the VF is disabled or reset.
*/
/* Input (24 bytes) */
struct hwrm_func_vf_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the first_vf_id field to be configured. */
#define HWRM_FUNC_VF_ALLOC_INPUT_ENABLES_FIRST_VF_ID UINT32_C(0x1)
uint16_t first_vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint16_t num_vfs;
/* The number of virtual functions requested. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vf_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t first_vf_id;
/* The ID of the first VF allocated. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vf_free */
/*
* Description: This command will free allocated virtual functions on a physical
* function. If this command is called on a virtual function or a physical
* function that is not enabled for SR-IOV, the HWRM shall return an error.
* After the successful completion of this command, the VF IDs of the VFs that
* are freed on the PF are invalid.
*/
/* Input (24 bytes) */
struct hwrm_func_vf_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the first_vf_id field to be configured. */
#define HWRM_FUNC_VF_FREE_INPUT_ENABLES_FIRST_VF_ID UINT32_C(0x1)
uint16_t first_vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint16_t num_vfs;
/*
* The number of virtual functions requested. 0xFFFF - Cleanup all
* children of this PF.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vf_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vf_cfg */
/*
* Description: This command allows configuration of a VF by its driver. If this
* function is called by a PF driver, then the HWRM shall fail this command. If
* guest VLAN and/or MAC address are provided in this command, then the HWRM
* shall set up appropriate MAC/VLAN filters for the VF that is being
* configured. A VF driver should set VF MTU/MRU using this command prior to
* allocating RX VNICs or TX rings for the corresponding VF.
*/
/* Input (32 bytes) */
struct hwrm_func_vf_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the mtu field to be configured. */
#define HWRM_FUNC_VF_CFG_INPUT_ENABLES_MTU UINT32_C(0x1)
/* This bit must be '1' for the guest_vlan field to be configured. */
#define HWRM_FUNC_VF_CFG_INPUT_ENABLES_GUEST_VLAN UINT32_C(0x2)
/* This bit must be '1' for the async_event_cr field to be configured. */
#define HWRM_FUNC_VF_CFG_INPUT_ENABLES_ASYNC_EVENT_CR UINT32_C(0x4)
/* This bit must be '1' for the dflt_mac_addr field to be configured. */
#define HWRM_FUNC_VF_CFG_INPUT_ENABLES_DFLT_MAC_ADDR UINT32_C(0x8)
uint16_t mtu;
/*
* The maximum transmission unit requested on the function. The HWRM
* should make sure that the mtu of the function does not exceed the mtu
* of the physical port that this function is associated with. In
* addition to requesting mtu per function, it is possible to configure
* mtu per transmit ring. By default, the mtu of each transmit ring
* associated with a function is equal to the mtu of the function. The
* HWRM should make sure that the mtu of each transmit ring that is
* assigned to a function has a valid mtu.
*/
uint16_t guest_vlan;
/*
* The guest VLAN for the function being configured. This field's format
* is same as 802.1Q Tag's Tag Control Information (TCI) format that
* includes both Priority Code Point (PCP) and VLAN Identifier (VID).
*/
uint16_t async_event_cr;
/*
* ID of the target completion ring for receiving asynchronous event
* completions. If this field is not valid, then the HWRM shall use the
* default completion ring of the function that is being configured as
* the target completion ring for providing any asynchronous event
* completions for that function. If this field is valid, then the HWRM
* shall use the completion ring identified by this ID as the target
* completion ring for providing any asynchronous event completions for
* the function that is being configured.
*/
uint8_t dflt_mac_addr[6];
/*
* This value is the current MAC address requested by the VF driver to
* be configured on this VF. A value of 00-00-00-00-00-00 indicates no
* MAC address configuration is requested by the VF driver. The parent
* PF driver may reject or overwrite this MAC address.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vf_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_qcaps */
/*
* Description: This command returns capabilities of a function. The input FID
* value is used to indicate what function is being queried. This allows a
* physical function driver to query virtual functions that are children of the
* physical function. The output FID value is needed to configure Rings and
* MSI-X vectors so their DMA operations appear correctly on the PCI bus.
*/
/* Input (24 bytes) */
struct hwrm_func_qcaps_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being queried. 0xFF... (All Fs)
* if the query is for the requesting function.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (80 bytes) */
struct hwrm_func_qcaps_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t fid;
/*
* FID value. This value is used to identify operations on the PCI bus
* as belonging to a particular PCI function.
*/
uint16_t port_id;
/*
* Port ID of port that this function is associated with. Valid only for
* the PF. 0xFF... (All Fs) if this function is not associated with any
* port. 0xFF... (All Fs) if this function is called from a VF.
*/
uint32_t flags;
/* If 1, then Push mode is supported on this function. */
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_PUSH_MODE_SUPPORTED UINT32_C(0x1)
/* If 1, then the global MSI-X auto-masking is enabled for the device. */
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_GLOBAL_MSIX_AUTOMASKING UINT32_C(0x2)
/*
* If 1, then the Precision Time Protocol (PTP) processing is supported
* on this function. The HWRM should enable PTP on only a single
* Physical Function (PF) per port.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_PTP_SUPPORTED UINT32_C(0x4)
/*
* If 1, then RDMA over Converged Ethernet (RoCE) v1 is supported on
* this function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_ROCE_V1_SUPPORTED UINT32_C(0x8)
/*
* If 1, then RDMA over Converged Ethernet (RoCE) v2 is supported on
* this function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_ROCE_V2_SUPPORTED UINT32_C(0x10)
/*
* If 1, then control and configuration of WoL magic packet are
* supported on this function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_WOL_MAGICPKT_SUPPORTED UINT32_C(0x20)
/*
* If 1, then control and configuration of bitmap pattern packet are
* supported on this function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_WOL_BMP_SUPPORTED UINT32_C(0x40)
/*
* If set to 1, then the control and configuration of rate limit of an
* allocated TX ring on the queried function is supported.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_TX_RING_RL_SUPPORTED UINT32_C(0x80)
/*
* If 1, then control and configuration of minimum and maximum
* bandwidths are supported on the queried function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_TX_BW_CFG_SUPPORTED UINT32_C(0x100)
/*
* If the query is for a VF, then this flag shall be ignored. If this
* query is for a PF and this flag is set to 1, then the PF has the
* capability to set the rate limits on the TX rings of its children
* VFs. If this query is for a PF and this flag is set to 0, then the PF
* does not have the capability to set the rate limits on the TX rings
* of its children VFs.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_VF_TX_RING_RL_SUPPORTED UINT32_C(0x200)
/*
* If the query is for a VF, then this flag shall be ignored. If this
* query is for a PF and this flag is set to 1, then the PF has the
* capability to set the minimum and/or maximum bandwidths for its
* children VFs. If this query is for a PF and this flag is set to 0,
* then the PF does not have the capability to set the minimum or
* maximum bandwidths for its children VFs.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_VF_BW_CFG_SUPPORTED UINT32_C(0x400)
/*
* Standard TX Ring mode is used for the allocation of TX ring and
* underlying scheduling resources that allow bandwidth reservation and
* limit settings on the queried function. If set to 1, then standard TX
* ring mode is supported on the queried function. If set to 0, then
* standard TX ring mode is not available on the queried function.
*/
#define HWRM_FUNC_QCAPS_OUTPUT_FLAGS_STD_TX_RING_MODE_SUPPORTED UINT32_C(0x800)
uint8_t mac_address[6];
/*
* This value is current MAC address configured for this function. A
* value of 00-00-00-00-00-00 indicates no MAC address is currently
* configured.
*/
uint16_t max_rsscos_ctx;
/*
* The maximum number of RSS/COS contexts that can be allocated to the
* function.
*/
uint16_t max_cmpl_rings;
/*
* The maximum number of completion rings that can be allocated to the
* function.
*/
uint16_t max_tx_rings;
/*
* The maximum number of transmit rings that can be allocated to the
* function.
*/
uint16_t max_rx_rings;
/*
* The maximum number of receive rings that can be allocated to the
* function.
*/
uint16_t max_l2_ctxs;
/*
* The maximum number of L2 contexts that can be allocated to the
* function.
*/
uint16_t max_vnics;
/* The maximum number of VNICs that can be allocated to the function. */
uint16_t first_vf_id;
/*
* The identifier for the first VF enabled on a PF. This is valid only
* on the PF with SR-IOV enabled. 0xFF... (All Fs) if this command is
* called on a PF with SR-IOV disabled or on a VF.
*/
uint16_t max_vfs;
/*
* The maximum number of VFs that can be allocated to the function. This
* is valid only on the PF with SR-IOV enabled. 0xFF... (All Fs) if this
* command is called on a PF with SR-IOV disabled or on a VF.
*/
uint16_t max_stat_ctx;
/*
* The maximum number of statistic contexts that can be allocated to the
* function.
*/
uint32_t max_encap_records;
/*
* The maximum number of Encapsulation records that can be offloaded by
* this function.
*/
uint32_t max_decap_records;
/*
* The maximum number of decapsulation records that can be offloaded by
* this function.
*/
uint32_t max_tx_em_flows;
/*
* The maximum number of Exact Match (EM) flows that can be offloaded by
* this function on the TX side.
*/
uint32_t max_tx_wm_flows;
/*
* The maximum number of Wildcard Match (WM) flows that can be offloaded
* by this function on the TX side.
*/
uint32_t max_rx_em_flows;
/*
* The maximum number of Exact Match (EM) flows that can be offloaded by
* this function on the RX side.
*/
uint32_t max_rx_wm_flows;
/*
* The maximum number of Wildcard Match (WM) flows that can be offloaded
* by this function on the RX side.
*/
uint32_t max_mcast_filters;
/*
* The maximum number of multicast filters that can be supported by this
* function on the RX side.
*/
uint32_t max_flow_id;
/*
* The maximum value of flow_id that can be supported in completion
* records.
*/
uint32_t max_hw_ring_grps;
/*
* The maximum number of HW ring groups that can be supported on this
* function.
*/
uint16_t max_sp_tx_rings;
/*
* The maximum number of strict priority transmit rings that can be
* allocated to the function. This number indicates the maximum number
* of TX rings that can be assigned strict priorities out of the maximum
* number of TX rings that can be allocated (max_tx_rings) to the
* function.
*/
uint8_t unused_0;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_qcfg */
/*
* Description: This command returns the current configuration of a function.
* The input FID value is used to indicate what function is being queried. This
* allows a physical function driver to query virtual functions that are
* children of the physical function. The output FID value is needed to
* configure Rings and MSI-X vectors so their DMA operations appear correctly on
* the PCI bus. This command should be called by every driver after
* 'hwrm_func_cfg' to get the actual number of resources allocated by the HWRM.
* The values returned by hwrm_func_qcfg are the values the driver shall use.
* These values may be different than what was originally requested in the
* 'hwrm_func_cfg' command.
*/
/* Input (24 bytes) */
struct hwrm_func_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being queried. 0xFF... (All Fs)
* if the query is for the requesting function.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (72 bytes) */
struct hwrm_func_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t fid;
/*
* FID value. This value is used to identify operations on the PCI bus
* as belonging to a particular PCI function.
*/
uint16_t port_id;
/*
* Port ID of port that this function is associated with. 0xFF... (All
* Fs) if this function is not associated with any port.
*/
uint16_t vlan;
/*
* This value is the current VLAN setting for this function. The value
* of 0 for this field indicates no priority tagging or VLAN is used.
* This field's format is same as 802.1Q Tag's Tag Control Information
* (TCI) format that includes both Priority Code Point (PCP) and VLAN
* Identifier (VID).
*/
uint16_t flags;
/*
* If 1, then magic packet based Out-Of-Box WoL is enabled on the port
* associated with this function.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_OOB_WOL_MAGICPKT_ENABLED UINT32_C(0x1)
/*
* If 1, then bitmap pattern based Out-Of-Box WoL packet is enabled on
* the port associated with this function.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_OOB_WOL_BMP_ENABLED UINT32_C(0x2)
/*
* If set to 1, then FW based DCBX agent is enabled and running on the
* port associated with this function. If set to 0, then DCBX agent is
* not running in the firmware.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_FW_DCBX_AGENT_ENABLED UINT32_C(0x4)
/*
* Standard TX Ring mode is used for the allocation of TX ring and
* underlying scheduling resources that allow bandwidth reservation and
* limit settings on the queried function. If set to 1, then standard TX
* ring mode is enabled on the queried function. If set to 0, then the
* standard TX ring mode is disabled on the queried function. In this
* extended TX ring resource mode, the minimum and maximum bandwidth
* settings are not supported to allow the allocation of TX rings to
* span multiple scheduler nodes.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_STD_TX_RING_MODE_ENABLED UINT32_C(0x8)
/*
* If set to 1 then FW based LLDP agent is enabled and running on the
* port associated with this function. If set to 0 then the LLDP agent
* is not running in the firmware.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_FW_LLDP_AGENT_ENABLED UINT32_C(0x10)
/*
* If set to 1, then multi-host mode is active for this function. If set
* to 0, then multi-host mode is inactive for this function or not
* applicable for this device.
*/
#define HWRM_FUNC_QCFG_OUTPUT_FLAGS_MULTI_HOST UINT32_C(0x20)
uint8_t mac_address[6];
/*
* This value is current MAC address configured for this function. A
* value of 00-00-00-00-00-00 indicates no MAC address is currently
* configured.
*/
uint16_t pci_id;
/*
* This value is current PCI ID of this function. If ARI is enabled,
* then it is Bus Number (8b):Function Number(8b). Otherwise, it is Bus
* Number (8b):Device Number (4b):Function Number(4b). If multi-host
* mode is active, the 4 lsb will indicate the PF index for this
* function.
*/
uint16_t alloc_rsscos_ctx;
/* The number of RSS/COS contexts currently allocated to the function. */
uint16_t alloc_cmpl_rings;
/*
* The number of completion rings currently allocated to the function.
* This does not include the rings allocated to any children functions
* if any.
*/
uint16_t alloc_tx_rings;
/*
* The number of transmit rings currently allocated to the function.
* This does not include the rings allocated to any children functions
* if any.
*/
uint16_t alloc_rx_rings;
/*
* The number of receive rings currently allocated to the function. This
* does not include the rings allocated to any children functions if
* any.
*/
uint16_t alloc_l2_ctx;
/* The allocated number of L2 contexts to the function. */
uint16_t alloc_vnics;
/* The allocated number of vnics to the function. */
uint16_t mtu;
/*
* The maximum transmission unit of the function. For rings allocated on
* this function, this default value is used if ring MTU is not
* specified.
*/
uint16_t mru;
/*
* The maximum receive unit of the function. For vnics allocated on this
* function, this default value is used if vnic MRU is not specified.
*/
uint16_t stat_ctx_id;
/* The statistics context assigned to a function. */
uint8_t port_partition_type;
/*
* The HWRM shall return Unknown value for this field when this command
* is used to query VF's configuration.
*/
/* Single physical function */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_SPF UINT32_C(0x0)
/* Multiple physical functions */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_MPFS UINT32_C(0x1)
/* Network Partitioning 1.0 */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_NPAR1_0 UINT32_C(0x2)
/* Network Partitioning 1.5 */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_NPAR1_5 UINT32_C(0x3)
/* Network Partitioning 2.0 */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_NPAR2_0 UINT32_C(0x4)
/* Unknown */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PARTITION_TYPE_UNKNOWN UINT32_C(0xff)
uint8_t port_pf_cnt;
/*
* This field will indicate number of physical functions on this
* port_partition. HWRM shall return unavail (i.e. value of 0) for this
* field when this command is used to query VF's configuration or from
* older firmware that doesn't support this field.
*/
/* number of PFs is not available */
#define HWRM_FUNC_QCFG_OUTPUT_PORT_PF_CNT_UNAVAIL UINT32_C(0x0)
uint16_t dflt_vnic_id;
/* The default VNIC ID assigned to a function that is being queried. */
uint8_t unused_0;
uint8_t unused_1;
uint32_t min_bw;
/*
* Minimum BW allocated for this function. The HWRM will translate this
* value into byte counter and time interval used for the scheduler
* inside the device. A value of 0 indicates the minimum bandwidth is
* not configured.
*/
/* The bandwidth value. */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_SCALE_LAST HWRM_FUNC_QCFG_OUTPUT_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_LAST HWRM_FUNC_QCFG_OUTPUT_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t max_bw;
/*
* Maximum BW allocated for this function. The HWRM will translate this
* value into byte counter and time interval used for the scheduler
* inside the device. A value of 0 indicates that the maximum bandwidth
* is not configured.
*/
/* The bandwidth value. */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_SCALE_LAST HWRM_FUNC_QCFG_OUTPUT_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_LAST HWRM_FUNC_QCFG_OUTPUT_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t evb_mode;
/*
* This value indicates the Edge virtual bridge mode for the domain that
* this function belongs to.
*/
/* No Edge Virtual Bridging (EVB) */
#define HWRM_FUNC_QCFG_OUTPUT_EVB_MODE_NO_EVB UINT32_C(0x0)
/* Virtual Ethernet Bridge (VEB) */
#define HWRM_FUNC_QCFG_OUTPUT_EVB_MODE_VEB UINT32_C(0x1)
/* Virtual Ethernet Port Aggregator (VEPA) */
#define HWRM_FUNC_QCFG_OUTPUT_EVB_MODE_VEPA UINT32_C(0x2)
uint8_t unused_2;
uint16_t alloc_vfs;
/*
* The number of VFs that are allocated to the function. This is valid
* only on the PF with SR-IOV enabled. 0xFF... (All Fs) if this command
* is called on a PF with SR-IOV disabled or on a VF.
*/
uint32_t alloc_mcast_filters;
/*
* The number of allocated multicast filters for this function on the RX
* side.
*/
uint32_t alloc_hw_ring_grps;
/* The number of allocated HW ring groups for this function. */
uint16_t alloc_sp_tx_rings;
/*
* The number of strict priority transmit rings out of currently
* allocated TX rings to the function (alloc_tx_rings).
*/
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vlan_qcfg */
/*
* Description: This command should be called by PF driver to get the current
* C-TAG, S-TAG and correcponsing PCP and TPID values configured for the
* function.
*/
/* Input (24 bytes) */
struct hwrm_func_vlan_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being configured. If set to
* 0xFF... (All Fs), then the configuration is for the requesting
* function.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (40 bytes) */
struct hwrm_func_vlan_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
uint16_t stag_vid;
/* S-TAG VLAN identifier configured for the function. */
uint8_t stag_pcp;
/* S-TAG PCP value configured for the function. */
uint8_t unused_4;
uint16_t stag_tpid; /* big endian */
/*
* S-TAG TPID value configured for the function. This field is specified
* in network byte order.
*/
uint16_t ctag_vid;
/* C-TAG VLAN identifier configured for the function. */
uint8_t ctag_pcp;
/* C-TAG PCP value configured for the function. */
uint8_t unused_5;
uint16_t ctag_tpid; /* big endian */
/*
* C-TAG TPID value configured for the function. This field is specified
* in network byte order.
*/
uint32_t rsvd2;
/* Future use. */
uint32_t rsvd3;
/* Future use. */
uint32_t unused_6;
} __attribute__((packed));
/* hwrm_func_vlan_cfg */
/*
* Description: This command allows PF driver to configure C-TAG, S-TAG and
* corresponding PCP and TPID values for a function.
*/
/* Input (48 bytes) */
struct hwrm_func_vlan_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being configured. If set to
* 0xFF... (All Fs), then the configuration is for the requesting
* function.
*/
uint8_t unused_0;
uint8_t unused_1;
uint32_t enables;
/* This bit must be '1' for the stag_vid field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_STAG_VID UINT32_C(0x1)
/* This bit must be '1' for the ctag_vid field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_CTAG_VID UINT32_C(0x2)
/* This bit must be '1' for the stag_pcp field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_STAG_PCP UINT32_C(0x4)
/* This bit must be '1' for the ctag_pcp field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_CTAG_PCP UINT32_C(0x8)
/* This bit must be '1' for the stag_tpid field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_STAG_TPID UINT32_C(0x10)
/* This bit must be '1' for the ctag_tpid field to be configured. */
#define HWRM_FUNC_VLAN_CFG_INPUT_ENABLES_CTAG_TPID UINT32_C(0x20)
uint16_t stag_vid;
/* S-TAG VLAN identifier configured for the function. */
uint8_t stag_pcp;
/* S-TAG PCP value configured for the function. */
uint8_t unused_2;
uint16_t stag_tpid; /* big endian */
/*
* S-TAG TPID value configured for the function. This field is specified
* in network byte order.
*/
uint16_t ctag_vid;
/* C-TAG VLAN identifier configured for the function. */
uint8_t ctag_pcp;
/* C-TAG PCP value configured for the function. */
uint8_t unused_3;
uint16_t ctag_tpid; /* big endian */
/*
* C-TAG TPID value configured for the function. This field is specified
* in network byte order.
*/
uint32_t rsvd1;
/* Future use. */
uint32_t rsvd2;
/* Future use. */
uint32_t unused_4;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vlan_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_cfg */
/*
* Description: This command allows configuration of a PF by the corresponding
* PF driver. This command also allows configuration of a child VF by its parent
* PF driver. The input FID value is used to indicate what function is being
* configured. This allows a PF driver to configure the PF owned by itself or a
* virtual function that is a child of the PF. This command allows to reserve
* resources for a VF by its parent PF. To reverse the process, the command
* should be called with all enables flags cleared for resources. This will free
* allocated resources for the VF and return them to the resource pool. If this
* command is requested by a VF driver to configure or reserve resources, then
* the HWRM shall fail this command. If default MAC address and/or VLAN are
* provided in this command, then the HWRM shall set up appropriate MAC/VLAN
* filters for the function that is being configured. If source properties
* checks are enabled and default MAC address and/or IP address are provided in
* this command, then the HWRM shall set appropriate source property checks
* based on provided MAC and/or IP addresses. The parent PF driver should not
* set MTU/MRU for a VF using this command. This is to allow MTU/MRU setting by
* the VF driver. If the MTU or MRU for a VF is set by the PF driver, then the
* HWRM should ignore it. A function's MTU/MRU should be set prior to allocating
* RX VNICs or TX rings. A PF driver calls hwrm_func_cfg to allocate resources
* for itself or its children VFs. All function drivers shall call hwrm_func_cfg
* to reserve resources. A request to hwrm_func_cfg may not be fully granted;
* that is, a request for resources may be larger than what can be supported by
* the device and the HWRM will allocate the best set of resources available,
* but that may be less than requested. If all the amounts requested could not
* be fulfilled, the HWRM shall allocate what it could and return a status code
* of success. A function driver should call hwrm_func_qcfg immediately after
* hwrm_func_cfg to determine what resources were assigned to the configured
* function. A call by a PF driver to hwrm_func_cfg to allocate resources for
* itself shall only allocate resources for the PF driver to use, not for its
* children VFs. Likewise, a call to hwrm_func_qcfg shall return the resources
* available for the PF driver to use, not what is available to its children
* VFs.
*/
/* Input (88 bytes) */
struct hwrm_func_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being configured. If set to
* 0xFF... (All Fs), then the the configuration is for the requesting
* function.
*/
uint8_t unused_0;
uint8_t unused_1;
uint32_t flags;
/*
* When this bit is '1', the function is disabled with source MAC
* address check. This is an anti-spoofing check. If this flag is set,
* then the function shall be configured to disallow transmission of
* frames with the source MAC address that is configured for this
* function.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_SRC_MAC_ADDR_CHECK_DISABLE UINT32_C(0x1)
/*
* When this bit is '1', the function is enabled with source MAC address
* check. This is an anti-spoofing check. If this flag is set, then the
* function shall be configured to allow transmission of frames with the
* source MAC address that is configured for this function.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_SRC_MAC_ADDR_CHECK_ENABLE UINT32_C(0x2)
/* reserved */
#define HWRM_FUNC_CFG_INPUT_FLAGS_RSVD_MASK UINT32_C(0x1fc)
#define HWRM_FUNC_CFG_INPUT_FLAGS_RSVD_SFT 2
/*
* Standard TX Ring mode is used for the allocation of TX ring and
* underlying scheduling resources that allow bandwidth reservation and
* limit settings on the queried function. If set to 1, then standard TX
* ring mode is requested to be enabled on the function being
* configured.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_STD_TX_RING_MODE_ENABLE UINT32_C(0x200)
/*
* Standard TX Ring mode is used for the allocation of TX ring and
* underlying scheduling resources that allow bandwidth reservation and
* limit settings on the queried function. If set to 1, then the
* standard TX ring mode is requested to be disabled on the function
* being configured. In this extended TX ring resource mode, the minimum
* and maximum bandwidth settings are not supported to allow the
* allocation of TX rings to span multiple scheduler nodes.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_STD_TX_RING_MODE_DISABLE UINT32_C(0x400)
/*
* If this bit is set, virtual mac address configured in this command
* will be persistent over warm boot.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_VIRT_MAC_PERSIST UINT32_C(0x800)
/*
* This bit only applies to the VF. If this bit is set, the statistic
* context counters will not be cleared when the statistic context is
* freed or a function reset is called on VF. This bit will be cleared
* when the PF is unloaded or a function reset is called on the PF.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_NO_AUTOCLEAR_STATISTIC UINT32_C(0x1000)
/*
* This bit requests that the firmware test to see if all the assets
* requested in this command (i.e. number of TX rings) are available.
* The firmware will return an error if the requested assets are not
* available. The firwmare will NOT reserve the assets if they are
* available.
*/
#define HWRM_FUNC_CFG_INPUT_FLAGS_TX_ASSETS_TEST UINT32_C(0x2000)
uint32_t enables;
/* This bit must be '1' for the mtu field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_MTU UINT32_C(0x1)
/* This bit must be '1' for the mru field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_MRU UINT32_C(0x2)
/* This bit must be '1' for the num_rsscos_ctxs field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_RSSCOS_CTXS UINT32_C(0x4)
/* This bit must be '1' for the num_cmpl_rings field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_CMPL_RINGS UINT32_C(0x8)
/* This bit must be '1' for the num_tx_rings field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_TX_RINGS UINT32_C(0x10)
/* This bit must be '1' for the num_rx_rings field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_RX_RINGS UINT32_C(0x20)
/* This bit must be '1' for the num_l2_ctxs field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_L2_CTXS UINT32_C(0x40)
/* This bit must be '1' for the num_vnics field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_VNICS UINT32_C(0x80)
/* This bit must be '1' for the num_stat_ctxs field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_STAT_CTXS UINT32_C(0x100)
/* This bit must be '1' for the dflt_mac_addr field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_DFLT_MAC_ADDR UINT32_C(0x200)
/* This bit must be '1' for the dflt_vlan field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_DFLT_VLAN UINT32_C(0x400)
/* This bit must be '1' for the dflt_ip_addr field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_DFLT_IP_ADDR UINT32_C(0x800)
/* This bit must be '1' for the min_bw field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_MIN_BW UINT32_C(0x1000)
/* This bit must be '1' for the max_bw field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_MAX_BW UINT32_C(0x2000)
/* This bit must be '1' for the async_event_cr field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_ASYNC_EVENT_CR UINT32_C(0x4000)
/*
* This bit must be '1' for the vlan_antispoof_mode field to be
* configured.
*/
#define HWRM_FUNC_CFG_INPUT_ENABLES_VLAN_ANTISPOOF_MODE UINT32_C(0x8000)
/*
* This bit must be '1' for the allowed_vlan_pris field to be
* configured.
*/
#define HWRM_FUNC_CFG_INPUT_ENABLES_ALLOWED_VLAN_PRIS UINT32_C(0x10000)
/* This bit must be '1' for the evb_mode field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_EVB_MODE UINT32_C(0x20000)
/*
* This bit must be '1' for the num_mcast_filters field to be
* configured.
*/
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_MCAST_FILTERS UINT32_C(0x40000)
/* This bit must be '1' for the num_hw_ring_grps field to be configured. */
#define HWRM_FUNC_CFG_INPUT_ENABLES_NUM_HW_RING_GRPS UINT32_C(0x80000)
uint16_t mtu;
/*
* The maximum transmission unit of the function. The HWRM should make
* sure that the mtu of the function does not exceed the mtu of the
* physical port that this function is associated with. In addition to
* configuring mtu per function, it is possible to configure mtu per
* transmit ring. By default, the mtu of each transmit ring associated
* with a function is equal to the mtu of the function. The HWRM should
* make sure that the mtu of each transmit ring that is assigned to a
* function has a valid mtu.
*/
uint16_t mru;
/*
* The maximum receive unit of the function. The HWRM should make sure
* that the mru of the function does not exceed the mru of the physical
* port that this function is associated with. In addition to
* configuring mru per function, it is possible to configure mru per
* vnic. By default, the mru of each vnic associated with a function is
* equal to the mru of the function. The HWRM should make sure that the
* mru of each vnic that is assigned to a function has a valid mru.
*/
uint16_t num_rsscos_ctxs;
/* The number of RSS/COS contexts requested for the function. */
uint16_t num_cmpl_rings;
/*
* The number of completion rings requested for the function. This does
* not include the rings allocated to any children functions if any.
*/
uint16_t num_tx_rings;
/*
* The number of transmit rings requested for the function. This does
* not include the rings allocated to any children functions if any.
*/
uint16_t num_rx_rings;
/*
* The number of receive rings requested for the function. This does not
* include the rings allocated to any children functions if any.
*/
uint16_t num_l2_ctxs;
/* The requested number of L2 contexts for the function. */
uint16_t num_vnics;
/* The requested number of vnics for the function. */
uint16_t num_stat_ctxs;
/* The requested number of statistic contexts for the function. */
uint16_t num_hw_ring_grps;
/*
* The number of HW ring groups that should be reserved for this
* function.
*/
uint8_t dflt_mac_addr[6];
/* The default MAC address for the function being configured. */
uint16_t dflt_vlan;
/*
* The default VLAN for the function being configured. This field's
* format is same as 802.1Q Tag's Tag Control Information (TCI) format
* that includes both Priority Code Point (PCP) and VLAN Identifier
* (VID).
*/
uint32_t dflt_ip_addr[4]; /* big endian */
/*
* The default IP address for the function being configured. This
* address is only used in enabling source property check.
*/
uint32_t min_bw;
/*
* Minimum BW allocated for this function. The HWRM will translate this
* value into byte counter and time interval used for the scheduler
* inside the device.
*/
/* The bandwidth value. */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_FUNC_CFG_INPUT_MIN_BW_SCALE_LAST HWRM_FUNC_CFG_INPUT_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_LAST HWRM_FUNC_CFG_INPUT_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t max_bw;
/*
* Maximum BW allocated for this function. The HWRM will translate this
* value into byte counter and time interval used for the scheduler
* inside the device.
*/
/* The bandwidth value. */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_FUNC_CFG_INPUT_MAX_BW_SCALE_LAST HWRM_FUNC_CFG_INPUT_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_LAST HWRM_FUNC_CFG_INPUT_MAX_BW_BW_VALUE_UNIT_INVALID
uint16_t async_event_cr;
/*
* ID of the target completion ring for receiving asynchronous event
* completions. If this field is not valid, then the HWRM shall use the
* default completion ring of the function that is being configured as
* the target completion ring for providing any asynchronous event
* completions for that function. If this field is valid, then the HWRM
* shall use the completion ring identified by this ID as the target
* completion ring for providing any asynchronous event completions for
* the function that is being configured.
*/
uint8_t vlan_antispoof_mode;
/* VLAN Anti-spoofing mode. */
/* No VLAN anti-spoofing checks are enabled */
#define HWRM_FUNC_CFG_INPUT_VLAN_ANTISPOOF_MODE_NOCHECK UINT32_C(0x0)
/* Validate VLAN against the configured VLAN(s) */
#define HWRM_FUNC_CFG_INPUT_VLAN_ANTISPOOF_MODE_VALIDATE_VLAN UINT32_C(0x1)
/* Insert VLAN if it does not exist, otherwise discard */
#define HWRM_FUNC_CFG_INPUT_VLAN_ANTISPOOF_MODE_INSERT_IF_VLANDNE UINT32_C(0x2)
/* Insert VLAN if it does not exist, override VLAN if it exists */
#define HWRM_FUNC_CFG_INPUT_VLAN_ANTISPOOF_MODE_INSERT_OR_OVERRIDE_VLAN UINT32_C(0x3)
uint8_t allowed_vlan_pris;
/*
* This bit field defines VLAN PRIs that are allowed on this function.
* If nth bit is set, then VLAN PRI n is allowed on this function.
*/
uint8_t evb_mode;
/*
* The HWRM shall allow a PF driver to change EVB mode for the partition
* it belongs to. The HWRM shall not allow a VF driver to change the EVB
* mode. The HWRM shall take into account the switching of EVB mode from
* one to another and reconfigure hardware resources as appropriately.
* The switching from VEB to VEPA mode requires the disabling of the
* loopback traffic. Additionally, source knock outs are handled
* differently in VEB and VEPA modes.
*/
/* No Edge Virtual Bridging (EVB) */
#define HWRM_FUNC_CFG_INPUT_EVB_MODE_NO_EVB UINT32_C(0x0)
/* Virtual Ethernet Bridge (VEB) */
#define HWRM_FUNC_CFG_INPUT_EVB_MODE_VEB UINT32_C(0x1)
/* Virtual Ethernet Port Aggregator (VEPA) */
#define HWRM_FUNC_CFG_INPUT_EVB_MODE_VEPA UINT32_C(0x2)
uint8_t unused_2;
uint16_t num_mcast_filters;
/*
* The number of multicast filters that should be reserved for this
* function on the RX side.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_qstats */
/*
* Description: This command returns statistics of a function. The input FID
* value is used to indicate what function is being queried. This allows a
* physical function driver to query virtual functions that are children of the
* physical function. The HWRM shall return any unsupported counter with a value
* of 0xFFFFFFFF for 32-bit counters and 0xFFFFFFFFFFFFFFFF for 64-bit counters.
*/
/* Input (24 bytes) */
struct hwrm_func_qstats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being queried. 0xFF... (All Fs)
* if the query is for the requesting function.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (176 bytes) */
struct hwrm_func_qstats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t tx_ucast_pkts;
/* Number of transmitted unicast packets on the function. */
uint64_t tx_mcast_pkts;
/* Number of transmitted multicast packets on the function. */
uint64_t tx_bcast_pkts;
/* Number of transmitted broadcast packets on the function. */
uint64_t tx_discard_pkts;
/*
* Number of transmitted packets that were discarded due to internal NIC
* resource problems. For transmit, this can only happen if TMP is
* configured to allow dropping in HOL blocking conditions, which is not
* a normal configuration.
*/
uint64_t tx_drop_pkts;
/*
* Number of dropped packets on transmit path on the function. These are
* packets that have been marked for drop by the TE CFA block or are
* packets that exceeded the transmit MTU limit for the function.
*/
uint64_t tx_ucast_bytes;
/* Number of transmitted bytes for unicast traffic on the function. */
uint64_t tx_mcast_bytes;
/* Number of transmitted bytes for multicast traffic on the function. */
uint64_t tx_bcast_bytes;
/* Number of transmitted bytes for broadcast traffic on the function. */
uint64_t rx_ucast_pkts;
/* Number of received unicast packets on the function. */
uint64_t rx_mcast_pkts;
/* Number of received multicast packets on the function. */
uint64_t rx_bcast_pkts;
/* Number of received broadcast packets on the function. */
uint64_t rx_discard_pkts;
/*
* Number of received packets that were discarded on the function due to
* resource limitations. This can happen for 3 reasons. # The BD used
* for the packet has a bad format. # There were no BDs available in the
* ring for the packet. # There were no BDs available on-chip for the
* packet.
*/
uint64_t rx_drop_pkts;
/*
* Number of dropped packets on received path on the function. These are
* packets that have been marked for drop by the RE CFA.
*/
uint64_t rx_ucast_bytes;
/* Number of received bytes for unicast traffic on the function. */
uint64_t rx_mcast_bytes;
/* Number of received bytes for multicast traffic on the function. */
uint64_t rx_bcast_bytes;
/* Number of received bytes for broadcast traffic on the function. */
uint64_t rx_agg_pkts;
/* Number of aggregated unicast packets on the function. */
uint64_t rx_agg_bytes;
/* Number of aggregated unicast bytes on the function. */
uint64_t rx_agg_events;
/* Number of aggregation events on the function. */
uint64_t rx_agg_aborts;
/* Number of aborted aggregations on the function. */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_clr_stats */
/*
* Description: This command clears statistics of a function. The input FID
* value is used to indicate what function's statistics is being cleared. This
* allows a physical function driver to clear statistics of virtual functions
* that are children of the physical function.
*/
/* Input (24 bytes) */
struct hwrm_func_clr_stats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function. 0xFF... (All Fs) if the query is for the
* requesting function.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_clr_stats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vf_resc_free */
/* Description: This command frees resources of a vf. */
/* Input (24 bytes) */
struct hwrm_func_vf_resc_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vf_resc_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_vf_vnic_ids_query */
/* Description: This command is used to query vf vnic ids. */
/* Input (32 bytes) */
struct hwrm_func_vf_vnic_ids_query_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint8_t unused_0;
uint8_t unused_1;
uint32_t max_vnic_id_cnt;
/* Max number of vnic ids in vnic id table */
uint64_t vnic_id_tbl_addr;
/* This is the address for VF VNIC ID table */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_vf_vnic_ids_query_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t vnic_id_cnt;
/* Actual number of vnic ids Each VNIC ID is written as a 32-bit number. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_drv_rgtr */
/*
* Description: This command is used by the function driver to register its
* information with the HWRM. A function driver shall implement this command. A
* function driver shall use this command during the driver initialization right
* after the HWRM version discovery and default ring resources allocation.
*/
/* Input (80 bytes) */
struct hwrm_func_drv_rgtr_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', the function driver is requesting all requests
* from its children VF drivers to be forwarded to itself. This flag can
* only be set by the PF driver. If a VF driver sets this flag, it
* should be ignored by the HWRM.
*/
#define HWRM_FUNC_DRV_RGTR_INPUT_FLAGS_FWD_ALL_MODE UINT32_C(0x1)
/*
* When this bit is '1', the function is requesting none of the requests
* from its children VF drivers to be forwarded to itself. This flag can
* only be set by the PF driver. If a VF driver sets this flag, it
* should be ignored by the HWRM.
*/
#define HWRM_FUNC_DRV_RGTR_INPUT_FLAGS_FWD_NONE_MODE UINT32_C(0x2)
uint32_t enables;
/* This bit must be '1' for the os_type field to be configured. */
#define HWRM_FUNC_DRV_RGTR_INPUT_ENABLES_OS_TYPE UINT32_C(0x1)
/* This bit must be '1' for the ver field to be configured. */
#define HWRM_FUNC_DRV_RGTR_INPUT_ENABLES_VER UINT32_C(0x2)
/* This bit must be '1' for the timestamp field to be configured. */
#define HWRM_FUNC_DRV_RGTR_INPUT_ENABLES_TIMESTAMP UINT32_C(0x4)
/* This bit must be '1' for the vf_req_fwd field to be configured. */
#define HWRM_FUNC_DRV_RGTR_INPUT_ENABLES_VF_REQ_FWD UINT32_C(0x8)
/* This bit must be '1' for the async_event_fwd field to be configured. */
#define HWRM_FUNC_DRV_RGTR_INPUT_ENABLES_ASYNC_EVENT_FWD UINT32_C(0x10)
uint16_t os_type;
/*
* This value indicates the type of OS. The values are based on
* CIM_OperatingSystem.mof file as published by the DMTF.
*/
/* Unknown */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_UNKNOWN UINT32_C(0x0)
/* Other OS not listed below. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_OTHER UINT32_C(0x1)
/* MSDOS OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_MSDOS UINT32_C(0xe)
/* Windows OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_WINDOWS UINT32_C(0x12)
/* Solaris OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_SOLARIS UINT32_C(0x1d)
/* Linux OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_LINUX UINT32_C(0x24)
/* FreeBSD OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_FREEBSD UINT32_C(0x2a)
/* VMware ESXi OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_ESXI UINT32_C(0x68)
/* Microsoft Windows 8 64-bit OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_WIN864 UINT32_C(0x73)
/* Microsoft Windows Server 2012 R2 OS. */
#define HWRM_FUNC_DRV_RGTR_INPUT_OS_TYPE_WIN2012R2 UINT32_C(0x74)
uint8_t ver_maj;
/* This is the major version of the driver. */
uint8_t ver_min;
/* This is the minor version of the driver. */
uint8_t ver_upd;
/* This is the update version of the driver. */
uint8_t unused_0;
uint16_t unused_1;
uint32_t timestamp;
/*
* This is a 32-bit timestamp provided by the driver for keep alive. The
* timestamp is in multiples of 1ms.
*/
uint32_t unused_2;
uint32_t vf_req_fwd[8];
/*
* This is a 256-bit bit mask provided by the PF driver for letting the
* HWRM know what commands issued by the VF driver to the HWRM should be
* forwarded to the PF driver. Nth bit refers to the Nth req_type.
* Setting Nth bit to 1 indicates that requests from the VF driver with
* req_type equal to N shall be forwarded to the parent PF driver. This
* field is not valid for the VF driver.
*/
uint32_t async_event_fwd[8];
/*
* This is a 256-bit bit mask provided by the function driver (PF or VF
* driver) to indicate the list of asynchronous event completions to be
* forwarded. Nth bit refers to the Nth event_id. Setting Nth bit to 1
* by the function driver shall result in the HWRM forwarding
* asynchronous event completion with event_id equal to N. If all bits
* are set to 0 (value of 0), then the HWRM shall not forward any
* asynchronous event completion to this function driver.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_drv_rgtr_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_drv_unrgtr */
/*
* Description: This command is used by the function driver to un register with
* the HWRM. A function driver shall implement this command. A function driver
* shall use this command during the driver unloading.
*/
/* Input (24 bytes) */
struct hwrm_func_drv_unrgtr_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', the function driver is notifying the HWRM to
* prepare for the shutdown.
*/
#define HWRM_FUNC_DRV_UNRGTR_INPUT_FLAGS_PREPARE_FOR_SHUTDOWN UINT32_C(0x1)
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_drv_unrgtr_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_buf_rgtr */
/*
* Description: This command is used by the PF driver to register buffers used
* in the PF-VF communication with the HWRM. The PF driver uses this command to
* register buffers for each PF-VF channel. A parent PF may issue this command
* per child VF. If VF ID is not valid, then this command is used to register
* buffers for all children VFs of the PF.
*/
/* Input (128 bytes) */
struct hwrm_func_buf_rgtr_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the vf_id field to be configured. */
#define HWRM_FUNC_BUF_RGTR_INPUT_ENABLES_VF_ID UINT32_C(0x1)
/* This bit must be '1' for the err_buf_addr field to be configured. */
#define HWRM_FUNC_BUF_RGTR_INPUT_ENABLES_ERR_BUF_ADDR UINT32_C(0x2)
uint16_t vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint16_t req_buf_num_pages;
/* This field represents the number of pages used for request buffer(s). */
uint16_t req_buf_page_size;
/* This field represents the page size used for request buffer(s). */
/* 16 bytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_16B UINT32_C(0x4)
/* 4 Kbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_4K UINT32_C(0xc)
/* 8 Kbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_8K UINT32_C(0xd)
/* 64 Kbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_64K UINT32_C(0x10)
/* 2 Mbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_2M UINT32_C(0x15)
/* 4 Mbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_4M UINT32_C(0x16)
/* 1 Gbytes */
#define HWRM_FUNC_BUF_RGTR_INPUT_REQ_BUF_PAGE_SIZE_1G UINT32_C(0x1e)
uint16_t req_buf_len;
/* The length of the request buffer per VF in bytes. */
uint16_t resp_buf_len;
/* The length of the response buffer in bytes. */
uint8_t unused_0;
uint8_t unused_1;
uint64_t req_buf_page_addr0;
/* This field represents the page address of page #0. */
uint64_t req_buf_page_addr1;
/* This field represents the page address of page #1. */
uint64_t req_buf_page_addr2;
/* This field represents the page address of page #2. */
uint64_t req_buf_page_addr3;
/* This field represents the page address of page #3. */
uint64_t req_buf_page_addr4;
/* This field represents the page address of page #4. */
uint64_t req_buf_page_addr5;
/* This field represents the page address of page #5. */
uint64_t req_buf_page_addr6;
/* This field represents the page address of page #6. */
uint64_t req_buf_page_addr7;
/* This field represents the page address of page #7. */
uint64_t req_buf_page_addr8;
/* This field represents the page address of page #8. */
uint64_t req_buf_page_addr9;
/* This field represents the page address of page #9. */
uint64_t error_buf_addr;
/*
* This field is used to receive the error reporting from the chipset.
* Only applicable for PFs.
*/
uint64_t resp_buf_addr;
/* This field is used to receive the response forwarded by the HWRM. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_buf_rgtr_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_buf_unrgtr */
/*
* Description: This command is used by the PF driver to unregister buffers used
* in the PF-VF communication with the HWRM. The PF driver uses this command to
* unregister buffers for PF-VF communication. A parent PF may issue this
* command to unregister buffers for communication between the PF and a specific
* VF. If the VF ID is not valid, then this command is used to unregister
* buffers used for communications with all children VFs of the PF.
*/
/* Input (24 bytes) */
struct hwrm_func_buf_unrgtr_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the vf_id field to be configured. */
#define HWRM_FUNC_BUF_UNRGTR_INPUT_ENABLES_VF_ID UINT32_C(0x1)
uint16_t vf_id;
/*
* This value is used to identify a Virtual Function (VF). The scope of
* VF ID is local within a PF.
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_buf_unrgtr_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_func_drv_qver */
/*
* Description: This command is used to query the version of the driver. Any
* driver version with major = 0, minor = 0, and update = 0 shall be considered
* an invalid or unknown version.
*/
/* Input (24 bytes) */
struct hwrm_func_drv_qver_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t reserved;
/* Reserved for future use */
uint16_t fid;
/*
* Function ID of the function that is being queried. 0xFF... (All Fs)
* if the query is for the requesting function.
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_func_drv_qver_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t os_type;
/*
* This value indicates the type of OS. The values are based on
* CIM_OperatingSystem.mof file as published by the DMTF.
*/
/* Unknown */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_UNKNOWN UINT32_C(0x0)
/* Other OS not listed below. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_OTHER UINT32_C(0x1)
/* MSDOS OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_MSDOS UINT32_C(0xe)
/* Windows OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_WINDOWS UINT32_C(0x12)
/* Solaris OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_SOLARIS UINT32_C(0x1d)
/* Linux OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_LINUX UINT32_C(0x24)
/* FreeBSD OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_FREEBSD UINT32_C(0x2a)
/* VMware ESXi OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_ESXI UINT32_C(0x68)
/* Microsoft Windows 8 64-bit OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_WIN864 UINT32_C(0x73)
/* Microsoft Windows Server 2012 R2 OS. */
#define HWRM_FUNC_DRV_QVER_OUTPUT_OS_TYPE_WIN2012R2 UINT32_C(0x74)
uint8_t ver_maj;
/* This is the major version of the driver. */
uint8_t ver_min;
/* This is the minor version of the driver. */
uint8_t ver_upd;
/* This is the update version of the driver. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_phy_cfg */
/*
* Description: This command configures the PHY device for the port. It allows
* setting of the most generic settings for the PHY. The HWRM shall complete
* this command as soon as PHY settings are configured. They may not be applied
* when the command response is provided. A VF driver shall not be allowed to
* configure PHY using this command. In a network partition mode, a PF driver
* shall not be allowed to configure PHY using this command.
*/
/* Input (56 bytes) */
struct hwrm_port_phy_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is set to '1', the PHY for the port shall be reset. #
* If this bit is set to 1, then the HWRM shall reset the PHY after
* applying PHY configuration changes specified in this command. # In
* order to guarantee that PHY configuration changes specified in this
* command take effect, the HWRM client should set this flag to 1. # If
* this bit is not set to 1, then the HWRM may reset the PHY depending
* on the current PHY configuration and settings specified in this
* command.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_RESET_PHY UINT32_C(0x1)
/* deprecated bit. Do not use!!! */
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_DEPRECATED UINT32_C(0x2)
/*
* When this bit is set to '1', the link shall be forced to the
* force_link_speed value. When this bit is set to '1', the HWRM client
* should not enable any of the auto negotiation related fields
* represented by auto_XXX fields in this command. When this bit is set
* to '1' and the HWRM client has enabled a auto_XXX field in this
* command, then the HWRM shall ignore the enabled auto_XXX field. When
* this bit is set to zero, the link shall be allowed to autoneg.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FORCE UINT32_C(0x4)
/*
* When this bit is set to '1', the auto-negotiation process shall be
* restarted on the link.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_RESTART_AUTONEG UINT32_C(0x8)
/*
* When this bit is set to '1', Energy Efficient Ethernet (EEE) is
* requested to be enabled on this link. If EEE is not supported on this
* port, then this flag shall be ignored by the HWRM.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_EEE_ENABLE UINT32_C(0x10)
/*
* When this bit is set to '1', Energy Efficient Ethernet (EEE) is
* requested to be disabled on this link. If EEE is not supported on
* this port, then this flag shall be ignored by the HWRM.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_EEE_DISABLE UINT32_C(0x20)
/*
* When this bit is set to '1' and EEE is enabled on this link, then TX
* LPI is requested to be enabled on the link. If EEE is not supported
* on this port, then this flag shall be ignored by the HWRM. If EEE is
* disabled on this port, then this flag shall be ignored by the HWRM.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_EEE_TX_LPI_ENABLE UINT32_C(0x40)
/*
* When this bit is set to '1' and EEE is enabled on this link, then TX
* LPI is requested to be disabled on the link. If EEE is not supported
* on this port, then this flag shall be ignored by the HWRM. If EEE is
* disabled on this port, then this flag shall be ignored by the HWRM.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_EEE_TX_LPI_DISABLE UINT32_C(0x80)
/*
* When set to 1, then the HWRM shall enable FEC autonegotitation on
* this port if supported. When set to 0, then this flag shall be
* ignored. If FEC autonegotiation is not supported, then the HWRM shall
* ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_AUTONEG_ENABLE UINT32_C(0x100)
/*
* When set to 1, then the HWRM shall disable FEC autonegotiation on
* this port if supported. When set to 0, then this flag shall be
* ignored. If FEC autonegotiation is not supported, then the HWRM shall
* ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_AUTONEG_DISABLE UINT32_C(0x200)
/*
* When set to 1, then the HWRM shall enable FEC CLAUSE 74 (Fire Code)
* on this port if supported. When set to 0, then this flag shall be
* ignored. If FEC CLAUSE 74 is not supported, then the HWRM shall
* ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_CLAUSE74_ENABLE UINT32_C(0x400)
/*
* When set to 1, then the HWRM shall disable FEC CLAUSE 74 (Fire Code)
* on this port if supported. When set to 0, then this flag shall be
* ignored. If FEC CLAUSE 74 is not supported, then the HWRM shall
* ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_CLAUSE74_DISABLE UINT32_C(0x800)
/*
* When set to 1, then the HWRM shall enable FEC CLAUSE 91 (Reed
* Solomon) on this port if supported. When set to 0, then this flag
* shall be ignored. If FEC CLAUSE 91 is not supported, then the HWRM
* shall ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_CLAUSE91_ENABLE UINT32_C(0x1000)
/*
* When set to 1, then the HWRM shall disable FEC CLAUSE 91 (Reed
* Solomon) on this port if supported. When set to 0, then this flag
* shall be ignored. If FEC CLAUSE 91 is not supported, then the HWRM
* shall ignore this flag.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FEC_CLAUSE91_DISABLE UINT32_C(0x2000)
/*
* When this bit is set to '1', the link shall be forced to be taken
* down. # When this bit is set to '1", all other command input settings
* related to the link speed shall be ignored. Once the link state is
* forced down, it can be explicitly cleared from that state by setting
* this flag to '0'. # If this flag is set to '0', then the link shall
* be cleared from forced down state if the link is in forced down
* state. There may be conditions (e.g. out-of-band or sideband
* configuration changes for the link) outside the scope of the HWRM
* implementation that may clear forced down link state.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FLAGS_FORCE_LINK_DWN UINT32_C(0x4000)
uint32_t enables;
/* This bit must be '1' for the auto_mode field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_AUTO_MODE UINT32_C(0x1)
/* This bit must be '1' for the auto_duplex field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_AUTO_DUPLEX UINT32_C(0x2)
/* This bit must be '1' for the auto_pause field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_AUTO_PAUSE UINT32_C(0x4)
/* This bit must be '1' for the auto_link_speed field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_AUTO_LINK_SPEED UINT32_C(0x8)
/*
* This bit must be '1' for the auto_link_speed_mask field to be
* configured.
*/
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_AUTO_LINK_SPEED_MASK UINT32_C(0x10)
/* This bit must be '1' for the wirespeed field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_WIRESPEED UINT32_C(0x20)
/* This bit must be '1' for the lpbk field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_LPBK UINT32_C(0x40)
/* This bit must be '1' for the preemphasis field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_PREEMPHASIS UINT32_C(0x80)
/* This bit must be '1' for the force_pause field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_FORCE_PAUSE UINT32_C(0x100)
/*
* This bit must be '1' for the eee_link_speed_mask field to be
* configured.
*/
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_EEE_LINK_SPEED_MASK UINT32_C(0x200)
/* This bit must be '1' for the tx_lpi_timer field to be configured. */
#define HWRM_PORT_PHY_CFG_INPUT_ENABLES_TX_LPI_TIMER UINT32_C(0x400)
uint16_t port_id;
/* Port ID of port that is to be configured. */
uint16_t force_link_speed;
/*
* This is the speed that will be used if the force bit is '1'. If
* unsupported speed is selected, an error will be generated.
*/
/* 100Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_100MB UINT32_C(0x1)
/* 1Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_1GB UINT32_C(0xa)
/* 2Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_2GB UINT32_C(0x14)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_2_5GB UINT32_C(0x19)
/* 10Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_10GB UINT32_C(0x64)
/* 20Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_20GB UINT32_C(0xc8)
/* 25Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_25GB UINT32_C(0xfa)
/* 40Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_40GB UINT32_C(0x190)
/* 50Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_50GB UINT32_C(0x1f4)
/* 100Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_100GB UINT32_C(0x3e8)
/* 10Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_LINK_SPEED_10MB UINT32_C(0xffff)
uint8_t auto_mode;
/*
* This value is used to identify what autoneg mode is used when the
* link speed is not being forced.
*/
/* Disable autoneg or autoneg disabled. No speeds are selected. */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_MODE_NONE UINT32_C(0x0)
/* Select all possible speeds for autoneg mode. */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_MODE_ALL_SPEEDS UINT32_C(0x1)
/*
* Select only the auto_link_speed speed for autoneg mode. This
* mode has been DEPRECATED. An HWRM client should not use this
* mode.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_MODE_ONE_SPEED UINT32_C(0x2)
/*
* Select the auto_link_speed or any speed below that speed for
* autoneg. This mode has been DEPRECATED. An HWRM client should
* not use this mode.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_MODE_ONE_OR_BELOW UINT32_C(0x3)
/*
* Select the speeds based on the corresponding link speed mask
* value that is provided.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_MODE_SPEED_MASK UINT32_C(0x4)
uint8_t auto_duplex;
/*
* This is the duplex setting that will be used if the autoneg_mode is
* "one_speed" or "one_or_below".
*/
/* Half Duplex will be requested. */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_DUPLEX_HALF UINT32_C(0x0)
/* Full duplex will be requested. */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_DUPLEX_FULL UINT32_C(0x1)
/* Both Half and Full dupex will be requested. */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_DUPLEX_BOTH UINT32_C(0x2)
uint8_t auto_pause;
/*
* This value is used to configure the pause that will be used for
* autonegotiation. Add text on the usage of auto_pause and force_pause.
*/
/*
* When this bit is '1', Generation of tx pause messages has been
* requested. Disabled otherwise.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages has been
* requested. Disabled otherwise.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_PAUSE_RX UINT32_C(0x2)
/*
* When set to 1, the advertisement of pause is enabled. # When the
* auto_mode is not set to none and this flag is set to 1, then the
* auto_pause bits on this port are being advertised and autoneg pause
* results are being interpreted. # When the auto_mode is not set to
* none and this flag is set to 0, the pause is forced as indicated in
* force_pause, and also advertised as auto_pause bits, but the autoneg
* results are not interpreted since the pause configuration is being
* forced. # When the auto_mode is set to none and this flag is set to
* 1, auto_pause bits should be ignored and should be set to 0.
*/
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_PAUSE_AUTONEG_PAUSE UINT32_C(0x4)
uint8_t unused_0;
uint16_t auto_link_speed;
/*
* This is the speed that will be used if the autoneg_mode is
* "one_speed" or "one_or_below". If an unsupported speed is selected,
* an error will be generated.
*/
/* 100Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_100MB UINT32_C(0x1)
/* 1Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_1GB UINT32_C(0xa)
/* 2Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_2GB UINT32_C(0x14)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_2_5GB UINT32_C(0x19)
/* 10Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_10GB UINT32_C(0x64)
/* 20Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_20GB UINT32_C(0xc8)
/* 25Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_25GB UINT32_C(0xfa)
/* 40Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_40GB UINT32_C(0x190)
/* 50Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_50GB UINT32_C(0x1f4)
/* 100Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_100GB UINT32_C(0x3e8)
/* 10Mb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_10MB UINT32_C(0xffff)
uint16_t auto_link_speed_mask;
/*
* This is a mask of link speeds that will be used if autoneg_mode is
* "mask". If unsupported speed is enabled an error will be generated.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_AUTO_LINK_SPEED_MASK_10MB UINT32_C(0x2000)
uint8_t wirespeed;
/* This value controls the wirespeed feature. */
/* Wirespeed feature is disabled. */
#define HWRM_PORT_PHY_CFG_INPUT_WIRESPEED_OFF UINT32_C(0x0)
/* Wirespeed feature is enabled. */
#define HWRM_PORT_PHY_CFG_INPUT_WIRESPEED_ON UINT32_C(0x1)
uint8_t lpbk;
/* This value controls the loopback setting for the PHY. */
/* No loopback is selected. Normal operation. */
#define HWRM_PORT_PHY_CFG_INPUT_LPBK_NONE UINT32_C(0x0)
/*
* The HW will be configured with local loopback such that host
* data is sent back to the host without modification.
*/
#define HWRM_PORT_PHY_CFG_INPUT_LPBK_LOCAL UINT32_C(0x1)
/*
* The HW will be configured with remote loopback such that port
* logic will send packets back out the transmitter that are
* received.
*/
#define HWRM_PORT_PHY_CFG_INPUT_LPBK_REMOTE UINT32_C(0x2)
uint8_t force_pause;
/*
* This value is used to configure the pause that will be used for force
* mode.
*/
/*
* When this bit is '1', Generation of tx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_CFG_INPUT_FORCE_PAUSE_RX UINT32_C(0x2)
uint8_t unused_1;
uint32_t preemphasis;
/*
* This value controls the pre-emphasis to be used for the link. Driver
* should not set this value (use enable.preemphasis = 0) unless driver
* is sure of setting. Normally HWRM FW will determine proper pre-
* emphasis.
*/
uint16_t eee_link_speed_mask;
/*
* Setting for link speed mask that is used to advertise speeds during
* autonegotiation when EEE is enabled. This field is valid only when
* EEE is enabled. The speeds specified in this field shall be a subset
* of speeds specified in auto_link_speed_mask. If EEE is enabled,then
* at least one speed shall be provided in this mask.
*/
/* Reserved */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_RSVD1 UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_100MB UINT32_C(0x2)
/* Reserved */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_RSVD2 UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_1GB UINT32_C(0x8)
/* Reserved */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_RSVD3 UINT32_C(0x10)
/* Reserved */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_RSVD4 UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_CFG_INPUT_EEE_LINK_SPEED_MASK_10GB UINT32_C(0x40)
uint8_t unused_2;
uint8_t unused_3;
uint32_t tx_lpi_timer;
uint32_t unused_4;
/*
* Reuested setting of TX LPI timer in microseconds. This field is valid
* only when EEE is enabled and TX LPI is enabled.
*/
#define HWRM_PORT_PHY_CFG_INPUT_TX_LPI_TIMER_MASK UINT32_C(0xffffff)
#define HWRM_PORT_PHY_CFG_INPUT_TX_LPI_TIMER_SFT 0
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_phy_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_phy_qcfg */
/* Description: This command queries the PHY configuration for the port. */
/* Input (24 bytes) */
struct hwrm_port_phy_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is to be queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (96 bytes) */
struct hwrm_port_phy_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t link;
/* This value indicates the current link status. */
/* There is no link or cable detected. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_NO_LINK UINT32_C(0x0)
/* There is no link, but a cable has been detected. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SIGNAL UINT32_C(0x1)
/* There is a link. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_LINK UINT32_C(0x2)
uint8_t unused_0;
uint16_t link_speed;
/* This value indicates the current link speed of the connection. */
/* 100Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_100MB UINT32_C(0x1)
/* 1Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_1GB UINT32_C(0xa)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_2GB UINT32_C(0x14)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_2_5GB UINT32_C(0x19)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_10GB UINT32_C(0x64)
/* 20Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_20GB UINT32_C(0xc8)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_25GB UINT32_C(0xfa)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_40GB UINT32_C(0x190)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_50GB UINT32_C(0x1f4)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_100GB UINT32_C(0x3e8)
/* 10Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_SPEED_10MB UINT32_C(0xffff)
uint8_t duplex_cfg;
/* This value is indicates the duplex of the current configuration. */
/* Half Duplex connection. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_DUPLEX_CFG_HALF UINT32_C(0x0)
/* Full duplex connection. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_DUPLEX_CFG_FULL UINT32_C(0x1)
uint8_t pause;
/*
* This value is used to indicate the current pause configuration. When
* autoneg is enabled, this value represents the autoneg results of
* pause configuration.
*/
/*
* When this bit is '1', Generation of tx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_PAUSE_RX UINT32_C(0x2)
uint16_t support_speeds;
/*
* The supported speeds for the port. This is a bit mask. For each speed
* that is supported, the corrresponding bit will be set to '1'.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_SUPPORT_SPEEDS_10MB UINT32_C(0x2000)
uint16_t force_link_speed;
/*
* Current setting of forced link speed. When the link speed is not
* being forced, this value shall be set to 0.
*/
/* 100Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_100MB UINT32_C(0x1)
/* 1Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_1GB UINT32_C(0xa)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_2GB UINT32_C(0x14)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_2_5GB UINT32_C(0x19)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_10GB UINT32_C(0x64)
/* 20Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_20GB UINT32_C(0xc8)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_25GB UINT32_C(0xfa)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_40GB UINT32_C(0x190)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_50GB UINT32_C(0x1f4)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_100GB UINT32_C(0x3e8)
/* 10Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_LINK_SPEED_10MB UINT32_C(0xffff)
uint8_t auto_mode;
/* Current setting of auto negotiation mode. */
/* Disable autoneg or autoneg disabled. No speeds are selected. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_MODE_NONE UINT32_C(0x0)
/* Select all possible speeds for autoneg mode. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_MODE_ALL_SPEEDS UINT32_C(0x1)
/*
* Select only the auto_link_speed speed for autoneg mode. This
* mode has been DEPRECATED. An HWRM client should not use this
* mode.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_MODE_ONE_SPEED UINT32_C(0x2)
/*
* Select the auto_link_speed or any speed below that speed for
* autoneg. This mode has been DEPRECATED. An HWRM client should
* not use this mode.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_MODE_ONE_OR_BELOW UINT32_C(0x3)
/*
* Select the speeds based on the corresponding link speed mask
* value that is provided.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_MODE_SPEED_MASK UINT32_C(0x4)
uint8_t auto_pause;
/*
* Current setting of pause autonegotiation. Move autoneg_pause flag
* here.
*/
/*
* When this bit is '1', Generation of tx pause messages has been
* requested. Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages has been
* requested. Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_PAUSE_RX UINT32_C(0x2)
/*
* When set to 1, the advertisement of pause is enabled. # When the
* auto_mode is not set to none and this flag is set to 1, then the
* auto_pause bits on this port are being advertised and autoneg pause
* results are being interpreted. # When the auto_mode is not set to
* none and this flag is set to 0, the pause is forced as indicated in
* force_pause, and also advertised as auto_pause bits, but the autoneg
* results are not interpreted since the pause configuration is being
* forced. # When the auto_mode is set to none and this flag is set to
* 1, auto_pause bits should be ignored and should be set to 0.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_PAUSE_AUTONEG_PAUSE UINT32_C(0x4)
uint16_t auto_link_speed;
/*
* Current setting for auto_link_speed. This field is only valid when
* auto_mode is set to "one_speed" or "one_or_below".
*/
/* 100Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_100MB UINT32_C(0x1)
/* 1Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_1GB UINT32_C(0xa)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_2GB UINT32_C(0x14)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_2_5GB UINT32_C(0x19)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_10GB UINT32_C(0x64)
/* 20Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_20GB UINT32_C(0xc8)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_25GB UINT32_C(0xfa)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_40GB UINT32_C(0x190)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_50GB UINT32_C(0x1f4)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_100GB UINT32_C(0x3e8)
/* 10Mb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_10MB UINT32_C(0xffff)
uint16_t auto_link_speed_mask;
/*
* Current setting for auto_link_speed_mask that is used to advertise
* speeds during autonegotiation. This field is only valid when
* auto_mode is set to "mask". The speeds specified in this field shall
* be a subset of supported speeds on this port.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_AUTO_LINK_SPEED_MASK_10MB UINT32_C(0x2000)
uint8_t wirespeed;
/* Current setting for wirespeed. */
/* Wirespeed feature is disabled. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_WIRESPEED_OFF UINT32_C(0x0)
/* Wirespeed feature is enabled. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_WIRESPEED_ON UINT32_C(0x1)
uint8_t lpbk;
/* Current setting for loopback. */
/* No loopback is selected. Normal operation. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LPBK_NONE UINT32_C(0x0)
/*
* The HW will be configured with local loopback such that host
* data is sent back to the host without modification.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LPBK_LOCAL UINT32_C(0x1)
/*
* The HW will be configured with remote loopback such that port
* logic will send packets back out the transmitter that are
* received.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LPBK_REMOTE UINT32_C(0x2)
uint8_t force_pause;
/*
* Current setting of forced pause. When the pause configuration is not
* being forced, then this value shall be set to 0.
*/
/*
* When this bit is '1', Generation of tx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FORCE_PAUSE_RX UINT32_C(0x2)
uint8_t module_status;
/*
* This value indicates the current status of the optics module on this
* port.
*/
/* Module is inserted and accepted */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_NONE UINT32_C(0x0)
/* Module is rejected and transmit side Laser is disabled. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_DISABLETX UINT32_C(0x1)
/* Module mismatch warning. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_WARNINGMSG UINT32_C(0x2)
/* Module is rejected and powered down. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_PWRDOWN UINT32_C(0x3)
/* Module is not inserted. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_NOTINSERTED UINT32_C(0x4)
/* Module status is not applicable. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MODULE_STATUS_NOTAPPLICABLE UINT32_C(0xff)
uint32_t preemphasis;
/* Current setting for preemphasis. */
uint8_t phy_maj;
/* This field represents the major version of the PHY. */
uint8_t phy_min;
/* This field represents the minor version of the PHY. */
uint8_t phy_bld;
/* This field represents the build version of the PHY. */
uint8_t phy_type;
/* This value represents a PHY type. */
/* Unknown */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_UNKNOWN UINT32_C(0x0)
/* BASE-CR */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASECR UINT32_C(0x1)
/* BASE-KR4 (Deprecated) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASEKR4 UINT32_C(0x2)
/* BASE-LR */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASELR UINT32_C(0x3)
/* BASE-SR */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASESR UINT32_C(0x4)
/* BASE-KR2 (Deprecated) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASEKR2 UINT32_C(0x5)
/* BASE-KX */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASEKX UINT32_C(0x6)
/* BASE-KR */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASEKR UINT32_C(0x7)
/* BASE-T */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASET UINT32_C(0x8)
/* EEE capable BASE-T */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_BASETE UINT32_C(0x9)
/* SGMII connected external PHY */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_SGMIIEXTPHY UINT32_C(0xa)
/* 25G_BASECR_CA_L */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_25G_BASECR_CA_L UINT32_C(0xb)
/* 25G_BASECR_CA_S */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_25G_BASECR_CA_S UINT32_C(0xc)
/* 25G_BASECR_CA_N */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_25G_BASECR_CA_N UINT32_C(0xd)
/* 25G_BASESR */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_25G_BASESR UINT32_C(0xe)
/* 100G_BASECR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_100G_BASECR4 UINT32_C(0xf)
/* 100G_BASESR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_100G_BASESR4 UINT32_C(0x10)
/* 100G_BASELR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_100G_BASELR4 UINT32_C(0x11)
/* 100G_BASEER4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_100G_BASEER4 UINT32_C(0x12)
/* 100G_BASESR10 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_100G_BASESR10 UINT32_C(0x13)
/* 40G_BASECR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_40G_BASECR4 UINT32_C(0x14)
/* 40G_BASESR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_40G_BASESR4 UINT32_C(0x15)
/* 40G_BASELR4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_40G_BASELR4 UINT32_C(0x16)
/* 40G_BASEER4 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_40G_BASEER4 UINT32_C(0x17)
/* 40G_ACTIVE_CABLE */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_40G_ACTIVE_CABLE UINT32_C(0x18)
/* 1G_baseT */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_1G_BASET UINT32_C(0x19)
/* 1G_baseSX */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_1G_BASESX UINT32_C(0x1a)
/* 1G_baseCX */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_TYPE_1G_BASECX UINT32_C(0x1b)
uint8_t media_type;
/* This value represents a media type. */
/* Unknown */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MEDIA_TYPE_UNKNOWN UINT32_C(0x0)
/* Twisted Pair */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MEDIA_TYPE_TP UINT32_C(0x1)
/* Direct Attached Copper */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MEDIA_TYPE_DAC UINT32_C(0x2)
/* Fiber */
#define HWRM_PORT_PHY_QCFG_OUTPUT_MEDIA_TYPE_FIBRE UINT32_C(0x3)
uint8_t xcvr_pkg_type;
/* This value represents a transceiver type. */
/* PHY and MAC are in the same package */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_PKG_TYPE_XCVR_INTERNAL UINT32_C(0x1)
/* PHY and MAC are in different packages */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_PKG_TYPE_XCVR_EXTERNAL UINT32_C(0x2)
uint8_t eee_config_phy_addr;
/*
* This field represents flags related to EEE configuration. These EEE
* configuration flags are valid only when the auto_mode is not set to
* none (in other words autonegotiation is enabled).
*/
/* This field represents PHY address. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_ADDR_MASK UINT32_C(0x1f)
#define HWRM_PORT_PHY_QCFG_OUTPUT_PHY_ADDR_SFT 0
/*
* When set to 1, Energy Efficient Ethernet (EEE) mode is enabled.
* Speeds for autoneg with EEE mode enabled are based on
* eee_link_speed_mask.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_EEE_CONFIG_EEE_ENABLED UINT32_C(0x20)
/*
* This flag is valid only when eee_enabled is set to 1. # If
* eee_enabled is set to 0, then EEE mode is disabled and this flag
* shall be ignored. # If eee_enabled is set to 1 and this flag is set
* to 1, then Energy Efficient Ethernet (EEE) mode is enabled and in
* use. # If eee_enabled is set to 1 and this flag is set to 0, then
* Energy Efficient Ethernet (EEE) mode is enabled but is currently not
* in use.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_EEE_CONFIG_EEE_ACTIVE UINT32_C(0x40)
/*
* This flag is valid only when eee_enabled is set to 1. # If
* eee_enabled is set to 0, then EEE mode is disabled and this flag
* shall be ignored. # If eee_enabled is set to 1 and this flag is set
* to 1, then Energy Efficient Ethernet (EEE) mode is enabled and TX LPI
* is enabled. # If eee_enabled is set to 1 and this flag is set to 0,
* then Energy Efficient Ethernet (EEE) mode is enabled but TX LPI is
* disabled.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_EEE_CONFIG_EEE_TX_LPI UINT32_C(0x80)
/*
* This field represents flags related to EEE configuration. These EEE
* configuration flags are valid only when the auto_mode is not set to
* none (in other words autonegotiation is enabled).
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_EEE_CONFIG_MASK UINT32_C(0xe0)
#define HWRM_PORT_PHY_QCFG_OUTPUT_EEE_CONFIG_SFT 5
uint8_t parallel_detect;
/* Reserved field, set to 0 */
/*
* When set to 1, the parallel detection is used to determine the speed
* of the link partner. Parallel detection is used when a
* autonegotiation capable device is connected to a link parter that is
* not capable of autonegotiation.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_PARALLEL_DETECT UINT32_C(0x1)
/* Reserved field, set to 0 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_RESERVED_MASK UINT32_C(0xfe)
#define HWRM_PORT_PHY_QCFG_OUTPUT_RESERVED_SFT 1
uint16_t link_partner_adv_speeds;
/*
* The advertised speeds for the port by the link partner. Each
* advertised speed will be set to '1'.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_SPEEDS_10MB UINT32_C(0x2000)
uint8_t link_partner_adv_auto_mode;
/*
* The advertised autoneg for the port by the link partner. This field
* is deprecated and should be set to 0.
*/
/* Disable autoneg or autoneg disabled. No speeds are selected. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_AUTO_MODE_NONE UINT32_C(0x0)
/* Select all possible speeds for autoneg mode. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_AUTO_MODE_ALL_SPEEDS UINT32_C(0x1)
/*
* Select only the auto_link_speed speed for autoneg mode. This
* mode has been DEPRECATED. An HWRM client should not use this
* mode.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_AUTO_MODE_ONE_SPEED UINT32_C(0x2)
/*
* Select the auto_link_speed or any speed below that speed for
* autoneg. This mode has been DEPRECATED. An HWRM client should
* not use this mode.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_AUTO_MODE_ONE_OR_BELOW UINT32_C(0x3)
/*
* Select the speeds based on the corresponding link speed mask
* value that is provided.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_AUTO_MODE_SPEED_MASK UINT32_C(0x4)
uint8_t link_partner_adv_pause;
/* The advertised pause settings on the port by the link partner. */
/*
* When this bit is '1', Generation of tx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_PAUSE_TX UINT32_C(0x1)
/*
* When this bit is '1', Reception of rx pause messages is supported.
* Disabled otherwise.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_PAUSE_RX UINT32_C(0x2)
uint16_t adv_eee_link_speed_mask;
/*
* Current setting for link speed mask that is used to advertise speeds
* during autonegotiation when EEE is enabled. This field is valid only
* when eee_enabled flags is set to 1. The speeds specified in this
* field shall be a subset of speeds specified in auto_link_speed_mask.
*/
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_RSVD1 UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_100MB UINT32_C(0x2)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_RSVD2 UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_1GB UINT32_C(0x8)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_RSVD3 UINT32_C(0x10)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_RSVD4 UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_ADV_EEE_LINK_SPEED_MASK_10GB UINT32_C(0x40)
uint16_t link_partner_adv_eee_link_speed_mask;
/*
* Current setting for link speed mask that is advertised by the link
* partner when EEE is enabled. This field is valid only when
* eee_enabled flags is set to 1.
*/
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_RSVD1 UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_100MB UINT32_C(0x2)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_RSVD2 UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_1GB UINT32_C(0x8)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_RSVD3 UINT32_C(0x10)
/* Reserved */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_RSVD4 UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCFG_OUTPUT_LINK_PARTNER_ADV_EEE_LINK_SPEED_MASK_10GB UINT32_C(0x40)
uint32_t xcvr_identifier_type_tx_lpi_timer;
/* This value represents transceiver identifier type. */
/*
* Current setting of TX LPI timer in microseconds. This field is valid
* only when_eee_enabled flag is set to 1 and tx_lpi_enabled is set to
* 1.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_TX_LPI_TIMER_MASK UINT32_C(0xffffff)
#define HWRM_PORT_PHY_QCFG_OUTPUT_TX_LPI_TIMER_SFT 0
/* This value represents transceiver identifier type. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_MASK UINT32_C(0xff000000)
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_SFT 24
/* Unknown */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_UNKNOWN (UINT32_C(0x0) << 24)
/* SFP/SFP+/SFP28 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_SFP (UINT32_C(0x3) << 24)
/* QSFP */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_QSFP (UINT32_C(0xc) << 24)
/* QSFP+ */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_QSFPPLUS (UINT32_C(0xd) << 24)
/* QSFP28 */
#define HWRM_PORT_PHY_QCFG_OUTPUT_XCVR_IDENTIFIER_TYPE_QSFP28 (UINT32_C(0x11) << 24)
uint16_t fec_cfg;
/*
* This value represents the current configuration of Forward Error
* Correction (FEC) on the port.
*/
/*
* When set to 1, then FEC is not supported on this port. If this flag
* is set to 1, then all other FEC configuration flags shall be ignored.
* When set to 0, then FEC is supported as indicated by other
* configuration flags. If no cable is attached and the HWRM does not
* yet know the FEC capability, then the HWRM shall set this flag to 1
* when reporting FEC capability.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_NONE_SUPPORTED UINT32_C(0x1)
/*
* When set to 1, then FEC autonegotiation is supported on this port.
* When set to 0, then FEC autonegotiation is not supported on this
* port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_AUTONEG_SUPPORTED UINT32_C(0x2)
/*
* When set to 1, then FEC autonegotiation is enabled on this port. When
* set to 0, then FEC autonegotiation is disabled if supported. This
* flag should be ignored if FEC autonegotiation is not supported on
* this port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_AUTONEG_ENABLED UINT32_C(0x4)
/*
* When set to 1, then FEC CLAUSE 74 (Fire Code) is supported on this
* port. When set to 0, then FEC CLAUSE 74 (Fire Code) is not supported
* on this port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_CLAUSE74_SUPPORTED UINT32_C(0x8)
/*
* When set to 1, then FEC CLAUSE 74 (Fire Code) is enabled on this
* port. When set to 0, then FEC CLAUSE 74 (Fire Code) is disabled if
* supported. This flag should be ignored if FEC CLAUSE 74 is not
* supported on this port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_CLAUSE74_ENABLED UINT32_C(0x10)
/*
* When set to 1, then FEC CLAUSE 91 (Reed Solomon) is supported on this
* port. When set to 0, then FEC CLAUSE 91 (Reed Solomon) is not
* supported on this port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_CLAUSE91_SUPPORTED UINT32_C(0x20)
/*
* When set to 1, then FEC CLAUSE 91 (Reed Solomon) is enabled on this
* port. When set to 0, then FEC CLAUSE 91 (Reed Solomon) is disabled if
* supported. This flag should be ignored if FEC CLAUSE 91 is not
* supported on this port.
*/
#define HWRM_PORT_PHY_QCFG_OUTPUT_FEC_CFG_FEC_CLAUSE91_ENABLED UINT32_C(0x40)
uint8_t duplex_state;
/* This value is indicates the duplex of the current connection state. */
/* Half Duplex connection. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_DUPLEX_STATE_HALF UINT32_C(0x0)
/* Full duplex connection. */
#define HWRM_PORT_PHY_QCFG_OUTPUT_DUPLEX_STATE_FULL UINT32_C(0x1)
uint8_t unused_1;
char phy_vendor_name[16];
/*
* Up to 16 bytes of null padded ASCII string representing PHY vendor.
* If the string is set to null, then the vendor name is not available.
*/
char phy_vendor_partnumber[16];
/*
* Up to 16 bytes of null padded ASCII string that identifies vendor
* specific part number of the PHY. If the string is set to null, then
* the vendor specific part number is not available.
*/
uint32_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_mac_cfg */
/*
* Description: This command configures the MAC block for the port. # Only PF
* drivers shall be allowed to configure MAC. # A VF driver should not be
* allowed to configure MAC using this command. # In a network partition mode, a
* PF driver should not be allowed to configure MAC using this command. The QoS
* settings in port_mac_cfg() are global for all ports/functions. If multiple PF
* drivers on different ports are configuring QoS settings, then the HWRM is not
* responsible for maintaining consistency between them. A PF driver changing
* global QoS settings using this command may impact other PF drivers on
* different ports.
*/
/* Input (40 bytes) */
struct hwrm_port_mac_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* In this field, there are a number of CoS mappings related flags that
* are used to configure CoS mappings and their corresponding priorities
* in the hardware. For the priorities of CoS mappings, the HWRM uses
* the following priority order (high to low) by default: # vlan pri #
* ip_dscp # tunnel_vlan_pri # default cos A subset of CoS mappings can
* be enabled. If a priority is not specified for an enabled CoS
* mapping, the priority will be assigned in the above order for the
* enabled CoS mappings. For example, if vlan_pri and ip_dscp CoS
* mappings are enabled and their priorities are not specified, the
* following priority order (high to low) will be used by the HWRM: #
* vlan_pri # ip_dscp # default cos vlan_pri CoS mapping together with
* default CoS with lower priority are enabled by default by the HWRM.
*/
/*
* When this bit is '1', this command will configure the MAC to match
* the current link state of the PHY. If the link is not established on
* the PHY, then this bit has no effect.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_MATCH_LINK UINT32_C(0x1)
/*
* When this bit is set to '1', the inner VLAN PRI to CoS mapping is
* requested to be enabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_VLAN_PRI2COS_ENABLE UINT32_C(0x2)
/*
* When this bit is set to '1', tunnel VLAN PRI field to CoS mapping is
* requested to be enabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_TUNNEL_PRI2COS_ENABLE UINT32_C(0x4)
/*
* When this bit is set to '1', the IP DSCP to CoS mapping is requested
* to be enabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_IP_DSCP2COS_ENABLE UINT32_C(0x8)
/*
* When this bit is '1', the HWRM is requested to enable timestamp
* capture capability on the receive side of this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_PTP_RX_TS_CAPTURE_ENABLE UINT32_C(0x10)
/*
* When this bit is '1', the HWRM is requested to disable timestamp
* capture capability on the receive side of this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_PTP_RX_TS_CAPTURE_DISABLE UINT32_C(0x20)
/*
* When this bit is '1', the HWRM is requested to enable timestamp
* capture capability on the transmit side of this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_PTP_TX_TS_CAPTURE_ENABLE UINT32_C(0x40)
/*
* When this bit is '1', the HWRM is requested to disable timestamp
* capture capability on the transmit side of this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_PTP_TX_TS_CAPTURE_DISABLE UINT32_C(0x80)
/*
* When this bit is '1', the Out-Of-Box WoL is requested to be enabled
* on this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_OOB_WOL_ENABLE UINT32_C(0x100)
/*
* When this bit is '1', the the Out-Of-Box WoL is requested to be
* disabled on this port.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_OOB_WOL_DISABLE UINT32_C(0x200)
/*
* When this bit is set to '1', the inner VLAN PRI to CoS mapping is
* requested to be disabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_VLAN_PRI2COS_DISABLE UINT32_C(0x400)
/*
* When this bit is set to '1', tunnel VLAN PRI field to CoS mapping is
* requested to be disabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_TUNNEL_PRI2COS_DISABLE UINT32_C(0x800)
/*
* When this bit is set to '1', the IP DSCP to CoS mapping is requested
* to be disabled.
*/
#define HWRM_PORT_MAC_CFG_INPUT_FLAGS_IP_DSCP2COS_DISABLE UINT32_C(0x1000)
uint32_t enables;
/* This bit must be '1' for the ipg field to be configured. */
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_IPG UINT32_C(0x1)
/* This bit must be '1' for the lpbk field to be configured. */
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_LPBK UINT32_C(0x2)
/*
* This bit must be '1' for the vlan_pri2cos_map_pri field to be
* configured.
*/
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_VLAN_PRI2COS_MAP_PRI UINT32_C(0x4)
/* This bit must be '1' for the Reserved1 field to be configured. */
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_RESERVED1 UINT32_C(0x8)
/*
* This bit must be '1' for the tunnel_pri2cos_map_pri field to be
* configured.
*/
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_TUNNEL_PRI2COS_MAP_PRI UINT32_C(0x10)
/* This bit must be '1' for the dscp2cos_map_pri field to be configured. */
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_DSCP2COS_MAP_PRI UINT32_C(0x20)
/*
* This bit must be '1' for the rx_ts_capture_ptp_msg_type field to be
* configured.
*/
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_RX_TS_CAPTURE_PTP_MSG_TYPE UINT32_C(0x40)
/*
* This bit must be '1' for the tx_ts_capture_ptp_msg_type field to be
* configured.
*/
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_TX_TS_CAPTURE_PTP_MSG_TYPE UINT32_C(0x80)
/* This bit must be '1' for the cos_field_cfg field to be configured. */
#define HWRM_PORT_MAC_CFG_INPUT_ENABLES_COS_FIELD_CFG UINT32_C(0x100)
uint16_t port_id;
/* Port ID of port that is to be configured. */
uint8_t ipg;
/*
* This value is used to configure the minimum IPG that will be sent
* between packets by this port.
*/
uint8_t lpbk;
/* This value controls the loopback setting for the MAC. */
/* No loopback is selected. Normal operation. */
#define HWRM_PORT_MAC_CFG_INPUT_LPBK_NONE UINT32_C(0x0)
/*
* The HW will be configured with local loopback such that host
* data is sent back to the host without modification.
*/
#define HWRM_PORT_MAC_CFG_INPUT_LPBK_LOCAL UINT32_C(0x1)
/*
* The HW will be configured with remote loopback such that port
* logic will send packets back out the transmitter that are
* received.
*/
#define HWRM_PORT_MAC_CFG_INPUT_LPBK_REMOTE UINT32_C(0x2)
uint8_t vlan_pri2cos_map_pri;
/*
* This value controls the priority setting of VLAN PRI to CoS mapping
* based on VLAN Tags of inner packet headers of tunneled packets or
* packet headers of non-tunneled packets. # Each XXX_pri variable shall
* have a unique priority value when it is being specified. # When
* comparing priorities of mappings, higher value indicates higher
* priority. For example, a value of 0-3 is returned where 0 is being
* the lowest priority and 3 is being the highest priority.
*/
uint8_t reserved1;
/* Reserved field */
uint8_t tunnel_pri2cos_map_pri;
/*
* This value controls the priority setting of VLAN PRI to CoS mapping
* based on VLAN Tags of tunneled header. This mapping only applies when
* tunneled headers are present. # Each XXX_pri variable shall have a
* unique priority value when it is being specified. # When comparing
* priorities of mappings, higher value indicates higher priority. For
* example, a value of 0-3 is returned where 0 is being the lowest
* priority and 3 is being the highest priority.
*/
uint8_t dscp2pri_map_pri;
/*
* This value controls the priority setting of IP DSCP to CoS mapping
* based on inner IP header of tunneled packets or IP header of non-
* tunneled packets. # Each XXX_pri variable shall have a unique
* priority value when it is being specified. # When comparing
* priorities of mappings, higher value indicates higher priority. For
* example, a value of 0-3 is returned where 0 is being the lowest
* priority and 3 is being the highest priority.
*/
uint16_t rx_ts_capture_ptp_msg_type;
/*
* This is a 16-bit bit mask that is used to request a specific
* configuration of time stamp capture of PTP messages on the receive
* side of this port. This field shall be ignored if the
* ptp_rx_ts_capture_enable flag is not set in this command. Otherwise,
* if bit 'i' is set, then the HWRM is being requested to configure the
* receive side of the port to capture the time stamp of every received
* PTP message with messageType field value set to i.
*/
uint16_t tx_ts_capture_ptp_msg_type;
/*
* This is a 16-bit bit mask that is used to request a specific
* configuration of time stamp capture of PTP messages on the transmit
* side of this port. This field shall be ignored if the
* ptp_tx_ts_capture_enable flag is not set in this command. Otherwise,
* if bit 'i' is set, then the HWRM is being requested to configure the
* transmit sied of the port to capture the time stamp of every
* transmitted PTP message with messageType field value set to i.
*/
uint8_t cos_field_cfg;
/* Configuration of CoS fields. */
/* Reserved. */
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_RSVD1 UINT32_C(0x1)
/*
* This field is used to specify selection of VLAN PRI value based on
* whether one or two VLAN Tags are present in the inner packet headers
* of tunneled packets or non-tunneled packets. This field is valid only
* if inner VLAN PRI to CoS mapping is enabled. If VLAN PRI to CoS
* mapping is not enabled, then this field shall be ignored.
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_MASK UINT32_C(0x6)
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_SFT 1
/*
* Select inner VLAN PRI when 1 or 2 VLAN Tags are present in
* the inner packet headers
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_INNERMOST (UINT32_C(0x0) << 1)
/*
* Select outer VLAN Tag PRI when 2 VLAN Tags are present in the
* inner packet headers. No VLAN PRI shall be selected for this
* configuration if only one VLAN Tag is present in the inner
* packet headers.
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_OUTER (UINT32_C(0x1) << 1)
/*
* Select outermost VLAN PRI when 1 or 2 VLAN Tags are present
* in the inner packet headers
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_OUTERMOST (UINT32_C(0x2) << 1)
/* Unspecified */
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_UNSPECIFIED (UINT32_C(0x3) << 1)
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_LAST HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_VLAN_PRI_SEL_UNSPECIFIED
/*
* This field is used to specify selection of tunnel VLAN PRI value
* based on whether one or two VLAN Tags are present in tunnel headers.
* This field is valid only if tunnel VLAN PRI to CoS mapping is
* enabled. If tunnel VLAN PRI to CoS mapping is not enabled, then this
* field shall be ignored.
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_MASK UINT32_C(0x18)
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_SFT 3
/*
* Select inner VLAN PRI when 1 or 2 VLAN Tags are present in
* the tunnel packet headers
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_INNERMOST (UINT32_C(0x0) << 3)
/*
* Select outer VLAN Tag PRI when 2 VLAN Tags are present in the
* tunnel packet headers. No tunnel VLAN PRI shall be selected
* for this configuration if only one VLAN Tag is present in the
* tunnel packet headers.
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_OUTER (UINT32_C(0x1) << 3)
/*
* Select outermost VLAN PRI when 1 or 2 VLAN Tags are present
* in the tunnel packet headers
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_OUTERMOST (UINT32_C(0x2) << 3)
/* Unspecified */
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_UNSPECIFIED (UINT32_C(0x3) << 3)
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_LAST HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_UNSPECIFIED
/*
* This field shall be used to provide default CoS value that has been
* configured on this port. This field is valid only if default CoS
* mapping is enabled. If default CoS mapping is not enabled, then this
* field shall be ignored.
*/
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_DEFAULT_COS_MASK UINT32_C(0xe0)
#define HWRM_PORT_MAC_CFG_INPUT_COS_FIELD_CFG_DEFAULT_COS_SFT 5
uint8_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_mac_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t mru;
/*
* This is the configured maximum length of Ethernet packet payload that
* is allowed to be received on the port. This value does not include
* the number of bytes used by Ethernet header and trailer (CRC).
*/
uint16_t mtu;
/*
* This is the configured maximum length of Ethernet packet payload that
* is allowed to be transmitted on the port. This value does not include
* the number of bytes used by Ethernet header and trailer (CRC).
*/
uint8_t ipg;
/* Current configuration of the IPG value. */
uint8_t lpbk;
/* Current value of the loopback value. */
/* No loopback is selected. Normal operation. */
#define HWRM_PORT_MAC_CFG_OUTPUT_LPBK_NONE UINT32_C(0x0)
/*
* The HW will be configured with local loopback such that host
* data is sent back to the host without modification.
*/
#define HWRM_PORT_MAC_CFG_OUTPUT_LPBK_LOCAL UINT32_C(0x1)
/*
* The HW will be configured with remote loopback such that port
* logic will send packets back out the transmitter that are
* received.
*/
#define HWRM_PORT_MAC_CFG_OUTPUT_LPBK_REMOTE UINT32_C(0x2)
uint8_t unused_0;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_mac_qcfg */
/* Description: This command queries the MAC block for the port. */
/* Input (24 bytes) */
struct hwrm_port_mac_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is to be configured. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_port_mac_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t mru;
/*
* This is the configured maximum length of Ethernet packet payload that
* is allowed to be received on the port. This value does not include
* the number of bytes used by the Ethernet header and trailer (CRC).
*/
uint16_t mtu;
/*
* This is the configured maximum length of Ethernet packet payload that
* is allowed to be transmitted on the port. This value does not include
* the number of bytes used by the Ethernet header and trailer (CRC).
*/
uint8_t ipg;
/* The minimum IPG that will be sent between packets by this port. */
uint8_t lpbk;
/* The loopback setting for the MAC. */
/* No loopback is selected. Normal operation. */
#define HWRM_PORT_MAC_QCFG_OUTPUT_LPBK_NONE UINT32_C(0x0)
/*
* The HW will be configured with local loopback such that host
* data is sent back to the host without modification.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_LPBK_LOCAL UINT32_C(0x1)
/*
* The HW will be configured with remote loopback such that port
* logic will send packets back out the transmitter that are
* received.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_LPBK_REMOTE UINT32_C(0x2)
uint8_t vlan_pri2cos_map_pri;
/*
* Priority setting for VLAN PRI to CoS mapping. # Each XXX_pri variable
* shall have a unique priority value when it is being used. # When
* comparing priorities of mappings, higher value indicates higher
* priority. For example, a value of 0-3 is returned where 0 is being
* the lowest priority and 3 is being the highest priority. # If the
* correspoding CoS mapping is not enabled, then this field should be
* ignored. # This value indicates the normalized priority value
* retained in the HWRM.
*/
uint8_t flags;
/*
* In this field, a number of CoS mappings related flags are used to
* indicate configured CoS mappings.
*/
/*
* When this bit is set to '1', the inner VLAN PRI to CoS mapping is
* enabled.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_VLAN_PRI2COS_ENABLE UINT32_C(0x1)
/*
* When this bit is set to '1', tunnel VLAN PRI field to CoS mapping is
* enabled.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_TUNNEL_PRI2COS_ENABLE UINT32_C(0x2)
/* When this bit is set to '1', the IP DSCP to CoS mapping is enabled. */
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_IP_DSCP2COS_ENABLE UINT32_C(0x4)
/* When this bit is '1', the Out-Of-Box WoL is enabled on this port. */
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_OOB_WOL_ENABLE UINT32_C(0x8)
/* When this bit is '1', PTP is enabled for RX on this port. */
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_PTP_RX_TS_CAPTURE_ENABLE UINT32_C(0x10)
/* When this bit is '1', PTP is enabled for TX on this port. */
#define HWRM_PORT_MAC_QCFG_OUTPUT_FLAGS_PTP_TX_TS_CAPTURE_ENABLE UINT32_C(0x20)
uint8_t tunnel_pri2cos_map_pri;
/*
* Priority setting for tunnel VLAN PRI to CoS mapping. # Each XXX_pri
* variable shall have a unique priority value when it is being used. #
* When comparing priorities of mappings, higher value indicates higher
* priority. For example, a value of 0-3 is returned where 0 is being
* the lowest priority and 3 is being the highest priority. # If the
* correspoding CoS mapping is not enabled, then this field should be
* ignored. # This value indicates the normalized priority value
* retained in the HWRM.
*/
uint8_t dscp2pri_map_pri;
/*
* Priority setting for DSCP to PRI mapping. # Each XXX_pri variable
* shall have a unique priority value when it is being used. # When
* comparing priorities of mappings, higher value indicates higher
* priority. For example, a value of 0-3 is returned where 0 is being
* the lowest priority and 3 is being the highest priority. # If the
* correspoding CoS mapping is not enabled, then this field should be
* ignored. # This value indicates the normalized priority value
* retained in the HWRM.
*/
uint16_t rx_ts_capture_ptp_msg_type;
/*
* This is a 16-bit bit mask that represents the current configuration
* of time stamp capture of PTP messages on the receive side of this
* port. If bit 'i' is set, then the receive side of the port is
* configured to capture the time stamp of every received PTP message
* with messageType field value set to i. If all bits are set to 0 (i.e.
* field value set 0), then the receive side of the port is not
* configured to capture timestamp for PTP messages. If all bits are set
* to 1, then the receive side of the port is configured to capture
* timestamp for all PTP messages.
*/
uint16_t tx_ts_capture_ptp_msg_type;
/*
* This is a 16-bit bit mask that represents the current configuration
* of time stamp capture of PTP messages on the transmit side of this
* port. If bit 'i' is set, then the transmit side of the port is
* configured to capture the time stamp of every received PTP message
* with messageType field value set to i. If all bits are set to 0 (i.e.
* field value set 0), then the transmit side of the port is not
* configured to capture timestamp for PTP messages. If all bits are set
* to 1, then the transmit side of the port is configured to capture
* timestamp for all PTP messages.
*/
uint8_t cos_field_cfg;
/* Configuration of CoS fields. */
/* Reserved */
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_RSVD UINT32_C(0x1)
/*
* This field is used for selecting VLAN PRI value based on whether one
* or two VLAN Tags are present in the inner packet headers of tunneled
* packets or non-tunneled packets.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_MASK UINT32_C(0x6)
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_SFT 1
/*
* Select inner VLAN PRI when 1 or 2 VLAN Tags are present in
* the inner packet headers
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_INNERMOST (UINT32_C(0x0) << 1)
/*
* Select outer VLAN Tag PRI when 2 VLAN Tags are present in the
* inner packet headers. No VLAN PRI is selected for this
* configuration if only one VLAN Tag is present in the inner
* packet headers.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_OUTER (UINT32_C(0x1) << 1)
/*
* Select outermost VLAN PRI when 1 or 2 VLAN Tags are present
* in the inner packet headers
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_OUTERMOST (UINT32_C(0x2) << 1)
/* Unspecified */
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_UNSPECIFIED (UINT32_C(0x3) << 1)
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_LAST HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_VLAN_PRI_SEL_UNSPECIFIED
/*
* This field is used for selecting tunnel VLAN PRI value based on
* whether one or two VLAN Tags are present in the tunnel headers of
* tunneled packets. This selection does not apply to non-tunneled
* packets.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_MASK UINT32_C(0x18)
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_SFT 3
/*
* Select inner VLAN PRI when 1 or 2 VLAN Tags are present in
* the tunnel packet headers
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_INNERMOST (UINT32_C(0x0) << 3)
/*
* Select outer VLAN Tag PRI when 2 VLAN Tags are present in the
* tunnel packet headers. No VLAN PRI is selected for this
* configuration if only one VLAN Tag is present in the tunnel
* packet headers.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_OUTER (UINT32_C(0x1) << 3)
/*
* Select outermost VLAN PRI when 1 or 2 VLAN Tags are present
* in the tunnel packet headers
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_OUTERMOST (UINT32_C(0x2) << 3)
/* Unspecified */
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_UNSPECIFIED (UINT32_C(0x3) << 3)
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_LAST HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_T_VLAN_PRI_SEL_UNSPECIFIED
/*
* This field is used to provide default CoS value that has been
* configured on this port.
*/
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_DEFAULT_COS_MASK UINT32_C(0xe0)
#define HWRM_PORT_MAC_QCFG_OUTPUT_COS_FIELD_CFG_DEFAULT_COS_SFT 5
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_mac_ptp_qcfg */
/* Description: This command queries the PTP information for the port. */
/* Input (24 bytes) */
struct hwrm_port_mac_ptp_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (80 bytes) */
struct hwrm_port_mac_ptp_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t flags;
/*
* In this field, a number of PTP related flags are used to indicate
* configured PTP capabilities.
*/
/*
* When this bit is set to '1', the PTP related registers are directly
* accessible by the host.
*/
#define HWRM_PORT_MAC_PTP_QCFG_OUTPUT_FLAGS_DIRECT_ACCESS UINT32_C(0x1)
/*
* When this bit is set to '1', the PTP information is accessible via
* HWRM commands.
*/
#define HWRM_PORT_MAC_PTP_QCFG_OUTPUT_FLAGS_HWRM_ACCESS UINT32_C(0x2)
uint8_t unused_0;
uint16_t unused_1;
uint32_t rx_ts_reg_off_lower;
/* Offset of the PTP register for the lower 32 bits of timestamp for RX. */
uint32_t rx_ts_reg_off_upper;
/* Offset of the PTP register for the upper 32 bits of timestamp for RX. */
uint32_t rx_ts_reg_off_seq_id;
/* Offset of the PTP register for the sequence ID for RX. */
uint32_t rx_ts_reg_off_src_id_0;
/* Offset of the first PTP source ID for RX. */
uint32_t rx_ts_reg_off_src_id_1;
/* Offset of the second PTP source ID for RX. */
uint32_t rx_ts_reg_off_src_id_2;
/* Offset of the third PTP source ID for RX. */
uint32_t rx_ts_reg_off_domain_id;
/* Offset of the domain ID for RX. */
uint32_t rx_ts_reg_off_fifo;
/* Offset of the PTP FIFO register for RX. */
uint32_t rx_ts_reg_off_fifo_adv;
/* Offset of the PTP advance FIFO register for RX. */
uint32_t rx_ts_reg_off_granularity;
/* PTP timestamp granularity for RX. */
uint32_t tx_ts_reg_off_lower;
/* Offset of the PTP register for the lower 32 bits of timestamp for TX. */
uint32_t tx_ts_reg_off_upper;
/* Offset of the PTP register for the upper 32 bits of timestamp for TX. */
uint32_t tx_ts_reg_off_seq_id;
/* Offset of the PTP register for the sequence ID for TX. */
uint32_t tx_ts_reg_off_fifo;
/* Offset of the PTP FIFO register for TX. */
uint32_t tx_ts_reg_off_granularity;
/* PTP timestamp granularity for TX. */
uint32_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_qstats */
/* Description: This function returns per port Ethernet statistics. */
/* Input (40 bytes) */
struct hwrm_port_qstats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is being queried. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2[3];
uint8_t unused_3;
uint64_t tx_stat_host_addr;
/* This is the host address where Tx port statistics will be stored */
uint64_t rx_stat_host_addr;
/* This is the host address where Rx port statistics will be stored */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_qstats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t tx_stat_size;
/* The size of TX port statistics block in bytes. */
uint16_t rx_stat_size;
/* The size of RX port statistics block in bytes. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_lpbk_qstats */
/* Description: This function returns loopback statistics. */
/* Input (16 bytes) */
struct hwrm_port_lpbk_qstats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (96 bytes) */
struct hwrm_port_lpbk_qstats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t lpbk_ucast_frames;
/* Number of transmitted unicast frames */
uint64_t lpbk_mcast_frames;
/* Number of transmitted multicast frames */
uint64_t lpbk_bcast_frames;
/* Number of transmitted broadcast frames */
uint64_t lpbk_ucast_bytes;
/* Number of transmitted bytes for unicast traffic */
uint64_t lpbk_mcast_bytes;
/* Number of transmitted bytes for multicast traffic */
uint64_t lpbk_bcast_bytes;
/* Number of transmitted bytes for broadcast traffic */
uint64_t tx_stat_discard;
/* Total Tx Drops for loopback traffic reported by STATS block */
uint64_t tx_stat_error;
/* Total Tx Error Drops for loopback traffic reported by STATS block */
uint64_t rx_stat_discard;
/* Total Rx Drops for loopback traffic reported by STATS block */
uint64_t rx_stat_error;
/* Total Rx Error Drops for loopback traffic reported by STATS block */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_clr_stats */
/*
* Description: This function clears per port statistics. The HWRM shall not
* allow a VF driver to clear port statistics. The HWRM shall not allow a PF
* driver to clear port statistics in a partitioning mode. The HWRM may allow a
* PF driver to clear port statistics in the non-partitioning mode.
*/
/* Input (24 bytes) */
struct hwrm_port_clr_stats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_clr_stats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_lpbk_clr_stats */
/*
* Description: This function clears loopback statistics. The HWRM shall not
* allow a VF driver to clear loopback statistics. The HWRM shall not allow a PF
* driver to clear loopback statistics in a partitioning mode. The HWRM may
* allow a PF driver to clear loopback statistics in the non-partitioning mode.
*/
/* Input (16 bytes) */
struct hwrm_port_lpbk_clr_stats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_lpbk_clr_stats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_ts_query */
/*
* Description: This function is used to read timestamp information captured for
* PTP messages on this port.
*/
/* Input (24 bytes) */
struct hwrm_port_ts_query_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_PORT_TS_QUERY_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_PORT_TS_QUERY_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_PORT_TS_QUERY_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_PORT_TS_QUERY_INPUT_FLAGS_PATH_LAST HWRM_PORT_TS_QUERY_INPUT_FLAGS_PATH_RX
uint16_t port_id;
/* Port ID of port that is being queried. */
uint16_t unused_0;
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_port_ts_query_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t ptp_msg_ts;
/* Timestamp value of PTP message captured. */
uint16_t ptp_msg_seqid;
/* Sequence ID of the PTP message captured. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_phy_qcaps */
/*
* Description: This function is used to query the current capabilities of PHY
* on this link.
*/
/* Input (24 bytes) */
struct hwrm_port_phy_qcaps_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port that is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_port_phy_qcaps_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t flags;
/* PHY capability flags */
/*
* If set to 1, then this field indicates that the link is capable of
* supporting EEE.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_FLAGS_EEE_SUPPORTED UINT32_C(0x1)
/*
* Reserved field. The HWRM shall set this field to 0. An HWRM client
* shall ignore this field.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_FLAGS_RSVD1_MASK UINT32_C(0xfe)
#define HWRM_PORT_PHY_QCAPS_OUTPUT_FLAGS_RSVD1_SFT 1
uint8_t port_cnt;
/* Number of front panel ports for this device. */
/* Not supported or unknown */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_PORT_CNT_UNKNOWN UINT32_C(0x0)
/* single port device */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_PORT_CNT_1 UINT32_C(0x1)
/* 2-port device */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_PORT_CNT_2 UINT32_C(0x2)
/* 3-port device */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_PORT_CNT_3 UINT32_C(0x3)
/* 4-port device */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_PORT_CNT_4 UINT32_C(0x4)
uint16_t supported_speeds_force_mode;
/*
* This is a bit mask to indicate what speeds are supported as forced
* speeds on this link. For each speed that can be forced on this link,
* the corresponding mask bit shall be set to '1'.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_FORCE_MODE_10MB UINT32_C(0x2000)
uint16_t supported_speeds_auto_mode;
/*
* This is a bit mask to indicate what speeds are supported for
* autonegotiation on this link. For each speed that can be
* autonegotiated on this link, the corresponding mask bit shall be set
* to '1'.
*/
/* 100Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_100MBHD UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_100MB UINT32_C(0x2)
/* 1Gb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_1GBHD UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_1GB UINT32_C(0x8)
/* 2Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_2GB UINT32_C(0x10)
/* 2.5Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_2_5GB UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_10GB UINT32_C(0x40)
/* 20Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_20GB UINT32_C(0x80)
/* 25Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_25GB UINT32_C(0x100)
/* 40Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_40GB UINT32_C(0x200)
/* 50Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_50GB UINT32_C(0x400)
/* 100Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_100GB UINT32_C(0x800)
/* 10Mb link speed (Half-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_10MBHD UINT32_C(0x1000)
/* 10Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_AUTO_MODE_10MB UINT32_C(0x2000)
uint16_t supported_speeds_eee_mode;
/*
* This is a bit mask to indicate what speeds are supported for EEE on
* this link. For each speed that can be autonegotiated when EEE is
* enabled on this link, the corresponding mask bit shall be set to '1'.
* This field is only valid when the eee_suppotred is set to '1'.
*/
/* Reserved */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_RSVD1 UINT32_C(0x1)
/* 100Mb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_100MB UINT32_C(0x2)
/* Reserved */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_RSVD2 UINT32_C(0x4)
/* 1Gb link speed (Full-duplex) */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_1GB UINT32_C(0x8)
/* Reserved */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_RSVD3 UINT32_C(0x10)
/* Reserved */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_RSVD4 UINT32_C(0x20)
/* 10Gb link speed */
#define HWRM_PORT_PHY_QCAPS_OUTPUT_SUPPORTED_SPEEDS_EEE_MODE_10GB UINT32_C(0x40)
uint32_t tx_lpi_timer_low;
/*
* Reserved field. The HWRM shall set this field to 0. An HWRM client
* shall ignore this field.
*/
/*
* The lowest value of TX LPI timer that can be set on this link when
* EEE is enabled. This value is in microseconds. This field is valid
* only when_eee_supported is set to '1'.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_TX_LPI_TIMER_LOW_MASK UINT32_C(0xffffff)
#define HWRM_PORT_PHY_QCAPS_OUTPUT_TX_LPI_TIMER_LOW_SFT 0
/*
* Reserved field. The HWRM shall set this field to 0. An HWRM client
* shall ignore this field.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_RSVD2_MASK UINT32_C(0xff000000)
#define HWRM_PORT_PHY_QCAPS_OUTPUT_RSVD2_SFT 24
uint32_t valid_tx_lpi_timer_high;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
/*
* The highest value of TX LPI timer that can be set on this link when
* EEE is enabled. This value is in microseconds. This field is valid
* only when_eee_supported is set to '1'.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_TX_LPI_TIMER_HIGH_MASK UINT32_C(0xffffff)
#define HWRM_PORT_PHY_QCAPS_OUTPUT_TX_LPI_TIMER_HIGH_SFT 0
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
#define HWRM_PORT_PHY_QCAPS_OUTPUT_VALID_MASK UINT32_C(0xff000000)
#define HWRM_PORT_PHY_QCAPS_OUTPUT_VALID_SFT 24
} __attribute__((packed));
/* hwrm_port_led_cfg */
/*
* Description: This function is used to configure LEDs on a given port. Each
* port has individual set of LEDs associated with it. These LEDs are used for
* speed/link configuration as well as activity indicator configuration. Up to
* three LEDs can be configured, one for activity and two for speeds.
*/
/* Input (64 bytes) */
struct hwrm_port_led_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the led0_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_ID UINT32_C(0x1)
/* This bit must be '1' for the led0_state field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_STATE UINT32_C(0x2)
/* This bit must be '1' for the led0_color field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_COLOR UINT32_C(0x4)
/* This bit must be '1' for the led0_blink_on field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_BLINK_ON UINT32_C(0x8)
/* This bit must be '1' for the led0_blink_off field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_BLINK_OFF UINT32_C(0x10)
/* This bit must be '1' for the led0_group_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED0_GROUP_ID UINT32_C(0x20)
/* This bit must be '1' for the led1_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_ID UINT32_C(0x40)
/* This bit must be '1' for the led1_state field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_STATE UINT32_C(0x80)
/* This bit must be '1' for the led1_color field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_COLOR UINT32_C(0x100)
/* This bit must be '1' for the led1_blink_on field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_BLINK_ON UINT32_C(0x200)
/* This bit must be '1' for the led1_blink_off field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_BLINK_OFF UINT32_C(0x400)
/* This bit must be '1' for the led1_group_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED1_GROUP_ID UINT32_C(0x800)
/* This bit must be '1' for the led2_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_ID UINT32_C(0x1000)
/* This bit must be '1' for the led2_state field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_STATE UINT32_C(0x2000)
/* This bit must be '1' for the led2_color field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_COLOR UINT32_C(0x4000)
/* This bit must be '1' for the led2_blink_on field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_BLINK_ON UINT32_C(0x8000)
/* This bit must be '1' for the led2_blink_off field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_BLINK_OFF UINT32_C(0x10000)
/* This bit must be '1' for the led2_group_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED2_GROUP_ID UINT32_C(0x20000)
/* This bit must be '1' for the led3_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_ID UINT32_C(0x40000)
/* This bit must be '1' for the led3_state field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_STATE UINT32_C(0x80000)
/* This bit must be '1' for the led3_color field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_COLOR UINT32_C(0x100000)
/* This bit must be '1' for the led3_blink_on field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_BLINK_ON UINT32_C(0x200000)
/* This bit must be '1' for the led3_blink_off field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_BLINK_OFF UINT32_C(0x400000)
/* This bit must be '1' for the led3_group_id field to be configured. */
#define HWRM_PORT_LED_CFG_INPUT_ENABLES_LED3_GROUP_ID UINT32_C(0x800000)
uint16_t port_id;
/* Port ID of port whose LEDs are configured. */
uint8_t num_leds;
/*
* The number of LEDs that are being configured. Up to 4 LEDs can be
* configured with this command.
*/
uint8_t rsvd;
/* Reserved field. */
uint8_t led0_id;
/* An identifier for the LED #0. */
uint8_t led0_state;
/* The requested state of the LED #0. */
/* Default state of the LED */
#define HWRM_PORT_LED_CFG_INPUT_LED0_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_CFG_INPUT_LED0_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_CFG_INPUT_LED0_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_CFG_INPUT_LED0_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_CFG_INPUT_LED0_STATE_BLINKALT UINT32_C(0x4)
uint8_t led0_color;
/* The requested color of LED #0. */
/* Default */
#define HWRM_PORT_LED_CFG_INPUT_LED0_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED0_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_CFG_INPUT_LED0_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED0_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_0;
uint16_t led0_blink_on;
/*
* If the LED #0 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led0_blink_off;
/*
* If the LED #0 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led0_group_id;
/*
* An identifier for the group of LEDs that LED #0 belongs to. If set to
* 0, then the LED #0 shall not be grouped and shall be treated as an
* individual resource. For all other non-zero values of this field, LED
* #0 shall be grouped together with the LEDs with the same group ID
* value.
*/
uint8_t rsvd0;
/* Reserved field. */
uint8_t led1_id;
/* An identifier for the LED #1. */
uint8_t led1_state;
/* The requested state of the LED #1. */
/* Default state of the LED */
#define HWRM_PORT_LED_CFG_INPUT_LED1_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_CFG_INPUT_LED1_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_CFG_INPUT_LED1_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_CFG_INPUT_LED1_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_CFG_INPUT_LED1_STATE_BLINKALT UINT32_C(0x4)
uint8_t led1_color;
/* The requested color of LED #1. */
/* Default */
#define HWRM_PORT_LED_CFG_INPUT_LED1_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED1_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_CFG_INPUT_LED1_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED1_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_1;
uint16_t led1_blink_on;
/*
* If the LED #1 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led1_blink_off;
/*
* If the LED #1 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led1_group_id;
/*
* An identifier for the group of LEDs that LED #1 belongs to. If set to
* 0, then the LED #1 shall not be grouped and shall be treated as an
* individual resource. For all other non-zero values of this field, LED
* #1 shall be grouped together with the LEDs with the same group ID
* value.
*/
uint8_t rsvd1;
/* Reserved field. */
uint8_t led2_id;
/* An identifier for the LED #2. */
uint8_t led2_state;
/* The requested state of the LED #2. */
/* Default state of the LED */
#define HWRM_PORT_LED_CFG_INPUT_LED2_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_CFG_INPUT_LED2_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_CFG_INPUT_LED2_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_CFG_INPUT_LED2_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_CFG_INPUT_LED2_STATE_BLINKALT UINT32_C(0x4)
uint8_t led2_color;
/* The requested color of LED #2. */
/* Default */
#define HWRM_PORT_LED_CFG_INPUT_LED2_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED2_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_CFG_INPUT_LED2_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED2_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_2;
uint16_t led2_blink_on;
/*
* If the LED #2 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led2_blink_off;
/*
* If the LED #2 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led2_group_id;
/*
* An identifier for the group of LEDs that LED #2 belongs to. If set to
* 0, then the LED #2 shall not be grouped and shall be treated as an
* individual resource. For all other non-zero values of this field, LED
* #2 shall be grouped together with the LEDs with the same group ID
* value.
*/
uint8_t rsvd2;
/* Reserved field. */
uint8_t led3_id;
/* An identifier for the LED #3. */
uint8_t led3_state;
/* The requested state of the LED #3. */
/* Default state of the LED */
#define HWRM_PORT_LED_CFG_INPUT_LED3_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_CFG_INPUT_LED3_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_CFG_INPUT_LED3_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_CFG_INPUT_LED3_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_CFG_INPUT_LED3_STATE_BLINKALT UINT32_C(0x4)
uint8_t led3_color;
/* The requested color of LED #3. */
/* Default */
#define HWRM_PORT_LED_CFG_INPUT_LED3_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED3_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_CFG_INPUT_LED3_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_CFG_INPUT_LED3_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_3;
uint16_t led3_blink_on;
/*
* If the LED #3 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led3_blink_off;
/*
* If the LED #3 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led3_group_id;
/*
* An identifier for the group of LEDs that LED #3 belongs to. If set to
* 0, then the LED #3 shall not be grouped and shall be treated as an
* individual resource. For all other non-zero values of this field, LED
* #3 shall be grouped together with the LEDs with the same group ID
* value.
*/
uint8_t rsvd3;
/* Reserved field. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_port_led_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_led_qcfg */
/*
* Description: This function is used to query configuration of LEDs on a given
* port. Each port has individual set of LEDs associated with it. These LEDs are
* used for speed/link configuration as well as activity indicator
* configuration. Up to three LEDs can be configured, one for activity and two
* for speeds.
*/
/* Input (24 bytes) */
struct hwrm_port_led_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port whose LED configuration is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (56 bytes) */
struct hwrm_port_led_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t num_leds;
/*
* The number of LEDs that are configured on this port. Up to 4 LEDs can
* be returned in the response.
*/
uint8_t led0_id;
/* An identifier for the LED #0. */
uint8_t led0_type;
/* The type of LED #0. */
/* Speed LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_TYPE_INVALID UINT32_C(0xff)
uint8_t led0_state;
/* The current state of the LED #0. */
/* Default state of the LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_STATE_BLINKALT UINT32_C(0x4)
uint8_t led0_color;
/* The color of LED #0. */
/* Default */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED0_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_0;
uint16_t led0_blink_on;
/*
* If the LED #0 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led0_blink_off;
/*
* If the LED #0 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led0_group_id;
/*
* An identifier for the group of LEDs that LED #0 belongs to. If set to
* 0, then the LED #0 is not grouped. For all other non-zero values of
* this field, LED #0 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t led1_id;
/* An identifier for the LED #1. */
uint8_t led1_type;
/* The type of LED #1. */
/* Speed LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_TYPE_INVALID UINT32_C(0xff)
uint8_t led1_state;
/* The current state of the LED #1. */
/* Default state of the LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_STATE_BLINKALT UINT32_C(0x4)
uint8_t led1_color;
/* The color of LED #1. */
/* Default */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED1_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_1;
uint16_t led1_blink_on;
/*
* If the LED #1 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led1_blink_off;
/*
* If the LED #1 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led1_group_id;
/*
* An identifier for the group of LEDs that LED #1 belongs to. If set to
* 0, then the LED #1 is not grouped. For all other non-zero values of
* this field, LED #1 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t led2_id;
/* An identifier for the LED #2. */
uint8_t led2_type;
/* The type of LED #2. */
/* Speed LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_TYPE_INVALID UINT32_C(0xff)
uint8_t led2_state;
/* The current state of the LED #2. */
/* Default state of the LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_STATE_BLINKALT UINT32_C(0x4)
uint8_t led2_color;
/* The color of LED #2. */
/* Default */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED2_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_2;
uint16_t led2_blink_on;
/*
* If the LED #2 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led2_blink_off;
/*
* If the LED #2 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led2_group_id;
/*
* An identifier for the group of LEDs that LED #2 belongs to. If set to
* 0, then the LED #2 is not grouped. For all other non-zero values of
* this field, LED #2 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t led3_id;
/* An identifier for the LED #3. */
uint8_t led3_type;
/* The type of LED #3. */
/* Speed LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_TYPE_INVALID UINT32_C(0xff)
uint8_t led3_state;
/* The current state of the LED #3. */
/* Default state of the LED */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_STATE_DEFAULT UINT32_C(0x0)
/* Off */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_STATE_OFF UINT32_C(0x1)
/* On */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_STATE_ON UINT32_C(0x2)
/* Blink */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_STATE_BLINK UINT32_C(0x3)
/* Blink Alternately */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_STATE_BLINKALT UINT32_C(0x4)
uint8_t led3_color;
/* The color of LED #3. */
/* Default */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_COLOR_DEFAULT UINT32_C(0x0)
/* Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_COLOR_AMBER UINT32_C(0x1)
/* Green */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_COLOR_GREEN UINT32_C(0x2)
/* Green or Amber */
#define HWRM_PORT_LED_QCFG_OUTPUT_LED3_COLOR_GREENAMBER UINT32_C(0x3)
uint8_t unused_3;
uint16_t led3_blink_on;
/*
* If the LED #3 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED on between
* cycles.
*/
uint16_t led3_blink_off;
/*
* If the LED #3 state is "blink" or "blinkalt", then this field
* represents the requested time in milliseconds to keep LED off between
* cycles.
*/
uint8_t led3_group_id;
/*
* An identifier for the group of LEDs that LED #3 belongs to. If set to
* 0, then the LED #3 is not grouped. For all other non-zero values of
* this field, LED #3 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t unused_4;
uint16_t unused_5;
uint8_t unused_6;
uint8_t unused_7;
uint8_t unused_8;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_port_led_qcaps */
/*
* Description: This function is used to query capabilities of LEDs on a given
* port. Each port has individual set of LEDs associated with it. These LEDs are
* used for speed/link configuration as well as activity indicator
* configuration.
*/
/* Input (24 bytes) */
struct hwrm_port_led_qcaps_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port whose LED configuration is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (48 bytes) */
struct hwrm_port_led_qcaps_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t num_leds;
/*
* The number of LEDs that are configured on this port. Up to 4 LEDs can
* be returned in the response.
*/
uint8_t unused_0[3];
/* Reserved for future use. */
uint8_t led0_id;
/* An identifier for the LED #0. */
uint8_t led0_type;
/* The type of LED #0. */
/* Speed LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_TYPE_INVALID UINT32_C(0xff)
uint8_t led0_group_id;
/*
* An identifier for the group of LEDs that LED #0 belongs to. If set to
* 0, then the LED #0 cannot be grouped. For all other non-zero values
* of this field, LED #0 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t unused_1;
uint16_t led0_state_caps;
/* The states supported by LED #0. */
/* If set to 1, this LED is enabled. If set to 0, this LED is disabled. */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_STATE_CAPS_ENABLED UINT32_C(0x1)
/*
* If set to 1, off state is supported on this LED. If set to 0, off
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_STATE_CAPS_OFF_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, on state is supported on this LED. If set to 0, on state
* is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_STATE_CAPS_ON_SUPPORTED UINT32_C(0x4)
/*
* If set to 1, blink state is supported on this LED. If set to 0, blink
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_STATE_CAPS_BLINK_SUPPORTED UINT32_C(0x8)
/*
* If set to 1, blink_alt state is supported on this LED. If set to 0,
* blink_alt state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_STATE_CAPS_BLINK_ALT_SUPPORTED UINT32_C(0x10)
uint16_t led0_color_caps;
/* The colors supported by LED #0. */
/* reserved */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_COLOR_CAPS_RSVD UINT32_C(0x1)
/*
* If set to 1, Amber color is supported on this LED. If set to 0, Amber
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_COLOR_CAPS_AMBER_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, Green color is supported on this LED. If set to 0, Green
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED0_COLOR_CAPS_GREEN_SUPPORTED UINT32_C(0x4)
uint8_t led1_id;
/* An identifier for the LED #1. */
uint8_t led1_type;
/* The type of LED #1. */
/* Speed LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_TYPE_INVALID UINT32_C(0xff)
uint8_t led1_group_id;
/*
* An identifier for the group of LEDs that LED #1 belongs to. If set to
* 0, then the LED #0 cannot be grouped. For all other non-zero values
* of this field, LED #0 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t unused_2;
uint16_t led1_state_caps;
/* The states supported by LED #1. */
/* If set to 1, this LED is enabled. If set to 0, this LED is disabled. */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_STATE_CAPS_ENABLED UINT32_C(0x1)
/*
* If set to 1, off state is supported on this LED. If set to 0, off
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_STATE_CAPS_OFF_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, on state is supported on this LED. If set to 0, on state
* is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_STATE_CAPS_ON_SUPPORTED UINT32_C(0x4)
/*
* If set to 1, blink state is supported on this LED. If set to 0, blink
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_STATE_CAPS_BLINK_SUPPORTED UINT32_C(0x8)
/*
* If set to 1, blink_alt state is supported on this LED. If set to 0,
* blink_alt state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_STATE_CAPS_BLINK_ALT_SUPPORTED UINT32_C(0x10)
uint16_t led1_color_caps;
/* The colors supported by LED #1. */
/* reserved */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_COLOR_CAPS_RSVD UINT32_C(0x1)
/*
* If set to 1, Amber color is supported on this LED. If set to 0, Amber
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_COLOR_CAPS_AMBER_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, Green color is supported on this LED. If set to 0, Green
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED1_COLOR_CAPS_GREEN_SUPPORTED UINT32_C(0x4)
uint8_t led2_id;
/* An identifier for the LED #2. */
uint8_t led2_type;
/* The type of LED #2. */
/* Speed LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_TYPE_INVALID UINT32_C(0xff)
uint8_t led2_group_id;
/*
* An identifier for the group of LEDs that LED #0 belongs to. If set to
* 0, then the LED #0 cannot be grouped. For all other non-zero values
* of this field, LED #0 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t unused_3;
uint16_t led2_state_caps;
/* The states supported by LED #2. */
/* If set to 1, this LED is enabled. If set to 0, this LED is disabled. */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_STATE_CAPS_ENABLED UINT32_C(0x1)
/*
* If set to 1, off state is supported on this LED. If set to 0, off
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_STATE_CAPS_OFF_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, on state is supported on this LED. If set to 0, on state
* is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_STATE_CAPS_ON_SUPPORTED UINT32_C(0x4)
/*
* If set to 1, blink state is supported on this LED. If set to 0, blink
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_STATE_CAPS_BLINK_SUPPORTED UINT32_C(0x8)
/*
* If set to 1, blink_alt state is supported on this LED. If set to 0,
* blink_alt state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_STATE_CAPS_BLINK_ALT_SUPPORTED UINT32_C(0x10)
uint16_t led2_color_caps;
/* The colors supported by LED #2. */
/* reserved */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_COLOR_CAPS_RSVD UINT32_C(0x1)
/*
* If set to 1, Amber color is supported on this LED. If set to 0, Amber
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_COLOR_CAPS_AMBER_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, Green color is supported on this LED. If set to 0, Green
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED2_COLOR_CAPS_GREEN_SUPPORTED UINT32_C(0x4)
uint8_t led3_id;
/* An identifier for the LED #3. */
uint8_t led3_type;
/* The type of LED #3. */
/* Speed LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_TYPE_SPEED UINT32_C(0x0)
/* Activity LED */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_TYPE_ACTIVITY UINT32_C(0x1)
/* Invalid */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_TYPE_INVALID UINT32_C(0xff)
uint8_t led3_group_id;
/*
* An identifier for the group of LEDs that LED #3 belongs to. If set to
* 0, then the LED #0 cannot be grouped. For all other non-zero values
* of this field, LED #0 is grouped together with the LEDs with the same
* group ID value.
*/
uint8_t unused_4;
uint16_t led3_state_caps;
/* The states supported by LED #3. */
/* If set to 1, this LED is enabled. If set to 0, this LED is disabled. */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_STATE_CAPS_ENABLED UINT32_C(0x1)
/*
* If set to 1, off state is supported on this LED. If set to 0, off
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_STATE_CAPS_OFF_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, on state is supported on this LED. If set to 0, on state
* is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_STATE_CAPS_ON_SUPPORTED UINT32_C(0x4)
/*
* If set to 1, blink state is supported on this LED. If set to 0, blink
* state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_STATE_CAPS_BLINK_SUPPORTED UINT32_C(0x8)
/*
* If set to 1, blink_alt state is supported on this LED. If set to 0,
* blink_alt state is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_STATE_CAPS_BLINK_ALT_SUPPORTED UINT32_C(0x10)
uint16_t led3_color_caps;
/* The colors supported by LED #3. */
/* reserved */
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_COLOR_CAPS_RSVD UINT32_C(0x1)
/*
* If set to 1, Amber color is supported on this LED. If set to 0, Amber
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_COLOR_CAPS_AMBER_SUPPORTED UINT32_C(0x2)
/*
* If set to 1, Green color is supported on this LED. If set to 0, Green
* color is not supported on this LED.
*/
#define HWRM_PORT_LED_QCAPS_OUTPUT_LED3_COLOR_CAPS_GREEN_SUPPORTED UINT32_C(0x4)
uint8_t unused_5;
uint8_t unused_6;
uint8_t unused_7;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_qportcfg */
/*
* Description: This function is called by a driver to query queue configuration
* of a port. # The HWRM shall at least advertise one queue with lossy service
* profile. # The driver shall use this command to query queue ids before
* configuring or using any queues. # If a service profile is not set for a
* queue, then the driver shall not use that queue without configuring a service
* profile for it. # If the driver is not allowed to configure service profiles,
* then the driver shall only use queues for which service profiles are pre-
* configured.
*/
/* Input (24 bytes) */
struct hwrm_queue_qportcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_QUEUE_QPORTCFG_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_QUEUE_QPORTCFG_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_QUEUE_QPORTCFG_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_QUEUE_QPORTCFG_INPUT_FLAGS_PATH_LAST HWRM_QUEUE_QPORTCFG_INPUT_FLAGS_PATH_RX
uint16_t port_id;
/*
* Port ID of port for which the queue configuration is being queried.
* This field is only required when sent by IPC.
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_queue_qportcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t max_configurable_queues;
/*
* The maximum number of queues that can be configured on this port.
* Valid values range from 1 through 8.
*/
uint8_t max_configurable_lossless_queues;
/*
* The maximum number of lossless queues that can be configured on this
* port. Valid values range from 0 through 8.
*/
uint8_t queue_cfg_allowed;
/*
* Bitmask indicating which queues can be configured by the
* hwrm_queue_cfg command. Each bit represents a specific queue where
* bit 0 represents queue 0 and bit 7 represents queue 7. # A value of 0
* indicates that the queue is not configurable by the hwrm_queue_cfg
* command. # A value of 1 indicates that the queue is configurable. # A
* hwrm_queue_cfg command shall return error when trying to configure a
* queue not configurable.
*/
uint8_t queue_cfg_info;
/* Information about queue configuration. */
/*
* If this flag is set to '1', then the queues are configured
* asymmetrically on TX and RX sides. If this flag is set to '0', then
* the queues are configured symmetrically on TX and RX sides. For
* symmetric configuration, the queue configuration including queue ids
* and service profiles on the TX side is the same as the corresponding
* queue configuration on the RX side.
*/
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_CFG_INFO_ASYM_CFG UINT32_C(0x1)
uint8_t queue_pfcenable_cfg_allowed;
/*
* Bitmask indicating which queues can be configured by the
* hwrm_queue_pfcenable_cfg command. Each bit represents a specific
* priority where bit 0 represents priority 0 and bit 7 represents
* priority 7. # A value of 0 indicates that the priority is not
* configurable by the hwrm_queue_pfcenable_cfg command. # A value of 1
* indicates that the priority is configurable. # A
* hwrm_queue_pfcenable_cfg command shall return error when trying to
* configure a priority that is not configurable.
*/
uint8_t queue_pri2cos_cfg_allowed;
/*
* Bitmask indicating which queues can be configured by the
* hwrm_queue_pri2cos_cfg command. Each bit represents a specific queue
* where bit 0 represents queue 0 and bit 7 represents queue 7. # A
* value of 0 indicates that the queue is not configurable by the
* hwrm_queue_pri2cos_cfg command. # A value of 1 indicates that the
* queue is configurable. # A hwrm_queue_pri2cos_cfg command shall
* return error when trying to configure a queue that is not
* configurable.
*/
uint8_t queue_cos2bw_cfg_allowed;
/*
* Bitmask indicating which queues can be configured by the
* hwrm_queue_pri2cos_cfg command. Each bit represents a specific queue
* where bit 0 represents queue 0 and bit 7 represents queue 7. # A
* value of 0 indicates that the queue is not configurable by the
* hwrm_queue_pri2cos_cfg command. # A value of 1 indicates that the
* queue is configurable. # A hwrm_queue_pri2cos_cfg command shall
* return error when trying to configure a queue not configurable.
*/
uint8_t queue_id0;
/*
* ID of CoS Queue 0. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id0_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID0_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID0_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID0_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id1;
/*
* ID of CoS Queue 1. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id1_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID1_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID1_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID1_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id2;
/*
* ID of CoS Queue 2. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id2_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID2_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID2_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID2_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id3;
/*
* ID of CoS Queue 3. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id3_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID3_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID3_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID3_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id4;
/*
* ID of CoS Queue 4. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id4_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID4_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID4_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID4_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id5;
/*
* ID of CoS Queue 5. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id5_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID5_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID5_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID5_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id6;
/*
* ID of CoS Queue 6. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id6_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID6_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID6_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID6_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_id7;
/*
* ID of CoS Queue 7. FF - Invalid id # This ID can be used on any
* subsequent call to an hwrm command that takes a queue id. # IDs must
* always be queried by this command before any use by the driver or
* software. # Any driver or software should not make any assumptions
* about queue IDs. # A value of 0xff indicates that the queue is not
* available. # Available queues may not be in sequential order.
*/
uint8_t queue_id7_service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID7_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID7_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QPORTCFG_OUTPUT_QUEUE_ID7_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_qcfg */
/*
* Description: This function is called by a driver to query a queue
* configuration.
*/
/* Input (24 bytes) */
struct hwrm_queue_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_QUEUE_QCFG_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_QUEUE_QCFG_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_QUEUE_QCFG_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_QUEUE_QCFG_INPUT_FLAGS_PATH_LAST HWRM_QUEUE_QCFG_INPUT_FLAGS_PATH_RX
uint32_t queue_id;
/* Queue ID of the queue. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t queue_len;
/* This value is a the estimate packet length used in the TX arbiter. */
uint8_t service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_QCFG_OUTPUT_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_QCFG_OUTPUT_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_QCFG_OUTPUT_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t queue_cfg_info;
/* Information about queue configuration. */
/*
* If this flag is set to '1', then the queue is configured
* asymmetrically on TX and RX sides. If this flag is set to '0', then
* this queue is configured symmetrically on TX and RX sides.
*/
#define HWRM_QUEUE_QCFG_OUTPUT_QUEUE_CFG_INFO_ASYM_CFG UINT32_C(0x1)
uint8_t unused_0;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_cfg */
/* Description: This function is called by a driver to configure a queue. */
/* Input (40 bytes) */
struct hwrm_queue_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX, or both directions applicable to the
* resource. This enumeration is used for resources that are similar for
* both TX and RX paths of the chip.
*/
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_MASK UINT32_C(0x3)
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_SFT 0
/* tx path */
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
/* Bi-directional (Symmetrically applicable to TX and RX paths) */
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_BIDIR UINT32_C(0x2)
#define HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_LAST HWRM_QUEUE_CFG_INPUT_FLAGS_PATH_BIDIR
uint32_t enables;
/* This bit must be '1' for the dflt_len field to be configured. */
#define HWRM_QUEUE_CFG_INPUT_ENABLES_DFLT_LEN UINT32_C(0x1)
/* This bit must be '1' for the service_profile field to be configured. */
#define HWRM_QUEUE_CFG_INPUT_ENABLES_SERVICE_PROFILE UINT32_C(0x2)
uint32_t queue_id;
/* Queue ID of queue that is to be configured by this function. */
uint32_t dflt_len;
/*
* This value is a the estimate packet length used in the TX arbiter.
* Set to 0xFF... (All Fs) to not adjust this value.
*/
uint8_t service_profile;
/* This value is applicable to CoS queues only. */
/* Lossy (best-effort) */
#define HWRM_QUEUE_CFG_INPUT_SERVICE_PROFILE_LOSSY UINT32_C(0x0)
/* Lossless */
#define HWRM_QUEUE_CFG_INPUT_SERVICE_PROFILE_LOSSLESS UINT32_C(0x1)
/* Set to 0xFF... (All Fs) if there is no service profile specified */
#define HWRM_QUEUE_CFG_INPUT_SERVICE_PROFILE_UNKNOWN UINT32_C(0xff)
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_pfcenable_qcfg */
/*
* Description: This function is called by a driver to query PFC configuration
* for different priorities on that port. This mapping can be different on
* different ports.
*/
/* Input (24 bytes) */
struct hwrm_queue_pfcenable_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_pfcenable_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t flags;
/* If set to 1, then PFC is enabled on PRI 0. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI0_PFC_ENABLED UINT32_C(0x1)
/* If set to 1, then PFC is enabled on PRI 1. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI1_PFC_ENABLED UINT32_C(0x2)
/* If set to 1, then PFC is enabled on PRI 2. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI2_PFC_ENABLED UINT32_C(0x4)
/* If set to 1, then PFC is enabled on PRI 3. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI3_PFC_ENABLED UINT32_C(0x8)
/* If set to 1, then PFC is enabled on PRI 4. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI4_PFC_ENABLED UINT32_C(0x10)
/* If set to 1, then PFC is enabled on PRI 5. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI5_PFC_ENABLED UINT32_C(0x20)
/* If set to 1, then PFC is enabled on PRI 6. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI6_PFC_ENABLED UINT32_C(0x40)
/* If set to 1, then PFC is enabled on PRI 7. */
#define HWRM_QUEUE_PFCENABLE_QCFG_OUTPUT_FLAGS_PRI7_PFC_ENABLED UINT32_C(0x80)
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_pfcenable_cfg */
/*
* Description: This function is called by a driver to configure the PFC enabled
* for different priorities on that port. This mapping can be different on
* different ports.
*/
/* Input (24 bytes) */
struct hwrm_queue_pfcenable_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/* If set to 1, then PFC is requested to be enabled on PRI 0. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI0_PFC_ENABLED UINT32_C(0x1)
/* If set to 1, then PFC is requested to be enabled on PRI 1. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI1_PFC_ENABLED UINT32_C(0x2)
/* If set to 1, then PFC is requested to be enabled on PRI 2. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI2_PFC_ENABLED UINT32_C(0x4)
/* If set to 1, then PFC is requested to be enabled on PRI 3. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI3_PFC_ENABLED UINT32_C(0x8)
/* If set to 1, then PFC is requested to be enabled on PRI 4. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI4_PFC_ENABLED UINT32_C(0x10)
/* If set to 1, then PFC is requested to be enabled on PRI 5. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI5_PFC_ENABLED UINT32_C(0x20)
/* If set to 1, then PFC is requested to be enabled on PRI 6. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI6_PFC_ENABLED UINT32_C(0x40)
/* If set to 1, then PFC is requested to be enabled on PRI 7. */
#define HWRM_QUEUE_PFCENABLE_CFG_INPUT_FLAGS_PRI7_PFC_ENABLED UINT32_C(0x80)
uint16_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_pfcenable_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_pri2cos_qcfg */
/*
* Description: This function is called by a driver to query configuration of
* the priority to CoS queue mapping on the transmit side and receive side. This
* mapping can be different in each direction (TX or RX). This mapping can be
* different on different ports. Each CoS queue represents a Traffic Class (TC)
* on that port.
*/
/* Input (24 bytes) */
struct hwrm_queue_pri2cos_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_PATH_TX (UINT32_C(0x0) << 0)
/* rx path */
#define HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_PATH_RX (UINT32_C(0x1) << 0)
#define HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_PATH_LAST HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_PATH_RX
/*
* When this bit is set to '0', the query is for VLAN PRI field in
* tunnel headers. When this bit is set to '1', the query is for VLAN
* PRI field in inner packet headers.
*/
#define HWRM_QUEUE_PRI2COS_QCFG_INPUT_FLAGS_IVLAN UINT32_C(0x2)
uint8_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint8_t unused_0[3];
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_queue_pri2cos_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t pri0_cos_queue_id;
/*
* CoS Queue assigned to priority 0. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri1_cos_queue_id;
/*
* CoS Queue assigned to priority 1. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri2_cos_queue_id;
/*
* CoS Queue assigned to priority 2 This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri3_cos_queue_id;
/*
* CoS Queue assigned to priority 3. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri4_cos_queue_id;
/*
* CoS Queue assigned to priority 4. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri5_cos_queue_id;
/*
* CoS Queue assigned to priority 5. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri6_cos_queue_id;
/*
* CoS Queue assigned to priority 6. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t pri7_cos_queue_id;
/*
* CoS Queue assigned to priority 7. This value can only be changed
* before traffic has started. A value of 0xff indicates that no CoS
* queue is assigned to the specified priority.
*/
uint8_t queue_cfg_info;
/* Information about queue configuration. */
/*
* If this flag is set to '1', then the PRI to CoS configuration is
* asymmetric on TX and RX sides. If this flag is set to '0', then PRI
* to CoS configuration is symmetric on TX and RX sides.
*/
#define HWRM_QUEUE_PRI2COS_QCFG_OUTPUT_QUEUE_CFG_INFO_ASYM_CFG UINT32_C(0x1)
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_pri2cos_cfg */
/*
* Description: This function is called by a driver to configure the priority to
* CoS queue mapping on the transmit side and receive side. This mapping can be
* different in each direction (TX or RX). This mapping can be different on
* different ports. Each CoS queue represents a Traffic Class (TC) on that port.
* This command configures the VLAN PRI-to-TC mapping for a specific port in
* specific direction.
*/
/* Input (40 bytes) */
struct hwrm_queue_pri2cos_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX, or both directions applicable to the
* resource. This enumeration is used for resources that are similar for
* both TX and RX paths of the chip.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_MASK UINT32_C(0x3)
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_SFT 0
/* tx path */
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_TX (UINT32_C(0x0) << 0)
/* rx path */
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_RX (UINT32_C(0x1) << 0)
/* Bi-directional (Symmetrically applicable to TX and RX paths) */
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_BIDIR (UINT32_C(0x2) << 0)
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_LAST HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_PATH_BIDIR
/*
* When this bit is set to '0', the mapping is requested for VLAN PRI
* field in tunnel headers. When this bit is set to '1', the mapping is
* requested for VLAN PRI field in inner packet headers.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_FLAGS_IVLAN UINT32_C(0x4)
uint32_t enables;
/*
* This bit must be '1' for the pri0_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI0_COS_QUEUE_ID UINT32_C(0x1)
/*
* This bit must be '1' for the pri1_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI1_COS_QUEUE_ID UINT32_C(0x2)
/*
* This bit must be '1' for the pri2_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI2_COS_QUEUE_ID UINT32_C(0x4)
/*
* This bit must be '1' for the pri3_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI3_COS_QUEUE_ID UINT32_C(0x8)
/*
* This bit must be '1' for the pri4_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI4_COS_QUEUE_ID UINT32_C(0x10)
/*
* This bit must be '1' for the pri5_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI5_COS_QUEUE_ID UINT32_C(0x20)
/*
* This bit must be '1' for the pri6_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI6_COS_QUEUE_ID UINT32_C(0x40)
/*
* This bit must be '1' for the pri7_cos_queue_id field to be
* configured.
*/
#define HWRM_QUEUE_PRI2COS_CFG_INPUT_ENABLES_PRI7_COS_QUEUE_ID UINT32_C(0x80)
uint8_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint8_t pri0_cos_queue_id;
/*
* CoS Queue assigned to priority 0. This value can only be changed
* before traffic has started.
*/
uint8_t pri1_cos_queue_id;
/*
* CoS Queue assigned to priority 1. This value can only be changed
* before traffic has started.
*/
uint8_t pri2_cos_queue_id;
/*
* CoS Queue assigned to priority 2 This value can only be changed
* before traffic has started.
*/
uint8_t pri3_cos_queue_id;
/*
* CoS Queue assigned to priority 3. This value can only be changed
* before traffic has started.
*/
uint8_t pri4_cos_queue_id;
/*
* CoS Queue assigned to priority 4. This value can only be changed
* before traffic has started.
*/
uint8_t pri5_cos_queue_id;
/*
* CoS Queue assigned to priority 5. This value can only be changed
* before traffic has started.
*/
uint8_t pri6_cos_queue_id;
/*
* CoS Queue assigned to priority 6. This value can only be changed
* before traffic has started.
*/
uint8_t pri7_cos_queue_id;
/*
* CoS Queue assigned to priority 7. This value can only be changed
* before traffic has started.
*/
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_pri2cos_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_cos2bw_qcfg */
/*
* Description: This function is called by a driver to query the BW to CoS queue
* mapping on the transmit side of a specific port. This mapping can be
* different on different ports. Each CoS queue represents a Traffic Class (TC)
* on that port. Each traffic class can be assigned a valid combination of the
* following: - Minimum bandwidth - Maximum bandwidth - Transmission selection
* algorithm (TSA) - Priority Level (only applies to strict priority COS) -
* Bandwidth weight # A CoS can be SP or non-SP: A SP CoS always gets the strict
* priority. Is an COS min BW is set to 0x0 then it is considered to be non-SP;
* this is a valid configuration. Note: SP provides lower latency in addition to
* reserved bandwidth # For both SP CoS and non-SP CoS, min BW can be specified
* to reserve specific amount of the port BW. # The min BW specified for a CoS
* shall not exceed max port bandwidth. # The total of min BWs specified for all
* CoS shall not exceed max port bandwidth. # For any non-SP CoS, the minimum
* bandwidth guarantees are subject to round-robin scheduling. This allows BW
* reservation with anti-starvation; one CoS will not block another CoS using
* RR. Note: The bandwidth guarantees for any non-SP CoS are met after servicing
* all SP CoS. # An SP CoS can potentially starve other lower priority SP CoS
* and non-SP CoS queues. This can occur to the extent the SP min exceeds the
* available port BW. # For any CoS, max BW can be specified to limit the BW
* consumed by the CoS. # The max BW specified for a CoS shall not exceed the
* max port bandwidth. # The WFQ provides a mechanism for sharing available
* bandwidth beyond the reserved minimums configured for each CoS. The WFQ
* scheduler is used to provide the percentages of remaining bandwidth after: *
* first servicing the reserved bandwidth for all SP CoS, * followed by the
* reserved bandwidth for all non-SP CoS * All CoS may participate in the WFQ #
* If a CoS does not have a configured max BW it may use all available bandwidth
* up to the max port bandwidth Minimum Bandwidth (min BW): # This is the
* guaranteed bandwidth for the COS. # A value of 0x0 is valid and it means that
* this COS is not guaranteed any bandwidth. A value of 0xFF.. (all Fs) means
* min BW is not specified. When the min BW is not specified, the HWRM can set
* it to any value it considers appropriate. Note: For a non-SP COS, the HWRM
* should set min BW to 0 when the min BW is not specified. For an SP COS, the
* HWRM should set min BW to some small value when the min BW is not specified.
* Maximum Bandwidth: # This is the bandwidth limit of the COS. # Values 0x0 and
* 0xFF.. (all Fs) are considered unspecified and the HWRM will set the maximum
* bandwidth to maximum port bandwidth. Priority Level: # It applies only to SP.
* # This parameter is ignored for non-SP. # 0-7 are valid values (higher value
* means higher priority) # A priority level can be assigned to at most one SP.
* # Invalid priority levels assignment for SPs shall result in failure.
* Additional notes: # The HWRM may have to use min and (max - min) to set
* appropriate counters of hardware rate limiters. # The bandwidth percentage as
* specified in the DCB TC BW assignment should be used by the driver to specify
* maximum bandwidth and bandwidth weight for a COS. For example, the driver
* should set max BW to 20 Gbps and weight to 50 for two COSs when these two
* COSs are assigned 50% share of 40 Gbps max port bandwidth.
*/
/* Input (24 bytes) */
struct hwrm_queue_cos2bw_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure TC BW
* assignment on this port.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (112 bytes) */
struct hwrm_queue_cos2bw_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t queue_id0;
/* ID of CoS Queue 0. */
uint8_t unused_0;
uint16_t unused_1;
uint32_t queue_id0_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id0_max_bw;
/*
* Maximum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id0_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID0_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id0_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id0_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id1;
/* ID of CoS Queue 1. */
uint32_t queue_id1_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id1_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id1_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID1_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id1_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id1_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id2;
/* ID of CoS Queue 2. */
uint32_t queue_id2_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id2_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id2_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID2_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id2_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id2_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id3;
/* ID of CoS Queue 3. */
uint32_t queue_id3_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id3_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id3_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID3_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id3_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id3_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id4;
/* ID of CoS Queue 4. */
uint32_t queue_id4_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id4_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id4_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID4_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id4_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id4_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id5;
/* ID of CoS Queue 5. */
uint32_t queue_id5_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id5_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id5_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID5_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id5_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id5_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id6;
/* ID of CoS Queue 6. */
uint32_t queue_id6_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id6_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id6_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID6_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id6_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id6_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id7;
/* ID of CoS Queue 7. */
uint32_t queue_id7_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id7_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id7_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_QCFG_OUTPUT_QUEUE_ID7_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id7_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id7_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_cos2bw_cfg */
/*
* Description: This function is called by a driver to configure the BW to CoS
* queue mapping on the transmit side of a specific port. This mapping can be
* different on different ports. Each CoS queue represents a Traffic Class (TC)
* on that port. Each traffic class can be assigned a valid combination of the
* following: - Minimum bandwidth - Maximum bandwidth - Transmission selection
* algorithm (TSA) - Priority Level (only applies to strict priority COS) -
* Bandwidth weight # A CoS can be SP or non-SP: A SP CoS always gets the strict
* priority. Note: SP provides lower latency in addition to reserved bandwidth #
* For non-SP CoS, min BW can be specified to reserve specific amount of the
* port BW. # The min BW specified for a CoS shall not exceed max port
* bandwidth. # The total of min BWs specified for all CoS shall not exceed max
* port bandwidth. # For any non-SP CoS, the minimum bandwidth guarantees are
* subject to round-robin scheduling. This allows BW reservation with anti-
* starvation; one CoS will not block another CoS using RR. Note: The bandwidth
* guarantees for any non-SP CoS are met after servicing all SP CoS. # An SP CoS
* can potentially starve other lower priority SP CoS and non-SP CoS queues.
* This can occur to the extent the SP min exceeds the available port BW. # For
* any CoS, max BW can be specified to limit the BW consumed by the CoS. # A max
* BW can be used for a SP CoS to limit the starvation of other CoS, but using
* this will cause some characteristics of any ETS CoS to be violated. # The max
* BW specified for a CoS shall not exceed the max port bandwidth. # For SP CoS,
* it is recommended to set min and max BW to 0. This instructs the adapter to
* use default values. # The WFQ provides a mechanism for sharing available
* bandwidth beyond the reserved minimums configured for each CoS. The WFQ
* scheduler is used to provide the percentages of remaining bandwidth after: -
* first servicing the reserved bandwidth for all SP CoS, - followed by the
* reserved bandwidth for all non-SP CoS - All CoS may participate in the WFQ #
* If a CoS does not have a configured max BW it may use all available bandwidth
* up to the max port bandwidth Minimum Bandwidth (min BW): # This is the
* guaranteed bandwidth for the COS. # A value of 0x0 is valid and it means that
* this COS is not guaranteed any bandwidth. A value of 0xFF.. (all Fs) means
* min BW is not specified. When the min BW is not specified, the HWRM can set
* it to any value it considers appropriate. Note: For a non-SP COS, the HWRM
* should set min BW to 0 when the min BW is not specified. For an SP COS, min
* BW value is ignored. Maximum Bandwidth: # This is the bandwidth limit of the
* COS. # Values 0x0 and 0xFF.. (all Fs) are considered unspecified and the HWRM
* will set the maximum bandwidth to maximum port bandwidth. Priority Level: #
* It applies only to SP. # This parameter is ignored for non-SP. # 0-7 are
* valid values (higher value means higher priority) # A priority level can be
* assigned to at most one SP. # Invalid priority levels assignment for SPs
* shall result in failure. Additional notes: # The HWRM may have to use min and
* (max - min) to set appropriate counters of hardware rate limiters. # The
* bandwidth percentage as specified in the DCB TC BW assignment should be used
* by the driver to specify minimum bandwidth and bandwidth weight for a COS.
* For example, the driver should set max BW to 20 Gbps and weight to 50 for two
* COSs when these two COSs are assigned 50% share of 40 Gbps max port
* bandwidth. DCBX use cases should always use max BW of 100% for all ETS CoS
* queues.
*/
/* Input (128 bytes) */
struct hwrm_queue_cos2bw_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
uint32_t enables;
/*
* If this bit is set to 1, then all queue_id0 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID0_VALID UINT32_C(0x1)
/*
* If this bit is set to 1, then all queue_id1 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID1_VALID UINT32_C(0x2)
/*
* If this bit is set to 1, then all queue_id2 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID2_VALID UINT32_C(0x4)
/*
* If this bit is set to 1, then all queue_id3 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID3_VALID UINT32_C(0x8)
/*
* If this bit is set to 1, then all queue_id4 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID4_VALID UINT32_C(0x10)
/*
* If this bit is set to 1, then all queue_id5 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID5_VALID UINT32_C(0x20)
/*
* If this bit is set to 1, then all queue_id6 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID6_VALID UINT32_C(0x40)
/*
* If this bit is set to 1, then all queue_id7 related parameters in
* this command are valid.
*/
#define HWRM_QUEUE_COS2BW_CFG_INPUT_ENABLES_COS_QUEUE_ID7_VALID UINT32_C(0x80)
uint16_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure TC BW
* assignment on this port.
*/
uint8_t queue_id0;
/* ID of CoS Queue 0. */
uint8_t unused_0;
uint32_t queue_id0_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id0_max_bw;
/*
* Maximum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id0_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID0_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id0_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id0_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id1;
/* ID of CoS Queue 1. */
uint32_t queue_id1_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id1_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id1_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID1_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id1_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id1_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id2;
/* ID of CoS Queue 2. */
uint32_t queue_id2_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id2_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id2_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID2_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id2_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id2_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id3;
/* ID of CoS Queue 3. */
uint32_t queue_id3_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id3_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id3_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID3_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id3_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id3_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id4;
/* ID of CoS Queue 4. */
uint32_t queue_id4_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id4_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id4_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID4_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id4_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id4_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id5;
/* ID of CoS Queue 5. */
uint32_t queue_id5_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id5_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id5_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID5_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id5_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id5_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id6;
/* ID of CoS Queue 6. */
uint32_t queue_id6_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id6_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id6_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID6_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id6_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id6_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t queue_id7;
/* ID of CoS Queue 7. */
uint32_t queue_id7_min_bw;
/*
* Minimum BW allocated to CoS Queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MIN_BW_BW_VALUE_UNIT_INVALID
uint32_t queue_id7_max_bw;
/*
* Maximum BW allocated to CoS queue. The HWRM will translate this value
* into byte counter and time interval used for this COS inside the
* device.
*/
/* The bandwidth value. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_SCALE_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_LAST HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t queue_id7_tsa_assign;
/* Transmission Selection Algorithm (TSA) for CoS Queue. */
/* Strict Priority */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_TSA_ASSIGN_SP UINT32_C(0x0)
/* Enhanced Transmission Selection */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_TSA_ASSIGN_ETS UINT32_C(0x1)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_TSA_ASSIGN_RESERVED_FIRST UINT32_C(0x2)
/* reserved */
#define HWRM_QUEUE_COS2BW_CFG_INPUT_QUEUE_ID7_TSA_ASSIGN_RESERVED_LAST UINT32_C(0xff)
uint8_t queue_id7_pri_lvl;
/*
* Priority level for strict priority. Valid only when the tsa_assign is
* 0 - Strict Priority (SP) 0..7 - Valid values. 8..255 - Reserved.
*/
uint8_t queue_id7_bw_weight;
/*
* Weight used to allocate remaining BW for this COS after servicing
* guaranteed bandwidths for all COS.
*/
uint8_t unused_1[5];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_cos2bw_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_dscp_qcaps */
/*
* Description: This command is called by a driver to query the DSCP
* capabilities for a port.
*/
/* Input (24 bytes) */
struct hwrm_queue_dscp_qcaps_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_dscp_qcaps_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t num_dscp_bits;
/* The number of bits provided by the hardware for the DSCP value. */
uint8_t unused_0;
uint16_t max_entries;
/* Max number of DSCP-MASK-PRI entries supported. */
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_dscp2pri_qcfg */
/*
* Description: This command is called by a driver to query configuration of the
* DSCP to PRI mapping on the receive side. This mapping can be different on
* different ports.
*/
/* Input (32 bytes) */
struct hwrm_queue_dscp2pri_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t dest_data_addr;
/*
* This is the host address where the 24-bits DSCP-MASK-PRI tuple(s)
* will be copied to.
*/
uint8_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint8_t unused_0;
uint16_t dest_data_buffer_size;
/* Size of the buffer pointed to by dest_data_addr. */
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_dscp2pri_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t entry_cnt;
/*
* A count of the number of DSCP-MASK-PRI tuple(s) pointed to by the
* dest_data_addr.
*/
uint8_t default_pri;
/*
* This is the default PRI which un-initialized DSCP values are mapped
* to.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_queue_dscp2pri_cfg */
/*
* Description: This command is called by a driver to configure the DSCP to PRI
* mapping on the receive side. This mapping can be different on different
* ports.
*/
/* Input (40 bytes) */
struct hwrm_queue_dscp2pri_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t src_data_addr;
/*
* This is the host address where the 24-bits DSCP-MASK-PRI tuple will
* be copied from.
*/
uint32_t flags;
/* use_hw_default_pri is 1 b */
#define HWRM_QUEUE_DSCP2PRI_CFG_INPUT_FLAGS_USE_HW_DEFAULT_PRI UINT32_C(0x1)
uint32_t enables;
/* This bit must be '1' for the default_pri field to be configured. */
#define HWRM_QUEUE_DSCP2PRI_CFG_INPUT_ENABLES_DEFAULT_PRI UINT32_C(0x1)
uint8_t port_id;
/*
* Port ID of port for which the table is being configured. The HWRM
* needs to check whether this function is allowed to configure pri2cos
* mapping on this port.
*/
uint8_t default_pri;
/*
* This is the default PRI which un-initialized DSCP values will be
* mapped to.
*/
uint16_t entry_cnt;
/*
* A count of the number of DSCP-MASK-PRI tuple(s) in the data pointed
* to by src_data_addr.
*/
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_queue_dscp2pri_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_alloc */
/*
* Description: This VNIC is a resource in the RX side of the chip that is used
* to represent a virtual host "interface". # At the time of VNIC allocation or
* configuration, the function can specify whether it wants the requested VNIC
* to be the default VNIC for the function or not. # If a function requests
* allocation of a VNIC for the first time and a VNIC is successfully allocated
* by the HWRM, then the HWRM shall make the allocated VNIC as the default VNIC
* for that function. # The default VNIC shall be used for the default action
* for a partition or function. # For each VNIC allocated on a function, a
* mapping on the RX side to map the allocated VNIC to source virtual interface
* shall be performed by the HWRM. This should be hidden to the function driver
* requesting the VNIC allocation. This enables broadcast/multicast replication
* with source knockout. # If multicast replication with source knockout is
* enabled, then the internal VNIC to SVIF mapping data structures shall be
* programmed at the time of VNIC allocation.
*/
/* Input (24 bytes) */
struct hwrm_vnic_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', this VNIC is requested to be the default VNIC
* for this function.
*/
#define HWRM_VNIC_ALLOC_INPUT_FLAGS_DEFAULT UINT32_C(0x1)
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t vnic_id;
/* Logical vnic ID */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_free */
/*
* Description: Free a VNIC resource. Idle any resources associated with the
* VNIC as well as the VNIC. Reset and release all resources associated with the
* VNIC.
*/
/* Input (24 bytes) */
struct hwrm_vnic_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t vnic_id;
/* Logical vnic ID */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_cfg */
/* Description: Configure the RX VNIC structure. */
/* Input (40 bytes) */
struct hwrm_vnic_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', the VNIC is requested to be the default VNIC
* for the function.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_DEFAULT UINT32_C(0x1)
/*
* When this bit is '1', the VNIC is being configured to strip VLAN in
* the RX path. If set to '0', then VLAN stripping is disabled on this
* VNIC.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_VLAN_STRIP_MODE UINT32_C(0x2)
/*
* When this bit is '1', the VNIC is being configured to buffer receive
* packets in the hardware until the host posts new receive buffers. If
* set to '0', then bd_stall is being configured to be disabled on this
* VNIC.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_BD_STALL_MODE UINT32_C(0x4)
/*
* When this bit is '1', the VNIC is being configured to receive both
* RoCE and non-RoCE traffic. If set to '0', then this VNIC is not
* configured to be operating in dual VNIC mode.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_ROCE_DUAL_VNIC_MODE UINT32_C(0x8)
/*
* When this flag is set to '1', the VNIC is requested to be configured
* to receive only RoCE traffic. If this flag is set to '0', then this
* flag shall be ignored by the HWRM. If roce_dual_vnic_mode flag is set
* to '1', then the HWRM client shall not set this flag to '1'.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_ROCE_ONLY_VNIC_MODE UINT32_C(0x10)
/*
* When a VNIC uses one destination ring group for certain application
* (e.g. Receive Flow Steering) where exact match is used to direct
* packets to a VNIC with one destination ring group only, there is no
* need to configure RSS indirection table for that VNIC as only one
* destination ring group is used. This flag is used to enable a mode
* where RSS is enabled in the VNIC using a RSS context for computing
* RSS hash but the RSS indirection table is not configured using
* hwrm_vnic_rss_cfg. If this mode is enabled, then the driver should
* not program RSS indirection table for the RSS context that is used
* for computing RSS hash only.
*/
#define HWRM_VNIC_CFG_INPUT_FLAGS_RSS_DFLT_CR_MODE UINT32_C(0x20)
uint32_t enables;
/* This bit must be '1' for the dflt_ring_grp field to be configured. */
#define HWRM_VNIC_CFG_INPUT_ENABLES_DFLT_RING_GRP UINT32_C(0x1)
/* This bit must be '1' for the rss_rule field to be configured. */
#define HWRM_VNIC_CFG_INPUT_ENABLES_RSS_RULE UINT32_C(0x2)
/* This bit must be '1' for the cos_rule field to be configured. */
#define HWRM_VNIC_CFG_INPUT_ENABLES_COS_RULE UINT32_C(0x4)
/* This bit must be '1' for the lb_rule field to be configured. */
#define HWRM_VNIC_CFG_INPUT_ENABLES_LB_RULE UINT32_C(0x8)
/* This bit must be '1' for the mru field to be configured. */
#define HWRM_VNIC_CFG_INPUT_ENABLES_MRU UINT32_C(0x10)
uint16_t vnic_id;
/* Logical vnic ID */
uint16_t dflt_ring_grp;
/*
* Default Completion ring for the VNIC. This ring will be chosen if
* packet does not match any RSS rules and if there is no COS rule.
*/
uint16_t rss_rule;
/*
* RSS ID for RSS rule/table structure. 0xFF... (All Fs) if there is no
* RSS rule.
*/
uint16_t cos_rule;
/*
* RSS ID for COS rule/table structure. 0xFF... (All Fs) if there is no
* COS rule.
*/
uint16_t lb_rule;
/*
* RSS ID for load balancing rule/table structure. 0xFF... (All Fs) if
* there is no LB rule.
*/
uint16_t mru;
/*
* The maximum receive unit of the vnic. Each vnic is associated with a
* function. The vnic mru value overwrites the mru setting of the
* associated function. The HWRM shall make sure that vnic mru does not
* exceed the mru of the port the function is associated with.
*/
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_qcfg */
/*
* Description: Query the RX VNIC structure. This function can be used by a PF
* driver to query its own VNIC resource or VNIC resource of its child VF. This
* function can also be used by a VF driver to query its own VNIC resource.
*/
/* Input (32 bytes) */
struct hwrm_vnic_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the vf_id_valid field to be configured. */
#define HWRM_VNIC_QCFG_INPUT_ENABLES_VF_ID_VALID UINT32_C(0x1)
uint32_t vnic_id;
/* Logical vnic ID */
uint16_t vf_id;
/* ID of Virtual Function whose VNIC resource is being queried. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_vnic_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t dflt_ring_grp;
/* Default Completion ring for the VNIC. */
uint16_t rss_rule;
/*
* RSS ID for RSS rule/table structure. 0xFF... (All Fs) if there is no
* RSS rule.
*/
uint16_t cos_rule;
/*
* RSS ID for COS rule/table structure. 0xFF... (All Fs) if there is no
* COS rule.
*/
uint16_t lb_rule;
/*
* RSS ID for load balancing rule/table structure. 0xFF... (All Fs) if
* there is no LB rule.
*/
uint16_t mru;
/* The maximum receive unit of the vnic. */
uint8_t unused_0;
uint8_t unused_1;
uint32_t flags;
/* When this bit is '1', the VNIC is the default VNIC for the function. */
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_DEFAULT UINT32_C(0x1)
/*
* When this bit is '1', the VNIC is configured to strip VLAN in the RX
* path. If set to '0', then VLAN stripping is disabled on this VNIC.
*/
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_VLAN_STRIP_MODE UINT32_C(0x2)
/*
* When this bit is '1', the VNIC is configured to buffer receive
* packets in the hardware until the host posts new receive buffers. If
* set to '0', then bd_stall is disabled on this VNIC.
*/
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_BD_STALL_MODE UINT32_C(0x4)
/*
* When this bit is '1', the VNIC is configured to receive both RoCE and
* non-RoCE traffic. If set to '0', then this VNIC is not configured to
* operate in dual VNIC mode.
*/
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_ROCE_DUAL_VNIC_MODE UINT32_C(0x8)
/*
* When this flag is set to '1', the VNIC is configured to receive only
* RoCE traffic. When this flag is set to '0', the VNIC is not
* configured to receive only RoCE traffic. If roce_dual_vnic_mode flag
* and this flag both are set to '1', then it is an invalid
* configuration of the VNIC. The HWRM should not allow that type of
* mis-configuration by HWRM clients.
*/
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_ROCE_ONLY_VNIC_MODE UINT32_C(0x10)
/*
* When a VNIC uses one destination ring group for certain application
* (e.g. Receive Flow Steering) where exact match is used to direct
* packets to a VNIC with one destination ring group only, there is no
* need to configure RSS indirection table for that VNIC as only one
* destination ring group is used. When this bit is set to '1', then the
* VNIC is enabled in a mode where RSS is enabled in the VNIC using a
* RSS context for computing RSS hash but the RSS indirection table is
* not configured.
*/
#define HWRM_VNIC_QCFG_OUTPUT_FLAGS_RSS_DFLT_CR_MODE UINT32_C(0x20)
uint32_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_qcaps */
/*
* Description: This function is used to query the capabilities of VNIC
* resources.
*/
/* Input (24 bytes) */
struct hwrm_vnic_qcaps_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
uint32_t unused_0;
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_vnic_qcaps_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t mru;
/* The maximum receive unit that is settable on a vnic. */
uint8_t unused_0;
uint8_t unused_1;
uint32_t flags;
/* Unused. */
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_UNUSED UINT32_C(0x1)
/*
* When this bit is '1', the capability of stripping VLAN in the RX path
* is supported on VNIC(s). If set to '0', then VLAN stripping
* capability is not supported on VNIC(s).
*/
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_VLAN_STRIP_CAP UINT32_C(0x2)
/*
* When this bit is '1', the capability to buffer receive packets in the
* hardware until the host posts new receive buffers is supported on
* VNIC(s). If set to '0', then bd_stall capability is not supported on
* VNIC(s).
*/
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_BD_STALL_CAP UINT32_C(0x4)
/*
* When this bit is '1', the capability to receive both RoCE and non-
* RoCE traffic on VNIC(s) is supported. If set to '0', then the
* capability to receive both RoCE and non-RoCE traffic on VNIC(s) is
* not supported.
*/
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_ROCE_DUAL_VNIC_CAP UINT32_C(0x8)
/*
* When this bit is set to '1', the capability to configure a VNIC to
* receive only RoCE traffic is supported. When this flag is set to '0',
* the VNIC capability to configure to receive only RoCE traffic is not
* supported.
*/
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_ROCE_ONLY_VNIC_CAP UINT32_C(0x10)
/*
* When this bit is set to '1', then the capability to enable a VNIC in
* a mode where RSS context without configuring RSS indirection table is
* supported (for RSS hash computation). When this bit is set to '0',
* then a VNIC can not be configured with a mode to enable RSS context
* without configuring RSS indirection table.
*/
#define HWRM_VNIC_QCAPS_OUTPUT_FLAGS_RSS_DFLT_CR_CAP UINT32_C(0x20)
uint32_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_tpa_cfg */
/* Description: This function is used to enable/configure TPA on the VNIC. */
/* Input (40 bytes) */
struct hwrm_vnic_tpa_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) of non-tunneled TCP packets.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_TPA UINT32_C(0x1)
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) of tunneled TCP packets.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_ENCAP_TPA UINT32_C(0x2)
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) according to Windows Receive
* Segment Coalescing (RSC) rules.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_RSC_WND_UPDATE UINT32_C(0x4)
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) according to Linux Generic
* Receive Offload (GRO) rules.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_GRO UINT32_C(0x8)
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) for TCP packets with IP ECN set
* to non-zero.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_AGG_WITH_ECN UINT32_C(0x10)
/*
* When this bit is '1', the VNIC shall be configured to perform
* transparent packet aggregation (TPA) for GRE tunneled TCP packets
* only if all packets have the same GRE sequence.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_AGG_WITH_SAME_GRE_SEQ UINT32_C(0x20)
/*
* When this bit is '1' and the GRO mode is enabled, the VNIC shall be
* configured to perform transparent packet aggregation (TPA) for
* TCP/IPv4 packets with consecutively increasing IPIDs. In other words,
* the last packet that is being aggregated to an already existing
* aggregation context shall have IPID 1 more than the IPID of the last
* packet that was aggregated in that aggregation context.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_GRO_IPID_CHECK UINT32_C(0x40)
/*
* When this bit is '1' and the GRO mode is enabled, the VNIC shall be
* configured to perform transparent packet aggregation (TPA) for TCP
* packets with the same TTL (IPv4) or Hop limit (IPv6) value.
*/
#define HWRM_VNIC_TPA_CFG_INPUT_FLAGS_GRO_TTL_CHECK UINT32_C(0x80)
uint32_t enables;
/* This bit must be '1' for the max_agg_segs field to be configured. */
#define HWRM_VNIC_TPA_CFG_INPUT_ENABLES_MAX_AGG_SEGS UINT32_C(0x1)
/* This bit must be '1' for the max_aggs field to be configured. */
#define HWRM_VNIC_TPA_CFG_INPUT_ENABLES_MAX_AGGS UINT32_C(0x2)
/* This bit must be '1' for the max_agg_timer field to be configured. */
#define HWRM_VNIC_TPA_CFG_INPUT_ENABLES_MAX_AGG_TIMER UINT32_C(0x4)
/* This bit must be '1' for the min_agg_len field to be configured. */
#define HWRM_VNIC_TPA_CFG_INPUT_ENABLES_MIN_AGG_LEN UINT32_C(0x8)
uint16_t vnic_id;
/* Logical vnic ID */
uint16_t max_agg_segs;
/*
* This is the maximum number of TCP segments that can be aggregated
* (unit is Log2). Max value is 31.
*/
/* 1 segment */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGG_SEGS_1 UINT32_C(0x0)
/* 2 segments */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGG_SEGS_2 UINT32_C(0x1)
/* 4 segments */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGG_SEGS_4 UINT32_C(0x2)
/* 8 segments */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGG_SEGS_8 UINT32_C(0x3)
/* Any segment size larger than this is not valid */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGG_SEGS_MAX UINT32_C(0x1f)
uint16_t max_aggs;
/*
* This is the maximum number of aggregations this VNIC is allowed (unit
* is Log2). Max value is 7
*/
/* 1 aggregation */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_1 UINT32_C(0x0)
/* 2 aggregations */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_2 UINT32_C(0x1)
/* 4 aggregations */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_4 UINT32_C(0x2)
/* 8 aggregations */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_8 UINT32_C(0x3)
/* 16 aggregations */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_16 UINT32_C(0x4)
/* Any aggregation size larger than this is not valid */
#define HWRM_VNIC_TPA_CFG_INPUT_MAX_AGGS_MAX UINT32_C(0x7)
uint8_t unused_0;
uint8_t unused_1;
uint32_t max_agg_timer;
/*
* This is the maximum amount of time allowed for an aggregation context
* to complete after it was initiated.
*/
uint32_t min_agg_len;
/*
* This is the minimum amount of payload length required to start an
* aggregation context.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_tpa_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_tpa_qcfg */
/*
* Description: This function can be used to query TPA configuration on the
* VNIC.
*/
/* Input (24 bytes) */
struct hwrm_vnic_tpa_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t vnic_id;
/* Logical vnic ID */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_vnic_tpa_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t flags;
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) of non-tunneled TCP packets.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_TPA UINT32_C(0x1)
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) of tunneled TCP packets.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_ENCAP_TPA UINT32_C(0x2)
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) according to Windows Receive Segment
* Coalescing (RSC) rules.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_RSC_WND_UPDATE UINT32_C(0x4)
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) according to Linux Generic Receive Offload
* (GRO) rules.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_GRO UINT32_C(0x8)
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) for TCP packets with IP ECN set to non-zero.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_AGG_WITH_ECN UINT32_C(0x10)
/*
* When this bit is '1', the VNIC is configured to perform transparent
* packet aggregation (TPA) for GRE tunneled TCP packets only if all
* packets have the same GRE sequence.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_AGG_WITH_SAME_GRE_SEQ UINT32_C(0x20)
/*
* When this bit is '1' and the GRO mode is enabled, the VNIC is
* configured to perform transparent packet aggregation (TPA) for
* TCP/IPv4 packets with consecutively increasing IPIDs. In other words,
* the last packet that is being aggregated to an already existing
* aggregation context shall have IPID 1 more than the IPID of the last
* packet that was aggregated in that aggregation context.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_GRO_IPID_CHECK UINT32_C(0x40)
/*
* When this bit is '1' and the GRO mode is enabled, the VNIC is
* configured to perform transparent packet aggregation (TPA) for TCP
* packets with the same TTL (IPv4) or Hop limit (IPv6) value.
*/
#define HWRM_VNIC_TPA_QCFG_OUTPUT_FLAGS_GRO_TTL_CHECK UINT32_C(0x80)
uint16_t max_agg_segs;
/*
* This is the maximum number of TCP segments that can be aggregated
* (unit is Log2). Max value is 31.
*/
/* 1 segment */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGG_SEGS_1 UINT32_C(0x0)
/* 2 segments */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGG_SEGS_2 UINT32_C(0x1)
/* 4 segments */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGG_SEGS_4 UINT32_C(0x2)
/* 8 segments */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGG_SEGS_8 UINT32_C(0x3)
/* Any segment size larger than this is not valid */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGG_SEGS_MAX UINT32_C(0x1f)
uint16_t max_aggs;
/*
* This is the maximum number of aggregations this VNIC is allowed (unit
* is Log2). Max value is 7
*/
/* 1 aggregation */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_1 UINT32_C(0x0)
/* 2 aggregations */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_2 UINT32_C(0x1)
/* 4 aggregations */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_4 UINT32_C(0x2)
/* 8 aggregations */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_8 UINT32_C(0x3)
/* 16 aggregations */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_16 UINT32_C(0x4)
/* Any aggregation size larger than this is not valid */
#define HWRM_VNIC_TPA_QCFG_OUTPUT_MAX_AGGS_MAX UINT32_C(0x7)
uint32_t max_agg_timer;
/*
* This is the maximum amount of time allowed for an aggregation context
* to complete after it was initiated.
*/
uint32_t min_agg_len;
/*
* This is the minimum amount of payload length required to start an
* aggregation context.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_rss_cfg */
/* Description: This function is used to enable RSS configuration. */
/* Input (48 bytes) */
struct hwrm_vnic_rss_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t hash_type;
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv4 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_IPV4 UINT32_C(0x1)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* TCP/IPv4 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_TCP_IPV4 UINT32_C(0x2)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* UDP/IPv4 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_UDP_IPV4 UINT32_C(0x4)
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv6 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_IPV6 UINT32_C(0x8)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* TCP/IPv6 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_TCP_IPV6 UINT32_C(0x10)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* UDP/IPv6 packets.
*/
#define HWRM_VNIC_RSS_CFG_INPUT_HASH_TYPE_UDP_IPV6 UINT32_C(0x20)
uint32_t unused_0;
uint64_t ring_grp_tbl_addr;
/* This is the address for rss ring group table */
uint64_t hash_key_tbl_addr;
/* This is the address for rss hash key table */
uint16_t rss_ctx_idx;
/* Index to the rss indirection table. */
uint16_t unused_1[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_rss_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_rss_qcfg */
/* Description: This function is used to query RSS context configuration. */
/* Input (24 bytes) */
struct hwrm_vnic_rss_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t rss_ctx_idx;
/* Index to the rss indirection table. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (64 bytes) */
struct hwrm_vnic_rss_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t hash_type;
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv4 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_IPV4 UINT32_C(0x1)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* TCP/IPv4 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_TCP_IPV4 UINT32_C(0x2)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* UDP/IPv4 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_UDP_IPV4 UINT32_C(0x4)
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv6 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_IPV6 UINT32_C(0x8)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* TCP/IPv6 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_TCP_IPV6 UINT32_C(0x10)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* UDP/IPv6 packets.
*/
#define HWRM_VNIC_RSS_QCFG_OUTPUT_HASH_TYPE_UDP_IPV6 UINT32_C(0x20)
uint32_t unused_0;
uint32_t hash_key[10];
/* This is the value of rss hash key */
uint32_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_plcmodes_cfg */
/*
* Description: This function can be used to set placement mode configuration of
* the VNIC.
*/
/* Input (40 bytes) */
struct hwrm_vnic_plcmodes_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* When this bit is '1', the VNIC shall be configured to use regular
* placement algorithm. By default, the regular placement algorithm
* shall be enabled on the VNIC.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_REGULAR_PLACEMENT UINT32_C(0x1)
/*
* When this bit is '1', the VNIC shall be configured use the jumbo
* placement algorithm.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_JUMBO_PLACEMENT UINT32_C(0x2)
/*
* When this bit is '1', the VNIC shall be configured to enable Header-
* Data split for IPv4 packets according to the following rules: # If
* the packet is identified as TCP/IPv4, then the packet is split at the
* beginning of the TCP payload. # If the packet is identified as
* UDP/IPv4, then the packet is split at the beginning of UDP payload. #
* If the packet is identified as non-TCP and non-UDP IPv4 packet, then
* the packet is split at the beginning of the upper layer protocol
* header carried in the IPv4 packet.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_HDS_IPV4 UINT32_C(0x4)
/*
* When this bit is '1', the VNIC shall be configured to enable Header-
* Data split for IPv6 packets according to the following rules: # If
* the packet is identified as TCP/IPv6, then the packet is split at the
* beginning of the TCP payload. # If the packet is identified as
* UDP/IPv6, then the packet is split at the beginning of UDP payload. #
* If the packet is identified as non-TCP and non-UDP IPv6 packet, then
* the packet is split at the beginning of the upper layer protocol
* header carried in the IPv6 packet.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_HDS_IPV6 UINT32_C(0x8)
/*
* When this bit is '1', the VNIC shall be configured to enable Header-
* Data split for FCoE packets at the beginning of FC payload.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_HDS_FCOE UINT32_C(0x10)
/*
* When this bit is '1', the VNIC shall be configured to enable Header-
* Data split for RoCE packets at the beginning of RoCE payload (after
* BTH/GRH headers).
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_FLAGS_HDS_ROCE UINT32_C(0x20)
uint32_t enables;
/*
* This bit must be '1' for the jumbo_thresh_valid field to be
* configured.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_ENABLES_JUMBO_THRESH_VALID UINT32_C(0x1)
/* This bit must be '1' for the hds_offset_valid field to be configured. */
#define HWRM_VNIC_PLCMODES_CFG_INPUT_ENABLES_HDS_OFFSET_VALID UINT32_C(0x2)
/*
* This bit must be '1' for the hds_threshold_valid field to be
* configured.
*/
#define HWRM_VNIC_PLCMODES_CFG_INPUT_ENABLES_HDS_THRESHOLD_VALID UINT32_C(0x4)
uint32_t vnic_id;
/* Logical vnic ID */
uint16_t jumbo_thresh;
/*
* When jumbo placement algorithm is enabled, this value is used to
* determine the threshold for jumbo placement. Packets with length
* larger than this value will be placed according to the jumbo
* placement algorithm.
*/
uint16_t hds_offset;
/*
* This value is used to determine the offset into packet buffer where
* the split data (payload) will be placed according to one of of HDS
* placement algorithm. The lengths of packet buffers provided for split
* data shall be larger than this value.
*/
uint16_t hds_threshold;
/*
* When one of the HDS placement algorithm is enabled, this value is
* used to determine the threshold for HDS placement. Packets with
* length larger than this value will be placed according to the HDS
* placement algorithm. This value shall be in multiple of 4 bytes.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_plcmodes_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_plcmodes_qcfg */
/*
* Description: This function can be used to query placement mode configuration
* of the VNIC.
*/
/* Input (24 bytes) */
struct hwrm_vnic_plcmodes_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t vnic_id;
/* Logical vnic ID */
uint32_t unused_0;
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_vnic_plcmodes_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t flags;
/*
* When this bit is '1', the VNIC is configured to use regular placement
* algorithm.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_REGULAR_PLACEMENT UINT32_C(0x1)
/*
* When this bit is '1', the VNIC is configured to use the jumbo
* placement algorithm.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_JUMBO_PLACEMENT UINT32_C(0x2)
/*
* When this bit is '1', the VNIC is configured to enable Header-Data
* split for IPv4 packets.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_HDS_IPV4 UINT32_C(0x4)
/*
* When this bit is '1', the VNIC is configured to enable Header-Data
* split for IPv6 packets.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_HDS_IPV6 UINT32_C(0x8)
/*
* When this bit is '1', the VNIC is configured to enable Header-Data
* split for FCoE packets.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_HDS_FCOE UINT32_C(0x10)
/*
* When this bit is '1', the VNIC is configured to enable Header-Data
* split for RoCE packets.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_HDS_ROCE UINT32_C(0x20)
/*
* When this bit is '1', the VNIC is configured to be the default VNIC
* of the requesting function.
*/
#define HWRM_VNIC_PLCMODES_QCFG_OUTPUT_FLAGS_DFLT_VNIC UINT32_C(0x40)
uint16_t jumbo_thresh;
/*
* When jumbo placement algorithm is enabled, this value is used to
* determine the threshold for jumbo placement. Packets with length
* larger than this value will be placed according to the jumbo
* placement algorithm.
*/
uint16_t hds_offset;
/*
* This value is used to determine the offset into packet buffer where
* the split data (payload) will be placed according to one of of HDS
* placement algorithm. The lengths of packet buffers provided for split
* data shall be larger than this value.
*/
uint16_t hds_threshold;
/*
* When one of the HDS placement algorithm is enabled, this value is
* used to determine the threshold for HDS placement. Packets with
* length larger than this value will be placed according to the HDS
* placement algorithm. This value shall be in multiple of 4 bytes.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_rss_cos_lb_ctx_alloc */
/* Description: This function is used to allocate COS/Load Balance context. */
/* Input (16 bytes) */
struct hwrm_vnic_rss_cos_lb_ctx_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_rss_cos_lb_ctx_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t rss_cos_lb_ctx_id;
/* rss_cos_lb_ctx_id is 16 b */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_vnic_rss_cos_lb_ctx_free */
/* Description: This function can be used to free COS/Load Balance context. */
/* Input (24 bytes) */
struct hwrm_vnic_rss_cos_lb_ctx_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t rss_cos_lb_ctx_id;
/* rss_cos_lb_ctx_id is 16 b */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_vnic_rss_cos_lb_ctx_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_alloc */
/*
* Description: This command allocates and does basic preparation for a ring.
*/
/* Input (80 bytes) */
struct hwrm_ring_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the Reserved1 field to be configured. */
#define HWRM_RING_ALLOC_INPUT_ENABLES_RESERVED1 UINT32_C(0x1)
/* This bit must be '1' for the ring_arb_cfg field to be configured. */
#define HWRM_RING_ALLOC_INPUT_ENABLES_RING_ARB_CFG UINT32_C(0x2)
/* This bit must be '1' for the Reserved3 field to be configured. */
#define HWRM_RING_ALLOC_INPUT_ENABLES_RESERVED3 UINT32_C(0x4)
/*
* This bit must be '1' for the stat_ctx_id_valid field to be
* configured.
*/
#define HWRM_RING_ALLOC_INPUT_ENABLES_STAT_CTX_ID_VALID UINT32_C(0x8)
/* This bit must be '1' for the Reserved4 field to be configured. */
#define HWRM_RING_ALLOC_INPUT_ENABLES_RESERVED4 UINT32_C(0x10)
/* This bit must be '1' for the max_bw_valid field to be configured. */
#define HWRM_RING_ALLOC_INPUT_ENABLES_MAX_BW_VALID UINT32_C(0x20)
uint8_t ring_type;
/* Ring Type. */
/* L2 Completion Ring (CR) */
#define HWRM_RING_ALLOC_INPUT_RING_TYPE_L2_CMPL UINT32_C(0x0)
/* TX Ring (TR) */
#define HWRM_RING_ALLOC_INPUT_RING_TYPE_TX UINT32_C(0x1)
/* RX Ring (RR) */
#define HWRM_RING_ALLOC_INPUT_RING_TYPE_RX UINT32_C(0x2)
/* RoCE Notification Completion Ring (ROCE_CR) */
#define HWRM_RING_ALLOC_INPUT_RING_TYPE_ROCE_CMPL UINT32_C(0x3)
uint8_t unused_0;
uint16_t unused_1;
uint64_t page_tbl_addr;
/* This value is a pointer to the page table for the Ring. */
uint32_t fbo;
/* First Byte Offset of the first entry in the first page. */
uint8_t page_size;
/*
* Actual page size in 2^page_size. The supported range is increments in
* powers of 2 from 16 bytes to 1GB. - 4 = 16 B Page size is 16 B. - 12
* = 4 KB Page size is 4 KB. - 13 = 8 KB Page size is 8 KB. - 16 = 64 KB
* Page size is 64 KB. - 21 = 2 MB Page size is 2 MB. - 22 = 4 MB Page
* size is 4 MB. - 30 = 1 GB Page size is 1 GB.
*/
uint8_t page_tbl_depth;
/*
* This value indicates the depth of page table. For this version of the
* specification, value other than 0 or 1 shall be considered as an
* invalid value. When the page_tbl_depth = 0, then it is treated as a
* special case with the following. 1. FBO and page size fields are not
* valid. 2. page_tbl_addr is the physical address of the first element
* of the ring.
*/
uint8_t unused_2;
uint8_t unused_3;
uint32_t length;
/*
* Number of 16B units in the ring. Minimum size for a ring is 16 16B
* entries.
*/
uint16_t logical_id;
/*
* Logical ring number for the ring to be allocated. This value
* determines the position in the doorbell area where the update to the
* ring will be made. For completion rings, this value is also the MSI-X
* vector number for the function the completion ring is associated
* with.
*/
uint16_t cmpl_ring_id;
/*
* This field is used only when ring_type is a TX ring. This value
* indicates what completion ring the TX ring is associated with.
*/
uint16_t queue_id;
/*
* This field is used only when ring_type is a TX ring. This value
* indicates what CoS queue the TX ring is associated with.
*/
uint8_t unused_4;
uint8_t unused_5;
uint32_t reserved1;
/* This field is reserved for the future use. It shall be set to 0. */
uint16_t ring_arb_cfg;
/*
* This field is used only when ring_type is a TX ring. This field is
* used to configure arbitration related parameters for a TX ring.
*/
/* Arbitration policy used for the ring. */
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_MASK UINT32_C(0xf)
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_SFT 0
/*
* Use strict priority for the TX ring. Priority value is
* specified in arb_policy_param
*/
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_SP (UINT32_C(0x1) << 0)
/*
* Use weighted fair queue arbitration for the TX ring. Weight
* is specified in arb_policy_param
*/
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_WFQ (UINT32_C(0x2) << 0)
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_LAST HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_WFQ
/* Reserved field. */
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_RSVD_MASK UINT32_C(0xf0)
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_RSVD_SFT 4
/*
* Arbitration policy specific parameter. # For strict priority
* arbitration policy, this field represents a priority value. If set to
* 0, then the priority is not specified and the HWRM is allowed to
* select any priority for this TX ring. # For weighted fair queue
* arbitration policy, this field represents a weight value. If set to
* 0, then the weight is not specified and the HWRM is allowed to select
* any weight for this TX ring.
*/
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_PARAM_MASK UINT32_C(0xff00)
#define HWRM_RING_ALLOC_INPUT_RING_ARB_CFG_ARB_POLICY_PARAM_SFT 8
uint8_t unused_6;
uint8_t unused_7;
uint32_t reserved3;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t stat_ctx_id;
/*
* This field is used only when ring_type is a TX ring. This input
* indicates what statistics context this ring should be associated
* with.
*/
uint32_t reserved4;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t max_bw;
/*
* This field is used only when ring_type is a TX ring to specify
* maximum BW allocated to the TX ring. The HWRM will translate this
* value into byte counter and time interval used for this ring inside
* the device.
*/
/* The bandwidth value. */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_RING_ALLOC_INPUT_MAX_BW_SCALE_LAST HWRM_RING_ALLOC_INPUT_MAX_BW_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_LAST HWRM_RING_ALLOC_INPUT_MAX_BW_BW_VALUE_UNIT_INVALID
uint8_t int_mode;
/*
* This field is used only when ring_type is a Completion ring. This
* value indicates what interrupt mode should be used on this completion
* ring. Note: In the legacy interrupt mode, no more than 16 completion
* rings are allowed.
*/
/* Legacy INTA */
#define HWRM_RING_ALLOC_INPUT_INT_MODE_LEGACY UINT32_C(0x0)
/* Reserved */
#define HWRM_RING_ALLOC_INPUT_INT_MODE_RSVD UINT32_C(0x1)
/* MSI-X */
#define HWRM_RING_ALLOC_INPUT_INT_MODE_MSIX UINT32_C(0x2)
/* No Interrupt - Polled mode */
#define HWRM_RING_ALLOC_INPUT_INT_MODE_POLL UINT32_C(0x3)
uint8_t unused_8[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t ring_id;
/*
* Physical number of ring allocated. This value shall be unique for a
* ring type.
*/
uint16_t logical_ring_id;
/* Logical number of ring allocated. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_free */
/*
* Description: This command is used to free a ring and associated resources.
* With QoS and DCBx agents, it is possible the traffic classes will be moved
* from one CoS queue to another. When this occurs, the driver shall call
* 'hwrm_ring_free' to free the allocated rings and then call 'hwrm_ring_alloc'
* to re-allocate each ring and assign it to a new CoS queue. hwrm_ring_free
* shall be called on a ring only after it has been idle for 500ms or more and
* no frames have been posted to the ring during this time. All frames queued
* for transmission shall be completed and at least 500ms time elapsed from the
* last completion before calling this command.
*/
/* Input (24 bytes) */
struct hwrm_ring_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t ring_type;
/* Ring Type. */
/* L2 Completion Ring (CR) */
#define HWRM_RING_FREE_INPUT_RING_TYPE_L2_CMPL UINT32_C(0x0)
/* TX Ring (TR) */
#define HWRM_RING_FREE_INPUT_RING_TYPE_TX UINT32_C(0x1)
/* RX Ring (RR) */
#define HWRM_RING_FREE_INPUT_RING_TYPE_RX UINT32_C(0x2)
/* RoCE Notification Completion Ring (ROCE_CR) */
#define HWRM_RING_FREE_INPUT_RING_TYPE_ROCE_CMPL UINT32_C(0x3)
uint8_t unused_0;
uint16_t ring_id;
/* Physical number of ring allocated. */
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_cmpl_ring_qaggint_params */
/*
* Description: This command is used to query aggregation and interrupt related
* parameters specified on a given completion ring.
*/
/* Input (24 bytes) */
struct hwrm_ring_cmpl_ring_qaggint_params_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t ring_id;
/* Physical number of completion ring. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_ring_cmpl_ring_qaggint_params_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t flags;
/*
* When this bit is set to '1', interrupt max timer is reset whenever a
* completion is received.
*/
#define HWRM_RING_CMPL_RING_QAGGINT_PARAMS_OUTPUT_FLAGS_TIMER_RESET UINT32_C(0x1)
/*
* When this bit is set to '1', ring idle mode aggregation will be
* enabled.
*/
#define HWRM_RING_CMPL_RING_QAGGINT_PARAMS_OUTPUT_FLAGS_RING_IDLE UINT32_C(0x2)
uint16_t num_cmpl_dma_aggr;
/* Number of completions to aggregate before DMA during the normal mode. */
uint16_t num_cmpl_dma_aggr_during_int;
/*
* Number of completions to aggregate before DMA during the interrupt
* mode.
*/
uint16_t cmpl_aggr_dma_tmr;
/*
* Timer in unit of 80-nsec used to aggregate completions before DMA
* during the normal mode (not in interrupt mode).
*/
uint16_t cmpl_aggr_dma_tmr_during_int;
/*
* Timer in unit of 80-nsec used to aggregate completions before DMA
* during the interrupt mode.
*/
uint16_t int_lat_tmr_min;
/* Minimum time (in unit of 80-nsec) between two interrupts. */
uint16_t int_lat_tmr_max;
/*
* Maximum wait time (in unit of 80-nsec) spent aggregating completions
* before signaling the interrupt after the interrupt is enabled.
*/
uint16_t num_cmpl_aggr_int;
/*
* Minimum number of completions aggregated before signaling an
* interrupt.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_cmpl_ring_cfg_aggint_params */
/*
* Description: This command is used to configure aggregation and interrupt
* related parameters specified on a given completion ring.
*/
/* Input (40 bytes) */
struct hwrm_ring_cmpl_ring_cfg_aggint_params_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t ring_id;
/* Physical number of completion ring. */
uint16_t flags;
/*
* When this bit is set to '1', interrupt latency max timer is reset
* whenever a completion is received.
*/
#define HWRM_RING_CMPL_RING_CFG_AGGINT_PARAMS_INPUT_FLAGS_TIMER_RESET UINT32_C(0x1)
/*
* When this bit is set to '1', ring idle mode aggregation will be
* enabled.
*/
#define HWRM_RING_CMPL_RING_CFG_AGGINT_PARAMS_INPUT_FLAGS_RING_IDLE UINT32_C(0x2)
uint16_t num_cmpl_dma_aggr;
/* Number of completions to aggregate before DMA during the normal mode. */
uint16_t num_cmpl_dma_aggr_during_int;
/*
* Number of completions to aggregate before DMA during the interrupt
* mode.
*/
uint16_t cmpl_aggr_dma_tmr;
/*
* Timer in unit of 80-nsec used to aggregate completions before DMA
* during the normal mode (not in interrupt mode).
*/
uint16_t cmpl_aggr_dma_tmr_during_int;
/*
* Timer in unit of 80-nsec used to aggregate completions before DMA
* during the interrupt mode.
*/
uint16_t int_lat_tmr_min;
/* Minimum time (in unit of 80-nsec) between two interrupts. */
uint16_t int_lat_tmr_max;
/*
* Maximum wait time (in unit of 80-nsec) spent aggregating cmpls before
* signaling the interrupt after the interrupt is enabled.
*/
uint16_t num_cmpl_aggr_int;
/*
* Minimum number of completions aggregated before signaling an
* interrupt.
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_cmpl_ring_cfg_aggint_params_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_reset */
/*
* Description: This command is used to reset a given ring. When an RX ring is
* being reset, the HWRM shall perform TPA flush on all VNICs associated with
* the RX ring that is being reset.
*/
/* Input (24 bytes) */
struct hwrm_ring_reset_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t ring_type;
/* Ring Type. */
/* L2 Completion Ring (CR) */
#define HWRM_RING_RESET_INPUT_RING_TYPE_L2_CMPL UINT32_C(0x0)
/* TX Ring (TR) */
#define HWRM_RING_RESET_INPUT_RING_TYPE_TX UINT32_C(0x1)
/* RX Ring (RR) */
#define HWRM_RING_RESET_INPUT_RING_TYPE_RX UINT32_C(0x2)
/* RoCE Notification Completion Ring (ROCE_CR) */
#define HWRM_RING_RESET_INPUT_RING_TYPE_ROCE_CMPL UINT32_C(0x3)
uint8_t unused_0;
uint16_t ring_id;
/* Physical number of the ring. */
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_reset_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_grp_alloc */
/*
* Description: This API allocates and does basic preparation for a ring group.
*/
/* Input (24 bytes) */
struct hwrm_ring_grp_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t cr;
/* This value identifies the CR associated with the ring group. */
uint16_t rr;
/* This value identifies the main RR associated with the ring group. */
uint16_t ar;
/*
* This value identifies the aggregation RR associated with the ring
* group. If this value is 0xFF... (All Fs), then no Aggregation ring
* will be set.
*/
uint16_t sc;
/*
* This value identifies the statistics context associated with the ring
* group.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_grp_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t ring_group_id;
/*
* This is the ring group ID value. Use this value to program the
* default ring group for the VNIC or as table entries in an RSS/COS
* context.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_ring_grp_free */
/*
* Description: This API frees a ring group and associated resources. # If a
* ring in the ring group is reset or free, then the associated rings in the
* ring group shall also be reset/free using hwrm_ring_free. # A function driver
* shall always use hwrm_ring_grp_free after freeing all rings in a group. # As
* a part of executing this command, the HWRM shall reset all associated ring
* group resources.
*/
/* Input (24 bytes) */
struct hwrm_ring_grp_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t ring_group_id;
/* This is the ring group ID value. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_ring_grp_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_l2_filter_alloc */
/*
* Description: An L2 filter is a filter resource that is used to identify a
* vnic or ring for a packet based on layer 2 fields. Layer 2 fields for
* encapsulated packets include both outer L2 header and/or inner l2 header of
* encapsulated packet. The L2 filter resource covers the following OS specific
* L2 filters. Linux/FreeBSD (per function): # Broadcast enable/disable # List
* of individual multicast filters # All multicast enable/disable filter #
* Unicast filters # Promiscuous mode VMware: # Broadcast enable/disable (per
* physical function) # All multicast enable/disable (per function) # Unicast
* filters per ring or vnic # Promiscuous mode per PF Windows: # Broadcast
* enable/disable (per physical function) # List of individual multicast filters
* (Driver needs to advertise the maximum number of filters supported) # All
* multicast enable/disable per physical function # Unicast filters per vnic #
* Promiscuous mode per PF Implementation notes on the use of VNIC in this
* command: # By default, these filters belong to default vnic for the function.
* # Once these filters are set up, only destination VNIC can be modified. # If
* the destination VNIC is not specified in this command, then the HWRM shall
* only create an l2 context id. HWRM Implementation notes for multicast
* filters: # The hwrm_filter_alloc command can be used to set up multicast
* filters (perfect match or partial match). Each individual function driver can
* set up multicast filters independently. # The HWRM needs to keep track of
* multicast filters set up by function drivers and maintain multicast group
* replication records to enable a subset of functions to receive traffic for a
* specific multicast address. # When a specific multicast filter cannot be set,
* the HWRM shall return an error. In this error case, the driver should fall
* back to using one general filter (rather than specific) for all multicast
* traffic. # When the SR-IOV is enabled, the HWRM needs to additionally track
* source knockout per multicast group record. Examples of setting unicast
* filters: For a unicast MAC based filter, one can use a combination of the
* fields and masks provided in this command to set up the filter. Below are
* some examples: # MAC + no VLAN filter: This filter is used to identify
* traffic that does not contain any VLAN tags and matches destination (or
* source) MAC address. This filter can be set up by setting only l2_addr field
* to be a valid field. All other fields are not valid. The following value is
* set for l2_addr. l2_addr = MAC # MAC + Any VLAN filter: This filter is used
* to identify traffic that carries single VLAN tag and matches (destination or
* source) MAC address. This filter can be set up by setting only l2_addr and
* l2_ovlan_mask fields to be valid fields. All other fields are not valid. The
* following values are set for those two valid fields. l2_addr = MAC,
* l2_ovlan_mask = 0xFFFF # MAC + no VLAN or VLAN ID=0: This filter is used to
* identify untagged traffic that does not contain any VLAN tags or a VLAN tag
* with VLAN ID = 0 and matches destination (or source) MAC address. This filter
* can be set up by setting only l2_addr and l2_ovlan fields to be valid fields.
* All other fields are not valid. The following value are set for l2_addr and
* l2_ovlan. l2_addr = MAC, l2_ovlan = 0x0 # MAC + no VLAN or any VLAN: This
* filter is used to identify traffic that contains zero or 1 VLAN tag and
* matches destination (or source) MAC address. This filter can be set up by
* setting only l2_addr, l2_ovlan, and l2_mask fields to be valid fields. All
* other fields are not valid. The following value are set for l2_addr,
* l2_ovlan, and l2_mask fields. l2_addr = MAC, l2_ovlan = 0x0, l2_ovlan_mask =
* 0xFFFF # MAC + VLAN ID filter: This filter can be set up by setting only
* l2_addr, l2_ovlan, and l2_ovlan_mask fields to be valid fields. All other
* fields are not valid. The following values are set for those three valid
* fields. l2_addr = MAC, l2_ovlan = VLAN ID, l2_ovlan_mask = 0xF000
*/
/* Input (96 bytes) */
struct hwrm_cfa_l2_filter_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_PATH_TX (UINT32_C(0x0) << 0)
/* rx path */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_PATH_RX (UINT32_C(0x1) << 0)
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_PATH_LAST HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_PATH_RX
/*
* Setting of this flag indicates the applicability to the loopback
* path.
*/
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_LOOPBACK UINT32_C(0x2)
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_DROP UINT32_C(0x4)
/*
* If this flag is set, all t_l2_* fields are invalid and they should
* not be specified. If this flag is set, then l2_* fields refer to
* fields of outermost L2 header.
*/
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_FLAGS_OUTERMOST UINT32_C(0x8)
uint32_t enables;
/* This bit must be '1' for the l2_addr field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_ADDR UINT32_C(0x1)
/* This bit must be '1' for the l2_addr_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_ADDR_MASK UINT32_C(0x2)
/* This bit must be '1' for the l2_ovlan field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_OVLAN UINT32_C(0x4)
/* This bit must be '1' for the l2_ovlan_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_OVLAN_MASK UINT32_C(0x8)
/* This bit must be '1' for the l2_ivlan field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_IVLAN UINT32_C(0x10)
/* This bit must be '1' for the l2_ivlan_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_L2_IVLAN_MASK UINT32_C(0x20)
/* This bit must be '1' for the t_l2_addr field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_ADDR UINT32_C(0x40)
/* This bit must be '1' for the t_l2_addr_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_ADDR_MASK UINT32_C(0x80)
/* This bit must be '1' for the t_l2_ovlan field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_OVLAN UINT32_C(0x100)
/* This bit must be '1' for the t_l2_ovlan_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_OVLAN_MASK UINT32_C(0x200)
/* This bit must be '1' for the t_l2_ivlan field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_IVLAN UINT32_C(0x400)
/* This bit must be '1' for the t_l2_ivlan_mask field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_T_L2_IVLAN_MASK UINT32_C(0x800)
/* This bit must be '1' for the src_type field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_SRC_TYPE UINT32_C(0x1000)
/* This bit must be '1' for the src_id field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_SRC_ID UINT32_C(0x2000)
/* This bit must be '1' for the tunnel_type field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_TUNNEL_TYPE UINT32_C(0x4000)
/* This bit must be '1' for the dst_id field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_DST_ID UINT32_C(0x8000)
/* This bit must be '1' for the mirror_vnic_id field to be configured. */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_ENABLES_MIRROR_VNIC_ID UINT32_C(0x10000)
uint8_t l2_addr[6];
/*
* This value sets the match value for the L2 MAC address. Destination
* MAC address for RX path. Source MAC address for TX path.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t l2_addr_mask[6];
/*
* This value sets the mask value for the L2 address. A value of 0 will
* mask the corresponding bit from compare.
*/
uint16_t l2_ovlan;
/* This value sets VLAN ID value for outer VLAN. */
uint16_t l2_ovlan_mask;
/*
* This value sets the mask value for the ovlan id. A value of 0 will
* mask the corresponding bit from compare.
*/
uint16_t l2_ivlan;
/* This value sets VLAN ID value for inner VLAN. */
uint16_t l2_ivlan_mask;
/*
* This value sets the mask value for the ivlan id. A value of 0 will
* mask the corresponding bit from compare.
*/
uint8_t unused_2;
uint8_t unused_3;
uint8_t t_l2_addr[6];
/*
* This value sets the match value for the tunnel L2 MAC address.
* Destination MAC address for RX path. Source MAC address for TX path.
*/
uint8_t unused_4;
uint8_t unused_5;
uint8_t t_l2_addr_mask[6];
/*
* This value sets the mask value for the tunnel L2 address. A value of
* 0 will mask the corresponding bit from compare.
*/
uint16_t t_l2_ovlan;
/* This value sets VLAN ID value for tunnel outer VLAN. */
uint16_t t_l2_ovlan_mask;
/*
* This value sets the mask value for the tunnel ovlan id. A value of 0
* will mask the corresponding bit from compare.
*/
uint16_t t_l2_ivlan;
/* This value sets VLAN ID value for tunnel inner VLAN. */
uint16_t t_l2_ivlan_mask;
/*
* This value sets the mask value for the tunnel ivlan id. A value of 0
* will mask the corresponding bit from compare.
*/
uint8_t src_type;
/* This value identifies the type of source of the packet. */
/* Network port */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_NPORT UINT32_C(0x0)
/* Physical function */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_PF UINT32_C(0x1)
/* Virtual function */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_VF UINT32_C(0x2)
/* Virtual NIC of a function */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_VNIC UINT32_C(0x3)
/* Embedded processor for CFA management */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_KONG UINT32_C(0x4)
/* Embedded processor for OOB management */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_APE UINT32_C(0x5)
/* Embedded processor for RoCE */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_BONO UINT32_C(0x6)
/* Embedded processor for network proxy functions */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_SRC_TYPE_TANG UINT32_C(0x7)
uint8_t unused_6;
uint32_t src_id;
/*
* This value is the id of the source. For a network port, it represents
* port_id. For a physical function, it represents fid. For a virtual
* function, it represents vf_id. For a vnic, it represents vnic_id. For
* embedded processors, this id is not valid. Notes: 1. The function ID
* is implied if it src_id is not provided for a src_type that is either
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Non-tunnel */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NONTUNNEL UINT32_C(0x0)
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) inside Ethernet payload */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_MPLS UINT32_C(0x6)
/* Stateless Transport Tunnel (STT) */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_STT UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPGRE UINT32_C(0x8)
/* Any tunneled traffic */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_TUNNEL_TYPE_ANYTUNNEL UINT32_C(0xff)
uint8_t unused_7;
uint16_t dst_id;
/*
* If set, this value shall represent the Logical VNIC ID of the
* destination VNIC for the RX path and network port id of the
* destination port for the TX path.
*/
uint16_t mirror_vnic_id;
/* Logical VNIC ID of the VNIC where traffic is mirrored. */
uint8_t pri_hint;
/*
* This hint is provided to help in placing the filter in the filter
* table.
*/
/* No preference */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_PRI_HINT_NO_PREFER UINT32_C(0x0)
/* Above the given filter */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_PRI_HINT_ABOVE_FILTER UINT32_C(0x1)
/* Below the given filter */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_PRI_HINT_BELOW_FILTER UINT32_C(0x2)
/* As high as possible */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_PRI_HINT_MAX UINT32_C(0x3)
/* As low as possible */
#define HWRM_CFA_L2_FILTER_ALLOC_INPUT_PRI_HINT_MIN UINT32_C(0x4)
uint8_t unused_8;
uint32_t unused_9;
uint64_t l2_filter_id_hint;
/*
* This is the ID of the filter that goes along with the pri_hint. This
* field is valid only for the following values. 1 - Above the given
* filter 2 - Below the given filter
*/
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_cfa_l2_filter_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
uint32_t flow_id;
/*
* This is the ID of the flow associated with this filter. This value
* shall be used to match and associate the flow identifier returned in
* completion records. A value of 0xFFFFFFFF shall indicate no flow id.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_l2_filter_free */
/*
* Description: Free a L2 filter. The HWRM shall free all associated filter
* resources with the L2 filter.
*/
/* Input (24 bytes) */
struct hwrm_cfa_l2_filter_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_l2_filter_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_l2_filter_cfg */
/* Description: Change the configuration of an existing L2 filter */
/* Input (40 bytes) */
struct hwrm_cfa_l2_filter_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_PATH_TX (UINT32_C(0x0) << 0)
/* rx path */
#define HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_PATH_RX (UINT32_C(0x1) << 0)
#define HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_PATH_LAST HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_PATH_RX
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_L2_FILTER_CFG_INPUT_FLAGS_DROP UINT32_C(0x2)
uint32_t enables;
/* This bit must be '1' for the dst_id field to be configured. */
#define HWRM_CFA_L2_FILTER_CFG_INPUT_ENABLES_DST_ID UINT32_C(0x1)
/*
* This bit must be '1' for the new_mirror_vnic_id field to be
* configured.
*/
#define HWRM_CFA_L2_FILTER_CFG_INPUT_ENABLES_NEW_MIRROR_VNIC_ID UINT32_C(0x2)
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
uint32_t dst_id;
/*
* If set, this value shall represent the Logical VNIC ID of the
* destination VNIC for the RX path and network port id of the
* destination port for the TX path.
*/
uint32_t new_mirror_vnic_id;
/* New Logical VNIC ID of the VNIC where traffic is mirrored. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_l2_filter_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_l2_set_rx_mask */
/* Description: This command will set rx mask of the function. */
/* Input (56 bytes) */
struct hwrm_cfa_l2_set_rx_mask_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t vnic_id;
/* VNIC ID */
uint32_t mask;
/* Reserved for future use. */
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_RESERVED UINT32_C(0x1)
/*
* When this bit is '1', the function is requested to accept multi-cast
* packets specified by the multicast addr table.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_MCAST UINT32_C(0x2)
/*
* When this bit is '1', the function is requested to accept all multi-
* cast packets.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_ALL_MCAST UINT32_C(0x4)
/*
* When this bit is '1', the function is requested to accept broadcast
* packets.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_BCAST UINT32_C(0x8)
/*
* When this bit is '1', the function is requested to be put in the
* promiscuous mode. The HWRM should accept any function to set up
* promiscuous mode. The HWRM shall follow the semantics below for the
* promiscuous mode support. # When partitioning is not enabled on a
* port (i.e. single PF on the port), then the PF shall be allowed to be
* in the promiscuous mode. When the PF is in the promiscuous mode, then
* it shall receive all host bound traffic on that port. # When
* partitioning is enabled on a port (i.e. multiple PFs per port) and a
* PF on that port is in the promiscuous mode, then the PF receives all
* traffic within that partition as identified by a unique identifier
* for the PF (e.g. S-Tag). If a unique outer VLAN for the PF is
* specified, then the setting of promiscuous mode on that PF shall
* result in the PF receiving all host bound traffic with matching outer
* VLAN. # A VF shall can be set in the promiscuous mode. In the
* promiscuous mode, the VF does not receive any traffic unless a unique
* outer VLAN for the VF is specified. If a unique outer VLAN for the VF
* is specified, then the setting of promiscuous mode on that VF shall
* result in the VF receiving all host bound traffic with the matching
* outer VLAN. # The HWRM shall allow the setting of promiscuous mode on
* a function independently from the promiscuous mode settings on other
* functions.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_PROMISCUOUS UINT32_C(0x10)
/*
* If this flag is set, the corresponding RX filters shall be set up to
* cover multicast/broadcast filters for the outermost Layer 2
* destination MAC address field.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_OUTERMOST UINT32_C(0x20)
/*
* If this flag is set, the corresponding RX filters shall be set up to
* cover multicast/broadcast filters for the VLAN-tagged packets that
* match the TPID and VID fields of VLAN tags in the VLAN tag table
* specified in this command.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_VLANONLY UINT32_C(0x40)
/*
* If this flag is set, the corresponding RX filters shall be set up to
* cover multicast/broadcast filters for non-VLAN tagged packets and
* VLAN-tagged packets that match the TPID and VID fields of VLAN tags
* in the VLAN tag table specified in this command.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_VLAN_NONVLAN UINT32_C(0x80)
/*
* If this flag is set, the corresponding RX filters shall be set up to
* cover multicast/broadcast filters for non-VLAN tagged packets and
* VLAN-tagged packets matching any VLAN tag. If this flag is set, then
* the HWRM shall ignore VLAN tags specified in vlan_tag_tbl. If none of
* vlanonly, vlan_nonvlan, and anyvlan_nonvlan flags is set, then the
* HWRM shall ignore VLAN tags specified in vlan_tag_tbl. The HWRM
* client shall set at most one flag out of vlanonly, vlan_nonvlan, and
* anyvlan_nonvlan.
*/
#define HWRM_CFA_L2_SET_RX_MASK_INPUT_MASK_ANYVLAN_NONVLAN UINT32_C(0x100)
uint64_t mc_tbl_addr;
/* This is the address for mcast address tbl. */
uint32_t num_mc_entries;
/*
* This value indicates how many entries in mc_tbl are valid. Each entry
* is 6 bytes.
*/
uint32_t unused_0;
uint64_t vlan_tag_tbl_addr;
/*
* This is the address for VLAN tag table. Each VLAN entry in the table
* is 4 bytes of a VLAN tag including TPID, PCP, DEI, and VID fields in
* network byte order.
*/
uint32_t num_vlan_tags;
/*
* This value indicates how many entries in vlan_tag_tbl are valid. Each
* entry is 4 bytes.
*/
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_l2_set_rx_mask_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_cfa_l2_set_rx_mask_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_CFA_L2_SET_RX_MASK_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* Unable to complete operation due to conflict with Ntuple Filter */
#define HWRM_CFA_L2_SET_RX_MASK_CMD_ERR_CODE_NTUPLE_FILTER_CONFLICT_ERR UINT32_C(0x1)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_cfa_vlan_antispoof_cfg */
/* Description: Configures vlan anti-spoof filters for VF. */
/* Input (32 bytes) */
struct hwrm_cfa_vlan_antispoof_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being configured. Only valid for
* a VF FID configured by the PF.
*/
uint8_t unused_0;
uint8_t unused_1;
uint32_t num_vlan_entries;
/* Number of VLAN entries in the vlan_tag_mask_tbl. */
uint64_t vlan_tag_mask_tbl_addr;
/*
* The vlan_tag_mask_tbl_addr is the DMA address of the VLAN antispoof
* table. Each table entry contains the 16-bit TPID (0x8100 or 0x88a8
* only), 16-bit VLAN ID, and a 16-bit mask, all in network order to
* match hwrm_cfa_l2_set_rx_mask. For an individual VLAN entry, the mask
* value should be 0xfff for the 12-bit VLAN ID.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vlan_antispoof_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vlan_antispoof_qcfg */
/*
* Description: Returns the current configuration of the vlan anti-spoof filters
* for VF.
*/
/* Input (32 bytes) */
struct hwrm_cfa_vlan_antispoof_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t fid;
/*
* Function ID of the function that is being queried. Only valid for a
* VF FID queried by the PF.
*/
uint8_t unused_0;
uint8_t unused_1;
uint32_t max_vlan_entries;
/*
* Maximum number of VLAN entries the firmware is allowed to DMA to
* vlan_tag_mask_tbl.
*/
uint64_t vlan_tag_mask_tbl_addr;
/*
* The vlan_tag_mask_tbl_addr is the DMA address of the VLAN antispoof
* table to which firmware will DMA to. Each table entry will contain
* the 16-bit TPID (0x8100 or 0x88a8 only), 16-bit VLAN ID, and a 16-bit
* mask, all in network order to match hwrm_cfa_l2_set_rx_mask. For an
* individual VLAN entry, the mask value should be 0xfff for the 12-bit
* VLAN ID.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vlan_antispoof_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t num_vlan_entries;
/* Number of valid entries DMAd by firmware to vlan_tag_mask_tbl. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_tunnel_filter_alloc */
/*
* Description: This is a tunnel filter that uses fields from tunnel header in
* addition to l2 context. The tunnel filter applies to receive side only. The
* l2_* fields in this command represent fields of inner L2 header. They are
* optional to be specified. It allows l2_filter_id to be created with outer L2
* header fields that can be shared with multiple tunnel filters specified as
* combinations of inner L2 header fields, tunnel type, and VNI.
*/
/* Input (88 bytes) */
struct hwrm_cfa_tunnel_filter_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Setting of this flag indicates the applicability to the loopback
* path.
*/
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_FLAGS_LOOPBACK UINT32_C(0x1)
uint32_t enables;
/* This bit must be '1' for the l2_filter_id field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_L2_FILTER_ID UINT32_C(0x1)
/* This bit must be '1' for the l2_addr field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_L2_ADDR UINT32_C(0x2)
/* This bit must be '1' for the l2_ivlan field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_L2_IVLAN UINT32_C(0x4)
/* This bit must be '1' for the l3_addr field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_L3_ADDR UINT32_C(0x8)
/* This bit must be '1' for the l3_addr_type field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_L3_ADDR_TYPE UINT32_C(0x10)
/* This bit must be '1' for the t_l3_addr_type field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_T_L3_ADDR_TYPE UINT32_C(0x20)
/* This bit must be '1' for the t_l3_addr field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_T_L3_ADDR UINT32_C(0x40)
/* This bit must be '1' for the tunnel_type field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_TUNNEL_TYPE UINT32_C(0x80)
/* This bit must be '1' for the vni field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_VNI UINT32_C(0x100)
/* This bit must be '1' for the dst_vnic_id field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_DST_VNIC_ID UINT32_C(0x200)
/* This bit must be '1' for the mirror_vnic_id field to be configured. */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_ENABLES_MIRROR_VNIC_ID UINT32_C(0x400)
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
uint8_t l2_addr[6];
/*
* This value sets the match value for the inner L2 MAC address.
* Destination MAC address for RX path. Source MAC address for TX path.
*/
uint16_t l2_ivlan;
/*
* This value sets VLAN ID value for inner VLAN. Only 12-bits of VLAN ID
* are used in setting the filter.
*/
uint32_t l3_addr[4];
/*
* The value of inner destination IP address to be used in filtering.
* For IPv4, first four bytes represent the IP address.
*/
uint32_t t_l3_addr[4];
/*
* The value of tunnel destination IP address to be used in filtering.
* For IPv4, first four bytes represent the IP address.
*/
uint8_t l3_addr_type;
/*
* This value indicates the type of inner IP address. 4 - IPv4 6 - IPv6
* All others are invalid.
*/
uint8_t t_l3_addr_type;
/*
* This value indicates the type of tunnel IP address. 4 - IPv4 6 - IPv6
* All others are invalid.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Non-tunnel */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NONTUNNEL UINT32_C(0x0)
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) inside Ethernet payload */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_MPLS UINT32_C(0x6)
/* Stateless Transport Tunnel (STT) */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_STT UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPGRE UINT32_C(0x8)
/* Any tunneled traffic */
#define HWRM_CFA_TUNNEL_FILTER_ALLOC_INPUT_TUNNEL_TYPE_ANYTUNNEL UINT32_C(0xff)
uint8_t unused_0;
uint32_t vni;
/*
* Virtual Network Identifier (VNI). Only valid with tunnel_types VXLAN,
* NVGRE, and Geneve. Only lower 24-bits of VNI field are used in
* setting up the filter.
*/
uint32_t dst_vnic_id;
/* Logical VNIC ID of the destination VNIC. */
uint32_t mirror_vnic_id;
/* Logical VNIC ID of the VNIC where traffic is mirrored. */
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_cfa_tunnel_filter_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t tunnel_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t flow_id;
/*
* This is the ID of the flow associated with this filter. This value
* shall be used to match and associate the flow identifier returned in
* completion records. A value of 0xFFFFFFFF shall indicate no flow id.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_tunnel_filter_free */
/* Description: Free a tunnel filter */
/* Input (24 bytes) */
struct hwrm_cfa_tunnel_filter_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t tunnel_filter_id;
/* This value is an opaque id into CFA data structures. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_tunnel_filter_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_encap_record_alloc */
/*
* Description: This command is used to create an encapsulation record. The
* source MAC address and source IP address specified for the source property
* checks shall be used in the encapsulation where applicable.
*/
/* Input (32 bytes) */
struct hwrm_cfa_encap_record_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Setting of this flag indicates the applicability to the loopback
* path.
*/
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_FLAGS_LOOPBACK UINT32_C(0x1)
uint8_t encap_type;
/* Encapsulation Type. */
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) after inside Ethernet payload */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_MPLS UINT32_C(0x6)
/* VLAN */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_VLAN UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_ENCAP_RECORD_ALLOC_INPUT_ENCAP_TYPE_IPGRE UINT32_C(0x8)
uint8_t unused_0;
uint16_t unused_1;
uint32_t encap_data[20];
/* This value is encap data used for the given encap type. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_encap_record_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t encap_record_id;
/* This value is an opaque id into CFA data structures. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_encap_record_free */
/* Description: Free an encap record */
/* Input (24 bytes) */
struct hwrm_cfa_encap_record_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t encap_record_id;
/* This value is an opaque id into CFA data structures. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_encap_record_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_ntuple_filter_alloc */
/*
* Description: This is a ntuple filter that uses fields from L4/L3 header and
* optionally fields from L2. The ntuple filters apply to receive traffic only.
* All L2/L3/L4 header fields are specified in network byte order. These filters
* can be used for Receive Flow Steering (RFS). # For ethertype value, only
* 0x0800 (IPv4) and 0x86dd (IPv6) shall be supported for ntuple filters. # If a
* field specified in this command is not enabled as a valid field, then that
* field shall not be used in matching packet header fields against this filter.
*/
/* Input (128 bytes) */
struct hwrm_cfa_ntuple_filter_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Setting of this flag indicates the applicability to the loopback
* path.
*/
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_FLAGS_LOOPBACK UINT32_C(0x1)
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_FLAGS_DROP UINT32_C(0x2)
/*
* Setting of this flag indicates that a meter is expected to be
* attached to this flow. This hint can be used when choosing the action
* record format required for the flow.
*/
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_FLAGS_METER UINT32_C(0x4)
uint32_t enables;
/* This bit must be '1' for the l2_filter_id field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_L2_FILTER_ID UINT32_C(0x1)
/* This bit must be '1' for the ethertype field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_ETHERTYPE UINT32_C(0x2)
/* This bit must be '1' for the tunnel_type field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_TUNNEL_TYPE UINT32_C(0x4)
/* This bit must be '1' for the src_macaddr field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_SRC_MACADDR UINT32_C(0x8)
/* This bit must be '1' for the ipaddr_type field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_IPADDR_TYPE UINT32_C(0x10)
/* This bit must be '1' for the src_ipaddr field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_SRC_IPADDR UINT32_C(0x20)
/* This bit must be '1' for the src_ipaddr_mask field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_SRC_IPADDR_MASK UINT32_C(0x40)
/* This bit must be '1' for the dst_ipaddr field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_IPADDR UINT32_C(0x80)
/* This bit must be '1' for the dst_ipaddr_mask field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_IPADDR_MASK UINT32_C(0x100)
/* This bit must be '1' for the ip_protocol field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_IP_PROTOCOL UINT32_C(0x200)
/* This bit must be '1' for the src_port field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_SRC_PORT UINT32_C(0x400)
/* This bit must be '1' for the src_port_mask field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_SRC_PORT_MASK UINT32_C(0x800)
/* This bit must be '1' for the dst_port field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_PORT UINT32_C(0x1000)
/* This bit must be '1' for the dst_port_mask field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_PORT_MASK UINT32_C(0x2000)
/* This bit must be '1' for the pri_hint field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_PRI_HINT UINT32_C(0x4000)
/* This bit must be '1' for the ntuple_filter_id field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_NTUPLE_FILTER_ID UINT32_C(0x8000)
/* This bit must be '1' for the dst_id field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_ID UINT32_C(0x10000)
/* This bit must be '1' for the mirror_vnic_id field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_MIRROR_VNIC_ID UINT32_C(0x20000)
/* This bit must be '1' for the dst_macaddr field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_ENABLES_DST_MACADDR UINT32_C(0x40000)
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
uint8_t src_macaddr[6];
/* This value indicates the source MAC address in the Ethernet header. */
uint16_t ethertype; /* big endian */
/* This value indicates the ethertype in the Ethernet header. */
uint8_t ip_addr_type;
/*
* This value indicates the type of IP address. 4 - IPv4 6 - IPv6 All
* others are invalid.
*/
/* invalid */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_UNKNOWN UINT32_C(0x0)
/* IPv4 */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_IPV4 UINT32_C(0x4)
/* IPv6 */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_IPV6 UINT32_C(0x6)
uint8_t ip_protocol;
/*
* The value of protocol filed in IP header. Applies to UDP and TCP
* traffic. 6 - TCP 17 - UDP
*/
/* invalid */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_PROTOCOL_UNKNOWN UINT32_C(0x0)
/* TCP */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_PROTOCOL_TCP UINT32_C(0x6)
/* UDP */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_IP_PROTOCOL_UDP UINT32_C(0x11)
uint16_t dst_id;
/*
* If set, this value shall represent the Logical VNIC ID of the
* destination VNIC for the RX path and network port id of the
* destination port for the TX path.
*/
uint16_t mirror_vnic_id;
/* Logical VNIC ID of the VNIC where traffic is mirrored. */
uint8_t tunnel_type;
/*
* This value indicates the tunnel type for this filter. If this field
* is not specified, then the filter shall apply to both non-tunneled
* and tunneled packets. If this field conflicts with the tunnel_type
* specified in the l2_filter_id, then the HWRM shall return an error
* for this command.
*/
/* Non-tunnel */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NONTUNNEL UINT32_C(0x0)
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) inside Ethernet payload */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_MPLS UINT32_C(0x6)
/* Stateless Transport Tunnel (STT) */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_STT UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPGRE UINT32_C(0x8)
/* Any tunneled traffic */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_TUNNEL_TYPE_ANYTUNNEL UINT32_C(0xff)
uint8_t pri_hint;
/*
* This hint is provided to help in placing the filter in the filter
* table.
*/
/* No preference */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_PRI_HINT_NO_PREFER UINT32_C(0x0)
/* Above the given filter */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_PRI_HINT_ABOVE UINT32_C(0x1)
/* Below the given filter */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_PRI_HINT_BELOW UINT32_C(0x2)
/* As high as possible */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_PRI_HINT_HIGHEST UINT32_C(0x3)
/* As low as possible */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_INPUT_PRI_HINT_LOWEST UINT32_C(0x4)
uint32_t src_ipaddr[4]; /* big endian */
/*
* The value of source IP address to be used in filtering. For IPv4,
* first four bytes represent the IP address.
*/
uint32_t src_ipaddr_mask[4]; /* big endian */
/*
* The value of source IP address mask to be used in filtering. For
* IPv4, first four bytes represent the IP address mask.
*/
uint32_t dst_ipaddr[4]; /* big endian */
/*
* The value of destination IP address to be used in filtering. For
* IPv4, first four bytes represent the IP address.
*/
uint32_t dst_ipaddr_mask[4]; /* big endian */
/*
* The value of destination IP address mask to be used in filtering. For
* IPv4, first four bytes represent the IP address mask.
*/
uint16_t src_port; /* big endian */
/*
* The value of source port to be used in filtering. Applies to UDP and
* TCP traffic.
*/
uint16_t src_port_mask; /* big endian */
/*
* The value of source port mask to be used in filtering. Applies to UDP
* and TCP traffic.
*/
uint16_t dst_port; /* big endian */
/*
* The value of destination port to be used in filtering. Applies to UDP
* and TCP traffic.
*/
uint16_t dst_port_mask; /* big endian */
/*
* The value of destination port mask to be used in filtering. Applies
* to UDP and TCP traffic.
*/
uint64_t ntuple_filter_id_hint;
/* This is the ID of the filter that goes along with the pri_hint. */
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_cfa_ntuple_filter_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t ntuple_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t flow_id;
/*
* This is the ID of the flow associated with this filter. This value
* shall be used to match and associate the flow identifier returned in
* completion records. A value of 0xFFFFFFFF shall indicate no flow id.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_cfa_ntuple_filter_alloc_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* Unable to complete operation due to conflict with Rx Mask VLAN */
#define HWRM_CFA_NTUPLE_FILTER_ALLOC_CMD_ERR_CODE_RX_MASK_VLAN_CONFLICT_ERR UINT32_C(0x1)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_cfa_ntuple_filter_free */
/* Description: Free an ntuple filter */
/* Input (24 bytes) */
struct hwrm_cfa_ntuple_filter_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t ntuple_filter_id;
/* This value is an opaque id into CFA data structures. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_ntuple_filter_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_ntuple_filter_cfg */
/*
* Description: Configure an ntuple filter with a new destination VNIC and/or
* meter.
*/
/* Input (48 bytes) */
struct hwrm_cfa_ntuple_filter_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the new_dst_id field to be configured. */
#define HWRM_CFA_NTUPLE_FILTER_CFG_INPUT_ENABLES_NEW_DST_ID UINT32_C(0x1)
/*
* This bit must be '1' for the new_mirror_vnic_id field to be
* configured.
*/
#define HWRM_CFA_NTUPLE_FILTER_CFG_INPUT_ENABLES_NEW_MIRROR_VNIC_ID UINT32_C(0x2)
/*
* This bit must be '1' for the new_meter_instance_id field to be
* configured.
*/
#define HWRM_CFA_NTUPLE_FILTER_CFG_INPUT_ENABLES_NEW_METER_INSTANCE_ID UINT32_C(0x4)
uint32_t unused_0;
uint64_t ntuple_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t new_dst_id;
/*
* If set, this value shall represent the new Logical VNIC ID of the
* destination VNIC for the RX path and new network port id of the
* destination port for the TX path.
*/
uint32_t new_mirror_vnic_id;
/* New Logical VNIC ID of the VNIC where traffic is mirrored. */
uint16_t new_meter_instance_id;
/*
* New meter to attach to the flow. Specifying the invalid instance ID
* is used to remove any existing meter from the flow.
*/
/*
* A value of 0xfff is considered invalid and implies the
* instance is not configured.
*/
#define HWRM_CFA_NTUPLE_FILTER_CFG_INPUT_NEW_METER_INSTANCE_ID_INVALID UINT32_C(0xffff)
uint16_t unused_1[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_ntuple_filter_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_em_flow_alloc */
/*
* Description: This is a generic Exact Match (EM) flow that uses fields from
* L4/L3/L2 headers. The EM flows apply to transmit and receive traffic. All
* L2/L3/L4 header fields are specified in network byte order. For each EM flow,
* there is an associated set of actions specified. For tunneled packets, all
* L2/L3/L4 fields specified are fields of inner headers unless otherwise
* specified. # If a field specified in this command is not enabled as a valid
* field, then that field shall not be used in matching packet header fields
* against this EM flow entry.
*/
/* Input (112 bytes) */
struct hwrm_cfa_em_flow_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PATH_TX (UINT32_C(0x0) << 0)
/* rx path */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PATH_RX (UINT32_C(0x1) << 0)
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PATH_LAST HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PATH_RX
/*
* Setting of this flag indicates enabling of a byte counter for a given
* flow.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_BYTE_CTR UINT32_C(0x2)
/*
* Setting of this flag indicates enabling of a packet counter for a
* given flow.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_PKT_CTR UINT32_C(0x4)
/*
* Setting of this flag indicates de-capsulation action for the given
* flow.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_DECAP UINT32_C(0x8)
/*
* Setting of this flag indicates encapsulation action for the given
* flow.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_ENCAP UINT32_C(0x10)
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_DROP UINT32_C(0x20)
/*
* Setting of this flag indicates that a meter is expected to be
* attached to this flow. This hint can be used when choosing the action
* record format required for the flow.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_FLAGS_METER UINT32_C(0x40)
uint32_t enables;
/* This bit must be '1' for the l2_filter_id field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_L2_FILTER_ID UINT32_C(0x1)
/* This bit must be '1' for the tunnel_type field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_TUNNEL_TYPE UINT32_C(0x2)
/* This bit must be '1' for the tunnel_id field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_TUNNEL_ID UINT32_C(0x4)
/* This bit must be '1' for the src_macaddr field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_SRC_MACADDR UINT32_C(0x8)
/* This bit must be '1' for the dst_macaddr field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_DST_MACADDR UINT32_C(0x10)
/* This bit must be '1' for the ovlan_vid field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_OVLAN_VID UINT32_C(0x20)
/* This bit must be '1' for the ivlan_vid field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_IVLAN_VID UINT32_C(0x40)
/* This bit must be '1' for the ethertype field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_ETHERTYPE UINT32_C(0x80)
/* This bit must be '1' for the src_ipaddr field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_SRC_IPADDR UINT32_C(0x100)
/* This bit must be '1' for the dst_ipaddr field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_DST_IPADDR UINT32_C(0x200)
/* This bit must be '1' for the ipaddr_type field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_IPADDR_TYPE UINT32_C(0x400)
/* This bit must be '1' for the ip_protocol field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_IP_PROTOCOL UINT32_C(0x800)
/* This bit must be '1' for the src_port field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_SRC_PORT UINT32_C(0x1000)
/* This bit must be '1' for the dst_port field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_DST_PORT UINT32_C(0x2000)
/* This bit must be '1' for the dst_id field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_DST_ID UINT32_C(0x4000)
/* This bit must be '1' for the mirror_vnic_id field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_MIRROR_VNIC_ID UINT32_C(0x8000)
/* This bit must be '1' for the encap_record_id field to be configured. */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_ENCAP_RECORD_ID UINT32_C(0x10000)
/*
* This bit must be '1' for the meter_instance_id field to be
* configured.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_ENABLES_METER_INSTANCE_ID UINT32_C(0x20000)
uint64_t l2_filter_id;
/*
* This value identifies a set of CFA data structures used for an L2
* context.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Non-tunnel */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_NONTUNNEL UINT32_C(0x0)
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) inside Ethernet payload */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_MPLS UINT32_C(0x6)
/* Stateless Transport Tunnel (STT) */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_STT UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_IPGRE UINT32_C(0x8)
/* Any tunneled traffic */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_TUNNEL_TYPE_ANYTUNNEL UINT32_C(0xff)
uint8_t unused_0;
uint16_t unused_1;
uint32_t tunnel_id;
/*
* Tunnel identifier. Virtual Network Identifier (VNI). Only valid with
* tunnel_types VXLAN, NVGRE, and Geneve. Only lower 24-bits of VNI
* field are used in setting up the filter.
*/
uint8_t src_macaddr[6];
/* This value indicates the source MAC address in the Ethernet header. */
uint16_t meter_instance_id;
/* The meter instance to attach to the flow. */
/*
* A value of 0xfff is considered invalid and implies the
* instance is not configured.
*/
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_METER_INSTANCE_ID_INVALID UINT32_C(0xffff)
uint8_t dst_macaddr[6];
/*
* This value indicates the destination MAC address in the Ethernet
* header.
*/
uint16_t ovlan_vid;
/*
* This value indicates the VLAN ID of the outer VLAN tag in the
* Ethernet header.
*/
uint16_t ivlan_vid;
/*
* This value indicates the VLAN ID of the inner VLAN tag in the
* Ethernet header.
*/
uint16_t ethertype; /* big endian */
/* This value indicates the ethertype in the Ethernet header. */
uint8_t ip_addr_type;
/*
* This value indicates the type of IP address. 4 - IPv4 6 - IPv6 All
* others are invalid.
*/
/* invalid */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_ADDR_TYPE_UNKNOWN UINT32_C(0x0)
/* IPv4 */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_ADDR_TYPE_IPV4 UINT32_C(0x4)
/* IPv6 */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_ADDR_TYPE_IPV6 UINT32_C(0x6)
uint8_t ip_protocol;
/*
* The value of protocol filed in IP header. Applies to UDP and TCP
* traffic. 6 - TCP 17 - UDP
*/
/* invalid */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_PROTOCOL_UNKNOWN UINT32_C(0x0)
/* TCP */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_PROTOCOL_TCP UINT32_C(0x6)
/* UDP */
#define HWRM_CFA_EM_FLOW_ALLOC_INPUT_IP_PROTOCOL_UDP UINT32_C(0x11)
uint8_t unused_2;
uint8_t unused_3;
uint32_t src_ipaddr[4]; /* big endian */
/*
* The value of source IP address to be used in filtering. For IPv4,
* first four bytes represent the IP address.
*/
uint32_t dst_ipaddr[4]; /* big endian */
/*
* big_endian = True The value of destination IP address to be used in
* filtering. For IPv4, first four bytes represent the IP address.
*/
uint16_t src_port; /* big endian */
/*
* The value of source port to be used in filtering. Applies to UDP and
* TCP traffic.
*/
uint16_t dst_port; /* big endian */
/*
* The value of destination port to be used in filtering. Applies to UDP
* and TCP traffic.
*/
uint16_t dst_id;
/*
* If set, this value shall represent the Logical VNIC ID of the
* destination VNIC for the RX path and network port id of the
* destination port for the TX path.
*/
uint16_t mirror_vnic_id;
/* Logical VNIC ID of the VNIC where traffic is mirrored. */
uint32_t encap_record_id;
/* Logical ID of the encapsulation record. */
uint32_t unused_4;
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_cfa_em_flow_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t em_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t flow_id;
/*
* This is the ID of the flow associated with this filter. This value
* shall be used to match and associate the flow identifier returned in
* completion records. A value of 0xFFFFFFFF shall indicate no flow id.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_em_flow_free */
/* Description: Free an EM flow table entry */
/* Input (24 bytes) */
struct hwrm_cfa_em_flow_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t em_filter_id;
/* This value is an opaque id into CFA data structures. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_em_flow_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_em_flow_cfg */
/*
* Description: Configure an EM flow with a new destination VNIC and/or meter.
*/
/* Input (48 bytes) */
struct hwrm_cfa_em_flow_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the new_dst_id field to be configured. */
#define HWRM_CFA_EM_FLOW_CFG_INPUT_ENABLES_NEW_DST_ID UINT32_C(0x1)
/*
* This bit must be '1' for the new_mirror_vnic_id field to be
* configured.
*/
#define HWRM_CFA_EM_FLOW_CFG_INPUT_ENABLES_NEW_MIRROR_VNIC_ID UINT32_C(0x2)
/*
* This bit must be '1' for the new_meter_instance_id field to be
* configured.
*/
#define HWRM_CFA_EM_FLOW_CFG_INPUT_ENABLES_NEW_METER_INSTANCE_ID UINT32_C(0x4)
uint32_t unused_0;
uint64_t em_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t new_dst_id;
/*
* If set, this value shall represent the new Logical VNIC ID of the
* destination VNIC for the RX path and network port id of the
* destination port for the TX path.
*/
uint32_t new_mirror_vnic_id;
/* New Logical VNIC ID of the VNIC where traffic is mirrored. */
uint16_t new_meter_instance_id;
/*
* New meter to attach to the flow. Specifying the invalid instance ID
* is used to remove any existing meter from the flow.
*/
/*
* A value of 0xfff is considered invalid and implies the
* instance is not configured.
*/
#define HWRM_CFA_EM_FLOW_CFG_INPUT_NEW_METER_INSTANCE_ID_INVALID UINT32_C(0xffff)
uint16_t unused_1[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_em_flow_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_meter_profile_alloc */
/*
* Description: This is a meter profile that defines the characteristics of the
* meter. This includes the algorithm, information rates, and burst sizes. No
* running state is kept in a profile and instead meter instances are allocated
* that reference a profile.
*/
/* Input (40 bytes) */
struct hwrm_cfa_meter_profile_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_FLAGS_PATH_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_FLAGS_PATH_RX
uint8_t meter_type;
/* The meter algorithm type. */
/* RFC 2697 (srTCM) */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_METER_TYPE_RFC2697 UINT32_C(0x0)
/* RFC 2698 (trTCM) */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_METER_TYPE_RFC2698 UINT32_C(0x1)
/* RFC 4115 (trTCM) */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_METER_TYPE_RFC4115 UINT32_C(0x2)
uint16_t reserved1;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t reserved2;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t commit_rate;
/* A meter rate specified in bytes-per-second. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_SCALE_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_RATE_BW_VALUE_UNIT_INVALID
uint32_t commit_burst;
/* A meter burst size specified in bytes. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_SCALE_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_COMMIT_BURST_BW_VALUE_UNIT_INVALID
uint32_t excess_peak_rate;
/* A meter rate specified in bytes-per-second. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_SCALE_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_INVALID
uint32_t excess_peak_burst;
/* A meter burst size specified in bytes. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_SCALE_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_ALLOC_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_INVALID
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_meter_profile_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t meter_profile_id;
/* This value identifies a meter profile in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* profile is not configured.
*/
#define HWRM_CFA_METER_PROFILE_ALLOC_OUTPUT_METER_PROFILE_ID_INVALID UINT32_C(0xffff)
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_meter_profile_free */
/* Description: Free a meter profile. */
/* Input (24 bytes) */
struct hwrm_cfa_meter_profile_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_METER_PROFILE_FREE_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_METER_PROFILE_FREE_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_CFA_METER_PROFILE_FREE_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_CFA_METER_PROFILE_FREE_INPUT_FLAGS_PATH_LAST HWRM_CFA_METER_PROFILE_FREE_INPUT_FLAGS_PATH_RX
uint8_t unused_0;
uint16_t meter_profile_id;
/* This value identifies a meter profile in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* profile is not configured.
*/
#define HWRM_CFA_METER_PROFILE_FREE_INPUT_METER_PROFILE_ID_INVALID UINT32_C(0xffff)
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_meter_profile_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_meter_profile_cfg */
/* Description: Reconfigure a meter profile. */
/* Input (40 bytes) */
struct hwrm_cfa_meter_profile_cfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_FLAGS_PATH_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_FLAGS_PATH_RX
uint8_t meter_type;
/* The meter algorithm type. */
/* RFC 2697 (srTCM) */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_METER_TYPE_RFC2697 UINT32_C(0x0)
/* RFC 2698 (trTCM) */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_METER_TYPE_RFC2698 UINT32_C(0x1)
/* RFC 4115 (trTCM) */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_METER_TYPE_RFC4115 UINT32_C(0x2)
uint16_t meter_profile_id;
/* This value identifies a meter profile in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* profile is not configured.
*/
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_METER_PROFILE_ID_INVALID UINT32_C(0xffff)
uint32_t reserved;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t commit_rate;
/* A meter rate specified in bytes-per-second. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_SCALE_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_RATE_BW_VALUE_UNIT_INVALID
uint32_t commit_burst;
/* A meter burst size specified in bytes. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_SCALE_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_COMMIT_BURST_BW_VALUE_UNIT_INVALID
uint32_t excess_peak_rate;
/* A meter rate specified in bytes-per-second. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_SCALE_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_RATE_BW_VALUE_UNIT_INVALID
uint32_t excess_peak_burst;
/* A meter burst size specified in bytes. */
/* The bandwidth value. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_MASK UINT32_C(0xfffffff)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_SFT 0
/* The granularity of the value (bits or bytes). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_SCALE UINT32_C(0x10000000)
/* Value is in bits. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_SCALE_BITS (UINT32_C(0x0) << 28)
/* Value is in bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_SCALE_BYTES (UINT32_C(0x1) << 28)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_SCALE_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_SCALE_BYTES
/* bw_value_unit is 3 b */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_MASK UINT32_C(0xe0000000)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_SFT 29
/* Value is in Mb or MB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_MEGA (UINT32_C(0x0) << 29)
/* Value is in Kb or KB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_KILO (UINT32_C(0x2) << 29)
/* Value is in bits or bytes. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_BASE (UINT32_C(0x4) << 29)
/* Value is in Gb or GB (base 10). */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_GIGA (UINT32_C(0x6) << 29)
/* Value is in 1/100th of a percentage of total bandwidth. */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_PERCENT1_100 (UINT32_C(0x1) << 29)
/* Invalid unit */
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_INVALID (UINT32_C(0x7) << 29)
#define HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_LAST HWRM_CFA_METER_PROFILE_CFG_INPUT_EXCESS_PEAK_BURST_BW_VALUE_UNIT_INVALID
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_meter_profile_cfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_meter_instance_alloc */
/*
* Description: This is a meter instance which is used to track a meter's bucket
* fill values for a flow. Each meter instance references a meter profile that
* defines the meter algorithm in use.
*/
/* Input (24 bytes) */
struct hwrm_cfa_meter_instance_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_FLAGS_PATH_LAST HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_FLAGS_PATH_RX
uint8_t unused_0;
uint16_t meter_profile_id;
/* This value identifies a meter profile in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* profile is not configured.
*/
#define HWRM_CFA_METER_INSTANCE_ALLOC_INPUT_METER_PROFILE_ID_INVALID UINT32_C(0xffff)
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_meter_instance_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t meter_instance_id;
/* This value identifies a meter instance in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* instance is not configured.
*/
#define HWRM_CFA_METER_INSTANCE_ALLOC_OUTPUT_METER_INSTANCE_ID_INVALID UINT32_C(0xffff)
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_meter_instance_free */
/* Description: Free a meter instance. */
/* Input (24 bytes) */
struct hwrm_cfa_meter_instance_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/*
* Enumeration denoting the RX, TX type of the resource. This
* enumeration is used for resources that are similar for both TX and RX
* paths of the chip.
*/
#define HWRM_CFA_METER_INSTANCE_FREE_INPUT_FLAGS_PATH UINT32_C(0x1)
/* tx path */
#define HWRM_CFA_METER_INSTANCE_FREE_INPUT_FLAGS_PATH_TX UINT32_C(0x0)
/* rx path */
#define HWRM_CFA_METER_INSTANCE_FREE_INPUT_FLAGS_PATH_RX UINT32_C(0x1)
#define HWRM_CFA_METER_INSTANCE_FREE_INPUT_FLAGS_PATH_LAST HWRM_CFA_METER_INSTANCE_FREE_INPUT_FLAGS_PATH_RX
uint8_t unused_0;
uint16_t meter_instance_id;
/* This value identifies a meter instance in CFA. */
/*
* A value of 0xfff is considered invalid and implies the
* instance is not configured.
*/
#define HWRM_CFA_METER_INSTANCE_FREE_INPUT_METER_INSTANCE_ID_INVALID UINT32_C(0xffff)
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_meter_instance_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_decap_filter_alloc */
/*
* Description: This command uses fields from L4/L3/L2 headers. All L2/L3/L4
* header fields are specified in network byte order.
*/
/* Input (104 bytes) */
struct hwrm_cfa_decap_filter_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/* ovs_tunnel is 1 b */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_FLAGS_OVS_TUNNEL UINT32_C(0x1)
uint32_t enables;
/* This bit must be '1' for the tunnel_type field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_TUNNEL_TYPE UINT32_C(0x1)
/* This bit must be '1' for the tunnel_id field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_TUNNEL_ID UINT32_C(0x2)
/* This bit must be '1' for the src_macaddr field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_SRC_MACADDR UINT32_C(0x4)
/* This bit must be '1' for the dst_macaddr field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_DST_MACADDR UINT32_C(0x8)
/* This bit must be '1' for the ovlan_vid field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_OVLAN_VID UINT32_C(0x10)
/* This bit must be '1' for the ivlan_vid field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_IVLAN_VID UINT32_C(0x20)
/* This bit must be '1' for the t_ovlan_vid field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_T_OVLAN_VID UINT32_C(0x40)
/* This bit must be '1' for the t_ivlan_vid field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_T_IVLAN_VID UINT32_C(0x80)
/* This bit must be '1' for the ethertype field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_ETHERTYPE UINT32_C(0x100)
/* This bit must be '1' for the src_ipaddr field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_SRC_IPADDR UINT32_C(0x200)
/* This bit must be '1' for the dst_ipaddr field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_DST_IPADDR UINT32_C(0x400)
/* This bit must be '1' for the ipaddr_type field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_IPADDR_TYPE UINT32_C(0x800)
/* This bit must be '1' for the ip_protocol field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_IP_PROTOCOL UINT32_C(0x1000)
/* This bit must be '1' for the src_port field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_SRC_PORT UINT32_C(0x2000)
/* This bit must be '1' for the dst_port field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_DST_PORT UINT32_C(0x4000)
/* This bit must be '1' for the dst_id field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_DST_ID UINT32_C(0x8000)
/* This bit must be '1' for the mirror_vnic_id field to be configured. */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_ENABLES_MIRROR_VNIC_ID UINT32_C(0x10000)
uint32_t tunnel_id;
/*
* Tunnel identifier. Virtual Network Identifier (VNI). Only valid with
* tunnel_types VXLAN, NVGRE, and Geneve. Only lower 24-bits of VNI
* field are used in setting up the filter.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Non-tunnel */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NONTUNNEL UINT32_C(0x0)
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Network Virtualization Generic Routing Encapsulation (NVGRE) */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_NVGRE UINT32_C(0x2)
/* Generic Routing Encapsulation (GRE) inside Ethernet payload */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_L2GRE UINT32_C(0x3)
/* IP in IP */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPIP UINT32_C(0x4)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
/* Multi-Protocol Lable Switching (MPLS) */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_MPLS UINT32_C(0x6)
/* Stateless Transport Tunnel (STT) */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_STT UINT32_C(0x7)
/* Generic Routing Encapsulation (GRE) inside IP datagram payload */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_IPGRE UINT32_C(0x8)
/* Any tunneled traffic */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_TUNNEL_TYPE_ANYTUNNEL UINT32_C(0xff)
uint8_t unused_0;
uint16_t unused_1;
uint8_t src_macaddr[6];
/* This value indicates the source MAC address in the Ethernet header. */
uint8_t unused_2;
uint8_t unused_3;
uint8_t dst_macaddr[6];
/*
* This value indicates the destination MAC address in the Ethernet
* header.
*/
uint16_t ovlan_vid;
/*
* This value indicates the VLAN ID of the outer VLAN tag in the
* Ethernet header.
*/
uint16_t ivlan_vid;
/*
* This value indicates the VLAN ID of the inner VLAN tag in the
* Ethernet header.
*/
uint16_t t_ovlan_vid;
/*
* This value indicates the VLAN ID of the outer VLAN tag in the tunnel
* Ethernet header.
*/
uint16_t t_ivlan_vid;
/*
* This value indicates the VLAN ID of the inner VLAN tag in the tunnel
* Ethernet header.
*/
uint16_t ethertype; /* big endian */
/* This value indicates the ethertype in the Ethernet header. */
uint8_t ip_addr_type;
/*
* This value indicates the type of IP address. 4 - IPv4 6 - IPv6 All
* others are invalid.
*/
/* invalid */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_UNKNOWN UINT32_C(0x0)
/* IPv4 */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_IPV4 UINT32_C(0x4)
/* IPv6 */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_ADDR_TYPE_IPV6 UINT32_C(0x6)
uint8_t ip_protocol;
/*
* The value of protocol filed in IP header. Applies to UDP and TCP
* traffic. 6 - TCP 17 - UDP
*/
/* invalid */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_PROTOCOL_UNKNOWN UINT32_C(0x0)
/* TCP */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_PROTOCOL_TCP UINT32_C(0x6)
/* UDP */
#define HWRM_CFA_DECAP_FILTER_ALLOC_INPUT_IP_PROTOCOL_UDP UINT32_C(0x11)
uint8_t unused_4;
uint8_t unused_5;
uint8_t unused_6[3];
uint8_t unused_7;
uint32_t src_ipaddr[4]; /* big endian */
/*
* The value of source IP address to be used in filtering. For IPv4,
* first four bytes represent the IP address.
*/
uint32_t dst_ipaddr[4]; /* big endian */
/*
* The value of destination IP address to be used in filtering. For
* IPv4, first four bytes represent the IP address.
*/
uint16_t src_port; /* big endian */
/*
* The value of source port to be used in filtering. Applies to UDP and
* TCP traffic.
*/
uint16_t dst_port; /* big endian */
/*
* The value of destination port to be used in filtering. Applies to UDP
* and TCP traffic.
*/
uint16_t dst_id;
/*
* If set, this value shall represent the Logical VNIC ID of the
* destination VNIC for the RX path.
*/
uint16_t l2_ctxt_ref_id;
/*
* If set, this value shall represent the L2 context that matches the L2
* information of the decap filter.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_decap_filter_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t decap_filter_id;
/* This value is an opaque id into CFA data structures. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_decap_filter_free */
/* Description: Free an decap filter table entry */
/* Input (24 bytes) */
struct hwrm_cfa_decap_filter_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t decap_filter_id;
/* This value is an opaque id into CFA data structures. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_decap_filter_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_flow_alloc */
/* Description: Flow is added to table and resources are allocated. */
/* Input (128 bytes) */
struct hwrm_cfa_flow_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t flags;
/* tunnel is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_TUNNEL UINT32_C(0x1)
/* num_vlan is 2 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_MASK UINT32_C(0x6)
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_SFT 1
/* no tags */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_NONE (UINT32_C(0x0) << 1)
/* 1 tag */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_ONE (UINT32_C(0x1) << 1)
/* 2 tags */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_TWO (UINT32_C(0x2) << 1)
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_LAST HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_NUM_VLAN_TWO
/* Enumeration denoting the Flow Type. */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_MASK UINT32_C(0x38)
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_SFT 3
/* L2 flow */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_L2 (UINT32_C(0x0) << 3)
/* IPV4 flow */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_IPV4 (UINT32_C(0x1) << 3)
/* IPV6 flow */
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_IPV6 (UINT32_C(0x2) << 3)
#define HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_LAST HWRM_CFA_FLOW_ALLOC_INPUT_FLAGS_FLOWTYPE_IPV6
uint16_t src_fid;
/* Tx Flow: vf fid. Rx Flow: pf fid. */
uint32_t tunnel_handle;
/* Tunnel handle valid when tunnel flag is set. */
uint16_t action_flags;
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_FWD UINT32_C(0x1)
/* recycle is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_RECYCLE UINT32_C(0x2)
/*
* Setting of this flag indicates drop action. If this flag is not set,
* then it should be considered accept action.
*/
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_DROP UINT32_C(0x4)
/* meter is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_METER UINT32_C(0x8)
/* tunnel is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_TUNNEL UINT32_C(0x10)
/* nat_src is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_NAT_SRC UINT32_C(0x20)
/* nat_dest is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_NAT_DEST UINT32_C(0x40)
/* nat_ipv4_address is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_NAT_IPV4_ADDRESS UINT32_C(0x80)
/* l2_header_rewrite is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_L2_HEADER_REWRITE UINT32_C(0x100)
/* ttl_decrement is 1 b */
#define HWRM_CFA_FLOW_ALLOC_INPUT_ACTION_FLAGS_TTL_DECREMENT UINT32_C(0x200)
uint16_t dst_fid;
/* Tx Flow: pf or vf fid. Rx Flow: vf fid. */
uint16_t l2_rewrite_vlan_tpid; /* big endian */
/* VLAN tpid, valid when push_vlan flag is set. */
uint16_t l2_rewrite_vlan_tci; /* big endian */
/* VLAN tci, valid when push_vlan flag is set. */
uint16_t act_meter_id;
/* Meter id, valid when meter flag is set. */
uint16_t ref_flow_handle;
/* Flow with the same l2 context tcam key. */
uint16_t ethertype; /* big endian */
/* This value sets the match value for the ethertype. */
uint16_t outer_vlan_tci; /* big endian */
/* valid when num tags is 1 or 2. */
uint16_t dmac[3]; /* big endian */
/* This value sets the match value for the Destination MAC address. */
uint16_t inner_vlan_tci; /* big endian */
/* valid when num tags is 2. */
uint16_t smac[3]; /* big endian */
/* This value sets the match value for the Source MAC address. */
uint8_t ip_dst_mask_len;
/* The bit length of destination IP address mask. */
uint8_t ip_src_mask_len;
/* The bit length of source IP address mask. */
uint32_t ip_dst[4]; /* big endian */
/* The value of destination IPv4/IPv6 address. */
uint32_t ip_src[4]; /* big endian */
/* The source IPv4/IPv6 address. */
uint16_t l4_src_port; /* big endian */
/* The value of source port. Applies to UDP and TCP traffic. */
uint16_t l4_src_port_mask; /* big endian */
/* The value of source port mask. Applies to UDP and TCP traffic. */
uint16_t l4_dst_port; /* big endian */
/* The value of destination port. Applies to UDP and TCP traffic. */
uint16_t l4_dst_port_mask; /* big endian */
/* The value of destination port mask. Applies to UDP and TCP traffic. */
uint32_t nat_ip_address[4]; /* big endian */
/* NAT IPv4/6 address based on address type flag. 0 values are ignored. */
uint16_t l2_rewrite_dmac[3]; /* big endian */
/* L2 header re-write Destination MAC address. */
uint16_t nat_port; /* big endian */
/*
* The NAT source/destination port based on direction flag. Applies to
* UDP and TCP traffic. 0 values are ignored.
*/
uint16_t l2_rewrite_smac[3]; /* big endian */
/* L2 header re-write Source MAC address. */
uint8_t ip_proto;
/* The value of ip protocol. */
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_flow_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t flow_handle;
/* Flow record index. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_flow_free */
/* Description: Flow is removed from table and resources are released. */
/* Input (24 bytes) */
struct hwrm_cfa_flow_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t flow_handle;
/* Flow record index. */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_cfa_flow_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t packet;
/* packet is 64 b */
uint64_t byte;
/* byte is 64 b */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_flow_info */
/* Description: Flow record content for specified flow is returned. */
/* Input (24 bytes) */
struct hwrm_cfa_flow_info_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t flow_handle;
/* Flow record index. */
/* Max flow handle */
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_MAX_MASK UINT32_C(0xfff)
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_MAX_SFT 0
/* CNP flow handle */
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_CNP_CNT UINT32_C(0x1000)
/* Reserved */
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_RESERVED_MASK UINT32_C(0x6000)
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_RESERVED_SFT 13
/* Direction rx = 1 */
#define HWRM_CFA_FLOW_INFO_INPUT_FLOW_HANDLE_DIR_RX UINT32_C(0x8000)
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (56 bytes) */
struct hwrm_cfa_flow_info_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t flags;
/* flags is 8 b */
uint8_t profile;
/* profile is 8 b */
uint16_t src_fid;
/* src_fid is 16 b */
uint16_t dst_fid;
/* dst_fid is 16 b */
uint16_t l2_ctxt_id;
/* l2_ctxt_id is 16 b */
uint64_t em_info;
/* em_info is 64 b */
uint64_t tcam_info;
/* tcam_info is 64 b */
uint64_t vfp_tcam_info;
/* vfp_tcam_info is 64 b */
uint16_t ar_id;
/* ar_id is 16 b */
uint16_t flow_handle;
/* flow_handle is 16 b */
uint32_t tunnel_handle;
/* tunnel_handle is 32 b */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_flow_flush */
/* Description: All flows are removed from table and resources are released. */
/* Input (24 bytes) */
struct hwrm_cfa_flow_flush_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_flow_flush_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_flow_stats */
/* Description: Flow is removed from table and resources are released. */
/* Input (40 bytes) */
struct hwrm_cfa_flow_stats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t num_flows;
/* Flow handle. */
uint16_t flow_handle_0;
/* Flow handle. */
uint16_t flow_handle_1;
/* Flow handle. */
uint16_t flow_handle_2;
/* Flow handle. */
uint16_t flow_handle_3;
/* Flow handle. */
uint16_t flow_handle_4;
/* Flow handle. */
uint16_t flow_handle_5;
/* Flow handle. */
uint16_t flow_handle_6;
/* Flow handle. */
uint16_t flow_handle_7;
/* Flow handle. */
uint16_t flow_handle_8;
/* Flow handle. */
uint16_t flow_handle_9;
/* Flow handle. */
uint16_t unused_0;
} __attribute__((packed));
/* Output (176 bytes) */
struct hwrm_cfa_flow_stats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t packet_0;
/* packet_0 is 64 b */
uint64_t packet_1;
/* packet_1 is 64 b */
uint64_t packet_2;
/* packet_2 is 64 b */
uint64_t packet_3;
/* packet_3 is 64 b */
uint64_t packet_4;
/* packet_4 is 64 b */
uint64_t packet_5;
/* packet_5 is 64 b */
uint64_t packet_6;
/* packet_6 is 64 b */
uint64_t packet_7;
/* packet_7 is 64 b */
uint64_t packet_8;
/* packet_8 is 64 b */
uint64_t packet_9;
/* packet_9 is 64 b */
uint64_t byte_0;
/* byte_0 is 64 b */
uint64_t byte_1;
/* byte_1 is 64 b */
uint64_t byte_2;
/* byte_2 is 64 b */
uint64_t byte_3;
/* byte_3 is 64 b */
uint64_t byte_4;
/* byte_4 is 64 b */
uint64_t byte_5;
/* byte_5 is 64 b */
uint64_t byte_6;
/* byte_6 is 64 b */
uint64_t byte_7;
/* byte_7 is 64 b */
uint64_t byte_8;
/* byte_8 is 64 b */
uint64_t byte_9;
/* byte_9 is 64 b */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vf_pair_alloc */
/* Description: VF pair is added to table and resources are allocated. */
/* Input (32 bytes) */
struct hwrm_cfa_vf_pair_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t vf_a_id;
/* Logical VF number (range: 0 -> MAX_VFS -1). */
uint16_t vf_b_id;
/* Logical VF number (range: 0 -> MAX_VFS -1). */
uint32_t unused_0;
char pair_name[32];
/* VF Pair name (32 byte string). */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vf_pair_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vf_pair_free */
/* Description: VF Pair is removed from table and resources are released. */
/* Input (24 bytes) */
struct hwrm_cfa_vf_pair_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
char pair_name[32];
/* VF Pair name (32 byte string). */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vf_pair_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vf_pair_info */
/* Description: VF pair information is returned. */
/* Input (32 bytes) */
struct hwrm_cfa_vf_pair_info_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/* If this flag is set, lookup by name else lookup by index. */
#define HWRM_CFA_VF_PAIR_INFO_INPUT_FLAGS_LOOKUP_TYPE UINT32_C(0x1)
uint16_t vf_pair_index;
/* vf pair table index. */
uint8_t unused_0;
uint8_t unused_1;
char vf_pair_name[32];
/* VF Pair name (32 byte string). */
} __attribute__((packed));
/* Output (64 bytes) */
struct hwrm_cfa_vf_pair_info_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t next_vf_pair_index;
/* vf pair table index. */
uint16_t vf_a_fid;
/* vf pair member a's vf_fid. */
uint16_t vf_a_index;
/* vf pair member a's Linux logical VF number. */
uint16_t vf_b_fid;
/* vf pair member b's vf_fid. */
uint16_t vf_b_index;
/* vf pair member a's Linux logical VF number. */
uint8_t pair_state;
/* vf pair state. */
/* Pair has been allocated */
#define HWRM_CFA_VF_PAIR_INFO_OUTPUT_PAIR_STATE_ALLOCATED UINT32_C(0x1)
/* Both pair members are active */
#define HWRM_CFA_VF_PAIR_INFO_OUTPUT_PAIR_STATE_ACTIVE UINT32_C(0x2)
uint8_t unused_0;
uint32_t unused_1;
char pair_name[32];
/* VF Pair name (32 byte string). */
uint32_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t unused_5;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vfr_alloc */
/* Description: VF-R is added to table and resources are allocated. */
/* Input (32 bytes) */
struct hwrm_cfa_vfr_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t vf_id;
/* Logical VF number (range: 0 -> MAX_VFS -1). */
uint16_t reserved;
/* This field is reserved for the future use. It shall be set to 0. */
uint32_t unused_0;
char vfr_name[32];
/* VF Representor name (32 byte string). */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vfr_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t rx_cfa_code;
/* Rx CFA code. */
uint16_t tx_cfa_action;
/* Tx CFA action. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_cfa_vfr_free */
/* Description: VF-R is removed from table and resources are released. */
/* Input (24 bytes) */
struct hwrm_cfa_vfr_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
char vfr_name[32];
/* VF Representor name (32 byte string). */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_cfa_vfr_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_tunnel_dst_port_query */
/*
* Description: This function is called by a driver to query tunnel type
* specific destination port configuration.
*/
/* Input (24 bytes) */
struct hwrm_tunnel_dst_port_query_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_TUNNEL_DST_PORT_QUERY_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_TUNNEL_DST_PORT_QUERY_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_tunnel_dst_port_query_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t tunnel_dst_port_id;
/*
* This field represents the identifier of L4 destination port used for
* the given tunnel type. This field is valid for specific tunnel types
* that use layer 4 (e.g. UDP) transports for tunneling.
*/
uint16_t tunnel_dst_port_val; /* big endian */
/*
* This field represents the value of L4 destination port identified by
* tunnel_dst_port_id. This field is valid for specific tunnel types
* that use layer 4 (e.g. UDP) transports for tunneling. This field is
* in network byte order. A value of 0 means that the destination port
* is not configured.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_tunnel_dst_port_alloc */
/*
* Description: This function is called by a driver to allocate l4 destination
* port for a specific tunnel type. The destination port value is provided in
* the input. If the HWRM supports only one global destination port for a tunnel
* type, then the HWRM shall keep track of its usage as described below. # The
* first caller that allocates a destination port shall always succeed and the
* HWRM shall save the destination port configuration for that tunnel type and
* increment the usage count to 1. # Subsequent callers allocating the same
* destination port for that tunnel type shall succeed and the HWRM shall
* increment the usage count for that port for each subsequent caller that
* succeeds. # Any subsequent caller trying to allocate a different destination
* port for that tunnel type shall fail until the usage count for the original
* destination port goes to zero. # A caller that frees a port will cause the
* usage count for that port to decrement.
*/
/* Input (24 bytes) */
struct hwrm_tunnel_dst_port_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_TUNNEL_DST_PORT_ALLOC_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_TUNNEL_DST_PORT_ALLOC_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
uint8_t unused_0;
uint16_t tunnel_dst_port_val; /* big endian */
/*
* This field represents the value of L4 destination port used for the
* given tunnel type. This field is valid for specific tunnel types that
* use layer 4 (e.g. UDP) transports for tunneling. This field is in
* network byte order. A value of 0 shall fail the command.
*/
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_tunnel_dst_port_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t tunnel_dst_port_id;
/*
* Identifier of a tunnel L4 destination port value. Only applies to
* tunnel types that has l4 destination port parameters.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_tunnel_dst_port_free */
/*
* Description: This function is called by a driver to free l4 destination port
* for a specific tunnel type.
*/
/* Input (24 bytes) */
struct hwrm_tunnel_dst_port_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t tunnel_type;
/* Tunnel Type. */
/* Virtual eXtensible Local Area Network (VXLAN) */
#define HWRM_TUNNEL_DST_PORT_FREE_INPUT_TUNNEL_TYPE_VXLAN UINT32_C(0x1)
/* Generic Network Virtualization Encapsulation (Geneve) */
#define HWRM_TUNNEL_DST_PORT_FREE_INPUT_TUNNEL_TYPE_GENEVE UINT32_C(0x5)
uint8_t unused_0;
uint16_t tunnel_dst_port_id;
/*
* Identifier of a tunnel L4 destination port value. Only applies to
* tunnel types that has l4 destination port parameters.
*/
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_tunnel_dst_port_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_stat_ctx_alloc */
/*
* Description: This command allocates and does basic preparation for a stat
* context.
*/
/* Input (32 bytes) */
struct hwrm_stat_ctx_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t stats_dma_addr;
/* This is the address for statistic block. */
uint32_t update_period_ms;
/*
* The statistic block update period in ms. e.g. 250ms, 500ms, 750ms,
* 1000ms. If update_period_ms is 0, then the stats update shall be
* never done and the DMA address shall not be used. In this case, the
* stat block can only be read by hwrm_stat_ctx_query command.
*/
uint8_t stat_ctx_flags;
/*
* This field is used to specify statistics context specific
* configuration flags.
*/
/*
* When this bit is set to '1', the statistics context shall be
* allocated for RoCE traffic only. In this case, traffic other than
* offloaded RoCE traffic shall not be included in this statistic
* context. When this bit is set to '0', the statistics context shall be
* used for the network traffic other than offloaded RoCE traffic.
*/
#define HWRM_STAT_CTX_ALLOC_INPUT_STAT_CTX_FLAGS_ROCE UINT32_C(0x1)
uint8_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_stat_ctx_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t stat_ctx_id;
/* This is the statistics context ID value. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_stat_ctx_free */
/* Description: This command is used to free a stat context. */
/* Input (24 bytes) */
struct hwrm_stat_ctx_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t stat_ctx_id;
/* ID of the statistics context that is being queried. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_stat_ctx_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t stat_ctx_id;
/* This is the statistics context ID value. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_stat_ctx_query */
/* Description: This command returns statistics of a context. */
/* Input (24 bytes) */
struct hwrm_stat_ctx_query_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t stat_ctx_id;
/* ID of the statistics context that is being queried. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (176 bytes) */
struct hwrm_stat_ctx_query_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t tx_ucast_pkts;
/* Number of transmitted unicast packets */
uint64_t tx_mcast_pkts;
/* Number of transmitted multicast packets */
uint64_t tx_bcast_pkts;
/* Number of transmitted broadcast packets */
uint64_t tx_err_pkts;
/* Number of transmitted packets with error */
uint64_t tx_drop_pkts;
/* Number of dropped packets on transmit path */
uint64_t tx_ucast_bytes;
/* Number of transmitted bytes for unicast traffic */
uint64_t tx_mcast_bytes;
/* Number of transmitted bytes for multicast traffic */
uint64_t tx_bcast_bytes;
/* Number of transmitted bytes for broadcast traffic */
uint64_t rx_ucast_pkts;
/* Number of received unicast packets */
uint64_t rx_mcast_pkts;
/* Number of received multicast packets */
uint64_t rx_bcast_pkts;
/* Number of received broadcast packets */
uint64_t rx_err_pkts;
/* Number of received packets with error */
uint64_t rx_drop_pkts;
/* Number of dropped packets on received path */
uint64_t rx_ucast_bytes;
/* Number of received bytes for unicast traffic */
uint64_t rx_mcast_bytes;
/* Number of received bytes for multicast traffic */
uint64_t rx_bcast_bytes;
/* Number of received bytes for broadcast traffic */
uint64_t rx_agg_pkts;
/* Number of aggregated unicast packets */
uint64_t rx_agg_bytes;
/* Number of aggregated unicast bytes */
uint64_t rx_agg_events;
/* Number of aggregation events */
uint64_t rx_agg_aborts;
/* Number of aborted aggregations */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_stat_ctx_clr_stats */
/* Description: This command clears statistics of a context. */
/* Input (24 bytes) */
struct hwrm_stat_ctx_clr_stats_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t stat_ctx_id;
/* ID of the statistics context that is being queried. */
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_stat_ctx_clr_stats_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fw_reset */
/*
* Description: This function is called by a driver to self reset the firmware
* running on the processor indicated by the embedded_proc_type.
*/
/* Input (24 bytes) */
struct hwrm_fw_reset_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t embedded_proc_type;
/* Type of embedded processor. */
/* Boot Processor */
#define HWRM_FW_RESET_INPUT_EMBEDDED_PROC_TYPE_BOOT UINT32_C(0x0)
/* Management Processor */
#define HWRM_FW_RESET_INPUT_EMBEDDED_PROC_TYPE_MGMT UINT32_C(0x1)
/* Network control processor */
#define HWRM_FW_RESET_INPUT_EMBEDDED_PROC_TYPE_NETCTRL UINT32_C(0x2)
/* RoCE control processor */
#define HWRM_FW_RESET_INPUT_EMBEDDED_PROC_TYPE_ROCE UINT32_C(0x3)
/*
* Host (in multi-host environment): This is only valid if
* requester is IPC
*/
#define HWRM_FW_RESET_INPUT_EMBEDDED_PROC_TYPE_HOST UINT32_C(0x4)
uint8_t selfrst_status;
/* Type of self reset. */
/* No Self Reset */
#define HWRM_FW_RESET_INPUT_SELFRST_STATUS_SELFRSTNONE UINT32_C(0x0)
/* Self Reset as soon as possible to do so safely */
#define HWRM_FW_RESET_INPUT_SELFRST_STATUS_SELFRSTASAP UINT32_C(0x1)
/* Self Reset on PCIe Reset */
#define HWRM_FW_RESET_INPUT_SELFRST_STATUS_SELFRSTPCIERST UINT32_C(0x2)
uint8_t host_idx;
/*
* Indicate which host is being reset. 0 means first host. Only valid
* when embedded_proc_type is host in multihost environment
*/
uint8_t unused_0[5];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_reset_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t selfrst_status;
/* Type of self reset. */
/* No Self Reset */
#define HWRM_FW_RESET_OUTPUT_SELFRST_STATUS_SELFRSTNONE UINT32_C(0x0)
/* Self Reset as soon as possible to do so safely */
#define HWRM_FW_RESET_OUTPUT_SELFRST_STATUS_SELFRSTASAP UINT32_C(0x1)
/* Self Reset on PCIe Reset */
#define HWRM_FW_RESET_OUTPUT_SELFRST_STATUS_SELFRSTPCIERST UINT32_C(0x2)
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fw_qstatus */
/*
* Description: This function is called by a driver to query the status of the
* firmware running on the processor indicated by the embedded_proc_type.
*/
/* Input (24 bytes) */
struct hwrm_fw_qstatus_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t embedded_proc_type;
/* Type of embedded processor. */
/* Boot Processor */
#define HWRM_FW_QSTATUS_INPUT_EMBEDDED_PROC_TYPE_BOOT UINT32_C(0x0)
/* Management Processor */
#define HWRM_FW_QSTATUS_INPUT_EMBEDDED_PROC_TYPE_MGMT UINT32_C(0x1)
/* Network control processor */
#define HWRM_FW_QSTATUS_INPUT_EMBEDDED_PROC_TYPE_NETCTRL UINT32_C(0x2)
/* RoCE control processor */
#define HWRM_FW_QSTATUS_INPUT_EMBEDDED_PROC_TYPE_ROCE UINT32_C(0x3)
/*
* Host (in multi-host environment): This is only valid if
* requester is IPC
*/
#define HWRM_FW_QSTATUS_INPUT_EMBEDDED_PROC_TYPE_HOST UINT32_C(0x4)
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_qstatus_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t selfrst_status;
/* Type of self reset. */
/* No Self Reset */
#define HWRM_FW_QSTATUS_OUTPUT_SELFRST_STATUS_SELFRSTNONE UINT32_C(0x0)
/* Self Reset as soon as possible to do so safely */
#define HWRM_FW_QSTATUS_OUTPUT_SELFRST_STATUS_SELFRSTASAP UINT32_C(0x1)
/* Self Reset on PCIe Reset */
#define HWRM_FW_QSTATUS_OUTPUT_SELFRST_STATUS_SELFRSTPCIERST UINT32_C(0x2)
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fw_set_time */
/*
* Description: Inform the HWRM firmware of the current date/time. Ideally, the
* date/time will be current time in GMT/UTC and the zone value will be 0
* (indicating UTC). If the time zone is not known, the zone value shall be
* 0xffff. Other values for zone are discouraged, but if specified, they
* indicate the number of minutes east of UTC, while zones west of UTC are
* represented with a 2's complement negative value (e.g. PST would be -480
* while PDT would be -420).
*/
/* Input (32 bytes) */
struct hwrm_fw_set_time_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t year;
/* Current year */
/* Date/time is not known */
#define HWRM_FW_SET_TIME_INPUT_YEAR_UNKNOWN UINT32_C(0x0)
uint8_t month;
/* Current month of year (1-12) */
uint8_t day;
/* Current day of month (1-31) */
uint8_t hour;
/* Current hour (0-23) */
uint8_t minute;
/* Current minute (0-59) */
uint8_t second;
/* Current second (0-59) */
uint8_t unused_0;
uint16_t millisecond;
/* Current millisecond (0-999) */
uint16_t zone;
/* Minutes east of UTC, 0xffff if TZ is not known */
/* Time zone is Coordinated Universal Time (UTC) */
#define HWRM_FW_SET_TIME_INPUT_ZONE_UTC UINT32_C(0x0)
/* Time zone is not known */
#define HWRM_FW_SET_TIME_INPUT_ZONE_UNKNOWN UINT32_C(0xffff)
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_set_time_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fw_get_time */
/* Description: Query the HWRM firmware's notion of the current date/time. */
/* Input (16 bytes) */
struct hwrm_fw_get_time_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_fw_get_time_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t year;
/* Current year */
/* Date/time is not known */
#define HWRM_FW_GET_TIME_OUTPUT_YEAR_UNKNOWN UINT32_C(0x0)
uint8_t month;
/* Current month of year (1-12) */
uint8_t day;
/* Current day of month (1-31) */
uint8_t hour;
/* Current hour (0-23) */
uint8_t minute;
/* Current minute (0-59) */
uint8_t second;
/* Current second (0-59) */
uint8_t unused_0;
uint16_t millisecond;
/* Current millisecond (0-999) */
uint16_t zone;
/* Minutes east of UTC, 0xffff if TZ is not known */
/* Time zone is Coordinated Universal Time (UTC) */
#define HWRM_FW_GET_TIME_OUTPUT_ZONE_UTC UINT32_C(0x0)
/* Time zone is not known */
#define HWRM_FW_GET_TIME_OUTPUT_ZONE_UNKNOWN UINT32_C(0xffff)
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fw_set_structured_data */
/*
* Description: There can be a variable number of Structure Data Headers (SDH)
* between offset 0x0 and the 'valid' field to handle customizable return
* values. Each Structure Data Header will include one defined structure. The
* number of returned structures can be 0, in which case the 'valid' field
* starts at offset 0x8. The 'valid' field offset is adjusted based on the
* Structure Data Header length and the length of the structured data it
* contains.
*/
/* Input (32 bytes) */
struct hwrm_fw_set_structured_data_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t src_data_addr;
/* This is the host address where structured data will be copied from */
uint16_t data_len;
/* size of data in bytes */
uint8_t hdr_cnt;
/*
* a count of the number of Structured Data Headers in the data pointed
* by src_data_addr.
*/
uint8_t unused_0[5];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_set_structured_data_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_fw_set_structured_data_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_FW_SET_STRUCTURED_DATA_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* count_of_headers is incorrect */
#define HWRM_FW_SET_STRUCTURED_DATA_CMD_ERR_CODE_BAD_HDR_CNT UINT32_C(0x1)
/* data improperly formatted */
#define HWRM_FW_SET_STRUCTURED_DATA_CMD_ERR_CODE_BAD_FMT UINT32_C(0x2)
/* unknown structure ID(s) */
#define HWRM_FW_SET_STRUCTURED_DATA_CMD_ERR_CODE_BAD_ID UINT32_C(0x3)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_fw_get_structured_data */
/* Input (32 bytes) */
struct hwrm_fw_get_structured_data_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t dest_data_addr;
/* This is the host address where structured data will be copied to */
uint16_t data_len;
/* size of data in bytes */
uint16_t structure_id;
/*
* Structure_id is the id of the structure data requesting and count is
* a requested number of instances of this data requested. The actual
* number will be returned in count_of_headers
*/
uint16_t subtype;
/*
* Subtype is an optional field used to specify additional information
* of the data being retrieved. For example, if data can be categorized
* as "live" vs "saved" then this field can be used to provide an
* indication of "saved" vs "live" data. Not all structured data
* supports subtypes and if they are supported then the structured data
* will specify the valid values. If structured data is requested that
* supports subtypes but no subtype is given then it is implementation
* specific what will be returned. Some structure data can support a
* subtype of "All" which would cause a list of structures to be
* returned for all supported subtypes. "All" is only used on the
* hwrm_get_structured_data command.
*/
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_ALL UINT32_C(0xffff)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NEAR_BRIDGE_ADMIN UINT32_C(0x100)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NEAR_BRIDGE_PEER UINT32_C(0x101)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NEAR_BRIDGE_OPERATIONAL UINT32_C(0x102)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NON_TPMR_ADMIN UINT32_C(0x200)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NON_TPMR_PEER UINT32_C(0x201)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_NON_TPMR_OPERATIONAL UINT32_C(0x202)
#define HWRM_FW_GET_STRUCTURED_DATA_INPUT_SUBTYPE_HOST_OPERATIONAL UINT32_C(0x300)
uint8_t count;
/* Number of elements. This allows support of arrayed data */
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_get_structured_data_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t hdr_cnt;
/*
* a count of the number of Structured Data Headers in the data pointed
* by dest_data_addr.
*/
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_fw_get_structured_data_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_FW_GET_STRUCTURED_DATA_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* unknown structure ID(s) */
#define HWRM_FW_GET_STRUCTURED_DATA_CMD_ERR_CODE_BAD_ID UINT32_C(0x3)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_fw_ipc_mailbox */
/* Input (32 bytes) */
struct hwrm_fw_ipc_mailbox_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
uint8_t unused_0;
/* unused is 8 b */
uint8_t event_id;
/* asynchronous event to hosts. */
uint8_t port_id;
/* PORT ID */
uint32_t event_data1;
/* event data1 of asynchronous event */
uint32_t event_data2;
/* event data2 of asynchronous event */
uint32_t unused_1;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fw_ipc_mailbox_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_fw_ipc_mailbox_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_FW_IPC_MAILBOX_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* invalid event */
#define HWRM_FW_IPC_MAILBOX_CMD_ERR_CODE_BAD_ID UINT32_C(0x3)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_exec_fwd_resp */
/*
* Description: This command is used to send an encapsulated request to the
* HWRM. This command instructs the HWRM to execute the request and forward the
* response of the encapsulated request to the location specified in the
* original request that is encapsulated. The target id of this command shall be
* set to 0xFFFF (HWRM). The response location in this command shall be used to
* acknowledge the receipt of the encapsulated request and forwarding of the
* response.
*/
/* Input (128 bytes) */
struct hwrm_exec_fwd_resp_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t encap_request[26];
/*
* This is an encapsulated request. This request should be executed by
* the HWRM and the response should be provided in the response buffer
* inside the encapsulated request.
*/
uint16_t encap_resp_target_id;
/*
* This value indicates the target id of the response to the
* encapsulated request. 0x0 - 0xFFF8 - Used for function ids 0xFFF8 -
* 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_exec_fwd_resp_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_reject_fwd_resp */
/*
* Description: This command is used to send an encapsulated request to the
* HWRM. This command instructs the HWRM to reject the request and forward the
* error response of the encapsulated request to the location specified in the
* original request that is encapsulated. The target id of this command shall be
* set to 0xFFFF (HWRM). The response location in this command shall be used to
* acknowledge the receipt of the encapsulated request and forwarding of the
* response.
*/
/* Input (128 bytes) */
struct hwrm_reject_fwd_resp_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t encap_request[26];
/*
* This is an encapsulated request. This request should be rejected by
* the HWRM and the error response should be provided in the response
* buffer inside the encapsulated request.
*/
uint16_t encap_resp_target_id;
/*
* This value indicates the target id of the response to the
* encapsulated request. 0x0 - 0xFFF8 - Used for function ids 0xFFF8 -
* 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_reject_fwd_resp_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fwd_resp */
/*
* Description: This command is used to send an encapsulated response to the
* HWRM. The HWRM shall forward this response based on the target id. The
* response address provided in this command shall be used to acknowledge the
* receipt of the encapsulated response. The encapsulated response address
* provided in this command shall be used to provide the encapsulated response.
*/
/* Input (40 bytes) */
struct hwrm_fwd_resp_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t encap_resp_target_id;
/*
* This value indicates the target id of the encapsulated response. 0x0
* - 0xFFF8 - Used for function ids 0xFFF8 - 0xFFFE - Reserved for
* internal processors 0xFFFF - HWRM
*/
uint16_t encap_resp_cmpl_ring;
/*
* This value indicates the completion ring the encapsulated response
* will be optionally completed on. If the value is -1, then no CR
* completion shall be generated for the encapsulated response. Any
* other value must be a valid CR ring_id value. If a valid
* encap_resp_cmpl_ring is provided, then a CR completion shall be
* generated for the encapsulated response.
*/
uint16_t encap_resp_len;
/* This field indicates the length of encapsulated response. */
uint8_t unused_0;
uint8_t unused_1;
uint64_t encap_resp_addr;
/*
* This is the host address where the encapsulated response will be
* written. This area must be 16B aligned and must be cleared to zero
* before the original request is made.
*/
uint32_t encap_resp[24];
/* This is an encapsulated response. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fwd_resp_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_fwd_async_event_cmpl */
/*
* Description: This command is used to send an encapsulated asynchronous event
* completion to the HWRM. The HWRM shall forward this asynchronous event
* completion to target(s) specified in the command. The HWRM shall complete
* this command only after forwarding asynchronous event completion to specified
* targets.
*/
/* Input (32 bytes) */
struct hwrm_fwd_async_event_cmpl_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t encap_async_event_target_id;
/*
* This value indicates the target id of the encapsulated asynchronous
* event. 0x0 - 0xFFF8 - Used for function ids 0xFFF8 - 0xFFFE -
* Reserved for internal processors 0xFFFF - Broadcast to all children
* VFs (only applicable when a PF is the requester)
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2[3];
uint8_t unused_3;
uint32_t encap_async_event_cmpl[4];
/* This is an encapsulated asynchronous event completion. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_fwd_async_event_cmpl_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_temp_monitor_query */
/*
* Description: A temperature monitor is used to query the device temperature.
*/
/* Input (16 bytes) */
struct hwrm_temp_monitor_query_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_temp_monitor_query_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t temp;
/* The HWRM shall provide the current temperature of device in Celsius. */
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_wol_filter_alloc */
/*
* Description: A Wake-On-LAN (WoL) filter is a filter resource that is used to
* identify a WoL packet. # Among all function drivers, the HWRM shall only
* allow PF drivers to allocate WoL filters. # The HWRM shall not allow VF
* drivers to allocate any WoL filters. # When partitioning is enabled and WoL
* is supported, the HWRM shall support at least one WoL filter per partition. #
* The HWRM shall retain a WoL filter setting until the filter is freed. # If
* the HWRM client is a function driver, then the HWRM shall not allow the HWRM
* client to set up WoL filters on the port that the function is not associated
* with. # If the HWRM client is one of the trusted embedded services (e.g.
* management service), the the HWRM shall allow the HWRM client to set up WoL
* filters on any port of the device.
*/
/* Input (64 bytes) */
struct hwrm_wol_filter_alloc_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
uint32_t enables;
/* This bit must be '1' for the mac_address field to be configured. */
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_MAC_ADDRESS UINT32_C(0x1)
/* This bit must be '1' for the pattern_offset field to be configured. */
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_PATTERN_OFFSET UINT32_C(0x2)
/* This bit must be '1' for the pattern_buf_size field to be configured. */
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_PATTERN_BUF_SIZE UINT32_C(0x4)
/* This bit must be '1' for the pattern_buf_addr field to be configured. */
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_PATTERN_BUF_ADDR UINT32_C(0x8)
/*
* This bit must be '1' for the pattern_mask_addr field to be
* configured.
*/
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_PATTERN_MASK_ADDR UINT32_C(0x10)
/*
* This bit must be '1' for the pattern_mask_size field to be
* configured.
*/
#define HWRM_WOL_FILTER_ALLOC_INPUT_ENABLES_PATTERN_MASK_SIZE UINT32_C(0x20)
uint16_t port_id;
/* Port ID of port on which WoL filter is configured. */
uint8_t wol_type;
/* This value represents a Wake-on-LAN type. */
/* Magic Paket */
#define HWRM_WOL_FILTER_ALLOC_INPUT_WOL_TYPE_MAGICPKT UINT32_C(0x0)
/* Bitmap */
#define HWRM_WOL_FILTER_ALLOC_INPUT_WOL_TYPE_BMP UINT32_C(0x1)
/* Invalid */
#define HWRM_WOL_FILTER_ALLOC_INPUT_WOL_TYPE_INVALID UINT32_C(0xff)
uint8_t unused_0;
uint32_t unused_1;
uint8_t mac_address[6];
/*
* # If this field is enabled and magic packet WoL filter type is
* specified in this command, the value set in this field shall be used
* in setting the magic packet based WoL filter. # If this field is not
* enabled and magic packet WoL filter type is specified and port id is
* specified to 0xFF in this command, then the HWRM shall use default
* MAC address configured on the function associated with the HWRM
* client. # If this field is not enabled and magic packet WoL filter
* type is specified and port id is not specified to 0xFF in this
* command, then the HWRM shall use default MAC address configured on
* the port.
*/
uint16_t pattern_offset;
/*
* The offset from the beginning of MAC header where pattern should be
* matched. Applies to bitmap WoL.
*/
uint16_t pattern_buf_size;
/* The size of the pattern that is being matched. Applies to bitmap WoL. */
uint16_t pattern_mask_size;
/* The size of the pattern mask. Applies to bitmap WoL. */
uint32_t unused_2;
uint64_t pattern_buf_addr;
/* Physical address of the pattern buffer. Applies to bitmap WoL. */
uint64_t pattern_mask_addr;
/* Physical address of the pattern mask. Applies to bitmap WoL. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_wol_filter_alloc_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t wol_filter_id;
/* This value identifies a Wake-on-LAN (WoL) filter. */
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_wol_filter_free */
/*
* Description: Free a WoL filter. # Among all function drivers, the HWRM shall
* only allow PF drivers to free WoL filters. # The HWRM shall not allow VF
* drivers to free any WoL filters. # The HWRM shall not allow a function driver
* to free an Out-Of-Box WoL filter. # The HWRM shall not allow a function
* driver to free a WoL filter on a port that the corresponding function is not
* associated with. # The HWRM shall not allow a function driver to free a WoL
* filter on a function that the function driver is not associated with.
*/
/* Input (32 bytes) */
struct hwrm_wol_filter_free_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t flags;
/*
* # When this bit is set to '1', then all active WoL filters on the
* port are requested to be freed. # If the a function driver sets this
* flag to '1', then the HWRM shall free all active WoL filters that are
* not set by other function drivers on that port.
*/
#define HWRM_WOL_FILTER_FREE_INPUT_FLAGS_FREE_ALL_WOL_FILTERS UINT32_C(0x1)
uint32_t enables;
/* This bit must be '1' for the wol_filter_id field to be configured. */
#define HWRM_WOL_FILTER_FREE_INPUT_ENABLES_WOL_FILTER_ID UINT32_C(0x1)
uint16_t port_id;
/* Port ID of the port on which WoL filter(s) is (are) being freed. */
uint8_t wol_filter_id;
/* The HWRM shall ignore this field if free_all_wol_filters flag is set. */
uint8_t unused_0[5];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_wol_filter_free_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_wol_filter_qcfg */
/*
* Description: Query WoL filter configuration. # Among all function drivers,
* the HWRM shall only allow PF drivers to query WoL filters. # The HWRM shall
* not allow VF drivers to query any WoL filters. # The HWRM shall return WoL
* filters that are active on the associated port for which this query is being
* performed. # If the HWRM client is a function driver, then the HWRM shall not
* allow the HWRM client to query WoL filters that are set up by other function
* drivers. # If the HWRM client is a function driver, then the HWRM shall not
* allow the HWRM client to query WoL filters on the port that the function is
* not associated with. # If the HWRM client is one of the trusted embedded
* service (e.g. management service), the the HWRM shall allow the HWRM client
* to query WoL filters on any port of the device.
*/
/* Input (56 bytes) */
struct hwrm_wol_filter_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port on which WoL filter that is being queried. */
uint16_t handle;
/*
* This is an opaque handle used to access filters. # The HWRM client
* shall set this field to 0x0000 to begin the query. # After the first
* query, the HWRM client shall retrieve next filters (if they exist)
* using the HWRM provided handle in the response.
*/
uint32_t unused_0;
uint64_t pattern_buf_addr;
/*
* Physical address of the pattern buffer. Applies to bitmap WoL filter
* only. # Value of 0 indicates an invalid buffer address. If this field
* is set to 0, then HWRM shall ignore pattern_buf_size. # If the HWRM
* client provides an invalid buffer address for the pattern, then the
* HWRM is not required to provide pattern when the response contains a
* bitmap WoL filter.
*/
uint16_t pattern_buf_size;
/* The size of the pattern buffer. Applies to bitmap WoL filter only. */
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3[3];
uint8_t unused_4;
uint64_t pattern_mask_addr;
/*
* Physical address of the pattern mask. Applies to bitmap WoL filter
* only. # Value of 0 indicates an invalid pattern mask address. If this
* field is set to 0, then HWRM shall ignore pattern_mask_size. # If the
* HWRM client provides an invalid mask address for the pattern, then
* the HWRM is not required to provide mask when the response contains a
* bitmap WoL filter.
*/
uint16_t pattern_mask_size;
/*
* The size of the buffer for pattern mask. Applies to bitmap WoL filter
* only.
*/
uint16_t unused_5[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_wol_filter_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t next_handle;
/*
* This is the next handle that is used to access filters. # If this
* field is set to 0x0000, then no WoL filters are currently configured
* on this port and all other fields in the output shall be ignored by
* the HWRM client. # If this field is set to neither 0x0000 nor 0xFFFF,
* then the wol_filter_id is valid and the parameters provided in the
* response are based on the wol_type. # If this field is set to 0xFFFF,
* then there are no remaining configured WoL filters to be queried for
* the queried function after this response, wol_filter_id is valid and
* the parameters provided in the response are based on the wol_type.
*/
uint8_t wol_filter_id;
/* This value identifies the filter returned in this response. */
uint8_t wol_type;
/*
* This value identifies the type of WoL filter returned in this
* response.
*/
/* Magic Paket */
#define HWRM_WOL_FILTER_QCFG_OUTPUT_WOL_TYPE_MAGICPKT UINT32_C(0x0)
/* Bitmap */
#define HWRM_WOL_FILTER_QCFG_OUTPUT_WOL_TYPE_BMP UINT32_C(0x1)
/* Invalid */
#define HWRM_WOL_FILTER_QCFG_OUTPUT_WOL_TYPE_INVALID UINT32_C(0xff)
uint32_t unused_0;
uint8_t mac_address[6];
/*
* The MAC address value used by the WoL filter. Applies to magic packet
* based WoL.
*/
uint16_t pattern_offset;
/*
* The offset from the beginning of MAC header where pattern should be
* matched. Applies to bitmap WoL.
*/
uint16_t pattern_size;
/*
* The actual size of the pattern that is being returned. Applies to
* bitmap WoL.
*/
uint16_t pattern_mask_size;
/*
* The actual size of the pattern mask that is being returned. Applies
* to bitmap WoL.
*/
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_wol_reason_qcfg */
/* Description: Query WoL reason for the last system wake up. */
/* Input (40 bytes) */
struct hwrm_wol_reason_qcfg_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t port_id;
/* Port ID of port for which this query is for. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2[3];
uint8_t unused_3;
uint64_t wol_pkt_buf_addr;
/* Physical address of the packet buffer for querying WoL packet. */
uint16_t wol_pkt_buf_size;
/* The size of the buffer for the WoL packet. */
uint16_t unused_4[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_wol_reason_qcfg_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t wol_filter_id;
/*
* This value identifies the filter that matched the last WoL packet.
* This id is only valid with valid WoL reason.
*/
uint8_t wol_reason;
/*
* This value identifies the type of WoL reason returned in this
* response. When the wol_type is set to invalid, then there is no WoL
* event that happened during last system wake-up.
*/
/* Magic Paket */
#define HWRM_WOL_REASON_QCFG_OUTPUT_WOL_REASON_MAGICPKT UINT32_C(0x0)
/* Bitmap */
#define HWRM_WOL_REASON_QCFG_OUTPUT_WOL_REASON_BMP UINT32_C(0x1)
/* Invalid */
#define HWRM_WOL_REASON_QCFG_OUTPUT_WOL_REASON_INVALID UINT32_C(0xff)
uint8_t wol_pkt_len;
/* The value identifies the length of the WoL packet in bytes. */
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_dbg_dump */
/*
* Description: This command is used by to initiate the dump of debug
* information to a driver specified address.
*/
/* Input (40 bytes) */
struct hwrm_dbg_dump_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t handle;
/*
* Handle used to dump debug data. handle = 0 indicates the beginning of
* the dump. handle != 0 indicates the request to dump the next part.
*/
uint32_t unused_0;
uint64_t host_dbg_dump_addr;
/*
* Address of the host buffer where the debug data is requested to be
* dumped.
*/
uint64_t host_dbg_dump_addr_len;
/* Length of host buffer used for transferring debug data. */
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_dbg_dump_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t nexthandle;
/*
* Handle used to indicate availability of additional debug data.
* nexthandle = 0 indicates that there is no more debug data available.
* nexthandle != 0 indicates the handle value that should be used to
* request the next part of debug data.
*/
uint32_t dbg_data_len;
/* The number of bytes of debug data written to debug dump buffer. */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_raw_write_blk */
/*
* Note: Write an unmanaged block of data at any physical offset within the
* NVRAM. Used for initial provisioning/manufacturing purposes only. Implemented
* in the ChiMP boot-strap firmware (fwutil.bin) only.
*/
/* Input (32 bytes) */
struct hwrm_nvm_raw_write_blk_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_src_addr;
/*
* 64-bit Host Source Address. This is the loation of the source data to
* be written.
*/
uint32_t dest_addr;
/*
* 32-bit Destination Address. This is the NVRAM byte-offset where the
* source data will be written to.
*/
uint32_t len;
/* Length of data to be written, in bytes. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_raw_write_blk_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_read */
/*
* Note: Read the contents of an NVRAM item as referenced (indexed) by an
* existing directory entry.
*/
/* Input (40 bytes) */
struct hwrm_nvm_read_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_dest_addr;
/*
* 64-bit Host Destination Address. This is the host address where the
* data will be written to.
*/
uint16_t dir_idx;
/* The 0-based index of the directory entry. */
uint8_t unused_0;
uint8_t unused_1;
uint32_t offset;
/* The NVRAM byte-offset to read from. */
uint32_t len;
/* The length of the data to be read, in bytes. */
uint32_t unused_2;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_read_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_raw_dump */
/* Note: Dump a raw block of data from NVRAM. */
/* Input (32 bytes) */
struct hwrm_nvm_raw_dump_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_dest_addr;
/*
* 64-bit Host Destination Address. This is the host address where the
* data will be written to.
*/
uint32_t offset;
/* 32-bit NVRAM byte-offset to read from. */
uint32_t len;
/* Total length of NVRAM contents to be read, in bytes. */
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_raw_dump_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_get_dir_entries */
/*
* Description: Read the NVRAM directory. Each directory entry is at least 24
* bytes in length and contains the: - 16-bit directory entry type
* (BNX_DIR_TYPE_* value) - 16-bit ordinal (instance of this directory entry
* type) - 16-bit extension flags (identifies inactive entries and entries for
* firmware update) - 16-bit attribute flags (identifies entries with a
* purposely invalid chksum value) - 32-bit byte-offset into NVRAM where this
* item data is located - 32-bit length of allocated NVRAM for item, in bytes
* (multiple of block size) - 32-bit length of data (excluding padding), in
* bytes (may be 0) - 32-bit data checksum (CRC-32) See the
* bnxnvm_directory_entry_t definition in the file bnxnvm_defs.h.
*/
/* Input (24 bytes) */
struct hwrm_nvm_get_dir_entries_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_dest_addr;
/*
* 64-bit Host Destination Address. This is the host address where the
* directory will be written.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_get_dir_entries_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_get_dir_info */
/* Note: Get Directory Header info. */
/* Input (16 bytes) */
struct hwrm_nvm_get_dir_info_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_nvm_get_dir_info_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t entries;
/* Number of directory entries in the directory. */
uint32_t entry_length;
/* Size of each directory entry, in bytes. */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_write */
/*
* Note: Write to the allocated NVRAM of an item referenced by an existing
* directory entry.
*/
/* Input (48 bytes) */
struct hwrm_nvm_write_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_src_addr;
/* 64-bit Host Source Address. This is where the source data is. */
uint16_t dir_type;
/*
* The Directory Entry Type (valid values are defined in the
* bnxnvm_directory_type enum defined in the file bnxnvm_defs.h).
*/
uint16_t dir_ordinal;
/*
* Directory ordinal. The 0-based instance of the combined Directory
* Entry Type and Extension.
*/
uint16_t dir_ext;
/*
* The Directory Entry Extension flags (see BNX_DIR_EXT_* in the file
* bnxnvm_defs.h).
*/
uint16_t dir_attr;
/*
* Directory Entry Attribute flags (see BNX_DIR_ATTR_* in the file
* bnxnvm_defs.h).
*/
uint32_t dir_data_length;
/*
* Length of data to write, in bytes. May be less than or equal to the
* allocated size for the directory entry. The data length stored in the
* directory entry will be updated to reflect this value once the write
* is complete.
*/
uint16_t option;
/* Option. */
uint16_t flags;
/*
* When this bit is '1', the original active image will not be removed.
* TBD: what purpose is this?
*/
#define HWRM_NVM_WRITE_INPUT_FLAGS_KEEP_ORIG_ACTIVE_IMG UINT32_C(0x1)
uint32_t dir_item_length;
/*
* The requested length of the allocated NVM for the item, in bytes.
* This value may be greater than or equal to the specified data length
* (dir_data_length). If this value is less than the specified data
* length, it will be ignored. The response will contain the actual
* allocated item length, which may be greater than the requested item
* length. The purpose for allocating more than the required number of
* bytes for an item's data is to pre-allocate extra storage (padding)
* to accomodate the potential future growth of an item (e.g. upgraded
* firmware with a size increase, log growth, expanded configuration
* data).
*/
uint32_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_write_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t dir_item_length;
/*
* Length of the allocated NVM for the item, in bytes. The value may be
* greater than or equal to the specified data length or the requested
* item length. The actual item length used when creating a new
* directory entry will be a multiple of an NVM block size.
*/
uint16_t dir_idx;
/* The directory index of the created or modified item. */
uint8_t unused_0;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_write_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_WRITE_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* Unable to complete operation due to fragmentation */
#define HWRM_NVM_WRITE_CMD_ERR_CODE_FRAG_ERR UINT32_C(0x1)
/* nvm is completely full. */
#define HWRM_NVM_WRITE_CMD_ERR_CODE_NO_SPACE UINT32_C(0x2)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_nvm_modify */
/*
* Note: Modify the contents of an NVRAM item as referenced (indexed) by an
* existing directory entry.
*/
/* Input (40 bytes) */
struct hwrm_nvm_modify_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t host_src_addr;
/* 64-bit Host Source Address. This is where the modified data is. */
uint16_t dir_idx;
/* 16-bit directory entry index. */
uint8_t unused_0;
uint8_t unused_1;
uint32_t offset;
/* 32-bit NVRAM byte-offset to modify content from. */
uint32_t len;
/*
* Length of data to be modified, in bytes. The length shall be non-
* zero.
*/
uint32_t unused_2;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_modify_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_find_dir_entry */
/*
* Note: Search a directory entry in the directory by either directory entry
* index or directory entry parameters.
*/
/* Input (32 bytes) */
struct hwrm_nvm_find_dir_entry_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the dir_idx_valid field to be configured. */
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_ENABLES_DIR_IDX_VALID UINT32_C(0x1)
uint16_t dir_idx;
/* Directory Entry Index */
uint16_t dir_type;
/* Directory Entry (Image) Type */
uint16_t dir_ordinal;
/* Directory ordinal. The instance of this Directory Type */
uint16_t dir_ext;
/* The Directory Entry Extension flags. */
uint8_t opt_ordinal;
/* This value indicates the search option using dir_ordinal. */
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_OPT_ORDINAL_MASK UINT32_C(0x3)
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_OPT_ORDINAL_SFT 0
/* Equal to specified ordinal value. */
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_OPT_ORDINAL_EQ UINT32_C(0x0)
/* Greater than or equal to specified ordinal value */
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_OPT_ORDINAL_GE UINT32_C(0x1)
/* Greater than specified ordinal value */
#define HWRM_NVM_FIND_DIR_ENTRY_INPUT_OPT_ORDINAL_GT UINT32_C(0x2)
uint8_t unused_1[3];
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_nvm_find_dir_entry_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t dir_item_length;
/* Allocated NVRAM for this directory entry, in bytes. */
uint32_t dir_data_length;
/* Size of the stored data for this directory entry, in bytes. */
uint32_t fw_ver;
/*
* Firmware version. Only valid if the directory entry is for embedded
* firmware stored in APE_BIN Format.
*/
uint16_t dir_ordinal;
/* Directory ordinal. */
uint16_t dir_idx;
/* Directory Entry Index */
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_erase_dir_entry */
/*
* Note: Remove a directory entry specified by the directory entry index from
* the directory.
*/
/* Input (24 bytes) */
struct hwrm_nvm_erase_dir_entry_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t dir_idx;
/* Directory Entry Index */
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_erase_dir_entry_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_get_dev_info */
/*
* Note: Get device info. Return Manufacturer_ID, Device_ID, block_size,
* nvram_size, reserved_size and available_size.
*/
/* Input (16 bytes) */
struct hwrm_nvm_get_dev_info_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (32 bytes) */
struct hwrm_nvm_get_dev_info_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t manufacturer_id;
/* Manufacturer ID. */
uint16_t device_id;
/* Device ID. */
uint32_t sector_size;
/* Sector size of the NVRAM device. */
uint32_t nvram_size;
/* Total size, in bytes of the NVRAM device. */
uint32_t reserved_size;
uint32_t available_size;
/*
* Available size that can be used, in bytes. Available size is the
* NVRAM size take away the used size and reserved size.
*/
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_mod_dir_entry */
/* Note: Modify a directory entry parameters in the directory. */
/* Input (32 bytes) */
struct hwrm_nvm_mod_dir_entry_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t enables;
/* This bit must be '1' for the checksum field to be configured. */
#define HWRM_NVM_MOD_DIR_ENTRY_INPUT_ENABLES_CHECKSUM UINT32_C(0x1)
uint16_t dir_idx;
/* Directory Entry Index */
uint16_t dir_ordinal;
/* Directory ordinal. The (0-based) instance of this Directory Type. */
uint16_t dir_ext;
/*
* The Directory Entry Extension flags (see BNX_DIR_EXT_* for extension
* flag definitions).
*/
uint16_t dir_attr;
/*
* Directory Entry Attribute flags (see BNX_DIR_ATTR_* for attribute
* flag definitions).
*/
uint32_t checksum;
/*
* If valid, then this field updates the checksum value of the content
* in the directory entry.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_mod_dir_entry_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_verify_update */
/*
* Description: Verify updated content of a directory entry. Before this
* verification, there should be two valid directory entries of the given
* directory type (one with "UPDATE" directory extension flag and the current
* one "ACTIVE"). Below are steps the HWRM performs for executing this command:
* # The HWRM finds the directory entry with "UDPATE" extension flag based on
* input parameters. The new directory entry should already have updated
* contents. # The HWRM performs signature verification of the updated content.
* # If the signature verification is successful, the two directory entries are
* switched (the verified updated entry is made active and the current "ACTIVE"
* entry is marked with "UPDATE" extension flag). Implementation notes: # The
* HWRM shall allow this command to be requested against any dir_type value (and
* not limit it to a subset). # In the case of an updated HWRM firmware, the new
* firmware version shall not automatically take effect (i.e. be executed).
*/
/* Input (24 bytes) */
struct hwrm_nvm_verify_update_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint16_t dir_type;
/* Directory Entry Type, to be verified. */
uint16_t dir_ordinal;
/* Directory ordinal. The instance of the Directory Type to be verified. */
uint16_t dir_ext;
/*
* The Directory Entry Extension flags. The "UPDATE" extension flag must
* be set in this value. A corresponding directory entry with the same
* type and ordinal values but *without* the "UPDATE" extension flag
* must also exist. The other flags of the extension must be identical
* between the active and update entries.
*/
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_verify_update_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* hwrm_nvm_install_update */
/*
* Description: Install a staged NVM package. A package file must first be
* staged into the "UPDATE" NVM item. This staging is accomplished using the
* nvm_write and/or nvm_modify HWRM commands.
*/
/* Input (24 bytes) */
struct hwrm_nvm_install_update_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint32_t install_type;
/*
* Installation type. If the value 3 through 0xffff is used, only
* packaged items with that type value will be installed and conditional
* installation directives for those packaged items will be over-ridden
* (i.e. 'create' or 'replace' will be treated as 'install').
*/
/*
* Perform a normal package installation. Conditional
* installation directives (e.g. 'create' and 'replace') of
* packaged items will be followed.
*/
#define HWRM_NVM_INSTALL_UPDATE_INPUT_INSTALL_TYPE_NORMAL UINT32_C(0x0)
/*
* Install all packaged items regardless of installation
* directive (i.e. treat all packaged items as though they have
* an installation directive of 'install').
*/
#define HWRM_NVM_INSTALL_UPDATE_INPUT_INSTALL_TYPE_ALL UINT32_C(0xffffffff)
uint16_t flags;
/*
* If set to 1, then securely erase all unused locations in persistent
* storage.
*/
#define HWRM_NVM_INSTALL_UPDATE_INPUT_FLAGS_ERASE_UNUSED_SPACE UINT32_C(0x1)
/*
* If set to 1, then unspecifed images, images not in the package file,
* will be safely deleted. When combined with erase_unused_space then
* unspecified images will be securely erased.
*/
#define HWRM_NVM_INSTALL_UPDATE_INPUT_FLAGS_REMOVE_UNUSED_PKG UINT32_C(0x2)
/*
* If set to 1, FW will defragment the NVM if defragmentation is
* required for the update. Allow additional time for this command to
* complete if this bit is set to 1.
*/
#define HWRM_NVM_INSTALL_UPDATE_INPUT_FLAGS_ALLOWED_TO_DEFRAG UINT32_C(0x4)
uint16_t unused_0;
} __attribute__((packed));
/* Output (24 bytes) */
struct hwrm_nvm_install_update_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint64_t installed_items;
/*
* Bit-mask of successfully installed items. Bit-0 corresponding to the
* first packaged item, Bit-1 for the second item, etc. A value of 0
* indicates that no items were successfully installed.
*/
uint8_t result;
/* result is 8 b */
/* There was no problem with the package installation. */
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_RESULT_SUCCESS UINT32_C(0x0)
uint8_t problem_item;
/* problem_item is 8 b */
/* There was no problem with any packaged items. */
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_PROBLEM_ITEM_NONE UINT32_C(0x0)
/* There was a problem with the NVM package itself. */
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_PROBLEM_ITEM_PACKAGE UINT32_C(0xff)
uint8_t reset_required;
/* reset_required is 8 b */
/*
* No reset is required for installed/updated firmware or
* microcode to take effect.
*/
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_RESET_REQUIRED_NONE UINT32_C(0x0)
/*
* A PCIe reset (e.g. system reboot) is required for newly
* installed/updated firmware or microcode to take effect.
*/
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_RESET_REQUIRED_PCI UINT32_C(0x1)
/*
* A controller power reset (e.g. system power-cycle) is
* required for newly installed/updated firmware or microcode to
* take effect. Some newly installed/updated firmware or
* microcode may still take effect upon the next PCIe reset.
*/
#define HWRM_NVM_INSTALL_UPDATE_OUTPUT_RESET_REQUIRED_POWER UINT32_C(0x2)
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_install_update_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_INSTALL_UPDATE_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* Unable to complete operation due to fragmentation */
#define HWRM_NVM_INSTALL_UPDATE_CMD_ERR_CODE_FRAG_ERR UINT32_C(0x1)
/* nvm is completely full. */
#define HWRM_NVM_INSTALL_UPDATE_CMD_ERR_CODE_NO_SPACE UINT32_C(0x2)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_nvm_flush */
/* Input (16 bytes) */
struct hwrm_nvm_flush_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_flush_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_flush_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_FLUSH_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* flush could not be performed */
#define HWRM_NVM_FLUSH_CMD_ERR_CODE_FAIL UINT32_C(0x1)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_nvm_get_variable */
/* Input (40 bytes) */
struct hwrm_nvm_get_variable_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t dest_data_addr;
/* This is the host address where nvm variable will be stored */
uint16_t data_len;
/* size of data in bits */
uint16_t option_num;
/* nvm cfg option number */
/* reserved. */
#define HWRM_NVM_GET_VARIABLE_INPUT_OPTION_NUM_RSVD_0 UINT32_C(0x0)
/* reserved. */
#define HWRM_NVM_GET_VARIABLE_INPUT_OPTION_NUM_RSVD_FFFF UINT32_C(0xffff)
uint16_t dimensions;
/*
* Number of dimensions for this nvm configuration variable. This value
* indicates how many of the indexN values to use. A value of 0 means
* that none of the indexN values are valid. A value of 1 requires at
* index0 is valued, a value of 2 requires that index0 and index1 are
* valid, and so forth
*/
uint16_t index_0;
/* index for the 1st dimensions */
uint16_t index_1;
/* index for the 2nd dimensions */
uint16_t index_2;
/* index for the 3rd dimensions */
uint16_t index_3;
/* index for the 4th dimensions */
uint8_t flags;
/*
* When this bit is set to 1, the factory default value will be
* returned, 0 returns the operational value.
*/
#define HWRM_NVM_GET_VARIABLE_INPUT_FLAGS_FACTORY_DFLT UINT32_C(0x1)
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_get_variable_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t data_len;
/* size of data of the actual variable retrieved in bits */
uint16_t option_num;
/*
* option_num is the option number for the data retrieved. It is
* possible in the future that the option number returned would be
* different than requested. This condition could occur if an option is
* deprecated and a new option id is defined with similar
* characteristics, but has a slightly different definition. This also
* makes it convenient for the caller to identify the variable result
* with the option id from the response.
*/
/* reserved. */
#define HWRM_NVM_GET_VARIABLE_OUTPUT_OPTION_NUM_RSVD_0 UINT32_C(0x0)
/* reserved. */
#define HWRM_NVM_GET_VARIABLE_OUTPUT_OPTION_NUM_RSVD_FFFF UINT32_C(0xffff)
uint8_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_get_variable_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_GET_VARIABLE_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* variable does not exist */
#define HWRM_NVM_GET_VARIABLE_CMD_ERR_CODE_VAR_NOT_EXIST UINT32_C(0x1)
/* configuration is corrupted and the variable cannot be saved */
#define HWRM_NVM_GET_VARIABLE_CMD_ERR_CODE_CORRUPT_VAR UINT32_C(0x2)
/* length specified is too small */
#define HWRM_NVM_GET_VARIABLE_CMD_ERR_CODE_LEN_TOO_SHORT UINT32_C(0x3)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_nvm_set_variable */
/* Input (40 bytes) */
struct hwrm_nvm_set_variable_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t src_data_addr;
/* This is the host address where nvm variable will be copied from */
uint16_t data_len;
/* size of data in bits */
uint16_t option_num;
/* nvm cfg option number */
/* reserved. */
#define HWRM_NVM_SET_VARIABLE_INPUT_OPTION_NUM_RSVD_0 UINT32_C(0x0)
/* reserved. */
#define HWRM_NVM_SET_VARIABLE_INPUT_OPTION_NUM_RSVD_FFFF UINT32_C(0xffff)
uint16_t dimensions;
/*
* Number of dimensions for this nvm configuration variable. This value
* indicates how many of the indexN values to use. A value of 0 means
* that none of the indexN values are valid. A value of 1 requires at
* index0 is valued, a value of 2 requires that index0 and index1 are
* valid, and so forth
*/
uint16_t index_0;
/* index for the 1st dimensions */
uint16_t index_1;
/* index for the 2nd dimensions */
uint16_t index_2;
/* index for the 3rd dimensions */
uint16_t index_3;
/* index for the 4th dimensions */
uint8_t flags;
/*
* When this bit is 1, flush internal cache after this write operation
* (see hwrm_nvm_flush command.)
*/
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_FORCE_FLUSH UINT32_C(0x1)
/* encryption method */
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_MASK UINT32_C(0xe)
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_SFT 1
/* No encryption. */
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_NONE (UINT32_C(0x0) << 1)
/* one-way encryption. */
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_HMAC_SHA1 (UINT32_C(0x1) << 1)
#define HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_LAST HWRM_NVM_SET_VARIABLE_INPUT_FLAGS_ENCRYPT_MODE_HMAC_SHA1
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_set_variable_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t unused_0;
uint8_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_set_variable_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_SET_VARIABLE_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
/* variable does not exist */
#define HWRM_NVM_SET_VARIABLE_CMD_ERR_CODE_VAR_NOT_EXIST UINT32_C(0x1)
/* configuration is corrupted and the variable cannot be saved */
#define HWRM_NVM_SET_VARIABLE_CMD_ERR_CODE_CORRUPT_VAR UINT32_C(0x2)
uint8_t unused_0[7];
} __attribute__((packed));
/* hwrm_nvm_validate_option */
/* Input (40 bytes) */
struct hwrm_nvm_validate_option_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t src_data_addr;
/* This is the host address where nvm variable will be copied from */
uint16_t data_len;
/* size of data in bits */
uint16_t option_num;
/* nvm cfg option number */
/* reserved. */
#define HWRM_NVM_VALIDATE_OPTION_INPUT_OPTION_NUM_RSVD_0 UINT32_C(0x0)
/* reserved. */
#define HWRM_NVM_VALIDATE_OPTION_INPUT_OPTION_NUM_RSVD_FFFF UINT32_C(0xffff)
uint16_t dimensions;
/*
* Number of dimensions for this nvm configuration variable. This value
* indicates how many of the indexN values to use. A value of 0 means
* that none of the indexN values are valid. A value of 1 requires at
* index0 is valued, a value of 2 requires that index0 and index1 are
* valid, and so forth
*/
uint16_t index_0;
/* index for the 1st dimensions */
uint16_t index_1;
/* index for the 2nd dimensions */
uint16_t index_2;
/* index for the 3rd dimensions */
uint16_t index_3;
/* index for the 4th dimensions */
uint16_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_nvm_validate_option_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t result;
/*
* indicates that the value provided for the option is not
* matching with the saved data.
*/
#define HWRM_NVM_VALIDATE_OPTION_OUTPUT_RESULT_NOT_MATCH UINT32_C(0x0)
/*
* indicates that the value provided for the option is matching
* the saved data.
*/
#define HWRM_NVM_VALIDATE_OPTION_OUTPUT_RESULT_MATCH UINT32_C(0x1)
uint8_t unused_0;
uint16_t unused_1;
uint8_t unused_2;
uint8_t unused_3;
uint8_t unused_4;
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Command specific Error Codes (8 bytes) */
struct hwrm_nvm_validate_option_cmd_err {
uint8_t code;
/*
* command specific error codes that goes to the cmd_err field in Common
* HWRM Error Response.
*/
/* Unknown error */
#define HWRM_NVM_VALIDATE_OPTION_CMD_ERR_CODE_UNKNOWN UINT32_C(0x0)
uint8_t unused_0[7];
} __attribute__((packed));
/* Command Queue (CMDQ) Interface */
/* Description: This command queries congestion control settings. */
/* Init CMDQ (16 bytes) */
struct cmdq_init {
uint64_t cmdq_pbl;
/* CMDQ PBL physical address. */
uint16_t cmdq_size_cmdq_lvl;
/* CMDQ size. */
/* CMDQ PBL indirection levels. */
#define CMDQ_INIT_CMDQ_LVL_MASK UINT32_C(0x3)
#define CMDQ_INIT_CMDQ_LVL_SFT 0
/* CMDQ size. */
#define CMDQ_INIT_CMDQ_SIZE_MASK UINT32_C(0xfffc)
#define CMDQ_INIT_CMDQ_SIZE_SFT 2
uint16_t creq_ring_id;
/* CREQ completion ring id. */
uint32_t prod_idx;
/* Mailbox producer index. MSB must also be set. */
} __attribute__((packed));
/* Update CMDQ producer index (16 bytes) */
struct cmdq_update {
uint64_t reserved64;
/* reserved64 is 64 b */
uint32_t reserved32;
/* reserved32 is 32 b */
uint32_t prod_idx;
/* Mailbox producer index. */
} __attribute__((packed));
/* CMDQ common header structure (16 bytes) */
struct cmdq_base {
uint8_t opcode;
/* Command opcode. */
/*
* Create QP command allocates QP context with the specified SQ,
* RQ/SRQ, CQ and other parameters.
*/
#define CMDQ_BASE_OPCODE_CREATE_QP UINT32_C(0x1)
/*
* Destroy QP command deletes the QP context and ceases any
* further reference.
*/
#define CMDQ_BASE_OPCODE_DESTROY_QP UINT32_C(0x2)
/*
* Modify QP command changes QP states and other QP specific
* parameters.
*/
#define CMDQ_BASE_OPCODE_MODIFY_QP UINT32_C(0x3)
/* Query QP command retrieves info about the specified QP. */
#define CMDQ_BASE_OPCODE_QUERY_QP UINT32_C(0x4)
/* Create SRQ command allocates a SRQ with the specified parameters. */
#define CMDQ_BASE_OPCODE_CREATE_SRQ UINT32_C(0x5)
/* Destroy SRQ command deletes and flushes the specified SRQ. */
#define CMDQ_BASE_OPCODE_DESTROY_SRQ UINT32_C(0x6)
/* Query SRP command retrieves info about the specified SRQ. */
#define CMDQ_BASE_OPCODE_QUERY_SRQ UINT32_C(0x8)
/* Create CQ command allocates a CQ with the specified parameters. */
#define CMDQ_BASE_OPCODE_CREATE_CQ UINT32_C(0x9)
/* Destroy CQ command deletes and flushes the specified CQ. */
#define CMDQ_BASE_OPCODE_DESTROY_CQ UINT32_C(0xa)
/* Resize CQ command resizes the specified CQ. */
#define CMDQ_BASE_OPCODE_RESIZE_CQ UINT32_C(0xc)
/*
* Allocate MRW command allocates a MR/MW with the specified
* parameters and returns the region's L_KEY/R_KEY
*/
#define CMDQ_BASE_OPCODE_ALLOCATE_MRW UINT32_C(0xd)
/*
* De-allocate key command frees a MR/MW entry associated with
* the specified key.
*/
#define CMDQ_BASE_OPCODE_DEALLOCATE_KEY UINT32_C(0xe)
/* Register MR command registers memory to the specified MR. */
#define CMDQ_BASE_OPCODE_REGISTER_MR UINT32_C(0xf)
/* Deregister MR command de-registers memory from the specified MR. */
#define CMDQ_BASE_OPCODE_DEREGISTER_MR UINT32_C(0x10)
/* Add GID command adds a GID to the local address table. */
#define CMDQ_BASE_OPCODE_ADD_GID UINT32_C(0x11)
/* Delete GID command deletes a GID from the local address table. */
#define CMDQ_BASE_OPCODE_DELETE_GID UINT32_C(0x12)
/* Modify GID command modifies a GID in the local address table. */
#define CMDQ_BASE_OPCODE_MODIFY_GID UINT32_C(0x17)
/* Query GID command queries a GID in the local address table. */
#define CMDQ_BASE_OPCODE_QUERY_GID UINT32_C(0x18)
/* Create QP1 command allocates a QP1 only. */
#define CMDQ_BASE_OPCODE_CREATE_QP1 UINT32_C(0x13)
/* Destroy QP1 command deletes and flushes the specified QP1. */
#define CMDQ_BASE_OPCODE_DESTROY_QP1 UINT32_C(0x14)
/* Create AH command allocates an AH with the specified parameters. */
#define CMDQ_BASE_OPCODE_CREATE_AH UINT32_C(0x15)
/* Destroy AH command deletes the specified AH. */
#define CMDQ_BASE_OPCODE_DESTROY_AH UINT32_C(0x16)
/*
* Initialize firmware command initializes the firmware with the
* specified parameters.
*/
#define CMDQ_BASE_OPCODE_INITIALIZE_FW UINT32_C(0x80)
/* De-initialize firmware command deinitializes the firmware. */
#define CMDQ_BASE_OPCODE_DEINITIALIZE_FW UINT32_C(0x81)
/* Stop the function */
#define CMDQ_BASE_OPCODE_STOP_FUNC UINT32_C(0x82)
/* Query the HW capabilities for the function. */
#define CMDQ_BASE_OPCODE_QUERY_FUNC UINT32_C(0x83)
/*
* Set the following resources for the function: - Max QP, CQ,
* MR+MW, SRQ per PF - Max QP, CQ, MR+MW, SRQ per VF
*/
#define CMDQ_BASE_OPCODE_SET_FUNC_RESOURCES UINT32_C(0x84)
/*
* Read the current state of any internal resource context. Can
* only be issued from a PF.
*/
#define CMDQ_BASE_OPCODE_READ_CONTEXT UINT32_C(0x85)
/*
* Send a request from VF to pass a command to the PF. VF HSI is
* suspended until the PF returns the response
*/
#define CMDQ_BASE_OPCODE_VF_BACKCHANNEL_REQUEST UINT32_C(0x86)
/*
* Read VF memory (primarily to get the backchannel request
* blob). Can only be issued from a PF.
*/
#define CMDQ_BASE_OPCODE_READ_VF_MEMORY UINT32_C(0x87)
/*
* Write VF memory (primarily to put the backchannel response
* blob), and reenable VF HSI (post a CAG completion to it). Can
* only be issued from a PF.
*/
#define CMDQ_BASE_OPCODE_COMPLETE_VF_REQUEST UINT32_C(0x88)
/*
* Extend resource (QPC, MRW, CQ, SRQ) array, after the host
* allocates more. Can only be issued from a PF.
*/
#define CMDQ_BASE_OPCODE_EXTEND_CONTEXT_ARRRAY UINT32_C(0x89)
/* Map TC to COS. Can only be issued from a PF. */
#define CMDQ_BASE_OPCODE_MAP_TC_TO_COS UINT32_C(0x8a)
/* Query version. */
#define CMDQ_BASE_OPCODE_QUERY_VERSION UINT32_C(0x8b)
/* Modify congestion control. Can only be issued from a PF. */
#define CMDQ_BASE_OPCODE_MODIFY_ROCE_CC UINT32_C(0x8c)
/* Query congestion control. */
#define CMDQ_BASE_OPCODE_QUERY_ROCE_CC UINT32_C(0x8d)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Create QP command (96 bytes) */
struct cmdq_create_qp {
uint8_t opcode;
/* Command opcode. */
/*
* Create QP command allocates QP context with the specified SQ,
* RQ/SRQ, CQ and other parameters.
*/
#define CMDQ_CREATE_QP_OPCODE_CREATE_QP UINT32_C(0x1)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t qp_handle;
/* QP handle. */
uint32_t qp_flags;
/* Create QP flags. */
/* SRQ is used. */
#define CMDQ_CREATE_QP_QP_FLAGS_SRQ_USED UINT32_C(0x1)
/* post CQE for all SQ WQEs. */
#define CMDQ_CREATE_QP_QP_FLAGS_FORCE_COMPLETION UINT32_C(0x2)
/* This QP can use reserved L_Key */
#define CMDQ_CREATE_QP_QP_FLAGS_RESERVED_LKEY_ENABLE UINT32_C(0x4)
/* This QP can fast register physical memory */
#define CMDQ_CREATE_QP_QP_FLAGS_FR_PMR_ENABLED UINT32_C(0x8)
uint8_t type;
/* Supported QP types. */
/* Reliable Connection. */
#define CMDQ_CREATE_QP_TYPE_RC UINT32_C(0x2)
/* Unreliable Datagram. */
#define CMDQ_CREATE_QP_TYPE_UD UINT32_C(0x4)
/* Raw Ethertype. */
#define CMDQ_CREATE_QP_TYPE_RAW_ETHERTYPE UINT32_C(0x6)
uint8_t sq_pg_size_sq_lvl;
/* SQ page size. */
/* SQ PBL indirect levels. */
#define CMDQ_CREATE_QP_SQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP_SQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_QP_SQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_QP_SQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_QP_SQ_LVL_LVL_2 UINT32_C(0x2)
/* SQ page size. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_CREATE_QP_SQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_CREATE_QP_SQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t rq_pg_size_rq_lvl;
/* RQ page size. */
/* RQ PBL indirect levels. */
#define CMDQ_CREATE_QP_RQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP_RQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_QP_RQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_QP_RQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_QP_RQ_LVL_LVL_2 UINT32_C(0x2)
/* RQ page size. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_CREATE_QP_RQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_CREATE_QP_RQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t unused_0;
uint32_t dpi;
/* Doorbell page index. */
uint32_t sq_size;
/* Max number of SQ wqes. */
uint32_t rq_size;
/* Max number of RQ wqes. */
uint16_t sq_fwo_sq_sge;
/* Offset of First WQE in the first SQ page, in 128 byte units */
/* Max send SGEs per SWQE. */
#define CMDQ_CREATE_QP_SQ_SGE_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP_SQ_SGE_SFT 0
/* Offset of First WQE in the first SQ page, in 128 byte units */
#define CMDQ_CREATE_QP_SQ_FWO_MASK UINT32_C(0xfff0)
#define CMDQ_CREATE_QP_SQ_FWO_SFT 4
uint16_t rq_fwo_rq_sge;
/* Offset of First WQE in the first RQ page, in 128 byte units */
/* Max recv SGEs per RWQE (NOT SUPPORTED BY HARDWARE). */
#define CMDQ_CREATE_QP_RQ_SGE_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP_RQ_SGE_SFT 0
/* Offset of First WQE in the first RQ page, in 128 byte units */
#define CMDQ_CREATE_QP_RQ_FWO_MASK UINT32_C(0xfff0)
#define CMDQ_CREATE_QP_RQ_FWO_SFT 4
uint32_t scq_cid;
/* Send CQ context id. */
uint32_t rcq_cid;
/* Receive CQ context id. */
uint32_t srq_cid;
/* SRQ CQ context id. */
uint32_t pd_id;
/* Protection domain id. */
uint64_t sq_pbl;
/* SQ PBL physical address. */
uint64_t rq_pbl;
/* RQ PBL physical address. */
uint64_t irrq_addr;
/* IRRQ address. */
uint64_t orrq_addr;
/* ORRQ address. */
} __attribute__((packed));
/* Destroy QP command (24 bytes) */
struct cmdq_destroy_qp {
uint8_t opcode;
/* Command opcode. */
/*
* Destroy QP command deletes the QP context and ceases any
* further reference.
*/
#define CMDQ_DESTROY_QP_OPCODE_DESTROY_QP UINT32_C(0x2)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t qp_cid;
/* QP context id */
uint32_t unused_0;
} __attribute__((packed));
/* Modify QP command (112 bytes) */
struct cmdq_modify_qp {
uint8_t opcode;
/* Command opcode. */
/*
* Modify QP command changes QP states and other QP specific
* parameters.
*/
#define CMDQ_MODIFY_QP_OPCODE_MODIFY_QP UINT32_C(0x3)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t modify_mask;
/* Modify mask signifies the field that is requesting the change. */
/* QP state change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_STATE UINT32_C(0x1)
/* Enable SQ drain asynchronous notification change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_EN_SQD_ASYNC_NOTIFY UINT32_C(0x2)
/* Access change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_ACCESS UINT32_C(0x4)
/* P_KEY change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_PKEY UINT32_C(0x8)
/* Q_KEY index change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_QKEY UINT32_C(0x10)
/* Destination GID change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_DGID UINT32_C(0x20)
/* Flow label change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_FLOW_LABEL UINT32_C(0x40)
/* SGID change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_SGID_INDEX UINT32_C(0x80)
/* Hop limit change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_HOP_LIMIT UINT32_C(0x100)
/* Traffic class change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_TRAFFIC_CLASS UINT32_C(0x200)
/* destination MAC change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_DEST_MAC UINT32_C(0x400)
/* unused is 1 b */
#define CMDQ_MODIFY_QP_MODIFY_MASK_UNUSED UINT32_C(0x800)
/* Path MTU change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_PATH_MTU UINT32_C(0x1000)
/* Timeout change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_TIMEOUT UINT32_C(0x2000)
/* Retry count change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_RETRY_CNT UINT32_C(0x4000)
/* RNR Retry change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_RNR_RETRY UINT32_C(0x8000)
/* RQ start packet sequence number change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_RQ_PSN UINT32_C(0x10000)
/* Max outstanding RDMA read atomic change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_MAX_RD_ATOMIC UINT32_C(0x20000)
/* RNR minimum timer change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_MIN_RNR_TIMER UINT32_C(0x40000)
/* SQ start packet sequence number change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_SQ_PSN UINT32_C(0x80000)
/* Max destination outstanding RDMA read atomic change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_MAX_DEST_RD_ATOMIC UINT32_C(0x100000)
/* Max send WQE change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_SQ_SIZE UINT32_C(0x200000)
/* Max recv WQE change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_RQ_SIZE UINT32_C(0x400000)
/* Max recv SGEs per SWQE change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_SQ_SGE UINT32_C(0x800000)
/* Max send SGEs per RWQE change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_RQ_SGE UINT32_C(0x1000000)
/* Max inline data length change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_MAX_INLINE_DATA UINT32_C(0x2000000)
/* Destination QP id change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_DEST_QP_ID UINT32_C(0x4000000)
/* Source MAC change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_SRC_MAC UINT32_C(0x8000000)
/* Source VLAN id change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_VLAN_ID UINT32_C(0x10000000)
/* Congestion control RoCE v2 change. */
#define CMDQ_MODIFY_QP_MODIFY_MASK_ENABLE_CC UINT32_C(0x20000000)
/* IP TOS ECN change */
#define CMDQ_MODIFY_QP_MODIFY_MASK_TOS_ECN UINT32_C(0x40000000)
/* IP TOS DSCP change */
#define CMDQ_MODIFY_QP_MODIFY_MASK_TOS_DSCP UINT32_C(0x80000000)
uint32_t qp_cid;
/* QP context id. */
uint8_t network_type_en_sqd_async_notify_new_state;
/* network type. */
/* New QP state. */
#define CMDQ_MODIFY_QP_NEW_STATE_MASK UINT32_C(0xf)
#define CMDQ_MODIFY_QP_NEW_STATE_SFT 0
/* Reset. */
#define CMDQ_MODIFY_QP_NEW_STATE_RESET UINT32_C(0x0)
/* Init. */
#define CMDQ_MODIFY_QP_NEW_STATE_INIT UINT32_C(0x1)
/* Ready To Receive. */
#define CMDQ_MODIFY_QP_NEW_STATE_RTR UINT32_C(0x2)
/* Ready To Send. */
#define CMDQ_MODIFY_QP_NEW_STATE_RTS UINT32_C(0x3)
/* SQ Drain. */
#define CMDQ_MODIFY_QP_NEW_STATE_SQD UINT32_C(0x4)
/* SQ Error. */
#define CMDQ_MODIFY_QP_NEW_STATE_SQE UINT32_C(0x5)
/* Error. */
#define CMDQ_MODIFY_QP_NEW_STATE_ERR UINT32_C(0x6)
/* Enable SQ drain asynchronous notification. */
#define CMDQ_MODIFY_QP_EN_SQD_ASYNC_NOTIFY UINT32_C(0x10)
/* unused1 is 1 b */
/* network type. */
#define CMDQ_MODIFY_QP_NETWORK_TYPE_MASK UINT32_C(0xc0)
#define CMDQ_MODIFY_QP_NETWORK_TYPE_SFT 6
/* RoCEv1. */
#define CMDQ_MODIFY_QP_NETWORK_TYPE_ROCEV1 (UINT32_C(0x0) << 6)
/* RoCEv2 IPv4. */
#define CMDQ_MODIFY_QP_NETWORK_TYPE_ROCEV2_IPV4 (UINT32_C(0x2) << 6)
/* RoCEv2 IPv6. */
#define CMDQ_MODIFY_QP_NETWORK_TYPE_ROCEV2_IPV6 (UINT32_C(0x3) << 6)
uint8_t access;
/* Access flags. */
/* Local write access. */
#define CMDQ_MODIFY_QP_ACCESS_LOCAL_WRITE UINT32_C(0x1)
/* Remote write access. */
#define CMDQ_MODIFY_QP_ACCESS_REMOTE_WRITE UINT32_C(0x2)
/* Remote read access. */
#define CMDQ_MODIFY_QP_ACCESS_REMOTE_READ UINT32_C(0x4)
/* Remote atomic access. */
#define CMDQ_MODIFY_QP_ACCESS_REMOTE_ATOMIC UINT32_C(0x8)
uint16_t pkey;
/* P_KEY. */
uint32_t qkey;
/* Q_KEY. */
uint32_t dgid[4];
/* Destination GID. */
uint32_t flow_label;
/* Flow label. */
uint16_t sgid_index;
/* Source GID index. */
uint8_t hop_limit;
/* Hop limit. */
uint8_t traffic_class;
/* Traffic class. */
uint16_t dest_mac[3];
/* Destination MAC address. */
uint8_t tos_dscp_tos_ecn;
/* IP TOS DSCP. */
/* IP TOS ECN. Valid values are 1 or 2 when ECN is enabled. */
#define CMDQ_MODIFY_QP_TOS_ECN_MASK UINT32_C(0x3)
#define CMDQ_MODIFY_QP_TOS_ECN_SFT 0
/* IP TOS DSCP. */
#define CMDQ_MODIFY_QP_TOS_DSCP_MASK UINT32_C(0xfc)
#define CMDQ_MODIFY_QP_TOS_DSCP_SFT 2
uint8_t path_mtu;
/* Path MTU. */
/* unused4 is 4 b */
/* Path MTU. */
#define CMDQ_MODIFY_QP_PATH_MTU_MASK UINT32_C(0xf0)
#define CMDQ_MODIFY_QP_PATH_MTU_SFT 4
/* 256. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_256 (UINT32_C(0x0) << 4)
/* 512. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_512 (UINT32_C(0x1) << 4)
/* 1024. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_1024 (UINT32_C(0x2) << 4)
/* 2048. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_2048 (UINT32_C(0x3) << 4)
/* 4096. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_4096 (UINT32_C(0x4) << 4)
/* 8192. */
#define CMDQ_MODIFY_QP_PATH_MTU_MTU_8192 (UINT32_C(0x5) << 4)
uint8_t timeout;
/* Timeout value for SWQEs. */
uint8_t retry_cnt;
/* Max retry count for WQEs. */
uint8_t rnr_retry;
/* Max RNR retry count for WQEs. */
uint8_t min_rnr_timer;
/* Min RNR timer that the QP will report to the remote. */
uint32_t rq_psn;
/* RQ start packet sequence number. */
uint32_t sq_psn;
/* SQ start packet sequence number. */
uint8_t max_rd_atomic;
/* Max outstanding RDMA read atomic. */
uint8_t max_dest_rd_atomic;
/* Max destination outstanding RDMA read atomic. */
uint16_t enable_cc;
/* unused15 is 15 b */
/* Enable congestion control. */
#define CMDQ_MODIFY_QP_ENABLE_CC UINT32_C(0x1)
/* unused15 is 15 b */
uint32_t sq_size;
/* Max send WQE. */
uint32_t rq_size;
/* Max recv WQE. */
uint16_t sq_sge;
/* Max send SGEs per SWQE. */
uint16_t rq_sge;
/* Max recv SGEs per RWQE. */
uint32_t max_inline_data;
/* Max inline data length (upto 120 bytes). */
uint32_t dest_qp_id;
/* Destination QP id. */
uint32_t unused_3;
uint16_t src_mac[3];
/* Source MAC. (Unused. Comes from Source GID index) */
uint16_t vlan_pcp_vlan_dei_vlan_id;
/* VLAN PCP field - Priority Code Point. */
/* VLAN id. (Unused. Comes from Source GID index) */
#define CMDQ_MODIFY_QP_VLAN_ID_MASK UINT32_C(0xfff)
#define CMDQ_MODIFY_QP_VLAN_ID_SFT 0
/* VLAN DEI field - Drop Eligibility Indicator. */
#define CMDQ_MODIFY_QP_VLAN_DEI UINT32_C(0x1000)
/* VLAN PCP field - Priority Code Point. */
#define CMDQ_MODIFY_QP_VLAN_PCP_MASK UINT32_C(0xe000)
#define CMDQ_MODIFY_QP_VLAN_PCP_SFT 13
} __attribute__((packed));
/* Query QP command (24 bytes) */
struct cmdq_query_qp {
uint8_t opcode;
/* Command opcode. */
/* Query QP command retrieves info about the specified QP. */
#define CMDQ_QUERY_QP_OPCODE_QUERY_QP UINT32_C(0x4)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t qp_cid;
/* QP context id */
uint32_t unused_0;
} __attribute__((packed));
/* Create SRQ command (48 bytes) */
struct cmdq_create_srq {
uint8_t opcode;
/* Command opcode. */
/* Create SRQ command allocates a SRQ with the specified parameters. */
#define CMDQ_CREATE_SRQ_OPCODE_CREATE_SRQ UINT32_C(0x5)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t srq_handle;
/* SRQ handle. */
uint16_t pg_size_lvl;
/* unused11 is 11 b */
/* SRQ PBL indirect levels. */
#define CMDQ_CREATE_SRQ_LVL_MASK UINT32_C(0x3)
#define CMDQ_CREATE_SRQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_SRQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_SRQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_SRQ_LVL_LVL_2 UINT32_C(0x2)
/* page size. */
#define CMDQ_CREATE_SRQ_PG_SIZE_MASK UINT32_C(0x1c)
#define CMDQ_CREATE_SRQ_PG_SIZE_SFT 2
/* 4KB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 2)
/* 8KB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 2)
/* 64KB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 2)
/* 2MB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 2)
/* 8MB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 2)
/* 1GB. */
#define CMDQ_CREATE_SRQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 2)
/* unused11 is 11 b */
uint16_t eventq_id;
/* unused4 is 4 b */
/* eventq_id is 12 b */
#define CMDQ_CREATE_SRQ_EVENTQ_ID_MASK UINT32_C(0xfff)
#define CMDQ_CREATE_SRQ_EVENTQ_ID_SFT 0
/* unused4 is 4 b */
uint16_t srq_size;
/* Max number of SRQ wqes. */
uint16_t srq_fwo;
/* Offsetof first WQE in the first page of SRQ, in 128 byte units */
uint32_t dpi;
/* Doorbell page index. */
uint32_t pd_id;
/* Protection domain id. */
uint64_t pbl;
/* RQ PBL physical address. */
} __attribute__((packed));
/* Destroy SRQ command (24 bytes) */
struct cmdq_destroy_srq {
uint8_t opcode;
/* Command opcode. */
/* Destroy SRQ command deletes and flushes the specified SRQ. */
#define CMDQ_DESTROY_SRQ_OPCODE_DESTROY_SRQ UINT32_C(0x6)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t srq_cid;
/* SRQ context id */
uint32_t unused_0;
} __attribute__((packed));
/* Query SRQ command (24 bytes) */
struct cmdq_query_srq {
uint8_t opcode;
/* Command opcode. */
/* Query SRP command retrieves info about the specified SRQ. */
#define CMDQ_QUERY_SRQ_OPCODE_QUERY_SRQ UINT32_C(0x8)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t srq_cid;
/* SRQ context id */
uint32_t unused_0;
} __attribute__((packed));
/* Create CQ command (48 bytes) */
struct cmdq_create_cq {
uint8_t opcode;
/* Command opcode. */
/* Create CQ command allocates a CQ with the specified parameters. */
#define CMDQ_CREATE_CQ_OPCODE_CREATE_CQ UINT32_C(0x9)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t cq_handle;
/* CQ handle. */
uint32_t pg_size_lvl;
/* unused27 is 27 b */
/* PBL indirect levels. */
#define CMDQ_CREATE_CQ_LVL_MASK UINT32_C(0x3)
#define CMDQ_CREATE_CQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_CQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_CQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_CQ_LVL_LVL_2 UINT32_C(0x2)
/* page size. */
#define CMDQ_CREATE_CQ_PG_SIZE_MASK UINT32_C(0x1c)
#define CMDQ_CREATE_CQ_PG_SIZE_SFT 2
/* 4KB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 2)
/* 8KB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 2)
/* 64KB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 2)
/* 2MB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 2)
/* 8MB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 2)
/* 1GB. */
#define CMDQ_CREATE_CQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 2)
/* unused27 is 27 b */
uint32_t cq_fco_cnq_id;
/* Offset of first CQE in the first Page, in 32 byte units */
/* cnq_id is 12 b */
#define CMDQ_CREATE_CQ_CNQ_ID_MASK UINT32_C(0xfff)
#define CMDQ_CREATE_CQ_CNQ_ID_SFT 0
/* Offset of first CQE in the first Page, in 32 byte units */
#define CMDQ_CREATE_CQ_CQ_FCO_MASK UINT32_C(0xfffff000)
#define CMDQ_CREATE_CQ_CQ_FCO_SFT 12
uint32_t dpi;
/* Doorbell page index. */
uint32_t cq_size;
/* Max number of CQ wqes. */
uint64_t pbl;
/* CQ PBL physical address. */
} __attribute__((packed));
/* Destroy CQ command (24 bytes) */
struct cmdq_destroy_cq {
uint8_t opcode;
/* Command opcode. */
/* Destroy CQ command deletes and flushes the specified CQ. */
#define CMDQ_DESTROY_CQ_OPCODE_DESTROY_CQ UINT32_C(0xa)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t cq_cid;
/* CQ context id */
uint32_t unused_0;
} __attribute__((packed));
/* Resize CQ command (40 bytes) */
struct cmdq_resize_cq {
uint8_t opcode;
/* Command opcode. */
/* Resize CQ command resizes the specified CQ. */
#define CMDQ_RESIZE_CQ_OPCODE_RESIZE_CQ UINT32_C(0xc)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t cq_cid;
/* CQ context id */
uint32_t new_cq_size_pg_size_lvl;
/* PBL indirect levels. */
#define CMDQ_RESIZE_CQ_LVL_MASK UINT32_C(0x3)
#define CMDQ_RESIZE_CQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_RESIZE_CQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_RESIZE_CQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_RESIZE_CQ_LVL_LVL_2 UINT32_C(0x2)
/* page size. */
#define CMDQ_RESIZE_CQ_PG_SIZE_MASK UINT32_C(0x1c)
#define CMDQ_RESIZE_CQ_PG_SIZE_SFT 2
/* 4KB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 2)
/* 8KB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 2)
/* 64KB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 2)
/* 2MB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 2)
/* 8MB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 2)
/* 1GB. */
#define CMDQ_RESIZE_CQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 2)
/* New max number of CQ wqes. */
#define CMDQ_RESIZE_CQ_NEW_CQ_SIZE_MASK UINT32_C(0x1fffe0)
#define CMDQ_RESIZE_CQ_NEW_CQ_SIZE_SFT 5
uint64_t new_pbl;
/* CQ PBL physical address. */
uint32_t new_cq_fco;
/* Offset of first CQE in the first Page, in 32 byte units */
uint32_t unused_2;
} __attribute__((packed));
/* Allocate MRW command (32 bytes) */
struct cmdq_allocate_mrw {
uint8_t opcode;
/* Command opcode. */
/*
* Allocate MRW command allocates a MR/MW with the specified
* parameters and returns the region's L_KEY/R_KEY
*/
#define CMDQ_ALLOCATE_MRW_OPCODE_ALLOCATE_MRW UINT32_C(0xd)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t mrw_handle;
/* MRW handle. */
uint8_t mrw_flags;
/* unused4 is 4 b */
/* Allocate MRW flags. */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_MASK UINT32_C(0xf)
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_SFT 0
/* Allocate Memory Region */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_MR UINT32_C(0x0)
/* Allocate Physical Memory Region */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_PMR UINT32_C(0x1)
/* Allocate Memory Window (type 1) */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE1 UINT32_C(0x2)
/* Allocate Memory Window (type 2A) */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2A UINT32_C(0x3)
/* Allocate Memory Window (type 2B) */
#define CMDQ_ALLOCATE_MRW_MRW_FLAGS_MW_TYPE2B UINT32_C(0x4)
/* unused4 is 4 b */
uint8_t access;
/* Access flags. */
#define CMDQ_ALLOCATE_MRW_ACCESS_RESERVED_MASK UINT32_C(0x1f)
#define CMDQ_ALLOCATE_MRW_ACCESS_RESERVED_SFT 0
/* Consumer owns the key */
#define CMDQ_ALLOCATE_MRW_ACCESS_CONSUMER_OWNED_KEY UINT32_C(0x20)
uint16_t unused_1;
/* unused16 is 16 b */
uint32_t pd_id;
/* Protection domain id. */
} __attribute__((packed));
/* De-allocate key command (24 bytes) */
struct cmdq_deallocate_key {
uint8_t opcode;
/* Command opcode. */
/*
* De-allocate key command frees a MR/MW entry associated with
* the specified key.
*/
#define CMDQ_DEALLOCATE_KEY_OPCODE_DEALLOCATE_KEY UINT32_C(0xe)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint8_t mrw_flags;
/* unused4 is 4 b */
/* Deallocate MRW flags. */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_MASK UINT32_C(0xf)
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_SFT 0
/* Deallocate Memory Region */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_MR UINT32_C(0x0)
/* Deallocate Physical Memory Region */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_PMR UINT32_C(0x1)
/* Deallocate Memory Window (type 1) */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_MW_TYPE1 UINT32_C(0x2)
/* Deallocate Memory Window (type 2A) */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_MW_TYPE2A UINT32_C(0x3)
/* Deallocate Memory Window (type 2B) */
#define CMDQ_DEALLOCATE_KEY_MRW_FLAGS_MW_TYPE2B UINT32_C(0x4)
/* unused4 is 4 b */
uint8_t unused_1[3];
/* unused24 is 24 b */
uint32_t key;
/* key is 32 b */
} __attribute__((packed));
/* Register MR command (48 bytes) */
struct cmdq_register_mr {
uint8_t opcode;
/* Command opcode. */
/* Register MR command registers memory to the specified MR. */
#define CMDQ_REGISTER_MR_OPCODE_REGISTER_MR UINT32_C(0xf)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint8_t log2_pg_size_lvl;
/* unused1 is 1 b */
/* PBL indirect levels. */
#define CMDQ_REGISTER_MR_LVL_MASK UINT32_C(0x3)
#define CMDQ_REGISTER_MR_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_REGISTER_MR_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_REGISTER_MR_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_REGISTER_MR_LVL_LVL_2 UINT32_C(0x2)
/*
* Log base 2 of page size; 12 is the minimum for 4KB. HW supported
* values are enumerated below.
*/
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_MASK UINT32_C(0x7c)
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_SFT 2
/* 4KB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_4K (UINT32_C(0xc) << 2)
/* 8KB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_8K (UINT32_C(0xd) << 2)
/* 64KB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_64K (UINT32_C(0x10) << 2)
/* 256KB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_256K (UINT32_C(0x12) << 2)
/* 1MB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_1M (UINT32_C(0x14) << 2)
/* 2MB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_2M (UINT32_C(0x15) << 2)
/* 4MB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_4M (UINT32_C(0x16) << 2)
/* 1GB. */
#define CMDQ_REGISTER_MR_LOG2_PG_SIZE_PG_1G (UINT32_C(0x1e) << 2)
/* unused1 is 1 b */
uint8_t access;
/* Access flags. */
/* Local write access. */
#define CMDQ_REGISTER_MR_ACCESS_LOCAL_WRITE UINT32_C(0x1)
/* Remote read access. */
#define CMDQ_REGISTER_MR_ACCESS_REMOTE_READ UINT32_C(0x2)
/* Remote write access. */
#define CMDQ_REGISTER_MR_ACCESS_REMOTE_WRITE UINT32_C(0x4)
/* Remote atomic access. */
#define CMDQ_REGISTER_MR_ACCESS_REMOTE_ATOMIC UINT32_C(0x8)
/* Bind access allowed. */
#define CMDQ_REGISTER_MR_ACCESS_MW_BIND UINT32_C(0x10)
/* Indicate Zero Based Virtual Address (ZBVA). */
#define CMDQ_REGISTER_MR_ACCESS_ZERO_BASED UINT32_C(0x20)
uint16_t log2_pbl_pg_size;
/* unused11 is 11 b */
/*
* Log base 2 of PBL page size; 12 is the minimum for 4KB. HW supported
* values are enumerated below
*/
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_MASK UINT32_C(0x1f)
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_SFT 0
/* 4KB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_4K UINT32_C(0xc)
/* 8KB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_8K UINT32_C(0xd)
/* 64KB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_64K UINT32_C(0x10)
/* 256KB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_256K UINT32_C(0x12)
/* 1MB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_1M UINT32_C(0x14)
/* 2MB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_2M UINT32_C(0x15)
/* 4MB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_4M UINT32_C(0x16)
/* 1GB. */
#define CMDQ_REGISTER_MR_LOG2_PBL_PG_SIZE_PG_1G UINT32_C(0x1e)
/* unused11 is 11 b */
uint32_t key;
/* KEY of the MR. */
uint64_t pbl;
/* Page table of the MR memory. */
uint64_t va;
/* Virtual address of the MR. */
uint64_t mr_size;
/* Size of the MR. */
} __attribute__((packed));
/* Deregister MR command (24 bytes) */
struct cmdq_deregister_mr {
uint8_t opcode;
/* Command opcode. */
/* Deregister MR command de-registers memory from the specified MR. */
#define CMDQ_DEREGISTER_MR_OPCODE_DEREGISTER_MR UINT32_C(0x10)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t lkey;
/* L_KEY of the MR. */
uint32_t unused_0;
} __attribute__((packed));
/* Add GID command (48 bytes) */
struct cmdq_add_gid {
uint8_t opcode;
/* Command opcode. */
/* Add GID command adds a GID to the local address table. */
#define CMDQ_ADD_GID_OPCODE_ADD_GID UINT32_C(0x11)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t gid[4];
/* GID */
uint16_t src_mac[3];
/* Source MAC. */
uint16_t vlan;
/* flags. */
/* Source VLAN id. */
#define CMDQ_ADD_GID_VLAN_VLAN_ID_MASK UINT32_C(0xfff)
#define CMDQ_ADD_GID_VLAN_VLAN_ID_SFT 0
/* This set of bits select the TPID of the VLAN Tag. */
#define CMDQ_ADD_GID_VLAN_TPID_MASK UINT32_C(0x7000)
#define CMDQ_ADD_GID_VLAN_TPID_SFT 12
/* TPID = 0x88A8. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_88A8 (UINT32_C(0x0) << 12)
/* TPID = 0x8100. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_8100 (UINT32_C(0x1) << 12)
/* TPID = 0x9100. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_9100 (UINT32_C(0x2) << 12)
/* TPID = 0x9200. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_9200 (UINT32_C(0x3) << 12)
/* TPID = 0x9300. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_9300 (UINT32_C(0x4) << 12)
/* TPID = Configurable 1. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_CFG1 (UINT32_C(0x5) << 12)
/* TPID = Configurable 2. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_CFG2 (UINT32_C(0x6) << 12)
/* TPID = Configurable 3. */
#define CMDQ_ADD_GID_VLAN_TPID_TPID_CFG3 (UINT32_C(0x7) << 12)
#define CMDQ_ADD_GID_VLAN_TPID_LAST CMDQ_ADD_GID_VLAN_TPID_TPID_CFG3
/*
* Setting this bit to 1 enables insertion of a VLAN Tag to a RoCE
* header.
*/
#define CMDQ_ADD_GID_VLAN_VLAN_EN UINT32_C(0x8000)
uint16_t ipid;
/* Identifier field in the IP header. */
uint16_t stats_ctx;
/* Stats context ID to use with this SGID */
/* stats_ctx_id is 15 b */
#define CMDQ_ADD_GID_STATS_CTX_STATS_CTX_ID_MASK UINT32_C(0x7fff)
#define CMDQ_ADD_GID_STATS_CTX_STATS_CTX_ID_SFT 0
/*
* Setting this bit to 1 enables use of own stats context ID instead of
* per-function
*/
#define CMDQ_ADD_GID_STATS_CTX_STATS_CTX_VALID UINT32_C(0x8000)
uint32_t unused_0;
} __attribute__((packed));
/* Delete GID command (24 bytes) */
struct cmdq_delete_gid {
uint8_t opcode;
/* Command opcode. */
/* Delete GID command deletes a GID from the local address table. */
#define CMDQ_DELETE_GID_OPCODE_DELETE_GID UINT32_C(0x12)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint16_t gid_index;
/* GID index */
uint16_t unused_0;
/* unused16 is 16 b */
uint32_t unused_1;
} __attribute__((packed));
/* Modify GID command (48 bytes) */
struct cmdq_modify_gid {
uint8_t opcode;
/* Command opcode. */
/* Modify GID command modifies a GID in the local address table. */
#define CMDQ_MODIFY_GID_OPCODE_MODIFY_GID UINT32_C(0x17)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t gid[4];
/* GID */
uint16_t src_mac[3];
/* Source MAC. */
uint16_t vlan;
/* flags. */
/* Source VLAN id. */
#define CMDQ_MODIFY_GID_VLAN_VLAN_ID_MASK UINT32_C(0xfff)
#define CMDQ_MODIFY_GID_VLAN_VLAN_ID_SFT 0
/* This set of bits select the TPID of the VLAN Tag. */
#define CMDQ_MODIFY_GID_VLAN_TPID_MASK UINT32_C(0x7000)
#define CMDQ_MODIFY_GID_VLAN_TPID_SFT 12
/* TPID = 0x88A8. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_88A8 (UINT32_C(0x0) << 12)
/* TPID = 0x8100. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_8100 (UINT32_C(0x1) << 12)
/* TPID = 0x9100. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_9100 (UINT32_C(0x2) << 12)
/* TPID = 0x9200. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_9200 (UINT32_C(0x3) << 12)
/* TPID = 0x9300. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_9300 (UINT32_C(0x4) << 12)
/* TPID = Configurable 1. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_CFG1 (UINT32_C(0x5) << 12)
/* TPID = Configurable 2. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_CFG2 (UINT32_C(0x6) << 12)
/* TPID = Configurable 3. */
#define CMDQ_MODIFY_GID_VLAN_TPID_TPID_CFG3 (UINT32_C(0x7) << 12)
#define CMDQ_MODIFY_GID_VLAN_TPID_LAST CMDQ_MODIFY_GID_VLAN_TPID_TPID_CFG3
/*
* Setting this bit to 1 enables insertion of a VLAN Tag to a RoCE
* header.
*/
#define CMDQ_MODIFY_GID_VLAN_VLAN_EN UINT32_C(0x8000)
uint16_t ipid;
/* Identifier field in the IP header. */
uint16_t gid_index;
/* GID index */
uint16_t stats_ctx;
/* Stats context ID to use with this SGID */
/* stats_ctx_id is 15 b */
#define CMDQ_MODIFY_GID_STATS_CTX_STATS_CTX_ID_MASK UINT32_C(0x7fff)
#define CMDQ_MODIFY_GID_STATS_CTX_STATS_CTX_ID_SFT 0
/*
* Setting this bit to 1 enables use of own stats context ID instead of
* per-function
*/
#define CMDQ_MODIFY_GID_STATS_CTX_STATS_CTX_VALID UINT32_C(0x8000)
uint16_t unused_0;
} __attribute__((packed));
/* Query GID command (24 bytes) */
struct cmdq_query_gid {
uint8_t opcode;
/* Command opcode. */
/* Query GID command queries a GID in the local address table. */
#define CMDQ_QUERY_GID_OPCODE_QUERY_GID UINT32_C(0x18)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint16_t gid_index;
/* GID index */
uint16_t unused_0;
/* unused16 is 16 b */
uint32_t unused_1;
} __attribute__((packed));
/* Create QP1 command (80 bytes) */
struct cmdq_create_qp1 {
uint8_t opcode;
/* Command opcode. */
/* Create QP1 command allocates a QP1 only. */
#define CMDQ_CREATE_QP1_OPCODE_CREATE_QP1 UINT32_C(0x13)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t qp_handle;
/* QP1 handle. */
uint32_t qp_flags;
/* Create QP1 flags. */
/* SRQ is used. */
#define CMDQ_CREATE_QP1_QP_FLAGS_SRQ_USED UINT32_C(0x1)
/* post CQE for all SQ WQEs. */
#define CMDQ_CREATE_QP1_QP_FLAGS_FORCE_COMPLETION UINT32_C(0x2)
/* This QP can use reserved L_Key */
#define CMDQ_CREATE_QP1_QP_FLAGS_RESERVED_LKEY_ENABLE UINT32_C(0x4)
uint8_t type;
/* Supported QP1 types. */
/* General Services Interface on QP 1. */
#define CMDQ_CREATE_QP1_TYPE_GSI UINT32_C(0x1)
uint8_t sq_pg_size_sq_lvl;
/* SQ page size. */
/* SQ PBL indirect levels. */
#define CMDQ_CREATE_QP1_SQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP1_SQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_QP1_SQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_QP1_SQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_QP1_SQ_LVL_LVL_2 UINT32_C(0x2)
/* SQ page size. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_CREATE_QP1_SQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t rq_pg_size_rq_lvl;
/* RQ page size. */
/* RQ PBL indirect levels. */
#define CMDQ_CREATE_QP1_RQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP1_RQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_CREATE_QP1_RQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_CREATE_QP1_RQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_CREATE_QP1_RQ_LVL_LVL_2 UINT32_C(0x2)
/* RQ page size. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_CREATE_QP1_RQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t unused_0;
uint32_t dpi;
/* Doorbell page index. */
uint32_t sq_size;
/* Max number of SQ wqes. */
uint32_t rq_size;
/* Max number of RQ wqes. */
uint16_t sq_fwo_sq_sge;
/* Offset of First WQE in the first SQ page, in 128 byte units */
/* Max send SGEs per SWQE. */
#define CMDQ_CREATE_QP1_SQ_SGE_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP1_SQ_SGE_SFT 0
/* Offset of First WQE in the first SQ page, in 128 byte units */
#define CMDQ_CREATE_QP1_SQ_FWO_MASK UINT32_C(0xfff0)
#define CMDQ_CREATE_QP1_SQ_FWO_SFT 4
uint16_t rq_fwo_rq_sge;
/* Offset of First WQE in the first RQ page, in 128 byte units */
/* Max recv SGEs per RWQE (NOT SUPPORTED BY HARDWARE). */
#define CMDQ_CREATE_QP1_RQ_SGE_MASK UINT32_C(0xf)
#define CMDQ_CREATE_QP1_RQ_SGE_SFT 0
/* Offset of First WQE in the first RQ page, in 128 byte units */
#define CMDQ_CREATE_QP1_RQ_FWO_MASK UINT32_C(0xfff0)
#define CMDQ_CREATE_QP1_RQ_FWO_SFT 4
uint32_t scq_cid;
/* Send CQ context id. */
uint32_t rcq_cid;
/* Receive CQ context id. */
uint32_t srq_cid;
/* SRQ CQ context id. */
uint32_t pd_id;
/* Protection domain id. */
uint64_t sq_pbl;
/* SQ PBL physical address. */
uint64_t rq_pbl;
/* RQ PBL physical address. */
} __attribute__((packed));
/* Destroy QP1 command (24 bytes) */
struct cmdq_destroy_qp1 {
uint8_t opcode;
/* Command opcode. */
/* Destroy QP1 command deletes and flushes the specified QP1. */
#define CMDQ_DESTROY_QP1_OPCODE_DESTROY_QP1 UINT32_C(0x14)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t qp1_cid;
/* QP1 context id */
uint32_t unused_0;
} __attribute__((packed));
/* Create AH command (64 bytes) */
struct cmdq_create_ah {
uint8_t opcode;
/* Command opcode. */
/* Create AH command allocates an AH with the specified parameters. */
#define CMDQ_CREATE_AH_OPCODE_CREATE_AH UINT32_C(0x15)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t ah_handle;
/* AH handle. */
uint32_t dgid[4];
/* Destination GID. */
uint8_t type;
/* V1, V2IPv4 or V2IPv6. */
/* V2IPv4. */
#define CMDQ_CREATE_AH_TYPE_V1 UINT32_C(0x0)
/* V2IPv4. */
#define CMDQ_CREATE_AH_TYPE_V2IPV4 UINT32_C(0x2)
/* V2IPv6. */
#define CMDQ_CREATE_AH_TYPE_V2IPV6 UINT32_C(0x3)
uint8_t hop_limit;
/* IPv6 Hop limit. */
uint16_t sgid_index;
/* SGID index. */
uint32_t dest_vlan_id_flow_label;
/* Destination VLAN ID. */
/* Flow label. */
#define CMDQ_CREATE_AH_FLOW_LABEL_MASK UINT32_C(0xfffff)
#define CMDQ_CREATE_AH_FLOW_LABEL_SFT 0
/* Destination VLAN ID. */
#define CMDQ_CREATE_AH_DEST_VLAN_ID_MASK UINT32_C(0xfff00000)
#define CMDQ_CREATE_AH_DEST_VLAN_ID_SFT 20
uint32_t pd_id;
/* Protection domain id. */
uint32_t unused_0;
uint16_t dest_mac[3];
/* Destination MAC address. */
uint8_t traffic_class;
/* Traffic class. */
uint8_t enable_cc;
/* Enable congestion control. */
#define CMDQ_CREATE_AH_ENABLE_CC UINT32_C(0x1)
} __attribute__((packed));
/* Destroy AH command (24 bytes) */
struct cmdq_destroy_ah {
uint8_t opcode;
/* Command opcode. */
/* Destroy AH command deletes the specified AH. */
#define CMDQ_DESTROY_AH_OPCODE_DESTROY_AH UINT32_C(0x16)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t ah_cid;
/* AH context id */
uint32_t unused_0;
} __attribute__((packed));
/* Initialize Firmware command (112 bytes) */
struct cmdq_initialize_fw {
uint8_t opcode;
/* Command opcode. */
/*
* Initialize firmware command initializes the firmware with the
* specified parameters.
*/
#define CMDQ_INITIALIZE_FW_OPCODE_INITIALIZE_FW UINT32_C(0x80)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint8_t qpc_pg_size_qpc_lvl;
/* QPC page size. */
/* QPC PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_QPC_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_QPC_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_QPC_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_QPC_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_QPC_LVL_LVL_2 UINT32_C(0x2)
/* QPC page size. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_QPC_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t mrw_pg_size_mrw_lvl;
/* MRW page size. */
/* MRW PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_MRW_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_MRW_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_MRW_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_MRW_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_MRW_LVL_LVL_2 UINT32_C(0x2)
/* MRW page size. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_MRW_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t srq_pg_size_srq_lvl;
/* SRQ page size. */
/* SRQ PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_SRQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_SRQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_SRQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_SRQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_SRQ_LVL_LVL_2 UINT32_C(0x2)
/* SRQ page size. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_SRQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t cq_pg_size_cq_lvl;
/* CQ page size. */
/* CQ PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_CQ_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_CQ_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_CQ_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_CQ_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_CQ_LVL_LVL_2 UINT32_C(0x2)
/* CQ page size. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_CQ_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t tqm_pg_size_tqm_lvl;
/* TQM page size. */
/* TQM PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_TQM_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_TQM_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_TQM_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_TQM_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_TQM_LVL_LVL_2 UINT32_C(0x2)
/* TQM page size. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_TQM_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint8_t tim_pg_size_tim_lvl;
/* TIM page size. */
/* TIM PBL indirect levels. */
#define CMDQ_INITIALIZE_FW_TIM_LVL_MASK UINT32_C(0xf)
#define CMDQ_INITIALIZE_FW_TIM_LVL_SFT 0
/* PBL pointer is physical start address. */
#define CMDQ_INITIALIZE_FW_TIM_LVL_LVL_0 UINT32_C(0x0)
/* PBL pointer points to PTE table. */
#define CMDQ_INITIALIZE_FW_TIM_LVL_LVL_1 UINT32_C(0x1)
/*
* PBL pointer points to PDE table with each entry pointing to
* PTE tables.
*/
#define CMDQ_INITIALIZE_FW_TIM_LVL_LVL_2 UINT32_C(0x2)
/* TIM page size. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_MASK UINT32_C(0xf0)
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_SFT 4
/* 4KB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_4K (UINT32_C(0x0) << 4)
/* 8KB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_8K (UINT32_C(0x1) << 4)
/* 64KB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_64K (UINT32_C(0x2) << 4)
/* 2MB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_2M (UINT32_C(0x3) << 4)
/* 8MB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_8M (UINT32_C(0x4) << 4)
/* 1GB. */
#define CMDQ_INITIALIZE_FW_TIM_PG_SIZE_PG_1G (UINT32_C(0x5) << 4)
uint16_t reserved16;
uint64_t qpc_page_dir;
/* Kernel notification queue page directory. */
uint64_t mrw_page_dir;
/* MRW page directory. */
uint64_t srq_page_dir;
/* SRQ page directory. */
uint64_t cq_page_dir;
/* CQ page directory. */
uint64_t tqm_page_dir;
/* TQM page directory. */
uint64_t tim_page_dir;
/* TIM page directory. */
uint32_t number_of_qp;
/* Number of QPs. */
uint32_t number_of_mrw;
/* Number of MRWs. */
uint32_t number_of_srq;
/* Number of SRQs. */
uint32_t number_of_cq;
/* Number of CQs. */
uint32_t max_qp_per_vf;
/* Number of QPs per VF. */
uint32_t max_mrw_per_vf;
/* Number of MRWs per VF. */
uint32_t max_srq_per_vf;
/* Number of SRQs per VF. */
uint32_t max_cq_per_vf;
/* Number of CQs per VF. */
uint32_t max_gid_per_vf;
/* Number of GIDs per VF. */
uint32_t stat_ctx_id;
/* Statistics context index for this function. */
} __attribute__((packed));
/* De-initialize Firmware command (16 bytes) */
struct cmdq_deinitialize_fw {
uint8_t opcode;
/* Command opcode. */
/* De-initialize firmware command deinitializes the firmware. */
#define CMDQ_DEINITIALIZE_FW_OPCODE_DEINITIALIZE_FW UINT32_C(0x81)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Stop function command (16 bytes) */
struct cmdq_stop_func {
uint8_t opcode;
/* Command opcode. */
/* Stop the function */
#define CMDQ_STOP_FUNC_OPCODE_STOP_FUNC UINT32_C(0x82)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Query function command (16 bytes) */
struct cmdq_query_func {
uint8_t opcode;
/* Command opcode. */
/* Query the HW capabilities for the function. */
#define CMDQ_QUERY_FUNC_OPCODE_QUERY_FUNC UINT32_C(0x83)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Set function resources command (56 bytes) */
struct cmdq_set_func_resources {
uint8_t opcode;
/* Command opcode. */
/*
* Set the following resources for the function: - Max QP, CQ,
* MR+MW, SRQ per PF - Max QP, CQ, MR+MW, SRQ per VF
*/
#define CMDQ_SET_FUNC_RESOURCES_OPCODE_SET_FUNC_RESOURCES UINT32_C(0x84)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t number_of_qp;
/*
* Number of QPs. It is the responsibility of the host to first extend
* the existing PBL with new addresses to pages to handle the
* adjustment. Must be greater or equal to current.
*/
uint32_t number_of_mrw;
/*
* Number of MRWs. It is the responsibility of the host to first extend
* the existing PBL with new addresses to pages to handle the
* adjustment. Must be greater or equal to current.
*/
uint32_t number_of_srq;
/*
* Number of SRQs. It is the responsibility of the host to first extend
* the existing PBL with new addresses to pages to handle the
* adjustment. Must be greater or equal to current.
*/
uint32_t number_of_cq;
/*
* Number of CQs. It is the responsibility of the host to first extend
* the existing PBL with new addresses to pages to handle the
* adjustment. Must be greater or equal to current.
*/
uint32_t max_qp_per_vf;
/* Number of QPs per VF. */
uint32_t max_mrw_per_vf;
/* Number of MRWs per VF. */
uint32_t max_srq_per_vf;
/* Number of SRQs per VF. */
uint32_t max_cq_per_vf;
/* Number of CQs per VF. */
uint32_t max_gid_per_vf;
/* Number of GIDs per VF. */
uint32_t stat_ctx_id;
/* Statistics context index for this function. */
} __attribute__((packed));
/* Read hardware resource context command (24 bytes) */
struct cmdq_read_context {
uint8_t opcode;
/* Command opcode. */
/*
* Read the current state of any internal resource context. Can
* only be issued from a PF.
*/
#define CMDQ_READ_CONTEXT_OPCODE_READ_CONTEXT UINT32_C(0x85)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t type_xid;
/* Context type */
/* Context ID */
#define CMDQ_READ_CONTEXT_XID_MASK UINT32_C(0xffffff)
#define CMDQ_READ_CONTEXT_XID_SFT 0
/* Context type */
#define CMDQ_READ_CONTEXT_TYPE_MASK UINT32_C(0xff000000)
#define CMDQ_READ_CONTEXT_TYPE_SFT 24
/*
* Read QPC. The context (448 bytes) goes to resp_addr (as is,
* without a header), and resp_size should be set to 28 (448/16)
*/
#define CMDQ_READ_CONTEXT_TYPE_QPC (UINT32_C(0x0) << 24)
/*
* Read CQ. The context (64 bytes) goes to resp_addr (as is,
* without a header), and resp_size should be set to 4 (64/16)
*/
#define CMDQ_READ_CONTEXT_TYPE_CQ (UINT32_C(0x1) << 24)
/*
* Read MRW. The context (128 bytes) goes to resp_addr (as is,
* without a header), and resp_size should be set to 8 (128/16)
*/
#define CMDQ_READ_CONTEXT_TYPE_MRW (UINT32_C(0x2) << 24)
/*
* Read SRQ. The context (64 bytes) goes to resp_addr (as is,
* without a header), and resp_size should be set to 4 (64/16)
*/
#define CMDQ_READ_CONTEXT_TYPE_SRQ (UINT32_C(0x3) << 24)
uint32_t unused_0;
} __attribute__((packed));
/* Send a request from VF to pass a command to the PF. VF HSI is suspended until the PF returns the response (32 bytes) */
struct cmdq_vf_backchannel_request {
uint8_t opcode;
/* Command opcode. */
/*
* Send a request from VF to pass a command to the PF. VF HSI is
* suspended until the PF returns the response
*/
#define CMDQ_VF_BACKCHANNEL_REQUEST_OPCODE_VF_BACKCHANNEL_REQUEST UINT32_C(0x86)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t command_addr;
/* Address of command request structure in VF space */
uint16_t command_length;
/*
* Command request length (up to 4K). An optional address of the
* extended response buffer should be provided in the request
*/
uint16_t unused_0[3];
} __attribute__((packed));
/* Read VF memory (primarily to get the backchannel request blob). Can only be issued from a PF. (32 bytes) */
struct cmdq_read_vf_memory {
uint8_t opcode;
/* Command opcode. */
/*
* Read VF memory (primarily to get the backchannel request
* blob). Can only be issued from a PF.
*/
#define CMDQ_READ_VF_MEMORY_OPCODE_READ_VF_MEMORY UINT32_C(0x87)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t addr;
/* Address of memory in VF space to read */
uint16_t vf_id;
/* VF id, as provided in 0xC0 VF request notification */
uint16_t length;
/* Length to read, up to 4K */
uint32_t unused_0;
} __attribute__((packed));
/* Write VF memory (primarily to put the backchannel response blob), and reenable VF HSI (post a CAG completion to it). Can only be issued from a PF. (40 bytes) */
struct cmdq_complete_vf_request {
uint8_t opcode;
/* Command opcode. */
/*
* Write VF memory (primarily to put the backchannel response
* blob), and reenable VF HSI (post a CAG completion to it). Can
* only be issued from a PF.
*/
#define CMDQ_COMPLETE_VF_REQUEST_OPCODE_COMPLETE_VF_REQUEST UINT32_C(0x88)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint64_t addr;
/*
* Optional address of extended response in VF space to write. Length is
* in resp_size in 16 byte units.
*/
uint32_t vf_misc;
/* Completion misc field to VF CREQ */
uint16_t vf_id;
/* VF id, as provided in 0xC0 VF request notification */
uint16_t vf_cookie;
/* Completion cookie for the VF command, goes to VF CREQ */
uint8_t vf_status;
/* Completion status for the VF command, goes to VF CREQ */
uint8_t unused_0[7];
} __attribute__((packed));
/* Map TC to COS. Can only be issued from a PF (24 bytes) */
struct cmdq_map_tc_to_cos {
uint8_t opcode;
/* Command opcode. */
/* Map TC to COS. Can only be issued from a PF. */
#define CMDQ_MAP_TC_TO_COS_OPCODE_MAP_TC_TO_COS UINT32_C(0x8a)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint16_t cos0;
/* 1st COS index mapped to RoCE */
/* Don't change this COS. */
#define CMDQ_MAP_TC_TO_COS_COS0_NO_CHANGE UINT32_C(0xffff)
uint16_t cos1;
/* 2nd COS index mapped to RoCE */
/* Disable this COS. */
#define CMDQ_MAP_TC_TO_COS_COS1_DISABLE UINT32_C(0x8000)
/* Don't change this COS. */
#define CMDQ_MAP_TC_TO_COS_COS1_NO_CHANGE UINT32_C(0xffff)
uint32_t unused_0;
} __attribute__((packed));
/* Query version command (16 bytes) */
struct cmdq_query_version {
uint8_t opcode;
/* Command opcode. */
/* Query version. */
#define CMDQ_QUERY_VERSION_OPCODE_QUERY_VERSION UINT32_C(0x8b)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Modify congestion control command (56 bytes) */
struct cmdq_modify_roce_cc {
uint8_t opcode;
/* Command opcode. */
/* Modify congestion control. Can only be issued from a PF. */
#define CMDQ_MODIFY_ROCE_CC_OPCODE_MODIFY_ROCE_CC UINT32_C(0x8c)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
uint32_t modify_mask;
/* Modify mask signifies the field that is requesting the change. */
/* Enable change. */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_ENABLE_CC UINT32_C(0x1)
/* Running average weight change. */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_G UINT32_C(0x2)
/* Number of phases in Fast Recovery. */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_NUMPHASEPERSTATE UINT32_C(0x4)
/* The starting value of rate change. */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_INIT_CR UINT32_C(0x8)
/* The starting value of target rate change. */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_INIT_TR UINT32_C(0x10)
/* IP TOS ECN change */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_TOS_ECN UINT32_C(0x20)
/* IP TOS DSCP change */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_TOS_DSCP UINT32_C(0x40)
/* Alternate IP TOS ECN change */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_ALT_VLAN_PCP UINT32_C(0x80)
/* Alternate IP TOS DSCP change */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_ALT_TOS_DSCP UINT32_C(0x100)
/* Round trip time in units of usecs */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_RTT UINT32_C(0x200)
/* 0 for DCTCP , 1 for TCP */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_CC_MODE UINT32_C(0x400)
/* The value used as CP when cc_mode is 1(TCP) */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_TCP_CP UINT32_C(0x800)
/* Specifies the RoCE Tx Queue ( o to 3) to use for sending CNP packets */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_TX_QUEUE UINT32_C(0x1000)
/* Inactivity time after which QP CC parameters are initialized */
#define CMDQ_MODIFY_ROCE_CC_MODIFY_MASK_INACTIVITY_CP UINT32_C(0x2000)
uint8_t enable_cc;
/* rsvd1 is 7 b */
/* Enable. */
#define CMDQ_MODIFY_ROCE_CC_ENABLE_CC UINT32_C(0x1)
/* rsvd1 is 7 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD1_MASK UINT32_C(0xfe)
#define CMDQ_MODIFY_ROCE_CC_RSVD1_SFT 1
uint8_t g;
/* rsvd2 is 5 b */
/* Congestion Probability averaging factor. */
#define CMDQ_MODIFY_ROCE_CC_G_MASK UINT32_C(0x7)
#define CMDQ_MODIFY_ROCE_CC_G_SFT 0
/* rsvd2 is 5 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD2_MASK UINT32_C(0xf8)
#define CMDQ_MODIFY_ROCE_CC_RSVD2_SFT 3
uint8_t num_phases_per_state;
/* Number of phases in Fast Recovery. */
uint8_t rsvd9;
/* rsvd9 is 8 b */
uint16_t init_cr;
/* The starting value of rate. */
uint16_t init_tr;
/* The starting value of target rate. */
uint8_t tos_dscp_tos_ecn;
/* IP TOS DSCP. */
/* IP TOS ECN. Valid values are 1 or 2 when ECN is enabled. */
#define CMDQ_MODIFY_ROCE_CC_TOS_ECN_MASK UINT32_C(0x3)
#define CMDQ_MODIFY_ROCE_CC_TOS_ECN_SFT 0
/* IP TOS DSCP. */
#define CMDQ_MODIFY_ROCE_CC_TOS_DSCP_MASK UINT32_C(0xfc)
#define CMDQ_MODIFY_ROCE_CC_TOS_DSCP_SFT 2
uint8_t alt_vlan_pcp;
/* rsvd3 is 5 b */
/* Alternate vlan pcp value for CNP packets. */
#define CMDQ_MODIFY_ROCE_CC_ALT_VLAN_PCP_MASK UINT32_C(0x7)
#define CMDQ_MODIFY_ROCE_CC_ALT_VLAN_PCP_SFT 0
/* rsvd3 is 5 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD3_MASK UINT32_C(0xf8)
#define CMDQ_MODIFY_ROCE_CC_RSVD3_SFT 3
uint16_t alt_tos_dscp;
/* rsvd4 is 10 b */
/* Alternate IP TOS DSCP. */
#define CMDQ_MODIFY_ROCE_CC_ALT_TOS_DSCP_MASK UINT32_C(0x3f)
#define CMDQ_MODIFY_ROCE_CC_ALT_TOS_DSCP_SFT 0
/* rsvd4 is 10 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD4_MASK UINT32_C(0xffc0)
#define CMDQ_MODIFY_ROCE_CC_RSVD4_SFT 6
uint16_t rtt;
/* rsvd5 is 2 b */
/* Round trip time in units of usecs */
#define CMDQ_MODIFY_ROCE_CC_RTT_MASK UINT32_C(0x3fff)
#define CMDQ_MODIFY_ROCE_CC_RTT_SFT 0
/* rsvd5 is 2 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD5_MASK UINT32_C(0xc000)
#define CMDQ_MODIFY_ROCE_CC_RSVD5_SFT 14
uint16_t tcp_cp;
/* rsvd6 is 6 b */
/* The value used as CP when cc_mode is 1(TCP) */
#define CMDQ_MODIFY_ROCE_CC_TCP_CP_MASK UINT32_C(0x3ff)
#define CMDQ_MODIFY_ROCE_CC_TCP_CP_SFT 0
/* rsvd6 is 6 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD6_MASK UINT32_C(0xfc00)
#define CMDQ_MODIFY_ROCE_CC_RSVD6_SFT 10
uint8_t cc_mode;
/* rsvd7 is 7 b */
/* 0 for DCTCP , 1 for TCP */
#define CMDQ_MODIFY_ROCE_CC_CC_MODE UINT32_C(0x1)
/* rsvd7 is 7 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD7_MASK UINT32_C(0xfe)
#define CMDQ_MODIFY_ROCE_CC_RSVD7_SFT 1
uint8_t tx_queue;
/* rsvd8 is 6 b */
/* Specifies the RoCE Tx Queue ( o to 3) to use for sending CNP packets */
#define CMDQ_MODIFY_ROCE_CC_TX_QUEUE_MASK UINT32_C(0x3)
#define CMDQ_MODIFY_ROCE_CC_TX_QUEUE_SFT 0
/* rsvd8 is 6 b */
#define CMDQ_MODIFY_ROCE_CC_RSVD8_MASK UINT32_C(0xfc)
#define CMDQ_MODIFY_ROCE_CC_RSVD8_SFT 2
uint16_t inactivity_th;
/* Inactivity time after which QP CC parameters are initialized */
uint64_t reserved64;
uint64_t reserved64_1;
} __attribute__((packed));
/* Query congestion control command (16 bytes) */
struct cmdq_query_roce_cc {
uint8_t opcode;
/* Command opcode. */
/* Query congestion control. */
#define CMDQ_QUERY_ROCE_CC_OPCODE_QUERY_ROCE_CC UINT32_C(0x8d)
uint8_t cmd_size;
/* Size of the command in 16-byte units. */
uint16_t flags;
/* Flags and attribs of the command. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t resp_addr;
/* Host address of the response. */
} __attribute__((packed));
/* Command-Response Event Queue (CREQ) Structures */
/* Description: This is an async event indicating error happened on a QP. */
/* Base CREQ Record (16 bytes) */
struct creq_base {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_BASE_TYPE_MASK UINT32_C(0x3f)
#define CREQ_BASE_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_BASE_TYPE_QP_EVENT UINT32_C(0x38)
/* Function Async Notification */
#define CREQ_BASE_TYPE_FUNC_EVENT UINT32_C(0x3a)
#define CREQ_BASE_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_BASE_RESERVED2_SFT 6
uint8_t reserved56[7];
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_BASE_V UINT32_C(0x1)
#define CREQ_BASE_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_BASE_RESERVED7_SFT 1
uint8_t event;
/* This is the modifier on to the type field. */
uint16_t reserved48[3];
} __attribute__((packed));
/* RoCE Function Async Event Notification (16 bytes) */
struct creq_func_event {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_FUNC_EVENT_TYPE_MASK UINT32_C(0x3f)
#define CREQ_FUNC_EVENT_TYPE_SFT 0
/* Function Async Notification */
#define CREQ_FUNC_EVENT_TYPE_FUNC_EVENT UINT32_C(0x3a)
#define CREQ_FUNC_EVENT_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_FUNC_EVENT_RESERVED2_SFT 6
uint8_t reserved56[7];
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_FUNC_EVENT_V UINT32_C(0x1)
#define CREQ_FUNC_EVENT_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_FUNC_EVENT_RESERVED7_SFT 1
uint8_t event;
/*
* This value defines what type of async event has occurred on the
* function.
*/
/*
* Invalid PBL or PCIE UR response occurred in SQ WQE or IRRQ
* read access.
*/
#define CREQ_FUNC_EVENT_EVENT_TX_WQE_ERROR UINT32_C(0x1)
/* Invalid PBL or PCIE UR response occurred during data read access. */
#define CREQ_FUNC_EVENT_EVENT_TX_DATA_ERROR UINT32_C(0x2)
/*
* Invalid PBL or PCIE UR response occurred in RQ/SRQ WQE or
* ORRQ read access.
*/
#define CREQ_FUNC_EVENT_EVENT_RX_WQE_ERROR UINT32_C(0x3)
/* Invalid PBL occurred during data write access. */
#define CREQ_FUNC_EVENT_EVENT_RX_DATA_ERROR UINT32_C(0x4)
/* Invalid PBL occurred during CQ write access. */
#define CREQ_FUNC_EVENT_EVENT_CQ_ERROR UINT32_C(0x5)
/* Invalid PBL or PCIE UR response occurred in TQM read access. */
#define CREQ_FUNC_EVENT_EVENT_TQM_ERROR UINT32_C(0x6)
/* PCIE UR response occurred in CFC read access. */
#define CREQ_FUNC_EVENT_EVENT_CFCQ_ERROR UINT32_C(0x7)
/* PCIE UR response occurred in CFC read access. */
#define CREQ_FUNC_EVENT_EVENT_CFCS_ERROR UINT32_C(0x8)
/* PCIE UR response occurred in CFC read access. */
#define CREQ_FUNC_EVENT_EVENT_CFCC_ERROR UINT32_C(0x9)
/* PCIE UR response occurred in CFC read access. */
#define CREQ_FUNC_EVENT_EVENT_CFCM_ERROR UINT32_C(0xa)
/* Invalid PBL or PCIE UR response occurred on timer read access. */
#define CREQ_FUNC_EVENT_EVENT_TIM_ERROR UINT32_C(0xb)
/* A VF sent a backchannel command request */
#define CREQ_FUNC_EVENT_EVENT_VF_COMM_REQUEST UINT32_C(0x80)
/*
* Communication resource (QPC, CQ, SRQ, MRW) exhausted, and
* resource array extension is enabled
*/
#define CREQ_FUNC_EVENT_EVENT_RESOURCE_EXHAUSTED UINT32_C(0x81)
uint16_t reserved48[3];
} __attribute__((packed));
/* RoCE Slowpath Command Completion (16 bytes) */
struct creq_qp_event {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QP_EVENT_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QP_EVENT_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QP_EVENT_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QP_EVENT_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QP_EVENT_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
/* Success. */
#define CREQ_QP_EVENT_STATUS_SUCCESS UINT32_C(0x0)
/* Fail. */
#define CREQ_QP_EVENT_STATUS_FAIL UINT32_C(0x1)
/* Resources. */
#define CREQ_QP_EVENT_STATUS_RESOURCES UINT32_C(0x2)
/* Invalid command. */
#define CREQ_QP_EVENT_STATUS_INVALID_CMD UINT32_C(0x3)
/* Not implemented. */
#define CREQ_QP_EVENT_STATUS_NOT_IMPLEMENTED UINT32_C(0x4)
/* Invalid parameter. */
#define CREQ_QP_EVENT_STATUS_INVALID_PARAMETER UINT32_C(0x5)
/* Hardware operation failed. */
#define CREQ_QP_EVENT_STATUS_HARDWARE_ERROR UINT32_C(0x6)
/* Firmware operation failed due to internal error. */
#define CREQ_QP_EVENT_STATUS_INTERNAL_ERROR UINT32_C(0x7)
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QP_EVENT_V UINT32_C(0x1)
#define CREQ_QP_EVENT_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QP_EVENT_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create QP command response. */
#define CREQ_QP_EVENT_EVENT_CREATE_QP UINT32_C(0x1)
/* Destroy QP command response. */
#define CREQ_QP_EVENT_EVENT_DESTROY_QP UINT32_C(0x2)
/* Modify QP command response. */
#define CREQ_QP_EVENT_EVENT_MODIFY_QP UINT32_C(0x3)
/* Query QP command response. */
#define CREQ_QP_EVENT_EVENT_QUERY_QP UINT32_C(0x4)
/* Create SRQ command response. */
#define CREQ_QP_EVENT_EVENT_CREATE_SRQ UINT32_C(0x5)
/* Destroy SRQ command response. */
#define CREQ_QP_EVENT_EVENT_DESTROY_SRQ UINT32_C(0x6)
/* Query SRQ command response. */
#define CREQ_QP_EVENT_EVENT_QUERY_SRQ UINT32_C(0x8)
/* Create CQ command response. */
#define CREQ_QP_EVENT_EVENT_CREATE_CQ UINT32_C(0x9)
/* Destroy CQ command response. */
#define CREQ_QP_EVENT_EVENT_DESTROY_CQ UINT32_C(0xa)
/* Resize CQ command response. */
#define CREQ_QP_EVENT_EVENT_RESIZE_CQ UINT32_C(0xc)
/* Allocate MRW command response. */
#define CREQ_QP_EVENT_EVENT_ALLOCATE_MRW UINT32_C(0xd)
/* De-allocate key command response. */
#define CREQ_QP_EVENT_EVENT_DEALLOCATE_KEY UINT32_C(0xe)
/* Register MR command response. */
#define CREQ_QP_EVENT_EVENT_REGISTER_MR UINT32_C(0xf)
/* Deregister MR command response. */
#define CREQ_QP_EVENT_EVENT_DEREGISTER_MR UINT32_C(0x10)
/* Add GID command response. */
#define CREQ_QP_EVENT_EVENT_ADD_GID UINT32_C(0x11)
/* Delete GID command response. */
#define CREQ_QP_EVENT_EVENT_DELETE_GID UINT32_C(0x12)
/* Modify GID command response. */
#define CREQ_QP_EVENT_EVENT_MODIFY_GID UINT32_C(0x17)
/* Query GID command response. */
#define CREQ_QP_EVENT_EVENT_QUERY_GID UINT32_C(0x18)
/* Create QP1 command response. */
#define CREQ_QP_EVENT_EVENT_CREATE_QP1 UINT32_C(0x13)
/* Destroy QP1 command response. */
#define CREQ_QP_EVENT_EVENT_DESTROY_QP1 UINT32_C(0x14)
/* Create AH command response. */
#define CREQ_QP_EVENT_EVENT_CREATE_AH UINT32_C(0x15)
/* Destroy AH command response. */
#define CREQ_QP_EVENT_EVENT_DESTROY_AH UINT32_C(0x16)
/* Initialize firmware command response. */
#define CREQ_QP_EVENT_EVENT_INITIALIZE_FW UINT32_C(0x80)
/* De-initialize firmware command response. */
#define CREQ_QP_EVENT_EVENT_DEINITIALIZE_FW UINT32_C(0x81)
/* Stop PF command response. */
#define CREQ_QP_EVENT_EVENT_STOP_FUNC UINT32_C(0x82)
/* Query info PF command response. */
#define CREQ_QP_EVENT_EVENT_QUERY_FUNC UINT32_C(0x83)
/* Set function resources command response. */
#define CREQ_QP_EVENT_EVENT_SET_FUNC_RESOURCES UINT32_C(0x84)
/* Map TC to COS response. */
#define CREQ_QP_EVENT_EVENT_MAP_TC_TO_COS UINT32_C(0x8a)
/* Query firmware and interface version response. */
#define CREQ_QP_EVENT_EVENT_QUERY_VERSION UINT32_C(0x8b)
/* Modify congestion control response. */
#define CREQ_QP_EVENT_EVENT_MODIFY_ROCE_CC UINT32_C(0x8c)
/* Query congestion control response. */
#define CREQ_QP_EVENT_EVENT_QUERY_ROCE_CC UINT32_C(0x8d)
/* QP error notification event. */
#define CREQ_QP_EVENT_EVENT_QP_ERROR_NOTIFICATION UINT32_C(0xc0)
uint16_t reserved48[3];
} __attribute__((packed));
/* Create QP command response (16 bytes) */
struct creq_create_qp_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_CREATE_QP_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_CREATE_QP_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_CREATE_QP_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_CREATE_QP_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_CREATE_QP_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* QP context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_CREATE_QP_RESP_V UINT32_C(0x1)
#define CREQ_CREATE_QP_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_CREATE_QP_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create QP command response. */
#define CREQ_CREATE_QP_RESP_EVENT_CREATE_QP UINT32_C(0x1)
uint16_t reserved48[3];
} __attribute__((packed));
/* Destroy QP command response (16 bytes) */
struct creq_destroy_qp_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DESTROY_QP_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DESTROY_QP_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DESTROY_QP_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DESTROY_QP_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DESTROY_QP_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* QP context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DESTROY_QP_RESP_V UINT32_C(0x1)
#define CREQ_DESTROY_QP_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DESTROY_QP_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Destroy QP command response. */
#define CREQ_DESTROY_QP_RESP_EVENT_DESTROY_QP UINT32_C(0x2)
uint16_t reserved48[3];
} __attribute__((packed));
/* Modify QP command response (16 bytes) */
struct creq_modify_qp_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_MODIFY_QP_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_MODIFY_QP_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_MODIFY_QP_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_MODIFY_QP_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_MODIFY_QP_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* QP context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_MODIFY_QP_RESP_V UINT32_C(0x1)
#define CREQ_MODIFY_QP_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_MODIFY_QP_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Modify QP command response. */
#define CREQ_MODIFY_QP_RESP_EVENT_MODIFY_QP UINT32_C(0x3)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query QP command response (16 bytes) */
struct creq_query_qp_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_QP_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_QP_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_QP_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_QP_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_QP_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t size;
/* Side buffer size in 16-byte units */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_QP_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_QP_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_QP_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query QP command response. */
#define CREQ_QUERY_QP_RESP_EVENT_QUERY_QP UINT32_C(0x4)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query QP command response side buffer structure (104 bytes) */
struct creq_query_qp_resp_sb {
uint8_t opcode;
/* Command opcode. */
/* Query QP command response. */
#define CREQ_QUERY_QP_RESP_SB_OPCODE_QUERY_QP UINT32_C(0x4)
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint16_t flags;
/* Flags and attribs of the command. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint32_t xid;
/* QP context id */
uint8_t en_sqd_async_notify_state;
/* Enable congestion control. */
/* QP state */
#define CREQ_QUERY_QP_RESP_SB_STATE_MASK UINT32_C(0xf)
#define CREQ_QUERY_QP_RESP_SB_STATE_SFT 0
/* Reset. */
#define CREQ_QUERY_QP_RESP_SB_STATE_RESET UINT32_C(0x0)
/* Init. */
#define CREQ_QUERY_QP_RESP_SB_STATE_INIT UINT32_C(0x1)
/* Ready To Receive. */
#define CREQ_QUERY_QP_RESP_SB_STATE_RTR UINT32_C(0x2)
/* Ready To Send. */
#define CREQ_QUERY_QP_RESP_SB_STATE_RTS UINT32_C(0x3)
/* SQ Drain. */
#define CREQ_QUERY_QP_RESP_SB_STATE_SQD UINT32_C(0x4)
/* SQ Error. */
#define CREQ_QUERY_QP_RESP_SB_STATE_SQE UINT32_C(0x5)
/* Error. */
#define CREQ_QUERY_QP_RESP_SB_STATE_ERR UINT32_C(0x6)
/* SQ drain asynchronous notification. */
#define CREQ_QUERY_QP_RESP_SB_EN_SQD_ASYNC_NOTIFY UINT32_C(0x10)
/* Enable congestion control. */
uint8_t access;
/* Access flags. */
/* Local write access. */
#define CREQ_QUERY_QP_RESP_SB_ACCESS_LOCAL_WRITE UINT32_C(0x1)
/* Remote write access. */
#define CREQ_QUERY_QP_RESP_SB_ACCESS_REMOTE_WRITE UINT32_C(0x2)
/* Remote read access. */
#define CREQ_QUERY_QP_RESP_SB_ACCESS_REMOTE_READ UINT32_C(0x4)
/* Remote atomic access. */
#define CREQ_QUERY_QP_RESP_SB_ACCESS_REMOTE_ATOMIC UINT32_C(0x8)
uint16_t pkey;
/* P_KEY index. */
uint32_t qkey;
/* Q_KEY. */
uint32_t reserved32;
uint32_t dgid[4];
/* Destination GID. */
uint32_t flow_label;
/* Flow label. */
uint16_t sgid_index;
/* Source GID index. */
uint8_t hop_limit;
/* Hop limit. */
uint8_t traffic_class;
/* Traffic class. */
uint16_t dest_mac[3];
/* Destination MAC address. */
uint16_t path_mtu_dest_vlan_id;
/* Path MTU. */
/* Destination VLAN ID. */
#define CREQ_QUERY_QP_RESP_SB_DEST_VLAN_ID_MASK UINT32_C(0xfff)
#define CREQ_QUERY_QP_RESP_SB_DEST_VLAN_ID_SFT 0
/* Path MTU. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MASK UINT32_C(0xf000)
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_SFT 12
/* 256. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_256 (UINT32_C(0x0) << 12)
/* 512. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_512 (UINT32_C(0x1) << 12)
/* 1024. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_1024 (UINT32_C(0x2) << 12)
/* 2048. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_2048 (UINT32_C(0x3) << 12)
/* 4096. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_4096 (UINT32_C(0x4) << 12)
/* 8192. */
#define CREQ_QUERY_QP_RESP_SB_PATH_MTU_MTU_8192 (UINT32_C(0x5) << 12)
uint8_t timeout;
/* Timeout value for SWQEs. */
uint8_t retry_cnt;
/* Max retry count for WQEs. */
uint8_t rnr_retry;
/* Max RNR retry count for WQEs. */
uint8_t min_rnr_timer;
/* Min RNR timer that the QP will report to the remote. */
uint32_t rq_psn;
/* RQ start packet sequence number. */
uint32_t sq_psn;
/* SQ start packet sequence number. */
uint8_t max_rd_atomic;
/* Max outstanding RDMA read atomic. */
uint8_t max_dest_rd_atomic;
/* Max destination outstanding RDMA read atomic. */
uint8_t tos_dscp_tos_ecn;
/* IP TOS DSCP. */
/* IP TOS ECN. */
#define CREQ_QUERY_QP_RESP_SB_TOS_ECN_MASK UINT32_C(0x3)
#define CREQ_QUERY_QP_RESP_SB_TOS_ECN_SFT 0
/* IP TOS DSCP. */
#define CREQ_QUERY_QP_RESP_SB_TOS_DSCP_MASK UINT32_C(0xfc)
#define CREQ_QUERY_QP_RESP_SB_TOS_DSCP_SFT 2
uint8_t enable_cc;
/* enable_cc is 1 b */
#define CREQ_QUERY_QP_RESP_SB_ENABLE_CC UINT32_C(0x1)
#define CREQ_QUERY_QP_RESP_SB_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_QP_RESP_SB_RESERVED7_SFT 1
uint32_t sq_size;
/* Max send WQE. */
uint32_t rq_size;
/* Max recv WQE. */
uint16_t sq_sge;
/* Max send SGEs per SWQE. */
uint16_t rq_sge;
/* Max recv SGEs per RWQE (NOT SUPPORTED BY HARDWARE). */
uint32_t max_inline_data;
/* Max inline data length (upto 120 bytes). */
uint32_t dest_qp_id;
/* Destination QP id. */
uint32_t unused_1;
uint16_t src_mac[3];
/* Source MAC. */
uint16_t vlan_pcp_vlan_dei_vlan_id;
/* VLAN PCP field - Priority Code Point. */
/* Source VLAN id. */
#define CREQ_QUERY_QP_RESP_SB_VLAN_ID_MASK UINT32_C(0xfff)
#define CREQ_QUERY_QP_RESP_SB_VLAN_ID_SFT 0
/* VLAN DEI field - Drop Eligibility Indicator. */
#define CREQ_QUERY_QP_RESP_SB_VLAN_DEI UINT32_C(0x1000)
/* VLAN PCP field - Priority Code Point. */
#define CREQ_QUERY_QP_RESP_SB_VLAN_PCP_MASK UINT32_C(0xe000)
#define CREQ_QUERY_QP_RESP_SB_VLAN_PCP_SFT 13
} __attribute__((packed));
/* Create SRQ command response (16 bytes) */
struct creq_create_srq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_CREATE_SRQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_CREATE_SRQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_CREATE_SRQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_CREATE_SRQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_CREATE_SRQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* SRQ context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_CREATE_SRQ_RESP_V UINT32_C(0x1)
#define CREQ_CREATE_SRQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_CREATE_SRQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create SRQ command response. */
#define CREQ_CREATE_SRQ_RESP_EVENT_CREATE_SRQ UINT32_C(0x5)
uint16_t reserved48[3];
} __attribute__((packed));
/* Destroy SRQ command response (16 bytes) */
struct creq_destroy_srq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DESTROY_SRQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DESTROY_SRQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DESTROY_SRQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DESTROY_SRQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DESTROY_SRQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* SRQ context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DESTROY_SRQ_RESP_V UINT32_C(0x1)
#define CREQ_DESTROY_SRQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DESTROY_SRQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Destroy SRQ command response. */
#define CREQ_DESTROY_SRQ_RESP_EVENT_DESTROY_SRQ UINT32_C(0x6)
uint16_t enable_for_arm[3];
/* Set to 1 if this SRQ is allowed to be armed for threshold async event */
#define CREQ_DESTROY_SRQ_RESP_ENABLE_FOR_ARM_MASK UINT32_C(0x30000)
#define CREQ_DESTROY_SRQ_RESP_ENABLE_FOR_ARM_SFT 16
#define CREQ_DESTROY_SRQ_RESP_RESERVED46_MASK UINT32_C(0xfffc0000)
#define CREQ_DESTROY_SRQ_RESP_RESERVED46_SFT 18
} __attribute__((packed));
/* Query SRQ command response (16 bytes) */
struct creq_query_srq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_SRQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_SRQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_SRQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_SRQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_SRQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t size;
/* Side buffer size in 16-byte units */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_SRQ_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_SRQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_SRQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query SRQ command response. */
#define CREQ_QUERY_SRQ_RESP_EVENT_QUERY_SRQ UINT32_C(0x8)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query SRQ command response side buffer structure (24 bytes) */
struct creq_query_srq_resp_sb {
uint8_t opcode;
/* Command opcode. */
/* Query SRQ command response. */
#define CREQ_QUERY_SRQ_RESP_SB_OPCODE_QUERY_SRQ UINT32_C(0x8)
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint16_t flags;
/* Flags and attribs of the command. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint32_t xid;
/* SRQ context id */
uint16_t srq_limit;
/* Watermark value to generate a SRQ limit event. */
uint16_t reserved16;
uint32_t data[4];
/* data is 128 b */
} __attribute__((packed));
/* Create CQ command Response (16 bytes) */
struct creq_create_cq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_CREATE_CQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_CREATE_CQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_CREATE_CQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_CREATE_CQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_CREATE_CQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* CQ context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_CREATE_CQ_RESP_V UINT32_C(0x1)
#define CREQ_CREATE_CQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_CREATE_CQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create CQ command response. */
#define CREQ_CREATE_CQ_RESP_EVENT_CREATE_CQ UINT32_C(0x9)
uint16_t reserved48[3];
} __attribute__((packed));
/* Destroy CQ command response (16 bytes) */
struct creq_destroy_cq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DESTROY_CQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DESTROY_CQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DESTROY_CQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DESTROY_CQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DESTROY_CQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* CQ context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DESTROY_CQ_RESP_V UINT32_C(0x1)
#define CREQ_DESTROY_CQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DESTROY_CQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Destroy CQ command response. */
#define CREQ_DESTROY_CQ_RESP_EVENT_DESTROY_CQ UINT32_C(0xa)
uint16_t cq_arm_lvl;
/*
* CQ ARM Level: 0 ? Not Armed 1 ? Arm SE Only, Generate CNQE only for
* incoming Solicted Events 2 ? Arm all, Generate CNQE for Rx and Tx
*/
#define CREQ_DESTROY_CQ_RESP_CQ_ARM_LVL_MASK UINT32_C(0x3)
#define CREQ_DESTROY_CQ_RESP_CQ_ARM_LVL_SFT 0
#define CREQ_DESTROY_CQ_RESP_RESERVED14_MASK UINT32_C(0xfffc)
#define CREQ_DESTROY_CQ_RESP_RESERVED14_SFT 2
uint16_t total_cnq_events;
/*
* The total number of CNQ events for the CQ, incremented on each CNQ
* event for the CQ (including firmware-generated CQ error
* notification).
*/
uint16_t reserved16;
} __attribute__((packed));
/* Resize CQ command response (16 bytes) */
struct creq_resize_cq_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_RESIZE_CQ_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_RESIZE_CQ_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_RESIZE_CQ_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_RESIZE_CQ_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_RESIZE_CQ_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* CQ context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_RESIZE_CQ_RESP_V UINT32_C(0x1)
#define CREQ_RESIZE_CQ_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_RESIZE_CQ_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Resize CQ command response. */
#define CREQ_RESIZE_CQ_RESP_EVENT_RESIZE_CQ UINT32_C(0xc)
uint16_t reserved48[3];
} __attribute__((packed));
/* Allocate MRW command response (16 bytes) */
struct creq_allocate_mrw_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_ALLOCATE_MRW_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_ALLOCATE_MRW_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_ALLOCATE_MRW_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_ALLOCATE_MRW_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_ALLOCATE_MRW_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* L_KEY for MR, R_KEY for MW */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_ALLOCATE_MRW_RESP_V UINT32_C(0x1)
#define CREQ_ALLOCATE_MRW_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_ALLOCATE_MRW_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Allocate MRW command response. */
#define CREQ_ALLOCATE_MRW_RESP_EVENT_ALLOCATE_MRW UINT32_C(0xd)
uint16_t reserved48[3];
} __attribute__((packed));
/* De-allocate key command response (16 bytes) */
struct creq_deallocate_key_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DEALLOCATE_KEY_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DEALLOCATE_KEY_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DEALLOCATE_KEY_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DEALLOCATE_KEY_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DEALLOCATE_KEY_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* L_KEY for MR, R_KEY for MW */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DEALLOCATE_KEY_RESP_V UINT32_C(0x1)
#define CREQ_DEALLOCATE_KEY_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DEALLOCATE_KEY_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* De-allocate key command response. */
#define CREQ_DEALLOCATE_KEY_RESP_EVENT_DEALLOCATE_KEY UINT32_C(0xe)
uint16_t reserved16;
uint32_t bound_window_info;
/*
* This is advisory data to facilitate eventual descruction of lingering
* memory regions in Windows. For memory window, it contains non-zero
* HWID of a region this window was bound to (without the 8-bit key
* portion). The host may check if the region is lingering in destroyed
* state and try to destroy it now. For memory region, if deallocation
* fails because there are windows bound to this region, this field will
* contain approximate number of those windows. This number is read from
* the context right before the deregistration is attempted and can
* potentially be slightly different from the current number.
*/
} __attribute__((packed));
/* Register MR command response (16 bytes) */
struct creq_register_mr_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_REGISTER_MR_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_REGISTER_MR_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_REGISTER_MR_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_REGISTER_MR_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_REGISTER_MR_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* L_KEY */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_REGISTER_MR_RESP_V UINT32_C(0x1)
#define CREQ_REGISTER_MR_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_REGISTER_MR_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Register MR command response. */
#define CREQ_REGISTER_MR_RESP_EVENT_REGISTER_MR UINT32_C(0xf)
uint16_t reserved48[3];
} __attribute__((packed));
/* Deregister MR command response (16 bytes) */
struct creq_deregister_mr_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DEREGISTER_MR_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DEREGISTER_MR_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DEREGISTER_MR_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DEREGISTER_MR_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DEREGISTER_MR_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* L_KEY */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DEREGISTER_MR_RESP_V UINT32_C(0x1)
#define CREQ_DEREGISTER_MR_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DEREGISTER_MR_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Deregister MR command response. */
#define CREQ_DEREGISTER_MR_RESP_EVENT_DEREGISTER_MR UINT32_C(0x10)
uint16_t reserved16;
uint32_t bound_windows;
/*
* If deregister fails because there are windows bound to this region,
* this field will contain approximate number of those windows. This
* number is read from the context right before the deregistration is
* attempted and can potentially be slightly different from the current
* number.
*/
} __attribute__((packed));
/* Add GID command response (16 bytes) */
struct creq_add_gid_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_ADD_GID_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_ADD_GID_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_ADD_GID_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_ADD_GID_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_ADD_GID_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* GID index */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_ADD_GID_RESP_V UINT32_C(0x1)
#define CREQ_ADD_GID_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_ADD_GID_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Add GID command response. */
#define CREQ_ADD_GID_RESP_EVENT_ADD_GID UINT32_C(0x11)
uint16_t reserved48[3];
} __attribute__((packed));
/* Delete GID command response (16 bytes) */
struct creq_delete_gid_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DELETE_GID_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DELETE_GID_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DELETE_GID_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DELETE_GID_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DELETE_GID_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* GID index */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DELETE_GID_RESP_V UINT32_C(0x1)
#define CREQ_DELETE_GID_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DELETE_GID_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Delete GID command response. */
#define CREQ_DELETE_GID_RESP_EVENT_DELETE_GID UINT32_C(0x12)
uint16_t reserved48[3];
} __attribute__((packed));
/* Modify GID command response (16 bytes) */
struct creq_modify_gid_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_MODIFY_GID_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_MODIFY_GID_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_MODIFY_GID_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_MODIFY_GID_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_MODIFY_GID_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* GID index */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_MODIFY_GID_RESP_V UINT32_C(0x1)
#define CREQ_MODIFY_GID_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_MODIFY_GID_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Add GID command response. */
#define CREQ_MODIFY_GID_RESP_EVENT_ADD_GID UINT32_C(0x11)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query GID command response (16 bytes) */
struct creq_query_gid_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_GID_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_GID_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_GID_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_GID_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_GID_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t size;
/* Side buffer size in 16-byte units */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_GID_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_GID_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_GID_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query GID command response. */
#define CREQ_QUERY_GID_RESP_EVENT_QUERY_GID UINT32_C(0x18)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query GID command response side buffer structure (40 bytes) */
struct creq_query_gid_resp_sb {
uint8_t opcode;
/* Command opcode. */
/* Query GID command response. */
#define CREQ_QUERY_GID_RESP_SB_OPCODE_QUERY_GID UINT32_C(0x18)
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint16_t flags;
/* Flags and attribs of the command. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint32_t gid[4];
/* GID */
uint16_t src_mac[3];
/* Source MAC. */
uint16_t vlan;
/* flags. */
/* Source VLAN id. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_VLAN_ID_MASK UINT32_C(0xfff)
#define CREQ_QUERY_GID_RESP_SB_VLAN_VLAN_ID_SFT 0
/* This set of bits select the TPID of the VLAN Tag. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_MASK UINT32_C(0x7000)
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_SFT 12
/* TPID = 0x88A8. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_88A8 (UINT32_C(0x0) << 12)
/* TPID = 0x8100. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_8100 (UINT32_C(0x1) << 12)
/* TPID = 0x9100. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_9100 (UINT32_C(0x2) << 12)
/* TPID = 0x9200. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_9200 (UINT32_C(0x3) << 12)
/* TPID = 0x9300. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_9300 (UINT32_C(0x4) << 12)
/* TPID = Configurable 1. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_CFG1 (UINT32_C(0x5) << 12)
/* TPID = Configurable 2. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_CFG2 (UINT32_C(0x6) << 12)
/* TPID = Configurable 3. */
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_CFG3 (UINT32_C(0x7) << 12)
#define CREQ_QUERY_GID_RESP_SB_VLAN_TPID_LAST CREQ_QUERY_GID_RESP_SB_VLAN_TPID_TPID_CFG3
/*
* Setting this bit to 1 enables insertion of a VLAN Tag to a RoCE
* header.
*/
#define CREQ_QUERY_GID_RESP_SB_VLAN_VLAN_EN UINT32_C(0x8000)
uint16_t ipid;
/* Identifier field in the IP header. */
uint16_t gid_index;
/* GID index */
uint32_t unused_0;
} __attribute__((packed));
/* Create QP1 command response (16 bytes) */
struct creq_create_qp1_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_CREATE_QP1_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_CREATE_QP1_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_CREATE_QP1_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_CREATE_QP1_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_CREATE_QP1_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* QP1 context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_CREATE_QP1_RESP_V UINT32_C(0x1)
#define CREQ_CREATE_QP1_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_CREATE_QP1_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create QP1 command response. */
#define CREQ_CREATE_QP1_RESP_EVENT_CREATE_QP1 UINT32_C(0x13)
uint16_t reserved48[3];
} __attribute__((packed));
/* Destroy QP1 command response (16 bytes) */
struct creq_destroy_qp1_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DESTROY_QP1_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DESTROY_QP1_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DESTROY_QP1_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DESTROY_QP1_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DESTROY_QP1_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* QP1 context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DESTROY_QP1_RESP_V UINT32_C(0x1)
#define CREQ_DESTROY_QP1_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DESTROY_QP1_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Destroy QP1 command response. */
#define CREQ_DESTROY_QP1_RESP_EVENT_DESTROY_QP1 UINT32_C(0x14)
uint16_t reserved48[3];
} __attribute__((packed));
/* Create AH command response (16 bytes) */
struct creq_create_ah_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_CREATE_AH_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_CREATE_AH_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_CREATE_AH_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_CREATE_AH_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_CREATE_AH_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* AH context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_CREATE_AH_RESP_V UINT32_C(0x1)
#define CREQ_CREATE_AH_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_CREATE_AH_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Create AH command response. */
#define CREQ_CREATE_AH_RESP_EVENT_CREATE_AH UINT32_C(0x15)
uint16_t reserved48[3];
} __attribute__((packed));
/* Destroy AH command response (16 bytes) */
struct creq_destroy_ah_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DESTROY_AH_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DESTROY_AH_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DESTROY_AH_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DESTROY_AH_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DESTROY_AH_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t xid;
/* AH context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DESTROY_AH_RESP_V UINT32_C(0x1)
#define CREQ_DESTROY_AH_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DESTROY_AH_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Destroy AH command response. */
#define CREQ_DESTROY_AH_RESP_EVENT_DESTROY_AH UINT32_C(0x16)
uint16_t reserved48[3];
} __attribute__((packed));
/* Initialize Firmware command response (16 bytes) */
struct creq_initialize_fw_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_INITIALIZE_FW_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_INITIALIZE_FW_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_INITIALIZE_FW_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_INITIALIZE_FW_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_INITIALIZE_FW_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_INITIALIZE_FW_RESP_V UINT32_C(0x1)
#define CREQ_INITIALIZE_FW_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_INITIALIZE_FW_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Initialize firmware command response. */
#define CREQ_INITIALIZE_FW_RESP_EVENT_INITIALIZE_FW UINT32_C(0x80)
uint16_t reserved48[3];
} __attribute__((packed));
/* De-initialize Firmware command response (16 bytes) */
struct creq_deinitialize_fw_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_DEINITIALIZE_FW_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_DEINITIALIZE_FW_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_DEINITIALIZE_FW_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_DEINITIALIZE_FW_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_DEINITIALIZE_FW_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_DEINITIALIZE_FW_RESP_V UINT32_C(0x1)
#define CREQ_DEINITIALIZE_FW_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_DEINITIALIZE_FW_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* De-initialize firmware command response. */
#define CREQ_DEINITIALIZE_FW_RESP_EVENT_DEINITIALIZE_FW UINT32_C(0x81)
uint16_t reserved48[3];
} __attribute__((packed));
/* Stop function command response (16 bytes) */
struct creq_stop_func_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_STOP_FUNC_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_STOP_FUNC_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_STOP_FUNC_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_STOP_FUNC_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_STOP_FUNC_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_STOP_FUNC_RESP_V UINT32_C(0x1)
#define CREQ_STOP_FUNC_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_STOP_FUNC_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Stop PF command response. */
#define CREQ_STOP_FUNC_RESP_EVENT_STOP_FUNC UINT32_C(0x82)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query function command response (16 bytes) */
struct creq_query_func_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_FUNC_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_FUNC_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_FUNC_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_FUNC_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_FUNC_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t size;
/* Side buffer size in 16-byte units */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_FUNC_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_FUNC_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_FUNC_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query info PF command response. */
#define CREQ_QUERY_FUNC_RESP_EVENT_QUERY_FUNC UINT32_C(0x83)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query function command response side buffer structure (88 bytes) */
struct creq_query_func_resp_sb {
uint8_t opcode;
/* Command opcode. */
/* Query info PF command response. */
#define CREQ_QUERY_FUNC_RESP_SB_OPCODE_QUERY_FUNC UINT32_C(0x83)
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint16_t flags;
/* Flags and attribs of the command. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint64_t max_mr_size;
/* Max MR size supported. */
uint32_t max_qp;
/* Max QP supported. */
uint16_t max_qp_wr;
/* Max WQEs per QP. */
uint16_t dev_cap_flags;
/* Device capability flags. */
/* Allow QP resizing. */
#define CREQ_QUERY_FUNC_RESP_SB_DEV_CAP_FLAGS_RESIZE_QP UINT32_C(0x1)
uint32_t max_cq;
/* Max CQs supported. */
uint32_t max_cqe;
/* Max CQEs per CQ supported. */
uint32_t max_pd;
/* Max PDs supported. */
uint8_t max_sge;
/* Max SGEs per QP WQE supported. */
uint8_t max_srq_sge;
/* Max SGEs per SRQ WQE supported. */
uint8_t max_qp_rd_atom;
/* Max outstanding RDMA read & atomic supported. */
uint8_t max_qp_init_rd_atom;
/*
* Max outstanding RDMA read & atomic that can be sent from an
* initiator.
*/
uint32_t max_mr;
/* Max MRs supported. */
uint32_t max_mw;
/* Max MWs supported. */
uint32_t max_raw_eth_qp;
/* Max Raw Ethertype QPs supported. */
uint32_t max_ah;
/* Max AHs supported. */
uint32_t max_fmr;
/* Max FMRs supported. */
uint32_t max_srq_wr;
/* Max WQEs per SRQ supported. */
uint32_t max_pkeys;
/* Max PKEYs supported. */
uint32_t max_inline_data;
/* Max inline data supported. */
uint8_t max_map_per_fmr;
/* Max mappings per FMR supported. */
uint8_t l2_db_space_size;
/* L2 DB space size in pages. */
uint16_t max_srq;
/* Max SRQs supported. */
uint32_t max_gid;
/* Max GIDs supported. */
uint32_t tqm_alloc_reqs[12];
/*
* An array of 48 8-bit values to specify allocation multiplier for TQM
* host buffer regions. Each region occupies 16 MB of TQM PBL address
* space: 0x00000000, 0x01000000, 0x02000000, etc. The host needs to
* allocate (<Number of QPs>*multiplier, rounded up to page size) of
* physical memory for non-zero slots and map the pages to the
* corresponding 16MB regions. Typically there are total 3 non-zero
* values in this array, their values are 16, 16, 12. Cu+ will only
* populate up to index 11. SR may populate up to index 47.
*/
} __attribute__((packed));
/* Set resources command response (16 bytes) */
struct creq_set_func_resources_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_SET_FUNC_RESOURCES_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_SET_FUNC_RESOURCES_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_SET_FUNC_RESOURCES_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_SET_FUNC_RESOURCES_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_SET_FUNC_RESOURCES_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_SET_FUNC_RESOURCES_RESP_V UINT32_C(0x1)
#define CREQ_SET_FUNC_RESOURCES_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_SET_FUNC_RESOURCES_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Set function resources command response. */
#define CREQ_SET_FUNC_RESOURCES_RESP_EVENT_SET_FUNC_RESOURCES UINT32_C(0x84)
uint16_t reserved48[3];
} __attribute__((packed));
/* Map TC to COS response (16 bytes) */
struct creq_map_tc_to_cos_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_MAP_TC_TO_COS_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_MAP_TC_TO_COS_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_MAP_TC_TO_COS_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_MAP_TC_TO_COS_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_MAP_TC_TO_COS_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_MAP_TC_TO_COS_RESP_V UINT32_C(0x1)
#define CREQ_MAP_TC_TO_COS_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_MAP_TC_TO_COS_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Map TC to COS response. */
#define CREQ_MAP_TC_TO_COS_RESP_EVENT_MAP_TC_TO_COS UINT32_C(0x8a)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query version response (16 bytes) */
struct creq_query_version_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_VERSION_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_VERSION_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_VERSION_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_VERSION_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_VERSION_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint8_t fw_maj;
/* firmware major version */
uint8_t fw_minor;
/* firmware minor version */
uint8_t fw_bld;
/* firmware build version */
uint8_t fw_rsvd;
/* firmware reserved version */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_VERSION_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_VERSION_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_VERSION_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query firmware and interface version response. */
#define CREQ_QUERY_VERSION_RESP_EVENT_QUERY_VERSION UINT32_C(0x8b)
uint16_t reserved16;
uint8_t intf_maj;
/* interface major version */
uint8_t intf_minor;
/* interface minor version */
uint8_t intf_bld;
/* interface build version */
uint8_t intf_rsvd;
/* interface reserved version */
} __attribute__((packed));
/* Modify congestion control command response (16 bytes) */
struct creq_modify_roce_cc_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_MODIFY_ROCE_CC_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_MODIFY_ROCE_CC_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_MODIFY_ROCE_CC_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_MODIFY_ROCE_CC_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_MODIFY_ROCE_CC_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t reserved32;
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_MODIFY_ROCE_CC_RESP_V UINT32_C(0x1)
#define CREQ_MODIFY_ROCE_CC_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_MODIFY_ROCE_CC_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Modify congestion control response. */
#define CREQ_MODIFY_ROCE_CC_RESP_EVENT_MODIFY_ROCE_CC UINT32_C(0x8c)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query congestion control command response (16 bytes) */
struct creq_query_roce_cc_resp {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QUERY_ROCE_CC_RESP_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QUERY_ROCE_CC_RESP_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QUERY_ROCE_CC_RESP_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QUERY_ROCE_CC_RESP_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QUERY_ROCE_CC_RESP_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint32_t size;
/* Side buffer size in 16-byte units */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QUERY_ROCE_CC_RESP_V UINT32_C(0x1)
#define CREQ_QUERY_ROCE_CC_RESP_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QUERY_ROCE_CC_RESP_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* Query congestion control response. */
#define CREQ_QUERY_ROCE_CC_RESP_EVENT_QUERY_ROCE_CC UINT32_C(0x8d)
uint16_t reserved48[3];
} __attribute__((packed));
/* Query congestion control command response side buffer structure (32 bytes) */
struct creq_query_roce_cc_resp_sb {
uint8_t opcode;
/* Command opcode. */
/* Query congestion control response. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_OPCODE_QUERY_ROCE_CC UINT32_C(0x8d)
uint8_t status;
/* Status of the response. */
uint16_t cookie;
/* Driver supplied handle to associate the command and the response. */
uint16_t flags;
/* Flags and attribs of the command. */
uint8_t resp_size;
/* Size of the response buffer in 16-byte units. */
uint8_t reserved8;
uint8_t enable_cc;
/* unused7 is 7 b */
/* Enable. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_ENABLE_CC UINT32_C(0x1)
/* unused7 is 7 b */
uint8_t tos_dscp_tos_ecn;
/* IP TOS DSCP. */
/* IP TOS ECN. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_TOS_ECN_MASK UINT32_C(0x3)
#define CREQ_QUERY_ROCE_CC_RESP_SB_TOS_ECN_SFT 0
/* IP TOS DSCP. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_TOS_DSCP_MASK UINT32_C(0xfc)
#define CREQ_QUERY_ROCE_CC_RESP_SB_TOS_DSCP_SFT 2
uint8_t g;
/* unused5 is 5 b */
/* Congestion Probability averaging factor. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_G_MASK UINT32_C(0x7)
#define CREQ_QUERY_ROCE_CC_RESP_SB_G_SFT 0
/* unused5 is 5 b */
uint8_t num_phases_per_state;
/* Number of phases in Fast Recovery and Active Increase. */
uint16_t init_cr;
/* The starting value of rate. */
uint16_t init_tr;
/* The starting value of target rate. */
uint8_t alt_vlan_pcp;
/* rsvd1 is 5 b */
/* Alternate vlan pcp value for CNP packets. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_ALT_VLAN_PCP_MASK UINT32_C(0x7)
#define CREQ_QUERY_ROCE_CC_RESP_SB_ALT_VLAN_PCP_SFT 0
/* rsvd1 is 5 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD1_MASK UINT32_C(0xf8)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD1_SFT 3
uint8_t alt_tos_dscp;
/* rsvd4 is 2 b */
/* Alternate IP TOS DSCP. */
#define CREQ_QUERY_ROCE_CC_RESP_SB_ALT_TOS_DSCP_MASK UINT32_C(0x3f)
#define CREQ_QUERY_ROCE_CC_RESP_SB_ALT_TOS_DSCP_SFT 0
/* rsvd4 is 2 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD4_MASK UINT32_C(0xc0)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD4_SFT 6
uint8_t cc_mode;
/* rsvd2 is 7 b */
/* 0 for DCTCP , 1 for TCP */
#define CREQ_QUERY_ROCE_CC_RESP_SB_CC_MODE UINT32_C(0x1)
/* rsvd2 is 7 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD2_MASK UINT32_C(0xfe)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD2_SFT 1
uint8_t tx_queue;
/* rsvd3 is 6 b */
/* Specifies the RoCE Tx Queue ( o to 3) to use for sending CNP packets */
#define CREQ_QUERY_ROCE_CC_RESP_SB_TX_QUEUE_MASK UINT32_C(0x3)
#define CREQ_QUERY_ROCE_CC_RESP_SB_TX_QUEUE_SFT 0
/* rsvd3 is 6 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD3_MASK UINT32_C(0xfc)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD3_SFT 2
uint16_t rtt;
/* rsvd5 is 2 b */
/* Round trip time in units of usecs */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RTT_MASK UINT32_C(0x3fff)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RTT_SFT 0
/* rsvd5 is 2 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD5_MASK UINT32_C(0xc000)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD5_SFT 14
uint16_t tcp_cp;
/* rsvd6 is 6 b */
/* The value used as CP when cc_mode is 1(TCP) */
#define CREQ_QUERY_ROCE_CC_RESP_SB_TCP_CP_MASK UINT32_C(0x3ff)
#define CREQ_QUERY_ROCE_CC_RESP_SB_TCP_CP_SFT 0
/* rsvd6 is 6 b */
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD6_MASK UINT32_C(0xfc00)
#define CREQ_QUERY_ROCE_CC_RESP_SB_RSVD6_SFT 10
uint16_t inactivity_th;
/* Inactivity time after which QP CC parameters are initialized */
uint16_t reserved16;
uint32_t reserved32;
} __attribute__((packed));
/* QP error notification event (16 bytes) */
struct creq_qp_error_notification {
uint8_t type;
/*
* This field indicates the exact type of the completion. By convention,
* the LSB identifies the length of the record in 16B units. Even values
* indicate 16B records. Odd values indicate 32B records.
*/
#define CREQ_QP_ERROR_NOTIFICATION_TYPE_MASK UINT32_C(0x3f)
#define CREQ_QP_ERROR_NOTIFICATION_TYPE_SFT 0
/* QP Async Notification */
#define CREQ_QP_ERROR_NOTIFICATION_TYPE_QP_EVENT UINT32_C(0x38)
#define CREQ_QP_ERROR_NOTIFICATION_RESERVED2_MASK UINT32_C(0xc0)
#define CREQ_QP_ERROR_NOTIFICATION_RESERVED2_SFT 6
uint8_t status;
/* Status of the response. */
uint8_t req_slow_path_state;
/* requestor slow path state */
uint8_t req_err_state_reason;
/* requestor error reason */
uint32_t xid;
/* QP context id */
uint8_t v;
/*
* This value is written by the NIC such that it will be different for
* each pass through the completion queue. The even passes will write 1.
* The odd passes will write 0.
*/
#define CREQ_QP_ERROR_NOTIFICATION_V UINT32_C(0x1)
#define CREQ_QP_ERROR_NOTIFICATION_RESERVED7_MASK UINT32_C(0xfe)
#define CREQ_QP_ERROR_NOTIFICATION_RESERVED7_SFT 1
uint8_t event;
/* Event or command opcode. */
/* QP error notification event. */
#define CREQ_QP_ERROR_NOTIFICATION_EVENT_QP_ERROR_NOTIFICATION UINT32_C(0xc0)
uint8_t res_slow_path_state;
/* responder slow path state */
uint8_t res_err_state_reason;
uint16_t sq_cons_idx;
/*
* Final SQ Consumer Index value. Any additional SQ WQEs will have to be
* completed by the user provider.
*/
uint16_t rq_cons_idx;
/*
* Final RQ Consumer Index value. Any additional RQ WQEs will have to be
* completed by the user provider.
*/
} __attribute__((packed));
/* RoCE Slowpath Data Structures */
/*
* Note: This section documents the Host Structures used between software and
* RoCE control firmware.
*/
/* hwrm_selftest_qlist */
/*
* Description: This function is called by a driver to determine which selftests
* are available to be run against the requested function.
*/
/* Input (16 bytes) */
struct hwrm_selftest_qlist_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (272 bytes) */
struct hwrm_selftest_qlist_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t num_tests;
/*
* This field represents the number of tests available to be requested
* by a driver.
*/
uint8_t available_tests;
/* This field indicates which self-test is available to be run. */
/* Can run the NVM test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_NVM_TEST UINT32_C(0x1)
/* Can run the link test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_LINK_TEST UINT32_C(0x2)
/* Can run the register test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_REGISTER_TEST UINT32_C(0x4)
/* Can run the memory test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_MEMORY_TEST UINT32_C(0x8)
/* Can run the PCIe serdes test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_PCIE_SERDES_TEST UINT32_C(0x10)
/* Can run the Ethernet serdes test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_AVAILABLE_TESTS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint8_t offline_tests;
/* The NVM test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_NVM_TEST UINT32_C(0x1)
/* The link test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_LINK_TEST UINT32_C(0x2)
/* The register test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_REGISTER_TEST UINT32_C(0x4)
/* The memory test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_MEMORY_TEST UINT32_C(0x8)
/* The PCIe serdes test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_PCIE_SERDES_TEST UINT32_C(0x10)
/* The Ethernet serdes test is an offline test. */
#define HWRM_SELFTEST_QLIST_OUTPUT_OFFLINE_TESTS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint8_t unused_0;
uint16_t test_timeout;
/*
* This field represents the the maximum timeout for all the tests to
* complete in milliseconds.
*/
uint8_t unused_1;
uint8_t unused_2;
char test0_name[32];
/*
* This field represents the name of the NVM test (ASCII chars with NULL
* at the end).
*/
char test1_name[32];
/*
* This field represents the name of the link test (ASCII chars with
* NULL at the end).
*/
char test2_name[32];
/*
* This field represents the name of the register test (ASCII chars with
* NULL at the end).
*/
char test3_name[32];
/*
* This field represents the name of the memory test (ASCII chars with
* NULL at the end).
*/
char test4_name[32];
/*
* This field represents the name of the PCIe serdes test (ASCII chars
* with NULL at the end).
*/
char test5_name[32];
/*
* This field represents the name of the Ethernet serdes test (ASCII
* chars with NULL at the end).
*/
char test6_name[32];
/*
* This field represents the name of some future test (ASCII chars with
* NULL at the end).
*/
char test7_name[32];
/*
* This field represents the name of some future test (ASCII chars with
* NULL at the end).
*/
} __attribute__((packed));
/* hwrm_selftest_exec */
/*
* Description: This function is called by a driver to request which self tests
* are to be run.
*/
/* Input (24 bytes) */
struct hwrm_selftest_exec_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint8_t flags;
/* This field indicates which self-test is being requested to run. */
/* Run the NVM test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_NVM_TEST UINT32_C(0x1)
/* Run the link test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_LINK_TEST UINT32_C(0x2)
/* Run the register test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_REGISTER_TEST UINT32_C(0x4)
/* Run the memory test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_MEMORY_TEST UINT32_C(0x8)
/* Run the PCIe serdes test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_PCIE_SERDES_TEST UINT32_C(0x10)
/* Run the Ethernet serdes test. */
#define HWRM_SELFTEST_EXEC_INPUT_FLAGS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint8_t unused_0[7];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_selftest_exec_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint8_t requested_tests;
/* The following tests were requested to be run. */
/* A reqeust was made to run the NVM test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_NVM_TEST UINT32_C(0x1)
/* A request was made to run the link test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_LINK_TEST UINT32_C(0x2)
/* A request was made to run the register test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_REGISTER_TEST UINT32_C(0x4)
/* A request was made to run the memory test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_MEMORY_TEST UINT32_C(0x8)
/* A request was made to run the PCIe serdes test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_PCIE_SERDES_TEST UINT32_C(0x10)
/* A request was made to run the Ethernet serdes test. */
#define HWRM_SELFTEST_EXEC_OUTPUT_REQUESTED_TESTS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint8_t test_success;
/*
* If a test was requested to be run as seen in the requested_tests
* field, this bit indicates whether the test was successful(1) or
* failed(0).
*/
/*
* If requested, a value of 1 indicates the NVM test completed
* successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_NVM_TEST UINT32_C(0x1)
/*
* If requested, a value of 1 indicates the link test completed
* successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_LINK_TEST UINT32_C(0x2)
/*
* If requested, a value of 1 indicates the register test completed
* successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_REGISTER_TEST UINT32_C(0x4)
/*
* If requested, a value of 1 indicates the memory test completed
* successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_MEMORY_TEST UINT32_C(0x8)
/*
* If requested, a value of 1 indicates the PCIe serdes test completed
* successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_PCIE_SERDES_TEST UINT32_C(0x10)
/*
* If requested, a value of 1 indicates the Ethernet serdes test
* completed successfully.
*/
#define HWRM_SELFTEST_EXEC_OUTPUT_TEST_SUCCESS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint16_t unused_0[3];
} __attribute__((packed));
/* hwrm_selftest_irq */
/*
* Description: This function is called by a driver to request the interrupt
* test be run. In response to this request the interrupt associated with the
* completion ring specified in the cmpl_ring field will be asserted to the
* host.
*/
/* Input (16 bytes) */
struct hwrm_selftest_irq_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (8 bytes) */
struct hwrm_selftest_irq_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
} __attribute__((packed));
/* hwrm_selftest_retreive_serdes_data */
/*
* Description: This function is called by a driver to retreieve the data
* collected when running the previous PCIe or Ethernet serdes test. The driver
* can use multiple calls to this command to retreive the entire stored buffer
* in the event it cannot do so with a single call.
*/
/* Input (32 bytes) */
struct hwrm_selftest_retreive_serdes_data_input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
uint64_t resp_data_addr;
/* Host address data is to DMA'd to. */
uint32_t resp_data_offset;
/*
* This field contains the offset into the captured data to begin
* copying the data to the host from. This should be set to 0 on the
* initial call to this command.
*/
uint16_t data_len;
/*
* Size of the buffer pointed to by resp_data_addr. The firmware may use
* this entire buffer or less than the entire buffer, but never more.
*/
uint8_t flags;
/*
* This field allows this command to request the individual serdes tests
* to be run using this command.
*/
/* Unused. */
#define HWRM_SELFTEST_RETREIVE_SERDES_DATA_INPUT_FLAGS_UNUSED_TEST_MASK UINT32_C(0xf)
#define HWRM_SELFTEST_RETREIVE_SERDES_DATA_INPUT_FLAGS_UNUSED_TEST_SFT 0
/* Run the PCIe serdes test. */
#define HWRM_SELFTEST_RETREIVE_SERDES_DATA_INPUT_FLAGS_PCIE_SERDES_TEST UINT32_C(0x10)
/* Run the Ethernet serdes test. */
#define HWRM_SELFTEST_RETREIVE_SERDES_DATA_INPUT_FLAGS_ETHERNET_SERDES_TEST UINT32_C(0x20)
uint8_t unused_0;
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_selftest_retreive_serdes_data_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint16_t total_data_len;
/* Total length of stored data. */
uint16_t copied_data_len;
/*
* Amount of data DMA'd to host by this call. The driver can use this
* field along with the total_data_len field above to determine the
* value to write to the resp_data_offset field in the next call if more
* than one call to these commands is required to retreive all the
* stored data.
*/
uint32_t unused_0;
} __attribute__((packed));
/* Hardware Resource Manager Specification */
/* Description: This structure is used to configure a RSS Context. */
/*
* Note: The Hardware Resource Manager (HWRM) manages various hardware resources
* inside the chip. The HWRM is implemented in firmware, and runs on embedded
* processors inside the chip. This firmware service is vital part of the chip.
* The chip can not be used by a driver or HWRM client without the HWRM.
*/
/* Input (16 bytes) */
struct input {
uint16_t req_type;
/*
* This value indicates what type of request this is. The format for the
* rest of the command is determined by this field.
*/
uint16_t cmpl_ring;
/*
* This value indicates the what completion ring the request will be
* optionally completed on. If the value is -1, then no CR completion
* will be generated. Any other value must be a valid CR ring_id value
* for this function.
*/
uint16_t seq_id;
/* This value indicates the command sequence number. */
uint16_t target_id;
/*
* Target ID of this command. 0x0 - 0xFFF8 - Used for function ids
* 0xFFF8 - 0xFFFE - Reserved for internal processors 0xFFFF - HWRM
*/
uint64_t resp_addr;
/*
* This is the host address where the response will be written when the
* request is complete. This area must be 16B aligned and must be
* cleared to zero before the request is made.
*/
} __attribute__((packed));
/* Output (8 bytes) */
struct output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
} __attribute__((packed));
/* Short Command Structure (16 bytes) */
struct hwrm_short_input {
uint16_t req_type;
/*
* This field indicates the type of request in the request buffer. The
* format for the rest of the command (request) is determined by this
* field.
*/
uint16_t signature;
/*
* This field indicates a signature that is used to identify short form
* of the command listed here. This field shall be set to 17185
* (0x4321).
*/
/* Signature indicating this is a short form of HWRM command */
#define HWRM_SHORT_INPUT_SIGNATURE_SHORT_CMD UINT32_C(0x4321)
uint16_t unused_0;
/* Reserved for future use. */
uint16_t size;
/* This value indicates the length of the request. */
uint64_t req_addr;
/*
* This is the host address where the request was written. This area
* must be 16B aligned.
*/
} __attribute__((packed));
#define GET_HWRM_REQ_TYPE(x) \
((x) == 0x99 ? "HWRM_CFA_NTUPLE_FILTER_ALLOC": \
((x) == 0x90 ? "HWRM_CFA_L2_FILTER_ALLOC": \
((x) == 0x91 ? "HWRM_CFA_L2_FILTER_FREE": \
((x) == 0x92 ? "HWRM_CFA_L2_FILTER_CFG": \
((x) == 0x93 ? "HWRM_CFA_L2_SET_RX_MASK": \
((x) == 0x94 ? "HWRM_CFA_VLAN_ANTISPOOF_CFG": \
((x) == 0x95 ? "HWRM_CFA_TUNNEL_FILTER_ALLOC": \
((x) == 0x96 ? "HWRM_CFA_TUNNEL_FILTER_FREE": \
((x) == 0x10 ? "RESERVED1": \
((x) == 0x11 ? "HWRM_FUNC_RESET": \
((x) == 0x12 ? "HWRM_FUNC_GETFID": \
((x) == 0x13 ? "HWRM_FUNC_VF_ALLOC": \
((x) == 0x14 ? "HWRM_FUNC_VF_FREE": \
((x) == 0x15 ? "HWRM_FUNC_QCAPS": \
((x) == 0x16 ? "HWRM_FUNC_QCFG": \
((x) == 0x17 ? "HWRM_FUNC_CFG": \
((x) == 0x18 ? "HWRM_FUNC_QSTATS": \
((x) == 0x19 ? "HWRM_FUNC_CLR_STATS": \
((x) == 0xe0 ? "HWRM_TEMP_MONITOR_QUERY": \
((x) == 0x1a ? "HWRM_FUNC_DRV_UNRGTR": \
((x) == 0x1b ? "HWRM_FUNC_VF_RESC_FREE": \
((x) == 0x1c ? "HWRM_FUNC_VF_VNIC_IDS_QUERY": \
((x) == 0x1d ? "HWRM_FUNC_DRV_RGTR": \
((x) == 0x1e ? "HWRM_FUNC_DRV_QVER": \
((x) == 0x1f ? "HWRM_FUNC_BUF_RGTR": \
((x) == 0x9a ? "HWRM_CFA_NTUPLE_FILTER_FREE": \
((x) == 0x9b ? "HWRM_CFA_NTUPLE_FILTER_CFG": \
((x) == 0xd3 ? "HWRM_FWD_ASYNC_EVENT_CMPL": \
((x) == 0xd2 ? "HWRM_FWD_RESP": \
((x) == 0xd1 ? "HWRM_REJECT_FWD_RESP": \
((x) == 0xd0 ? "HWRM_EXEC_FWD_RESP": \
((x) == 0xc0 ? "HWRM_FW_RESET": \
((x) == 0xc1 ? "HWRM_FW_QSTATUS": \
((x) == 0x70 ? "HWRM_VNIC_RSS_COS_LB_CTX_ALLOC": \
((x) == 0x71 ? "HWRM_VNIC_RSS_COS_LB_CTX_FREE": \
((x) == 0xb1 ? "HWRM_STAT_CTX_FREE": \
((x) == 0xb0 ? "HWRM_STAT_CTX_ALLOC": \
((x) == 0xb3 ? "HWRM_STAT_CTX_CLR_STATS": \
((x) == 0xb2 ? "HWRM_STAT_CTX_QUERY": \
((x) == 0xfff6 ? "HWRM_NVM_GET_DEV_INFO": \
((x) == 0x61 ? "HWRM_RING_GRP_FREE": \
((x) == 0x60 ? "HWRM_RING_GRP_ALLOC": \
((x) == 0x24 ? "HWRM_PORT_LPBK_QSTATS": \
((x) == 0xf3 ? "HWRM_WOL_REASON_QCFG": \
((x) == 0xa0 ? "HWRM_TUNNEL_DST_PORT_QUERY": \
((x) == 0xa1 ? "HWRM_TUNNEL_DST_PORT_ALLOC": \
((x) == 0xa2 ? "HWRM_TUNNEL_DST_PORT_FREE": \
((x) == 0xfffc ? "HWRM_NVM_RAW_DUMP": \
((x) == 0xfffb ? "HWRM_NVM_GET_DIR_INFO": \
((x) == 0xfffa ? "HWRM_NVM_GET_DIR_ENTRIES": \
((x) == 0x10a ? "HWRM_CFA_VLAN_ANTISPOOF_QCFG": \
((x) == 0xe ? "HWRM_FUNC_BUF_UNRGTR": \
((x) == 0xf ? "HWRM_FUNC_VF_CFG": \
((x) == 0xffff ? "HWRM_NVM_RAW_WRITE_BLK": \
((x) == 0xfffe ? "HWRM_NVM_WRITE": \
((x) == 0xfffd ? "HWRM_NVM_READ": \
((x) == 0x50 ? "HWRM_RING_ALLOC": \
((x) == 0x51 ? "HWRM_RING_FREE": \
((x) == 0x52 ? "HWRM_RING_CMPL_RING_QAGGINT_PARAMS": \
((x) == 0x53 ? "HWRM_RING_CMPL_RING_CFG_AGGINT_PARAMS": \
((x) == 0x4a ? "HWRM_VNIC_QCAPS": \
((x) == 0x49 ? "HWRM_VNIC_PLCMODES_QCFG": \
((x) == 0x48 ? "HWRM_VNIC_PLCMODES_CFG": \
((x) == 0x47 ? "HWRM_VNIC_RSS_QCFG": \
((x) == 0x46 ? "HWRM_VNIC_RSS_CFG": \
((x) == 0x44 ? "HWRM_VNIC_TPA_CFG": \
((x) == 0x43 ? "HWRM_VNIC_QCFG": \
((x) == 0x42 ? "HWRM_VNIC_CFG": \
((x) == 0x41 ? "HWRM_VNIC_FREE": \
((x) == 0x40 ? "HWRM_VNIC_ALLOC": \
((x) == 0x0 ? "HWRM_VER_GET": \
((x) == 0xfff9 ? "HWRM_NVM_FIND_DIR_ENTRY": \
((x) == 0xfff8 ? "HWRM_NVM_MOD_DIR_ENTRY": \
((x) == 0xfff7 ? "HWRM_NVM_ERASE_DIR_ENTRY": \
((x) == 0x5e ? "HWRM_RING_RESET": \
((x) == 0xfff5 ? "HWRM_NVM_VERIFY_UPDATE": \
((x) == 0xfff4 ? "HWRM_NVM_MODIFY": \
((x) == 0xfff3 ? "HWRM_NVM_INSTALL_UPDATE": \
((x) == 0xfff2 ? "HWRM_NVM_SET_VARIABLE": \
((x) == 0xfff1 ? "HWRM_NVM_GET_VARIABLE": \
((x) == 0xfff0 ? "HWRM_NVM_FLUSH": \
((x) == 0x2e ? "HWRM_PORT_LED_QCFG": \
((x) == 0x2d ? "HWRM_PORT_LED_CFG": \
((x) == 0x2f ? "HWRM_PORT_LED_QCAPS": \
((x) == 0x2a ? "HWRM_PORT_PHY_QCAPS": \
((x) == 0x38 ? "HWRM_QUEUE_PRI2COS_CFG": \
((x) == 0x39 ? "HWRM_QUEUE_COS2BW_QCFG": \
((x) == 0x32 ? "HWRM_QUEUE_CFG": \
((x) == 0x33 ? "HWRM_FUNC_VLAN_CFG": \
((x) == 0x30 ? "HWRM_QUEUE_QPORTCFG": \
((x) == 0x31 ? "HWRM_QUEUE_QCFG": \
((x) == 0x36 ? "HWRM_QUEUE_PFCENABLE_CFG": \
((x) == 0x37 ? "HWRM_QUEUE_PRI2COS_QCFG": \
((x) == 0x34 ? "HWRM_FUNC_VLAN_QCFG": \
((x) == 0x35 ? "HWRM_QUEUE_PFCENABLE_QCFG": \
((x) == 0xff14 ? "HWRM_DBG_DUMP": \
((x) == 0xc8 ? "HWRM_FW_SET_TIME": \
((x) == 0xc9 ? "HWRM_FW_GET_TIME": \
((x) == 0xf1 ? "HWRM_WOL_FILTER_FREE": \
((x) == 0xf0 ? "HWRM_WOL_FILTER_ALLOC": \
((x) == 0x27 ? "HWRM_PORT_PHY_QCFG": \
((x) == 0xf2 ? "HWRM_WOL_FILTER_QCFG": \
((x) == 0x21 ? "HWRM_PORT_MAC_CFG": \
((x) == 0x20 ? "HWRM_PORT_PHY_CFG": \
((x) == 0x23 ? "HWRM_PORT_QSTATS": \
((x) == 0x28 ? "HWRM_PORT_MAC_QCFG": \
((x) == 0xffef ? "HWRM_NVM_VALIDATE_OPTION": \
((x) == 0x3a ? "HWRM_QUEUE_COS2BW_CFG": \
"Unknown req_type"))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))))
/* Command numbering (8 bytes) */
struct cmd_nums {
uint16_t req_type;
/*
* This version of the specification defines the commands listed in the
* table below. The following are general implementation requirements
* for these commands: # All commands listed below that are marked
* neither reserved nor experimental shall be implemented by the HWRM. #
* A HWRM client compliant to this specification should not use commands
* outside of the list below. # A HWRM client compliant to this
* specification should not use command numbers marked reserved below. #
* A command marked experimental below may not be implemented by the
* HWRM. # A command marked experimental may change in the future
* version of the HWRM specification. # A command not listed below may
* be implemented by the HWRM. The behavior of commands that are not
* listed below is outside the scope of this specification.
*/
#define HWRM_VER_GET (UINT32_C(0x0))
#define HWRM_FUNC_BUF_UNRGTR (UINT32_C(0xe))
#define HWRM_FUNC_VF_CFG (UINT32_C(0xf))
/* Reserved for future use */
#define RESERVED1 (UINT32_C(0x10))
#define HWRM_FUNC_RESET (UINT32_C(0x11))
#define HWRM_FUNC_GETFID (UINT32_C(0x12))
#define HWRM_FUNC_VF_ALLOC (UINT32_C(0x13))
#define HWRM_FUNC_VF_FREE (UINT32_C(0x14))
#define HWRM_FUNC_QCAPS (UINT32_C(0x15))
#define HWRM_FUNC_QCFG (UINT32_C(0x16))
#define HWRM_FUNC_CFG (UINT32_C(0x17))
#define HWRM_FUNC_QSTATS (UINT32_C(0x18))
#define HWRM_FUNC_CLR_STATS (UINT32_C(0x19))
#define HWRM_FUNC_DRV_UNRGTR (UINT32_C(0x1a))
#define HWRM_FUNC_VF_RESC_FREE (UINT32_C(0x1b))
#define HWRM_FUNC_VF_VNIC_IDS_QUERY (UINT32_C(0x1c))
#define HWRM_FUNC_DRV_RGTR (UINT32_C(0x1d))
#define HWRM_FUNC_DRV_QVER (UINT32_C(0x1e))
#define HWRM_FUNC_BUF_RGTR (UINT32_C(0x1f))
#define HWRM_PORT_PHY_CFG (UINT32_C(0x20))
#define HWRM_PORT_MAC_CFG (UINT32_C(0x21))
#define HWRM_PORT_QSTATS (UINT32_C(0x23))
#define HWRM_PORT_LPBK_QSTATS (UINT32_C(0x24))
#define HWRM_PORT_PHY_QCFG (UINT32_C(0x27))
#define HWRM_PORT_MAC_QCFG (UINT32_C(0x28))
#define HWRM_PORT_PHY_QCAPS (UINT32_C(0x2a))
#define HWRM_PORT_LED_CFG (UINT32_C(0x2d))
#define HWRM_PORT_LED_QCFG (UINT32_C(0x2e))
#define HWRM_PORT_LED_QCAPS (UINT32_C(0x2f))
#define HWRM_QUEUE_QPORTCFG (UINT32_C(0x30))
#define HWRM_QUEUE_QCFG (UINT32_C(0x31))
#define HWRM_QUEUE_CFG (UINT32_C(0x32))
#define HWRM_FUNC_VLAN_CFG (UINT32_C(0x33))
#define HWRM_FUNC_VLAN_QCFG (UINT32_C(0x34))
#define HWRM_QUEUE_PFCENABLE_QCFG (UINT32_C(0x35))
#define HWRM_QUEUE_PFCENABLE_CFG (UINT32_C(0x36))
#define HWRM_QUEUE_PRI2COS_QCFG (UINT32_C(0x37))
#define HWRM_QUEUE_PRI2COS_CFG (UINT32_C(0x38))
#define HWRM_QUEUE_COS2BW_QCFG (UINT32_C(0x39))
#define HWRM_QUEUE_COS2BW_CFG (UINT32_C(0x3a))
#define HWRM_VNIC_ALLOC (UINT32_C(0x40))
#define HWRM_VNIC_FREE (UINT32_C(0x41))
#define HWRM_VNIC_CFG (UINT32_C(0x42))
#define HWRM_VNIC_QCFG (UINT32_C(0x43))
#define HWRM_VNIC_TPA_CFG (UINT32_C(0x44))
#define HWRM_VNIC_RSS_CFG (UINT32_C(0x46))
#define HWRM_VNIC_RSS_QCFG (UINT32_C(0x47))
#define HWRM_VNIC_PLCMODES_CFG (UINT32_C(0x48))
#define HWRM_VNIC_PLCMODES_QCFG (UINT32_C(0x49))
#define HWRM_VNIC_QCAPS (UINT32_C(0x4a))
#define HWRM_RING_ALLOC (UINT32_C(0x50))
#define HWRM_RING_FREE (UINT32_C(0x51))
#define HWRM_RING_CMPL_RING_QAGGINT_PARAMS (UINT32_C(0x52))
#define HWRM_RING_CMPL_RING_CFG_AGGINT_PARAMS (UINT32_C(0x53))
#define HWRM_RING_RESET (UINT32_C(0x5e))
#define HWRM_RING_GRP_ALLOC (UINT32_C(0x60))
#define HWRM_RING_GRP_FREE (UINT32_C(0x61))
#define HWRM_VNIC_RSS_COS_LB_CTX_ALLOC (UINT32_C(0x70))
#define HWRM_VNIC_RSS_COS_LB_CTX_FREE (UINT32_C(0x71))
#define HWRM_CFA_L2_FILTER_ALLOC (UINT32_C(0x90))
#define HWRM_CFA_L2_FILTER_FREE (UINT32_C(0x91))
#define HWRM_CFA_L2_FILTER_CFG (UINT32_C(0x92))
#define HWRM_CFA_L2_SET_RX_MASK (UINT32_C(0x93))
#define HWRM_CFA_VLAN_ANTISPOOF_CFG (UINT32_C(0x94))
#define HWRM_CFA_TUNNEL_FILTER_ALLOC (UINT32_C(0x95))
#define HWRM_CFA_TUNNEL_FILTER_FREE (UINT32_C(0x96))
#define HWRM_CFA_NTUPLE_FILTER_ALLOC (UINT32_C(0x99))
#define HWRM_CFA_NTUPLE_FILTER_FREE (UINT32_C(0x9a))
#define HWRM_CFA_NTUPLE_FILTER_CFG (UINT32_C(0x9b))
#define HWRM_TUNNEL_DST_PORT_QUERY (UINT32_C(0xa0))
#define HWRM_TUNNEL_DST_PORT_ALLOC (UINT32_C(0xa1))
#define HWRM_TUNNEL_DST_PORT_FREE (UINT32_C(0xa2))
#define HWRM_STAT_CTX_ALLOC (UINT32_C(0xb0))
#define HWRM_STAT_CTX_FREE (UINT32_C(0xb1))
#define HWRM_STAT_CTX_QUERY (UINT32_C(0xb2))
#define HWRM_STAT_CTX_CLR_STATS (UINT32_C(0xb3))
#define HWRM_FW_RESET (UINT32_C(0xc0))
#define HWRM_FW_QSTATUS (UINT32_C(0xc1))
#define HWRM_FW_SET_TIME (UINT32_C(0xc8))
#define HWRM_FW_GET_TIME (UINT32_C(0xc9))
#define HWRM_EXEC_FWD_RESP (UINT32_C(0xd0))
#define HWRM_REJECT_FWD_RESP (UINT32_C(0xd1))
#define HWRM_FWD_RESP (UINT32_C(0xd2))
#define HWRM_FWD_ASYNC_EVENT_CMPL (UINT32_C(0xd3))
#define HWRM_TEMP_MONITOR_QUERY (UINT32_C(0xe0))
#define HWRM_WOL_FILTER_ALLOC (UINT32_C(0xf0))
#define HWRM_WOL_FILTER_FREE (UINT32_C(0xf1))
#define HWRM_WOL_FILTER_QCFG (UINT32_C(0xf2))
#define HWRM_WOL_REASON_QCFG (UINT32_C(0xf3))
#define HWRM_CFA_VLAN_ANTISPOOF_QCFG (UINT32_C(0x10a))
#define HWRM_DBG_DUMP (UINT32_C(0xff14))
#define HWRM_NVM_VALIDATE_OPTION (UINT32_C(0xffef))
#define HWRM_NVM_FLUSH (UINT32_C(0xfff0))
#define HWRM_NVM_GET_VARIABLE (UINT32_C(0xfff1))
#define HWRM_NVM_SET_VARIABLE (UINT32_C(0xfff2))
#define HWRM_NVM_INSTALL_UPDATE (UINT32_C(0xfff3))
#define HWRM_NVM_MODIFY (UINT32_C(0xfff4))
#define HWRM_NVM_VERIFY_UPDATE (UINT32_C(0xfff5))
#define HWRM_NVM_GET_DEV_INFO (UINT32_C(0xfff6))
#define HWRM_NVM_ERASE_DIR_ENTRY (UINT32_C(0xfff7))
#define HWRM_NVM_MOD_DIR_ENTRY (UINT32_C(0xfff8))
#define HWRM_NVM_FIND_DIR_ENTRY (UINT32_C(0xfff9))
#define HWRM_NVM_GET_DIR_ENTRIES (UINT32_C(0xfffa))
#define HWRM_NVM_GET_DIR_INFO (UINT32_C(0xfffb))
#define HWRM_NVM_RAW_DUMP (UINT32_C(0xfffc))
#define HWRM_NVM_READ (UINT32_C(0xfffd))
#define HWRM_NVM_WRITE (UINT32_C(0xfffe))
#define HWRM_NVM_RAW_WRITE_BLK (UINT32_C(0xffff))
uint16_t unused_0[3];
} __attribute__((packed));
#define GET_HWRM_ERROR_CODE(x) \
((x) == 0xf ? "HWRM_ERROR": \
((x) == 0xffff ? "CMD_NOT_SUPPORTED": \
((x) == 0xfffe ? "UNKNOWN_ERR": \
((x) == 0x4 ? "RESOURCE_ALLOC_ERROR": \
((x) == 0x5 ? "INVALID_FLAGS": \
((x) == 0x6 ? "INVALID_ENABLES": \
((x) == 0x0 ? "SUCCESS": \
((x) == 0x1 ? "FAIL": \
((x) == 0x2 ? "INVALID_PARAMS": \
((x) == 0x3 ? "RESOURCE_ACCESS_DENIED": \
"Unknown error_code"))))))))))
/* Return Codes (8 bytes) */
struct ret_codes {
uint16_t error_code;
/* These are numbers assigned to return/error codes. */
/* Request was successfully executed by the HWRM. */
#define HWRM_ERR_CODE_SUCCESS (UINT32_C(0x0))
/* THe HWRM failed to execute the request. */
#define HWRM_ERR_CODE_FAIL (UINT32_C(0x1))
/* The request contains invalid argument(s) or input parameters. */
#define HWRM_ERR_CODE_INVALID_PARAMS (UINT32_C(0x2))
/*
* The requester is not allowed to access the requested
* resource. This error code shall be provided in a response to
* a request to query or modify an existing resource that is not
* accessible by the requester.
*/
#define HWRM_ERR_CODE_RESOURCE_ACCESS_DENIED (UINT32_C(0x3))
/*
* The HWRM is unable to allocate the requested resource. This
* code only applies to requests for HWRM resource allocations.
*/
#define HWRM_ERR_CODE_RESOURCE_ALLOC_ERROR (UINT32_C(0x4))
/* Invalid combination of flags is specified in the request. */
#define HWRM_ERR_CODE_INVALID_FLAGS (UINT32_C(0x5))
/*
* Invalid combination of enables fields is specified in the
* request.
*/
#define HWRM_ERR_CODE_INVALID_ENABLES (UINT32_C(0x6))
/* Generic HWRM execution error that represents an internal error. */
#define HWRM_ERR_CODE_HWRM_ERROR (UINT32_C(0xf))
/* Unknown error */
#define HWRM_ERR_CODE_UNKNOWN_ERR (UINT32_C(0xfffe))
/* Unsupported or invalid command */
#define HWRM_ERR_CODE_CMD_NOT_SUPPORTED (UINT32_C(0xffff))
uint16_t unused_0[3];
} __attribute__((packed));
/* Output (16 bytes) */
struct hwrm_err_output {
uint16_t error_code;
/*
* Pass/Fail or error type Note: receiver to verify the in parameters,
* and fail the call with an error when appropriate
*/
uint16_t req_type;
/* This field returns the type of original request. */
uint16_t seq_id;
/* This field provides original sequence number of the command. */
uint16_t resp_len;
/*
* This field is the length of the response in bytes. The last byte of
* the response is a valid flag that will read as '1' when the command
* has been completely written to memory.
*/
uint32_t opaque_0;
/* debug info for this error response. */
uint16_t opaque_1;
/* debug info for this error response. */
uint8_t cmd_err;
/*
* In the case of an error response, command specific error code is
* returned in this field.
*/
uint8_t valid;
/*
* This field is used in Output records to indicate that the output is
* completely written to RAM. This field should be read as '1' to
* indicate that the output has been completely written. When writing a
* command completion or response to an internal processor, the order of
* writes has to be such that this field is written last.
*/
} __attribute__((packed));
/* Port Tx Statistics Formats (408 bytes) */
struct tx_port_stats {
uint64_t tx_64b_frames;
/* Total Number of 64 Bytes frames transmitted */
uint64_t tx_65b_127b_frames;
/* Total Number of 65-127 Bytes frames transmitted */
uint64_t tx_128b_255b_frames;
/* Total Number of 128-255 Bytes frames transmitted */
uint64_t tx_256b_511b_frames;
/* Total Number of 256-511 Bytes frames transmitted */
uint64_t tx_512b_1023b_frames;
/* Total Number of 512-1023 Bytes frames transmitted */
uint64_t tx_1024b_1518_frames;
/* Total Number of 1024-1518 Bytes frames transmitted */
uint64_t tx_good_vlan_frames;
/*
* Total Number of each good VLAN (exludes FCS errors) frame transmitted
* which is 1519 to 1522 bytes in length inclusive (excluding framing
* bits but including FCS bytes).
*/
uint64_t tx_1519b_2047_frames;
/* Total Number of 1519-2047 Bytes frames transmitted */
uint64_t tx_2048b_4095b_frames;
/* Total Number of 2048-4095 Bytes frames transmitted */
uint64_t tx_4096b_9216b_frames;
/* Total Number of 4096-9216 Bytes frames transmitted */
uint64_t tx_9217b_16383b_frames;
/* Total Number of 9217-16383 Bytes frames transmitted */
uint64_t tx_good_frames;
/* Total Number of good frames transmitted */
uint64_t tx_total_frames;
/* Total Number of frames transmitted */
uint64_t tx_ucast_frames;
/* Total number of unicast frames transmitted */
uint64_t tx_mcast_frames;
/* Total number of multicast frames transmitted */
uint64_t tx_bcast_frames;
/* Total number of broadcast frames transmitted */
uint64_t tx_pause_frames;
/* Total number of PAUSE control frames transmitted */
uint64_t tx_pfc_frames;
/* Total number of PFC/per-priority PAUSE control frames transmitted */
uint64_t tx_jabber_frames;
/* Total number of jabber frames transmitted */
uint64_t tx_fcs_err_frames;
/* Total number of frames transmitted with FCS error */
uint64_t tx_control_frames;
/* Total number of control frames transmitted */
uint64_t tx_oversz_frames;
/* Total number of over-sized frames transmitted */
uint64_t tx_single_dfrl_frames;
/* Total number of frames with single deferral */
uint64_t tx_multi_dfrl_frames;
/* Total number of frames with multiple deferrals */
uint64_t tx_single_coll_frames;
/* Total number of frames with single collision */
uint64_t tx_multi_coll_frames;
/* Total number of frames with multiple collisions */
uint64_t tx_late_coll_frames;
/* Total number of frames with late collisions */
uint64_t tx_excessive_coll_frames;
/* Total number of frames with excessive collisions */
uint64_t tx_frag_frames;
/* Total number of fragmented frames transmitted */
uint64_t tx_err;
/* Total number of transmit errors */
uint64_t tx_tagged_frames;
/* Total number of single VLAN tagged frames transmitted */
uint64_t tx_dbl_tagged_frames;
/* Total number of double VLAN tagged frames transmitted */
uint64_t tx_runt_frames;
/* Total number of runt frames transmitted */
uint64_t tx_fifo_underruns;
/* Total number of TX FIFO under runs */
uint64_t tx_pfc_ena_frames_pri0;
/* Total number of PFC frames with PFC enabled bit for Pri 0 transmitted */
uint64_t tx_pfc_ena_frames_pri1;
/* Total number of PFC frames with PFC enabled bit for Pri 1 transmitted */
uint64_t tx_pfc_ena_frames_pri2;
/* Total number of PFC frames with PFC enabled bit for Pri 2 transmitted */
uint64_t tx_pfc_ena_frames_pri3;
/* Total number of PFC frames with PFC enabled bit for Pri 3 transmitted */
uint64_t tx_pfc_ena_frames_pri4;
/* Total number of PFC frames with PFC enabled bit for Pri 4 transmitted */
uint64_t tx_pfc_ena_frames_pri5;
/* Total number of PFC frames with PFC enabled bit for Pri 5 transmitted */
uint64_t tx_pfc_ena_frames_pri6;
/* Total number of PFC frames with PFC enabled bit for Pri 6 transmitted */
uint64_t tx_pfc_ena_frames_pri7;
/* Total number of PFC frames with PFC enabled bit for Pri 7 transmitted */
uint64_t tx_eee_lpi_events;
/* Total number of EEE LPI Events on TX */
uint64_t tx_eee_lpi_duration;
/* EEE LPI Duration Counter on TX */
uint64_t tx_llfc_logical_msgs;
/* Total number of Link Level Flow Control (LLFC) messages transmitted */
uint64_t tx_hcfc_msgs;
/* Total number of HCFC messages transmitted */
uint64_t tx_total_collisions;
/* Total number of TX collisions */
uint64_t tx_bytes;
/* Total number of transmitted bytes */
uint64_t tx_xthol_frames;
/* Total number of end-to-end HOL frames */
uint64_t tx_stat_discard;
/* Total Tx Drops per Port reported by STATS block */
uint64_t tx_stat_error;
/* Total Tx Error Drops per Port reported by STATS block */
} __attribute__((packed));
/* Port Rx Statistics Formats (528 bytes) */
struct rx_port_stats {
uint64_t rx_64b_frames;
/* Total Number of 64 Bytes frames received */
uint64_t rx_65b_127b_frames;
/* Total Number of 65-127 Bytes frames received */
uint64_t rx_128b_255b_frames;
/* Total Number of 128-255 Bytes frames received */
uint64_t rx_256b_511b_frames;
/* Total Number of 256-511 Bytes frames received */
uint64_t rx_512b_1023b_frames;
/* Total Number of 512-1023 Bytes frames received */
uint64_t rx_1024b_1518_frames;
/* Total Number of 1024-1518 Bytes frames received */
uint64_t rx_good_vlan_frames;
/*
* Total Number of each good VLAN (exludes FCS errors) frame received
* which is 1519 to 1522 bytes in length inclusive (excluding framing
* bits but including FCS bytes).
*/
uint64_t rx_1519b_2047b_frames;
/* Total Number of 1519-2047 Bytes frames received */
uint64_t rx_2048b_4095b_frames;
/* Total Number of 2048-4095 Bytes frames received */
uint64_t rx_4096b_9216b_frames;
/* Total Number of 4096-9216 Bytes frames received */
uint64_t rx_9217b_16383b_frames;
/* Total Number of 9217-16383 Bytes frames received */
uint64_t rx_total_frames;
/* Total number of frames received */
uint64_t rx_ucast_frames;
/* Total number of unicast frames received */
uint64_t rx_mcast_frames;
/* Total number of multicast frames received */
uint64_t rx_bcast_frames;
/* Total number of broadcast frames received */
uint64_t rx_fcs_err_frames;
/* Total number of received frames with FCS error */
uint64_t rx_ctrl_frames;
/* Total number of control frames received */
uint64_t rx_pause_frames;
/* Total number of PAUSE frames received */
uint64_t rx_pfc_frames;
/* Total number of PFC frames received */
uint64_t rx_unsupported_opcode_frames;
/* Total number of frames received with an unsupported opcode */
uint64_t rx_unsupported_da_pausepfc_frames;
/*
* Total number of frames received with an unsupported DA for pause and
* PFC
*/
uint64_t rx_wrong_sa_frames;
/* Total number of frames received with an unsupported SA */
uint64_t rx_align_err_frames;
/* Total number of received packets with alignment error */
uint64_t rx_oor_len_frames;
/* Total number of received frames with out-of-range length */
uint64_t rx_code_err_frames;
/* Total number of received frames with error termination */
uint64_t rx_false_carrier_frames;
/*
* Total number of received frames with a false carrier is detected
* during idle, as defined by RX_ER samples active and RXD is 0xE. The
* event is reported along with the statistics generated on the next
* received frame. Only one false carrier condition can be detected and
* logged between frames. Carrier event, valid for 10M/100M speed modes
* only.
*/
uint64_t rx_ovrsz_frames;
/* Total number of over-sized frames received */
uint64_t rx_jbr_frames;
/* Total number of jabber packets received */
uint64_t rx_mtu_err_frames;
/* Total number of received frames with MTU error */
uint64_t rx_match_crc_frames;
/* Total number of received frames with CRC match */
uint64_t rx_promiscuous_frames;
/* Total number of frames received promiscuously */
uint64_t rx_tagged_frames;
/* Total number of received frames with one or two VLAN tags */
uint64_t rx_double_tagged_frames;
/* Total number of received frames with two VLAN tags */
uint64_t rx_trunc_frames;
/* Total number of truncated frames received */
uint64_t rx_good_frames;
/* Total number of good frames (without errors) received */
uint64_t rx_pfc_xon2xoff_frames_pri0;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 0
*/
uint64_t rx_pfc_xon2xoff_frames_pri1;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 1
*/
uint64_t rx_pfc_xon2xoff_frames_pri2;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 2
*/
uint64_t rx_pfc_xon2xoff_frames_pri3;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 3
*/
uint64_t rx_pfc_xon2xoff_frames_pri4;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 4
*/
uint64_t rx_pfc_xon2xoff_frames_pri5;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 5
*/
uint64_t rx_pfc_xon2xoff_frames_pri6;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 6
*/
uint64_t rx_pfc_xon2xoff_frames_pri7;
/*
* Total number of received PFC frames with transition from XON to XOFF
* on Pri 7
*/
uint64_t rx_pfc_ena_frames_pri0;
/* Total number of received PFC frames with PFC enabled bit for Pri 0 */
uint64_t rx_pfc_ena_frames_pri1;
/* Total number of received PFC frames with PFC enabled bit for Pri 1 */
uint64_t rx_pfc_ena_frames_pri2;
/* Total number of received PFC frames with PFC enabled bit for Pri 2 */
uint64_t rx_pfc_ena_frames_pri3;
/* Total number of received PFC frames with PFC enabled bit for Pri 3 */
uint64_t rx_pfc_ena_frames_pri4;
/* Total number of received PFC frames with PFC enabled bit for Pri 4 */
uint64_t rx_pfc_ena_frames_pri5;
/* Total number of received PFC frames with PFC enabled bit for Pri 5 */
uint64_t rx_pfc_ena_frames_pri6;
/* Total number of received PFC frames with PFC enabled bit for Pri 6 */
uint64_t rx_pfc_ena_frames_pri7;
/* Total number of received PFC frames with PFC enabled bit for Pri 7 */
uint64_t rx_sch_crc_err_frames;
/* Total Number of frames received with SCH CRC error */
uint64_t rx_undrsz_frames;
/* Total Number of under-sized frames received */
uint64_t rx_frag_frames;
/* Total Number of fragmented frames received */
uint64_t rx_eee_lpi_events;
/* Total number of RX EEE LPI Events */
uint64_t rx_eee_lpi_duration;
/* EEE LPI Duration Counter on RX */
uint64_t rx_llfc_physical_msgs;
/*
* Total number of physical type Link Level Flow Control (LLFC) messages
* received
*/
uint64_t rx_llfc_logical_msgs;
/*
* Total number of logical type Link Level Flow Control (LLFC) messages
* received
*/
uint64_t rx_llfc_msgs_with_crc_err;
/*
* Total number of logical type Link Level Flow Control (LLFC) messages
* received with CRC error
*/
uint64_t rx_hcfc_msgs;
/* Total number of HCFC messages received */
uint64_t rx_hcfc_msgs_with_crc_err;
/* Total number of HCFC messages received with CRC error */
uint64_t rx_bytes;
/* Total number of received bytes */
uint64_t rx_runt_bytes;
/* Total number of bytes received in runt frames */
uint64_t rx_runt_frames;
/* Total number of runt frames received */
uint64_t rx_stat_discard;
/* Total Rx Discards per Port reported by STATS block */
uint64_t rx_stat_err;
/* Total Rx Error Drops per Port reported by STATS block */
} __attribute__((packed));
/* Periodic Statistics Context DMA to host (160 bytes) */
struct ctx_hw_stats {
uint64_t rx_ucast_pkts;
/* Number of received unicast packets */
uint64_t rx_mcast_pkts;
/* Number of received multicast packets */
uint64_t rx_bcast_pkts;
/* Number of received broadcast packets */
uint64_t rx_discard_pkts;
/* Number of discarded packets on received path */
uint64_t rx_drop_pkts;
/* Number of dropped packets on received path */
uint64_t rx_ucast_bytes;
/* Number of received bytes for unicast traffic */
uint64_t rx_mcast_bytes;
/* Number of received bytes for multicast traffic */
uint64_t rx_bcast_bytes;
/* Number of received bytes for broadcast traffic */
uint64_t tx_ucast_pkts;
/* Number of transmitted unicast packets */
uint64_t tx_mcast_pkts;
/* Number of transmitted multicast packets */
uint64_t tx_bcast_pkts;
/* Number of transmitted broadcast packets */
uint64_t tx_discard_pkts;
/* Number of discarded packets on transmit path */
uint64_t tx_drop_pkts;
/* Number of dropped packets on transmit path */
uint64_t tx_ucast_bytes;
/* Number of transmitted bytes for unicast traffic */
uint64_t tx_mcast_bytes;
/* Number of transmitted bytes for multicast traffic */
uint64_t tx_bcast_bytes;
/* Number of transmitted bytes for broadcast traffic */
uint64_t tpa_pkts;
/* Number of TPA packets */
uint64_t tpa_bytes;
/* Number of TPA bytes */
uint64_t tpa_events;
/* Number of TPA events */
uint64_t tpa_aborts;
/* Number of TPA aborts */
} __attribute__((packed));
/* Structure data header (16 bytes) */
struct hwrm_struct_hdr {
uint16_t struct_id;
/* This value indicates the structured data ID. */
/* LLDP configuration structured data ID. */
#define HWRM_STRUCT_HDR_STRUCT_ID_LLDP_CFG UINT32_C(0x41b)
/* DCBX ETS configuration structured data ID. */
#define HWRM_STRUCT_HDR_STRUCT_ID_DCBX_ETS UINT32_C(0x41d)
/* DCBX PFC configuration structured data ID. */
#define HWRM_STRUCT_HDR_STRUCT_ID_DCBX_PFC UINT32_C(0x41f)
/* DCBX APP configuration structured data ID. */
#define HWRM_STRUCT_HDR_STRUCT_ID_DCBX_APP UINT32_C(0x421)
/*
* DCBX state configuration structured data ID for all DCBX
* features.
*/
#define HWRM_STRUCT_HDR_STRUCT_ID_DCBX_FEATURE_STATE UINT32_C(0x422)
/*
* LLDP generic structured data ID. This is used with
* GET_STRUCTURED_DATA only.
*/
#define HWRM_STRUCT_HDR_STRUCT_ID_LLDP_GENERIC UINT32_C(0x424)
/*
* LLDP device structured data ID. This is used with
* GET_STRUCTURED_DATA only.
*/
#define HWRM_STRUCT_HDR_STRUCT_ID_LLDP_DEVICE UINT32_C(0x426)
/* reserved for AFM usage. */
#define HWRM_STRUCT_HDR_STRUCT_ID_AFM_OPAQUE UINT32_C(0x1)
/* Port description. */
#define HWRM_STRUCT_HDR_STRUCT_ID_PORT_DESCRIPTION UINT32_C(0xa)
/* RSSv2 Configuration. */
#define HWRM_STRUCT_HDR_STRUCT_ID_RSS_V2 UINT32_C(0x64)
uint16_t len;
/* This value indicates the length of structured data. */
uint8_t version;
/* This value indicates the version of structured data. */
uint8_t count;
/* This value indicates the number of structured data elements. */
uint16_t subtype;
/* This value indicates the subtype. */
uint16_t next_offset;
/*
* This value indicates the count of 64-bit values that point to the
* next header. A value of 0 means that this is the last element. The
* value is a count of 64-bit words from the beginning of the current
* header.
*/
/* This value indicates this is the last element */
#define HWRM_STRUCT_HDR_NEXT_OFFSET_LAST UINT32_C(0x0)
uint16_t unused_0[3];
} __attribute__((packed));
/* DCBX ETS configuration structure (1053) (32 bytes) */
struct hwrm_struct_data_dcbx_ets {
uint8_t destination;
/*
* This field indicates if this configuration is ETS recommendation or
* ETS configuration. A value 1 means it is ETS configuration, A value
* of 2 means it is a ETS recommendation.
*/
/* ETS configuration */
#define HWRM_STRUCT_DATA_DCBX_ETS_DESTINATION_CONFIGURATION UINT32_C(0x1)
/* ETS recommendation */
#define HWRM_STRUCT_DATA_DCBX_ETS_DESTINATION_RECOMMMENDATION UINT32_C(0x2)
uint8_t max_tcs;
/* This value indicates maximum ETS TCs supported. */
uint16_t unused_0;
/* unused. */
uint8_t pri0_to_tc_map;
/* ETS priority 0 to TC map. */
uint8_t pri1_to_tc_map;
/* ETS priority 1 to TC map. */
uint8_t pri2_to_tc_map;
/* ETS priority 2 to TC map. */
uint8_t pri3_to_tc_map;
/* ETS priority 3 to TC map. */
uint8_t pri4_to_tc_map;
/* ETS priority 4 to TC map. */
uint8_t pri5_to_tc_map;
/* ETS priority 5 to TC map. */
uint8_t pri6_to_tc_map;
/* ETS priority 6 to TC map. */
uint8_t pri7_to_tc_map;
/* ETS priority 7 to TC map. */
uint8_t tc0_to_bw_map;
/* ETS TC 0 to bandwidth map. */
uint8_t tc1_to_bw_map;
/* ETS TC 1 to bandwidth map. */
uint8_t tc2_to_bw_map;
/* ETS TC 2 to bandwidth map. */
uint8_t tc3_to_bw_map;
/* ETS TC 3 to bandwidth map. */
uint8_t tc4_to_bw_map;
/* ETS TC 4 to bandwidth map. */
uint8_t tc5_to_bw_map;
/* ETS TC 5 to bandwidth map. */
uint8_t tc6_to_bw_map;
/* ETS TC 6 to bandwidth map. */
uint8_t tc7_to_bw_map;
/* ETS TC 7 to bandwidth map. */
uint8_t tc0_to_tsa_map;
/* ETS TC 0 to TSA map. */
/* strict priority */
#define HWRM_STRUCT_DATA_DCBX_ETS_TC0_TO_TSA_MAP_TSA_TYPE_SP UINT32_C(0x0)
/* credit based shaper */
#define HWRM_STRUCT_DATA_DCBX_ETS_TC0_TO_TSA_MAP_TSA_TYPE_CBS UINT32_C(0x1)
/* ETS */
#define HWRM_STRUCT_DATA_DCBX_ETS_TC0_TO_TSA_MAP_TSA_TYPE_ETS UINT32_C(0x2)
/* vendor specific */
#define HWRM_STRUCT_DATA_DCBX_ETS_TC0_TO_TSA_MAP_TSA_TYPE_VENDOR_SPECIFIC UINT32_C(0xff)
uint8_t tc1_to_tsa_map;
/* ETS TC 1 to TSA map. */
uint8_t tc2_to_tsa_map;
/* ETS TC 2 to TSA map. */
uint8_t tc3_to_tsa_map;
/* ETS TC 3 to TSA map. */
uint8_t tc4_to_tsa_map;
/* ETS TC 4 to TSA map. */
uint8_t tc5_to_tsa_map;
/* ETS TC 5 to TSA map. */
uint8_t tc6_to_tsa_map;
/* ETS TC 6 to TSA map. */
uint8_t tc7_to_tsa_map;
/* ETS TC 7 to TSA map. */
uint32_t unused_1;
} __attribute__((packed));
/* DCBX PFC configuration structure (1055) (8 bytes) */
struct hwrm_struct_data_dcbx_pfc {
uint8_t pfc_priority_bitmap;
/*
* This field indicates PFC priority bit map. A value of '0' indicates
* PFC is disabled. A value of '1' indicates PFC is enabled on that
* priority.
*/
uint8_t max_pfc_tcs;
/*
* This field indicates max PFC TCs supported. Each PFC TC will map to a
* lossless CoS queue.
*/
uint8_t mbc;
/*
* This field indicates if MACSec bypass capability is enabled. A value
* of '1' indicates MBC is enabled. A value of '0' indicates MBC is
* disabled.
*/
uint8_t unused_0[5];
} __attribute__((packed));
/* DCBX Application configuration structure (1057) (8 bytes) */
struct hwrm_struct_data_dcbx_app {
uint16_t protocol_id; /* big endian */
/*
* This field indicates the protocol identifier. This should be
* specified in big endian format.
*/
uint8_t protocol_selector;
/*
* This field indicates the protocol selector. The valid values are
* mentioned below.
*/
/* ether type */
#define HWRM_STRUCT_DATA_DCBX_APP_PROTOCOL_SELECTOR_ETHER_TYPE UINT32_C(0x1)
/* TCP port */
#define HWRM_STRUCT_DATA_DCBX_APP_PROTOCOL_SELECTOR_TCP_PORT UINT32_C(0x2)
/* UDP port */
#define HWRM_STRUCT_DATA_DCBX_APP_PROTOCOL_SELECTOR_UDP_PORT UINT32_C(0x3)
/* TCP & UDP port */
#define HWRM_STRUCT_DATA_DCBX_APP_PROTOCOL_SELECTOR_TCP_UDP_PORT UINT32_C(0x4)
uint8_t priority;
/* This field indicates application priority. */
uint8_t valid;
/* This field indicates this entry is valid. */
uint8_t unused_0[3];
} __attribute__((packed));
/* DCBX feature states configuration structure (1058) (8 bytes) */
struct hwrm_struct_data_dcbx_feature_state {
uint8_t dcbx_mode;
/* DCBX mode - IEEE or CEE. This is read only field. */
/* DCBX disabled mode. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_DCBX_MODE_DCBX_DISABLED UINT32_C(0x0)
/* DCBX IEEE mode. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_DCBX_MODE_DCBX_IEEE UINT32_C(0x1)
/* DCBX CEE mode. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_DCBX_MODE_DCBX_CEE UINT32_C(0x2)
uint8_t ets_state;
/* ETS TLV state. */
uint8_t pfc_state;
/* PFC TLV state. */
uint8_t app_state;
/* App TLV state. */
/* Feature enable bit position. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_APP_STATE_ENABLE_BIT_POS UINT32_C(0x7)
/* Feature willing bit position. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_APP_STATE_WILLING_BIT_POS UINT32_C(0x6)
/* Feature advertise bit position. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_APP_STATE_ADVERTISE_BIT_POS UINT32_C(0x5)
uint8_t unused_0[3];
/* unused. */
uint8_t resets;
/*
* This field is used to reset the DCBX configuration to factory
* defaults.
*/
/* reset ETS configuration. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_RESETS_RESET_ETS UINT32_C(0x1)
/* reset PFC configuration. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_RESETS_RESET_PFC UINT32_C(0x2)
/* reset application configuration. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_RESETS_RESET_APP UINT32_C(0x4)
/* reset DCBX state configuration. */
#define HWRM_STRUCT_DATA_DCBX_FEATURE_STATE_RESETS_RESET_STATE UINT32_C(0x8)
} __attribute__((packed));
/* LLDP TLVs transmit configuration structure (1051) (8 bytes) */
struct hwrm_struct_data_lldp {
uint8_t admin_state;
/* Port admin state */
/* Disable both Tx and Rx */
#define HWRM_STRUCT_DATA_LLDP_ADMIN_STATE_DISABLE UINT32_C(0x0)
/* Enable Tx only */
#define HWRM_STRUCT_DATA_LLDP_ADMIN_STATE_TX UINT32_C(0x1)
/* Enable Rx only */
#define HWRM_STRUCT_DATA_LLDP_ADMIN_STATE_RX UINT32_C(0x2)
/* Enable both Tx and Rx */
#define HWRM_STRUCT_DATA_LLDP_ADMIN_STATE_ENABLE UINT32_C(0x3)
uint8_t port_description_state;
/* Port desciption TLV transmit state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_PORT_DESCRIPTION_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_PORT_DESCRIPTION_STATE_ENABLE UINT32_C(0x1)
uint8_t system_name_state;
/* System name TLV transmit state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_NAME_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_NAME_STATE_ENABLE UINT32_C(0x1)
uint8_t system_desc_state;
/* System desciption TLV transmit state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_DESC_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_DESC_STATE_ENABLE UINT32_C(0x1)
uint8_t system_cap_state;
/* System capabilities TLV transmit state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_CAP_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_SYSTEM_CAP_STATE_ENABLE UINT32_C(0x1)
uint8_t mgmt_addr_state;
/* Management address TLV transmit state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_MGMT_ADDR_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_MGMT_ADDR_STATE_ENABLE UINT32_C(0x1)
uint8_t async_event_notification_state;
/* Async event notification state (enable(1)/disable(0)). */
/* Disable */
#define HWRM_STRUCT_DATA_LLDP_ASYNC_EVENT_NOTIFICATION_STATE_DISABLE UINT32_C(0x0)
/* Enable */
#define HWRM_STRUCT_DATA_LLDP_ASYNC_EVENT_NOTIFICATION_STATE_ENABLE UINT32_C(0x1)
uint8_t unused_0;
} __attribute__((packed));
/* LLDP generic TLV configuration (1060) (16 bytes) */
struct hwrm_struct_data_lldp_generic {
uint8_t tlv_type;
/* TLV type. */
/* Chassis ID TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_CHASSIS UINT32_C(0x1)
/* Port ID TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_PORT UINT32_C(0x2)
/* System name TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_SYSTEM_NAME UINT32_C(0x3)
/* System description TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_SYSTEM_DESCRIPTION UINT32_C(0x4)
/* Port name TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_PORT_NAME UINT32_C(0x5)
/* Port description TLV */
#define HWRM_STRUCT_DATA_LLDP_GENERIC_TLV_TYPE_PORT_DESCRIPTION UINT32_C(0x6)
uint8_t subtype;
/* TLV sub-type. */
uint8_t length;
/* Length. */
uint8_t unused_0;
/* unused. */
uint32_t unused_1;
uint32_t tlv_value[64];
/* TLV value. */
} __attribute__((packed));
/* LLDP device TLV configuration (1062) (64 bytes) */
struct hwrm_struct_data_lldp_device {
uint16_t ttl;
/* Time to Live. */
uint8_t mgmt_addr_len;
/* Management address length. */
uint8_t mgmt_addr_type;
/* Management address type. */
uint32_t unused_0;
uint32_t mgmt_addr[8];
/* Management address. */
uint32_t system_caps;
/* System capabilities. */
uint8_t intf_num_type;
/* Interface number type. */
uint8_t mgmt_addr_oid_length;
/* Management address OID length. */
uint8_t unused_1;
uint8_t unused_2;
uint32_t intf_num;
/* Interface number. */
uint32_t unused_3;
uint32_t mgmt_addr_oid[32];
/* Management address OID. */
} __attribute__((packed));
/* port description (10) (8 bytes) */
struct hwrm_struct_data_port_description {
uint8_t port_id;
/*
* Port #. Port number starts at 0 and anything greater than number of
* ports minus 1 is an error.
*/
uint8_t unused_0[7];
} __attribute__((packed));
/* RSSv2 Configuration (100) (16 bytes) */
struct hwrm_struct_data_rss_v2 {
uint16_t flags;
/* When this bit is '1', the hash type and hash key are included. */
#define HWRM_STRUCT_DATA_RSS_V2_FLAGS_HASH_VALID UINT32_C(0x1)
uint16_t rss_ctx_id;
/* RSS Context index. */
uint16_t num_ring_groups;
/* Number ring group IDs. */
uint16_t hash_type;
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv4 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_IPV4 UINT32_C(0x1)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* TCP/IPv4 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_TCP_IPV4 UINT32_C(0x2)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv4 addresses and source/destination ports of
* UDP/IPv4 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_UDP_IPV4 UINT32_C(0x4)
/*
* When this bit is '1', the RSS hash shall be computed over source and
* destination IPv4 addresses of IPv6 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_IPV6 UINT32_C(0x8)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* TCP/IPv6 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_TCP_IPV6 UINT32_C(0x10)
/*
* When this bit is '1', the RSS hash shall be computed over
* source/destination IPv6 addresses and source/destination ports of
* UDP/IPv6 packets.
*/
#define HWRM_STRUCT_DATA_RSS_V2_HASH_TYPE_UDP_IPV6 UINT32_C(0x20)
uint64_t hash_key_ring_group_ids;
/* Variable size data. Hash key (optional) followed by ring_group_ids. */
} __attribute__((packed));
#endif /* _HSI_STRUCT_DEF_EXTERNAL_H_ */