i.MX6 Gigabit Ethernet

Published on December 19, 2012

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We've recently been doing some digging into Gigabit Ethernet performance issues and questions for our i.MX6 boards and it's time to publish some of our results. We've discovered a number of settings and code updates that can dramatically improve network stability and throughput.

For the impatient

There are some architectural limitations on i.MX6 boards but some configuration options and driver issues are more likely to cause performance issues. We've identified a number of fixes that make the situation markedly better as shown below.

Before (TCP)

root@linaro-nano:~# cat /proc/cmdline video=mxcfb0:dev=hdmi,1280x720M@60,if=RGB24 video=mxcfb1:off video=mxcfb2:off ... root@linaro-nano:~# cat /proc/version Linux version 3.0.35-2026-geaaf30e (b21710@bluemeany) ... root@linaro-nano:~# while iperf -c 192.168.0.162 -r | grep Mbits ; do echo -n ; done [ 5] 0.0-10.0 sec 474 MBytes 397 Mbits/sec [ 4] 0.0-10.1 sec 10.1 MBytes 8.47 Mbits/sec [ 5] 0.0-10.0 sec 474 MBytes 397 Mbits/sec [ 4] 0.0-10.0 sec 10.4 MBytes 8.72 Mbits/sec [ 5] 0.0-10.0 sec 472 MBytes 396 Mbits/sec [ 4] 0.0-10.0 sec 17.2 MBytes 14.4 Mbits/sec  

After (TCP)

root@linaro-nano:~# cat /proc/cmdline enable_wait_mode=off video=mxcfb0:dev=hdmi,1280x720M@60,if=RGB24 video=mxcfb1:off ... root@linaro-nano:~# cat /proc/version Linux version 3.0.35-2026-geaaf30e-02076-g68b5fa7 ... root@linaro-nano:~# while iperf -c 192.168.0.162 -r | grep Mbits ; do echo -n ; done [ 5] 0.0-10.0 sec 473 MBytes 397 Mbits/sec [ 4] 0.0-10.0 sec 509 MBytes 426 Mbits/sec [ 5] 0.0-10.0 sec 473 MBytes 397 Mbits/sec [ 4] 0.0-10.0 sec 508 MBytes 426 Mbits/sec [ 5] 0.0-10.0 sec 471 MBytes 395 Mbits/sec [ 4] 0.0-10.0 sec 510 MBytes 427 Mbits/sec   In the output from iperf above, each pair of lines indicate the transmit and receive bandwidth in that order. Note the horrible performance numbers for receive in the baseline. The UDP performance is markedly better, with transmit throughput of ~450 Mbits/s and receive speeds that can exceed 600 Mbits/s.

After (UDP)

[  4]  0.0- 1.0 sec  55.3 MBytes   462 Mbits/sec  0.084 ms   15/39459 (0.038%)
[  3]  0.0- 1.0 sec  72.8 MBytes   611 Mbits/sec  0.012 ms   -1/51843 (-0.0019%)
  The details below will provide details of how we tested things, and describe a series of patches that lead to this improvement in both stability and speed.

Test environment

Four devices were used during the tests defined below:
  • A Sony Vaio laptop with internal Gb Ethernet adapter,
  • A Nitrogen6X board with i.MX6Quad TO 1.0
  • A SABRE SD board with i.MX6Quad TO 1.1
  • A SABRE Lite board with i.MX6Quad TO 1.2
  • A Cisco Linksys SE2500 Gigabit Ethernet switch
The tests used a Linaro nano userspace. A tar-ball is available here that contains all of the kernel versions mentioned. Specific baseline kernel versions include:
  • Blue Meany - This is the binary kernel (uImage) provided in the images_L3.0.35_12.09.01-GA release. We did not re-compile this kernel.
  • Boundary Before - This is the first version we compiled, as a test to ensure that it matches Blue Meany and serves as the baseline for this series of tests.
  • Boundary Latest - This is the latest release from the boundary-L3.0.35_12.09.01-GA branch of our Github kernel.
All of the testing was done with kernels based on Freescale's L3.0.35_12.09.01_GA release with various patches as described.

First change: enable_wait_mode=off

We've documented the first change made in this post a week ago, but we didn't mention the throughput implications. In the output below, you can see around a 10% improvement in the Blue Meany kernel by just adding enable_wait_mode=off to the kernel command-line. This change made a huge difference on Tapeout 1.2. It increased the receive speed from on the order of 10 Mbits/s to ~200 Mbits/s. on Tapeout 1.0 devices, the difference was less dramatic, presumably because a number of the spots that use enable_wait_mode in the kernel are also conditional on the silicon revision. In any case, with just this change, both revisions of board have markedly increased receive performance as shown below. root@linaro-nano:~# cat /proc/version Linux version 3.0.35-2026-geaaf30e (b21710@bluemeany)... root@linaro-nano:~# cat /proc/cmdline enable_wait_mode=off ... root@linaro-nano:~# while iperf -c 192.168.0.162 -r | grep Mbits ; do echo -n ; done [ 5] 0.0-10.0 sec 443 MBytes 372 Mbits/sec [ 4] 0.0-10.0 sec 250 MBytes 210 Mbits/sec [ 5] 0.0-10.0 sec 476 MBytes 399 Mbits/sec [ 4] 0.0-10.0 sec 252 MBytes 211 Mbits/sec ^C As noted in the previous post, this environment update will also make ping times more consistent.

Measuring performance

In the summary above, we showed the output from the simplest invocation of iperf. When used as shown, the program will connect over TCP: root@linaro-nano:~# iperf -c 192.168.0.162 -r ------------------------------------------------------------ Server listening on TCP port 5001 TCP window size: 85.3 KByte (default) ------------------------------------------------------------ ------------------------------------------------------------ Client connecting to 192.168.0.162, TCP port 5001 TCP window size: 58.4 KByte (default) ------------------------------------------------------------ [ 5] local 192.168.0.119 port 52681 connected with 192.168.0.162 port 5001 [ ID] Interval Transfer Bandwidth [ 5] 0.0-10.0 sec 475 MBytes 398 Mbits/sec [ 4] local 192.168.0.119 port 5001 connected with 192.168.0.162 port 42421 [ 4] 0.0-10.0 sec 228 MBytes 191 Mbits/sec Because of the use of TCP, flow control is imposed on the link by the upper layers, and the bandwidth is throttled to the slower of the speeds of the two ends. Using UDP removes this possible bottleneck and also allows a flag to set the target bandwidth (-b SPEED) and will show us the amount of packet loss. The -t flag allows us to override the default 10 second test for quicker results. root@linaro-nano:~# iperf -c 192.168.0.162 -r -u -b 200M -t 2 ------------------------------------------------------------ Server listening on UDP port 5001 Receiving 1470 byte datagrams UDP buffer size: 106 KByte (default) ------------------------------------------------------------ ------------------------------------------------------------ Client connecting to 192.168.0.162, UDP port 5001 Sending 1470 byte datagrams UDP buffer size: 106 KByte (default) ------------------------------------------------------------ [ 4] local 192.168.0.119 port 51275 connected with 192.168.0.162 port 5001 [ ID] Interval Transfer Bandwidth [ 4] 0.0- 2.0 sec 48.2 MBytes 202 Mbits/sec [ 4] Sent 34359 datagrams [ 4] Server Report: [ 4] 0.0- 2.0 sec 48.1 MBytes 202 Mbits/sec 0.063 ms 71/34358 (0.21%) [ 4] 0.0- 2.0 sec 1 datagrams received out-of-order [ 3] local 192.168.0.119 port 5001 connected with 192.168.0.162 port 53796 [ 3] 0.0- 2.0 sec 48.3 MBytes 203 Mbits/sec 0.038 ms 0/34483 (0%) [ 3] 0.0- 2.0 sec 1 datagrams received out-of-order Doing a quick smoke-test at a few key rates shows some interesting results. The following are slightly edited to make them more readable:

100Mbit/s UDP test

root@linaro-nano:~# iperf -c 192.168.0.162 -u -r -b 100M ; [ 4] 0.0- 2.0 sec 23.9 MBytes 100 Mbits/sec 0.048 ms 0/17082 (0%) [ 3] 0.0- 2.0 sec 24.0 MBytes 101 Mbits/sec 0.001 ms 3/17094 (0.018%)

400Mbit/s UDP test

root@linaro-nano:~# iperf -c 192.168.0.162 -u -r -b 400M -t 2; [ 4] 0.0- 2.0 sec 34.1 MBytes 143 Mbits/sec 0.091 ms 0/24338 (0%) [ 3] 0.0- 5.7 sec 205 MBytes 301 Mbits/sec 0.013 ms 198303/344825 (58%)

1Gbit/s UDP test

root@linaro-nano:~# iperf -c 192.168.0.162 -u -r -b 1000M -t 2; [ 4] 0.0- 2.0 sec 108 MBytes 453 Mbits/sec 0.036 ms 54/77241 (0.07%) [ 3] 0.0- 2.1 sec 64.9 MBytes 254 Mbits/sec 15.539 ms 95165/141465 (67%) As you can see, there's no loss at 100M, very little loss at 400M and a huge amount of receiver loss at 1G (the second line reports the receiver numbers). Interestingly, the received bandwidth also decreased when going from 400M to 1Gbit/s. Using a script to be a bit more thorough, and convince ourselves that the pattern holds: root@linaro-nano:~# cat > bwtest.sh << EOF #!/bin/sh bw=50; while [ $bw -le 1000 ]; do echo "----------bandwidth $bw" ; iperf -c 192.168.0.162 -u -r -t 2 -b ${bw}M | grep % ; bw=`expr $bw + 50` ; done EOF root@linaro-nano:~# chmod a+x bwtest.sh root@linaro-nano:~# ./bwtest.sh root@linaro-nano:~# ./bwtest.sh ----------bandwidth 50 [ 4] 0.0- 2.0 sec 11.9 MBytes 50.0 Mbits/sec 0.010 ms 0/ 8510 (0%) [ 3] 0.0- 2.0 sec 11.9 MBytes 50.0 Mbits/sec 0.002 ms 0/ 8511 (0%) ----------bandwidth 100 [ 4] 0.0- 2.0 sec 24.0 MBytes 100 Mbits/sec 0.048 ms 0/17085 (0%) [ 3] 0.0- 2.0 sec 24.0 MBytes 100 Mbits/sec 0.009 ms 4/17094 (0.023%) ----------bandwidth 150 [ 4] 0.0- 2.0 sec 35.9 MBytes 150 Mbits/sec 0.063 ms 8/25601 (0.031%) [ 3] 0.0- 2.0 sec 35.9 MBytes 151 Mbits/sec 0.010 ms 0/25641 (0%) ----------bandwidth 200 [ 4] 0.0- 2.0 sec 48.2 MBytes 202 Mbits/sec 0.066 ms 0/34413 (0%) [ 3] 0.0- 2.0 sec 48.3 MBytes 203 Mbits/sec 0.028 ms 0/34483 (0%) ----------bandwidth 250 [ 4] 0.0- 2.0 sec 59.2 MBytes 248 Mbits/sec 0.056 ms 52/42246 (0.12%) [ 3] 0.0- 2.0 sec 59.7 MBytes 250 Mbits/sec 0.028 ms 0/42553 (0%) ----------bandwidth 300 [ 4] 0.0- 2.0 sec 71.7 MBytes 301 Mbits/sec 0.030 ms 55/51222 (0.11%) [ 3] 0.0- 2.0 sec 71.8 MBytes 302 Mbits/sec 0.024 ms 33/51282 (0.064%) ----------bandwidth 350 [ 4] 0.0- 2.0 sec 83.8 MBytes 352 Mbits/sec 0.040 ms 87/59888 (0.15%) [ 3] 0.0- 2.0 sec 83.7 MBytes 355 Mbits/sec 0.018 ms 868/60606 (1.4%) ----------bandwidth 400 [ 4] 0.0- 2.0 sec 95.6 MBytes 401 Mbits/sec 0.043 ms 5/68180 (0.0073%) [ 3] 0.0- 2.0 sec 90.2 MBytes 379 Mbits/sec 0.012 ms 4601/68965 (6.7%) ----------bandwidth 450 [ 4] 0.0- 2.0 sec 105 MBytes 440 Mbits/sec 0.036 ms 369/75113 (0.49%) [ 3] 0.0- 2.0 sec 98.9 MBytes 415 Mbits/sec 0.013 ms 6388/76922 (8.3%) ----------bandwidth 500 [ 4] 0.0- 2.0 sec 110 MBytes 460 Mbits/sec 0.031 ms 36/78302 (0.046%) [ 3] 0.0- 2.0 sec 99.5 MBytes 420 Mbits/sec 0.010 ms 15956/86956 (18%) ----------bandwidth 550 [ 4] 0.0- 2.0 sec 110 MBytes 459 Mbits/sec 0.031 ms 22/78186 (0.028%) [ 3] 0.0- 2.0 sec 105 MBytes 440 Mbits/sec 0.008 ms 20359/95236 (21%) ----------bandwidth 600 [ 4] 0.0- 2.0 sec 109 MBytes 456 Mbits/sec 0.034 ms 0/77709 (0%) [ 3] 0.0- 2.0 sec 90.7 MBytes 381 Mbits/sec 0.009 ms 40526/105254 (39%) ----------bandwidth 650 [ 4] 0.0- 2.0 sec 109 MBytes 458 Mbits/sec 0.035 ms 0/77991 (0%) [ 3] 0.0- 2.2 sec 91.2 MBytes 340 Mbits/sec 15.658 ms 46033/111110 (41%) ----------bandwidth 700 [ 4] 0.0- 2.0 sec 109 MBytes 458 Mbits/sec 0.034 ms 111/78120 (0.14%) [ 3] 0.0- 1.9 sec 82.6 MBytes 358 Mbits/sec 0.009 ms 66049/124997 (53%) ----------bandwidth 750 [ 4] 0.0- 2.0 sec 110 MBytes 463 Mbits/sec 0.031 ms 62/78837 (0.079%) [ 3] 0.0- 2.2 sec 82.0 MBytes 311 Mbits/sec 15.645 ms 74847/133328 (56%) ----------bandwidth 800 [ 4] 0.0- 2.0 sec 109 MBytes 458 Mbits/sec 0.029 ms 11/78013 (0.014%) [ 3] 0.0- 2.0 sec 75.1 MBytes 315 Mbits/sec 0.006 ms 88480/142033 (62%) ----------bandwidth 850 [ 4] 0.0- 2.0 sec 109 MBytes 456 Mbits/sec 0.056 ms 10/77684 (0.013%) [ 3] 0.0- 2.2 sec 70.2 MBytes 262 Mbits/sec 15.214 ms 99717/149777 (67%) ----------bandwidth 900 [ 4] 0.0- 2.0 sec 109 MBytes 457 Mbits/sec 0.032 ms 85/77943 (0.11%) [ 3] 0.0- 2.0 sec 69.4 MBytes 290 Mbits/sec 0.009 ms 100431/149932 (67%) ----------bandwidth 950 [ 4] 0.0- 2.0 sec 108 MBytes 451 Mbits/sec 0.075 ms 0/76778 (0%) [ 3] 0.0- 2.2 sec 71.4 MBytes 266 Mbits/sec 15.250 ms 91053/142012 (64%) ----------bandwidth 1000 [ 4] 0.0- 2.0 sec 108 MBytes 453 Mbits/sec 0.076 ms 0/77143 (0%) [ 3] 0.0- 1.9 sec 71.2 MBytes 311 Mbits/sec 0.029 ms 90616/141376 (64%) From this, it's pretty clear that the transmit throughput rises pretty linearly to ~450 Mbits/s and stays there. The receiver bandwidth scales linearly to ~400 Mbits/s and then starts losing ground as the rate increases. Also note that we don't lose packets on the transmit side, only on the receiver side.

Cratering performance

Using UDP also exposed some issues on the boundary kernel. Using the boundary-before kernel, we see that the receive performance degrades as the bandwidth is increased past 400M. Note that this test has an updated bwtest.sh script that allows the test time to be set through the tsecs environment variable and the bandwidth increment to be set through incr. root@linaro-nano:~# tsecs=2 incr=200 ./bwtest.sh ----------bandwidth 200 [ 4] 0.0- 2.0 sec 48.1 MBytes 203 Mbits/sec 0.061 ms 164/34479 (0.48%) [ 3] 0.0- 2.0 sec 48.3 MBytes 203 Mbits/sec 0.034 ms 0/34483 (0%) ----------bandwidth 400 [ 4] 0.0- 2.0 sec 96.5 MBytes 405 Mbits/sec 0.040 ms 67/68911 (0.097%) [ 3] 0.0- 1.9 sec 93.9 MBytes 406 Mbits/sec 0.035 ms 1990/68965 (2.9%) ----------bandwidth 600 [ 4] 0.0- 2.0 sec 110 MBytes 460 Mbits/sec 0.030 ms 234/78615 (0.3%) [ 3] 0.0- 2.3 sec 110 MBytes 410 Mbits/sec 15.672 ms 26703/105262 (25%) ----------bandwidth 800 [ 4] 0.0- 2.0 sec 110 MBytes 461 Mbits/sec 0.033 ms 0/78511 (0%) [ 3] 0.0- 2.2 sec 2.91 MBytes 11.1 Mbits/sec 101.865 ms 140266/142342 (99%) ----------bandwidth 1000 [ 4] 0.0- 2.0 sec 110 MBytes 461 Mbits/sec 0.033 ms 0/78383 (0%) [ 3] 0.0- 0.2 sec 90.4 KBytes 3.18 Mbits/sec 110.420 ms 141295/141358 (1e+02%) This one took a while to find because it turned out to not be a code change between Blue Meany and our source tree, but a configuration change to enable a new driver API (NAPI). This API is is described on this web page. It is an architecture to decrease the interrupt overhead on high-performance networks. When enabled, the interrupt handler in the FEC driver schedules but does not process incoming packets. Instead, those are handled out of interrupt context. The change to our config file is trivial, but performance is much better at higher speeds as shown below: ----------bandwidth 200 [ 5] 0.0- 2.0 sec 48.1 MBytes 203 Mbits/sec 0.063 ms 153/34482 (0.44%) [ 3] 0.0- 2.0 sec 48.3 MBytes 203 Mbits/sec 0.029 ms 0/34483 (0%) ----------bandwidth 400 [ 4] 0.0- 2.0 sec 96.4 MBytes 404 Mbits/sec 0.052 ms 151/68888 (0.22%) [ 3] 0.0- 1.9 sec 85.5 MBytes 381 Mbits/sec 0.018 ms 7949/68965 (12%) ----------bandwidth 600 [ 4] 0.0- 2.0 sec 109 MBytes 458 Mbits/sec 0.075 ms 269/78262 (0.34%) [ 3] 0.0- 1.9 sec 102 MBytes 447 Mbits/sec 0.007 ms 32747/105262 (31%) ----------bandwidth 800 [ 4] 0.0- 2.0 sec 110 MBytes 461 Mbits/sec 0.090 ms 0/78464 (0%) [ 3] 0.0- 2.0 sec 82.2 MBytes 347 Mbits/sec 0.006 ms 84223/142847 (59%) ----------bandwidth 1000 [ 4] 0.0- 2.0 sec 110 MBytes 461 Mbits/sec 0.072 ms 123/78698 (0.16%) [ 3] 0.0- 2.1 sec 70.6 MBytes 278 Mbits/sec 15.230 ms 91863/142251 (65%) Note that there's still a lot of loss at rates of 400M and above.

How to improve this

Where is that loss coming from? If we look at ifconfig we can see that the network driver is aware of the dropped packets: root@linaro-nano:~# ifconfig eth0 eth0 Link encap:Ethernet HWaddr 00:19:b8:00:fa:9a inet addr:192.168.0.119 Bcast:192.168.0.255 Mask:255.255.255.0 UP BROADCAST RUNNING MULTICAST MTU:1500 Metric:1 RX packets:3901387 errors:782502 dropped:0 overruns:782502 frame:782502 TX packets:3775053 errors:0 dropped:0 overruns:0 carrier:0 collisions:0 txqueuelen:1000 RX bytes:4178248807 (4.1 GB) TX bytes:853327178 (853.3 MB) The condition that increments the overrun count is here. Table 23-85 in the i.MX6DQ Reference Manual says that this means "A receive FIFO overrun occurred during frame reception". The i.MX6DQ Errata document states in Errata ERR004512 that the maximum performance "is limited to 470 Mbps (total for Tx and Rx)". The errata doesn't say what the precise symptom of exceeding that limit might be, but this sure looks like it. The numbers above are pretty close to the 400Mbit/s reported in the errata. It turns out that we can do something about this. The Ethernet spec calls for a form of flow control using something called "pause frames", which allows a receiver to tell a sender to back off for a quantum of time. That's what this patch does. The very first part of the commit shows the addition of SUPPORTED_Pause to the phy device for i.MX6Quad and i.MX6DualLite processors. That part is key.

Sidebar: check out some other tools

Before we go too much further, we need to introduce a couple of key tools to understanding this. The first is a tool called ethtool. It is designed to allow you control the low-level functions of a network adapter. We'll use it to see the state of the link negotiation. The second is a tool we developed named devregs. It is designed to allow access to device registers through /dev/mem. You can find details in this post. The post describes the use of the program on i.MX5x, but it's perfectly happy to run on i.MX6 and we have a lot of registers defined in devregs_imx6x.dat. Let's look at the output before and after the patch:

Before

root@linaro-nano:~# cat /proc/version Linux version 3.0.35-2026-geaaf30e (b21710@bluemeany) root@linaro-nano:~# ethtool eth0 Settings for eth0: Supported ports: [ TP MII ] Supported link modes: 10baseT/Half 10baseT/Full 100baseT/Half 100baseT/Full 1000baseT/Half 1000baseT/Full Supported pause frame use: No Supports auto-negotiation: Yes Advertised link modes: 10baseT/Half 10baseT/Full 100baseT/Half 100baseT/Full 1000baseT/Half 1000baseT/Full Advertised pause frame use: No Advertised auto-negotiation: Yes Speed: 1000Mb/s Duplex: Full Port: MII PHYAD: 6 Transceiver: external Auto-negotiation: on Link detected: yes root@linaro-nano:~# devregs ENET_RCR ENET_RCR:0x02188084 =0x05ee0244

After

root@linaro-nano:~# cat /proc/version root@linaro-nano:~# cat /proc/version Linux version 3.0.35-2026-geaaf30e-02074-g92a9e1e ... root@linaro-nano:~# ethtool eth0 Settings for eth0: Supported ports: [ TP MII ] Supported link modes: 10baseT/Half 10baseT/Full 100baseT/Half 100baseT/Full 1000baseT/Half 1000baseT/Full Supported pause frame use: Symmetric Supports auto-negotiation: Yes Advertised link modes: 10baseT/Half 10baseT/Full 100baseT/Half 100baseT/Full 1000baseT/Half 1000baseT/Full Advertised pause frame use: Symmetric Advertised auto-negotiation: Yes Speed: 1000Mb/s Duplex: Full Port: MII PHYAD: 6 Transceiver: external Auto-negotiation: on Link detected: yes root@linaro-nano:~# devregs ENET_RCR ENET_RCR:0x02188084 =0x05ee0264 The key things to look at are the line that says "Supported pause frame use" and the line that shows the ENET_RCR register. Bit 5 of the ENET_RCR enables flow control (generation of pause frames) if set, and you can see that after the patch, flow control is enabled. Unfortunately, the situation is still much the same: The receive error numbers using bwtest.sh start rising and the bandwidth starts falling as we exceed 450 MBits/s.

Pause frames on TO1.0

The next patch in the series fixes this. It turns out that tweaking the default almost empty threshold on Tapeout 1.0 helps the situation, as does increasing the receive FIFO section full register. After applying this patch, we can see stable results when we overload the ethernet receiver. Note that we've also added a couple of lines to bwtest.sh to read the values of the ENET_IEEE_T_FDXFC and ENET_IEEE_R_MACERR statistics registers. These tell us how many pause frames were transmitted and how many receive FIFO overruns are seen. root@linaro-nano:~# tsecs=2 incr=200 ./bwtest.sh ----------bandwidth 200 [ 4] 0.0- 1.7 sec 40.1 MBytes 203 Mbits/sec 50.557 ms 176/28804 (0.61%) [ 3] 0.0- 2.0 sec 48.3 MBytes 203 Mbits/sec 0.034 ms 0/34483 (0%) ENET_IEEE_T_FDXFC:0x02188270 =0x00000d6c ENET_IEEE_R_MACERR:0x021882d8 =0x00000000 ----------bandwidth 400 [ 4] 0.0- 2.0 sec 96.5 MBytes 405 Mbits/sec 0.043 ms 103/68952 (0.15%) [ 3] 0.0- 1.9 sec 90.0 MBytes 406 Mbits/sec 0.021 ms 4751/68965 (6.9%) ENET_IEEE_T_FDXFC:0x02188270 =0x00001ad0 ENET_IEEE_R_MACERR:0x021882d8 =0x00000000 ----------bandwidth 600 [ 4] 0.0- 2.0 sec 110 MBytes 462 Mbits/sec 0.056 ms 0/78679 (0%) [ 3] 0.0- 1.9 sec 129 MBytes 583 Mbits/sec 0.061 ms 4750/96927 (4.9%) ENET_IEEE_T_FDXFC:0x02188270 =0x0000f544 ENET_IEEE_R_MACERR:0x021882d8 =0x00000000 ----------bandwidth 800 [ 4] 0.0- 2.0 sec 110 MBytes 461 Mbits/sec 0.030 ms 92/78732 (0.12%) [ 3] 0.0- 2.0 sec 138 MBytes 580 Mbits/sec 0.062 ms 20/98693 (0.02%) ENET_IEEE_T_FDXFC:0x02188270 =0x00000310 ENET_IEEE_R_MACERR:0x021882d8 =0x00000000 ----------bandwidth 1000 [ 4] 0.0- 2.0 sec 107 MBytes 449 Mbits/sec 0.060 ms 465/76969 (0.6%) [ 3] 0.0- 1.9 sec 129 MBytes 583 Mbits/sec 0.021 ms 4687/96830 (4.8%) ENET_IEEE_T_FDXFC:0x02188270 =0x0000f482 ENET_IEEE_R_MACERR:0x021882d8 =0x00000000 Now that's better! We're seeing no FIFO overruns even up to 1G and a substantial increase in receive performance. Tapeout 1.2 shows even better performance, peaking at over 630 Mbit/s.

Final changes

The final two patches are really belt and suspenders updates. The first sets the Frame truncation receive length register so a FIFO error will not result in an extra long frame and spew error messages to the kernel log. The second treats frames with FIFO errors in the same way as framing errors and doesn't forward them to the network stack for processing. We found that this increased performance in the presence of FIFO overruns.

Recap

We've uploaded the SD card image used in this testing so that you can repeat our results: If you format a single-partition SD card as ext3, you can extract it like so: ~/$ sudo mkfs.ext3 -L iperf /dev/sdc1 ~/$ udisks --mount /dev/sdc1 ... Assuming auto-mount as /media/iperf ~/$ sudo tar -C /media/iperf/ -zxvf imx6-iperf-test-20121214.tar.gz ~/$ sync && sudo umount /media/iperf As mentioned earlier, this started off as a Linaro nano filesystem. We updated it to include a boot script, the devregs program and each of the kernels used in the tests above. The SD card image has each in the /boot directory. We encourage you to download the image, test it out on your boards and report back. Note that we haven't yet updated the Android kernel tree, but will do that shortly. We'll also be testing i.MX6 Solo, Dual-Lite, and the new SABRE SDB boards in upcoming days. Stay tuned to the blog for updates. If you're using Gigabit ethernet, you're likely to see improvements by adopting these updates.