[dpdk.git] / doc / guides / nics / mlx5.rst

..  SPDX-License-Identifier: BSD-3-Clause
    Copyright 2015 6WIND S.A.
    Copyright 2015 Mellanox Technologies, Ltd

.. include:: <isonum.txt>

MLX5 poll mode driver
=====================

The MLX5 poll mode driver library (**librte_pmd_mlx5**) provides support
for **Mellanox ConnectX-4**, **Mellanox ConnectX-4 Lx** , **Mellanox
ConnectX-5**, **Mellanox ConnectX-6**, **Mellanox ConnectX-6 Dx** and
**Mellanox BlueField** families of 10/25/40/50/100/200 Gb/s adapters
as well as their virtual functions (VF) in SR-IOV context.

Information and documentation about these adapters can be found on the
`Mellanox website <http://www.mellanox.com>`__. Help is also provided by the
`Mellanox community <http://community.mellanox.com/welcome>`__.

There is also a `section dedicated to this poll mode driver
<http://www.mellanox.com/page/products_dyn?product_family=209&mtag=pmd_for_dpdk>`__.

.. note::

   Due to external dependencies, this driver is disabled in default configuration
   of the "make" build. It can be enabled with ``CONFIG_RTE_LIBRTE_MLX5_PMD=y``
   or by using "meson" build system which will detect dependencies.

Design
------

Besides its dependency on libibverbs (that implies libmlx5 and associated
kernel support), librte_pmd_mlx5 relies heavily on system calls for control
operations such as querying/updating the MTU and flow control parameters.

For security reasons and robustness, this driver only deals with virtual
memory addresses. The way resources allocations are handled by the kernel,
combined with hardware specifications that allow to handle virtual memory
addresses directly, ensure that DPDK applications cannot access random
physical memory (or memory that does not belong to the current process).

This capability allows the PMD to coexist with kernel network interfaces
which remain functional, although they stop receiving unicast packets as
long as they share the same MAC address.
This means legacy linux control tools (for example: ethtool, ifconfig and
more) can operate on the same network interfaces that owned by the DPDK
application.

The PMD can use libibverbs and libmlx5 to access the device firmware
or directly the hardware components.
There are different levels of objects and bypassing abilities
to get the best performances:

- Verbs is a complete high-level generic API
- Direct Verbs is a device-specific API
- DevX allows to access firmware objects
- Direct Rules manages flow steering at low-level hardware layer

Enabling librte_pmd_mlx5 causes DPDK applications to be linked against
libibverbs.

Features
--------

- Multi arch support: x86_64, POWER8, ARMv8, i686.
- Multiple TX and RX queues.
- Support for scattered TX and RX frames.
- IPv4, IPv6, TCPv4, TCPv6, UDPv4 and UDPv6 RSS on any number of queues.
- RSS using different combinations of fields: L3 only, L4 only or both,
  and source only, destination only or both.
- Several RSS hash keys, one for each flow type.
- Default RSS operation with no hash key specification.
- Configurable RETA table.
- Link flow control (pause frame).
- Support for multiple MAC addresses.
- VLAN filtering.
- RX VLAN stripping.
- TX VLAN insertion.
- RX CRC stripping configuration.
- Promiscuous mode on PF and VF.
- Multicast promiscuous mode on PF and VF.
- Hardware checksum offloads.
- Flow director (RTE_FDIR_MODE_PERFECT, RTE_FDIR_MODE_PERFECT_MAC_VLAN and
  RTE_ETH_FDIR_REJECT).
- Flow API, including :ref:`flow_isolated_mode`.
- Multiple process.
- KVM and VMware ESX SR-IOV modes are supported.
- RSS hash result is supported.
- Hardware TSO for generic IP or UDP tunnel, including VXLAN and GRE.
- Hardware checksum Tx offload for generic IP or UDP tunnel, including VXLAN and GRE.
- RX interrupts.
- Statistics query including Basic, Extended and per queue.
- Rx HW timestamp.
- Tunnel types: VXLAN, L3 VXLAN, VXLAN-GPE, GRE, MPLSoGRE, MPLSoUDP, IP-in-IP, Geneve, GTP.
- Tunnel HW offloads: packet type, inner/outer RSS, IP and UDP checksum verification.
- NIC HW offloads: encapsulation (vxlan, gre, mplsoudp, mplsogre), NAT, routing, TTL
  increment/decrement, count, drop, mark. For details please see :ref:`mlx5_offloads_support`.
- Flow insertion rate of more then million flows per second, when using Direct Rules.
- Support for multiple rte_flow groups.
- Per packet no-inline hint flag to disable packet data copying into Tx descriptors.
- Hardware LRO.

Limitations
-----------

- For secondary process:

  - Forked secondary process not supported.
  - External memory unregistered in EAL memseg list cannot be used for DMA
    unless such memory has been registered by ``mlx5_mr_update_ext_mp()`` in
    primary process and remapped to the same virtual address in secondary
    process. If the external memory is registered by primary process but has
    different virtual address in secondary process, unexpected error may happen.

- When using Verbs flow engine (``dv_flow_en`` = 0), flow pattern without any
  specific VLAN will match for VLAN packets as well:

  When VLAN spec is not specified in the pattern, the matching rule will be created with VLAN as a wild card.
  Meaning, the flow rule::

        flow create 0 ingress pattern eth / vlan vid is 3 / ipv4 / end ...

  Will only match vlan packets with vid=3. and the flow rule::

        flow create 0 ingress pattern eth / ipv4 / end ...

  Will match any ipv4 packet (VLAN included).

- VLAN pop offload command:

  - Flow rules having a VLAN pop offload command as one of their actions and
    are lacking a match on VLAN as one of their items are not supported.
  - The command is not supported on egress traffic.

- VLAN push offload is not supported on ingress traffic.

- VLAN set PCP offload is not supported on existing headers.

- A multi segment packet must have not more segments than reported by dev_infos_get()
  in tx_desc_lim.nb_seg_max field. This value depends on maximal supported Tx descriptor
  size and ``txq_inline_min`` settings and may be from 2 (worst case forced by maximal
  inline settings) to 58.

- Flows with a VXLAN Network Identifier equal (or ends to be equal)
  to 0 are not supported.

- VXLAN TSO and checksum offloads are not supported on VM.

- L3 VXLAN and VXLAN-GPE tunnels cannot be supported together with MPLSoGRE and MPLSoUDP.

- Match on Geneve header supports the following fields only:

     - VNI
     - OAM
     - protocol type
     - options length
       Currently, the only supported options length value is 0.

- VF: flow rules created on VF devices can only match traffic targeted at the
  configured MAC addresses (see ``rte_eth_dev_mac_addr_add()``).

- Match on GTP tunnel header item supports the following fields only:

     - msg_type
     - teid

- No Tx metadata go to the E-Switch steering domain for the Flow group 0.
  The flows within group 0 and set metadata action are rejected by hardware.

.. note::

   MAC addresses not already present in the bridge table of the associated
   kernel network device will be added and cleaned up by the PMD when closing
   the device. In case of ungraceful program termination, some entries may
   remain present and should be removed manually by other means.

- When Multi-Packet Rx queue is configured (``mprq_en``), a Rx packet can be
  externally attached to a user-provided mbuf with having EXT_ATTACHED_MBUF in
  ol_flags. As the mempool for the external buffer is managed by PMD, all the
  Rx mbufs must be freed before the device is closed. Otherwise, the mempool of
  the external buffers will be freed by PMD and the application which still
  holds the external buffers may be corrupted.

- If Multi-Packet Rx queue is configured (``mprq_en``) and Rx CQE compression is
  enabled (``rxq_cqe_comp_en``) at the same time, RSS hash result is not fully
  supported. Some Rx packets may not have PKT_RX_RSS_HASH.

- IPv6 Multicast messages are not supported on VM, while promiscuous mode
  and allmulticast mode are both set to off.
  To receive IPv6 Multicast messages on VM, explicitly set the relevant
  MAC address using rte_eth_dev_mac_addr_add() API.

- To support a mixed traffic pattern (some buffers from local host memory, some
  buffers from other devices) with high bandwidth, a mbuf flag is used.

  An application hints the PMD whether or not it should try to inline the
  given mbuf data buffer. PMD should do the best effort to act upon this request.

  The hint flag ``RTE_PMD_MLX5_FINE_GRANULARITY_INLINE`` is dynamic,
  registered by application with rte_mbuf_dynflag_register(). This flag is
  purely driver-specific and declared in PMD specific header ``rte_pmd_mlx5.h``,
  which is intended to be used by the application.

  To query the supported specific flags in runtime,
  the function ``rte_pmd_mlx5_get_dyn_flag_names`` returns the array of
  currently (over present hardware and configuration) supported specific flags.
  The "not inline hint" feature operating flow is the following one:

    - application starts
    - probe the devices, ports are created
    - query the port capabilities
    - if port supporting the feature is found
    - register dynamic flag ``RTE_PMD_MLX5_FINE_GRANULARITY_INLINE``
    - application starts the ports
    - on ``dev_start()`` PMD checks whether the feature flag is registered and
      enables the feature support in datapath
    - application might set the registered flag bit in ``ol_flags`` field
      of mbuf being sent and PMD will handle ones appropriately.

- The amount of descriptors in Tx queue may be limited by data inline settings.
  Inline data require the more descriptor building blocks and overall block
  amount may exceed the hardware supported limits. The application should
  reduce the requested Tx size or adjust data inline settings with
  ``txq_inline_max`` and ``txq_inline_mpw`` devargs keys.

- E-Switch decapsulation Flow:

  - can be applied to PF port only.
  - must specify VF port action (packet redirection from PF to VF).
  - optionally may specify tunnel inner source and destination MAC addresses.

- E-Switch  encapsulation Flow:

  - can be applied to VF ports only.
  - must specify PF port action (packet redirection from VF to PF).

- Raw encapsulation:

  - The input buffer, used as outer header, is not validated.

- Raw decapsulation:

  - The decapsulation is always done up to the outermost tunnel detected by the HW.
  - The input buffer, providing the removal size, is not validated.
  - The buffer size must match the length of the headers to be removed.

- ICMP/ICMP6 code/type matching, IP-in-IP and MPLS flow matching are all
  mutually exclusive features which cannot be supported together
  (see :ref:`mlx5_firmware_config`).

- LRO:

  - Requires DevX and DV flow to be enabled.
  - KEEP_CRC offload cannot be supported with LRO.
  - The first mbuf length, without head-room,  must be big enough to include the
    TCP header (122B).
  - Rx queue with LRO offload enabled, receiving a non-LRO packet, can forward
    it with size limited to max LRO size, not to max RX packet length.

Statistics
----------

MLX5 supports various methods to report statistics:

Port statistics can be queried using ``rte_eth_stats_get()``. The received and sent statistics are through SW only and counts the number of packets received or sent successfully by the PMD. The imissed counter is the amount of packets that could not be delivered to SW because a queue was full. Packets not received due to congestion in the bus or on the NIC can be queried via the rx_discards_phy xstats counter.

Extended statistics can be queried using ``rte_eth_xstats_get()``. The extended statistics expose a wider set of counters counted by the device. The extended port statistics counts the number of packets received or sent successfully by the port. As Mellanox NICs are using the :ref:`Bifurcated Linux Driver <linux_gsg_linux_drivers>` those counters counts also packet received or sent by the Linux kernel. The counters with ``_phy`` suffix counts the total events on the physical port, therefore not valid for VF.

Finally per-flow statistics can by queried using ``rte_flow_query`` when attaching a count action for specific flow. The flow counter counts the number of packets received successfully by the port and match the specific flow.

Configuration
-------------

Compilation options
~~~~~~~~~~~~~~~~~~~

These options can be modified in the ``.config`` file.

- ``CONFIG_RTE_LIBRTE_MLX5_PMD`` (default **n**)

  Toggle compilation of librte_pmd_mlx5 itself.

- ``CONFIG_RTE_IBVERBS_LINK_DLOPEN`` (default **n**)

  Build PMD with additional code to make it loadable without hard
  dependencies on **libibverbs** nor **libmlx5**, which may not be installed
  on the target system.

  In this mode, their presence is still required for it to run properly,
  however their absence won't prevent a DPDK application from starting (with
  ``CONFIG_RTE_BUILD_SHARED_LIB`` disabled) and they won't show up as
  missing with ``ldd(1)``.

  It works by moving these dependencies to a purpose-built rdma-core "glue"
  plug-in which must either be installed in a directory whose name is based
  on ``CONFIG_RTE_EAL_PMD_PATH`` suffixed with ``-glue`` if set, or in a
  standard location for the dynamic linker (e.g. ``/lib``) if left to the
  default empty string (``""``).

  This option has no performance impact.

- ``CONFIG_RTE_IBVERBS_LINK_STATIC`` (default **n**)

  Embed static flavor of the dependencies **libibverbs** and **libmlx5**
  in the PMD shared library or the executable static binary.

- ``CONFIG_RTE_LIBRTE_MLX5_DEBUG`` (default **n**)

  Toggle debugging code and stricter compilation flags. Enabling this option
  adds additional run-time checks and debugging messages at the cost of
  lower performance.

.. note::

   For BlueField, target should be set to ``arm64-bluefield-linux-gcc``. This
   will enable ``CONFIG_RTE_LIBRTE_MLX5_PMD`` and set ``RTE_CACHE_LINE_SIZE`` to
   64. Default armv8a configuration of make build and meson build set it to 128
   then brings performance degradation.

This option is available in meson:

- ``ibverbs_link`` can be ``static``, ``shared``, or ``dlopen``.

Environment variables
~~~~~~~~~~~~~~~~~~~~~

- ``MLX5_GLUE_PATH``

  A list of directories in which to search for the rdma-core "glue" plug-in,
  separated by colons or semi-colons.

  Only matters when compiled with ``CONFIG_RTE_IBVERBS_LINK_DLOPEN``
  enabled and most useful when ``CONFIG_RTE_EAL_PMD_PATH`` is also set,
  since ``LD_LIBRARY_PATH`` has no effect in this case.

- ``MLX5_SHUT_UP_BF``

  Configures HW Tx doorbell register as IO-mapped.

  By default, the HW Tx doorbell is configured as a write-combining register.
  The register would be flushed to HW usually when the write-combining buffer
  becomes full, but it depends on CPU design.

  Except for vectorized Tx burst routines, a write memory barrier is enforced
  after updating the register so that the update can be immediately visible to
  HW.

  When vectorized Tx burst is called, the barrier is set only if the burst size
  is not aligned to MLX5_VPMD_TX_MAX_BURST. However, setting this environmental
  variable will bring better latency even though the maximum throughput can
  slightly decline.

Run-time configuration
~~~~~~~~~~~~~~~~~~~~~~

- librte_pmd_mlx5 brings kernel network interfaces up during initialization
  because it is affected by their state. Forcing them down prevents packets
  reception.

- **ethtool** operations on related kernel interfaces also affect the PMD.

- ``rxq_cqe_comp_en`` parameter [int]

  A nonzero value enables the compression of CQE on RX side. This feature
  allows to save PCI bandwidth and improve performance. Enabled by default.

  Supported on:

  - x86_64 with ConnectX-4, ConnectX-4 Lx, ConnectX-5, ConnectX-6, ConnectX-6 Dx
    and BlueField.
  - POWER9 and ARMv8 with ConnectX-4 Lx, ConnectX-5, ConnectX-6, ConnectX-6 Dx
    and BlueField.

- ``rxq_cqe_pad_en`` parameter [int]

  A nonzero value enables 128B padding of CQE on RX side. The size of CQE
  is aligned with the size of a cacheline of the core. If cacheline size is
  128B, the CQE size is configured to be 128B even though the device writes
  only 64B data on the cacheline. This is to avoid unnecessary cache
  invalidation by device's two consecutive writes on to one cacheline.
  However in some architecture, it is more beneficial to update entire
  cacheline with padding the rest 64B rather than striding because
  read-modify-write could drop performance a lot. On the other hand,
  writing extra data will consume more PCIe bandwidth and could also drop
  the maximum throughput. It is recommended to empirically set this
  parameter. Disabled by default.

  Supported on:

  - CPU having 128B cacheline with ConnectX-5 and BlueField.

- ``rxq_pkt_pad_en`` parameter [int]

  A nonzero value enables padding Rx packet to the size of cacheline on PCI
  transaction. This feature would waste PCI bandwidth but could improve
  performance by avoiding partial cacheline write which may cause costly
  read-modify-copy in memory transaction on some architectures. Disabled by
  default.

  Supported on:

  - x86_64 with ConnectX-4, ConnectX-4 Lx, ConnectX-5, ConnectX-6, ConnectX-6 Dx
    and BlueField.
  - POWER8 and ARMv8 with ConnectX-4 Lx, ConnectX-5, ConnectX-6, ConnectX-6 Dx
    and BlueField.

- ``mprq_en`` parameter [int]

  A nonzero value enables configuring Multi-Packet Rx queues. Rx queue is
  configured as Multi-Packet RQ if the total number of Rx queues is
  ``rxqs_min_mprq`` or more and Rx scatter isn't configured. Disabled by
  default.

  Multi-Packet Rx Queue (MPRQ a.k.a Striding RQ) can further save PCIe bandwidth
  by posting a single large buffer for multiple packets. Instead of posting a
  buffers per a packet, one large buffer is posted in order to receive multiple
  packets on the buffer. A MPRQ buffer consists of multiple fixed-size strides
  and each stride receives one packet. MPRQ can improve throughput for
  small-packet traffic.

  When MPRQ is enabled, max_rx_pkt_len can be larger than the size of
  user-provided mbuf even if DEV_RX_OFFLOAD_SCATTER isn't enabled. PMD will
  configure large stride size enough to accommodate max_rx_pkt_len as long as
  device allows. Note that this can waste system memory compared to enabling Rx
  scatter and multi-segment packet.

- ``mprq_log_stride_num`` parameter [int]

  Log 2 of the number of strides for Multi-Packet Rx queue. Configuring more
  strides can reduce PCIe traffic further. If configured value is not in the
  range of device capability, the default value will be set with a warning
  message. The default value is 4 which is 16 strides per a buffer, valid only
  if ``mprq_en`` is set.

  The size of Rx queue should be bigger than the number of strides.

- ``mprq_max_memcpy_len`` parameter [int]

  The maximum length of packet to memcpy in case of Multi-Packet Rx queue. Rx
  packet is mem-copied to a user-provided mbuf if the size of Rx packet is less
  than or equal to this parameter. Otherwise, PMD will attach the Rx packet to
  the mbuf by external buffer attachment - ``rte_pktmbuf_attach_extbuf()``.
  A mempool for external buffers will be allocated and managed by PMD. If Rx
  packet is externally attached, ol_flags field of the mbuf will have
  EXT_ATTACHED_MBUF and this flag must be preserved. ``RTE_MBUF_HAS_EXTBUF()``
  checks the flag. The default value is 128, valid only if ``mprq_en`` is set.

- ``rxqs_min_mprq`` parameter [int]

  Configure Rx queues as Multi-Packet RQ if the total number of Rx queues is
  greater or equal to this value. The default value is 12, valid only if
  ``mprq_en`` is set.

- ``txq_inline`` parameter [int]

  Amount of data to be inlined during TX operations. This parameter is
  deprecated and converted to the new parameter ``txq_inline_max`` providing
  partial compatibility.

- ``txqs_min_inline`` parameter [int]

  Enable inline data send only when the number of TX queues is greater or equal
  to this value.

  This option should be used in combination with ``txq_inline_max`` and
  ``txq_inline_mpw`` below and does not affect ``txq_inline_min`` settings above.

  If this option is not specified the default value 16 is used for BlueField
  and 8 for other platforms

  The data inlining consumes the CPU cycles, so this option is intended to
  auto enable inline data if we have enough Tx queues, which means we have
  enough CPU cores and PCI bandwidth is getting more critical and CPU
  is not supposed to be bottleneck anymore.

  The copying data into WQE improves latency and can improve PPS performance
  when PCI back pressure is detected and may be useful for scenarios involving
  heavy traffic on many queues.

  Because additional software logic is necessary to handle this mode, this
  option should be used with care, as it may lower performance when back
  pressure is not expected.

  If inline data are enabled it may affect the maximal size of Tx queue in
  descriptors because the inline data increase the descriptor size and
  queue size limits supported by hardware may be exceeded.

- ``txq_inline_min`` parameter [int]

  Minimal amount of data to be inlined into WQE during Tx operations. NICs
  may require this minimal data amount to operate correctly. The exact value
  may depend on NIC operation mode, requested offloads, etc. It is strongly
  recommended to omit this parameter and use the default values. Anyway,
  applications using this parameter should take into consideration that
  specifying an inconsistent value may prevent the NIC from sending packets.

  If ``txq_inline_min`` key is present the specified value (may be aligned
  by the driver in order not to exceed the limits and provide better descriptor
  space utilization) will be used by the driver and it is guaranteed that
  requested amount of data bytes are inlined into the WQE beside other inline
  settings. This key also may update ``txq_inline_max`` value (default
  or specified explicitly in devargs) to reserve the space for inline data.

  If ``txq_inline_min`` key is not present, the value may be queried by the
  driver from the NIC via DevX if this feature is available. If there is no DevX
  enabled/supported the value 18 (supposing L2 header including VLAN) is set
  for ConnectX-4 and ConnectX-4 Lx, and 0 is set by default for ConnectX-5
  and newer NICs. If packet is shorter the ``txq_inline_min`` value, the entire
  packet is inlined.

  For ConnectX-4 NIC, driver does not allow specifying value below 18
  (minimal L2 header, including VLAN), error will be raised.

  For ConnectX-4 Lx NIC, it is allowed to specify values below 18, but
  it is not recommended and may prevent NIC from sending packets over
  some configurations.

  Please, note, this minimal data inlining disengages eMPW feature (Enhanced
  Multi-Packet Write), because last one does not support partial packet inlining.
  This is not very critical due to minimal data inlining is mostly required
  by ConnectX-4 and ConnectX-4 Lx, these NICs do not support eMPW feature.

- ``txq_inline_max`` parameter [int]

  Specifies the maximal packet length to be completely inlined into WQE
  Ethernet Segment for ordinary SEND method. If packet is larger than specified
  value, the packet data won't be copied by the driver at all, data buffer
  is addressed with a pointer. If packet length is less or equal all packet
  data will be copied into WQE. This may improve PCI bandwidth utilization for
  short packets significantly but requires the extra CPU cycles.

  The data inline feature is controlled by number of Tx queues, if number of Tx
  queues is larger than ``txqs_min_inline`` key parameter, the inline feature
  is engaged, if there are not enough Tx queues (which means not enough CPU cores
  and CPU resources are scarce), data inline is not performed by the driver.
  Assigning ``txqs_min_inline`` with zero always enables the data inline.

  The default ``txq_inline_max`` value is 290. The specified value may be adjusted
  by the driver in order not to exceed the limit (930 bytes) and to provide better
  WQE space filling without gaps, the adjustment is reflected in the debug log.
  Also, the default value (290) may be decreased in run-time if the large transmit
  queue size is requested and hardware does not support enough descriptor
  amount, in this case warning is emitted. If ``txq_inline_max`` key is
  specified and requested inline settings can not be satisfied then error
  will be raised.

- ``txq_inline_mpw`` parameter [int]

  Specifies the maximal packet length to be completely inlined into WQE for
  Enhanced MPW method. If packet is large the specified value, the packet data
  won't be copied, and data buffer is addressed with pointer. If packet length
  is less or equal, all packet data will be copied into WQE. This may improve PCI
  bandwidth utilization for short packets significantly but requires the extra
  CPU cycles.

  The data inline feature is controlled by number of TX queues, if number of Tx
  queues is larger than ``txqs_min_inline`` key parameter, the inline feature
  is engaged, if there are not enough Tx queues (which means not enough CPU cores
  and CPU resources are scarce), data inline is not performed by the driver.
  Assigning ``txqs_min_inline`` with zero always enables the data inline.

  The default ``txq_inline_mpw`` value is 268. The specified value may be adjusted
  by the driver in order not to exceed the limit (930 bytes) and to provide better
  WQE space filling without gaps, the adjustment is reflected in the debug log.
  Due to multiple packets may be included to the same WQE with Enhanced Multi
  Packet Write Method and overall WQE size is limited it is not recommended to
  specify large values for the ``txq_inline_mpw``. Also, the default value (268)
  may be decreased in run-time if the large transmit queue size is requested
  and hardware does not support enough descriptor amount, in this case warning
  is emitted. If ``txq_inline_mpw`` key is  specified and requested inline
  settings can not be satisfied then error will be raised.

- ``txqs_max_vec`` parameter [int]

  Enable vectorized Tx only when the number of TX queues is less than or
  equal to this value. This parameter is deprecated and ignored, kept
  for compatibility issue to not prevent driver from probing.

- ``txq_mpw_hdr_dseg_en`` parameter [int]

  A nonzero value enables including two pointers in the first block of TX
  descriptor. The parameter is deprecated and ignored, kept for compatibility
  issue.

- ``txq_max_inline_len`` parameter [int]

  Maximum size of packet to be inlined. This limits the size of packet to
  be inlined. If the size of a packet is larger than configured value, the
  packet isn't inlined even though there's enough space remained in the
  descriptor. Instead, the packet is included with pointer. This parameter
  is deprecated and converted directly to ``txq_inline_mpw`` providing full
  compatibility. Valid only if eMPW feature is engaged.

- ``txq_mpw_en`` parameter [int]

  A nonzero value enables Enhanced Multi-Packet Write (eMPW) for ConnectX-5,
  ConnectX-6, ConnectX-6 Dx and BlueField. eMPW allows the TX burst function to pack
  up multiple packets in a single descriptor session in order to save PCI bandwidth
  and improve performance at the cost of a slightly higher CPU usage. When
  ``txq_inline_mpw`` is set along with ``txq_mpw_en``, TX burst function copies
  entire packet data on to TX descriptor instead of including pointer of packet.

  The Enhanced Multi-Packet Write feature is enabled by default if NIC supports
  it, can be disabled by explicit specifying 0 value for ``txq_mpw_en`` option.
  Also, if minimal data inlining is requested by non-zero ``txq_inline_min``
  option or reported by the NIC, the eMPW feature is disengaged.

- ``tx_db_nc`` parameter [int]

  The rdma core library can map doorbell register in two ways, depending on the
  environment variable "MLX5_SHUT_UP_BF":

  - As regular cached memory (usually with write combining attribute), if the
    variable is either missing or set to zero.
  - As non-cached memory, if the variable is present and set to not "0" value.

  The type of mapping may slightly affect the Tx performance, the optimal choice
  is strongly relied on the host architecture and should be deduced practically.

  If ``tx_db_nc`` is set to zero, the doorbell is forced to be mapped to regular
  memory (with write combining), the PMD will perform the extra write memory barrier
  after writing to doorbell, it might increase the needed CPU clocks per packet
  to send, but latency might be improved.

  If ``tx_db_nc`` is set to one, the doorbell is forced to be mapped to non
  cached memory, the PMD will not perform the extra write memory barrier
  after writing to doorbell, on some architectures it might improve the
  performance.

  If ``tx_db_nc`` is set to two, the doorbell is forced to be mapped to regular
  memory, the PMD will use heuristics to decide whether write memory barrier
  should be performed. For bursts with size multiple of recommended one (64 pkts)
  it is supposed the next burst is coming and no need to issue the extra memory
  barrier (it is supposed to be issued in the next coming burst, at least after
  descriptor writing). It might increase latency (on some hosts till next
  packets transmit) and should be used with care.

  If ``tx_db_nc`` is omitted or set to zero, the preset (if any) environment
  variable "MLX5_SHUT_UP_BF" value is used. If there is no "MLX5_SHUT_UP_BF",
  the default ``tx_db_nc`` value is zero for ARM64 hosts and one for others.

- ``tx_vec_en`` parameter [int]

  A nonzero value enables Tx vector on ConnectX-5, ConnectX-6, ConnectX-6 Dx
  and BlueField NICs if the number of global Tx queues on the port is less than
  ``txqs_max_vec``. The parameter is deprecated and ignored.

- ``rx_vec_en`` parameter [int]

  A nonzero value enables Rx vector if the port is not configured in
  multi-segment otherwise this parameter is ignored.

  Enabled by default.

- ``vf_nl_en`` parameter [int]

  A nonzero value enables Netlink requests from the VF to add/remove MAC
  addresses or/and enable/disable promiscuous/all multicast on the Netdevice.
  Otherwise the relevant configuration must be run with Linux iproute2 tools.
  This is a prerequisite to receive this kind of traffic.

  Enabled by default, valid only on VF devices ignored otherwise.

- ``l3_vxlan_en`` parameter [int]

  A nonzero value allows L3 VXLAN and VXLAN-GPE flow creation. To enable
  L3 VXLAN or VXLAN-GPE, users has to configure firmware and enable this
  parameter. This is a prerequisite to receive this kind of traffic.

  Disabled by default.

- ``dv_xmeta_en`` parameter [int]

  A nonzero value enables extensive flow metadata support if device is
  capable and driver supports it. This can enable extensive support of
  ``MARK`` and ``META`` item of ``rte_flow``. The newly introduced
  ``SET_TAG`` and ``SET_META`` actions do not depend on ``dv_xmeta_en``.

  There are some possible configurations, depending on parameter value:

  - 0, this is default value, defines the legacy mode, the ``MARK`` and
    ``META`` related actions and items operate only within NIC Tx and
    NIC Rx steering domains, no ``MARK`` and ``META`` information crosses
    the domain boundaries. The ``MARK`` item is 24 bits wide, the ``META``
    item is 32 bits wide and match supported on egress only.

  - 1, this engages extensive metadata mode, the ``MARK`` and ``META``
    related actions and items operate within all supported steering domains,
    including FDB, ``MARK`` and ``META`` information may cross the domain
    boundaries. The ``MARK`` item is 24 bits wide, the ``META`` item width
    depends on kernel and firmware configurations and might be 0, 16 or
    32 bits. Within NIC Tx domain ``META`` data width is 32 bits for
    compatibility, the actual width of data transferred to the FDB domain
    depends on kernel configuration and may be vary. The actual supported
    width can be retrieved in runtime by series of rte_flow_validate()
    trials.

  - 2, this engages extensive metadata mode, the ``MARK`` and ``META``
    related actions and items operate within all supported steering domains,
    including FDB, ``MARK`` and ``META`` information may cross the domain
    boundaries. The ``META`` item is 32 bits wide, the ``MARK`` item width
    depends on kernel and firmware configurations and might be 0, 16 or
    24 bits. The actual supported width can be retrieved in runtime by
    series of rte_flow_validate() trials.

  +------+-----------+-----------+-------------+-------------+
  | Mode | ``MARK``  | ``META``  | ``META`` Tx | FDB/Through |
  +======+===========+===========+=============+=============+
  | 0    | 24 bits   | 32 bits   | 32 bits     | no          |
  +------+-----------+-----------+-------------+-------------+
  | 1    | 24 bits   | vary 0-32 | 32 bits     | yes         |
  +------+-----------+-----------+-------------+-------------+
  | 2    | vary 0-32 | 32 bits   | 32 bits     | yes         |
  +------+-----------+-----------+-------------+-------------+

  If there is no E-Switch configuration the ``dv_xmeta_en`` parameter is
  ignored and the device is configured to operate in legacy mode (0).

  Disabled by default (set to 0).

  The Direct Verbs/Rules (engaged with ``dv_flow_en`` = 1) supports all
  of the extensive metadata features. The legacy Verbs supports FLAG and
  MARK metadata actions over NIC Rx steering domain only.

- ``dv_flow_en`` parameter [int]

  A nonzero value enables the DV flow steering assuming it is supported
  by the driver (RDMA Core library version is rdma-core-24.0 or higher).

  Enabled by default if supported.

- ``dv_esw_en`` parameter [int]

  A nonzero value enables E-Switch using Direct Rules.

  Enabled by default if supported.

- ``mr_ext_memseg_en`` parameter [int]

  A nonzero value enables extending memseg when registering DMA memory. If
  enabled, the number of entries in MR (Memory Region) lookup table on datapath
  is minimized and it benefits performance. On the other hand, it worsens memory
  utilization because registered memory is pinned by kernel driver. Even if a
  page in the extended chunk is freed, that doesn't become reusable until the
  entire memory is freed.

  Enabled by default.

- ``representor`` parameter [list]

  This parameter can be used to instantiate DPDK Ethernet devices from
  existing port (or VF) representors configured on the device.

  It is a standard parameter whose format is described in
  :ref:`ethernet_device_standard_device_arguments`.

  For instance, to probe port representors 0 through 2::

    representor=[0-2]

- ``max_dump_files_num`` parameter [int]

  The maximum number of files per PMD entity that may be created for debug information.
  The files will be created in /var/log directory or in current directory.

  set to 128 by default.

- ``lro_timeout_usec`` parameter [int]

  The maximum allowed duration of an LRO session, in micro-seconds.
  PMD will set the nearest value supported by HW, which is not bigger than
  the input ``lro_timeout_usec`` value.
  If this parameter is not specified, by default PMD will set
  the smallest value supported by HW.

.. _mlx5_firmware_config:

Firmware configuration
~~~~~~~~~~~~~~~~~~~~~~

Firmware features can be configured as key/value pairs.

The command to set a value is::

  mlxconfig -d <device> set <key>=<value>

The command to query a value is::

  mlxconfig -d <device> query | grep <key>

The device name for the command ``mlxconfig`` can be either the PCI address,
or the mst device name found with::

  mst status

Below are some firmware configurations listed.

- link type::

    LINK_TYPE_P1
    LINK_TYPE_P2
    value: 1=Infiniband 2=Ethernet 3=VPI(auto-sense)

- enable SR-IOV::

    SRIOV_EN=1

- maximum number of SR-IOV virtual functions::

    NUM_OF_VFS=<max>

- enable DevX (required by Direct Rules and other features)::

    UCTX_EN=1

- aggressive CQE zipping::

    CQE_COMPRESSION=1

- L3 VXLAN and VXLAN-GPE destination UDP port::

    IP_OVER_VXLAN_EN=1
    IP_OVER_VXLAN_PORT=<udp dport>

- enable IP-in-IP tunnel flow matching::

    FLEX_PARSER_PROFILE_ENABLE=0

- enable MPLS flow matching::

    FLEX_PARSER_PROFILE_ENABLE=1

- enable ICMP/ICMP6 code/type fields matching::

    FLEX_PARSER_PROFILE_ENABLE=2

- enable Geneve flow matching::

   FLEX_PARSER_PROFILE_ENABLE=0

- enable GTP flow matching::

   FLEX_PARSER_PROFILE_ENABLE=3

Prerequisites
-------------

This driver relies on external libraries and kernel drivers for resources
allocations and initialization. The following dependencies are not part of
DPDK and must be installed separately:

- **libibverbs**

  User space Verbs framework used by librte_pmd_mlx5. This library provides
  a generic interface between the kernel and low-level user space drivers
  such as libmlx5.

  It allows slow and privileged operations (context initialization, hardware
  resources allocations) to be managed by the kernel and fast operations to
  never leave user space.

- **libmlx5**

  Low-level user space driver library for Mellanox
  ConnectX-4/ConnectX-5/ConnectX-6/BlueField devices, it is automatically loaded
  by libibverbs.

  This library basically implements send/receive calls to the hardware
  queues.

- **Kernel modules**

  They provide the kernel-side Verbs API and low level device drivers that
  manage actual hardware initialization and resources sharing with user
  space processes.

  Unlike most other PMDs, these modules must remain loaded and bound to
  their devices:

  - mlx5_core: hardware driver managing Mellanox
    ConnectX-4/ConnectX-5/ConnectX-6/BlueField devices and related Ethernet kernel
    network devices.
  - mlx5_ib: InifiniBand device driver.
  - ib_uverbs: user space driver for Verbs (entry point for libibverbs).

- **Firmware update**

  Mellanox OFED/EN releases include firmware updates for
  ConnectX-4/ConnectX-5/ConnectX-6/BlueField adapters.

  Because each release provides new features, these updates must be applied to
  match the kernel modules and libraries they come with.

.. note::

   Both libraries are BSD and GPL licensed. Linux kernel modules are GPL
   licensed.

Installation
~~~~~~~~~~~~

Either RDMA Core library with a recent enough Linux kernel release
(recommended) or Mellanox OFED/EN, which provides compatibility with older
releases.

RDMA Core with Linux Kernel
^^^^^^^^^^^^^^^^^^^^^^^^^^^

- Minimal kernel version : v4.14 or the most recent 4.14-rc (see `Linux installation documentation`_)
- Minimal rdma-core version: v15+ commit 0c5f5765213a ("Merge pull request #227 from yishaih/tm")
  (see `RDMA Core installation documentation`_)
- When building for i686 use:

  - rdma-core version 18.0 or above built with 32bit support.
  - Kernel version 4.14.41 or above.

- Starting with rdma-core v21, static libraries can be built::

    cd build
    CFLAGS=-fPIC cmake -DIN_PLACE=1 -DENABLE_STATIC=1 -GNinja ..
    ninja

.. _`Linux installation documentation`: https://git.kernel.org/pub/scm/linux/kernel/git/stable/linux-stable.git/plain/Documentation/admin-guide/README.rst
.. _`RDMA Core installation documentation`: https://raw.githubusercontent.com/linux-rdma/rdma-core/master/README.md

If rdma-core libraries are built but not installed, DPDK makefile can link them,
thanks to these environment variables:

   - ``EXTRA_CFLAGS=-I/path/to/rdma-core/build/include``
   - ``EXTRA_LDFLAGS=-L/path/to/rdma-core/build/lib``
   - ``PKG_CONFIG_PATH=/path/to/rdma-core/build/lib/pkgconfig``

Mellanox OFED/EN
^^^^^^^^^^^^^^^^

- Mellanox OFED version: ** 4.5, 4.6** /
  Mellanox EN version: **4.5, 4.6**
- firmware version:

  - ConnectX-4: **12.21.1000** and above.
  - ConnectX-4 Lx: **14.21.1000** and above.
  - ConnectX-5: **16.21.1000** and above.
  - ConnectX-5 Ex: **16.21.1000** and above.
  - ConnectX-6: **20.99.5374** and above.
  - ConnectX-6 Dx: **22.27.0090** and above.
  - BlueField: **18.25.1010** and above.

While these libraries and kernel modules are available on OpenFabrics
Alliance's `website <https://www.openfabrics.org/>`__ and provided by package
managers on most distributions, this PMD requires Ethernet extensions that
may not be supported at the moment (this is a work in progress).

`Mellanox OFED
<http://www.mellanox.com/page/products_dyn?product_family=26&mtag=linux>`__ and
`Mellanox EN
<http://www.mellanox.com/page/products_dyn?product_family=27&mtag=linux>`__
include the necessary support and should be used in the meantime. For DPDK,
only libibverbs, libmlx5, mlnx-ofed-kernel packages and firmware updates are
required from that distribution.

.. note::

   Several versions of Mellanox OFED/EN are available. Installing the version
   this DPDK release was developed and tested against is strongly
   recommended. Please check the `prerequisites`_.

Supported NICs
--------------

The following Mellanox device families are supported by the same mlx5 driver:

  - ConnectX-4
  - ConnectX-4 Lx
  - ConnectX-5
  - ConnectX-5 Ex
  - ConnectX-6
  - ConnectX-6 Dx
  - BlueField

Below are detailed device names:

* Mellanox\ |reg| ConnectX\ |reg|-4 10G MCX4111A-XCAT (1x10G)
* Mellanox\ |reg| ConnectX\ |reg|-4 10G MCX412A-XCAT (2x10G)
* Mellanox\ |reg| ConnectX\ |reg|-4 25G MCX4111A-ACAT (1x25G)
* Mellanox\ |reg| ConnectX\ |reg|-4 25G MCX412A-ACAT (2x25G)
* Mellanox\ |reg| ConnectX\ |reg|-4 40G MCX413A-BCAT (1x40G)
* Mellanox\ |reg| ConnectX\ |reg|-4 40G MCX4131A-BCAT (1x40G)
* Mellanox\ |reg| ConnectX\ |reg|-4 40G MCX415A-BCAT (1x40G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX413A-GCAT (1x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX4131A-GCAT (1x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX414A-BCAT (2x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX415A-GCAT (1x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX416A-BCAT (2x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX416A-GCAT (2x50G)
* Mellanox\ |reg| ConnectX\ |reg|-4 50G MCX415A-CCAT (1x100G)
* Mellanox\ |reg| ConnectX\ |reg|-4 100G MCX416A-CCAT (2x100G)
* Mellanox\ |reg| ConnectX\ |reg|-4 Lx 10G MCX4111A-XCAT (1x10G)
* Mellanox\ |reg| ConnectX\ |reg|-4 Lx 10G MCX4121A-XCAT (2x10G)
* Mellanox\ |reg| ConnectX\ |reg|-4 Lx 25G MCX4111A-ACAT (1x25G)
* Mellanox\ |reg| ConnectX\ |reg|-4 Lx 25G MCX4121A-ACAT (2x25G)
* Mellanox\ |reg| ConnectX\ |reg|-4 Lx 40G MCX4131A-BCAT (1x40G)
* Mellanox\ |reg| ConnectX\ |reg|-5 100G MCX556A-ECAT (2x100G)
* Mellanox\ |reg| ConnectX\ |reg|-5 Ex EN 100G MCX516A-CDAT (2x100G)
* Mellanox\ |reg| ConnectX\ |reg|-6 200G MCX654106A-HCAT (2x200G)
* Mellanox\ |reg| ConnectX\ |reg|-6 Dx EN 100G MCX623106AN-CDAT (2x100G)
* Mellanox\ |reg| ConnectX\ |reg|-6 Dx EN 200G MCX623105AN-VDAT (1x200G)

Quick Start Guide on OFED/EN
----------------------------

1. Download latest Mellanox OFED/EN. For more info check the  `prerequisites`_.


2. Install the required libraries and kernel modules either by installing
   only the required set, or by installing the entire Mellanox OFED/EN::

        ./mlnxofedinstall --upstream-libs --dpdk

3. Verify the firmware is the correct one::

        ibv_devinfo

4. Verify all ports links are set to Ethernet::

        mlxconfig -d <mst device> query | grep LINK_TYPE
        LINK_TYPE_P1                        ETH(2)
        LINK_TYPE_P2                        ETH(2)

   Link types may have to be configured to Ethernet::

        mlxconfig -d <mst device> set LINK_TYPE_P1/2=1/2/3

        * LINK_TYPE_P1=<1|2|3> , 1=Infiniband 2=Ethernet 3=VPI(auto-sense)

   For hypervisors, verify SR-IOV is enabled on the NIC::

        mlxconfig -d <mst device> query | grep SRIOV_EN
        SRIOV_EN                            True(1)

   If needed, configure SR-IOV::

        mlxconfig -d <mst device> set SRIOV_EN=1 NUM_OF_VFS=16
        mlxfwreset -d <mst device> reset

5. Restart the driver::

        /etc/init.d/openibd restart

   or::

        service openibd restart

   If link type was changed, firmware must be reset as well::

        mlxfwreset -d <mst device> reset

   For hypervisors, after reset write the sysfs number of virtual functions
   needed for the PF.

   To dynamically instantiate a given number of virtual functions (VFs)::

        echo [num_vfs] > /sys/class/infiniband/mlx5_0/device/sriov_numvfs

6. Compile DPDK and you are ready to go. See instructions on
   :ref:`Development Kit Build System <Development_Kit_Build_System>`

Enable switchdev mode
---------------------

Switchdev mode is a mode in E-Switch, that binds between representor and VF.
Representor is a port in DPDK that is connected to a VF in such a way
that assuming there are no offload flows, each packet that is sent from the VF
will be received by the corresponding representor. While each packet that is
sent to a representor will be received by the VF.
This is very useful in case of SRIOV mode, where the first packet that is sent
by the VF will be received by the DPDK application which will decide if this
flow should be offloaded to the E-Switch. After offloading the flow packet
that the VF that are matching the flow will not be received any more by
the DPDK application.

1. Enable SRIOV mode::

        mlxconfig -d <mst device> set SRIOV_EN=true

2. Configure the max number of VFs::

        mlxconfig -d <mst device> set NUM_OF_VFS=<num of vfs>

3. Reset the FW::

        mlxfwreset -d <mst device> reset

3. Configure the actual number of VFs::

        echo <num of vfs > /sys/class/net/<net device>/device/sriov_numvfs

4. Unbind the device (can be rebind after the switchdev mode)::

        echo -n "<device pci address" > /sys/bus/pci/drivers/mlx5_core/unbind

5. Enbale switchdev mode::

        echo switchdev > /sys/class/net/<net device>/compat/devlink/mode

Performance tuning
------------------

1. Configure aggressive CQE Zipping for maximum performance::

        mlxconfig -d <mst device> s CQE_COMPRESSION=1

  To set it back to the default CQE Zipping mode use::

        mlxconfig -d <mst device> s CQE_COMPRESSION=0

2. In case of virtualization:

   - Make sure that hypervisor kernel is 3.16 or newer.
   - Configure boot with ``iommu=pt``.
   - Use 1G huge pages.
   - Make sure to allocate a VM on huge pages.
   - Make sure to set CPU pinning.

3. Use the CPU near local NUMA node to which the PCIe adapter is connected,
   for better performance. For VMs, verify that the right CPU
   and NUMA node are pinned according to the above. Run::

        lstopo-no-graphics

   to identify the NUMA node to which the PCIe adapter is connected.

4. If more than one adapter is used, and root complex capabilities allow
   to put both adapters on the same NUMA node without PCI bandwidth degradation,
   it is recommended to locate both adapters on the same NUMA node.
   This in order to forward packets from one to the other without
   NUMA performance penalty.

5. Disable pause frames::

        ethtool -A <netdev> rx off tx off

6. Verify IO non-posted prefetch is disabled by default. This can be checked
   via the BIOS configuration. Please contact you server provider for more
   information about the settings.

.. note::

        On some machines, depends on the machine integrator, it is beneficial
        to set the PCI max read request parameter to 1K. This can be
        done in the following way:

        To query the read request size use::

                setpci -s <NIC PCI address> 68.w

        If the output is different than 3XXX, set it by::

                setpci -s <NIC PCI address> 68.w=3XXX

        The XXX can be different on different systems. Make sure to configure
        according to the setpci output.

7. To minimize overhead of searching Memory Regions:

   - '--socket-mem' is recommended to pin memory by predictable amount.
   - Configure per-lcore cache when creating Mempools for packet buffer.
   - Refrain from dynamically allocating/freeing memory in run-time.

.. _mlx5_offloads_support:

Supported hardware offloads
---------------------------

.. table:: Minimal SW/HW versions for queue offloads

   ============== ===== ===== ========= ===== ========== ==========
   Offload        DPDK  Linux rdma-core OFED   firmware   hardware
   ============== ===== ===== ========= ===== ========== ==========
   common base    17.11  4.14    16     4.2-1 12.21.1000 ConnectX-4
   checksums      17.11  4.14    16     4.2-1 12.21.1000 ConnectX-4
   Rx timestamp   17.11  4.14    16     4.2-1 12.21.1000 ConnectX-4
   TSO            17.11  4.14    16     4.2-1 12.21.1000 ConnectX-4
   LRO            19.08  N/A     N/A    4.6-4 16.25.6406 ConnectX-5
   ============== ===== ===== ========= ===== ========== ==========

.. table:: Minimal SW/HW versions for rte_flow offloads

   +-----------------------+-----------------+-----------------+
   | Offload               | with E-Switch   | with NIC        |
   +=======================+=================+=================+
   | Count                 | | DPDK 19.05    | | DPDK 19.02    |
   |                       | | OFED 4.6      | | OFED 4.6      |
   |                       | | rdma-core 24  | | rdma-core 23  |
   |                       | | ConnectX-5    | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Drop                  | | DPDK 19.05    | | DPDK 18.11    |
   |                       | | OFED 4.6      | | OFED 4.5      |
   |                       | | rdma-core 24  | | rdma-core 23  |
   |                       | | ConnectX-5    | | ConnectX-4    |
   +-----------------------+-----------------+-----------------+
   | Queue / RSS           | |               | | DPDK 18.11    |
   |                       | |     N/A       | | OFED 4.5      |
   |                       | |               | | rdma-core 23  |
   |                       | |               | | ConnectX-4    |
   +-----------------------+-----------------+-----------------+
   | Encapsulation         | | DPDK 19.05    | | DPDK 19.02    |
   | (VXLAN / NVGRE / RAW) | | OFED 4.7-1    | | OFED 4.6      |
   |                       | | rdma-core 24  | | rdma-core 23  |
   |                       | | ConnectX-5    | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Encapsulation         | | DPDK 19.11    | | DPDK 19.11    |
   | GENEVE                | | OFED 4.7-3    | | OFED 4.7-3    |
   |                       | | rdma-core 27  | | rdma-core 27  |
   |                       | | ConnectX-5    | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | | Header rewrite      | | DPDK 19.05    | | DPDK 19.02    |
   | | (set_ipv4_src /     | | OFED 4.7-1    | | OFED 4.7-1    |
   | | set_ipv4_dst /      | | rdma-core 24  | | rdma-core 24  |
   | | set_ipv6_src /      | | ConnectX-5    | | ConnectX-5    |
   | | set_ipv6_dst /      | |               | |               |
   | | set_tp_src /        | |               | |               |
   | | set_tp_dst /        | |               | |               |
   | | dec_ttl /           | |               | |               |
   | | set_ttl /           | |               | |               |
   | | set_mac_src /       | |               | |               |
   | | set_mac_dst)        | |               | |               |
   +-----------------------+-----------------+-----------------+
   | | Header rewrite      | | DPDK 20.02    | | DPDK 20.02    |
   | | (set_dscp)          | | OFED 5.0      | | OFED 5.0      |
   | |                     | | rdma-core 24  | | rdma-core 24  |
   | |                     | | ConnectX-5    | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Jump                  | | DPDK 19.05    | | DPDK 19.02    |
   |                       | | OFED 4.7-1    | | OFED 4.7-1    |
   |                       | | rdma-core 24  | | N/A           |
   |                       | | ConnectX-5    | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Mark / Flag           | | DPDK 19.05    | | DPDK 18.11    |
   |                       | | OFED 4.6      | | OFED 4.5      |
   |                       | | rdma-core 24  | | rdma-core 23  |
   |                       | | ConnectX-5    | | ConnectX-4    |
   +-----------------------+-----------------+-----------------+
   | Port ID               | | DPDK 19.05    |     | N/A       |
   |                       | | OFED 4.7-1    |     | N/A       |
   |                       | | rdma-core 24  |     | N/A       |
   |                       | | ConnectX-5    |     | N/A       |
   +-----------------------+-----------------+-----------------+
   | | VLAN                | | DPDK 19.11    | | DPDK 19.11    |
   | | (of_pop_vlan /      | | OFED 4.7-1    | | OFED 4.7-1    |
   | | of_push_vlan /      | | ConnectX-5    | | ConnectX-5    |
   | | of_set_vlan_pcp /   | |               | |               |
   | | of_set_vlan_vid)    | |               | |               |
   +-----------------------+-----------------+-----------------+
   | Hairpin               | |               | | DPDK 19.11    |
   |                       | |     N/A       | | OFED 4.7-3    |
   |                       | |               | | rdma-core 26  |
   |                       | |               | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Meta data             | |  DPDK 19.11   | | DPDK 19.11    |
   |                       | |  OFED 4.7-3   | | OFED 4.7-3    |
   |                       | |  rdma-core 26 | | rdma-core 26  |
   |                       | |  ConnectX-5   | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+
   | Metering              | |  DPDK 19.11   | | DPDK 19.11    |
   |                       | |  OFED 4.7-3   | | OFED 4.7-3    |
   |                       | |  rdma-core 26 | | rdma-core 26  |
   |                       | |  ConnectX-5   | | ConnectX-5    |
   +-----------------------+-----------------+-----------------+

Notes for testpmd
-----------------

Compared to librte_pmd_mlx4 that implements a single RSS configuration per
port, librte_pmd_mlx5 supports per-protocol RSS configuration.

Since ``testpmd`` defaults to IP RSS mode and there is currently no
command-line parameter to enable additional protocols (UDP and TCP as well
as IP), the following commands must be entered from its CLI to get the same
behavior as librte_pmd_mlx4::

   > port stop all
   > port config all rss all
   > port start all

Usage example
-------------

This section demonstrates how to launch **testpmd** with Mellanox
ConnectX-4/ConnectX-5/ConnectX-6/BlueField devices managed by librte_pmd_mlx5.

#. Load the kernel modules::

      modprobe -a ib_uverbs mlx5_core mlx5_ib

   Alternatively if MLNX_OFED/MLNX_EN is fully installed, the following script
   can be run::

      /etc/init.d/openibd restart

   .. note::

      User space I/O kernel modules (uio and igb_uio) are not used and do
      not have to be loaded.

#. Make sure Ethernet interfaces are in working order and linked to kernel
   verbs. Related sysfs entries should be present::

      ls -d /sys/class/net/*/device/infiniband_verbs/uverbs* | cut -d / -f 5

   Example output::

      eth30
      eth31
      eth32
      eth33

#. Optionally, retrieve their PCI bus addresses for whitelisting::

      {
          for intf in eth2 eth3 eth4 eth5;
          do
              (cd "/sys/class/net/${intf}/device/" && pwd -P);
          done;
      } |
      sed -n 's,.*/\(.*\),-w \1,p'

   Example output::

      -w 0000:05:00.1
      -w 0000:06:00.0
      -w 0000:06:00.1
      -w 0000:05:00.0

#. Request huge pages::

      echo 1024 > /sys/kernel/mm/hugepages/hugepages-2048kB/nr_hugepages/nr_hugepages

#. Start testpmd with basic parameters::

      testpmd -l 8-15 -n 4 -w 05:00.0 -w 05:00.1 -w 06:00.0 -w 06:00.1 -- --rxq=2 --txq=2 -i

   Example output::

      [...]
      EAL: PCI device 0000:05:00.0 on NUMA socket 0
      EAL:   probe driver: 15b3:1013 librte_pmd_mlx5
      PMD: librte_pmd_mlx5: PCI information matches, using device "mlx5_0" (VF: false)
      PMD: librte_pmd_mlx5: 1 port(s) detected
      PMD: librte_pmd_mlx5: port 1 MAC address is e4:1d:2d:e7:0c:fe
      EAL: PCI device 0000:05:00.1 on NUMA socket 0
      EAL:   probe driver: 15b3:1013 librte_pmd_mlx5
      PMD: librte_pmd_mlx5: PCI information matches, using device "mlx5_1" (VF: false)
      PMD: librte_pmd_mlx5: 1 port(s) detected
      PMD: librte_pmd_mlx5: port 1 MAC address is e4:1d:2d:e7:0c:ff
      EAL: PCI device 0000:06:00.0 on NUMA socket 0
      EAL:   probe driver: 15b3:1013 librte_pmd_mlx5
      PMD: librte_pmd_mlx5: PCI information matches, using device "mlx5_2" (VF: false)
      PMD: librte_pmd_mlx5: 1 port(s) detected
      PMD: librte_pmd_mlx5: port 1 MAC address is e4:1d:2d:e7:0c:fa
      EAL: PCI device 0000:06:00.1 on NUMA socket 0
      EAL:   probe driver: 15b3:1013 librte_pmd_mlx5
      PMD: librte_pmd_mlx5: PCI information matches, using device "mlx5_3" (VF: false)
      PMD: librte_pmd_mlx5: 1 port(s) detected
      PMD: librte_pmd_mlx5: port 1 MAC address is e4:1d:2d:e7:0c:fb
      Interactive-mode selected
      Configuring Port 0 (socket 0)
      PMD: librte_pmd_mlx5: 0x8cba80: TX queues number update: 0 -> 2
      PMD: librte_pmd_mlx5: 0x8cba80: RX queues number update: 0 -> 2
      Port 0: E4:1D:2D:E7:0C:FE
      Configuring Port 1 (socket 0)
      PMD: librte_pmd_mlx5: 0x8ccac8: TX queues number update: 0 -> 2
      PMD: librte_pmd_mlx5: 0x8ccac8: RX queues number update: 0 -> 2
      Port 1: E4:1D:2D:E7:0C:FF
      Configuring Port 2 (socket 0)
      PMD: librte_pmd_mlx5: 0x8cdb10: TX queues number update: 0 -> 2
      PMD: librte_pmd_mlx5: 0x8cdb10: RX queues number update: 0 -> 2
      Port 2: E4:1D:2D:E7:0C:FA
      Configuring Port 3 (socket 0)
      PMD: librte_pmd_mlx5: 0x8ceb58: TX queues number update: 0 -> 2
      PMD: librte_pmd_mlx5: 0x8ceb58: RX queues number update: 0 -> 2
      Port 3: E4:1D:2D:E7:0C:FB
      Checking link statuses...
      Port 0 Link Up - speed 40000 Mbps - full-duplex
      Port 1 Link Up - speed 40000 Mbps - full-duplex
      Port 2 Link Up - speed 10000 Mbps - full-duplex
      Port 3 Link Up - speed 10000 Mbps - full-duplex
      Done
      testpmd>

How to dump flows
-----------------

This section demonstrates how to dump flows. Currently, it's possible to dump
all flows with assistance of external tools.

#. 2 ways to get flow raw file:

   - Using testpmd CLI:

   .. code-block:: console

       testpmd> flow dump <port> <output_file>

   - call rte_flow_dev_dump api:

   .. code-block:: console

       rte_flow_dev_dump(port, file, NULL);

#. Dump human-readable flows from raw file:

   Get flow parsing tool from: https://github.com/Mellanox/mlx_steering_dump

   .. code-block:: console

       mlx_steering_dump.py -f <output_file>