Based on kernel version 6.12.4
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1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 105 106 107 108 109 110 111 112 113 114 115 116 117 118 119 120 121 | .. SPDX-License-Identifier: GPL-2.0 .. _phy_link_topology: ================= PHY link topology ================= Overview ======== The PHY link topology representation in the networking stack aims at representing the hardware layout for any given Ethernet link. An Ethernet interface from userspace's point of view is nothing but a :c:type:`struct net_device <net_device>`, which exposes configuration options through the legacy ioctls and the ethtool netlink commands. The base assumption when designing these configuration APIs were that the link looks something like :: +-----------------------+ +----------+ +--------------+ | Ethernet Controller / | | Ethernet | | Connector / | | MAC | ------ | PHY | ---- | Port | ---... to LP +-----------------------+ +----------+ +--------------+ struct net_device struct phy_device Commands that needs to configure the PHY will go through the net_device.phydev field to reach the PHY and perform the relevant configuration. This assumption falls apart in more complex topologies that can arise when, for example, using SFP transceivers (although that's not the only specific case). Here, we have 2 basic scenarios. Either the MAC is able to output a serialized interface, that can directly be fed to an SFP cage, such as SGMII, 1000BaseX, 10GBaseR, etc. The link topology then looks like this (when an SFP module is inserted) :: +-----+ SGMII +------------+ | MAC | ------- | SFP Module | +-----+ +------------+ Knowing that some modules embed a PHY, the actual link is more like :: +-----+ SGMII +--------------+ | MAC | -------- | PHY (on SFP) | +-----+ +--------------+ In this case, the SFP PHY is handled by phylib, and registered by phylink through its SFP upstream ops. Now some Ethernet controllers aren't able to output a serialized interface, so we can't directly connect them to an SFP cage. However, some PHYs can be used as media-converters, to translate the non-serialized MAC MII interface to a serialized MII interface fed to the SFP :: +-----+ RGMII +-----------------------+ SGMII +--------------+ | MAC | ------- | PHY (media converter) | ------- | PHY (on SFP) | +-----+ +-----------------------+ +--------------+ This is where the model of having a single net_device.phydev pointer shows its limitations, as we now have 2 PHYs on the link. The phy_link topology framework aims at providing a way to keep track of every PHY on the link, for use by both kernel drivers and subsystems, but also to report the topology to userspace, allowing to target individual PHYs in configuration commands. API === The :c:type:`struct phy_link_topology <phy_link_topology>` is a per-netdevice resource, that gets initialized at netdevice creation. Once it's initialized, it is then possible to register PHYs to the topology through : :c:func:`phy_link_topo_add_phy` Besides registering the PHY to the topology, this call will also assign a unique index to the PHY, which can then be reported to userspace to refer to this PHY (akin to the ifindex). This index is a u32, ranging from 1 to U32_MAX. The value 0 is reserved to indicate the PHY doesn't belong to any topology yet. The PHY can then be removed from the topology through :c:func:`phy_link_topo_del_phy` These function are already hooked into the phylib subsystem, so all PHYs that are linked to a net_device through :c:func:`phy_attach_direct` will automatically join the netdev's topology. PHYs that are on a SFP module will also be automatically registered IF the SFP upstream is phylink (so, no media-converter). PHY drivers that can be used as SFP upstream need to call :c:func:`phy_sfp_attach_phy` and :c:func:`phy_sfp_detach_phy`, which can be used as a .attach_phy / .detach_phy implementation for the :c:type:`struct sfp_upstream_ops <sfp_upstream_ops>`. UAPI ==== There exist a set of netlink commands to query the link topology from userspace, see ``Documentation/networking/ethtool-netlink.rst``. The whole point of having a topology representation is to assign the phyindex field in :c:type:`struct phy_device <phy_device>`. This index is reported to userspace using the ``ETHTOOL_MSG_PHY_GET`` ethtnl command. Performing a DUMP operation will result in all PHYs from all net_device being listed. The DUMP command accepts either a ``ETHTOOL_A_HEADER_DEV_INDEX`` or ``ETHTOOL_A_HEADER_DEV_NAME`` to be passed in the request to filter the DUMP to a single net_device. The retrieved index can then be passed as a request parameter using the ``ETHTOOL_A_HEADER_PHY_INDEX`` field in the following ethnl commands : * ``ETHTOOL_MSG_STRSET_GET`` to get the stats string set from a given PHY * ``ETHTOOL_MSG_CABLE_TEST_ACT`` and ``ETHTOOL_MSG_CABLE_TEST_ACT``, to perform cable testing on a given PHY on the link (most likely the outermost PHY) * ``ETHTOOL_MSG_PSE_SET`` and ``ETHTOOL_MSG_PSE_GET`` for PHY-controlled PoE and PSE settings * ``ETHTOOL_MSG_PLCA_GET_CFG``, ``ETHTOOL_MSG_PLCA_SET_CFG`` and ``ETHTOOL_MSG_PLCA_GET_STATUS`` to set the PLCA (Physical Layer Collision Avoidance) parameters Note that the PHY index can be passed to other requests, which will silently ignore it if present and irrelevant. |