freebsd-dev/sys/dev/cxgbe/t4_ioctl.h

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/*-
* SPDX-License-Identifier: BSD-2-Clause-FreeBSD
*
* Copyright (c) 2011 Chelsio Communications, Inc.
* All rights reserved.
* Written by: Navdeep Parhar <np@FreeBSD.org>
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. 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 AUTHOR 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 AUTHOR 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.
*
* $FreeBSD$
*
*/
#ifndef __T4_IOCTL_H__
#define __T4_IOCTL_H__
#include <sys/types.h>
#include <net/ethernet.h>
cxgbe(4): Add support for Connection Offload Policy (aka COP). COP allows fine-grained control on whether to offload a TCP connection using t4_tom, and what settings to apply to a connection selected for offload. t4_tom must still be loaded and IFCAP_TOE must still be enabled for full TCP offload to take place on an interface. The difference is that IFCAP_TOE used to be the only knob and would enable TOE for all new connections on the inteface, but now the driver will also consult the COP, if any, before offloading to the hardware TOE. A policy is a plain text file with any number of rules, one per line. Each rule has a "match" part consisting of a socket-type (L = listen, A = active open, P = passive open, D = don't care) and a pcap-filter(7) expression, and a "settings" part that specifies whether to offload the connection or not and the parameters to use if so. The general format of a rule is: [socket-type] expr => settings Example. See cxgbetool(8) for more information. [L] ip && port http => offload [L] port 443 => !offload [L] port ssh => offload [P] src net 192.168/16 && dst port ssh => offload !nagle !timestamp cong newreno [P] dst port ssh => offload !nagle ecn cong tahoe [P] dst port http => offload [A] dst port 443 => offload tls [A] dst net 192.168/16 => offload !timestamp cong highspeed The driver processes the rules for each new listen, active open, or passive open and stops at the first match. There is an implicit rule at the end of every policy that prohibits offload when no rule in the policy matches: [D] all => !offload This is a reworked and expanded version of a patch submitted by Krishnamraju Eraparaju @ Chelsio. Sponsored by: Chelsio Communications
2018-04-14 19:07:56 +00:00
#include <net/bpf.h>
/*
* Ioctl commands specific to this driver.
*/
enum {
T4_GETREG = 0x40, /* read register */
T4_SETREG, /* write register */
T4_REGDUMP, /* dump of all registers */
T4_GET_FILTER_MODE, /* get global filter mode */
T4_SET_FILTER_MODE, /* set global filter mode */
T4_GET_FILTER, /* get information about a filter */
T4_SET_FILTER, /* program a filter */
T4_DEL_FILTER, /* delete a filter */
T4_GET_SGE_CONTEXT, /* get SGE context for a queue */
T4_LOAD_FW, /* flash firmware */
T4_GET_MEM, /* read memory */
T4_GET_I2C, /* read from i2c addressible device */
T4_CLEAR_STATS, /* clear a port's MAC statistics */
T4_SET_OFLD_POLICY, /* Set offload policy */
T4_SET_SCHED_CLASS, /* set sched class */
T4_SET_SCHED_QUEUE, /* set queue class */
Add support for packet-sniffing tracers to cxgbe(4). This works with all T4 and T5 based cards and is useful for analyzing TSO, LRO, TOE, and for general purpose monitoring without tapping any cxgbe or cxl ifnet directly. Tracers on the T4/T5 chips provide access to Ethernet frames exactly as they were received from or transmitted on the wire. On transmit, a tracer will capture a frame after TSO segmentation, hw VLAN tag insertion, hw L3 & L4 checksum insertion, etc. It will also capture frames generated by the TCP offload engine (TOE traffic is normally invisible to the kernel). On receive, a tracer will capture a frame before hw VLAN extraction, runt filtering, other badness filtering, before the steering/drop/L2-rewrite filters or the TOE have had a go at it, and of course before sw LRO in the driver. There are 4 tracers on a chip. A tracer can trace only in one direction (tx or rx). For now cxgbetool will set up tracers to capture the first 128B of every transmitted or received frame on a given port. This is a small subset of what the hardware can do. A pseudo ifnet with the same name as the nexus driver (t4nex0 or t5nex0) will be created for tracing. The data delivered to this ifnet is an additional copy made inside the chip. Normal delivery to cxgbe<n> or cxl<n> will be made as usual. /* watch cxl0, which is the first port hanging off t5nex0. */ # cxgbetool t5nex0 tracer 0 tx0 (watch what cxl0 is transmitting) # cxgbetool t5nex0 tracer 1 rx0 (watch what cxl0 is receiving) # cxgbetool t5nex0 tracer list # tcpdump -i t5nex0 <== all that cxl0 sees and puts on the wire If you were doing TSO, a tcpdump on cxl0 may have shown you ~64K "frames" with no L3/L4 checksum but this will show you the frames that were actually transmitted. /* all done */ # cxgbetool t5nex0 tracer 0 disable # cxgbetool t5nex0 tracer 1 disable # cxgbetool t5nex0 tracer list # ifconfig t5nex0 destroy
2013-07-26 22:04:11 +00:00
T4_GET_TRACER, /* get information about a tracer */
T4_SET_TRACER, /* program a tracer */
T4_LOAD_CFG, /* copy a config file to card's flash */
T4_LOAD_BOOT, /* flash boot rom */
T4_LOAD_BOOTCFG, /* flash bootcfg */
T4_CUDBG_DUMP, /* debug dump of chip state */
};
struct t4_reg {
uint32_t addr;
uint32_t size;
uint64_t val;
};
#define T4_REGDUMP_SIZE (160 * 1024)
#define T5_REGDUMP_SIZE (332 * 1024)
struct t4_regdump {
uint32_t version;
uint32_t len; /* bytes */
uint32_t *data;
};
struct t4_data {
uint32_t len;
uint8_t *data;
};
struct t4_bootrom {
uint32_t pf_offset;
uint32_t pfidx_addr;
uint32_t len;
uint8_t *data;
};
struct t4_i2c_data {
uint8_t port_id;
uint8_t dev_addr;
uint8_t offset;
uint8_t len;
uint8_t data[8];
};
/*
* A hardware filter is some valid combination of these.
*/
#define T4_FILTER_IPv4 0x1 /* IPv4 packet */
#define T4_FILTER_IPv6 0x2 /* IPv6 packet */
#define T4_FILTER_IP_SADDR 0x4 /* Source IP address or network */
#define T4_FILTER_IP_DADDR 0x8 /* Destination IP address or network */
#define T4_FILTER_IP_SPORT 0x10 /* Source IP port */
#define T4_FILTER_IP_DPORT 0x20 /* Destination IP port */
#define T4_FILTER_FCoE 0x40 /* Fibre Channel over Ethernet packet */
#define T4_FILTER_PORT 0x80 /* Physical ingress port */
#define T4_FILTER_VNIC 0x100 /* VNIC id or outer VLAN */
#define T4_FILTER_VLAN 0x200 /* VLAN ID */
#define T4_FILTER_IP_TOS 0x400 /* IPv4 TOS/IPv6 Traffic Class */
#define T4_FILTER_IP_PROTO 0x800 /* IP protocol */
#define T4_FILTER_ETH_TYPE 0x1000 /* Ethernet Type */
#define T4_FILTER_MAC_IDX 0x2000 /* MPS MAC address match index */
#define T4_FILTER_MPS_HIT_TYPE 0x4000 /* MPS match type */
#define T4_FILTER_IP_FRAGMENT 0x8000 /* IP fragment */
#define T4_FILTER_IC_VNIC 0x80000000 /* TP Ingress Config's F_VNIC
bit. It indicates whether
T4_FILTER_VNIC bit means VNIC
id (PF/VF) or outer VLAN.
0 = oVLAN, 1 = VNIC */
/* Filter action */
enum {
FILTER_PASS = 0, /* default */
FILTER_DROP,
FILTER_SWITCH
};
/* 802.1q manipulation on FILTER_SWITCH */
enum {
VLAN_NOCHANGE = 0, /* default */
VLAN_REMOVE,
VLAN_INSERT,
VLAN_REWRITE
};
/* MPS match type */
enum {
UCAST_EXACT = 0, /* exact unicast match */
UCAST_HASH = 1, /* inexact (hashed) unicast match */
MCAST_EXACT = 2, /* exact multicast match */
MCAST_HASH = 3, /* inexact (hashed) multicast match */
PROMISC = 4, /* no match but port is promiscuous */
HYPPROMISC = 5, /* port is hypervisor-promisuous + not bcast */
BCAST = 6, /* broadcast packet */
};
/* Rx steering */
enum {
DST_MODE_QUEUE, /* queue is directly specified by filter */
DST_MODE_RSS_QUEUE, /* filter specifies RSS entry containing queue */
DST_MODE_RSS, /* queue selected by default RSS hash lookup */
DST_MODE_FILT_RSS /* queue selected by hashing in filter-specified
RSS subtable */
};
enum {
NAT_MODE_NONE = 0, /* No NAT performed */
NAT_MODE_DIP, /* NAT on Dst IP */
NAT_MODE_DIP_DP, /* NAT on Dst IP, Dst Port */
NAT_MODE_DIP_DP_SIP, /* NAT on Dst IP, Dst Port and Src IP */
NAT_MODE_DIP_DP_SP, /* NAT on Dst IP, Dst Port and Src Port */
NAT_MODE_SIP_SP, /* NAT on Src IP and Src Port */
NAT_MODE_DIP_SIP_SP, /* NAT on Dst IP, Src IP and Src Port */
NAT_MODE_ALL /* NAT on entire 4-tuple */
};
struct t4_filter_tuple {
/*
* These are always available.
*/
uint8_t sip[16]; /* source IP address (IPv4 in [3:0]) */
uint8_t dip[16]; /* destination IP address (IPv4 in [3:0]) */
uint16_t sport; /* source port */
uint16_t dport; /* destination port */
/*
* A combination of these (up to 36 bits) is available. TP_VLAN_PRI_MAP
* is used to select the global mode and all filters are limited to the
* set of fields allowed by the global mode.
*/
uint16_t vnic; /* VNIC id (PF/VF) or outer VLAN tag */
uint16_t vlan; /* VLAN tag */
uint16_t ethtype; /* Ethernet type */
uint8_t tos; /* TOS/Traffic Type */
uint8_t proto; /* protocol type */
uint32_t fcoe:1; /* FCoE packet */
uint32_t iport:3; /* ingress port */
uint32_t matchtype:3; /* MPS match type */
uint32_t frag:1; /* fragmentation extension header */
uint32_t macidx:9; /* exact match MAC index */
uint32_t vlan_vld:1; /* VLAN valid */
uint32_t ovlan_vld:1; /* outer VLAN tag valid, value in "vnic" */
uint32_t pfvf_vld:1; /* VNIC id (PF/VF) valid, value in "vnic" */
};
struct t4_filter_specification {
uint32_t hitcnts:1; /* count filter hits in TCB */
uint32_t prio:1; /* filter has priority over active/server */
uint32_t type:1; /* 0 => IPv4, 1 => IPv6 */
cxgbe(4): Add support for hash filters. These filters reside in the card's memory instead of its TCAM and can be configured via a new "hashfilter" subcommand in cxgbetool. Hash and normal TCAM filters can be used together. The hardware does an exact-match of packet fields for hash filters, unlike the masked match performed for TCAM filters. Any T5/T6 card with memory can support at least half a million hash filters. The sample config file with the driver configures 512K of these, it is possible to double this to 1 million+ in some cases. The chip does an exact-match of fields of incoming datagrams with hash filters and performs the action configured for the filter if it matches. The fields to match are specified in a "filter mask" in the firmware config file. The filter mask always includes the 5-tuple (sip, dip, sport, dport, ipproto). It can, optionally, also include any subset of the filter mode (see filterMode and filterMask in the firmware config file). For example: filterMode = fragmentation, mpshittype, protocol, vlan, port, fcoe filterMask = protocol, port, vlan Exact values of the 5-tuple, the physical port, and VLAN tag would have to be provided while setting up a hash filter with the chip configuration above. Hash filters support all actions supported by TCAM filters. A packet that hits a hash filter can be dropped, let through (with optional steering to a specific queue or RSS region), switched out of another port (with optional L2 rewrite of DMAC, SMAC, VLAN tag), or get NAT'ed. (Support for some of these will show up in the driver in a follow-up commit very shortly). Sponsored by: Chelsio Communications
2018-05-09 04:09:49 +00:00
uint32_t hash:1; /* 0 => LE TCAM, 1 => Hash */
uint32_t action:2; /* drop, pass, switch */
uint32_t rpttid:1; /* report TID in RSS hash field */
uint32_t dirsteer:1; /* 0 => RSS, 1 => steer to iq */
uint32_t iq:10; /* ingress queue */
uint32_t maskhash:1; /* dirsteer=0: store RSS hash in TCB */
uint32_t dirsteerhash:1;/* dirsteer=1: 0 => TCB contains RSS hash */
/* 1 => TCB contains IQ ID */
/*
* Switch proxy/rewrite fields. An ingress packet which matches a
* filter with "switch" set will be looped back out as an egress
* packet -- potentially with some Ethernet header rewriting.
*/
uint32_t eport:2; /* egress port to switch packet out */
uint32_t newdmac:1; /* rewrite destination MAC address */
uint32_t newsmac:1; /* rewrite source MAC address */
uint32_t swapmac:1; /* swap SMAC/DMAC for loopback packet */
uint32_t newvlan:2; /* rewrite VLAN Tag */
uint32_t nat_mode:3; /* NAT operation mode */
uint32_t nat_flag_chk:1;/* check TCP flags before NAT'ing */
uint32_t nat_seq_chk; /* sequence value to use for NAT check*/
uint8_t dmac[ETHER_ADDR_LEN]; /* new destination MAC address */
uint8_t smac[ETHER_ADDR_LEN]; /* new source MAC address */
uint16_t vlan; /* VLAN Tag to insert */
uint8_t nat_dip[16]; /* destination IP to use after NAT'ing */
uint8_t nat_sip[16]; /* source IP to use after NAT'ing */
uint16_t nat_dport; /* destination port to use after NAT'ing */
uint16_t nat_sport; /* source port to use after NAT'ing */
/*
* Filter rule value/mask pairs.
*/
struct t4_filter_tuple val;
struct t4_filter_tuple mask;
};
struct t4_filter {
uint32_t idx;
uint16_t l2tidx;
uint16_t smtidx;
uint64_t hits;
struct t4_filter_specification fs;
};
/* Tx Scheduling Class parameters */
struct t4_sched_class_params {
int8_t level; /* scheduler hierarchy level */
int8_t mode; /* per-class or per-flow */
int8_t rateunit; /* bit or packet rate */
int8_t ratemode; /* %port relative or kbps absolute */
int8_t channel; /* scheduler channel [0..N] */
int8_t cl; /* scheduler class [0..N] */
int32_t minrate; /* minimum rate */
int32_t maxrate; /* maximum rate */
int16_t weight; /* percent weight */
int16_t pktsize; /* average packet size */
};
/*
* Support for "sched-class" command to allow a TX Scheduling Class to be
* programmed with various parameters.
*/
struct t4_sched_params {
int8_t subcmd; /* sub-command */
int8_t type; /* packet or flow */
union {
struct { /* sub-command SCHED_CLASS_CONFIG */
int8_t minmax; /* minmax enable */
} config;
struct t4_sched_class_params params;
uint8_t reserved[6 + 8 * 8];
} u;
};
enum {
SCHED_CLASS_SUBCMD_CONFIG, /* config sub-command */
SCHED_CLASS_SUBCMD_PARAMS, /* params sub-command */
};
enum {
SCHED_CLASS_TYPE_PACKET,
};
enum {
SCHED_CLASS_LEVEL_CL_RL, /* class rate limiter */
SCHED_CLASS_LEVEL_CL_WRR, /* class weighted round robin */
SCHED_CLASS_LEVEL_CH_RL, /* channel rate limiter */
};
enum {
SCHED_CLASS_MODE_CLASS, /* per-class scheduling */
SCHED_CLASS_MODE_FLOW, /* per-flow scheduling */
};
enum {
SCHED_CLASS_RATEUNIT_BITS, /* bit rate scheduling */
SCHED_CLASS_RATEUNIT_PKTS, /* packet rate scheduling */
};
enum {
SCHED_CLASS_RATEMODE_REL, /* percent of port bandwidth */
SCHED_CLASS_RATEMODE_ABS, /* Kb/s */
};
/*
* Support for "sched_queue" command to allow one or more NIC TX Queues to be
* bound to a TX Scheduling Class.
*/
struct t4_sched_queue {
uint8_t port;
int8_t queue; /* queue index; -1 => all queues */
int8_t cl; /* class index; -1 => unbind */
};
#define T4_SGE_CONTEXT_SIZE 24
enum {
SGE_CONTEXT_EGRESS,
SGE_CONTEXT_INGRESS,
SGE_CONTEXT_FLM,
SGE_CONTEXT_CNM
};
struct t4_sge_context {
uint32_t mem_id;
uint32_t cid;
uint32_t data[T4_SGE_CONTEXT_SIZE / 4];
};
struct t4_mem_range {
uint32_t addr;
uint32_t len;
uint32_t *data;
};
Add support for packet-sniffing tracers to cxgbe(4). This works with all T4 and T5 based cards and is useful for analyzing TSO, LRO, TOE, and for general purpose monitoring without tapping any cxgbe or cxl ifnet directly. Tracers on the T4/T5 chips provide access to Ethernet frames exactly as they were received from or transmitted on the wire. On transmit, a tracer will capture a frame after TSO segmentation, hw VLAN tag insertion, hw L3 & L4 checksum insertion, etc. It will also capture frames generated by the TCP offload engine (TOE traffic is normally invisible to the kernel). On receive, a tracer will capture a frame before hw VLAN extraction, runt filtering, other badness filtering, before the steering/drop/L2-rewrite filters or the TOE have had a go at it, and of course before sw LRO in the driver. There are 4 tracers on a chip. A tracer can trace only in one direction (tx or rx). For now cxgbetool will set up tracers to capture the first 128B of every transmitted or received frame on a given port. This is a small subset of what the hardware can do. A pseudo ifnet with the same name as the nexus driver (t4nex0 or t5nex0) will be created for tracing. The data delivered to this ifnet is an additional copy made inside the chip. Normal delivery to cxgbe<n> or cxl<n> will be made as usual. /* watch cxl0, which is the first port hanging off t5nex0. */ # cxgbetool t5nex0 tracer 0 tx0 (watch what cxl0 is transmitting) # cxgbetool t5nex0 tracer 1 rx0 (watch what cxl0 is receiving) # cxgbetool t5nex0 tracer list # tcpdump -i t5nex0 <== all that cxl0 sees and puts on the wire If you were doing TSO, a tcpdump on cxl0 may have shown you ~64K "frames" with no L3/L4 checksum but this will show you the frames that were actually transmitted. /* all done */ # cxgbetool t5nex0 tracer 0 disable # cxgbetool t5nex0 tracer 1 disable # cxgbetool t5nex0 tracer list # ifconfig t5nex0 destroy
2013-07-26 22:04:11 +00:00
#define T4_TRACE_LEN 112
struct t4_trace_params {
uint32_t data[T4_TRACE_LEN / 4];
uint32_t mask[T4_TRACE_LEN / 4];
uint16_t snap_len;
uint16_t min_len;
uint8_t skip_ofst;
uint8_t skip_len;
uint8_t invert;
uint8_t port;
};
struct t4_tracer {
uint8_t idx;
uint8_t enabled;
uint8_t valid;
struct t4_trace_params tp;
};
struct t4_cudbg_dump {
uint8_t wr_flash;
uint8_t bitmap[16];
uint32_t len;
uint8_t *data;
};
cxgbe(4): Add support for Connection Offload Policy (aka COP). COP allows fine-grained control on whether to offload a TCP connection using t4_tom, and what settings to apply to a connection selected for offload. t4_tom must still be loaded and IFCAP_TOE must still be enabled for full TCP offload to take place on an interface. The difference is that IFCAP_TOE used to be the only knob and would enable TOE for all new connections on the inteface, but now the driver will also consult the COP, if any, before offloading to the hardware TOE. A policy is a plain text file with any number of rules, one per line. Each rule has a "match" part consisting of a socket-type (L = listen, A = active open, P = passive open, D = don't care) and a pcap-filter(7) expression, and a "settings" part that specifies whether to offload the connection or not and the parameters to use if so. The general format of a rule is: [socket-type] expr => settings Example. See cxgbetool(8) for more information. [L] ip && port http => offload [L] port 443 => !offload [L] port ssh => offload [P] src net 192.168/16 && dst port ssh => offload !nagle !timestamp cong newreno [P] dst port ssh => offload !nagle ecn cong tahoe [P] dst port http => offload [A] dst port 443 => offload tls [A] dst net 192.168/16 => offload !timestamp cong highspeed The driver processes the rules for each new listen, active open, or passive open and stops at the first match. There is an implicit rule at the end of every policy that prohibits offload when no rule in the policy matches: [D] all => !offload This is a reworked and expanded version of a patch submitted by Krishnamraju Eraparaju @ Chelsio. Sponsored by: Chelsio Communications
2018-04-14 19:07:56 +00:00
enum {
OPEN_TYPE_LISTEN = 'L',
OPEN_TYPE_ACTIVE = 'A',
OPEN_TYPE_PASSIVE = 'P',
OPEN_TYPE_DONTCARE = 'D',
};
struct offload_settings {
int8_t offload;
int8_t rx_coalesce;
int8_t cong_algo;
int8_t sched_class;
int8_t tstamp;
int8_t sack;
int8_t nagle;
int8_t ecn;
int8_t ddp;
int8_t tls;
int16_t txq;
int16_t rxq;
int16_t mss;
};
struct offload_rule {
char open_type;
struct offload_settings settings;
struct bpf_program bpf_prog; /* compiled program/filter */
};
/*
* An offload policy consists of a set of rules matched in sequence. The
* settings of the first rule that matches are applied to that connection.
*/
struct t4_offload_policy {
uint32_t nrules;
struct offload_rule *rule;
};
#define CHELSIO_T4_GETREG _IOWR('f', T4_GETREG, struct t4_reg)
#define CHELSIO_T4_SETREG _IOW('f', T4_SETREG, struct t4_reg)
#define CHELSIO_T4_REGDUMP _IOWR('f', T4_REGDUMP, struct t4_regdump)
#define CHELSIO_T4_GET_FILTER_MODE _IOWR('f', T4_GET_FILTER_MODE, uint32_t)
#define CHELSIO_T4_SET_FILTER_MODE _IOW('f', T4_SET_FILTER_MODE, uint32_t)
#define CHELSIO_T4_GET_FILTER _IOWR('f', T4_GET_FILTER, struct t4_filter)
cxgbe(4): Add support for hash filters. These filters reside in the card's memory instead of its TCAM and can be configured via a new "hashfilter" subcommand in cxgbetool. Hash and normal TCAM filters can be used together. The hardware does an exact-match of packet fields for hash filters, unlike the masked match performed for TCAM filters. Any T5/T6 card with memory can support at least half a million hash filters. The sample config file with the driver configures 512K of these, it is possible to double this to 1 million+ in some cases. The chip does an exact-match of fields of incoming datagrams with hash filters and performs the action configured for the filter if it matches. The fields to match are specified in a "filter mask" in the firmware config file. The filter mask always includes the 5-tuple (sip, dip, sport, dport, ipproto). It can, optionally, also include any subset of the filter mode (see filterMode and filterMask in the firmware config file). For example: filterMode = fragmentation, mpshittype, protocol, vlan, port, fcoe filterMask = protocol, port, vlan Exact values of the 5-tuple, the physical port, and VLAN tag would have to be provided while setting up a hash filter with the chip configuration above. Hash filters support all actions supported by TCAM filters. A packet that hits a hash filter can be dropped, let through (with optional steering to a specific queue or RSS region), switched out of another port (with optional L2 rewrite of DMAC, SMAC, VLAN tag), or get NAT'ed. (Support for some of these will show up in the driver in a follow-up commit very shortly). Sponsored by: Chelsio Communications
2018-05-09 04:09:49 +00:00
#define CHELSIO_T4_SET_FILTER _IOWR('f', T4_SET_FILTER, struct t4_filter)
#define CHELSIO_T4_DEL_FILTER _IOW('f', T4_DEL_FILTER, struct t4_filter)
#define CHELSIO_T4_GET_SGE_CONTEXT _IOWR('f', T4_GET_SGE_CONTEXT, \
struct t4_sge_context)
#define CHELSIO_T4_LOAD_FW _IOW('f', T4_LOAD_FW, struct t4_data)
#define CHELSIO_T4_GET_MEM _IOW('f', T4_GET_MEM, struct t4_mem_range)
#define CHELSIO_T4_GET_I2C _IOWR('f', T4_GET_I2C, struct t4_i2c_data)
#define CHELSIO_T4_CLEAR_STATS _IOW('f', T4_CLEAR_STATS, uint32_t)
#define CHELSIO_T4_SCHED_CLASS _IOW('f', T4_SET_SCHED_CLASS, \
struct t4_sched_params)
#define CHELSIO_T4_SCHED_QUEUE _IOW('f', T4_SET_SCHED_QUEUE, \
struct t4_sched_queue)
Add support for packet-sniffing tracers to cxgbe(4). This works with all T4 and T5 based cards and is useful for analyzing TSO, LRO, TOE, and for general purpose monitoring without tapping any cxgbe or cxl ifnet directly. Tracers on the T4/T5 chips provide access to Ethernet frames exactly as they were received from or transmitted on the wire. On transmit, a tracer will capture a frame after TSO segmentation, hw VLAN tag insertion, hw L3 & L4 checksum insertion, etc. It will also capture frames generated by the TCP offload engine (TOE traffic is normally invisible to the kernel). On receive, a tracer will capture a frame before hw VLAN extraction, runt filtering, other badness filtering, before the steering/drop/L2-rewrite filters or the TOE have had a go at it, and of course before sw LRO in the driver. There are 4 tracers on a chip. A tracer can trace only in one direction (tx or rx). For now cxgbetool will set up tracers to capture the first 128B of every transmitted or received frame on a given port. This is a small subset of what the hardware can do. A pseudo ifnet with the same name as the nexus driver (t4nex0 or t5nex0) will be created for tracing. The data delivered to this ifnet is an additional copy made inside the chip. Normal delivery to cxgbe<n> or cxl<n> will be made as usual. /* watch cxl0, which is the first port hanging off t5nex0. */ # cxgbetool t5nex0 tracer 0 tx0 (watch what cxl0 is transmitting) # cxgbetool t5nex0 tracer 1 rx0 (watch what cxl0 is receiving) # cxgbetool t5nex0 tracer list # tcpdump -i t5nex0 <== all that cxl0 sees and puts on the wire If you were doing TSO, a tcpdump on cxl0 may have shown you ~64K "frames" with no L3/L4 checksum but this will show you the frames that were actually transmitted. /* all done */ # cxgbetool t5nex0 tracer 0 disable # cxgbetool t5nex0 tracer 1 disable # cxgbetool t5nex0 tracer list # ifconfig t5nex0 destroy
2013-07-26 22:04:11 +00:00
#define CHELSIO_T4_GET_TRACER _IOWR('f', T4_GET_TRACER, struct t4_tracer)
#define CHELSIO_T4_SET_TRACER _IOW('f', T4_SET_TRACER, struct t4_tracer)
#define CHELSIO_T4_LOAD_CFG _IOW('f', T4_LOAD_CFG, struct t4_data)
#define CHELSIO_T4_LOAD_BOOT _IOW('f', T4_LOAD_BOOT, struct t4_bootrom)
#define CHELSIO_T4_LOAD_BOOTCFG _IOW('f', T4_LOAD_BOOTCFG, struct t4_data)
#define CHELSIO_T4_CUDBG_DUMP _IOWR('f', T4_CUDBG_DUMP, struct t4_cudbg_dump)
cxgbe(4): Add support for Connection Offload Policy (aka COP). COP allows fine-grained control on whether to offload a TCP connection using t4_tom, and what settings to apply to a connection selected for offload. t4_tom must still be loaded and IFCAP_TOE must still be enabled for full TCP offload to take place on an interface. The difference is that IFCAP_TOE used to be the only knob and would enable TOE for all new connections on the inteface, but now the driver will also consult the COP, if any, before offloading to the hardware TOE. A policy is a plain text file with any number of rules, one per line. Each rule has a "match" part consisting of a socket-type (L = listen, A = active open, P = passive open, D = don't care) and a pcap-filter(7) expression, and a "settings" part that specifies whether to offload the connection or not and the parameters to use if so. The general format of a rule is: [socket-type] expr => settings Example. See cxgbetool(8) for more information. [L] ip && port http => offload [L] port 443 => !offload [L] port ssh => offload [P] src net 192.168/16 && dst port ssh => offload !nagle !timestamp cong newreno [P] dst port ssh => offload !nagle ecn cong tahoe [P] dst port http => offload [A] dst port 443 => offload tls [A] dst net 192.168/16 => offload !timestamp cong highspeed The driver processes the rules for each new listen, active open, or passive open and stops at the first match. There is an implicit rule at the end of every policy that prohibits offload when no rule in the policy matches: [D] all => !offload This is a reworked and expanded version of a patch submitted by Krishnamraju Eraparaju @ Chelsio. Sponsored by: Chelsio Communications
2018-04-14 19:07:56 +00:00
#define CHELSIO_T4_SET_OFLD_POLICY _IOW('f', T4_SET_OFLD_POLICY, struct t4_offload_policy)
#endif