xref: /linux/Documentation/networking/bridge.rst (revision c532de5a67a70f8533d495f8f2aaa9a0491c3ad0)
1.. SPDX-License-Identifier: GPL-2.0
2
3=================
4Ethernet Bridging
5=================
6
7Introduction
8============
9
10The IEEE 802.1Q-2022 (Bridges and Bridged Networks) standard defines the
11operation of bridges in computer networks. A bridge, in the context of this
12standard, is a device that connects two or more network segments and operates
13at the data link layer (Layer 2) of the OSI (Open Systems Interconnection)
14model. The purpose of a bridge is to filter and forward frames between
15different segments based on the destination MAC (Media Access Control) address.
16
17Bridge kAPI
18===========
19
20Here are some core structures of bridge code. Note that the kAPI is *unstable*,
21and can be changed at any time.
22
23.. kernel-doc:: net/bridge/br_private.h
24   :identifiers: net_bridge_vlan
25
26Bridge uAPI
27===========
28
29Modern Linux bridge uAPI is accessed via Netlink interface. You can find
30below files where the bridge and bridge port netlink attributes are defined.
31
32Bridge netlink attributes
33-------------------------
34
35.. kernel-doc:: include/uapi/linux/if_link.h
36   :doc: Bridge enum definition
37
38Bridge port netlink attributes
39------------------------------
40
41.. kernel-doc:: include/uapi/linux/if_link.h
42   :doc: Bridge port enum definition
43
44Bridge sysfs
45------------
46
47The sysfs interface is deprecated and should not be extended if new
48options are added.
49
50STP
51===
52
53The STP (Spanning Tree Protocol) implementation in the Linux bridge driver
54is a critical feature that helps prevent loops and broadcast storms in
55Ethernet networks by identifying and disabling redundant links. In a Linux
56bridge context, STP is crucial for network stability and availability.
57
58STP is a Layer 2 protocol that operates at the Data Link Layer of the OSI
59model. It was originally developed as IEEE 802.1D and has since evolved into
60multiple versions, including Rapid Spanning Tree Protocol (RSTP) and
61`Multiple Spanning Tree Protocol (MSTP)
62<https://lore.kernel.org/netdev/20220316150857.2442916-1-tobias@waldekranz.com/>`_.
63
64The 802.1D-2004 removed the original Spanning Tree Protocol, instead
65incorporating the Rapid Spanning Tree Protocol (RSTP). By 2014, all the
66functionality defined by IEEE 802.1D has been incorporated into either
67IEEE 802.1Q (Bridges and Bridged Networks) or IEEE 802.1AC (MAC Service
68Definition). 802.1D has been officially withdrawn in 2022.
69
70Bridge Ports and STP States
71---------------------------
72
73In the context of STP, bridge ports can be in one of the following states:
74  * Blocking: The port is disabled for data traffic and only listens for
75    BPDUs (Bridge Protocol Data Units) from other devices to determine the
76    network topology.
77  * Listening: The port begins to participate in the STP process and listens
78    for BPDUs.
79  * Learning: The port continues to listen for BPDUs and begins to learn MAC
80    addresses from incoming frames but does not forward data frames.
81  * Forwarding: The port is fully operational and forwards both BPDUs and
82    data frames.
83  * Disabled: The port is administratively disabled and does not participate
84    in the STP process. The data frames forwarding are also disabled.
85
86Root Bridge and Convergence
87---------------------------
88
89In the context of networking and Ethernet bridging in Linux, the root bridge
90is a designated switch in a bridged network that serves as a reference point
91for the spanning tree algorithm to create a loop-free topology.
92
93Here's how the STP works and root bridge is chosen:
94  1. Bridge Priority: Each bridge running a spanning tree protocol, has a
95     configurable Bridge Priority value. The lower the value, the higher the
96     priority. By default, the Bridge Priority is set to a standard value
97     (e.g., 32768).
98  2. Bridge ID: The Bridge ID is composed of two components: Bridge Priority
99     and the MAC address of the bridge. It uniquely identifies each bridge
100     in the network. The Bridge ID is used to compare the priorities of
101     different bridges.
102  3. Bridge Election: When the network starts, all bridges initially assume
103     that they are the root bridge. They start advertising Bridge Protocol
104     Data Units (BPDU) to their neighbors, containing their Bridge ID and
105     other information.
106  4. BPDU Comparison: Bridges exchange BPDUs to determine the root bridge.
107     Each bridge examines the received BPDUs, including the Bridge Priority
108     and Bridge ID, to determine if it should adjust its own priorities.
109     The bridge with the lowest Bridge ID will become the root bridge.
110  5. Root Bridge Announcement: Once the root bridge is determined, it sends
111     BPDUs with information about the root bridge to all other bridges in the
112     network. This information is used by other bridges to calculate the
113     shortest path to the root bridge and, in doing so, create a loop-free
114     topology.
115  6. Forwarding Ports: After the root bridge is selected and the spanning tree
116     topology is established, each bridge determines which of its ports should
117     be in the forwarding state (used for data traffic) and which should be in
118     the blocking state (used to prevent loops). The root bridge's ports are
119     all in the forwarding state. while other bridges have some ports in the
120     blocking state to avoid loops.
121  7. Root Ports: After the root bridge is selected and the spanning tree
122     topology is established, each non-root bridge processes incoming
123     BPDUs and determines which of its ports provides the shortest path to the
124     root bridge based on the information in the received BPDUs. This port is
125     designated as the root port. And it is in the Forwarding state, allowing
126     it to actively forward network traffic.
127  8. Designated ports: A designated port is the port through which the non-root
128     bridge will forward traffic towards the designated segment. Designated ports
129     are placed in the Forwarding state. All other ports on the non-root
130     bridge that are not designated for specific segments are placed in the
131     Blocking state to prevent network loops.
132
133STP ensures network convergence by calculating the shortest path and disabling
134redundant links. When network topology changes occur (e.g., a link failure),
135STP recalculates the network topology to restore connectivity while avoiding loops.
136
137Proper configuration of STP parameters, such as the bridge priority, can
138influence network performance, path selection and which bridge becomes the
139Root Bridge.
140
141User space STP helper
142---------------------
143
144The user space STP helper *bridge-stp* is a program to control whether to use
145user mode spanning tree. The ``/sbin/bridge-stp <bridge> <start|stop>`` is
146called by the kernel when STP is enabled/disabled on a bridge
147(via ``brctl stp <bridge> <on|off>`` or ``ip link set <bridge> type bridge
148stp_state <0|1>``).  The kernel enables user_stp mode if that command returns
1490, or enables kernel_stp mode if that command returns any other value.
150
151VLAN
152====
153
154A LAN (Local Area Network) is a network that covers a small geographic area,
155typically within a single building or a campus. LANs are used to connect
156computers, servers, printers, and other networked devices within a localized
157area. LANs can be wired (using Ethernet cables) or wireless (using Wi-Fi).
158
159A VLAN (Virtual Local Area Network) is a logical segmentation of a physical
160network into multiple isolated broadcast domains. VLANs are used to divide
161a single physical LAN into multiple virtual LANs, allowing different groups of
162devices to communicate as if they were on separate physical networks.
163
164Typically there are two VLAN implementations, IEEE 802.1Q and IEEE 802.1ad
165(also known as QinQ). IEEE 802.1Q is a standard for VLAN tagging in Ethernet
166networks. It allows network administrators to create logical VLANs on a
167physical network and tag Ethernet frames with VLAN information, which is
168called *VLAN-tagged frames*. IEEE 802.1ad, commonly known as QinQ or Double
169VLAN, is an extension of the IEEE 802.1Q standard. QinQ allows for the
170stacking of multiple VLAN tags within a single Ethernet frame. The Linux
171bridge supports both the IEEE 802.1Q and `802.1AD
172<https://lore.kernel.org/netdev/1402401565-15423-1-git-send-email-makita.toshiaki@lab.ntt.co.jp/>`_
173protocol for VLAN tagging.
174
175`VLAN filtering <https://lore.kernel.org/netdev/1360792820-14116-1-git-send-email-vyasevic@redhat.com/>`_
176on a bridge is disabled by default. After enabling VLAN filtering on a bridge,
177it will start forwarding frames to appropriate destinations based on their
178destination MAC address and VLAN tag (both must match).
179
180Multicast
181=========
182
183The Linux bridge driver has multicast support allowing it to process Internet
184Group Management Protocol (IGMP) or Multicast Listener Discovery (MLD)
185messages, and to efficiently forward multicast data packets. The bridge
186driver supports IGMPv2/IGMPv3 and MLDv1/MLDv2.
187
188Multicast snooping
189------------------
190
191Multicast snooping is a networking technology that allows network switches
192to intelligently manage multicast traffic within a local area network (LAN).
193
194The switch maintains a multicast group table, which records the association
195between multicast group addresses and the ports where hosts have joined these
196groups. The group table is dynamically updated based on the IGMP/MLD messages
197received. With the multicast group information gathered through snooping, the
198switch optimizes the forwarding of multicast traffic. Instead of blindly
199broadcasting the multicast traffic to all ports, it sends the multicast
200traffic based on the destination MAC address only to ports which have
201subscribed the respective destination multicast group.
202
203When created, the Linux bridge devices have multicast snooping enabled by
204default. It maintains a Multicast forwarding database (MDB) which keeps track
205of port and group relationships.
206
207IGMPv3/MLDv2 EHT support
208------------------------
209
210The Linux bridge supports IGMPv3/MLDv2 EHT (Explicit Host Tracking), which
211was added by `474ddb37fa3a ("net: bridge: multicast: add EHT allow/block handling")
212<https://lore.kernel.org/netdev/20210120145203.1109140-1-razor@blackwall.org/>`_
213
214The explicit host tracking enables the device to keep track of each
215individual host that is joined to a particular group or channel. The main
216benefit of the explicit host tracking in IGMP is to allow minimal leave
217latencies when a host leaves a multicast group or channel.
218
219The length of time between a host wanting to leave and a device stopping
220traffic forwarding is called the IGMP leave latency. A device configured
221with IGMPv3 or MLDv2 and explicit tracking can immediately stop forwarding
222traffic if the last host to request to receive traffic from the device
223indicates that it no longer wants to receive traffic. The leave latency
224is thus bound only by the packet transmission latencies in the multiaccess
225network and the processing time in the device.
226
227Other multicast features
228------------------------
229
230The Linux bridge also supports `per-VLAN multicast snooping
231<https://lore.kernel.org/netdev/20210719170637.435541-1-razor@blackwall.org/>`_,
232which is disabled by default but can be enabled. And `Multicast Router Discovery
233<https://lore.kernel.org/netdev/20190121062628.2710-1-linus.luessing@c0d3.blue/>`_,
234which help identify the location of multicast routers.
235
236Switchdev
237=========
238
239Linux Bridge Switchdev is a feature in the Linux kernel that extends the
240capabilities of the traditional Linux bridge to work more efficiently with
241hardware switches that support switchdev. With Linux Bridge Switchdev, certain
242networking functions like forwarding, filtering, and learning of Ethernet
243frames can be offloaded to a hardware switch. This offloading reduces the
244burden on the Linux kernel and CPU, leading to improved network performance
245and lower latency.
246
247To use Linux Bridge Switchdev, you need hardware switches that support the
248switchdev interface. This means that the switch hardware needs to have the
249necessary drivers and functionality to work in conjunction with the Linux
250kernel.
251
252Please see the :ref:`switchdev` document for more details.
253
254Netfilter
255=========
256
257The bridge netfilter module is a legacy feature that allows to filter bridged
258packets with iptables and ip6tables. Its use is discouraged. Users should
259consider using nftables for packet filtering.
260
261The older ebtables tool is more feature-limited compared to nftables, but
262just like nftables it doesn't need this module either to function.
263
264The br_netfilter module intercepts packets entering the bridge, performs
265minimal sanity tests on ipv4 and ipv6 packets and then pretends that
266these packets are being routed, not bridged. br_netfilter then calls
267the ip and ipv6 netfilter hooks from the bridge layer, i.e. ip(6)tables
268rulesets will also see these packets.
269
270br_netfilter is also the reason for the iptables *physdev* match:
271This match is the only way to reliably tell routed and bridged packets
272apart in an iptables ruleset.
273
274Note that ebtables and nftables will work fine without the br_netfilter module.
275iptables/ip6tables/arptables do not work for bridged traffic because they
276plug in the routing stack. nftables rules in ip/ip6/inet/arp families won't
277see traffic that is forwarded by a bridge either, but that's very much how it
278should be.
279
280Historically the feature set of ebtables was very limited (it still is),
281this module was added to pretend packets are routed and invoke the ipv4/ipv6
282netfilter hooks from the bridge so users had access to the more feature-rich
283iptables matching capabilities (including conntrack). nftables doesn't have
284this limitation, pretty much all features work regardless of the protocol family.
285
286So, br_netfilter is only needed if users, for some reason, need to use
287ip(6)tables to filter packets forwarded by the bridge, or NAT bridged
288traffic. For pure link layer filtering, this module isn't needed.
289
290Other Features
291==============
292
293The Linux bridge also supports `IEEE 802.11 Proxy ARP
294<https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/?id=958501163ddd6ea22a98f94fa0e7ce6d4734e5c4>`_,
295`Media Redundancy Protocol (MRP)
296<https://lore.kernel.org/netdev/20200426132208.3232-1-horatiu.vultur@microchip.com/>`_,
297`Media Redundancy Protocol (MRP) LC mode
298<https://lore.kernel.org/r/20201124082525.273820-1-horatiu.vultur@microchip.com>`_,
299`IEEE 802.1X port authentication
300<https://lore.kernel.org/netdev/20220218155148.2329797-1-schultz.hans+netdev@gmail.com/>`_,
301and `MAC Authentication Bypass (MAB)
302<https://lore.kernel.org/netdev/20221101193922.2125323-2-idosch@nvidia.com/>`_.
303
304FAQ
305===
306
307What does a bridge do?
308----------------------
309
310A bridge transparently forwards traffic between multiple network interfaces.
311In plain English this means that a bridge connects two or more physical
312Ethernet networks, to form one larger (logical) Ethernet network.
313
314Is it L3 protocol independent?
315------------------------------
316
317Yes. The bridge sees all frames, but it *uses* only L2 headers/information.
318As such, the bridging functionality is protocol independent, and there should
319be no trouble forwarding IPX, NetBEUI, IP, IPv6, etc.
320
321Contact Info
322============
323
324The code is currently maintained by Roopa Prabhu <roopa@nvidia.com> and
325Nikolay Aleksandrov <razor@blackwall.org>. Bridge bugs and enhancements
326are discussed on the linux-netdev mailing list netdev@vger.kernel.org and
327bridge@lists.linux.dev.
328
329The list is open to anyone interested: http://vger.kernel.org/vger-lists.html#netdev
330
331External Links
332==============
333
334The old Documentation for Linux bridging is on:
335https://wiki.linuxfoundation.org/networking/bridge
336