freebsd-skq/sys/dev/cxgbe/adapter.h

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/*-
* 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_ADAPTER_H__
#define __T4_ADAPTER_H__
#include <sys/kernel.h>
#include <sys/bus.h>
#include <sys/rman.h>
#include <sys/types.h>
#include <sys/lock.h>
#include <sys/malloc.h>
#include <sys/rwlock.h>
#include <sys/sx.h>
#include <vm/uma.h>
#include <dev/pci/pcivar.h>
#include <dev/pci/pcireg.h>
#include <machine/bus.h>
#include <sys/socket.h>
#include <sys/sysctl.h>
#include <net/ethernet.h>
#include <net/if.h>
#include <net/if_var.h>
#include <net/if_media.h>
#include <netinet/in.h>
#include <netinet/tcp_lro.h>
#include "offload.h"
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
#include "common/t4_msg.h"
#include "firmware/t4fw_interface.h"
#define KTR_CXGBE KTR_SPARE3
MALLOC_DECLARE(M_CXGBE);
#define CXGBE_UNIMPLEMENTED(s) \
panic("%s (%s, line %d) not implemented yet.", s, __FILE__, __LINE__)
#if defined(__i386__) || defined(__amd64__)
static __inline void
prefetch(void *x)
{
__asm volatile("prefetcht0 %0" :: "m" (*(unsigned long *)x));
}
#else
#define prefetch(x)
#endif
#ifndef SYSCTL_ADD_UQUAD
#define SYSCTL_ADD_UQUAD SYSCTL_ADD_QUAD
#define sysctl_handle_64 sysctl_handle_quad
#define CTLTYPE_U64 CTLTYPE_QUAD
#endif
#if (__FreeBSD_version >= 900030) || \
((__FreeBSD_version >= 802507) && (__FreeBSD_version < 900000))
#define SBUF_DRAIN 1
#endif
#ifdef __amd64__
/* XXX: need systemwide bus_space_read_8/bus_space_write_8 */
static __inline uint64_t
t4_bus_space_read_8(bus_space_tag_t tag, bus_space_handle_t handle,
bus_size_t offset)
{
KASSERT(tag == X86_BUS_SPACE_MEM,
("%s: can only handle mem space", __func__));
return (*(volatile uint64_t *)(handle + offset));
}
static __inline void
t4_bus_space_write_8(bus_space_tag_t tag, bus_space_handle_t bsh,
bus_size_t offset, uint64_t value)
{
KASSERT(tag == X86_BUS_SPACE_MEM,
("%s: can only handle mem space", __func__));
*(volatile uint64_t *)(bsh + offset) = value;
}
#else
static __inline uint64_t
t4_bus_space_read_8(bus_space_tag_t tag, bus_space_handle_t handle,
bus_size_t offset)
{
return (uint64_t)bus_space_read_4(tag, handle, offset) +
((uint64_t)bus_space_read_4(tag, handle, offset + 4) << 32);
}
static __inline void
t4_bus_space_write_8(bus_space_tag_t tag, bus_space_handle_t bsh,
bus_size_t offset, uint64_t value)
{
bus_space_write_4(tag, bsh, offset, value);
bus_space_write_4(tag, bsh, offset + 4, value >> 32);
}
#endif
struct adapter;
typedef struct adapter adapter_t;
enum {
/*
* All ingress queues use this entry size. Note that the firmware event
* queue and any iq expecting CPL_RX_PKT in the descriptor needs this to
* be at least 64.
*/
IQ_ESIZE = 64,
/* Default queue sizes for all kinds of ingress queues */
FW_IQ_QSIZE = 256,
RX_IQ_QSIZE = 1024,
/* All egress queues use this entry size */
EQ_ESIZE = 64,
/* Default queue sizes for all kinds of egress queues */
CTRL_EQ_QSIZE = 128,
TX_EQ_QSIZE = 1024,
#if MJUMPAGESIZE != MCLBYTES
SW_ZONE_SIZES = 4, /* cluster, jumbop, jumbo9k, jumbo16k */
#else
SW_ZONE_SIZES = 3, /* cluster, jumbo9k, jumbo16k */
#endif
CL_METADATA_SIZE = CACHE_LINE_SIZE,
SGE_MAX_WR_NDESC = SGE_MAX_WR_LEN / EQ_ESIZE, /* max WR size in desc */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
TX_SGL_SEGS = 39,
TX_SGL_SEGS_TSO = 38,
TX_WR_FLITS = SGE_MAX_WR_LEN / 8
};
enum {
/* adapter intr_type */
INTR_INTX = (1 << 0),
INTR_MSI = (1 << 1),
INTR_MSIX = (1 << 2)
};
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
enum {
XGMAC_MTU = (1 << 0),
XGMAC_PROMISC = (1 << 1),
XGMAC_ALLMULTI = (1 << 2),
XGMAC_VLANEX = (1 << 3),
XGMAC_UCADDR = (1 << 4),
XGMAC_MCADDRS = (1 << 5),
XGMAC_ALL = 0xffff
};
enum {
/* flags understood by begin_synchronized_op */
HOLD_LOCK = (1 << 0),
SLEEP_OK = (1 << 1),
INTR_OK = (1 << 2),
/* flags understood by end_synchronized_op */
LOCK_HELD = HOLD_LOCK,
};
enum {
/* adapter flags */
FULL_INIT_DONE = (1 << 0),
FW_OK = (1 << 1),
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
/* INTR_DIRECT = (1 << 2), No longer used. */
MASTER_PF = (1 << 3),
ADAP_SYSCTL_CTX = (1 << 4),
/* TOM_INIT_DONE= (1 << 5), No longer used */
BUF_PACKING_OK = (1 << 6),
CXGBE_BUSY = (1 << 9),
/* port flags */
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
HAS_TRACEQ = (1 << 3),
/* VI flags */
DOOMED = (1 << 0),
VI_INIT_DONE = (1 << 1),
VI_SYSCTL_CTX = (1 << 2),
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
INTR_RXQ = (1 << 4), /* All NIC rxq's take interrupts */
INTR_OFLD_RXQ = (1 << 5), /* All TOE rxq's take interrupts */
INTR_ALL = (INTR_RXQ | INTR_OFLD_RXQ),
VI_NETMAP = (1 << 6),
/* adapter debug_flags */
DF_DUMP_MBOX = (1 << 0),
};
#define IS_DOOMED(vi) ((vi)->flags & DOOMED)
#define SET_DOOMED(vi) do {(vi)->flags |= DOOMED;} while (0)
#define IS_BUSY(sc) ((sc)->flags & CXGBE_BUSY)
#define SET_BUSY(sc) do {(sc)->flags |= CXGBE_BUSY;} while (0)
#define CLR_BUSY(sc) do {(sc)->flags &= ~CXGBE_BUSY;} while (0)
struct vi_info {
device_t dev;
struct port_info *pi;
struct ifnet *ifp;
struct ifmedia media;
unsigned long flags;
int if_flags;
uint16_t *rss;
uint16_t viid;
int16_t xact_addr_filt;/* index of exact MAC address filter */
uint16_t rss_size; /* size of VI's RSS table slice */
uint16_t rss_base; /* start of VI's RSS table slice */
eventhandler_tag vlan_c;
int nintr;
int first_intr;
/* These need to be int as they are used in sysctl */
int ntxq; /* # of tx queues */
int first_txq; /* index of first tx queue */
int rsrv_noflowq; /* Reserve queue 0 for non-flowid packets */
int nrxq; /* # of rx queues */
int first_rxq; /* index of first rx queue */
int nofldtxq; /* # of offload tx queues */
int first_ofld_txq; /* index of first offload tx queue */
int nofldrxq; /* # of offload rx queues */
int first_ofld_rxq; /* index of first offload rx queue */
int tmr_idx;
int pktc_idx;
int qsize_rxq;
int qsize_txq;
struct timeval last_refreshed;
struct fw_vi_stats_vf stats;
struct callout tick;
struct sysctl_ctx_list ctx; /* from ifconfig up to driver detach */
uint8_t hw_addr[ETHER_ADDR_LEN]; /* factory MAC address, won't change */
};
struct port_info {
device_t dev;
struct adapter *adapter;
struct vi_info *vi;
int nvi;
int up_vis;
int uld_vis;
struct mtx pi_lock;
char lockname[16];
unsigned long flags;
uint8_t lport; /* associated offload logical port */
int8_t mdio_addr;
uint8_t port_type;
uint8_t mod_type;
uint8_t port_id;
uint8_t tx_chan;
uint8_t rx_chan_map; /* rx MPS channel bitmap */
int linkdnrc;
struct link_config link_cfg;
2014-09-27 05:50:31 +00:00
struct timeval last_refreshed;
struct port_stats stats;
u_int tnl_cong_drops;
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
u_int tx_parse_error;
struct callout tick;
};
#define IS_MAIN_VI(vi) ((vi) == &((vi)->pi->vi[0]))
/* Where the cluster came from, how it has been carved up. */
struct cluster_layout {
int8_t zidx;
int8_t hwidx;
uint16_t region1; /* mbufs laid out within this region */
/* region2 is the DMA region */
uint16_t region3; /* cluster_metadata within this region */
};
struct cluster_metadata {
u_int refcount;
struct fl_sdesc *sd; /* For debug only. Could easily be stale */
};
struct fl_sdesc {
caddr_t cl;
uint16_t nmbuf; /* # of driver originated mbufs with ref on cluster */
struct cluster_layout cll;
};
struct tx_desc {
__be64 flit[8];
};
struct tx_sdesc {
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct mbuf *m; /* m_nextpkt linked chain of frames */
uint8_t desc_used; /* # of hardware descriptors used by the WR */
};
#define IQ_PAD (IQ_ESIZE - sizeof(struct rsp_ctrl) - sizeof(struct rss_header))
struct iq_desc {
struct rss_header rss;
uint8_t cpl[IQ_PAD];
struct rsp_ctrl rsp;
};
#undef IQ_PAD
CTASSERT(sizeof(struct iq_desc) == IQ_ESIZE);
enum {
/* iq flags */
IQ_ALLOCATED = (1 << 0), /* firmware resources allocated */
IQ_HAS_FL = (1 << 1), /* iq associated with a freelist */
IQ_INTR = (1 << 2), /* iq takes direct interrupt */
IQ_LRO_ENABLED = (1 << 3), /* iq is an eth rxq with LRO enabled */
/* iq state */
IQS_DISABLED = 0,
IQS_BUSY = 1,
IQS_IDLE = 2,
};
/*
* Ingress Queue: T4 is producer, driver is consumer.
*/
struct sge_iq {
uint32_t flags;
volatile int state;
struct adapter *adapter;
struct iq_desc *desc; /* KVA of descriptor ring */
int8_t intr_pktc_idx; /* packet count threshold index */
uint8_t gen; /* generation bit */
uint8_t intr_params; /* interrupt holdoff parameters */
uint8_t intr_next; /* XXX: holdoff for next interrupt */
uint16_t qsize; /* size (# of entries) of the queue */
uint16_t sidx; /* index of the entry with the status page */
uint16_t cidx; /* consumer index */
uint16_t cntxt_id; /* SGE context id for the iq */
uint16_t abs_id; /* absolute SGE id for the iq */
STAILQ_ENTRY(sge_iq) link;
bus_dma_tag_t desc_tag;
bus_dmamap_t desc_map;
bus_addr_t ba; /* bus address of descriptor ring */
};
enum {
EQ_CTRL = 1,
EQ_ETH = 2,
EQ_OFLD = 3,
/* eq flags */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
EQ_TYPEMASK = 0x3, /* 2 lsbits hold the type (see above) */
EQ_ALLOCATED = (1 << 2), /* firmware resources allocated */
EQ_ENABLED = (1 << 3), /* open for business */
};
/* Listed in order of preference. Update t4_sysctls too if you change these */
enum {DOORBELL_UDB, DOORBELL_WCWR, DOORBELL_UDBWC, DOORBELL_KDB};
/*
* Egress Queue: driver is producer, T4 is consumer.
*
* Note: A free list is an egress queue (driver produces the buffers and T4
* consumes them) but it's special enough to have its own struct (see sge_fl).
*/
struct sge_eq {
unsigned int flags; /* MUST be first */
unsigned int cntxt_id; /* SGE context id for the eq */
struct mtx eq_lock;
struct tx_desc *desc; /* KVA of descriptor ring */
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
uint16_t doorbells;
volatile uint32_t *udb; /* KVA of doorbell (lies within BAR2) */
u_int udb_qid; /* relative qid within the doorbell page */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
uint16_t sidx; /* index of the entry with the status page */
uint16_t cidx; /* consumer idx (desc idx) */
uint16_t pidx; /* producer idx (desc idx) */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
uint16_t equeqidx; /* EQUEQ last requested at this pidx */
uint16_t dbidx; /* pidx of the most recent doorbell */
uint16_t iqid; /* iq that gets egr_update for the eq */
uint8_t tx_chan; /* tx channel used by the eq */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
volatile u_int equiq; /* EQUIQ outstanding */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
bus_dma_tag_t desc_tag;
bus_dmamap_t desc_map;
bus_addr_t ba; /* bus address of descriptor ring */
char lockname[16];
};
struct sw_zone_info {
uma_zone_t zone; /* zone that this cluster comes from */
int size; /* size of cluster: 2K, 4K, 9K, 16K, etc. */
int type; /* EXT_xxx type of the cluster */
int8_t head_hwidx;
int8_t tail_hwidx;
};
struct hw_buf_info {
int8_t zidx; /* backpointer to zone; -ve means unused */
int8_t next; /* next hwidx for this zone; -1 means no more */
int size;
};
enum {
NUM_MEMWIN = 3,
MEMWIN0_APERTURE = 2048,
MEMWIN0_BASE = 0x1b800,
MEMWIN1_APERTURE = 32768,
MEMWIN1_BASE = 0x28000,
MEMWIN2_APERTURE_T4 = 65536,
MEMWIN2_BASE_T4 = 0x30000,
MEMWIN2_APERTURE_T5 = 128 * 1024,
MEMWIN2_BASE_T5 = 0x60000,
};
struct memwin {
struct rwlock mw_lock __aligned(CACHE_LINE_SIZE);
uint32_t mw_base; /* constant after setup_memwin */
uint32_t mw_aperture; /* ditto */
uint32_t mw_curpos; /* protected by mw_lock */
};
enum {
FL_STARVING = (1 << 0), /* on the adapter's list of starving fl's */
FL_DOOMED = (1 << 1), /* about to be destroyed */
FL_BUF_PACKING = (1 << 2), /* buffer packing enabled */
FL_BUF_RESUME = (1 << 3), /* resume from the middle of the frame */
};
#define FL_RUNNING_LOW(fl) \
(IDXDIFF(fl->dbidx * 8, fl->cidx, fl->sidx * 8) <= fl->lowat)
#define FL_NOT_RUNNING_LOW(fl) \
(IDXDIFF(fl->dbidx * 8, fl->cidx, fl->sidx * 8) >= 2 * fl->lowat)
struct sge_fl {
struct mtx fl_lock;
__be64 *desc; /* KVA of descriptor ring, ptr to addresses */
struct fl_sdesc *sdesc; /* KVA of software descriptor ring */
struct cluster_layout cll_def; /* default refill zone, layout */
uint16_t lowat; /* # of buffers <= this means fl needs help */
int flags;
uint16_t buf_boundary;
/* The 16b idx all deal with hw descriptors */
uint16_t dbidx; /* hw pidx after last doorbell */
uint16_t sidx; /* index of status page */
volatile uint16_t hw_cidx;
/* The 32b idx are all buffer idx, not hardware descriptor idx */
uint32_t cidx; /* consumer index */
uint32_t pidx; /* producer index */
uint32_t dbval;
u_int rx_offset; /* offset in fl buf (when buffer packing) */
volatile uint32_t *udb;
uint64_t mbuf_allocated;/* # of mbuf allocated from zone_mbuf */
uint64_t mbuf_inlined; /* # of mbuf created within clusters */
uint64_t cl_allocated; /* # of clusters allocated */
uint64_t cl_recycled; /* # of clusters recycled */
uint64_t cl_fast_recycled; /* # of clusters recycled (fast) */
/* These 3 are valid when FL_BUF_RESUME is set, stale otherwise. */
struct mbuf *m0;
struct mbuf **pnext;
u_int remaining;
uint16_t qsize; /* # of hw descriptors (status page included) */
uint16_t cntxt_id; /* SGE context id for the freelist */
TAILQ_ENTRY(sge_fl) link; /* All starving freelists */
bus_dma_tag_t desc_tag;
bus_dmamap_t desc_map;
char lockname[16];
bus_addr_t ba; /* bus address of descriptor ring */
struct cluster_layout cll_alt; /* alternate refill zone, layout */
};
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct mp_ring;
/* txq: SGE egress queue + what's needed for Ethernet NIC */
struct sge_txq {
struct sge_eq eq; /* MUST be first */
struct ifnet *ifp; /* the interface this txq belongs to */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct mp_ring *r; /* tx software ring */
struct tx_sdesc *sdesc; /* KVA of software descriptor ring */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct sglist *gl;
__be32 cpl_ctrl0; /* for convenience */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct task tx_reclaim_task;
/* stats for common events first */
uint64_t txcsum; /* # of times hardware assisted with checksum */
uint64_t tso_wrs; /* # of TSO work requests */
uint64_t vlan_insertion;/* # of times VLAN tag was inserted */
uint64_t imm_wrs; /* # of work requests with immediate data */
uint64_t sgl_wrs; /* # of work requests with direct SGL */
uint64_t txpkt_wrs; /* # of txpkt work requests (not coalesced) */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
uint64_t txpkts0_wrs; /* # of type0 coalesced tx work requests */
uint64_t txpkts1_wrs; /* # of type1 coalesced tx work requests */
uint64_t txpkts0_pkts; /* # of frames in type0 coalesced tx WRs */
uint64_t txpkts1_pkts; /* # of frames in type1 coalesced tx WRs */
/* stats for not-that-common events */
} __aligned(CACHE_LINE_SIZE);
/* rxq: SGE ingress queue + SGE free list + miscellaneous items */
struct sge_rxq {
struct sge_iq iq; /* MUST be first */
struct sge_fl fl; /* MUST follow iq */
struct ifnet *ifp; /* the interface this rxq belongs to */
#if defined(INET) || defined(INET6)
struct lro_ctrl lro; /* LRO state */
#endif
/* stats for common events first */
uint64_t rxcsum; /* # of times hardware assisted with checksum */
uint64_t vlan_extraction;/* # of times VLAN tag was extracted */
/* stats for not-that-common events */
} __aligned(CACHE_LINE_SIZE);
static inline struct sge_rxq *
iq_to_rxq(struct sge_iq *iq)
{
return (__containerof(iq, struct sge_rxq, iq));
}
/* ofld_rxq: SGE ingress queue + SGE free list + miscellaneous items */
struct sge_ofld_rxq {
struct sge_iq iq; /* MUST be first */
struct sge_fl fl; /* MUST follow iq */
} __aligned(CACHE_LINE_SIZE);
static inline struct sge_ofld_rxq *
iq_to_ofld_rxq(struct sge_iq *iq)
{
return (__containerof(iq, struct sge_ofld_rxq, iq));
}
struct wrqe {
STAILQ_ENTRY(wrqe) link;
struct sge_wrq *wrq;
int wr_len;
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
char wr[] __aligned(16);
};
struct wrq_cookie {
TAILQ_ENTRY(wrq_cookie) link;
int ndesc;
int pidx;
};
/*
* wrq: SGE egress queue that is given prebuilt work requests. Both the control
* and offload tx queues are of this type.
*/
struct sge_wrq {
struct sge_eq eq; /* MUST be first */
struct adapter *adapter;
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
struct task wrq_tx_task;
/* Tx desc reserved but WR not "committed" yet. */
TAILQ_HEAD(wrq_incomplete_wrs , wrq_cookie) incomplete_wrs;
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
/* List of WRs ready to go out as soon as descriptors are available. */
STAILQ_HEAD(, wrqe) wr_list;
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
u_int nwr_pending;
u_int ndesc_needed;
/* stats for common events first */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
uint64_t tx_wrs_direct; /* # of WRs written directly to desc ring. */
uint64_t tx_wrs_ss; /* # of WRs copied from scratch space. */
uint64_t tx_wrs_copied; /* # of WRs queued and copied to desc ring. */
/* stats for not-that-common events */
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
/*
* Scratch space for work requests that wrap around after reaching the
* status page, and some infomation about the last WR that used it.
*/
uint16_t ss_pidx;
uint16_t ss_len;
uint8_t ss[SGE_MAX_WR_LEN];
} __aligned(CACHE_LINE_SIZE);
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
struct sge_nm_rxq {
struct vi_info *vi;
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
struct iq_desc *iq_desc;
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
uint16_t iq_abs_id;
uint16_t iq_cntxt_id;
uint16_t iq_cidx;
uint16_t iq_sidx;
uint8_t iq_gen;
__be64 *fl_desc;
uint16_t fl_cntxt_id;
uint32_t fl_cidx;
uint32_t fl_pidx;
uint32_t fl_sidx;
uint32_t fl_db_val;
u_int fl_hwidx:4;
u_int nid; /* netmap ring # for this queue */
/* infrequently used items after this */
bus_dma_tag_t iq_desc_tag;
bus_dmamap_t iq_desc_map;
bus_addr_t iq_ba;
int intr_idx;
bus_dma_tag_t fl_desc_tag;
bus_dmamap_t fl_desc_map;
bus_addr_t fl_ba;
} __aligned(CACHE_LINE_SIZE);
struct sge_nm_txq {
struct tx_desc *desc;
uint16_t cidx;
uint16_t pidx;
uint16_t sidx;
uint16_t equiqidx; /* EQUIQ last requested at this pidx */
uint16_t equeqidx; /* EQUEQ last requested at this pidx */
uint16_t dbidx; /* pidx of the most recent doorbell */
uint16_t doorbells;
volatile uint32_t *udb;
u_int udb_qid;
u_int cntxt_id;
__be32 cpl_ctrl0; /* for convenience */
u_int nid; /* netmap ring # for this queue */
/* infrequently used items after this */
bus_dma_tag_t desc_tag;
bus_dmamap_t desc_map;
bus_addr_t ba;
int iqidx;
} __aligned(CACHE_LINE_SIZE);
struct sge {
int nrxq; /* total # of Ethernet rx queues */
int ntxq; /* total # of Ethernet tx tx queues */
int nofldrxq; /* total # of TOE rx queues */
int nofldtxq; /* total # of TOE tx queues */
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
int nnmrxq; /* total # of netmap rx queues */
int nnmtxq; /* total # of netmap tx queues */
int niq; /* total # of ingress queues */
int neq; /* total # of egress queues */
struct sge_iq fwq; /* Firmware event queue */
struct sge_wrq mgmtq; /* Management queue (control queue) */
struct sge_wrq *ctrlq; /* Control queues */
struct sge_txq *txq; /* NIC tx queues */
struct sge_rxq *rxq; /* NIC rx queues */
struct sge_wrq *ofld_txq; /* TOE tx queues */
struct sge_ofld_rxq *ofld_rxq; /* TOE rx queues */
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
struct sge_nm_txq *nm_txq; /* netmap tx queues */
struct sge_nm_rxq *nm_rxq; /* netmap rx queues */
uint16_t iq_start;
int eq_start;
struct sge_iq **iqmap; /* iq->cntxt_id to iq mapping */
struct sge_eq **eqmap; /* eq->cntxt_id to eq mapping */
int8_t safe_hwidx1; /* may not have room for metadata */
int8_t safe_hwidx2; /* with room for metadata and maybe more */
struct sw_zone_info sw_zone_info[SW_ZONE_SIZES];
struct hw_buf_info hw_buf_info[SGE_FLBUF_SIZES];
};
struct rss_header;
typedef int (*cpl_handler_t)(struct sge_iq *, const struct rss_header *,
struct mbuf *);
typedef int (*an_handler_t)(struct sge_iq *, const struct rsp_ctrl *);
typedef int (*fw_msg_handler_t)(struct adapter *, const __be64 *);
struct adapter {
SLIST_ENTRY(adapter) link;
device_t dev;
struct cdev *cdev;
/* PCIe register resources */
int regs_rid;
struct resource *regs_res;
int msix_rid;
struct resource *msix_res;
bus_space_handle_t bh;
bus_space_tag_t bt;
bus_size_t mmio_len;
int udbs_rid;
struct resource *udbs_res;
volatile uint8_t *udbs_base;
unsigned int pf;
unsigned int mbox;
unsigned int vpd_busy;
unsigned int vpd_flag;
/* Interrupt information */
int intr_type;
int intr_count;
struct irq {
struct resource *res;
int rid;
void *tag;
} *irq;
bus_dma_tag_t dmat; /* Parent DMA tag */
struct sge sge;
int lro_timeout;
struct taskqueue *tq[MAX_NCHAN]; /* General purpose taskqueues */
struct port_info *port[MAX_NPORTS];
uint8_t chan_map[MAX_NCHAN];
void *tom_softc; /* (struct tom_data *) */
struct tom_tunables tt;
void *iwarp_softc; /* (struct c4iw_dev *) */
void *iscsi_ulp_softc; /* (struct cxgbei_data *) */
struct l2t_data *l2t; /* L2 table */
struct tid_info tids;
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
uint16_t doorbells;
int offload_map; /* ports with IFCAP_TOE enabled */
int active_ulds; /* ULDs activated on this adapter */
int flags;
int debug_flags;
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
char ifp_lockname[16];
struct mtx ifp_lock;
struct ifnet *ifp; /* tracer ifp */
struct ifmedia media;
int traceq; /* iq used by all tracers, -1 if none */
int tracer_valid; /* bitmap of valid tracers */
int tracer_enabled; /* bitmap of enabled tracers */
char fw_version[16];
char tp_version[16];
char exprom_version[16];
char cfg_file[32];
u_int cfcsum;
struct adapter_params params;
const struct chip_params *chip_params;
struct t4_virt_res vres;
uint16_t nbmcaps;
uint16_t linkcaps;
uint16_t switchcaps;
uint16_t niccaps;
uint16_t toecaps;
uint16_t rdmacaps;
uint16_t tlscaps;
uint16_t iscsicaps;
uint16_t fcoecaps;
struct sysctl_ctx_list ctx; /* from adapter_full_init to full_uninit */
struct mtx sc_lock;
char lockname[16];
/* Starving free lists */
struct mtx sfl_lock; /* same cache-line as sc_lock? but that's ok */
TAILQ_HEAD(, sge_fl) sfl;
struct callout sfl_callout;
struct mtx reg_lock; /* for indirect register access */
2014-09-27 05:50:31 +00:00
struct memwin memwin[NUM_MEMWIN]; /* memory windows */
an_handler_t an_handler __aligned(CACHE_LINE_SIZE);
fw_msg_handler_t fw_msg_handler[7]; /* NUM_FW6_TYPES */
cpl_handler_t cpl_handler[0xef]; /* NUM_CPL_CMDS */
const char *last_op;
const void *last_op_thr;
int last_op_flags;
int sc_do_rxcopy;
};
#define ADAPTER_LOCK(sc) mtx_lock(&(sc)->sc_lock)
#define ADAPTER_UNLOCK(sc) mtx_unlock(&(sc)->sc_lock)
#define ADAPTER_LOCK_ASSERT_OWNED(sc) mtx_assert(&(sc)->sc_lock, MA_OWNED)
#define ADAPTER_LOCK_ASSERT_NOTOWNED(sc) mtx_assert(&(sc)->sc_lock, MA_NOTOWNED)
#define ASSERT_SYNCHRONIZED_OP(sc) \
KASSERT(IS_BUSY(sc) && \
(mtx_owned(&(sc)->sc_lock) || sc->last_op_thr == curthread), \
("%s: operation not synchronized.", __func__))
#define PORT_LOCK(pi) mtx_lock(&(pi)->pi_lock)
#define PORT_UNLOCK(pi) mtx_unlock(&(pi)->pi_lock)
#define PORT_LOCK_ASSERT_OWNED(pi) mtx_assert(&(pi)->pi_lock, MA_OWNED)
#define PORT_LOCK_ASSERT_NOTOWNED(pi) mtx_assert(&(pi)->pi_lock, MA_NOTOWNED)
#define FL_LOCK(fl) mtx_lock(&(fl)->fl_lock)
#define FL_TRYLOCK(fl) mtx_trylock(&(fl)->fl_lock)
#define FL_UNLOCK(fl) mtx_unlock(&(fl)->fl_lock)
#define FL_LOCK_ASSERT_OWNED(fl) mtx_assert(&(fl)->fl_lock, MA_OWNED)
#define FL_LOCK_ASSERT_NOTOWNED(fl) mtx_assert(&(fl)->fl_lock, MA_NOTOWNED)
#define RXQ_FL_LOCK(rxq) FL_LOCK(&(rxq)->fl)
#define RXQ_FL_UNLOCK(rxq) FL_UNLOCK(&(rxq)->fl)
#define RXQ_FL_LOCK_ASSERT_OWNED(rxq) FL_LOCK_ASSERT_OWNED(&(rxq)->fl)
#define RXQ_FL_LOCK_ASSERT_NOTOWNED(rxq) FL_LOCK_ASSERT_NOTOWNED(&(rxq)->fl)
#define EQ_LOCK(eq) mtx_lock(&(eq)->eq_lock)
#define EQ_TRYLOCK(eq) mtx_trylock(&(eq)->eq_lock)
#define EQ_UNLOCK(eq) mtx_unlock(&(eq)->eq_lock)
#define EQ_LOCK_ASSERT_OWNED(eq) mtx_assert(&(eq)->eq_lock, MA_OWNED)
#define EQ_LOCK_ASSERT_NOTOWNED(eq) mtx_assert(&(eq)->eq_lock, MA_NOTOWNED)
#define TXQ_LOCK(txq) EQ_LOCK(&(txq)->eq)
#define TXQ_TRYLOCK(txq) EQ_TRYLOCK(&(txq)->eq)
#define TXQ_UNLOCK(txq) EQ_UNLOCK(&(txq)->eq)
#define TXQ_LOCK_ASSERT_OWNED(txq) EQ_LOCK_ASSERT_OWNED(&(txq)->eq)
#define TXQ_LOCK_ASSERT_NOTOWNED(txq) EQ_LOCK_ASSERT_NOTOWNED(&(txq)->eq)
#define CH_DUMP_MBOX(sc, mbox, data_reg) \
do { \
if (sc->debug_flags & DF_DUMP_MBOX) { \
log(LOG_NOTICE, \
"%s mbox %u: %016llx %016llx %016llx %016llx " \
"%016llx %016llx %016llx %016llx\n", \
device_get_nameunit(sc->dev), mbox, \
(unsigned long long)t4_read_reg64(sc, data_reg), \
(unsigned long long)t4_read_reg64(sc, data_reg + 8), \
(unsigned long long)t4_read_reg64(sc, data_reg + 16), \
(unsigned long long)t4_read_reg64(sc, data_reg + 24), \
(unsigned long long)t4_read_reg64(sc, data_reg + 32), \
(unsigned long long)t4_read_reg64(sc, data_reg + 40), \
(unsigned long long)t4_read_reg64(sc, data_reg + 48), \
(unsigned long long)t4_read_reg64(sc, data_reg + 56)); \
} \
} while (0)
#define for_each_txq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.txq[vi->first_txq], iter = 0; \
iter < vi->ntxq; ++iter, ++q)
#define for_each_rxq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.rxq[vi->first_rxq], iter = 0; \
iter < vi->nrxq; ++iter, ++q)
#define for_each_ofld_txq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.ofld_txq[vi->first_ofld_txq], iter = 0; \
iter < vi->nofldtxq; ++iter, ++q)
#define for_each_ofld_rxq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.ofld_rxq[vi->first_ofld_rxq], iter = 0; \
iter < vi->nofldrxq; ++iter, ++q)
#define for_each_nm_txq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.nm_txq[vi->first_txq], iter = 0; \
iter < vi->ntxq; ++iter, ++q)
#define for_each_nm_rxq(vi, iter, q) \
for (q = &vi->pi->adapter->sge.nm_rxq[vi->first_rxq], iter = 0; \
iter < vi->nrxq; ++iter, ++q)
#define for_each_vi(_pi, _iter, _vi) \
for ((_vi) = (_pi)->vi, (_iter) = 0; (_iter) < (_pi)->nvi; \
++(_iter), ++(_vi))
#define IDXINCR(idx, incr, wrap) do { \
idx = wrap - idx > incr ? idx + incr : incr - (wrap - idx); \
} while (0)
#define IDXDIFF(head, tail, wrap) \
((head) >= (tail) ? (head) - (tail) : (wrap) - (tail) + (head))
/* One for errors, one for firmware events */
#define T4_EXTRA_INTR 2
static inline uint32_t
t4_read_reg(struct adapter *sc, uint32_t reg)
{
return bus_space_read_4(sc->bt, sc->bh, reg);
}
static inline void
t4_write_reg(struct adapter *sc, uint32_t reg, uint32_t val)
{
bus_space_write_4(sc->bt, sc->bh, reg, val);
}
static inline uint64_t
t4_read_reg64(struct adapter *sc, uint32_t reg)
{
return t4_bus_space_read_8(sc->bt, sc->bh, reg);
}
static inline void
t4_write_reg64(struct adapter *sc, uint32_t reg, uint64_t val)
{
t4_bus_space_write_8(sc->bt, sc->bh, reg, val);
}
static inline void
t4_os_pci_read_cfg1(struct adapter *sc, int reg, uint8_t *val)
{
*val = pci_read_config(sc->dev, reg, 1);
}
static inline void
t4_os_pci_write_cfg1(struct adapter *sc, int reg, uint8_t val)
{
pci_write_config(sc->dev, reg, val, 1);
}
static inline void
t4_os_pci_read_cfg2(struct adapter *sc, int reg, uint16_t *val)
{
*val = pci_read_config(sc->dev, reg, 2);
}
static inline void
t4_os_pci_write_cfg2(struct adapter *sc, int reg, uint16_t val)
{
pci_write_config(sc->dev, reg, val, 2);
}
static inline void
t4_os_pci_read_cfg4(struct adapter *sc, int reg, uint32_t *val)
{
*val = pci_read_config(sc->dev, reg, 4);
}
static inline void
t4_os_pci_write_cfg4(struct adapter *sc, int reg, uint32_t val)
{
pci_write_config(sc->dev, reg, val, 4);
}
static inline struct port_info *
adap2pinfo(struct adapter *sc, int idx)
{
return (sc->port[idx]);
}
static inline void
t4_os_set_hw_addr(struct adapter *sc, int idx, uint8_t hw_addr[])
{
bcopy(hw_addr, sc->port[idx]->vi[0].hw_addr, ETHER_ADDR_LEN);
}
static inline bool
is_10G_port(const struct port_info *pi)
{
return ((pi->link_cfg.supported & FW_PORT_CAP_SPEED_10G) != 0);
}
static inline bool
is_40G_port(const struct port_info *pi)
{
return ((pi->link_cfg.supported & FW_PORT_CAP_SPEED_40G) != 0);
}
static inline int
port_top_speed(const struct port_info *pi)
{
if (pi->link_cfg.supported & FW_PORT_CAP_SPEED_100G)
return (100);
if (pi->link_cfg.supported & FW_PORT_CAP_SPEED_40G)
return (40);
if (pi->link_cfg.supported & FW_PORT_CAP_SPEED_10G)
return (10);
if (pi->link_cfg.supported & FW_PORT_CAP_SPEED_1G)
return (1);
return (0);
}
static inline int
tx_resume_threshold(struct sge_eq *eq)
{
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
/* not quite the same as qsize / 4, but this will do. */
return (eq->sidx / 4);
}
static inline int
t4_use_ldst(struct adapter *sc)
{
#ifdef notyet
return (sc->flags & FW_OK || !sc->use_bd);
#else
return (0);
#endif
}
/* t4_main.c */
int t4_os_find_pci_capability(struct adapter *, int);
int t4_os_pci_save_state(struct adapter *);
int t4_os_pci_restore_state(struct adapter *);
void t4_os_portmod_changed(const struct adapter *, int);
void t4_os_link_changed(struct adapter *, int, int, int);
void t4_iterate(void (*)(struct adapter *, void *), void *);
int t4_register_cpl_handler(struct adapter *, int, cpl_handler_t);
int t4_register_an_handler(struct adapter *, an_handler_t);
int t4_register_fw_msg_handler(struct adapter *, int, fw_msg_handler_t);
int t4_filter_rpl(struct sge_iq *, const struct rss_header *, struct mbuf *);
int begin_synchronized_op(struct adapter *, struct vi_info *, int, char *);
void doom_vi(struct adapter *, struct vi_info *);
void end_synchronized_op(struct adapter *, int);
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
int update_mac_settings(struct ifnet *, int);
int adapter_full_init(struct adapter *);
int adapter_full_uninit(struct adapter *);
uint64_t cxgbe_get_counter(struct ifnet *, ift_counter);
int vi_full_init(struct vi_info *);
int vi_full_uninit(struct vi_info *);
void vi_sysctls(struct vi_info *);
void vi_tick(void *);
cxgbe(4): netmap support for Terminator 5 (T5) based 10G/40G cards. Netmap gets its own hardware-assisted virtual interface and won't take over or disrupt the "normal" interface in any way. You can use both simultaneously. For kernels with DEV_NETMAP, cxgbe(4) carves out an ncxl<N> interface (note the 'n' prefix) in the hardware to accompany each cxl<N> interface. These two ifnet's per port share the same wire but really are separate interfaces in the hardware and software. Each gets its own L2 MAC addresses (unicast and multicast), MTU, checksum caps, etc. You should run netmap on the 'n' interfaces only, that's what they are for. With this, pkt-gen is able to transmit > 45Mpps out of a single 40G port of a T580 card. 2 port tx is at ~56Mpps total (28M + 28M) as of now. Single port receive is at 33Mpps but this is very much a work in progress. I expect it to be closer to 40Mpps once done. In any case the current effort can already saturate multiple 10G ports of a T5 card at the smallest legal packet size. T4 gear is totally untested. trantor:~# ./pkt-gen -i ncxl0 -f tx -D 00:07:43:ab:cd:ef 881.952141 main [1621] interface is ncxl0 881.952250 extract_ip_range [275] range is 10.0.0.1:0 to 10.0.0.1:0 881.952253 extract_ip_range [275] range is 10.1.0.1:0 to 10.1.0.1:0 881.962540 main [1804] mapped 334980KB at 0x801dff000 Sending on netmap:ncxl0: 4 queues, 1 threads and 1 cpus. 10.0.0.1 -> 10.1.0.1 (00:00:00:00:00:00 -> 00:07:43:ab:cd:ef) 881.962562 main [1882] Sending 512 packets every 0.000000000 s 881.962563 main [1884] Wait 2 secs for phy reset 884.088516 main [1886] Ready... 884.088535 nm_open [457] overriding ifname ncxl0 ringid 0x0 flags 0x1 884.088607 sender_body [996] start 884.093246 sender_body [1064] drop copy 885.090435 main_thread [1418] 45206353 pps (45289533 pkts in 1001840 usec) 886.091600 main_thread [1418] 45322792 pps (45375593 pkts in 1001165 usec) 887.092435 main_thread [1418] 45313992 pps (45351784 pkts in 1000834 usec) 888.094434 main_thread [1418] 45315765 pps (45406397 pkts in 1002000 usec) 889.095434 main_thread [1418] 45333218 pps (45378551 pkts in 1001000 usec) 890.097434 main_thread [1418] 45315247 pps (45405877 pkts in 1002000 usec) 891.099434 main_thread [1418] 45326515 pps (45417168 pkts in 1002000 usec) 892.101434 main_thread [1418] 45333039 pps (45423705 pkts in 1002000 usec) 893.103434 main_thread [1418] 45324105 pps (45414708 pkts in 1001999 usec) 894.105434 main_thread [1418] 45318042 pps (45408723 pkts in 1002001 usec) 895.106434 main_thread [1418] 45332430 pps (45377762 pkts in 1001000 usec) 896.107434 main_thread [1418] 45338072 pps (45383410 pkts in 1001000 usec) ... Relnotes: Yes Sponsored by: Chelsio Communications.
2014-05-27 18:18:41 +00:00
#ifdef DEV_NETMAP
/* t4_netmap.c */
int create_netmap_ifnet(struct port_info *);
int destroy_netmap_ifnet(struct port_info *);
void t4_nm_intr(void *);
#endif
/* t4_sge.c */
void t4_sge_modload(void);
void t4_sge_modunload(void);
uint64_t t4_sge_extfree_refs(void);
void t4_init_sge_cpl_handlers(struct adapter *);
void t4_tweak_chip_settings(struct adapter *);
int t4_read_chip_settings(struct adapter *);
int t4_create_dma_tag(struct adapter *);
void t4_sge_sysctls(struct adapter *, struct sysctl_ctx_list *,
struct sysctl_oid_list *);
int t4_destroy_dma_tag(struct adapter *);
int t4_setup_adapter_queues(struct adapter *);
int t4_teardown_adapter_queues(struct adapter *);
int t4_setup_vi_queues(struct vi_info *);
int t4_teardown_vi_queues(struct vi_info *);
void t4_intr_all(void *);
void t4_intr(void *);
void t4_intr_err(void *);
void t4_intr_evt(void *);
void t4_wrq_tx_locked(struct adapter *, struct sge_wrq *, struct wrqe *);
void t4_update_fl_bufsize(struct ifnet *);
cxgbe(4): major tx rework. a) Front load as much work as possible in if_transmit, before any driver lock or software queue has to get involved. b) Replace buf_ring with a brand new mp_ring (multiproducer ring). This is specifically for the tx multiqueue model where one of the if_transmit producer threads becomes the consumer and other producers carry on as usual. mp_ring is implemented as standalone code and it should be possible to use it in any driver with tx multiqueue. It also has: - the ability to enqueue/dequeue multiple items. This might become significant if packet batching is ever implemented. - an abdication mechanism to allow a thread to give up writing tx descriptors and have another if_transmit thread take over. A thread that's writing tx descriptors can end up doing so for an unbounded time period if a) there are other if_transmit threads continuously feeding the sofware queue, and b) the chip keeps up with whatever the thread is throwing at it. - accurate statistics about interesting events even when the stats come at the expense of additional branches/conditional code. The NIC txq lock is uncontested on the fast path at this point. I've left it there for synchronization with the control events (interface up/down, modload/unload). c) Add support for "type 1" coalescing work request in the normal NIC tx path. This work request is optimized for frames with a single item in the DMA gather list. These are very common when forwarding packets. Note that netmap tx in cxgbe already uses these "type 1" work requests. d) Do not request automatic cidx updates every 32 descriptors. Instead, request updates via bits in individual work requests (still every 32 descriptors approximately). Also, request an automatic final update when the queue idles after activity. This means NIC tx reclaim is still performed lazily but it will catch up quickly as soon as the queue idles. This seems to be the best middle ground and I'll probably do something similar for netmap tx as well. e) Implement a faster tx path for WRQs (used by TOE tx and control queues, _not_ by the normal NIC tx). Allow work requests to be written directly to the hardware descriptor ring if room is available. I will convert t4_tom and iw_cxgbe modules to this faster style gradually. MFC after: 2 months
2014-12-31 23:19:16 +00:00
int parse_pkt(struct mbuf **);
void *start_wrq_wr(struct sge_wrq *, int, struct wrq_cookie *);
void commit_wrq_wr(struct sge_wrq *, void *, struct wrq_cookie *);
int tnl_cong(struct port_info *, int);
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_tracer.c */
struct t4_tracer;
void t4_tracer_modload(void);
void t4_tracer_modunload(void);
void t4_tracer_port_detach(struct adapter *);
int t4_get_tracer(struct adapter *, struct t4_tracer *);
int t4_set_tracer(struct adapter *, struct t4_tracer *);
int t4_trace_pkt(struct sge_iq *, const struct rss_header *, struct mbuf *);
int t5_trace_pkt(struct sge_iq *, const struct rss_header *, struct mbuf *);
static inline struct wrqe *
alloc_wrqe(int wr_len, struct sge_wrq *wrq)
{
int len = offsetof(struct wrqe, wr) + wr_len;
struct wrqe *wr;
wr = malloc(len, M_CXGBE, M_NOWAIT);
if (__predict_false(wr == NULL))
return (NULL);
wr->wr_len = wr_len;
wr->wrq = wrq;
return (wr);
}
static inline void *
wrtod(struct wrqe *wr)
{
return (&wr->wr[0]);
}
static inline void
free_wrqe(struct wrqe *wr)
{
free(wr, M_CXGBE);
}
static inline void
t4_wrq_tx(struct adapter *sc, struct wrqe *wr)
{
struct sge_wrq *wrq = wr->wrq;
TXQ_LOCK(wrq);
t4_wrq_tx_locked(sc, wrq, wr);
TXQ_UNLOCK(wrq);
}
#endif