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Some DSA switches (and not only) cannot learn source MAC addresses from packets injected from the CPU. They only perform hardware address learning from inbound traffic. This can be problematic when we have a bridge spanning some DSA switch ports and some non-DSA ports (which we'll call "foreign interfaces" from DSA's perspective). There are 2 classes of problems created by the lack of learning on CPU-injected traffic: - excessive flooding, due to the fact that DSA treats those addresses as unknown - the risk of stale routes, which can lead to temporary packet loss To illustrate the second class, consider the following situation, which is common in production equipment (wireless access points, where there is a WLAN interface and an Ethernet switch, and these form a single bridging domain). AP 1: +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ | ^ ^ | | | | | | | Client A Client B | | | +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ AP 2 - br0 of AP 1 will know that Clients A and B are reachable via wlan0 - the hardware fdb of a DSA switch driver today is not kept in sync with the software entries on other bridge ports, so it will not know that clients A and B are reachable via the CPU port UNLESS the hardware switch itself performs SA learning from traffic injected from the CPU. Nonetheless, a substantial number of switches don't. - the hardware fdb of the DSA switch on AP 2 may autonomously learn that Client A and B are reachable through swp0. Therefore, the software br0 of AP 2 also may or may not learn this. In the example we're illustrating, some Ethernet traffic has been going on, and br0 from AP 2 has indeed learnt that it can reach Client B through swp0. One of the wireless clients, say Client B, disconnects from AP 1 and roams to AP 2. The topology now looks like this: AP 1: +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ | ^ | | | Client A | | | Client B | | | v +------------+ +------------+ +------------+ +------------+ +------------+ | swp0 | | swp1 | | swp2 | | swp3 | | wlan0 | +------------+ +------------+ +------------+ +------------+ +------------+ +------------------------------------------------------------------------+ | br0 | +------------------------------------------------------------------------+ AP 2 - br0 of AP 1 still knows that Client A is reachable via wlan0 (no change) - br0 of AP 1 will (possibly) know that Client B has left wlan0. There are cases where it might never find out though. Either way, DSA today does not process that notification in any way. - the hardware FDB of the DSA switch on AP 1 may learn autonomously that Client B can be reached via swp0, if it receives any packet with Client 1's source MAC address over Ethernet. - the hardware FDB of the DSA switch on AP 2 still thinks that Client B can be reached via swp0. It does not know that it has roamed to wlan0, because it doesn't perform SA learning from the CPU port. Now Client A contacts Client B. AP 1 routes the packet fine towards swp0 and delivers it on the Ethernet segment. AP 2 sees a frame on swp0 and its fdb says that the destination is swp0. Hairpinning is disabled => drop. This problem comes from the fact that these switches have a 'blind spot' for addresses coming from software bridging. The generic solution is not to assume that hardware learning can be enabled somehow, but to listen to more bridge learning events. It turns out that the bridge driver does learn in software from all inbound frames, in __br_handle_local_finish. A proper SWITCHDEV_FDB_ADD_TO_DEVICE notification is emitted for the addresses serviced by the bridge on 'foreign' interfaces. The software bridge also does the right thing on migration, by notifying that the old entry is deleted, so that does not need to be special-cased in DSA. When it is deleted, we just need to delete our static FDB entry towards the CPU too, and wait. The problem is that DSA currently only cares about SWITCHDEV_FDB_ADD_TO_DEVICE events received on its own interfaces, such as static FDB entries. Luckily we can change that, and DSA can listen to all switchdev FDB add/del events in the system and figure out if those events were emitted by a bridge that spans at least one of DSA's own ports. In case that is true, DSA will also offload that address towards its own CPU port, in the eventuality that there might be bridge clients attached to the DSA switch who want to talk to the station connected to the foreign interface. In terms of implementation, we need to keep the fdb_info->added_by_user check for the case where the switchdev event was targeted directly at a DSA switch port. But we don't need to look at that flag for snooped events. So the check is currently too late, we need to move it earlier. This also simplifies the code a bit, since we avoid uselessly allocating and freeing switchdev_work. We could probably do some improvements in the future. For example, multi-bridge support is rudimentary at the moment. If there are two bridges spanning a DSA switch's ports, and both of them need to service the same MAC address, then what will happen is that the migration of one of those stations will trigger the deletion of the FDB entry from the CPU port while it is still used by other bridge. That could be improved with reference counting but is left for another time. This behavior needs to be enabled at driver level by setting ds->assisted_learning_on_cpu_port = true. This is because we don't want to inflict a potential performance penalty (accesses through MDIO/I2C/SPI are expensive) to hardware that really doesn't need it because address learning on the CPU port works there. Reported-by: DENG Qingfang <dqfext@gmail.com> Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com> Reviewed-by: Florian Fainelli <f.fainelli@gmail.com> Reviewed-by: Andrew Lunn <andrew@lunn.ch> Signed-off-by: Jakub Kicinski <kuba@kernel.org> |
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bluetooth | ||
caif | ||
iucv | ||
netfilter | ||
netns | ||
nfc | ||
phonet | ||
sctp | ||
tc_act | ||
6lowpan.h | ||
act_api.h | ||
addrconf.h | ||
af_ieee802154.h | ||
af_rxrpc.h | ||
af_unix.h | ||
af_vsock.h | ||
ah.h | ||
arp.h | ||
atmclip.h | ||
ax25.h | ||
ax88796.h | ||
bareudp.h | ||
bond_3ad.h | ||
bond_alb.h | ||
bond_options.h | ||
bonding.h | ||
bpf_sk_storage.h | ||
busy_poll.h | ||
calipso.h | ||
cfg80211-wext.h | ||
cfg80211.h | ||
cfg802154.h | ||
checksum.h | ||
cipso_ipv4.h | ||
cls_cgroup.h | ||
codel_impl.h | ||
codel_qdisc.h | ||
codel.h | ||
compat.h | ||
datalink.h | ||
dcbevent.h | ||
dcbnl.h | ||
devlink.h | ||
dn_dev.h | ||
dn_fib.h | ||
dn_neigh.h | ||
dn_nsp.h | ||
dn_route.h | ||
dn.h | ||
dsa.h | ||
dsfield.h | ||
dst_cache.h | ||
dst_metadata.h | ||
dst_ops.h | ||
dst.h | ||
erspan.h | ||
esp.h | ||
espintcp.h | ||
ethoc.h | ||
failover.h | ||
fib_notifier.h | ||
fib_rules.h | ||
firewire.h | ||
flow_dissector.h | ||
flow_offload.h | ||
flow.h | ||
fou.h | ||
fq_impl.h | ||
fq.h | ||
garp.h | ||
gen_stats.h | ||
genetlink.h | ||
geneve.h | ||
gre.h | ||
gro_cells.h | ||
gtp.h | ||
gue.h | ||
hwbm.h | ||
icmp.h | ||
ieee80211_radiotap.h | ||
ieee802154_netdev.h | ||
if_inet6.h | ||
ife.h | ||
ila.h | ||
inet6_connection_sock.h | ||
inet6_hashtables.h | ||
inet_common.h | ||
inet_connection_sock.h | ||
inet_ecn.h | ||
inet_frag.h | ||
inet_hashtables.h | ||
inet_sock.h | ||
inet_timewait_sock.h | ||
inetpeer.h | ||
ip6_checksum.h | ||
ip6_fib.h | ||
ip6_route.h | ||
ip6_tunnel.h | ||
ip_fib.h | ||
ip_tunnels.h | ||
ip_vs.h | ||
ip.h | ||
ipcomp.h | ||
ipconfig.h | ||
ipv6_frag.h | ||
ipv6_stubs.h | ||
ipv6.h | ||
ipx.h | ||
iw_handler.h | ||
kcm.h | ||
l3mdev.h | ||
lag.h | ||
lapb.h | ||
lib80211.h | ||
llc_c_ac.h | ||
llc_c_ev.h | ||
llc_c_st.h | ||
llc_conn.h | ||
llc_if.h | ||
llc_pdu.h | ||
llc_s_ac.h | ||
llc_s_ev.h | ||
llc_s_st.h | ||
llc_sap.h | ||
llc.h | ||
lwtunnel.h | ||
mac80211.h | ||
mac802154.h | ||
macsec.h | ||
mip6.h | ||
mld.h | ||
mpls_iptunnel.h | ||
mpls.h | ||
mptcp.h | ||
mrp.h | ||
ncsi.h | ||
ndisc.h | ||
neighbour.h | ||
net_failover.h | ||
net_namespace.h | ||
net_ratelimit.h | ||
netevent.h | ||
netlabel.h | ||
netlink.h | ||
netprio_cgroup.h | ||
netrom.h | ||
nexthop.h | ||
nl802154.h | ||
nsh.h | ||
p8022.h | ||
page_pool.h | ||
pie.h | ||
ping.h | ||
pkt_cls.h | ||
pkt_sched.h | ||
pptp.h | ||
protocol.h | ||
psample.h | ||
psnap.h | ||
raw.h | ||
rawv6.h | ||
red.h | ||
regulatory.h | ||
request_sock.h | ||
rose.h | ||
route.h | ||
rpl.h | ||
rsi_91x.h | ||
rtnetlink.h | ||
rtnh.h | ||
sch_generic.h | ||
scm.h | ||
secure_seq.h | ||
seg6_hmac.h | ||
seg6_local.h | ||
seg6.h | ||
slhc_vj.h | ||
smc.h | ||
snmp.h | ||
sock_reuseport.h | ||
sock.h | ||
Space.h | ||
stp.h | ||
strparser.h | ||
switchdev.h | ||
tcp_states.h | ||
tcp.h | ||
timewait_sock.h | ||
tipc.h | ||
tls_toe.h | ||
tls.h | ||
transp_v6.h | ||
tso.h | ||
tun_proto.h | ||
udp_tunnel.h | ||
udp.h | ||
udplite.h | ||
vsock_addr.h | ||
vxlan.h | ||
wext.h | ||
x25.h | ||
x25device.h | ||
xdp_priv.h | ||
xdp_sock_drv.h | ||
xdp_sock.h | ||
xdp.h | ||
xfrm.h | ||
xsk_buff_pool.h |