From mboxrd@z Thu Jan 1 00:00:00 1970 From: Bill Fink Subject: Re: [PATCH 0/3] net: Byte queue limit patch series Date: Tue, 26 Apr 2011 01:56:45 -0400 Message-ID: <20110426015645.c2d19cfe.billfink@mindspring.com> References: Mime-Version: 1.0 Content-Type: text/plain; charset=US-ASCII Content-Transfer-Encoding: 7bit Cc: davem@davemloft.net, netdev@vger.kernel.org To: Tom Herbert Return-path: Received: from elasmtp-scoter.atl.sa.earthlink.net ([209.86.89.67]:33599 "EHLO elasmtp-scoter.atl.sa.earthlink.net" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S1754275Ab1DZF4r (ORCPT ); Tue, 26 Apr 2011 01:56:47 -0400 In-Reply-To: Sender: netdev-owner@vger.kernel.org List-ID: On Mon, 25 Apr 2011, Tom Herbert wrote: > This patch series implements byte queue limits (bql) for NIC TX queues. > > Byte queue limits are a mechanism to limit the size of the transmit > hardware queue on a NIC by number of bytes. The goal of these byte > limits is too reduce latency caused by excessive queuing in hardware > without sacrificing throughput. > > Hardware queuing limits are typically specified in terms of a number > hardware descriptors, each of which has a variable size. The variability > of the size of individual queued items can have a very wide range. For > instance with the e1000 NIC the size could range from 64 bytes to 4K > (with TSO enabled). This variability makes it next to impossible to > choose a single queue limit that prevents starvation and provides lowest > possible latency. > > The objective of byte queue limits is to set the limit to be the > minimum needed to prevent starvation between successive transmissions to > the hardware. The latency between two transmissions can be variable in a > system. It is dependent on interrupt frequency, NAPI polling latencies, > scheduling of the queuing discipline, lock contention, etc. Therefore we > propose that byte queue limits should be dynamic and change in > iaccordance with networking stack latencies a system encounters. > > Patches to implement this: > Patch 1: Dynamic queue limits (dql) library. This provides the general > queuing algorithm. > Patch 2: netdev changes that use dlq to support byte queue limits. > Patch 3: Support in forcedeth drvier for byte queue limits. > > The effects of BQL are demonstrated in the benchmark results below. > These were made running 200 stream of netperf RR tests: > > 140000 rr size > BQL: 80-215K bytes in queue, 856 tps, 3.26% > No BQL: 2700-2930K bytes in queue, 854 tps, 3.71% cpu tps +0.23 % > 14000 rr size > BQ: 25-55K bytes in queue, 8500 tps > No BQL: 1500-1622K bytes in queue, 8523 tps, 4.53% cpu tps -0.27 % > 1400 rr size > BQL: 20-38K in queue bytes in queue, 86582 tps, 7.38% cpu > No BQL: 29-117K 85738 tps, 7.67% cpu tps +0.98 % > 140 rr size > BQL: 1-10K bytes in queue, 320540 tps, 34.6% cpu > No BQL: 1-13K bytes in queue, 323158, 37.16% cpu tps -0.81 % > 1 rr size > BQL: 0-3K in queue, 338811 tps, 41.41% cpu > No BQL: 0-3K in queue, 339947 42.36% cpu tps -0.33 % > The amount of queuing in the NIC is reduced up to 90%, and I haven't > yet seen a consistent negative impact in terms of throughout or > CPU utilization. I don't quite follow your conclusion from your data. While there was a sweet spot for the 1400 rr size, other smaller rr took a hit. Now all the tps changes were within 1 %, so perhaps that isn't considered significant (I'm not qualified to make that call). But if that's the case, then the effective latency change seen by the user isn't significant either, although the amount of queuing in the NIC is admittedly significantly reduced for a rr size of 1400 or larger. -Bill