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Provide devlink documentation for three eswitch attributes: mode, inline-mode, and encap-mode. Signed-off-by: William Tu <witu@nvidia.com> Reviewed-by: Jakub Kicinski <kuba@kernel.org> Link: https://lore.kernel.org/r/20240325181228.6244-1-witu@nvidia.com Signed-off-by: Jakub Kicinski <kuba@kernel.org>
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ReStructuredText
263 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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.. _representors:
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=============================
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Network Function Representors
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=============================
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This document describes the semantics and usage of representor netdevices, as
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used to control internal switching on SmartNICs. For the closely-related port
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representors on physical (multi-port) switches, see
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:ref:`Documentation/networking/switchdev.rst <switchdev>`.
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Motivation
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----------
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Since the mid-2010s, network cards have started offering more complex
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virtualisation capabilities than the legacy SR-IOV approach (with its simple
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MAC/VLAN-based switching model) can support. This led to a desire to offload
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software-defined networks (such as OpenVSwitch) to these NICs to specify the
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network connectivity of each function. The resulting designs are variously
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called SmartNICs or DPUs.
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Network function representors bring the standard Linux networking stack to
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virtual switches and IOV devices. Just as each physical port of a Linux-
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controlled switch has a separate netdev, so does each virtual port of a virtual
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switch.
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When the system boots, and before any offload is configured, all packets from
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the virtual functions appear in the networking stack of the PF via the
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representors. The PF can thus always communicate freely with the virtual
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functions.
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The PF can configure standard Linux forwarding between representors, the uplink
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or any other netdev (routing, bridging, TC classifiers).
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Thus, a representor is both a control plane object (representing the function in
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administrative commands) and a data plane object (one end of a virtual pipe).
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As a virtual link endpoint, the representor can be configured like any other
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netdevice; in some cases (e.g. link state) the representee will follow the
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representor's configuration, while in others there are separate APIs to
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configure the representee.
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Definitions
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-----------
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This document uses the term "switchdev function" to refer to the PCIe function
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which has administrative control over the virtual switch on the device.
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Typically, this will be a PF, but conceivably a NIC could be configured to grant
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these administrative privileges instead to a VF or SF (subfunction).
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Depending on NIC design, a multi-port NIC might have a single switchdev function
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for the whole device or might have a separate virtual switch, and hence
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switchdev function, for each physical network port.
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If the NIC supports nested switching, there might be separate switchdev
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functions for each nested switch, in which case each switchdev function should
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only create representors for the ports on the (sub-)switch it directly
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administers.
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A "representee" is the object that a representor represents. So for example in
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the case of a VF representor, the representee is the corresponding VF.
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What does a representor do?
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---------------------------
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A representor has three main roles.
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1. It is used to configure the network connection the representee sees, e.g.
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link up/down, MTU, etc. For instance, bringing the representor
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administratively UP should cause the representee to see a link up / carrier
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on event.
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2. It provides the slow path for traffic which does not hit any offloaded
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fast-path rules in the virtual switch. Packets transmitted on the
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representor netdevice should be delivered to the representee; packets
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transmitted by the representee which fail to match any switching rule should
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be received on the representor netdevice. (That is, there is a virtual pipe
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connecting the representor to the representee, similar in concept to a veth
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pair.)
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This allows software switch implementations (such as OpenVSwitch or a Linux
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bridge) to forward packets between representees and the rest of the network.
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3. It acts as a handle by which switching rules (such as TC filters) can refer
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to the representee, allowing these rules to be offloaded.
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The combination of 2) and 3) means that the behaviour (apart from performance)
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should be the same whether a TC filter is offloaded or not. E.g. a TC rule
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on a VF representor applies in software to packets received on that representor
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netdevice, while in hardware offload it would apply to packets transmitted by
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the representee VF. Conversely, a mirred egress redirect to a VF representor
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corresponds in hardware to delivery directly to the representee VF.
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What functions should have a representor?
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-----------------------------------------
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Essentially, for each virtual port on the device's internal switch, there
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should be a representor.
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Some vendors have chosen to omit representors for the uplink and the physical
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network port, which can simplify usage (the uplink netdev becomes in effect the
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physical port's representor) but does not generalise to devices with multiple
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ports or uplinks.
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Thus, the following should all have representors:
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- VFs belonging to the switchdev function.
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- Other PFs on the local PCIe controller, and any VFs belonging to them.
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- PFs and VFs on external PCIe controllers on the device (e.g. for any embedded
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System-on-Chip within the SmartNIC).
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- PFs and VFs with other personalities, including network block devices (such
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as a vDPA virtio-blk PF backed by remote/distributed storage), if (and only
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if) their network access is implemented through a virtual switch port. [#]_
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Note that such functions can require a representor despite the representee
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not having a netdev.
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- Subfunctions (SFs) belonging to any of the above PFs or VFs, if they have
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their own port on the switch (as opposed to using their parent PF's port).
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- Any accelerators or plugins on the device whose interface to the network is
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through a virtual switch port, even if they do not have a corresponding PCIe
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PF or VF.
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This allows the entire switching behaviour of the NIC to be controlled through
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representor TC rules.
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It is a common misunderstanding to conflate virtual ports with PCIe virtual
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functions or their netdevs. While in simple cases there will be a 1:1
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correspondence between VF netdevices and VF representors, more advanced device
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configurations may not follow this.
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A PCIe function which does not have network access through the internal switch
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(not even indirectly through the hardware implementation of whatever services
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the function provides) should *not* have a representor (even if it has a
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netdev).
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Such a function has no switch virtual port for the representor to configure or
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to be the other end of the virtual pipe.
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The representor represents the virtual port, not the PCIe function nor the 'end
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user' netdevice.
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.. [#] The concept here is that a hardware IP stack in the device performs the
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translation between block DMA requests and network packets, so that only
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network packets pass through the virtual port onto the switch. The network
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access that the IP stack "sees" would then be configurable through tc rules;
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e.g. its traffic might all be wrapped in a specific VLAN or VxLAN. However,
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any needed configuration of the block device *qua* block device, not being a
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networking entity, would not be appropriate for the representor and would
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thus use some other channel such as devlink.
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Contrast this with the case of a virtio-blk implementation which forwards the
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DMA requests unchanged to another PF whose driver then initiates and
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terminates IP traffic in software; in that case the DMA traffic would *not*
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run over the virtual switch and the virtio-blk PF should thus *not* have a
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representor.
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How are representors created?
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-----------------------------
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The driver instance attached to the switchdev function should, for each virtual
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port on the switch, create a pure-software netdevice which has some form of
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in-kernel reference to the switchdev function's own netdevice or driver private
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data (``netdev_priv()``).
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This may be by enumerating ports at probe time, reacting dynamically to the
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creation and destruction of ports at run time, or a combination of the two.
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The operations of the representor netdevice will generally involve acting
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through the switchdev function. For example, ``ndo_start_xmit()`` might send
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the packet through a hardware TX queue attached to the switchdev function, with
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either packet metadata or queue configuration marking it for delivery to the
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representee.
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How are representors identified?
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--------------------------------
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The representor netdevice should *not* directly refer to a PCIe device (e.g.
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through ``net_dev->dev.parent`` / ``SET_NETDEV_DEV()``), either of the
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representee or of the switchdev function.
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Instead, the driver should use the ``SET_NETDEV_DEVLINK_PORT`` macro to
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assign a devlink port instance to the netdevice before registering the
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netdevice; the kernel uses the devlink port to provide the ``phys_switch_id``
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and ``phys_port_name`` sysfs nodes.
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(Some legacy drivers implement ``ndo_get_port_parent_id()`` and
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``ndo_get_phys_port_name()`` directly, but this is deprecated.) See
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:ref:`Documentation/networking/devlink/devlink-port.rst <devlink_port>` for the
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details of this API.
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It is expected that userland will use this information (e.g. through udev rules)
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to construct an appropriately informative name or alias for the netdevice. For
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instance if the switchdev function is ``eth4`` then a representor with a
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``phys_port_name`` of ``p0pf1vf2`` might be renamed ``eth4pf1vf2rep``.
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There are as yet no established conventions for naming representors which do not
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correspond to PCIe functions (e.g. accelerators and plugins).
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How do representors interact with TC rules?
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-------------------------------------------
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Any TC rule on a representor applies (in software TC) to packets received by
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that representor netdevice. Thus, if the delivery part of the rule corresponds
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to another port on the virtual switch, the driver may choose to offload it to
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hardware, applying it to packets transmitted by the representee.
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Similarly, since a TC mirred egress action targeting the representor would (in
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software) send the packet through the representor (and thus indirectly deliver
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it to the representee), hardware offload should interpret this as delivery to
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the representee.
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As a simple example, if ``PORT_DEV`` is the physical port representor and
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``REP_DEV`` is a VF representor, the following rules::
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tc filter add dev $REP_DEV parent ffff: protocol ipv4 flower \
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action mirred egress redirect dev $PORT_DEV
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tc filter add dev $PORT_DEV parent ffff: protocol ipv4 flower skip_sw \
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action mirred egress mirror dev $REP_DEV
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would mean that all IPv4 packets from the VF are sent out the physical port, and
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all IPv4 packets received on the physical port are delivered to the VF in
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addition to ``PORT_DEV``. (Note that without ``skip_sw`` on the second rule,
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the VF would get two copies, as the packet reception on ``PORT_DEV`` would
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trigger the TC rule again and mirror the packet to ``REP_DEV``.)
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On devices without separate port and uplink representors, ``PORT_DEV`` would
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instead be the switchdev function's own uplink netdevice.
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Of course the rules can (if supported by the NIC) include packet-modifying
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actions (e.g. VLAN push/pop), which should be performed by the virtual switch.
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Tunnel encapsulation and decapsulation are rather more complicated, as they
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involve a third netdevice (a tunnel netdev operating in metadata mode, such as
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a VxLAN device created with ``ip link add vxlan0 type vxlan external``) and
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require an IP address to be bound to the underlay device (e.g. switchdev
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function uplink netdev or port representor). TC rules such as::
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tc filter add dev $REP_DEV parent ffff: flower \
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action tunnel_key set id $VNI src_ip $LOCAL_IP dst_ip $REMOTE_IP \
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dst_port 4789 \
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action mirred egress redirect dev vxlan0
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tc filter add dev vxlan0 parent ffff: flower enc_src_ip $REMOTE_IP \
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enc_dst_ip $LOCAL_IP enc_key_id $VNI enc_dst_port 4789 \
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action tunnel_key unset action mirred egress redirect dev $REP_DEV
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where ``LOCAL_IP`` is an IP address bound to ``PORT_DEV``, and ``REMOTE_IP`` is
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another IP address on the same subnet, mean that packets sent by the VF should
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be VxLAN encapsulated and sent out the physical port (the driver has to deduce
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this by a route lookup of ``LOCAL_IP`` leading to ``PORT_DEV``, and also
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perform an ARP/neighbour table lookup to find the MAC addresses to use in the
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outer Ethernet frame), while UDP packets received on the physical port with UDP
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port 4789 should be parsed as VxLAN and, if their VSID matches ``$VNI``,
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decapsulated and forwarded to the VF.
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If this all seems complicated, just remember the 'golden rule' of TC offload:
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the hardware should ensure the same final results as if the packets were
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processed through the slow path, traversed software TC (except ignoring any
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``skip_hw`` rules and applying any ``skip_sw`` rules) and were transmitted or
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received through the representor netdevices.
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Configuring the representee's MAC
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---------------------------------
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The representee's link state is controlled through the representor. Setting the
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representor administratively UP or DOWN should cause carrier ON or OFF at the
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representee.
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Setting an MTU on the representor should cause that same MTU to be reported to
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the representee.
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(On hardware that allows configuring separate and distinct MTU and MRU values,
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the representor MTU should correspond to the representee's MRU and vice-versa.)
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Currently there is no way to use the representor to set the station permanent
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MAC address of the representee; other methods available to do this include:
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- legacy SR-IOV (``ip link set DEVICE vf NUM mac LLADDR``)
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- devlink port function (see **devlink-port(8)** and
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:ref:`Documentation/networking/devlink/devlink-port.rst <devlink_port>`)
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