On 12/12/19 1:11 PM, Johannes Berg wrote:
Hi Eric,
Thanks for looking :)
I'm not sure how to do headers-only, but I guess -s100 will work.
https://johannes.sipsolutions.net/files/he-tcp.pcap.xz
Lack of GRO on receiver is probably what is killing performance,
both for receiver (generating gazillions of acks) and sender
(to process all these acks)
Yes, I'm aware of this, to some extent. And I'm not saying we should see
even close to 1800 Mbps like we have with UDP...
Mind you, the biggest thing that kills performance with many ACKs isn't
the load on the system - the sender system is only moderately loaded at
~20-25% of a single core with TSO, and around double that without TSO.
The thing that kills performance is eating up all the medium time with
small non-aggregated packets, due to the the half-duplex nature of WiFi.
I know you know, but in case somebody else is reading along :-)
But unless somehow you think processing the (many) ACKs on the sender
will cause it to stop transmitting, or something like that, I don't
think I should be seeing what I described earlier: we sometimes (have
to?) reclaim the entire transmit queue before TCP starts pushing data
again. That's less than 2MB split across at least two TCP streams, I
don't see why we should have to get to 0 (which takes about 7ms) until
more packets come in from TCP?
Or put another way - if I free say 400kB worth of SKBs, what could be
the reason we don't see more packets be sent out of the TCP stack within
the few ms or so? I guess I have to correlate this somehow with the ACKs
so I know how much data is outstanding for ACKs. (*)
The sk_pacing_shift is set to 7, btw, which should give us 8ms of
outstanding data. For now in this setup that's enough(**), and indeed
bumping the limit up (setting sk_pacing_shift to say 5) doesn't change
anything. So I think this part we actually solved - I get basically the
same performance and behaviour with two streams (needed due to GBit LAN
on the other side) as with 20 streams.
I had a plan about enabling compressing ACK as I did for SACK
in commit
https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/commit/?id=5d9f4262b7ea41ca9981cc790e37cca6e37c789e
But I have not done it yet.
It is a pity because this would tremendously help wifi I am sure.
Nice :-)
But that is something the *receiver* would have to do.
The dirty secret here is that we're getting close to 1700 Mbps TCP with
Windows in place of Linux in the setup, with the same receiver on the
other end (which is actually a single Linux machine with two GBit
network connections to the AP). So if we had this I'm sure it'd increase
performance, but it still wouldn't explain why we're so much slower than
Windows :-)
Now, I'm certainly not saying that TCP behaviour is the only reason for
the difference, we already found an issue for example where due to a
small Windows driver bug some packet extension was always used, and the
AP is also buggy in that it needs the extension but didn't request it
... so the two bugs cancelled each other out and things worked well, but
our Linux driver believed the AP ... :) Certainly there can be more
things like that still, I just started on the TCP side and ran into the
queueing behaviour that I cannot explain.
In any case, I'll try to dig deeper into the TCP stack to understand the
reason for this transmit behaviour.
Thanks,
johannes
(*) Hmm. Now I have another idea. Maybe we have some kind of problem
with the medium access configuration, and we transmit all this data
without the AP having a chance to send back all the ACKs? Too bad I
can't put an air sniffer into the setup - it's a conductive setup.
splitter/combiner?
If it is just delayed acks coming back, which would slow down a stream, then
multiple streams would tend to work around that problem?
I would actually expect similar speedup with multiple streams if some TCP socket
was blocked on waiting for ACKs too.
Even if you can't sniff the air, you could sniff the wire or just look at packet
in/out counts. If you have a huge number of ACKs, that would show up in raw pkt
counters.
I'm not sure it matters these days, but this patch greatly helped TCP throughput on
ath10k for a while, and we are still using it. Maybe your sk_pacing change already
tweaked the same logic:
https://github.com/greearb/linux-ct-5.4/commit/65651d4269eb2b0d4b4952483c56316a7fbe2f48
if [ -w /proc/sys/net/ipv4/tcp_tsq_limit_output_interval ]
then
# This helps TCP tx throughput when using ath10k. Setting > 1 likely
# increases latency in some cases, but on average, seems a win for us.
TCP_TSQ=200
echo -n "Setting TCP-tsq limit to $TCP_TSQ....................................... "
echo $TCP_TSQ > /proc/sys/net/ipv4/tcp_tsq_limit_output_interval
echo "DONE"
fi
Thanks,
Ben
--
Ben Greear <greearb@xxxxxxxxxxxxxxx>
Candela Technologies Inc http://www.candelatech.com
