ARP table question

Ben Greear wrote:
> David Miller wrote:
> 
>> This change makes a lot of sense to me, I'll add it to net-next-2.6
>> so it can cook in there for a while just in case there are some
>> unwanted side-effects.
> 
> Thanks Dave.
> 
> I think I found another problem as well:  If I start 1 TCP and 1 UDP 
> connection
> between each of the 500 interfaces on mac-vlans, the ARP tables will not 
> converge.
> 
> It seems to be because mac-vlan has to copy broadcast packets to every
> mac-vlan on a physical device, there are just too many packets:
> 
> 500 vlans arping once per second means 500 pkts per second on the
> other NIC.
> Other NIC must copy these 500 times,
> so, 250000 packets per second in each direction are
> processed by the stack (they are not all on the wire, at least).
> 
> A few get through and those UDP/TCP connections start consuming
> bandwidth, which clogs up the 1G link enough that other responses
> are lost most of the time.
> 
> I'm going to try to work on some sort of random backoff for ARP that can
> be enabled in this situation next.

Ok, here is the patch that implements this.  The idea is to spread out
arp requests when you do something like start 500 TCP connections on 500
MAC-VLANs talking to 500 other MAC-VLANs.

With a retrans timer of 1 sec, and a high volume of traffic, and a semi flaky
network in between, my system will not resolve the ARPs and the retransmits
overload my processors.

Setting the retrans timer to 5 secs on my system also works, so I'm not sure
if this patch is really required, but it might help keep arp requests somewhat
random in cases where arp timers would otherwise try to all fire at the same
time.

This is against 2.6.25.20 plus my patches, but I believe it should
apply to a clean 2.6.25.20 as well.

Comments are welcome.

Signed-Off-By  Ben Greear<greearb@candelatech.com>

Thanks,
Ben

Ben Greear wrote:
> Ok, here is the patch that implements this.  The idea is to spread out
> arp requests when you do something like start 500 TCP connections on 500
> MAC-VLANs talking to 500 other MAC-VLANs.
> 
> With a retrans timer of 1 sec, and a high volume of traffic, and a
> semi flaky network in between, my system will not resolve the ARPs
> and the retransmits overload my processors.
> 
> Setting the retrans timer to 5 secs on my system also works, so I'm
> not sure if this patch is really required, but it might help keep arp
> requests somewhat random in cases where arp timers would otherwise
> try to all fire at the same time.
> 
> This is against 2.6.25.20 plus my patches, but I believe it should
> apply to a clean 2.6.25.20 as well.
> 
> Comments are welcome.
> 
> Signed-Off-By  Ben Greear<greearb@candelatech.com>
> 
> Thanks,
> Ben
> 
> 
> 
> ------------------------------------------------------------------------
> 
> diff --git a/Documentation/filesystems/proc.txt b/Documentation/filesystems/proc.txt
> index 518ebe6..4c805b3 100644
> --- a/Documentation/filesystems/proc.txt
> +++ b/Documentation/filesystems/proc.txt
> @@ -2028,6 +2028,16 @@ Expression of retrans_time, which is deprecated, is in 1/100 seconds (for
>  IPv4) or in jiffies (for IPv6).
>  Expression of retrans_time_ms is in milliseconds.
>  
> +
> +retrans_rand_backof_ms
> +----------------------
> +
> +This is an extra delay (ms) for the retransmit timer.  A random value between
> +0 and retrans_rand_backof_ms will be added to the retrans_timer.  Default
> +is zero.  Setting this to a larger value will help large broadcast domains
> +resolve ARP (for instance, 500 mac-vlans talking to 500 other mac-vlans).
> +
> +
>  unres_qlen
>  ----------
> ...
 >
> diff --git a/net/core/neighbour.c b/net/core/neighbour.c
> index 19b8e00..ec1f048 100644
> --- a/net/core/neighbour.c
> +++ b/net/core/neighbour.c
> @@ -765,6 +765,13 @@ static __inline__ int neigh_max_probes(struct neighbour *n)
>  		p->ucast_probes + p->app_probes + p->mcast_probes);
>  }
>  
> +static unsigned long neigh_rand_retry(struct neighbour* neigh) {
> +	if (neigh->parms->retrans_rand_backoff) {
> +		return net_random() % neigh->parms->retrans_rand_backoff;
> +	}
> +	return 0;
> +}
> +
>  /* Called when a timer expires for a neighbour entry. */

I thought that mod was something we tried to avoid?  Could you instead 
use something that isn't random but perhaps varies among all the 
requests?  Say some of the low-order bits of the IP being resolved?

It wouldn't necessarily be "fair" to some destination IP's but it should 
serve to spread things out a bit without having to generate a random 
number and mod it.

rick jones
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Rick Jones wrote:

>> +static unsigned long neigh_rand_retry(struct neighbour* neigh) {
>> +    if (neigh->parms->retrans_rand_backoff) {
>> +        return net_random() % neigh->parms->retrans_rand_backoff;
>> +    }
>> +    return 0;
>> +}
>> +
>>  /* Called when a timer expires for a neighbour entry. */
> 
> I thought that mod was something we tried to avoid?  Could you instead 
> use something that isn't random but perhaps varies among all the 
> requests?  Say some of the low-order bits of the IP being resolved?

This is only called when we are going to retransmit an ARP, which shouldn't
be in any sort of hot path, so I figured MOD was fine.

The net_random is a very cheap method (last I checked), as well.

So, I think that part is OK as it is, but I'm open to
persuasion :)

Thanks,
Ben

Ben Greear wrote:
> Rick Jones wrote:
> 
>>> +static unsigned long neigh_rand_retry(struct neighbour* neigh) {
>>> +    if (neigh->parms->retrans_rand_backoff) {
>>> +        return net_random() % neigh->parms->retrans_rand_backoff;
>>> +    }
>>> +    return 0;
>>> +}
>>> +
>>>  /* Called when a timer expires for a neighbour entry. */
>>
>>
>> I thought that mod was something we tried to avoid?  Could you instead 
>> use something that isn't random but perhaps varies among all the 
>> requests?  Say some of the low-order bits of the IP being resolved?
> 
> 
> This is only called when we are going to retransmit an ARP, which shouldn't
> be in any sort of hot path, so I figured MOD was fine.
> 
> The net_random is a very cheap method (last I checked), as well.
> 
> So, I think that part is OK as it is, but I'm open to
> persuasion :)

Perhaps I'm confused, or simply channeling Emily Litella again, but if 
you only do this on the 1st through Nth retransmissions (ie after the 
first retransmission timer has popped) don't you still have a thundering 
herd problem on the first transmission and the first retransmission of 
ARP requests?

rick jones
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Rick Jones wrote:
> Ben Greear wrote:
>> Rick Jones wrote:
>>
>>>> +static unsigned long neigh_rand_retry(struct neighbour* neigh) {
>>>> +    if (neigh->parms->retrans_rand_backoff) {
>>>> +        return net_random() % neigh->parms->retrans_rand_backoff;
>>>> +    }
>>>> +    return 0;
>>>> +}
>>>> +
>>>>  /* Called when a timer expires for a neighbour entry. */
>>>
>>>
>>> I thought that mod was something we tried to avoid?  Could you 
>>> instead use something that isn't random but perhaps varies among all 
>>> the requests?  Say some of the low-order bits of the IP being resolved?
>>
>>
>> This is only called when we are going to retransmit an ARP, which 
>> shouldn't
>> be in any sort of hot path, so I figured MOD was fine.
>>
>> The net_random is a very cheap method (last I checked), as well.
>>
>> So, I think that part is OK as it is, but I'm open to
>> persuasion :)
> 
> Perhaps I'm confused, or simply channeling Emily Litella again, but if 
> you only do this on the 1st through Nth retransmissions (ie after the 
> first retransmission timer has popped) don't you still have a thundering 
> herd problem on the first transmission and the first retransmission of 
> ARP requests?

You'd certainly have it on the first transmission, but I think from there on
the randomness should kick in.  This is a pretty rare case, and I'd rather
not slow down the initial ARP.  If we *are* in the overload situation, then
the network can just purge/drop/whatever the initial flood and then the
retransmits should start doing their random thing.  On my system, it still
takes maybe 30 seconds for all the ARPs to resolve since a good deal of
the requests and/or responses are being lost.

After some more testing, I can still get it into a bad
state if I have a retrans timer of 1 sec and a randomness of 5 secs
and manage to cause all 1000 arp entries to go stale at once (by
yanking a cable, for instance).

It seems I have to bump up the base timer to 3-5 seconds (I'm
leaving the random backoff at 5 secs as well).

Thanks,
Ben

From: Ben Greear <greearb@candelatech.com>
Date: Mon, 17 Nov 2008 17:50:50 -0800

> Rick Jones wrote:
> > Ben Greear wrote:
> >> Rick Jones wrote:
> >>
> >>>> +static unsigned long neigh_rand_retry(struct neighbour* neigh) {
> >>>> +    if (neigh->parms->retrans_rand_backoff) {
> >>>> +        return net_random() % neigh->parms->retrans_rand_backoff;
> >>>> +    }
> >>>> +    return 0;
> >>>> +}
> >>>> +
> >>>>  /* Called when a timer expires for a neighbour entry. */
> >>>
> >>>
> >>> I thought that mod was something we tried to avoid?  Could you instead use something that isn't random but perhaps varies among all the requests?  Say some of the low-order bits of the IP being resolved?
> >>
> >>
> >> This is only called when we are going to retransmit an ARP, which shouldn't
> >> be in any sort of hot path, so I figured MOD was fine.
> >>
> >> The net_random is a very cheap method (last I checked), as well.
> >>
> >> So, I think that part is OK as it is, but I'm open to
> >> persuasion :)
> > Perhaps I'm confused, or simply channeling Emily Litella again, but if you only do this on the 1st through Nth retransmissions (ie after the first retransmission timer has popped) don't you still have a thundering herd problem on the first transmission and the first retransmission of ARP requests?
> 
> You'd certainly have it on the first transmission, but I think from there on
> the randomness should kick in.  This is a pretty rare case, and I'd rather
> not slow down the initial ARP.  If we *are* in the overload situation, then
> the network can just purge/drop/whatever the initial flood and then the
> retransmits should start doing their random thing.  On my system, it still
> takes maybe 30 seconds for all the ARPs to resolve since a good deal of
> the requests and/or responses are being lost.
> 
> After some more testing, I can still get it into a bad
> state if I have a retrans timer of 1 sec and a randomness of 5 secs
> and manage to cause all 1000 arp entries to go stale at once (by
> yanking a cable, for instance).
> 
> It seems I have to bump up the base timer to 3-5 seconds (I'm
> leaving the random backoff at 5 secs as well).

This scheme still seems hackish to me, so I'm going to defer on this
for now.
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David Miller wrote:

>> After some more testing, I can still get it into a bad
>> state if I have a retrans timer of 1 sec and a randomness of 5 secs
>> and manage to cause all 1000 arp entries to go stale at once (by
>> yanking a cable, for instance).
>>
>> It seems I have to bump up the base timer to 3-5 seconds (I'm
>> leaving the random backoff at 5 secs as well).
> 
> This scheme still seems hackish to me, so I'm going to defer on this
> for now.

You think something like an exponential backoff capped at some user-configurable
max-value would be better?

On Thu, Nov 20, 2008 at 09:23:53AM -0800, Ben Greear wrote:
> You think something like an exponential backoff capped at some 
> user-configurable
> max-value would be better?

I'll throw in an observation on arp behaviour on wifi / HomePNA: neither 
protocol provides reliable delivery of broadcast traffic, while point to 
point traffic is reliably delivered.  If arp traffic is not sufficiently 
aggressive when a connection is first used, the user can end up waiting 
some time until one of the broadcast packets finally gets through.  Doing 
an exponential backoff will make this significantly worse, unless the 
initial timeout is sufficiently small.

		-ben