freebsd-skq/sys/contrib/octeon-sdk/cvmx-wqe.h
Juli Mallett dc4ee6ca91 Merge the Cavium Octeon SDK 2.3.0 Simple Executive code and update FreeBSD to
make use of it where possible.

This primarily brings in support for newer hardware, and FreeBSD is not yet
able to support the abundance of IRQs on new hardware and many features in the
Ethernet driver.

Because of the changes to IRQs in the Simple Executive, we have to maintain our
own list of Octeon IRQs now, which probably can be pared-down and be specific
to the CIU interrupt unit soon, and when other interrupt mechanisms are added
they can maintain their own definitions.

Remove unmasking of interrupts from within the UART device now that the
function used is no longer present in the Simple Executive.  The unmasking
seems to have been gratuitous as this is more properly handled by the buses
above the UART device, and seems to work on that basis.
2012-03-11 06:17:49 +00:00

712 lines
39 KiB
C

/***********************license start***************
* Copyright (c) 2003-2010 Cavium Inc. (support@cavium.com). All rights
* reserved.
*
*
* 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.
* * Neither the name of Cavium Inc. nor the names of
* its contributors may be used to endorse or promote products
* derived from this software without specific prior written
* permission.
* This Software, including technical data, may be subject to U.S. export control
* laws, including the U.S. Export Administration Act and its associated
* regulations, and may be subject to export or import regulations in other
* countries.
* TO THE MAXIMUM EXTENT PERMITTED BY LAW, THE SOFTWARE IS PROVIDED "AS IS"
* AND WITH ALL FAULTS AND CAVIUM INC. MAKES NO PROMISES, REPRESENTATIONS OR
* WARRANTIES, EITHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, WITH RESPECT TO
* THE SOFTWARE, INCLUDING ITS CONDITION, ITS CONFORMITY TO ANY REPRESENTATION OR
* DESCRIPTION, OR THE EXISTENCE OF ANY LATENT OR PATENT DEFECTS, AND CAVIUM
* SPECIFICALLY DISCLAIMS ALL IMPLIED (IF ANY) WARRANTIES OF TITLE,
* MERCHANTABILITY, NONINFRINGEMENT, FITNESS FOR A PARTICULAR PURPOSE, LACK OF
* VIRUSES, ACCURACY OR COMPLETENESS, QUIET ENJOYMENT, QUIET POSSESSION OR
* CORRESPONDENCE TO DESCRIPTION. THE ENTIRE RISK ARISING OUT OF USE OR
* PERFORMANCE OF THE SOFTWARE LIES WITH YOU.
***********************license end**************************************/
/**
* @file
*
* This header file defines the work queue entry (wqe) data structure.
* Since this is a commonly used structure that depends on structures
* from several hardware blocks, those definitions have been placed
* in this file to create a single point of definition of the wqe
* format.
* Data structures are still named according to the block that they
* relate to.
*
* This file must not depend on any other header files, except for cvmx.h!!!
*
*
* <hr>$Revision: 70030 $<hr>
*
*
*/
#ifndef __CVMX_WQE_H__
#define __CVMX_WQE_H__
#ifdef __cplusplus
extern "C" {
#endif
#define OCT_TAG_TYPE_STRING(x) (((x) == CVMX_POW_TAG_TYPE_ORDERED) ? "ORDERED" : \
(((x) == CVMX_POW_TAG_TYPE_ATOMIC) ? "ATOMIC" : \
(((x) == CVMX_POW_TAG_TYPE_NULL) ? "NULL" : \
"NULL_NULL")))
/**
* HW decode / err_code in work queue entry
*/
typedef union
{
uint64_t u64;
/** Use this struct if the hardware determines that the packet is IP */
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t ip_offset : 8; /**< HW sets to the number of L2 bytes prior to the IP */
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t varies:12; /**< 38xx and 68xx have different definitions. */
uint64_t dec_ipcomp : 1; /**< the packet needs to be decompressed */
uint64_t tcp_or_udp : 1; /**< the packet is either TCP or UDP */
uint64_t dec_ipsec : 1; /**< the packet needs to be decrypted (ESP or AH) */
uint64_t is_v6 : 1; /**< the packet is IPv6 */
/* (rcv_error, not_IP, IP_exc, is_frag, L4_error, software, etc.) */
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
/* exceptional conditions below */
uint64_t L4_error : 1; /**< the receive interface hardware detected an L4 error (only applies if !is_frag)
(only applies if !rcv_error && !not_IP && !IP_exc && !is_frag)
failure indicated in err_code below, decode:
- 1 = Malformed L4
- 2 = L4 Checksum Error: the L4 checksum value is
- 3 = UDP Length Error: The UDP length field would make the UDP data longer than what
remains in the IP packet (as defined by the IP header length field).
- 4 = Bad L4 Port: either the source or destination TCP/UDP port is 0.
- 8 = TCP FIN Only: the packet is TCP and only the FIN flag set.
- 9 = TCP No Flags: the packet is TCP and no flags are set.
- 10 = TCP FIN RST: the packet is TCP and both FIN and RST are set.
- 11 = TCP SYN URG: the packet is TCP and both SYN and URG are set.
- 12 = TCP SYN RST: the packet is TCP and both SYN and RST are set.
- 13 = TCP SYN FIN: the packet is TCP and both SYN and FIN are set. */
uint64_t is_frag : 1; /**< set if the packet is a fragment */
uint64_t IP_exc : 1; /**< the receive interface hardware detected an IP error / exception
(only applies if !rcv_error && !not_IP) failure indicated in err_code below, decode:
- 1 = Not IP: the IP version field is neither 4 nor 6.
- 2 = IPv4 Header Checksum Error: the IPv4 header has a checksum violation.
- 3 = IP Malformed Header: the packet is not long enough to contain the IP header.
- 4 = IP Malformed: the packet is not long enough to contain the bytes indicated by the IP
header. Pad is allowed.
- 5 = IP TTL Hop: the IPv4 TTL field or the IPv6 Hop Count field are zero.
- 6 = IP Options */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be zero in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error (must be zero in this case) */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /**< type is cvmx_pip_err_t */
} s;
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t ip_offset : 8; /**< HW sets to the number of L2 bytes prior to the IP */
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t port:12; /**< MAC/PIP port number. */
uint64_t dec_ipcomp : 1; /**< the packet needs to be decompressed */
uint64_t tcp_or_udp : 1; /**< the packet is either TCP or UDP */
uint64_t dec_ipsec : 1; /**< the packet needs to be decrypted (ESP or AH) */
uint64_t is_v6 : 1; /**< the packet is IPv6 */
/* (rcv_error, not_IP, IP_exc, is_frag, L4_error, software, etc.) */
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
/* exceptional conditions below */
uint64_t L4_error : 1; /**< the receive interface hardware detected an L4 error (only applies if !is_frag)
(only applies if !rcv_error && !not_IP && !IP_exc && !is_frag)
failure indicated in err_code below, decode:
- 1 = Malformed L4
- 2 = L4 Checksum Error: the L4 checksum value is
- 3 = UDP Length Error: The UDP length field would make the UDP data longer than what
remains in the IP packet (as defined by the IP header length field).
- 4 = Bad L4 Port: either the source or destination TCP/UDP port is 0.
- 8 = TCP FIN Only: the packet is TCP and only the FIN flag set.
- 9 = TCP No Flags: the packet is TCP and no flags are set.
- 10 = TCP FIN RST: the packet is TCP and both FIN and RST are set.
- 11 = TCP SYN URG: the packet is TCP and both SYN and URG are set.
- 12 = TCP SYN RST: the packet is TCP and both SYN and RST are set.
- 13 = TCP SYN FIN: the packet is TCP and both SYN and FIN are set. */
uint64_t is_frag : 1; /**< set if the packet is a fragment */
uint64_t IP_exc : 1; /**< the receive interface hardware detected an IP error / exception
(only applies if !rcv_error && !not_IP) failure indicated in err_code below, decode:
- 1 = Not IP: the IP version field is neither 4 nor 6.
- 2 = IPv4 Header Checksum Error: the IPv4 header has a checksum violation.
- 3 = IP Malformed Header: the packet is not long enough to contain the IP header.
- 4 = IP Malformed: the packet is not long enough to contain the bytes indicated by the IP
header. Pad is allowed.
- 5 = IP TTL Hop: the IPv4 TTL field or the IPv6 Hop Count field are zero.
- 6 = IP Options */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be zero in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error (must be zero in this case) */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /**< type is cvmx_pip_err_t */
} s_cn68xx;
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t ip_offset : 8; /**< HW sets to the number of L2 bytes prior to the IP */
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t pr : 4; /**< Ring Identifier (if PCIe). Requires PIP_GBL_CTL[RING_EN]=1 */
uint64_t unassigned2a :4;
uint64_t unassigned2 :4;
uint64_t dec_ipcomp : 1; /**< the packet needs to be decompressed */
uint64_t tcp_or_udp : 1; /**< the packet is either TCP or UDP */
uint64_t dec_ipsec : 1; /**< the packet needs to be decrypted (ESP or AH) */
uint64_t is_v6 : 1; /**< the packet is IPv6 */
/* (rcv_error, not_IP, IP_exc, is_frag, L4_error, software, etc.) */
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
/* exceptional conditions below */
uint64_t L4_error : 1; /**< the receive interface hardware detected an L4 error (only applies if !is_frag)
(only applies if !rcv_error && !not_IP && !IP_exc && !is_frag)
failure indicated in err_code below, decode:
- 1 = Malformed L4
- 2 = L4 Checksum Error: the L4 checksum value is
- 3 = UDP Length Error: The UDP length field would make the UDP data longer than what
remains in the IP packet (as defined by the IP header length field).
- 4 = Bad L4 Port: either the source or destination TCP/UDP port is 0.
- 8 = TCP FIN Only: the packet is TCP and only the FIN flag set.
- 9 = TCP No Flags: the packet is TCP and no flags are set.
- 10 = TCP FIN RST: the packet is TCP and both FIN and RST are set.
- 11 = TCP SYN URG: the packet is TCP and both SYN and URG are set.
- 12 = TCP SYN RST: the packet is TCP and both SYN and RST are set.
- 13 = TCP SYN FIN: the packet is TCP and both SYN and FIN are set. */
uint64_t is_frag : 1; /**< set if the packet is a fragment */
uint64_t IP_exc : 1; /**< the receive interface hardware detected an IP error / exception
(only applies if !rcv_error && !not_IP) failure indicated in err_code below, decode:
- 1 = Not IP: the IP version field is neither 4 nor 6.
- 2 = IPv4 Header Checksum Error: the IPv4 header has a checksum violation.
- 3 = IP Malformed Header: the packet is not long enough to contain the IP header.
- 4 = IP Malformed: the packet is not long enough to contain the bytes indicated by the IP
header. Pad is allowed.
- 5 = IP TTL Hop: the IPv4 TTL field or the IPv6 Hop Count field are zero.
- 6 = IP Options */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be zero in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error (must be zero in this case) */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /**< type is cvmx_pip_err_t */
} s_cn38xx;
/**< use this to get at the 16 vlan bits */
struct
{
uint64_t unused1 :16;
uint64_t vlan :16;
uint64_t unused2 :32;
} svlan;
/**< use this struct if the hardware could not determine that the packet is ip */
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t unused : 8;
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t varies:12; /**< 38xx and 68xx have different definitions. */
uint64_t unassigned2:4;
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
uint64_t unassigned3 : 1;
uint64_t is_rarp : 1; /**< set if the hardware determined that the packet is rarp */
uint64_t is_arp : 1; /**< set if the hardware determined that the packet is arp */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be one in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error.
Failure indicated in err_code below, decode:
- 1 = partial error: a packet was partially received, but internal
buffering / bandwidth was not adequate to receive the entire packet.
- 2 = jabber error: the RGMII packet was too large and is truncated.
- 3 = overrun error: the RGMII packet is longer than allowed and had
an FCS error.
- 4 = oversize error: the RGMII packet is longer than allowed.
- 5 = alignment error: the RGMII packet is not an integer number of bytes
and had an FCS error (100M and 10M only).
- 6 = fragment error: the RGMII packet is shorter than allowed and had an
FCS error.
- 7 = GMX FCS error: the RGMII packet had an FCS error.
- 8 = undersize error: the RGMII packet is shorter than allowed.
- 9 = extend error: the RGMII packet had an extend error.
- 10 = length mismatch error: the RGMII packet had a length that did not
match the length field in the L2 HDR.
- 11 = RGMII RX error/SPI4 DIP4 Error: the RGMII packet had one or more
data reception errors (RXERR) or the SPI4 packet had one or more DIP4
errors.
- 12 = RGMII skip error/SPI4 Abort Error: the RGMII packet was not large
enough to cover the skipped bytes or the SPI4 packet was terminated
with an About EOPS.
- 13 = RGMII nibble error/SPI4 Port NXA Error: the RGMII packet had a
studder error (data not repeated - 10/100M only) or the SPI4 packet
was sent to an NXA.
- 16 = FCS error: a SPI4.2 packet had an FCS error.
- 17 = Skip error: a packet was not large enough to cover the skipped bytes.
- 18 = L2 header malformed: the packet is not long enough to contain the L2 */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /* type is cvmx_pip_err_t (union, so can't use directly */
} snoip;
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t unused : 8;
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t port:12; /**< MAC/PIP port number. */
uint64_t unassigned2:4;
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
uint64_t unassigned3 : 1;
uint64_t is_rarp : 1; /**< set if the hardware determined that the packet is rarp */
uint64_t is_arp : 1; /**< set if the hardware determined that the packet is arp */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be one in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error.
Failure indicated in err_code below, decode:
- 1 = partial error: a packet was partially received, but internal
buffering / bandwidth was not adequate to receive the entire packet.
- 2 = jabber error: the RGMII packet was too large and is truncated.
- 3 = overrun error: the RGMII packet is longer than allowed and had
an FCS error.
- 4 = oversize error: the RGMII packet is longer than allowed.
- 5 = alignment error: the RGMII packet is not an integer number of bytes
and had an FCS error (100M and 10M only).
- 6 = fragment error: the RGMII packet is shorter than allowed and had an
FCS error.
- 7 = GMX FCS error: the RGMII packet had an FCS error.
- 8 = undersize error: the RGMII packet is shorter than allowed.
- 9 = extend error: the RGMII packet had an extend error.
- 10 = length mismatch error: the RGMII packet had a length that did not
match the length field in the L2 HDR.
- 11 = RGMII RX error/SPI4 DIP4 Error: the RGMII packet had one or more
data reception errors (RXERR) or the SPI4 packet had one or more DIP4
errors.
- 12 = RGMII skip error/SPI4 Abort Error: the RGMII packet was not large
enough to cover the skipped bytes or the SPI4 packet was terminated
with an About EOPS.
- 13 = RGMII nibble error/SPI4 Port NXA Error: the RGMII packet had a
studder error (data not repeated - 10/100M only) or the SPI4 packet
was sent to an NXA.
- 16 = FCS error: a SPI4.2 packet had an FCS error.
- 17 = Skip error: a packet was not large enough to cover the skipped bytes.
- 18 = L2 header malformed: the packet is not long enough to contain the L2 */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /* type is cvmx_pip_err_t (union, so can't use directly */
} snoip_cn68xx;
struct
{
uint64_t bufs : 8; /**< HW sets this to the number of buffers used by this packet */
uint64_t unused : 8;
uint64_t vlan_valid : 1; /**< set to 1 if we found DSA/VLAN in the L2 */
uint64_t vlan_stacked : 1; /**< Set to 1 if the DSA/VLAN tag is stacked */
uint64_t unassigned : 1;
uint64_t vlan_cfi : 1; /**< HW sets to the DSA/VLAN CFI flag (valid when vlan_valid) */
uint64_t vlan_id :12; /**< HW sets to the DSA/VLAN_ID field (valid when vlan_valid) */
uint64_t pr : 4; /**< Ring Identifier (if PCIe). Requires PIP_GBL_CTL[RING_EN]=1 */
uint64_t unassigned2a :8;
uint64_t unassigned2 :4;
uint64_t software : 1; /**< reserved for software use, hardware will clear on packet creation */
uint64_t unassigned3 : 1;
uint64_t is_rarp : 1; /**< set if the hardware determined that the packet is rarp */
uint64_t is_arp : 1; /**< set if the hardware determined that the packet is arp */
uint64_t is_bcast : 1; /**< set if the hardware determined that the packet is a broadcast */
uint64_t is_mcast : 1; /**< set if the hardware determined that the packet is a multi-cast */
uint64_t not_IP : 1; /**< set if the packet may not be IP (must be one in this case) */
uint64_t rcv_error : 1; /**< the receive interface hardware detected a receive error.
Failure indicated in err_code below, decode:
- 1 = partial error: a packet was partially received, but internal
buffering / bandwidth was not adequate to receive the entire packet.
- 2 = jabber error: the RGMII packet was too large and is truncated.
- 3 = overrun error: the RGMII packet is longer than allowed and had
an FCS error.
- 4 = oversize error: the RGMII packet is longer than allowed.
- 5 = alignment error: the RGMII packet is not an integer number of bytes
and had an FCS error (100M and 10M only).
- 6 = fragment error: the RGMII packet is shorter than allowed and had an
FCS error.
- 7 = GMX FCS error: the RGMII packet had an FCS error.
- 8 = undersize error: the RGMII packet is shorter than allowed.
- 9 = extend error: the RGMII packet had an extend error.
- 10 = length mismatch error: the RGMII packet had a length that did not
match the length field in the L2 HDR.
- 11 = RGMII RX error/SPI4 DIP4 Error: the RGMII packet had one or more
data reception errors (RXERR) or the SPI4 packet had one or more DIP4
errors.
- 12 = RGMII skip error/SPI4 Abort Error: the RGMII packet was not large
enough to cover the skipped bytes or the SPI4 packet was terminated
with an About EOPS.
- 13 = RGMII nibble error/SPI4 Port NXA Error: the RGMII packet had a
studder error (data not repeated - 10/100M only) or the SPI4 packet
was sent to an NXA.
- 16 = FCS error: a SPI4.2 packet had an FCS error.
- 17 = Skip error: a packet was not large enough to cover the skipped bytes.
- 18 = L2 header malformed: the packet is not long enough to contain the L2 */
/* lower err_code = first-level descriptor of the work */
/* zero for packet submitted by hardware that isn't on the slow path */
uint64_t err_code : 8; /* type is cvmx_pip_err_t (union, so can't use directly */
} snoip_cn38xx;
} cvmx_pip_wqe_word2_t;
typedef union {
struct {
/**
* raw chksum result generated by the HW
*/
uint16_t hw_chksum;
/**
* Field unused by hardware - available for software
*/
uint8_t unused;
/**
* Next pointer used by hardware for list maintenance.
* May be written/read by HW before the work queue
* entry is scheduled to a PP (Only 36 bits used in
* Octeon 1)
*/
uint64_t next_ptr : 40;
} cn38xx;
struct {
uint64_t l4ptr:8; /* 56..63 */
uint64_t unused0:8; /* 48..55 */
uint64_t l3ptr:8; /* 40..47 */
uint64_t l2ptr:8; /* 32..39 */
uint64_t unused1:18; /* 14..31 */
uint64_t bpid:6; /* 8..13 */
uint64_t unused2:2; /* 6..7 */
uint64_t pknd:6; /* 0..5 */
} cn68xx;
} cvmx_pip_wqe_word0_t;
typedef union {
uint64_t u64;
cvmx_pip_wqe_word0_t pip;
struct {
uint64_t unused:24;
uint64_t next_ptr:40; /* on cn68xx this is unused as well */
} raw;
} cvmx_wqe_word0_t;
typedef union {
uint64_t u64;
struct {
uint64_t len:16;
uint64_t varies:14;
/**
* the type of the tag (ORDERED, ATOMIC, NULL)
*/
cvmx_pow_tag_type_t tag_type:2;
uint64_t tag:32;
} s;
struct {
uint64_t len:16;
uint64_t zero_0:1;
/**
* HW sets this to what it thought the priority of the input packet was
*/
uint64_t qos:3;
uint64_t zero_1:1;
/**
* the group that the work queue entry will be scheduled to
*/
uint64_t grp:6;
uint64_t zero_2:3;
cvmx_pow_tag_type_t tag_type:2;
uint64_t tag:32;
} cn68xx;
struct {
uint64_t len:16;
/**
* HW sets this to input physical port
*/
uint64_t ipprt:6;
/**
* HW sets this to what it thought the priority of the input packet was
*/
uint64_t qos:3;
/**
* the group that the work queue entry will be scheduled to
*/
uint64_t grp:4;
uint64_t zero_2:1;
cvmx_pow_tag_type_t tag_type:2;
uint64_t tag:32;
} cn38xx;
} cvmx_wqe_word1_t;
/**
* Work queue entry format
*
* must be 8-byte aligned
*/
typedef struct
{
/*****************************************************************
* WORD 0
* HW WRITE: the following 64 bits are filled by HW when a packet arrives
*/
cvmx_wqe_word0_t word0;
/*****************************************************************
* WORD 1
* HW WRITE: the following 64 bits are filled by HW when a packet arrives
*/
cvmx_wqe_word1_t word1;
/**
* WORD 2
* HW WRITE: the following 64-bits are filled in by hardware when a packet arrives
* This indicates a variety of status and error conditions.
*/
cvmx_pip_wqe_word2_t word2;
/**
* Pointer to the first segment of the packet.
*/
cvmx_buf_ptr_t packet_ptr;
/**
* HW WRITE: octeon will fill in a programmable amount from the
* packet, up to (at most, but perhaps less) the amount
* needed to fill the work queue entry to 128 bytes
* If the packet is recognized to be IP, the hardware starts (except that
* the IPv4 header is padded for appropriate alignment) writing here where
* the IP header starts.
* If the packet is not recognized to be IP, the hardware starts writing
* the beginning of the packet here.
*/
uint8_t packet_data[96];
/**
* If desired, SW can make the work Q entry any length. For the
* purposes of discussion here, Assume 128B always, as this is all that
* the hardware deals with.
*
*/
} CVMX_CACHE_LINE_ALIGNED cvmx_wqe_t;
static inline int cvmx_wqe_get_port(cvmx_wqe_t *work)
{
int port;
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
port = work->word2.s_cn68xx.port;
else
port = work->word1.cn38xx.ipprt;
return port;
}
static inline void cvmx_wqe_set_port(cvmx_wqe_t *work, int port)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
port = work->word2.s_cn68xx.port = port;
else
port = work->word1.cn38xx.ipprt = port;
}
static inline int cvmx_wqe_get_grp(cvmx_wqe_t *work)
{
int grp;
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
grp = work->word1.cn68xx.grp;
else
grp = work->word1.cn38xx.grp;
return grp;
}
static inline void cvmx_wqe_set_grp(cvmx_wqe_t *work, int grp)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
work->word1.cn68xx.grp = grp;
else
work->word1.cn38xx.grp = grp;
}
static inline int cvmx_wqe_get_qos(cvmx_wqe_t *work)
{
int qos;
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
qos = work->word1.cn68xx.qos;
else
qos = work->word1.cn38xx.qos;
return qos;
}
static inline void cvmx_wqe_set_qos(cvmx_wqe_t *work, int qos)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
work->word1.cn68xx.qos = qos;
else
work->word1.cn38xx.qos = qos;
}
static inline int cvmx_wqe_get_len(cvmx_wqe_t *work)
{
int len;
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
len = work->word1.cn68xx.len;
else
len = work->word1.cn38xx.len;
return len;
}
static inline void cvmx_wqe_set_len(cvmx_wqe_t *work, int len)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
work->word1.cn68xx.len = len;
else
work->word1.cn38xx.len = len;
}
static inline uint32_t cvmx_wqe_get_tag(cvmx_wqe_t *work)
{
return work->word1.s.tag;
}
static inline void cvmx_wqe_set_tag(cvmx_wqe_t *work, uint32_t tag)
{
work->word1.s.tag = tag;
}
static inline int cvmx_wqe_get_tt(cvmx_wqe_t *work)
{
return work->word1.s.tag_type;
}
static inline void cvmx_wqe_set_tt(cvmx_wqe_t *work, int tt)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
{
work->word1.cn68xx.tag_type = (cvmx_pow_tag_type_t)tt;
work->word1.cn68xx.zero_2 = 0;
}
else
{
work->word1.cn38xx.tag_type = (cvmx_pow_tag_type_t)tt;
work->word1.cn38xx.zero_2 = 0;
}
}
static inline int cvmx_wqe_get_unused8(cvmx_wqe_t *work)
{
int len;
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
len = work->word0.pip.cn68xx.unused1;
else
len = work->word0.pip.cn38xx.unused;
return len;
}
static inline void cvmx_wqe_set_unused8(cvmx_wqe_t *work, int v)
{
if (octeon_has_feature(OCTEON_FEATURE_CN68XX_WQE))
work->word0.pip.cn68xx.unused1 = v;
else
work->word0.pip.cn38xx.unused = v;
}
#ifdef __cplusplus
}
#endif
#endif /* __CVMX_WQE_H__ */