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All modification made by update_kernel.sh in a fresh clone without existing toolchains. Build system: x86_64 Build-tested: ipq806x/R7800, bcm27xx/bcm2711 Run-tested: ipq806x/R7800 Compile-tested [*]: ath79/{tiny,generic}, ipq40xx, octeon, ramips/mt7621, realtek, x86/64 Run-tested [*]: ath79/generic, ipq40xx, octeon, ramips/mt7621 No dmesg regressions, everything functional Signed-off-by: John Audia <graysky@archlinux.us> Tested-by: Stijn Segers <foss@volatilesystems.org> [*]
150 lines
6.6 KiB
Diff
150 lines
6.6 KiB
Diff
From 937bf9496489cb4b491e75fe4436348bf3454dcd Mon Sep 17 00:00:00 2001
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From: Vladimir Oltean <vladimir.oltean@nxp.com>
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Date: Sat, 21 Dec 2019 23:19:20 +0200
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Subject: [PATCH] net: mscc: ocelot: Workaround to allow traffic to CPU in
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standalone mode
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The Ocelot switches have what is, in my opinion, a design flaw: their
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DSA header is in front of the Ethernet header, which means that they
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subvert the DSA master's RX filter, which for all practical purposes,
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either needs to be in promiscuous mode, or the OCELOT_TAG_PREFIX_LONG
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needs to be used for extraction, which makes the switch add a fake DMAC
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of ff:ff:ff:ff:ff:ff so that the DSA master accepts the frame.
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The issue with this design, of course, is that the CPU will be spammed
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with frames that it doesn't want to respond to, and there isn't any
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hardware offload in place by default to drop them.
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What is being done in the VSC7514 Ocelot driver is a process of
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selective whitelisting. The "MAC address" of each Ocelot switch net
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device, with all VLANs installed on that port, is being added as a FDB
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entry towards PGID_CPU.
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Some background first: Port Group IDs (PGIDs) are masks of destination
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ports. The switch performs 3 lookups in the PGID table for each frame,
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and forwards the frame to the ports that are present in the logical AND
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of all 3 PGIDs (for the most part, see below).
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The first PGID lookup is for the destination masks and the PGID table is
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indexed by the DEST_IDX field from the MAC table (FDB).
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The PGID can be an unicast set: PGIDs 0-11 are the per-port PGIDs, and
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by convention PGID i has only BIT(i) set, aka only this port is set in
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the destination mask.
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Or the PGID can be a multicast set: PGIDs 12-63 can (again, still by
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convention) hold a richer destination mask comprised of multiple ports.
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[ Ignoring the second PGID lookup, for aggregation, since it doesn't
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interfere. ]
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The third PGID lookup is for source masks: PGID entries 80-91 answer the
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question: is port i allowed to forward traffic to port j? If yes, then
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BIT(j) of PGID 80+i will be found set.
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What is interesting about the CPU port in this whole story is that, in
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the way the driver sets up the PGIDs, its bit isn't set in any source
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mask PGID of any other port (therefore, the third lookup would always
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decide to exclude the CPU port from this list). So frames are never
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_forwarded_ to the CPU.
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There is a loophole in this PGID mechanism which is described in the
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VSC7514 manual:
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If an entry is found in the MAC table entry of ENTRY_TYPE 0 or 1
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and the CPU port is set in the PGID pointed to by the MAC table
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entry, CPU extraction queue PGID.DST_PGID is added to the CPUQ.
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In other words, the CPU port is special, and frames are "copied" to the
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CPU, disregarding the source masks (third PGID lookup), if BIT(cpu) is
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found to be set in the destination masks (first PGID lookup).
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Now back to the story: what is PGID_CPU? It is a multicast set
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containing only BIT(cpu). I don't know why it was chosen to be a
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multicast PGID (59) and not simply the unicast one of this port, but it
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doesn't matter.
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The point is that frames that match the FDB will go to PGID_CPU by
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virtue of the DEST_IDX from the respective MAC table entry, and frames
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that don't will go to PGID_UC or PGID_MC, by virtue of the FLD_UNICAST,
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FLD_BROADCAST etc settings for flooding. And that is where the
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distinction is made: flooded frames will be subject to the third PGID
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lookup, while frames that are whitelisted to the PGID_CPU by the MAC
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table aren't.
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So we can use this mechanism to simulate an RX filter, given that we are
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subverting the DSA master's implicit one, as mentioned in the first
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paragraph. But this has some limitations:
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- In Ocelot each net device has its own MAC address. When simulating
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this with MAC table entries, it will practically result in having N
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MAC addresses for each of the N front-panel ports (because FDB entries
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are not per source port). A bit strange, I think.
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- In DSA we don't have the infrastructure in place to support this
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whitelisting mechanism. Calling .port_fdb_add on the CPU port for each
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slave net device dev_addr isn't, in itself, hard. The problem is with
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the VLANs that this port is part of. We would need to keep a duplicate
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list of the VLANs from the bridge, plus the ones added from 8021q, for
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each port. And we would need reference counting on each MAC address,
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such that when a front-panel port changes its MAC address and we need
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to delete the old FDB entry, we don't actually delete it if the other
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front-panel ports are still using it. Not to mention that this FDB
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entry would have to be added on the whole net of upstream DSA switches.
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So... it's complicated. What this patch does is to simply allow frames
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to be flooded to the CPU, which is anyway what the Ocelot driver is
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doing after removing the bridge from the net devices, see this snippet
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from ocelot_bridge_stp_state_set:
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/* Apply FWD mask. The loop is needed to add/remove the current port as
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* a source for the other ports.
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*/
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for (p = 0; p < ocelot->num_phys_ports; p++) {
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if (p == ocelot->cpu || (ocelot->bridge_fwd_mask & BIT(p))) {
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(...)
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} else {
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/* Only the CPU port, this is compatible with link
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* aggregation.
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*/
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ocelot_write_rix(ocelot,
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BIT(ocelot->cpu),
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ANA_PGID_PGID, PGID_SRC + p);
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}
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Otherwise said, the ocelot driver itself is already not self-coherent,
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since immediately after probe time, and immediately after removal from a
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bridge, it behaves in different ways, although the front panel ports are
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standalone in both cases.
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While standalone traffic _does_ work for the Felix DSA wrapper after
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enslaving and removing the ports from a bridge, this patch makes
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standalone traffic work at probe time too, with the caveat that even
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irrelevant frames will get processed by software, making it more
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susceptible to denial of service.
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Signed-off-by: Vladimir Oltean <vladimir.oltean@nxp.com>
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---
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drivers/net/ethernet/mscc/ocelot.c | 12 ++++++++++++
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1 file changed, 12 insertions(+)
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--- a/drivers/net/ethernet/mscc/ocelot.c
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+++ b/drivers/net/ethernet/mscc/ocelot.c
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@@ -2294,6 +2294,18 @@ void ocelot_set_cpu_port(struct ocelot *
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enum ocelot_tag_prefix injection,
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enum ocelot_tag_prefix extraction)
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{
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+ int port;
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+
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+ for (port = 0; port < ocelot->num_phys_ports; port++) {
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+ /* Disable old CPU port and enable new one */
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+ ocelot_rmw_rix(ocelot, 0, BIT(ocelot->cpu),
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+ ANA_PGID_PGID, PGID_SRC + port);
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+ if (port == cpu)
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+ continue;
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+ ocelot_rmw_rix(ocelot, BIT(cpu), BIT(cpu),
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+ ANA_PGID_PGID, PGID_SRC + port);
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+ }
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+
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/* Configure and enable the CPU port. */
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ocelot_write_rix(ocelot, 0, ANA_PGID_PGID, cpu);
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ocelot_write_rix(ocelot, BIT(cpu), ANA_PGID_PGID, PGID_CPU);
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