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Documentation: networking: document phy_link_topology
The newly introduced phy_link_topology tracks all ethernet PHYs that are attached to a netdevice. Document the base principle, internal and external APIs. As the phy_link_topology is expected to be extended, this documentation will hold any further improvements and additions made relative to topology handling. Signed-off-by: Maxime Chevallier <maxime.chevallier@bootlin.com> Reviewed-by: Andrew Lunn <andrew@lunn.ch> Reviewed-by: Christophe Leroy <christophe.leroy@csgroup.eu> Tested-by: Christophe Leroy <christophe.leroy@csgroup.eu> Signed-off-by: David S. Miller <davem@davemloft.net>
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@ -2198,10 +2198,13 @@ Retrieve information about a given Ethernet PHY sitting on the link. The DO
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operation returns all available information about dev->phydev. User can also
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specify a PHY_INDEX, in which case the DO request returns information about that
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specific PHY.
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As there can be more than one PHY, the DUMP operation can be used to list the PHYs
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present on a given interface, by passing an interface index or name in
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the dump request.
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For more information, refer to :ref:`phy_link_topology`
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Request contents:
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==================================== ====== ==========================
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@ -91,6 +91,7 @@ Contents:
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operstates
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packet_mmap
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phonet
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phy-link-topology
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pktgen
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plip
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ppp_generic
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121
Documentation/networking/phy-link-topology.rst
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121
Documentation/networking/phy-link-topology.rst
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.. SPDX-License-Identifier: GPL-2.0
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.. _phy_link_topology:
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=================
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PHY link topology
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=================
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Overview
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========
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The PHY link topology representation in the networking stack aims at representing
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the hardware layout for any given Ethernet link.
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An Ethernet interface from userspace's point of view is nothing but a
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:c:type:`struct net_device <net_device>`, which exposes configuration options
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through the legacy ioctls and the ethtool netlink commands. The base assumption
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when designing these configuration APIs were that the link looks something like ::
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+-----------------------+ +----------+ +--------------+
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| Ethernet Controller / | | Ethernet | | Connector / |
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| MAC | ------ | PHY | ---- | Port | ---... to LP
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+-----------------------+ +----------+ +--------------+
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struct net_device struct phy_device
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Commands that needs to configure the PHY will go through the net_device.phydev
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field to reach the PHY and perform the relevant configuration.
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This assumption falls apart in more complex topologies that can arise when,
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for example, using SFP transceivers (although that's not the only specific case).
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Here, we have 2 basic scenarios. Either the MAC is able to output a serialized
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interface, that can directly be fed to an SFP cage, such as SGMII, 1000BaseX,
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10GBaseR, etc.
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The link topology then looks like this (when an SFP module is inserted) ::
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+-----+ SGMII +------------+
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| MAC | ------- | SFP Module |
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+-----+ +------------+
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Knowing that some modules embed a PHY, the actual link is more like ::
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+-----+ SGMII +--------------+
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| MAC | -------- | PHY (on SFP) |
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+-----+ +--------------+
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In this case, the SFP PHY is handled by phylib, and registered by phylink through
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its SFP upstream ops.
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Now some Ethernet controllers aren't able to output a serialized interface, so
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we can't directly connect them to an SFP cage. However, some PHYs can be used
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as media-converters, to translate the non-serialized MAC MII interface to a
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serialized MII interface fed to the SFP ::
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+-----+ RGMII +-----------------------+ SGMII +--------------+
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| MAC | ------- | PHY (media converter) | ------- | PHY (on SFP) |
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+-----+ +-----------------------+ +--------------+
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This is where the model of having a single net_device.phydev pointer shows its
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limitations, as we now have 2 PHYs on the link.
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The phy_link topology framework aims at providing a way to keep track of every
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PHY on the link, for use by both kernel drivers and subsystems, but also to
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report the topology to userspace, allowing to target individual PHYs in configuration
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commands.
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API
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===
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The :c:type:`struct phy_link_topology <phy_link_topology>` is a per-netdevice
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resource, that gets initialized at netdevice creation. Once it's initialized,
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it is then possible to register PHYs to the topology through :
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:c:func:`phy_link_topo_add_phy`
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Besides registering the PHY to the topology, this call will also assign a unique
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index to the PHY, which can then be reported to userspace to refer to this PHY
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(akin to the ifindex). This index is a u32, ranging from 1 to U32_MAX. The value
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0 is reserved to indicate the PHY doesn't belong to any topology yet.
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The PHY can then be removed from the topology through
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:c:func:`phy_link_topo_del_phy`
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These function are already hooked into the phylib subsystem, so all PHYs that
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are linked to a net_device through :c:func:`phy_attach_direct` will automatically
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join the netdev's topology.
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PHYs that are on a SFP module will also be automatically registered IF the SFP
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upstream is phylink (so, no media-converter).
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PHY drivers that can be used as SFP upstream need to call :c:func:`phy_sfp_attach_phy`
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and :c:func:`phy_sfp_detach_phy`, which can be used as a
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.attach_phy / .detach_phy implementation for the
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:c:type:`struct sfp_upstream_ops <sfp_upstream_ops>`.
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UAPI
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====
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There exist a set of netlink commands to query the link topology from userspace,
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see ``Documentation/networking/ethtool-netlink.rst``.
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The whole point of having a topology representation is to assign the phyindex
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field in :c:type:`struct phy_device <phy_device>`. This index is reported to
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userspace using the ``ETHTOOL_MSG_PHY_GET`` ethtnl command. Performing a DUMP operation
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will result in all PHYs from all net_device being listed. The DUMP command
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accepts either a ``ETHTOOL_A_HEADER_DEV_INDEX`` or ``ETHTOOL_A_HEADER_DEV_NAME``
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to be passed in the request to filter the DUMP to a single net_device.
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The retrieved index can then be passed as a request parameter using the
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``ETHTOOL_A_HEADER_PHY_INDEX`` field in the following ethnl commands :
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* ``ETHTOOL_MSG_STRSET_GET`` to get the stats string set from a given PHY
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* ``ETHTOOL_MSG_CABLE_TEST_ACT`` and ``ETHTOOL_MSG_CABLE_TEST_ACT``, to perform
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cable testing on a given PHY on the link (most likely the outermost PHY)
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* ``ETHTOOL_MSG_PSE_SET`` and ``ETHTOOL_MSG_PSE_GET`` for PHY-controlled PoE and PSE settings
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* ``ETHTOOL_MSG_PLCA_GET_CFG``, ``ETHTOOL_MSG_PLCA_SET_CFG`` and ``ETHTOOL_MSG_PLCA_GET_STATUS``
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to set the PLCA (Physical Layer Collision Avoidance) parameters
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Note that the PHY index can be passed to other requests, which will silently
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ignore it if present and irrelevant.
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