Commit 637bc8f0 authored by David S. Miller's avatar David S. Miller

Merge tag 'mlx5-updates-2023-02-04' of git://git.kernel.org/pub/scm/linux/kernel/git/saeed/linux

Saeed Mahameed says:

====================
mlx5-updates-2023-02-04

This series provides misc updates to mlx5 driver:

1) Trivial LAG code cleanup patches from Roi

2) Rahul improves mlx5's documentation structure
Separates the documentation into multiple pages related to different
components in the device driver. Adds Kconfig parameters, devlink
parameters, and tracepoints that were previously introduced but not added
to the documentation. Introduces a new page on ethtool statistics counters
with information about counters previously implemented in the mlx5_core
driver but not documented in the kernel tree.

3) From Raed, policy/state selector support for IPSec.

4) From Fragos, add support for XDR speed in IPoIB mlx5 netdev

5) Few more misc cleanups and trivial changes
====================
Signed-off-by: default avatarDavid S. Miller <davem@davemloft.net>
parents 27369c9c 79efecb4
......@@ -39,7 +39,7 @@ Contents:
intel/ice
marvell/octeontx2
marvell/octeon_ep
mellanox/mlx5
mellanox/mlx5/index
microsoft/netvsc
neterion/s2io
netronome/nfp
......
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
================
Ethtool counters
================
:Copyright: |copy| 2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
Contents
========
- `Overview`_
- `Groups`_
- `Types`_
- `Descriptions`_
Overview
========
There are several counter groups based on where the counter is being counted. In
addition, each group of counters may have different counter types.
These counter groups are based on which component in a networking setup,
illustrated below, that they describe::
----------------------------------------
| |
---------------------------------------- ---------------------------------------- |
| Hypervisor | | VM | |
| | | | |
| ------------------- --------------- | | ------------------- --------------- | |
| | Ethernet driver | | RDMA driver | | | | Ethernet driver | | RDMA driver | | |
| ------------------- --------------- | | ------------------- --------------- | |
| | | | | | | | |
| ------------------- | | ------------------- | |
| | | | | |--
---------------------------------------- ----------------------------------------
| |
------------- -----------------------------
| |
------ ------ ------ ------ ------ ------ ------
-----| PF |----------------------| VF |-| VF |-| VF |----- --| PF |--- --| PF |--- --| PF |---
| ------ ------ ------ ------ | | ------ | | ------ | | ------ |
| | | | | | | |
| | | | | | | |
| | | | | | | |
| eSwitch | | eSwitch | | eSwitch | | eSwitch |
---------------------------------------------------------- ----------- ----------- -----------
-------------------------------------------------------------------------------
| |
| |
| Uplink (no counters) |
-------------------------------------------------------------------------------
---------------------------------------------------------------
| |
| |
| MPFS (no counters) |
---------------------------------------------------------------
|
|
| Port
Groups
======
Ring
Software counters populated by the driver stack.
Netdev
An aggregation of software ring counters.
vPort counters
Traffic counters and drops due to steering or no buffers. May indicate issues
with NIC. These counters include Ethernet traffic counters (including Raw
Ethernet) and RDMA/RoCE traffic counters.
Physical port counters
Counters that collect statistics about the PFs and VFs. May indicate issues
with NIC, link, or network. This measuring point holds information on
standardized counters like IEEE 802.3, RFC2863, RFC 2819, RFC 3635 and
additional counters like flow control, FEC and more. Physical port counters
are not exposed to virtual machines.
Priority Port Counters
A set of the physical port counters, per priority per port.
Types
=====
Counters are divided into three types.
Traffic Informative Counters
Counters which count traffic. These counters can be used for load estimation
or for general debug.
Traffic Acceleration Counters
Counters which count traffic that was accelerated by Mellanox driver or by
hardware. The counters are an additional layer to the informative counter set,
and the same traffic is counted in both informative and acceleration counters.
.. [#accel] Traffic acceleration counter.
Error Counters
Increment of these counters might indicate a problem. Each of these counters
has an explanation and correction action.
Statistic can be fetched via the `ip link` or `ethtool` commands. `ethtool`
provides more detailed information.::
ip –s link show <if-name>
ethtool -S <if-name>
Descriptions
============
XSK, PTP, and QoS counters that are similar to counters defined previously will
not be separately listed. For example, `ptp_tx[i]_packets` will not be
explicitly documented since `tx[i]_packets` describes the behavior of both
counters, except `ptp_tx[i]_packets` is only counted when precision time
protocol is used.
Ring / Netdev Counter
----------------------------
The following counters are available per ring or software port.
These counters provide information on the amount of traffic that was accelerated
by the NIC. The counters are counting the accelerated traffic in addition to the
standard counters which counts it (i.e. accelerated traffic is counted twice).
The counter names in the table below refers to both ring and port counters. The
notation for ring counters includes the [i] index without the braces. The
notation for port counters doesn't include the [i]. A counter name
`rx[i]_packets` will be printed as `rx0_packets` for ring 0 and `rx_packets` for
the software port.
.. flat-table:: Ring / Software Port Counter Table
:widths: 2 3 1
* - Counter
- Description
- Type
* - `rx[i]_packets`
- The number of packets received on ring i.
- Informative
* - `rx[i]_bytes`
- The number of bytes received on ring i.
- Informative
* - `tx[i]_packets`
- The number of packets transmitted on ring i.
- Informative
* - `tx[i]_bytes`
- The number of bytes transmitted on ring i.
- Informative
* - `tx[i]_recover`
- The number of times the SQ was recovered.
- Error
* - `tx[i]_cqes`
- Number of CQEs events on SQ issued on ring i.
- Informative
* - `tx[i]_cqe_err`
- The number of error CQEs encountered on the SQ for ring i.
- Error
* - `tx[i]_tso_packets`
- The number of TSO packets transmitted on ring i [#accel]_.
- Acceleration
* - `tx[i]_tso_bytes`
- The number of TSO bytes transmitted on ring i [#accel]_.
- Acceleration
* - `tx[i]_tso_inner_packets`
- The number of TSO packets which are indicated to be carry internal
encapsulation transmitted on ring i [#accel]_.
- Acceleration
* - `tx[i]_tso_inner_bytes`
- The number of TSO bytes which are indicated to be carry internal
encapsulation transmitted on ring i [#accel]_.
- Acceleration
* - `rx[i]_gro_packets`
- Number of received packets processed using hardware-accelerated GRO. The
number of hardware GRO offloaded packets received on ring i.
- Acceleration
* - `rx[i]_gro_bytes`
- Number of received bytes processed using hardware-accelerated GRO. The
number of hardware GRO offloaded bytes received on ring i.
- Acceleration
* - `rx[i]_gro_skbs`
- The number of receive SKBs constructed while performing
hardware-accelerated GRO.
- Informative
* - `rx[i]_gro_match_packets`
- Number of received packets processed using hardware-accelerated GRO that
met the flow table match criteria.
- Informative
* - `rx[i]_gro_large_hds`
- Number of receive packets using hardware-accelerated GRO that have large
headers that require additional memory to be allocated.
- Informative
* - `rx[i]_lro_packets`
- The number of LRO packets received on ring i [#accel]_.
- Acceleration
* - `rx[i]_lro_bytes`
- The number of LRO bytes received on ring i [#accel]_.
- Acceleration
* - `rx[i]_ecn_mark`
- The number of received packets where the ECN mark was turned on.
- Informative
* - `rx_oversize_pkts_buffer`
- The number of dropped received packets due to length which arrived to RQ
and exceed software buffer size allocated by the device for incoming
traffic. It might imply that the device MTU is larger than the software
buffers size.
- Error
* - `rx_oversize_pkts_sw_drop`
- Number of received packets dropped in software because the CQE data is
larger than the MTU size.
- Error
* - `rx[i]_csum_unnecessary`
- Packets received with a `CHECKSUM_UNNECESSARY` on ring i [#accel]_.
- Acceleration
* - `rx[i]_csum_unnecessary_inner`
- Packets received with inner encapsulation with a `CHECKSUM_UNNECESSARY`
on ring i [#accel]_.
- Acceleration
* - `rx[i]_csum_none`
- Packets received with a `CHECKSUM_NONE` on ring i [#accel]_.
- Acceleration
* - `rx[i]_csum_complete`
- Packets received with a `CHECKSUM_COMPLETE` on ring i [#accel]_.
- Acceleration
* - `rx[i]_csum_complete_tail`
- Number of received packets that had checksum calculation computed,
potentially needed padding, and were able to do so with
`CHECKSUM_PARTIAL`.
- Informative
* - `rx[i]_csum_complete_tail_slow`
- Number of received packets that need padding larger than eight bytes for
the checksum.
- Informative
* - `tx[i]_csum_partial`
- Packets transmitted with a `CHECKSUM_PARTIAL` on ring i [#accel]_.
- Acceleration
* - `tx[i]_csum_partial_inner`
- Packets transmitted with inner encapsulation with a `CHECKSUM_PARTIAL` on
ring i [#accel]_.
- Acceleration
* - `tx[i]_csum_none`
- Packets transmitted with no hardware checksum acceleration on ring i.
- Informative
* - `tx[i]_stopped` / `tx_queue_stopped` [#ring_global]_
- Events where SQ was full on ring i. If this counter is increased, check
the amount of buffers allocated for transmission.
- Informative
* - `tx[i]_wake` / `tx_queue_wake` [#ring_global]_
- Events where SQ was full and has become not full on ring i.
- Informative
* - `tx[i]_dropped` / `tx_queue_dropped` [#ring_global]_
- Packets transmitted that were dropped due to DMA mapping failure on
ring i. If this counter is increased, check the amount of buffers
allocated for transmission.
- Error
* - `tx[i]_nop`
- The number of nop WQEs (empty WQEs) inserted to the SQ (related to
ring i) due to the reach of the end of the cyclic buffer. When reaching
near to the end of cyclic buffer the driver may add those empty WQEs to
avoid handling a state the a WQE start in the end of the queue and ends
in the beginning of the queue. This is a normal condition.
- Informative
* - `tx[i]_added_vlan_packets`
- The number of packets sent where vlan tag insertion was offloaded to the
hardware.
- Acceleration
* - `rx[i]_removed_vlan_packets`
- The number of packets received where vlan tag stripping was offloaded to
the hardware.
- Acceleration
* - `rx[i]_wqe_err`
- The number of wrong opcodes received on ring i.
- Error
* - `rx[i]_mpwqe_frag`
- The number of WQEs that failed to allocate compound page and hence
fragmented MPWQE’s (Multi Packet WQEs) were used on ring i. If this
counter raise, it may suggest that there is no enough memory for large
pages, the driver allocated fragmented pages. This is not abnormal
condition.
- Informative
* - `rx[i]_mpwqe_filler_cqes`
- The number of filler CQEs events that were issued on ring i.
- Informative
* - `rx[i]_mpwqe_filler_strides`
- The number of strides consumed by filler CQEs on ring i.
- Informative
* - `tx[i]_mpwqe_blks`
- The number of send blocks processed from Multi-Packet WQEs (mpwqe).
- Informative
* - `tx[i]_mpwqe_pkts`
- The number of send packets processed from Multi-Packet WQEs (mpwqe).
- Informative
* - `rx[i]_cqe_compress_blks`
- The number of receive blocks with CQE compression on ring i [#accel]_.
- Acceleration
* - `rx[i]_cqe_compress_pkts`
- The number of receive packets with CQE compression on ring i [#accel]_.
- Acceleration
* - `rx[i]_cache_reuse`
- The number of events of successful reuse of a page from a driver's
internal page cache.
- Acceleration
* - `rx[i]_cache_full`
- The number of events of full internal page cache where driver can't put a
page back to the cache for recycling (page will be freed).
- Acceleration
* - `rx[i]_cache_empty`
- The number of events where cache was empty - no page to give. Driver
shall allocate new page.
- Acceleration
* - `rx[i]_cache_busy`
- The number of events where cache head was busy and cannot be recycled.
Driver allocated new page.
- Acceleration
* - `rx[i]_cache_waive`
- The number of cache evacuation. This can occur due to page move to
another NUMA node or page was pfmemalloc-ed and should be freed as soon
as possible.
- Acceleration
* - `rx[i]_arfs_err`
- Number of flow rules that failed to be added to the flow table.
- Error
* - `rx[i]_recover`
- The number of times the RQ was recovered.
- Error
* - `tx[i]_xmit_more`
- The number of packets sent with `xmit_more` indication set on the skbuff
(no doorbell).
- Acceleration
* - `ch[i]_poll`
- The number of invocations of NAPI poll of channel i.
- Informative
* - `ch[i]_arm`
- The number of times the NAPI poll function completed and armed the
completion queues on channel i.
- Informative
* - `ch[i]_aff_change`
- The number of times the NAPI poll function explicitly stopped execution
on a CPU due to a change in affinity, on channel i.
- Informative
* - `ch[i]_events`
- The number of hard interrupt events on the completion queues of channel i.
- Informative
* - `ch[i]_eq_rearm`
- The number of times the EQ was recovered.
- Error
* - `ch[i]_force_irq`
- Number of times NAPI is triggered by XSK wakeups by posting a NOP to
ICOSQ.
- Acceleration
* - `rx[i]_congst_umr`
- The number of times an outstanding UMR request is delayed due to
congestion, on ring i.
- Informative
* - `rx_pp_alloc_fast`
- Number of successful fast path allocations.
- Informative
* - `rx_pp_alloc_slow`
- Number of slow path order-0 allocations.
- Informative
* - `rx_pp_alloc_slow_high_order`
- Number of slow path high order allocations.
- Informative
* - `rx_pp_alloc_empty`
- Counter is incremented when ptr ring is empty, so a slow path allocation
was forced.
- Informative
* - `rx_pp_alloc_refill`
- Counter is incremented when an allocation which triggered a refill of the
cache.
- Informative
* - `rx_pp_alloc_waive`
- Counter is incremented when pages obtained from the ptr ring that cannot
be added to the cache due to a NUMA mismatch.
- Informative
* - `rx_pp_recycle_cached`
- Counter is incremented when recycling placed page in the page pool cache.
- Informative
* - `rx_pp_recycle_cache_full`
- Counter is incremented when page pool cache was full.
- Informative
* - `rx_pp_recycle_ring`
- Counter is incremented when page placed into the ptr ring.
- Informative
* - `rx_pp_recycle_ring_full`
- Counter is incremented when page released from page pool because the ptr
ring was full.
- Informative
* - `rx_pp_recycle_released_ref`
- Counter is incremented when page released (and not recycled) because
refcnt > 1.
- Informative
* - `rx[i]_xsk_buff_alloc_err`
- The number of times allocating an skb or XSK buffer failed in the XSK RQ
context.
- Error
* - `rx[i]_xsk_arfs_err`
- aRFS (accelerated Receive Flow Steering) does not occur in the XSK RQ
context, so this counter should never increment.
- Error
* - `rx[i]_xdp_tx_xmit`
- The number of packets forwarded back to the port due to XDP program
`XDP_TX` action (bouncing). these packets are not counted by other
software counters. These packets are counted by physical port and vPort
counters.
- Informative
* - `rx[i]_xdp_tx_mpwqe`
- Number of multi-packet WQEs transmitted by the netdev and `XDP_TX`-ed by
the netdev during the RQ context.
- Acceleration
* - `rx[i]_xdp_tx_inlnw`
- Number of WQE data segments transmitted where the data could be inlined
in the WQE and then `XDP_TX`-ed during the RQ context.
- Acceleration
* - `rx[i]_xdp_tx_nops`
- Number of NOP WQEBBs (WQE building blocks) received posted to the XDP SQ.
- Acceleration
* - `rx[i]_xdp_tx_full`
- The number of packets that should have been forwarded back to the port
due to `XDP_TX` action but were dropped due to full tx queue. These packets
are not counted by other software counters. These packets are counted by
physical port and vPort counters. You may open more rx queues and spread
traffic rx over all queues and/or increase rx ring size.
- Error
* - `rx[i]_xdp_tx_err`
- The number of times an `XDP_TX` error such as frame too long and frame
too short occurred on `XDP_TX` ring of RX ring.
- Error
* - `rx[i]_xdp_tx_cqes` / `rx_xdp_tx_cqe` [#ring_global]_
- The number of completions received on the CQ of the `XDP_TX` ring.
- Informative
* - `rx[i]_xdp_drop`
- The number of packets dropped due to XDP program `XDP_DROP` action. these
packets are not counted by other software counters. These packets are
counted by physical port and vPort counters.
- Informative
* - `rx[i]_xdp_redirect`
- The number of times an XDP redirect action was triggered on ring i.
- Acceleration
* - `tx[i]_xdp_xmit`
- The number of packets redirected to the interface(due to XDP redirect).
These packets are not counted by other software counters. These packets
are counted by physical port and vPort counters.
- Informative
* - `tx[i]_xdp_full`
- The number of packets redirected to the interface(due to XDP redirect),
but were dropped due to full tx queue. these packets are not counted by
other software counters. you may enlarge tx queues.
- Informative
* - `tx[i]_xdp_mpwqe`
- Number of multi-packet WQEs offloaded onto the NIC that were
`XDP_REDIRECT`-ed from other netdevs.
- Acceleration
* - `tx[i]_xdp_inlnw`
- Number of WQE data segments where the data could be inlined in the WQE
where the data segments were `XDP_REDIRECT`-ed from other netdevs.
- Acceleration
* - `tx[i]_xdp_nops`
- Number of NOP WQEBBs (WQE building blocks) posted to the SQ that were
`XDP_REDIRECT`-ed from other netdevs.
- Acceleration
* - `tx[i]_xdp_err`
- The number of packets redirected to the interface(due to XDP redirect)
but were dropped due to error such as frame too long and frame too short.
- Error
* - `tx[i]_xdp_cqes`
- The number of completions received for packets redirected to the
interface(due to XDP redirect) on the CQ.
- Informative
* - `tx[i]_xsk_xmit`
- The number of packets transmitted using XSK zerocopy functionality.
- Acceleration
* - `tx[i]_xsk_mpwqe`
- Number of multi-packet WQEs offloaded onto the NIC that were
`XDP_REDIRECT`-ed from other netdevs.
- Acceleration
* - `tx[i]_xsk_inlnw`
- Number of WQE data segments where the data could be inlined in the WQE
that are transmitted using XSK zerocopy.
- Acceleration
* - `tx[i]_xsk_full`
- Number of times doorbell is rung in XSK zerocopy mode when SQ is full.
- Error
* - `tx[i]_xsk_err`
- Number of errors that occurred in XSK zerocopy mode such as if the data
size is larger than the MTU size.
- Error
* - `tx[i]_xsk_cqes`
- Number of CQEs processed in XSK zerocopy mode.
- Acceleration
* - `tx_tls_ctx`
- Number of TLS TX HW offload contexts added to device for encryption.
- Acceleration
* - `tx_tls_del`
- Number of TLS TX HW offload contexts removed from device (connection
closed).
- Acceleration
* - `tx_tls_pool_alloc`
- Number of times a unit of work is successfully allocated in the TLS HW
offload pool.
- Acceleration
* - `tx_tls_pool_free`
- Number of times a unit of work is freed in the TLS HW offload pool.
- Acceleration
* - `rx_tls_ctx`
- Number of TLS RX HW offload contexts added to device for decryption.
- Acceleration
* - `rx_tls_del`
- Number of TLS RX HW offload contexts deleted from device (connection has
finished).
- Acceleration
* - `rx[i]_tls_decrypted_packets`
- Number of successfully decrypted RX packets which were part of a TLS
stream.
- Acceleration
* - `rx[i]_tls_decrypted_bytes`
- Number of TLS payload bytes in RX packets which were successfully
decrypted.
- Acceleration
* - `rx[i]_tls_resync_req_pkt`
- Number of received TLS packets with a resync request.
- Acceleration
* - `rx[i]_tls_resync_req_start`
- Number of times the TLS async resync request was started.
- Acceleration
* - `rx[i]_tls_resync_req_end`
- Number of times the TLS async resync request properly ended with
providing the HW tracked tcp-seq.
- Acceleration
* - `rx[i]_tls_resync_req_skip`
- Number of times the TLS async resync request procedure was started but
not properly ended.
- Error
* - `rx[i]_tls_resync_res_ok`
- Number of times the TLS resync response call to the driver was
successfully handled.
- Acceleration
* - `rx[i]_tls_resync_res_retry`
- Number of times the TLS resync response call to the driver was
reattempted when ICOSQ is full.
- Error
* - `rx[i]_tls_resync_res_skip`
- Number of times the TLS resync response call to the driver was terminated
unsuccessfully.
- Error
* - `rx[i]_tls_err`
- Number of times when CQE TLS offload was problematic.
- Error
* - `tx[i]_tls_encrypted_packets`
- The number of send packets that are TLS encrypted by the kernel.
- Acceleration
* - `tx[i]_tls_encrypted_bytes`
- The number of send bytes that are TLS encrypted by the kernel.
- Acceleration
* - `tx[i]_tls_ooo`
- Number of times out of order TLS SQE fragments were handled on ring i.
- Acceleration
* - `tx[i]_tls_dump_packets`
- Number of TLS decrypted packets copied over from NIC over DMA.
- Acceleration
* - `tx[i]_tls_dump_bytes`
- Number of TLS decrypted bytes copied over from NIC over DMA.
- Acceleration
* - `tx[i]_tls_resync_bytes`
- Number of TLS bytes requested to be resynchronized in order to be
decrypted.
- Acceleration
* - `tx[i]_tls_skip_no_sync_data`
- Number of TLS send data that can safely be skipped / do not need to be
decrypted.
- Acceleration
* - `tx[i]_tls_drop_no_sync_data`
- Number of TLS send data that were dropped due to retransmission of TLS
data.
- Acceleration
* - `ptp_cq[i]_abort`
- Number of times a CQE has to be skipped in precision time protocol due to
a skew between the port timestamp and CQE timestamp being greater than
128 seconds.
- Error
* - `ptp_cq[i]_abort_abs_diff_ns`
- Accumulation of time differences between the port timestamp and CQE
timestamp when the difference is greater than 128 seconds in precision
time protocol.
- Error
.. [#ring_global] The corresponding ring and global counters do not share the
same name (i.e. do not follow the common naming scheme).
vPort Counters
--------------
Counters on the NIC port that is connected to a eSwitch.
.. flat-table:: vPort Counter Table
:widths: 2 3 1
* - Counter
- Description
- Type
* - `rx_vport_unicast_packets`
- Unicast packets received, steered to a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_unicast_bytes`
- Unicast bytes received, steered to a port including Raw Ethernet QP/DPDK
traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_unicast_packets`
- Unicast packets transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_unicast_bytes`
- Unicast bytes transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_multicast_packets`
- Multicast packets received, steered to a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_multicast_bytes`
- Multicast bytes received, steered to a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_multicast_packets`
- Multicast packets transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_multicast_bytes`
- Multicast bytes transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_broadcast_packets`
- Broadcast packets received, steered to a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_broadcast_bytes`
- Broadcast bytes received, steered to a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_broadcast_packets`
- Broadcast packets transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `tx_vport_broadcast_bytes`
- Broadcast bytes transmitted, steered from a port including Raw Ethernet
QP/DPDK traffic, excluding RDMA traffic.
- Informative
* - `rx_vport_rdma_unicast_packets`
- RDMA unicast packets received, steered to a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `rx_vport_rdma_unicast_bytes`
- RDMA unicast bytes received, steered to a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `tx_vport_rdma_unicast_packets`
- RDMA unicast packets transmitted, steered from a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `tx_vport_rdma_unicast_bytes`
- RDMA unicast bytes transmitted, steered from a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `rx_vport_rdma_multicast_packets`
- RDMA multicast packets received, steered to a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `rx_vport_rdma_multicast_bytes`
- RDMA multicast bytes received, steered to a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `tx_vport_rdma_multicast_packets`
- RDMA multicast packets transmitted, steered from a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `tx_vport_rdma_multicast_bytes`
- RDMA multicast bytes transmitted, steered from a port (counters counts
RoCE/UD/RC traffic) [#accel]_.
- Acceleration
* - `rx_steer_missed_packets`
- Number of packets that was received by the NIC, however was discarded
because it did not match any flow in the NIC flow table.
- Error
* - `rx_packets`
- Representor only: packets received, that were handled by the hypervisor.
- Informative
* - `rx_bytes`
- Representor only: bytes received, that were handled by the hypervisor.
- Informative
* - `tx_packets`
- Representor only: packets transmitted, that were handled by the
hypervisor.
- Informative
* - `tx_bytes`
- Representor only: bytes transmitted, that were handled by the hypervisor.
- Informative
* - `dev_internal_queue_oob`
- The number of dropped packets due to lack of receive WQEs for an internal
device RQ.
- Error
Physical Port Counters
----------------------
The physical port counters are the counters on the external port connecting the
adapter to the network. This measuring point holds information on standardized
counters like IEEE 802.3, RFC2863, RFC 2819, RFC 3635 and additional counters
like flow control, FEC and more.
.. flat-table:: Physical Port Counter Table
:widths: 2 3 1
* - Counter
- Description
- Type
* - `rx_packets_phy`
- The number of packets received on the physical port. This counter doesn’t
include packets that were discarded due to FCS, frame size and similar
errors.
- Informative
* - `tx_packets_phy`
- The number of packets transmitted on the physical port.
- Informative
* - `rx_bytes_phy`
- The number of bytes received on the physical port, including Ethernet
header and FCS.
- Informative
* - `tx_bytes_phy`
- The number of bytes transmitted on the physical port.
- Informative
* - `rx_multicast_phy`
- The number of multicast packets received on the physical port.
- Informative
* - `tx_multicast_phy`
- The number of multicast packets transmitted on the physical port.
- Informative
* - `rx_broadcast_phy`
- The number of broadcast packets received on the physical port.
- Informative
* - `tx_broadcast_phy`
- The number of broadcast packets transmitted on the physical port.
- Informative
* - `rx_crc_errors_phy`
- The number of dropped received packets due to FCS (Frame Check Sequence)
error on the physical port. If this counter is increased in high rate,
check the link quality using `rx_symbol_error_phy` and
`rx_corrected_bits_phy` counters below.
- Error
* - `rx_in_range_len_errors_phy`
- The number of received packets dropped due to length/type errors on a
physical port.
- Error
* - `rx_out_of_range_len_phy`
- The number of received packets dropped due to length greater than allowed
on a physical port. If this counter is increasing, it implies that the
peer connected to the adapter has a larger MTU configured. Using same MTU
configuration shall resolve this issue.
- Error
* - `rx_oversize_pkts_phy`
- The number of dropped received packets due to length which exceed MTU
size on a physical port. If this counter is increasing, it implies that
the peer connected to the adapter has a larger MTU configured. Using same
MTU configuration shall resolve this issue.
- Error
* - `rx_symbol_err_phy`
- The number of received packets dropped due to physical coding errors
(symbol errors) on a physical port.
- Error
* - `rx_mac_control_phy`
- The number of MAC control packets received on the physical port.
- Informative
* - `tx_mac_control_phy`
- The number of MAC control packets transmitted on the physical port.
- Informative
* - `rx_pause_ctrl_phy`
- The number of link layer pause packets received on a physical port. If
this counter is increasing, it implies that the network is congested and
cannot absorb the traffic coming from to the adapter.
- Informative
* - `tx_pause_ctrl_phy`
- The number of link layer pause packets transmitted on a physical port. If
this counter is increasing, it implies that the NIC is congested and
cannot absorb the traffic coming from the network.
- Informative
* - `rx_unsupported_op_phy`
- The number of MAC control packets received with unsupported opcode on a
physical port.
- Error
* - `rx_discards_phy`
- The number of received packets dropped due to lack of buffers on a
physical port. If this counter is increasing, it implies that the adapter
is congested and cannot absorb the traffic coming from the network.
- Error
* - `tx_discards_phy`
- The number of packets which were discarded on transmission, even no
errors were detected. the drop might occur due to link in down state,
head of line drop, pause from the network, etc.
- Error
* - `tx_errors_phy`
- The number of transmitted packets dropped due to a length which exceed
MTU size on a physical port.
- Error
* - `rx_undersize_pkts_phy`
- The number of received packets dropped due to length which is shorter
than 64 bytes on a physical port. If this counter is increasing, it
implies that the peer connected to the adapter has a non-standard MTU
configured or malformed packet had arrived.
- Error
* - `rx_fragments_phy`
- The number of received packets dropped due to a length which is shorter
than 64 bytes and has FCS error on a physical port. If this counter is
increasing, it implies that the peer connected to the adapter has a
non-standard MTU configured.
- Error
* - `rx_jabbers_phy`
- The number of received packets d due to a length which is longer than 64
bytes and had FCS error on a physical port.
- Error
* - `rx_64_bytes_phy`
- The number of packets received on the physical port with size of 64 bytes.
- Informative
* - `rx_65_to_127_bytes_phy`
- The number of packets received on the physical port with size of 65 to
127 bytes.
- Informative
* - `rx_128_to_255_bytes_phy`
- The number of packets received on the physical port with size of 128 to
255 bytes.
- Informative
* - `rx_256_to_511_bytes_phy`
- The number of packets received on the physical port with size of 256 to
512 bytes.
- Informative
* - `rx_512_to_1023_bytes_phy`
- The number of packets received on the physical port with size of 512 to
1023 bytes.
- Informative
* - `rx_1024_to_1518_bytes_phy`
- The number of packets received on the physical port with size of 1024 to
1518 bytes.
- Informative
* - `rx_1519_to_2047_bytes_phy`
- The number of packets received on the physical port with size of 1519 to
2047 bytes.
- Informative
* - `rx_2048_to_4095_bytes_phy`
- The number of packets received on the physical port with size of 2048 to
4095 bytes.
- Informative
* - `rx_4096_to_8191_bytes_phy`
- The number of packets received on the physical port with size of 4096 to
8191 bytes.
- Informative
* - `rx_8192_to_10239_bytes_phy`
- The number of packets received on the physical port with size of 8192 to
10239 bytes.
- Informative
* - `link_down_events_phy`
- The number of times where the link operative state changed to down. In
case this counter is increasing it may imply on port flapping. You may
need to replace the cable/transceiver.
- Error
* - `rx_out_of_buffer`
- Number of times receive queue had no software buffers allocated for the
adapter's incoming traffic.
- Error
* - `module_bus_stuck`
- The number of times that module's I\ :sup:`2`\C bus (data or clock)
short-wire was detected. You may need to replace the cable/transceiver.
- Error
* - `module_high_temp`
- The number of times that the module temperature was too high. If this
issue persist, you may need to check the ambient temperature or replace
the cable/transceiver module.
- Error
* - `module_bad_shorted`
- The number of times that the module cables were shorted. You may need to
replace the cable/transceiver module.
- Error
* - `module_unplug`
- The number of times that module was ejected.
- Informative
* - `rx_buffer_passed_thres_phy`
- The number of events where the port receive buffer was over 85% full.
- Informative
* - `tx_pause_storm_warning_events`
- The number of times the device was sending pauses for a long period of
time.
- Informative
* - `tx_pause_storm_error_events`
- The number of times the device was sending pauses for a long period of
time, reaching time out and disabling transmission of pause frames. on
the period where pause frames were disabled, drop could have been
occurred.
- Error
* - `rx[i]_buff_alloc_err`
- Failed to allocate a buffer to received packet (or SKB) on ring i.
- Error
* - `rx_bits_phy`
- This counter provides information on the total amount of traffic that
could have been received and can be used as a guideline to measure the
ratio of errored traffic in `rx_pcs_symbol_err_phy` and
`rx_corrected_bits_phy`.
- Informative
* - `rx_pcs_symbol_err_phy`
- This counter counts the number of symbol errors that wasn’t corrected by
FEC correction algorithm or that FEC algorithm was not active on this
interface. If this counter is increasing, it implies that the link
between the NIC and the network is suffering from high BER, and that
traffic is lost. You may need to replace the cable/transceiver. The error
rate is the number of `rx_pcs_symbol_err_phy` divided by the number of
`rx_bits_phy` on a specific time frame.
- Error
* - `rx_corrected_bits_phy`
- The number of corrected bits on this port according to active FEC
(RS/FC). If this counter is increasing, it implies that the link between
the NIC and the network is suffering from high BER. The corrected bit
rate is the number of `rx_corrected_bits_phy` divided by the number of
`rx_bits_phy` on a specific time frame.
- Error
* - `rx_err_lane_[l]_phy`
- This counter counts the number of physical raw errors per lane l index.
The counter counts errors before FEC corrections. If this counter is
increasing, it implies that the link between the NIC and the network is
suffering from high BER, and that traffic might be lost. You may need to
replace the cable/transceiver. Please check in accordance with
`rx_corrected_bits_phy`.
- Error
* - `rx_global_pause`
- The number of pause packets received on the physical port. If this
counter is increasing, it implies that the network is congested and
cannot absorb the traffic coming from the adapter. Note: This counter is
only enabled when global pause mode is enabled.
- Informative
* - `rx_global_pause_duration`
- The duration of pause received (in microSec) on the physical port. The
counter represents the time the port did not send any traffic. If this
counter is increasing, it implies that the network is congested and
cannot absorb the traffic coming from the adapter. Note: This counter is
only enabled when global pause mode is enabled.
- Informative
* - `tx_global_pause`
- The number of pause packets transmitted on a physical port. If this
counter is increasing, it implies that the adapter is congested and
cannot absorb the traffic coming from the network. Note: This counter is
only enabled when global pause mode is enabled.
- Informative
* - `tx_global_pause_duration`
- The duration of pause transmitter (in microSec) on the physical port.
Note: This counter is only enabled when global pause mode is enabled.
- Informative
* - `rx_global_pause_transition`
- The number of times a transition from Xoff to Xon on the physical port
has occurred. Note: This counter is only enabled when global pause mode
is enabled.
- Informative
* - `rx_if_down_packets`
- The number of received packets that were dropped due to interface down.
- Informative
Priority Port Counters
----------------------
The following counters are physical port counters that are counted per L2
priority (0-7).
**Note:** `p` in the counter name represents the priority.
.. flat-table:: Priority Port Counter Table
:widths: 2 3 1
* - Counter
- Description
- Type
* - `rx_prio[p]_bytes`
- The number of bytes received with priority p on the physical port.
- Informative
* - `rx_prio[p]_packets`
- The number of packets received with priority p on the physical port.
- Informative
* - `tx_prio[p]_bytes`
- The number of bytes transmitted on priority p on the physical port.
- Informative
* - `tx_prio[p]_packets`
- The number of packets transmitted on priority p on the physical port.
- Informative
* - `rx_prio[p]_pause`
- The number of pause packets received with priority p on a physical port.
If this counter is increasing, it implies that the network is congested
and cannot absorb the traffic coming from the adapter. Note: This counter
is available only if PFC was enabled on priority p.
- Informative
* - `rx_prio[p]_pause_duration`
- The duration of pause received (in microSec) on priority p on the
physical port. The counter represents the time the port did not send any
traffic on this priority. If this counter is increasing, it implies that
the network is congested and cannot absorb the traffic coming from the
adapter. Note: This counter is available only if PFC was enabled on
priority p.
- Informative
* - `rx_prio[p]_pause_transition`
- The number of times a transition from Xoff to Xon on priority p on the
physical port has occurred. Note: This counter is available only if PFC
was enabled on priority p.
- Informative
* - `tx_prio[p]_pause`
- The number of pause packets transmitted on priority p on a physical port.
If this counter is increasing, it implies that the adapter is congested
and cannot absorb the traffic coming from the network. Note: This counter
is available only if PFC was enabled on priority p.
- Informative
* - `tx_prio[p]_pause_duration`
- The duration of pause transmitter (in microSec) on priority p on the
physical port. Note: This counter is available only if PFC was enabled on
priority p.
- Informative
* - `rx_prio[p]_buf_discard`
- The number of packets discarded by device due to lack of per host receive
buffers.
- Informative
* - `rx_prio[p]_cong_discard`
- The number of packets discarded by device due to per host congestion.
- Informative
* - `rx_prio[p]_marked`
- The number of packets ecn marked by device due to per host congestion.
- Informative
* - `rx_prio[p]_discards`
- The number of packets discarded by device due to lack of receive buffers.
- Informative
Device Counters
---------------
.. flat-table:: Device Counter Table
:widths: 2 3 1
* - Counter
- Description
- Type
* - `rx_pci_signal_integrity`
- Counts physical layer PCIe signal integrity errors, the number of
transitions to recovery due to Framing errors and CRC (dlp and tlp). If
this counter is raising, try moving the adapter card to a different slot
to rule out a bad PCI slot. Validate that you are running with the latest
firmware available and latest server BIOS version.
- Error
* - `tx_pci_signal_integrity`
- Counts physical layer PCIe signal integrity errors, the number of
transition to recovery initiated by the other side (moving to recovery
due to getting TS/EIEOS). If this counter is raising, try moving the
adapter card to a different slot to rule out a bad PCI slot. Validate
that you are running with the latest firmware available and latest server
BIOS version.
- Error
* - `outbound_pci_buffer_overflow`
- The number of packets dropped due to pci buffer overflow. If this counter
is raising in high rate, it might indicate that the receive traffic rate
for a host is larger than the PCIe bus and therefore a congestion occurs.
- Informative
* - `outbound_pci_stalled_rd`
- The percentage (in the range 0...100) of time within the last second that
the NIC had outbound non-posted reads requests but could not perform the
operation due to insufficient posted credits.
- Informative
* - `outbound_pci_stalled_wr`
- The percentage (in the range 0...100) of time within the last second that
the NIC had outbound posted writes requests but could not perform the
operation due to insufficient posted credits.
- Informative
* - `outbound_pci_stalled_rd_events`
- The number of seconds where `outbound_pci_stalled_rd` was above 30%.
- Informative
* - `outbound_pci_stalled_wr_events`
- The number of seconds where `outbound_pci_stalled_wr` was above 30%.
- Informative
* - `dev_out_of_buffer`
- The number of times the device owned queue had not enough buffers
allocated.
- Error
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
=======
Devlink
=======
:Copyright: |copy| 2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
Contents
========
- `Info`_
- `Parameters`_
- `Health reporters`_
Info
====
The devlink info reports the running and stored firmware versions on device.
It also prints the device PSID which represents the HCA board type ID.
User command example::
$ devlink dev info pci/0000:00:06.0
pci/0000:00:06.0:
driver mlx5_core
versions:
fixed:
fw.psid MT_0000000009
running:
fw.version 16.26.0100
stored:
fw.version 16.26.0100
Parameters
==========
flow_steering_mode: Device flow steering mode
---------------------------------------------
The flow steering mode parameter controls the flow steering mode of the driver.
Two modes are supported:
1. 'dmfs' - Device managed flow steering.
2. 'smfs' - Software/Driver managed flow steering.
In DMFS mode, the HW steering entities are created and managed through the
Firmware.
In SMFS mode, the HW steering entities are created and managed though by
the driver directly into hardware without firmware intervention.
SMFS mode is faster and provides better rule insertion rate compared to default DMFS mode.
User command examples:
- Set SMFS flow steering mode::
$ devlink dev param set pci/0000:06:00.0 name flow_steering_mode value "smfs" cmode runtime
- Read device flow steering mode::
$ devlink dev param show pci/0000:06:00.0 name flow_steering_mode
pci/0000:06:00.0:
name flow_steering_mode type driver-specific
values:
cmode runtime value smfs
enable_roce: RoCE enablement state
----------------------------------
If the device supports RoCE disablement, RoCE enablement state controls device
support for RoCE capability. Otherwise, the control occurs in the driver stack.
When RoCE is disabled at the driver level, only raw ethernet QPs are supported.
To change RoCE enablement state, a user must change the driverinit cmode value
and run devlink reload.
User command examples:
- Disable RoCE::
$ devlink dev param set pci/0000:06:00.0 name enable_roce value false cmode driverinit
$ devlink dev reload pci/0000:06:00.0
- Read RoCE enablement state::
$ devlink dev param show pci/0000:06:00.0 name enable_roce
pci/0000:06:00.0:
name enable_roce type generic
values:
cmode driverinit value true
esw_port_metadata: Eswitch port metadata state
----------------------------------------------
When applicable, disabling eswitch metadata can increase packet rate
up to 20% depending on the use case and packet sizes.
Eswitch port metadata state controls whether to internally tag packets with
metadata. Metadata tagging must be enabled for multi-port RoCE, failover
between representors and stacked devices.
By default metadata is enabled on the supported devices in E-switch.
Metadata is applicable only for E-switch in switchdev mode and
users may disable it when NONE of the below use cases will be in use:
1. HCA is in Dual/multi-port RoCE mode.
2. VF/SF representor bonding (Usually used for Live migration)
3. Stacked devices
When metadata is disabled, the above use cases will fail to initialize if
users try to enable them.
- Show eswitch port metadata::
$ devlink dev param show pci/0000:06:00.0 name esw_port_metadata
pci/0000:06:00.0:
name esw_port_metadata type driver-specific
values:
cmode runtime value true
- Disable eswitch port metadata::
$ devlink dev param set pci/0000:06:00.0 name esw_port_metadata value false cmode runtime
- Change eswitch mode to switchdev mode where after choosing the metadata value::
$ devlink dev eswitch set pci/0000:06:00.0 mode switchdev
Health reporters
================
tx reporter
-----------
The tx reporter is responsible for reporting and recovering of the following two error scenarios:
- tx timeout
Report on kernel tx timeout detection.
Recover by searching lost interrupts.
- tx error completion
Report on error tx completion.
Recover by flushing the tx queue and reset it.
tx reporter also support on demand diagnose callback, on which it provides
real time information of its send queues status.
User commands examples:
- Diagnose send queues status::
$ devlink health diagnose pci/0000:82:00.0 reporter tx
NOTE: This command has valid output only when interface is up, otherwise the command has empty output.
- Show number of tx errors indicated, number of recover flows ended successfully,
is autorecover enabled and graceful period from last recover::
$ devlink health show pci/0000:82:00.0 reporter tx
rx reporter
-----------
The rx reporter is responsible for reporting and recovering of the following two error scenarios:
- rx queues' initialization (population) timeout
Population of rx queues' descriptors on ring initialization is done
in napi context via triggering an irq. In case of a failure to get
the minimum amount of descriptors, a timeout would occur, and
descriptors could be recovered by polling the EQ (Event Queue).
- rx completions with errors (reported by HW on interrupt context)
Report on rx completion error.
Recover (if needed) by flushing the related queue and reset it.
rx reporter also supports on demand diagnose callback, on which it
provides real time information of its receive queues' status.
- Diagnose rx queues' status and corresponding completion queue::
$ devlink health diagnose pci/0000:82:00.0 reporter rx
NOTE: This command has valid output only when interface is up. Otherwise, the command has empty output.
- Show number of rx errors indicated, number of recover flows ended successfully,
is autorecover enabled, and graceful period from last recover::
$ devlink health show pci/0000:82:00.0 reporter rx
fw reporter
-----------
The fw reporter implements `diagnose` and `dump` callbacks.
It follows symptoms of fw error such as fw syndrome by triggering
fw core dump and storing it into the dump buffer.
The fw reporter diagnose command can be triggered any time by the user to check
current fw status.
User commands examples:
- Check fw heath status::
$ devlink health diagnose pci/0000:82:00.0 reporter fw
- Read FW core dump if already stored or trigger new one::
$ devlink health dump show pci/0000:82:00.0 reporter fw
NOTE: This command can run only on the PF which has fw tracer ownership,
running it on other PF or any VF will return "Operation not permitted".
fw fatal reporter
-----------------
The fw fatal reporter implements `dump` and `recover` callbacks.
It follows fatal errors indications by CR-space dump and recover flow.
The CR-space dump uses vsc interface which is valid even if the FW command
interface is not functional, which is the case in most FW fatal errors.
The recover function runs recover flow which reloads the driver and triggers fw
reset if needed.
On firmware error, the health buffer is dumped into the dmesg. The log
level is derived from the error's severity (given in health buffer).
User commands examples:
- Run fw recover flow manually::
$ devlink health recover pci/0000:82:00.0 reporter fw_fatal
- Read FW CR-space dump if already stored or trigger new one::
$ devlink health dump show pci/0000:82:00.1 reporter fw_fatal
NOTE: This command can run only on PF.
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
Mellanox ConnectX(R) mlx5 core VPI Network Driver
=================================================
:Copyright: |copy| 2019, Mellanox Technologies LTD.
:Copyright: |copy| 2020-2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
Contents:
.. toctree::
:maxdepth: 2
kconfig
devlink
switchdev
tracepoints
counters
.. only:: subproject and html
Indices
=======
* :ref:`genindex`
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
=======================================
Enabling the driver and kconfig options
=======================================
:Copyright: |copy| 2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
| mlx5 core is modular and most of the major mlx5 core driver features can be selected (compiled in/out)
| at build time via kernel Kconfig flags.
| Basic features, ethernet net device rx/tx offloads and XDP, are available with the most basic flags
| CONFIG_MLX5_CORE=y/m and CONFIG_MLX5_CORE_EN=y.
| For the list of advanced features, please see below.
**CONFIG_MLX5_BRIDGE=(y/n)**
| Enable :ref:`Ethernet Bridging (BRIDGE) offloading support <mlx5_bridge_offload>`.
| This will provide the ability to add representors of mlx5 uplink and VF
| ports to Bridge and offloading rules for traffic between such ports.
| Supports VLANs (trunk and access modes).
**CONFIG_MLX5_CORE=(y/m/n)** (module mlx5_core.ko)
| The driver can be enabled by choosing CONFIG_MLX5_CORE=y/m in kernel config.
| This will provide mlx5 core driver for mlx5 ulps to interface with (mlx5e, mlx5_ib).
**CONFIG_MLX5_CORE_EN=(y/n)**
| Choosing this option will allow basic ethernet netdevice support with all of the standard rx/tx offloads.
| mlx5e is the mlx5 ulp driver which provides netdevice kernel interface, when chosen, mlx5e will be
| built-in into mlx5_core.ko.
**CONFIG_MLX5_CORE_EN_DCB=(y/n)**:
| Enables `Data Center Bridging (DCB) Support <https://community.mellanox.com/s/article/howto-auto-config-pfc-and-ets-on-connectx-4-via-lldp-dcbx>`_.
**CONFIG_MLX5_CORE_IPOIB=(y/n)**
| IPoIB offloads & acceleration support.
| Requires CONFIG_MLX5_CORE_EN to provide an accelerated interface for the rdma
| IPoIB ulp netdevice.
**CONFIG_MLX5_CLS_ACT=(y/n)**
| Enables offload support for TC classifier action (NET_CLS_ACT).
| Works in both native NIC mode and Switchdev SRIOV mode.
| Flow-based classifiers, such as those registered through
| `tc-flower(8)`, are processed by the device, rather than the
| host. Actions that would then overwrite matching classification
| results would then be instant due to the offload.
**CONFIG_MLX5_EN_ARFS=(y/n)**
| Enables Hardware-accelerated receive flow steering (arfs) support, and ntuple filtering.
| https://community.mellanox.com/s/article/howto-configure-arfs-on-connectx-4
**CONFIG_MLX5_EN_IPSEC=(y/n)**
| Enables `IPSec XFRM cryptography-offload acceleration <https://support.mellanox.com/s/article/ConnectX-6DX-Bluefield-2-IPsec-HW-Full-Offload-Configuration-Guide>`_.
**CONFIG_MLX5_EN_MACSEC=(y/n)**
| Build support for MACsec cryptography-offload acceleration in the NIC.
**CONFIG_MLX5_EN_RXNFC=(y/n)**
| Enables ethtool receive network flow classification, which allows user defined
| flow rules to direct traffic into arbitrary rx queue via ethtool set/get_rxnfc API.
**CONFIG_MLX5_EN_TLS=(y/n)**
| TLS cryptography-offload acceleration.
**CONFIG_MLX5_ESWITCH=(y/n)**
| Ethernet SRIOV E-Switch support in ConnectX NIC. E-Switch provides internal SRIOV packet steering
| and switching for the enabled VFs and PF in two available modes:
| 1) `Legacy SRIOV mode (L2 mac vlan steering based) <https://community.mellanox.com/s/article/howto-configure-sr-iov-for-connectx-4-connectx-5-with-kvm--ethernet-x>`_.
| 2) `Switchdev mode (eswitch offloads) <https://www.mellanox.com/related-docs/prod_software/ASAP2_Hardware_Offloading_for_vSwitches_User_Manual_v4.4.pdf>`_.
**CONFIG_MLX5_FPGA=(y/n)**
| Build support for the Innova family of network cards by Mellanox Technologies.
| Innova network cards are comprised of a ConnectX chip and an FPGA chip on one board.
| If you select this option, the mlx5_core driver will include the Innova FPGA core and allow
| building sandbox-specific client drivers.
**CONFIG_MLX5_INFINIBAND=(y/n/m)** (module mlx5_ib.ko)
| Provides low-level InfiniBand/RDMA and `RoCE <https://community.mellanox.com/s/article/recommended-network-configuration-examples-for-roce-deployment>`_ support.
**CONFIG_MLX5_MPFS=(y/n)**
| Ethernet Multi-Physical Function Switch (MPFS) support in ConnectX NIC.
| MPFs is required for when `Multi-Host <http://www.mellanox.com/page/multihost>`_ configuration is enabled to allow passing
| user configured unicast MAC addresses to the requesting PF.
**CONFIG_MLX5_SF=(y/n)**
| Build support for subfunction.
| Subfunctons are more light weight than PCI SRIOV VFs. Choosing this option
| will enable support for creating subfunction devices.
**CONFIG_MLX5_SF_MANAGER=(y/n)**
| Build support for subfuction port in the NIC. A Mellanox subfunction
| port is managed through devlink. A subfunction supports RDMA, netdevice
| and vdpa device. It is similar to a SRIOV VF but it doesn't require
| SRIOV support.
**CONFIG_MLX5_SW_STEERING=(y/n)**
| Build support for software-managed steering in the NIC.
**CONFIG_MLX5_TC_CT=(y/n)**
| Support offloading connection tracking rules via tc ct action.
**CONFIG_MLX5_TC_SAMPLE=(y/n)**
| Support offloading sample rules via tc sample action.
**CONFIG_MLX5_VDPA=(y/n)**
| Support library for Mellanox VDPA drivers. Provides code that is
| common for all types of VDPA drivers. The following drivers are planned:
| net, block.
**CONFIG_MLX5_VDPA_NET=(y/n)**
| VDPA network driver for ConnectX6 and newer. Provides offloading
| of virtio net datapath such that descriptors put on the ring will
| be executed by the hardware. It also supports a variety of stateless
| offloads depending on the actual device used and firmware version.
**CONFIG_MLX5_VFIO_PCI=(y/n)**
| This provides migration support for MLX5 devices using the VFIO framework.
**External options** ( Choose if the corresponding mlx5 feature is required )
- CONFIG_MLXFW: When chosen, mlx5 firmware flashing support will be enabled (via devlink and ethtool).
- CONFIG_PTP_1588_CLOCK: When chosen, mlx5 ptp support will be enabled
- CONFIG_VXLAN: When chosen, mlx5 vxlan support will be enabled.
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
=================================================
Mellanox ConnectX(R) mlx5 core VPI Network Driver
=================================================
=========
Switchdev
=========
Copyright (c) 2019, Mellanox Technologies LTD.
:Copyright: |copy| 2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
Contents
========
- `Enabling the driver and kconfig options`_
- `Devlink info`_
- `Devlink parameters`_
- `Bridge offload`_
- `mlx5 subfunction`_
- `mlx5 function attributes`_
- `Devlink health reporters`_
- `mlx5 tracepoints`_
Enabling the driver and kconfig options
=======================================
| mlx5 core is modular and most of the major mlx5 core driver features can be selected (compiled in/out)
| at build time via kernel Kconfig flags.
| Basic features, ethernet net device rx/tx offloads and XDP, are available with the most basic flags
| CONFIG_MLX5_CORE=y/m and CONFIG_MLX5_CORE_EN=y.
| For the list of advanced features, please see below.
**CONFIG_MLX5_CORE=(y/m/n)** (module mlx5_core.ko)
| The driver can be enabled by choosing CONFIG_MLX5_CORE=y/m in kernel config.
| This will provide mlx5 core driver for mlx5 ulps to interface with (mlx5e, mlx5_ib).
**CONFIG_MLX5_CORE_EN=(y/n)**
| Choosing this option will allow basic ethernet netdevice support with all of the standard rx/tx offloads.
| mlx5e is the mlx5 ulp driver which provides netdevice kernel interface, when chosen, mlx5e will be
| built-in into mlx5_core.ko.
**CONFIG_MLX5_EN_ARFS=(y/n)**
| Enables Hardware-accelerated receive flow steering (arfs) support, and ntuple filtering.
| https://community.mellanox.com/s/article/howto-configure-arfs-on-connectx-4
**CONFIG_MLX5_EN_RXNFC=(y/n)**
| Enables ethtool receive network flow classification, which allows user defined
| flow rules to direct traffic into arbitrary rx queue via ethtool set/get_rxnfc API.
**CONFIG_MLX5_CORE_EN_DCB=(y/n)**:
| Enables `Data Center Bridging (DCB) Support <https://community.mellanox.com/s/article/howto-auto-config-pfc-and-ets-on-connectx-4-via-lldp-dcbx>`_.
**CONFIG_MLX5_MPFS=(y/n)**
| Ethernet Multi-Physical Function Switch (MPFS) support in ConnectX NIC.
| MPFs is required for when `Multi-Host <http://www.mellanox.com/page/multihost>`_ configuration is enabled to allow passing
| user configured unicast MAC addresses to the requesting PF.
**CONFIG_MLX5_ESWITCH=(y/n)**
| Ethernet SRIOV E-Switch support in ConnectX NIC. E-Switch provides internal SRIOV packet steering
| and switching for the enabled VFs and PF in two available modes:
| 1) `Legacy SRIOV mode (L2 mac vlan steering based) <https://community.mellanox.com/s/article/howto-configure-sr-iov-for-connectx-4-connectx-5-with-kvm--ethernet-x>`_.
| 2) `Switchdev mode (eswitch offloads) <https://www.mellanox.com/related-docs/prod_software/ASAP2_Hardware_Offloading_for_vSwitches_User_Manual_v4.4.pdf>`_.
**CONFIG_MLX5_CORE_IPOIB=(y/n)**
| IPoIB offloads & acceleration support.
| Requires CONFIG_MLX5_CORE_EN to provide an accelerated interface for the rdma
| IPoIB ulp netdevice.
**CONFIG_MLX5_FPGA=(y/n)**
| Build support for the Innova family of network cards by Mellanox Technologies.
| Innova network cards are comprised of a ConnectX chip and an FPGA chip on one board.
| If you select this option, the mlx5_core driver will include the Innova FPGA core and allow
| building sandbox-specific client drivers.
**CONFIG_MLX5_EN_IPSEC=(y/n)**
| Enables `IPSec XFRM cryptography-offload acceleration <http://www.mellanox.com/related-docs/prod_software/Mellanox_Innova_IPsec_Ethernet_Adapter_Card_User_Manual.pdf>`_.
**CONFIG_MLX5_EN_TLS=(y/n)**
| TLS cryptography-offload acceleration.
**CONFIG_MLX5_INFINIBAND=(y/n/m)** (module mlx5_ib.ko)
| Provides low-level InfiniBand/RDMA and `RoCE <https://community.mellanox.com/s/article/recommended-network-configuration-examples-for-roce-deployment>`_ support.
**CONFIG_MLX5_SF=(y/n)**
| Build support for subfunction.
| Subfunctons are more light weight than PCI SRIOV VFs. Choosing this option
| will enable support for creating subfunction devices.
**External options** ( Choose if the corresponding mlx5 feature is required )
- CONFIG_PTP_1588_CLOCK: When chosen, mlx5 ptp support will be enabled
- CONFIG_VXLAN: When chosen, mlx5 vxlan support will be enabled.
- CONFIG_MLXFW: When chosen, mlx5 firmware flashing support will be enabled (via devlink and ethtool).
Devlink info
============
The devlink info reports the running and stored firmware versions on device.
It also prints the device PSID which represents the HCA board type ID.
User command example::
$ devlink dev info pci/0000:00:06.0
pci/0000:00:06.0:
driver mlx5_core
versions:
fixed:
fw.psid MT_0000000009
running:
fw.version 16.26.0100
stored:
fw.version 16.26.0100
Devlink parameters
==================
flow_steering_mode: Device flow steering mode
---------------------------------------------
The flow steering mode parameter controls the flow steering mode of the driver.
Two modes are supported:
1. 'dmfs' - Device managed flow steering.
2. 'smfs' - Software/Driver managed flow steering.
In DMFS mode, the HW steering entities are created and managed through the
Firmware.
In SMFS mode, the HW steering entities are created and managed though by
the driver directly into hardware without firmware intervention.
SMFS mode is faster and provides better rule insertion rate compared to default DMFS mode.
User command examples:
- Set SMFS flow steering mode::
$ devlink dev param set pci/0000:06:00.0 name flow_steering_mode value "smfs" cmode runtime
- Read device flow steering mode::
$ devlink dev param show pci/0000:06:00.0 name flow_steering_mode
pci/0000:06:00.0:
name flow_steering_mode type driver-specific
values:
cmode runtime value smfs
enable_roce: RoCE enablement state
----------------------------------
RoCE enablement state controls driver support for RoCE traffic.
When RoCE is disabled, there is no gid table, only raw ethernet QPs are supported and traffic on the well-known UDP RoCE port is handled as raw ethernet traffic.
To change RoCE enablement state, a user must change the driverinit cmode value and run devlink reload.
User command examples:
- Disable RoCE::
$ devlink dev param set pci/0000:06:00.0 name enable_roce value false cmode driverinit
$ devlink dev reload pci/0000:06:00.0
- Read RoCE enablement state::
$ devlink dev param show pci/0000:06:00.0 name enable_roce
pci/0000:06:00.0:
name enable_roce type generic
values:
cmode driverinit value true
esw_port_metadata: Eswitch port metadata state
----------------------------------------------
When applicable, disabling eswitch metadata can increase packet rate
up to 20% depending on the use case and packet sizes.
Eswitch port metadata state controls whether to internally tag packets with
metadata. Metadata tagging must be enabled for multi-port RoCE, failover
between representors and stacked devices.
By default metadata is enabled on the supported devices in E-switch.
Metadata is applicable only for E-switch in switchdev mode and
users may disable it when NONE of the below use cases will be in use:
1. HCA is in Dual/multi-port RoCE mode.
2. VF/SF representor bonding (Usually used for Live migration)
3. Stacked devices
When metadata is disabled, the above use cases will fail to initialize if
users try to enable them.
- Show eswitch port metadata::
$ devlink dev param show pci/0000:06:00.0 name esw_port_metadata
pci/0000:06:00.0:
name esw_port_metadata type driver-specific
values:
cmode runtime value true
- Disable eswitch port metadata::
$ devlink dev param set pci/0000:06:00.0 name esw_port_metadata value false cmode runtime
- Change eswitch mode to switchdev mode where after choosing the metadata value::
$ devlink dev eswitch set pci/0000:06:00.0 mode switchdev
.. _mlx5_bridge_offload:
Bridge offload
==============
The mlx5 driver implements support for offloading bridge rules when in switchdev
mode. Linux bridge FDBs are automatically offloaded when mlx5 switchdev
representor is attached to bridge.
......@@ -234,6 +26,7 @@ representor is attached to bridge.
VLANs
-----
Following bridge VLAN functions are supported by mlx5:
- VLAN filtering (including multiple VLANs per port)::
......@@ -249,8 +42,9 @@ Following bridge VLAN functions are supported by mlx5:
$ bridge vlan add dev enp8s0f0 vid 3 untagged
mlx5 subfunction
================
Subfunction
===========
mlx5 supports subfunction management using devlink port (see :ref:`Documentation/networking/devlink/devlink-port.rst <devlink_port>`) interface.
A subfunction has its own function capabilities and its own resources. This
......@@ -338,8 +132,9 @@ Subfunction is created using devlink port interface.
$ devlink port del pci/0000:06:00.0/32768
mlx5 function attributes
========================
Function attributes
===================
The mlx5 driver provides a mechanism to setup PCI VF/SF function attributes in
a unified way for SmartNIC and non-SmartNIC.
......@@ -351,11 +146,12 @@ driver.
MAC address setup
-----------------
mlx5 driver support devlink port function attr mechanism to setup MAC
address. (refer to Documentation/networking/devlink/devlink-port.rst)
RoCE capability setup
---------------------
~~~~~~~~~~~~~~~~~~~~~
Not all mlx5 PCI devices/SFs require RoCE capability.
When RoCE capability is disabled, it saves 1 Mbytes worth of system memory per
......@@ -365,7 +161,7 @@ mlx5 driver support devlink port function attr mechanism to setup RoCE
capability. (refer to Documentation/networking/devlink/devlink-port.rst)
migratable capability setup
---------------------------
~~~~~~~~~~~~~~~~~~~~~~~~~~~
User who wants mlx5 PCI VFs to be able to perform live migration need to
explicitly enable the VF migratable capability.
......@@ -374,6 +170,7 @@ capability. (refer to Documentation/networking/devlink/devlink-port.rst)
SF state setup
--------------
To use the SF, the user must activate the SF using the SF function state
attribute.
......@@ -440,307 +237,3 @@ safe to delete the SF port for graceful termination of the subfunction.
pci/0000:06:00.0/32768: type eth netdev ens2f0npf0sf88 flavour pcisf controller 0 pfnum 0 sfnum 88 external false splittable false
function:
hw_addr 00:00:00:00:88:88 state active opstate attached
Devlink health reporters
========================
tx reporter
-----------
The tx reporter is responsible for reporting and recovering of the following two error scenarios:
- tx timeout
Report on kernel tx timeout detection.
Recover by searching lost interrupts.
- tx error completion
Report on error tx completion.
Recover by flushing the tx queue and reset it.
tx reporter also support on demand diagnose callback, on which it provides
real time information of its send queues status.
User commands examples:
- Diagnose send queues status::
$ devlink health diagnose pci/0000:82:00.0 reporter tx
NOTE: This command has valid output only when interface is up, otherwise the command has empty output.
- Show number of tx errors indicated, number of recover flows ended successfully,
is autorecover enabled and graceful period from last recover::
$ devlink health show pci/0000:82:00.0 reporter tx
rx reporter
-----------
The rx reporter is responsible for reporting and recovering of the following two error scenarios:
- rx queues' initialization (population) timeout
Population of rx queues' descriptors on ring initialization is done
in napi context via triggering an irq. In case of a failure to get
the minimum amount of descriptors, a timeout would occur, and
descriptors could be recovered by polling the EQ (Event Queue).
- rx completions with errors (reported by HW on interrupt context)
Report on rx completion error.
Recover (if needed) by flushing the related queue and reset it.
rx reporter also supports on demand diagnose callback, on which it
provides real time information of its receive queues' status.
- Diagnose rx queues' status and corresponding completion queue::
$ devlink health diagnose pci/0000:82:00.0 reporter rx
NOTE: This command has valid output only when interface is up. Otherwise, the command has empty output.
- Show number of rx errors indicated, number of recover flows ended successfully,
is autorecover enabled, and graceful period from last recover::
$ devlink health show pci/0000:82:00.0 reporter rx
fw reporter
-----------
The fw reporter implements `diagnose` and `dump` callbacks.
It follows symptoms of fw error such as fw syndrome by triggering
fw core dump and storing it into the dump buffer.
The fw reporter diagnose command can be triggered any time by the user to check
current fw status.
User commands examples:
- Check fw heath status::
$ devlink health diagnose pci/0000:82:00.0 reporter fw
- Read FW core dump if already stored or trigger new one::
$ devlink health dump show pci/0000:82:00.0 reporter fw
NOTE: This command can run only on the PF which has fw tracer ownership,
running it on other PF or any VF will return "Operation not permitted".
fw fatal reporter
-----------------
The fw fatal reporter implements `dump` and `recover` callbacks.
It follows fatal errors indications by CR-space dump and recover flow.
The CR-space dump uses vsc interface which is valid even if the FW command
interface is not functional, which is the case in most FW fatal errors.
The recover function runs recover flow which reloads the driver and triggers fw
reset if needed.
On firmware error, the health buffer is dumped into the dmesg. The log
level is derived from the error's severity (given in health buffer).
User commands examples:
- Run fw recover flow manually::
$ devlink health recover pci/0000:82:00.0 reporter fw_fatal
- Read FW CR-space dump if already stored or trigger new one::
$ devlink health dump show pci/0000:82:00.1 reporter fw_fatal
NOTE: This command can run only on PF.
mlx5 tracepoints
================
mlx5 driver provides internal tracepoints for tracking and debugging using
kernel tracepoints interfaces (refer to Documentation/trace/ftrace.rst).
For the list of support mlx5 events, check `/sys/kernel/debug/tracing/events/mlx5/`.
tc and eswitch offloads tracepoints:
- mlx5e_configure_flower: trace flower filter actions and cookies offloaded to mlx5::
$ echo mlx5:mlx5e_configure_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6535 [019] ...1 2672.404466: mlx5e_configure_flower: cookie=0000000067874a55 actions= REDIRECT
- mlx5e_delete_flower: trace flower filter actions and cookies deleted from mlx5::
$ echo mlx5:mlx5e_delete_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6569 [010] .N.1 2686.379075: mlx5e_delete_flower: cookie=0000000067874a55 actions= NULL
- mlx5e_stats_flower: trace flower stats request::
$ echo mlx5:mlx5e_stats_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6546 [010] ...1 2679.704889: mlx5e_stats_flower: cookie=0000000060eb3d6a bytes=0 packets=0 lastused=4295560217
- mlx5e_tc_update_neigh_used_value: trace tunnel rule neigh update value offloaded to mlx5::
$ echo mlx5:mlx5e_tc_update_neigh_used_value >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u48:4-8806 [009] ...1 55117.882428: mlx5e_tc_update_neigh_used_value: netdev: ens1f0 IPv4: 1.1.1.10 IPv6: ::ffff:1.1.1.10 neigh_used=1
- mlx5e_rep_neigh_update: trace neigh update tasks scheduled due to neigh state change events::
$ echo mlx5:mlx5e_rep_neigh_update >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u48:7-2221 [009] ...1 1475.387435: mlx5e_rep_neigh_update: netdev: ens1f0 MAC: 24:8a:07:9a:17:9a IPv4: 1.1.1.10 IPv6: ::ffff:1.1.1.10 neigh_connected=1
Bridge offloads tracepoints:
- mlx5_esw_bridge_fdb_entry_init: trace bridge FDB entry offloaded to mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_init >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u20:9-2217 [003] ...1 318.582243: mlx5_esw_bridge_fdb_entry_init: net_device=enp8s0f0_0 addr=e4:fd:05:08:00:02 vid=0 flags=0 used=0
- mlx5_esw_bridge_fdb_entry_cleanup: trace bridge FDB entry deleted from mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2581 [005] ...1 318.629871: mlx5_esw_bridge_fdb_entry_cleanup: net_device=enp8s0f0_1 addr=e4:fd:05:08:00:03 vid=0 flags=0 used=16
- mlx5_esw_bridge_fdb_entry_refresh: trace bridge FDB entry offload refreshed in
mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_refresh >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u20:8-3849 [003] ...1 466716: mlx5_esw_bridge_fdb_entry_refresh: net_device=enp8s0f0_0 addr=e4:fd:05:08:00:02 vid=3 flags=0 used=0
- mlx5_esw_bridge_vlan_create: trace bridge VLAN object add on mlx5
representor::
$ echo mlx5:mlx5_esw_bridge_vlan_create >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2560 [007] ...1 318.460258: mlx5_esw_bridge_vlan_create: vid=1 flags=6
- mlx5_esw_bridge_vlan_cleanup: trace bridge VLAN object delete from mlx5
representor::
$ echo mlx5:mlx5_esw_bridge_vlan_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
bridge-2582 [007] ...1 318.653496: mlx5_esw_bridge_vlan_cleanup: vid=2 flags=8
- mlx5_esw_bridge_vport_init: trace mlx5 vport assigned with bridge upper
device::
$ echo mlx5:mlx5_esw_bridge_vport_init >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2560 [007] ...1 318.458915: mlx5_esw_bridge_vport_init: vport_num=1
- mlx5_esw_bridge_vport_cleanup: trace mlx5 vport removed from bridge upper
device::
$ echo mlx5:mlx5_esw_bridge_vport_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-5387 [000] ...1 573713: mlx5_esw_bridge_vport_cleanup: vport_num=1
Eswitch QoS tracepoints:
- mlx5_esw_vport_qos_create: trace creation of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_create >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-23496 [018] .... 73136.838831: mlx5_esw_vport_qos_create: (0000:82:00.0) vport=2 tsar_ix=4 bw_share=0, max_rate=0 group=000000007b576bb3
- mlx5_esw_vport_qos_config: trace configuration of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_config >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-26548 [023] .... 75754.223823: mlx5_esw_vport_qos_config: (0000:82:00.0) vport=1 tsar_ix=3 bw_share=34, max_rate=10000 group=000000007b576bb3
- mlx5_esw_vport_qos_destroy: trace deletion of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_destroy >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27418 [004] .... 76546.680901: mlx5_esw_vport_qos_destroy: (0000:82:00.0) vport=1 tsar_ix=3
- mlx5_esw_group_qos_create: trace creation of transmit scheduler arbiter for rate group::
$ echo mlx5:mlx5_esw_group_qos_create >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-26578 [008] .... 75776.022112: mlx5_esw_group_qos_create: (0000:82:00.0) group=000000008dac63ea tsar_ix=5
- mlx5_esw_group_qos_config: trace configuration of transmit scheduler arbiter for rate group::
$ echo mlx5:mlx5_esw_group_qos_config >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27303 [020] .... 76461.455356: mlx5_esw_group_qos_config: (0000:82:00.0) group=000000008dac63ea tsar_ix=5 bw_share=100 max_rate=20000
- mlx5_esw_group_qos_destroy: trace deletion of transmit scheduler arbiter for group::
$ echo mlx5:mlx5_esw_group_qos_destroy >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27418 [006] .... 76547.187258: mlx5_esw_group_qos_destroy: (0000:82:00.0) group=000000007b576bb3 tsar_ix=1
SF tracepoints:
- mlx5_sf_add: trace addition of the SF port::
$ echo mlx5:mlx5_sf_add >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9363 [031] ..... 24610.188722: mlx5_sf_add: (0000:06:00.0) port_index=32768 controller=0 hw_id=0x8000 sfnum=88
- mlx5_sf_free: trace freeing of the SF port::
$ echo mlx5:mlx5_sf_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9830 [038] ..... 26300.404749: mlx5_sf_free: (0000:06:00.0) port_index=32768 controller=0 hw_id=0x8000
- mlx5_sf_hwc_alloc: trace allocating of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_alloc >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9775 [031] ..... 26296.385259: mlx5_sf_hwc_alloc: (0000:06:00.0) controller=0 hw_id=0x8000 sfnum=88
- mlx5_sf_hwc_free: trace freeing of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [046] ..... 24625.365771: mlx5_sf_hwc_free: (0000:06:00.0) hw_id=0x8000
- mlx5_sf_hwc_deferred_free : trace deferred freeing of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_deferred_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9519 [046] ..... 24624.400271: mlx5_sf_hwc_deferred_free: (0000:06:00.0) hw_id=0x8000
- mlx5_sf_vhca_event: trace SF vhca event and state::
$ echo mlx5:mlx5_sf_vhca_event >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [046] ..... 24625.365525: mlx5_sf_vhca_event: (0000:06:00.0) hw_id=0x8000 sfnum=88 vhca_state=1
- mlx5_sf_dev_add : trace SF device add event::
$ echo mlx5:mlx5_sf_dev_add>> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [000] ..... 24616.524495: mlx5_sf_dev_add: (0000:06:00.0) sfdev=00000000fc5d96fd aux_id=4 hw_id=0x8000 sfnum=88
- mlx5_sf_dev_del : trace SF device delete event::
$ echo mlx5:mlx5_sf_dev_del >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [044] ..... 24624.400749: mlx5_sf_dev_del: (0000:06:00.0) sfdev=00000000fc5d96fd aux_id=4 hw_id=0x8000 sfnum=88
.. SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
.. include:: <isonum.txt>
===========
Tracepoints
===========
:Copyright: |copy| 2023, NVIDIA CORPORATION & AFFILIATES. All rights reserved.
mlx5 driver provides internal tracepoints for tracking and debugging using
kernel tracepoints interfaces (refer to Documentation/trace/ftrace.rst).
For the list of support mlx5 events, check `/sys/kernel/debug/tracing/events/mlx5/`.
tc and eswitch offloads tracepoints:
- mlx5e_configure_flower: trace flower filter actions and cookies offloaded to mlx5::
$ echo mlx5:mlx5e_configure_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6535 [019] ...1 2672.404466: mlx5e_configure_flower: cookie=0000000067874a55 actions= REDIRECT
- mlx5e_delete_flower: trace flower filter actions and cookies deleted from mlx5::
$ echo mlx5:mlx5e_delete_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6569 [010] .N.1 2686.379075: mlx5e_delete_flower: cookie=0000000067874a55 actions= NULL
- mlx5e_stats_flower: trace flower stats request::
$ echo mlx5:mlx5e_stats_flower >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
tc-6546 [010] ...1 2679.704889: mlx5e_stats_flower: cookie=0000000060eb3d6a bytes=0 packets=0 lastused=4295560217
- mlx5e_tc_update_neigh_used_value: trace tunnel rule neigh update value offloaded to mlx5::
$ echo mlx5:mlx5e_tc_update_neigh_used_value >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u48:4-8806 [009] ...1 55117.882428: mlx5e_tc_update_neigh_used_value: netdev: ens1f0 IPv4: 1.1.1.10 IPv6: ::ffff:1.1.1.10 neigh_used=1
- mlx5e_rep_neigh_update: trace neigh update tasks scheduled due to neigh state change events::
$ echo mlx5:mlx5e_rep_neigh_update >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u48:7-2221 [009] ...1 1475.387435: mlx5e_rep_neigh_update: netdev: ens1f0 MAC: 24:8a:07:9a:17:9a IPv4: 1.1.1.10 IPv6: ::ffff:1.1.1.10 neigh_connected=1
Bridge offloads tracepoints:
- mlx5_esw_bridge_fdb_entry_init: trace bridge FDB entry offloaded to mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_init >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u20:9-2217 [003] ...1 318.582243: mlx5_esw_bridge_fdb_entry_init: net_device=enp8s0f0_0 addr=e4:fd:05:08:00:02 vid=0 flags=0 used=0
- mlx5_esw_bridge_fdb_entry_cleanup: trace bridge FDB entry deleted from mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2581 [005] ...1 318.629871: mlx5_esw_bridge_fdb_entry_cleanup: net_device=enp8s0f0_1 addr=e4:fd:05:08:00:03 vid=0 flags=0 used=16
- mlx5_esw_bridge_fdb_entry_refresh: trace bridge FDB entry offload refreshed in
mlx5::
$ echo mlx5:mlx5_esw_bridge_fdb_entry_refresh >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u20:8-3849 [003] ...1 466716: mlx5_esw_bridge_fdb_entry_refresh: net_device=enp8s0f0_0 addr=e4:fd:05:08:00:02 vid=3 flags=0 used=0
- mlx5_esw_bridge_vlan_create: trace bridge VLAN object add on mlx5
representor::
$ echo mlx5:mlx5_esw_bridge_vlan_create >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2560 [007] ...1 318.460258: mlx5_esw_bridge_vlan_create: vid=1 flags=6
- mlx5_esw_bridge_vlan_cleanup: trace bridge VLAN object delete from mlx5
representor::
$ echo mlx5:mlx5_esw_bridge_vlan_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
bridge-2582 [007] ...1 318.653496: mlx5_esw_bridge_vlan_cleanup: vid=2 flags=8
- mlx5_esw_bridge_vport_init: trace mlx5 vport assigned with bridge upper
device::
$ echo mlx5:mlx5_esw_bridge_vport_init >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-2560 [007] ...1 318.458915: mlx5_esw_bridge_vport_init: vport_num=1
- mlx5_esw_bridge_vport_cleanup: trace mlx5 vport removed from bridge upper
device::
$ echo mlx5:mlx5_esw_bridge_vport_cleanup >> set_event
$ cat /sys/kernel/debug/tracing/trace
...
ip-5387 [000] ...1 573713: mlx5_esw_bridge_vport_cleanup: vport_num=1
Eswitch QoS tracepoints:
- mlx5_esw_vport_qos_create: trace creation of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_create >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-23496 [018] .... 73136.838831: mlx5_esw_vport_qos_create: (0000:82:00.0) vport=2 tsar_ix=4 bw_share=0, max_rate=0 group=000000007b576bb3
- mlx5_esw_vport_qos_config: trace configuration of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_config >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-26548 [023] .... 75754.223823: mlx5_esw_vport_qos_config: (0000:82:00.0) vport=1 tsar_ix=3 bw_share=34, max_rate=10000 group=000000007b576bb3
- mlx5_esw_vport_qos_destroy: trace deletion of transmit scheduler arbiter for vport::
$ echo mlx5:mlx5_esw_vport_qos_destroy >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27418 [004] .... 76546.680901: mlx5_esw_vport_qos_destroy: (0000:82:00.0) vport=1 tsar_ix=3
- mlx5_esw_group_qos_create: trace creation of transmit scheduler arbiter for rate group::
$ echo mlx5:mlx5_esw_group_qos_create >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-26578 [008] .... 75776.022112: mlx5_esw_group_qos_create: (0000:82:00.0) group=000000008dac63ea tsar_ix=5
- mlx5_esw_group_qos_config: trace configuration of transmit scheduler arbiter for rate group::
$ echo mlx5:mlx5_esw_group_qos_config >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27303 [020] .... 76461.455356: mlx5_esw_group_qos_config: (0000:82:00.0) group=000000008dac63ea tsar_ix=5 bw_share=100 max_rate=20000
- mlx5_esw_group_qos_destroy: trace deletion of transmit scheduler arbiter for group::
$ echo mlx5:mlx5_esw_group_qos_destroy >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
<...>-27418 [006] .... 76547.187258: mlx5_esw_group_qos_destroy: (0000:82:00.0) group=000000007b576bb3 tsar_ix=1
SF tracepoints:
- mlx5_sf_add: trace addition of the SF port::
$ echo mlx5:mlx5_sf_add >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9363 [031] ..... 24610.188722: mlx5_sf_add: (0000:06:00.0) port_index=32768 controller=0 hw_id=0x8000 sfnum=88
- mlx5_sf_free: trace freeing of the SF port::
$ echo mlx5:mlx5_sf_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9830 [038] ..... 26300.404749: mlx5_sf_free: (0000:06:00.0) port_index=32768 controller=0 hw_id=0x8000
- mlx5_sf_activate: trace activation of the SF port::
$ echo mlx5:mlx5_sf_activate >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-29841 [008] ..... 3669.635095: mlx5_sf_activate: (0000:08:00.0) port_index=32768 controller=0 hw_id=0x8000
- mlx5_sf_deactivate: trace deactivation of the SF port::
$ echo mlx5:mlx5_sf_deactivate >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-29994 [008] ..... 4015.969467: mlx5_sf_deactivate: (0000:08:00.0) port_index=32768 controller=0 hw_id=0x8000
- mlx5_sf_hwc_alloc: trace allocating of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_alloc >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9775 [031] ..... 26296.385259: mlx5_sf_hwc_alloc: (0000:06:00.0) controller=0 hw_id=0x8000 sfnum=88
- mlx5_sf_hwc_free: trace freeing of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [046] ..... 24625.365771: mlx5_sf_hwc_free: (0000:06:00.0) hw_id=0x8000
- mlx5_sf_hwc_deferred_free: trace deferred freeing of the hardware SF context::
$ echo mlx5:mlx5_sf_hwc_deferred_free >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
devlink-9519 [046] ..... 24624.400271: mlx5_sf_hwc_deferred_free: (0000:06:00.0) hw_id=0x8000
- mlx5_sf_update_state: trace state updates for SF contexts::
$ echo mlx5:mlx5_sf_update_state >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u20:3-29490 [009] ..... 4141.453530: mlx5_sf_update_state: (0000:08:00.0) port_index=32768 controller=0 hw_id=0x8000 state=2
- mlx5_sf_vhca_event: trace SF vhca event and state::
$ echo mlx5:mlx5_sf_vhca_event >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [046] ..... 24625.365525: mlx5_sf_vhca_event: (0000:06:00.0) hw_id=0x8000 sfnum=88 vhca_state=1
- mlx5_sf_dev_add: trace SF device add event::
$ echo mlx5:mlx5_sf_dev_add>> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [000] ..... 24616.524495: mlx5_sf_dev_add: (0000:06:00.0) sfdev=00000000fc5d96fd aux_id=4 hw_id=0x8000 sfnum=88
- mlx5_sf_dev_del: trace SF device delete event::
$ echo mlx5:mlx5_sf_dev_del >> /sys/kernel/debug/tracing/set_event
$ cat /sys/kernel/debug/tracing/trace
...
kworker/u128:3-9093 [044] ..... 24624.400749: mlx5_sf_dev_del: (0000:06:00.0) sfdev=00000000fc5d96fd aux_id=4 hw_id=0x8000 sfnum=88
......@@ -454,6 +454,7 @@ struct mlx5e_txqsq {
struct mlx5_clock *clock;
struct net_device *netdev;
struct mlx5_core_dev *mdev;
struct mlx5e_channel *channel;
struct mlx5e_priv *priv;
/* control path */
......
......@@ -771,8 +771,8 @@ void mlx5e_ptp_activate_channel(struct mlx5e_ptp *c)
if (test_bit(MLX5E_PTP_STATE_RX, c->state)) {
mlx5e_ptp_rx_set_fs(c->priv);
mlx5e_activate_rq(&c->rq);
mlx5e_trigger_napi_sched(&c->napi);
}
mlx5e_trigger_napi_sched(&c->napi);
}
void mlx5e_ptp_deactivate_channel(struct mlx5e_ptp *c)
......
......@@ -81,6 +81,10 @@ static int mlx5e_tx_reporter_err_cqe_recover(void *ctx)
sq->stats->recover++;
clear_bit(MLX5E_SQ_STATE_RECOVERING, &sq->state);
mlx5e_activate_txqsq(sq);
if (sq->channel)
mlx5e_trigger_napi_icosq(sq->channel);
else
mlx5e_trigger_napi_sched(sq->cq.napi);
return 0;
out:
......
......@@ -232,9 +232,9 @@ parse_mirred(struct mlx5e_tc_act_parse_state *parse_state,
parse_state->ifindexes[if_count] = out_dev->ifindex;
parse_state->if_count++;
is_uplink_rep = mlx5e_eswitch_uplink_rep(out_dev);
err = mlx5_lag_do_mirred(priv->mdev, out_dev);
if (err)
return err;
if (mlx5_lag_mpesw_do_mirred(priv->mdev, out_dev, extack))
return -EOPNOTSUPP;
out_dev = get_fdb_out_dev(uplink_dev, out_dev);
if (!out_dev)
......
......@@ -158,6 +158,11 @@ void mlx5e_ipsec_build_accel_xfrm_attrs(struct mlx5e_ipsec_sa_entry *sa_entry,
attrs->family = x->props.family;
attrs->type = x->xso.type;
attrs->reqid = x->props.reqid;
attrs->upspec.dport = ntohs(x->sel.dport);
attrs->upspec.dport_mask = ntohs(x->sel.dport_mask);
attrs->upspec.sport = ntohs(x->sel.sport);
attrs->upspec.sport_mask = ntohs(x->sel.sport_mask);
attrs->upspec.proto = x->sel.proto;
mlx5e_ipsec_init_limits(sa_entry, attrs);
}
......@@ -221,6 +226,13 @@ static int mlx5e_xfrm_validate_state(struct mlx5_core_dev *mdev,
NL_SET_ERR_MSG_MOD(extack, "Cannot offload xfrm states with geniv other than seqiv");
return -EINVAL;
}
if (x->sel.proto != IPPROTO_IP &&
(x->sel.proto != IPPROTO_UDP || x->xso.dir != XFRM_DEV_OFFLOAD_OUT)) {
NL_SET_ERR_MSG_MOD(extack, "Device does not support upper protocol other than UDP, and only Tx direction");
return -EINVAL;
}
switch (x->xso.type) {
case XFRM_DEV_OFFLOAD_CRYPTO:
if (!(mlx5_ipsec_device_caps(mdev) & MLX5_IPSEC_CAP_CRYPTO)) {
......@@ -517,6 +529,12 @@ static int mlx5e_xfrm_validate_policy(struct xfrm_policy *x,
return -EINVAL;
}
if (x->selector.proto != IPPROTO_IP &&
(x->selector.proto != IPPROTO_UDP || x->xdo.dir != XFRM_DEV_OFFLOAD_OUT)) {
NL_SET_ERR_MSG_MOD(extack, "Device does not support upper protocol other than UDP, and only Tx direction");
return -EINVAL;
}
return 0;
}
......@@ -537,6 +555,11 @@ mlx5e_ipsec_build_accel_pol_attrs(struct mlx5e_ipsec_pol_entry *pol_entry,
attrs->action = x->action;
attrs->type = XFRM_DEV_OFFLOAD_PACKET;
attrs->reqid = x->xfrm_vec[0].reqid;
attrs->upspec.dport = ntohs(sel->dport);
attrs->upspec.dport_mask = ntohs(sel->dport_mask);
attrs->upspec.sport = ntohs(sel->sport);
attrs->upspec.sport_mask = ntohs(sel->sport_mask);
attrs->upspec.proto = sel->proto;
}
static int mlx5e_xfrm_add_policy(struct xfrm_policy *x,
......
......@@ -52,6 +52,14 @@ struct aes_gcm_keymat {
u32 aes_key[256 / 32];
};
struct upspec {
u16 dport;
u16 dport_mask;
u16 sport;
u16 sport_mask;
u8 proto;
};
struct mlx5_accel_esp_xfrm_attrs {
u32 esn;
u32 spi;
......@@ -68,6 +76,7 @@ struct mlx5_accel_esp_xfrm_attrs {
__be32 a6[4];
} daddr;
struct upspec upspec;
u8 dir : 2;
u8 esn_overlap : 1;
u8 esn_trigger : 1;
......@@ -181,6 +190,7 @@ struct mlx5_accel_pol_xfrm_attrs {
__be32 a6[4];
} daddr;
struct upspec upspec;
u8 family;
u8 action;
u8 type : 2;
......
......@@ -467,6 +467,27 @@ static void setup_fte_reg_c0(struct mlx5_flow_spec *spec, u32 reqid)
misc_parameters_2.metadata_reg_c_0, reqid);
}
static void setup_fte_upper_proto_match(struct mlx5_flow_spec *spec, struct upspec *upspec)
{
if (upspec->proto != IPPROTO_UDP)
return;
spec->match_criteria_enable |= MLX5_MATCH_OUTER_HEADERS;
MLX5_SET_TO_ONES(fte_match_set_lyr_2_4, spec->match_criteria, ip_protocol);
MLX5_SET(fte_match_set_lyr_2_4, spec->match_value, ip_protocol, upspec->proto);
if (upspec->dport) {
MLX5_SET(fte_match_set_lyr_2_4, spec->match_criteria, udp_dport,
upspec->dport_mask);
MLX5_SET(fte_match_set_lyr_2_4, spec->match_value, udp_dport, upspec->dport);
}
if (upspec->sport) {
MLX5_SET(fte_match_set_lyr_2_4, spec->match_criteria, udp_dport,
upspec->sport_mask);
MLX5_SET(fte_match_set_lyr_2_4, spec->match_value, udp_dport, upspec->sport);
}
}
static int setup_modify_header(struct mlx5_core_dev *mdev, u32 val, u8 dir,
struct mlx5_flow_act *flow_act)
{
......@@ -654,6 +675,7 @@ static int tx_add_rule(struct mlx5e_ipsec_sa_entry *sa_entry)
setup_fte_addr6(spec, attrs->saddr.a6, attrs->daddr.a6);
setup_fte_no_frags(spec);
setup_fte_upper_proto_match(spec, &attrs->upspec);
switch (attrs->type) {
case XFRM_DEV_OFFLOAD_CRYPTO:
......@@ -728,6 +750,7 @@ static int tx_add_policy(struct mlx5e_ipsec_pol_entry *pol_entry)
setup_fte_addr6(spec, attrs->saddr.a6, attrs->daddr.a6);
setup_fte_no_frags(spec);
setup_fte_upper_proto_match(spec, &attrs->upspec);
err = setup_modify_header(mdev, attrs->reqid, XFRM_DEV_OFFLOAD_OUT,
&flow_act);
......
......@@ -1470,6 +1470,7 @@ static int mlx5e_alloc_txqsq(struct mlx5e_channel *c,
sq->mkey_be = c->mkey_be;
sq->netdev = c->netdev;
sq->mdev = c->mdev;
sq->channel = c;
sq->priv = c->priv;
sq->ch_ix = c->ix;
sq->txq_ix = txq_ix;
......@@ -2482,8 +2483,6 @@ static void mlx5e_activate_channel(struct mlx5e_channel *c)
mlx5e_activate_xsk(c);
else
mlx5e_activate_rq(&c->rq);
mlx5e_trigger_napi_icosq(c);
}
static void mlx5e_deactivate_channel(struct mlx5e_channel *c)
......@@ -2575,13 +2574,19 @@ int mlx5e_open_channels(struct mlx5e_priv *priv,
return err;
}
static void mlx5e_activate_channels(struct mlx5e_channels *chs)
static void mlx5e_activate_channels(struct mlx5e_priv *priv, struct mlx5e_channels *chs)
{
int i;
for (i = 0; i < chs->num; i++)
mlx5e_activate_channel(chs->c[i]);
if (priv->htb)
mlx5e_qos_activate_queues(priv);
for (i = 0; i < chs->num; i++)
mlx5e_trigger_napi_icosq(chs->c[i]);
if (chs->ptp)
mlx5e_ptp_activate_channel(chs->ptp);
}
......@@ -2888,9 +2893,7 @@ static void mlx5e_build_txq_maps(struct mlx5e_priv *priv)
void mlx5e_activate_priv_channels(struct mlx5e_priv *priv)
{
mlx5e_build_txq_maps(priv);
mlx5e_activate_channels(&priv->channels);
if (priv->htb)
mlx5e_qos_activate_queues(priv);
mlx5e_activate_channels(priv, &priv->channels);
mlx5e_xdp_tx_enable(priv);
/* dev_watchdog() wants all TX queues to be started when the carrier is
......
......@@ -172,6 +172,7 @@ enum mlx5_ptys_rate {
MLX5_PTYS_RATE_EDR = 1 << 5,
MLX5_PTYS_RATE_HDR = 1 << 6,
MLX5_PTYS_RATE_NDR = 1 << 7,
MLX5_PTYS_RATE_XDR = 1 << 8,
};
static inline int mlx5_ptys_rate_enum_to_int(enum mlx5_ptys_rate rate)
......@@ -185,6 +186,7 @@ static inline int mlx5_ptys_rate_enum_to_int(enum mlx5_ptys_rate rate)
case MLX5_PTYS_RATE_EDR: return 25000;
case MLX5_PTYS_RATE_HDR: return 50000;
case MLX5_PTYS_RATE_NDR: return 100000;
case MLX5_PTYS_RATE_XDR: return 200000;
default: return -1;
}
}
......
......@@ -22,7 +22,7 @@ static int type_show(struct seq_file *file, void *priv)
struct mlx5_lag *ldev;
char *mode = NULL;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
if (__mlx5_lag_is_active(ldev))
mode = get_str_mode_type(ldev);
......@@ -41,7 +41,7 @@ static int port_sel_mode_show(struct seq_file *file, void *priv)
int ret = 0;
char *mode;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
if (__mlx5_lag_is_active(ldev))
mode = mlx5_get_str_port_sel_mode(ldev->mode, ldev->mode_flags);
......@@ -61,7 +61,7 @@ static int state_show(struct seq_file *file, void *priv)
struct mlx5_lag *ldev;
bool active;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
active = __mlx5_lag_is_active(ldev);
mutex_unlock(&ldev->lock);
......@@ -77,7 +77,7 @@ static int flags_show(struct seq_file *file, void *priv)
bool shared_fdb;
bool lag_active;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
lag_active = __mlx5_lag_is_active(ldev);
if (!lag_active)
......@@ -108,7 +108,7 @@ static int mapping_show(struct seq_file *file, void *priv)
int num_ports;
int i;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
lag_active = __mlx5_lag_is_active(ldev);
if (lag_active) {
......@@ -142,7 +142,7 @@ static int members_show(struct seq_file *file, void *priv)
struct mlx5_lag *ldev;
int i;
ldev = dev->priv.lag;
ldev = mlx5_lag_dev(dev);
mutex_lock(&ldev->lock);
for (i = 0; i < ldev->ports; i++) {
if (!ldev->pf[i].dev)
......
......@@ -1187,7 +1187,7 @@ static int __mlx5_lag_dev_add_mdev(struct mlx5_core_dev *dev)
tmp_dev = mlx5_get_next_phys_dev_lag(dev);
if (tmp_dev)
ldev = tmp_dev->priv.lag;
ldev = mlx5_lag_dev(tmp_dev);
if (!ldev) {
ldev = mlx5_lag_dev_alloc(dev);
......@@ -1386,8 +1386,7 @@ bool mlx5_lag_is_shared_fdb(struct mlx5_core_dev *dev)
spin_lock_irqsave(&lag_lock, flags);
ldev = mlx5_lag_dev(dev);
res = ldev && __mlx5_lag_is_sriov(ldev) &&
test_bit(MLX5_LAG_MODE_FLAG_SHARED_FDB, &ldev->mode_flags);
res = ldev && test_bit(MLX5_LAG_MODE_FLAG_SHARED_FDB, &ldev->mode_flags);
spin_unlock_irqrestore(&lag_lock, flags);
return res;
......
......@@ -50,19 +50,6 @@ struct lag_tracker {
enum netdev_lag_hash hash_type;
};
enum mpesw_op {
MLX5_MPESW_OP_ENABLE,
MLX5_MPESW_OP_DISABLE,
};
struct mlx5_mpesw_work_st {
struct work_struct work;
struct mlx5_lag *lag;
enum mpesw_op op;
struct completion comp;
int result;
};
/* LAG data of a ConnectX card.
* It serves both its phys functions.
*/
......@@ -124,8 +111,6 @@ int mlx5_activate_lag(struct mlx5_lag *ldev,
int mlx5_lag_dev_get_netdev_idx(struct mlx5_lag *ldev,
struct net_device *ndev);
bool mlx5_shared_fdb_supported(struct mlx5_lag *ldev);
void mlx5_lag_del_mpesw_rule(struct mlx5_core_dev *dev);
int mlx5_lag_add_mpesw_rule(struct mlx5_core_dev *dev);
char *mlx5_get_str_port_sel_mode(enum mlx5_lag_mode mode, unsigned long flags);
void mlx5_infer_tx_enabled(struct lag_tracker *tracker, u8 num_ports,
......
......@@ -28,13 +28,9 @@ static bool mlx5_lag_multipath_check_prereq(struct mlx5_lag *ldev)
bool mlx5_lag_is_multipath(struct mlx5_core_dev *dev)
{
struct mlx5_lag *ldev;
bool res;
ldev = mlx5_lag_dev(dev);
res = ldev && __mlx5_lag_is_multipath(ldev);
struct mlx5_lag *ldev = mlx5_lag_dev(dev);
return res;
return ldev && __mlx5_lag_is_multipath(ldev);
}
/**
......
......@@ -58,7 +58,7 @@ static void mlx5_mpesw_work(struct work_struct *work)
static int mlx5_lag_mpesw_queue_work(struct mlx5_core_dev *dev,
enum mpesw_op op)
{
struct mlx5_lag *ldev = dev->priv.lag;
struct mlx5_lag *ldev = mlx5_lag_dev(dev);
struct mlx5_mpesw_work_st *work;
int err = 0;
......@@ -96,25 +96,27 @@ int mlx5_lag_add_mpesw_rule(struct mlx5_core_dev *dev)
return mlx5_lag_mpesw_queue_work(dev, MLX5_MPESW_OP_ENABLE);
}
int mlx5_lag_do_mirred(struct mlx5_core_dev *mdev, struct net_device *out_dev)
int mlx5_lag_mpesw_do_mirred(struct mlx5_core_dev *mdev,
struct net_device *out_dev,
struct netlink_ext_ack *extack)
{
struct mlx5_lag *ldev = mdev->priv.lag;
struct mlx5_lag *ldev = mlx5_lag_dev(mdev);
if (!netif_is_bond_master(out_dev) || !ldev)
return 0;
if (ldev->mode == MLX5_LAG_MODE_MPESW)
return -EOPNOTSUPP;
if (ldev->mode != MLX5_LAG_MODE_MPESW)
return 0;
NL_SET_ERR_MSG_MOD(extack, "can't forward to bond in mpesw mode");
return -EOPNOTSUPP;
}
bool mlx5_lag_mpesw_is_activated(struct mlx5_core_dev *dev)
{
bool ret;
struct mlx5_lag *ldev = mlx5_lag_dev(dev);
ret = dev->priv.lag && dev->priv.lag->mode == MLX5_LAG_MODE_MPESW;
return ret;
return ldev && ldev->mode == MLX5_LAG_MODE_MPESW;
}
void mlx5_lag_mpesw_init(struct mlx5_lag *ldev)
......
......@@ -12,8 +12,25 @@ struct lag_mpesw {
atomic_t mpesw_rule_count;
};
int mlx5_lag_do_mirred(struct mlx5_core_dev *mdev, struct net_device *out_dev);
enum mpesw_op {
MLX5_MPESW_OP_ENABLE,
MLX5_MPESW_OP_DISABLE,
};
struct mlx5_mpesw_work_st {
struct work_struct work;
struct mlx5_lag *lag;
enum mpesw_op op;
struct completion comp;
int result;
};
int mlx5_lag_mpesw_do_mirred(struct mlx5_core_dev *mdev,
struct net_device *out_dev,
struct netlink_ext_ack *extack);
bool mlx5_lag_mpesw_is_activated(struct mlx5_core_dev *dev);
void mlx5_lag_del_mpesw_rule(struct mlx5_core_dev *dev);
int mlx5_lag_add_mpesw_rule(struct mlx5_core_dev *dev);
#if IS_ENABLED(CONFIG_MLX5_ESWITCH)
void mlx5_lag_mpesw_init(struct mlx5_lag *ldev);
void mlx5_lag_mpesw_cleanup(struct mlx5_lag *ldev);
......
......@@ -362,7 +362,7 @@ static int mlx5_ptp_adjphase(struct ptp_clock_info *ptp, s32 delta)
return mlx5_ptp_adjtime(ptp, delta);
}
static int mlx5_ptp_adjfreq_real_time(struct mlx5_core_dev *mdev, s32 freq)
static int mlx5_ptp_freq_adj_real_time(struct mlx5_core_dev *mdev, long scaled_ppm)
{
u32 in[MLX5_ST_SZ_DW(mtutc_reg)] = {};
......@@ -370,7 +370,15 @@ static int mlx5_ptp_adjfreq_real_time(struct mlx5_core_dev *mdev, s32 freq)
return 0;
MLX5_SET(mtutc_reg, in, operation, MLX5_MTUTC_OPERATION_ADJUST_FREQ_UTC);
MLX5_SET(mtutc_reg, in, freq_adjustment, freq);
if (MLX5_CAP_MCAM_FEATURE(mdev, mtutc_freq_adj_units)) {
MLX5_SET(mtutc_reg, in, freq_adj_units,
MLX5_MTUTC_FREQ_ADJ_UNITS_SCALED_PPM);
MLX5_SET(mtutc_reg, in, freq_adjustment, scaled_ppm);
} else {
MLX5_SET(mtutc_reg, in, freq_adj_units, MLX5_MTUTC_FREQ_ADJ_UNITS_PPB);
MLX5_SET(mtutc_reg, in, freq_adjustment, scaled_ppm_to_ppb(scaled_ppm));
}
return mlx5_set_mtutc(mdev, in, sizeof(in));
}
......@@ -385,7 +393,8 @@ static int mlx5_ptp_adjfine(struct ptp_clock_info *ptp, long scaled_ppm)
int err;
mdev = container_of(clock, struct mlx5_core_dev, clock);
err = mlx5_ptp_adjfreq_real_time(mdev, scaled_ppm_to_ppb(scaled_ppm));
err = mlx5_ptp_freq_adj_real_time(mdev, scaled_ppm);
if (err)
return err;
......
......@@ -211,7 +211,8 @@ static int alloc_4k(struct mlx5_core_dev *dev, u64 *addr, u32 function)
n = find_first_bit(&fp->bitmask, 8 * sizeof(fp->bitmask));
if (n >= MLX5_NUM_4K_IN_PAGE) {
mlx5_core_warn(dev, "alloc 4k bug\n");
mlx5_core_warn(dev, "alloc 4k bug: fw page = 0x%llx, n = %u, bitmask: %lu, max num of 4K pages: %d\n",
fp->addr, n, fp->bitmask, MLX5_NUM_4K_IN_PAGE);
return -ENOENT;
}
clear_bit(n, &fp->bitmask);
......
......@@ -9925,6 +9925,11 @@ struct mlx5_ifc_mpegc_reg_bits {
u8 reserved_at_60[0x100];
};
enum {
MLX5_MTUTC_FREQ_ADJ_UNITS_PPB = 0x0,
MLX5_MTUTC_FREQ_ADJ_UNITS_SCALED_PPM = 0x1,
};
enum {
MLX5_MTUTC_OPERATION_SET_TIME_IMMEDIATE = 0x1,
MLX5_MTUTC_OPERATION_ADJUST_TIME = 0x2,
......@@ -9932,7 +9937,9 @@ enum {
};
struct mlx5_ifc_mtutc_reg_bits {
u8 reserved_at_0[0x1c];
u8 reserved_at_0[0x5];
u8 freq_adj_units[0x3];
u8 reserved_at_8[0x14];
u8 operation[0x4];
u8 freq_adjustment[0x20];
......@@ -10005,7 +10012,8 @@ struct mlx5_ifc_pcam_reg_bits {
};
struct mlx5_ifc_mcam_enhanced_features_bits {
u8 reserved_at_0[0x51];
u8 reserved_at_0[0x50];
u8 mtutc_freq_adj_units[0x1];
u8 mtutc_time_adjustment_extended_range[0x1];
u8 reserved_at_52[0xb];
u8 mcia_32dwords[0x1];
......
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