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plget is a tool used to measure latency packets spent in network stack, NIC driver and on the wire, trace interpacket gap, based as on h/w as on sw timestamping, as for rx as for tx path, measure speed and more ...

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INTRODUCTION

plget is a tool used to measure latency packets spent in network stack, NIC driver and on the wire, trace interpacket gap, based as on h/w as on sw timestamping, as for RX as for TX path. It can be used to measure complete latency from wire to an application and from an application to wire, round trip time (RTT) and more. The plget tool uses socket interface and works with UDP and PTP l2/l4 packets.

Can be useful for developers to trace hw timestamps when packets were sent or received in case of some shaping verification, like CBS Qdisc in both, offload and not offload modes, observe interpacket gap, inverstigate interchannel impact and so on. In case if h/w timestamping is not supported or partly supported, the sw timestamps are used, but not for everything. All timestamps are bind to the packet, so no need in any additional tracing tools and tracing impact is moved to the minimum. Usually PHC counter is running on the same timeline with system counter, but their synchronization can be done only once at driver initialization. To avoid mistiming while stack latency measurements, the phc2sys tool from linux ptp packet should be running: "phc2sys -s CLOCK_REALTIME -c eth0 -m -O 0". It allows to keep in sync two time counters in sub-microsecond level accuracy, for TI AM572x it was ~172ns in average, depends on discreteness of timers and their accuracy).

One of the possible test models:

PURPOSE

This tool can do the following:

  • packet latency for networking stack for RX and TX
  • NIC driver latency (hw timestamping is required) for RX and TX
  • round trip time (RTT), NIC->server->NIC (hw timestamping is advisable)
  • tracing interpacket gap (hw timestamping is required) for RX and TX
  • tracing time of sending (hw timestamping is required)
  • figuring out bottlenecks for hi priority packets
  • figuring out interclass impact for AVB
  • speed based on h/w or s/w timestamps + packet generator
  • ...

HOW TO BUILD

For regular sockets

:~# make #for native
:~# export ARCH=arm; export CROSS_COMPILE=arm-linux-gnueabihf-; make #for cross
:~# export ARCH=arm; export CC=arm-linux-gnueabihf-gcc; make #for cross

For regular + af_xdp sockets

This is not required and not everywhere present. Except plget, it requires also kernel patching for now (no generic LK support), can be found under ./linux, at this moment only for cpsw . At this moment here is only patch for TI cpsw driver that can be used as an example: ./linux/afxdp_cpsw_ts_LK_5.0.patch

For AF_XDP sockets plget requires at least libbpf library, and it can be integrated with RFS environment so for cross-compilation SYSROOT address can be provided. And, if RFS doesn't have libbpf installed, then libbpf can be built along with plget but to do this first fetch sources doing the following (unless it's cloned with --recurse-submodules):

:~# git submodule init
:~# git submodule update

Build with AF_XDP support adding AFXDP=1:

:~# make ARCH=arm CROSS_COMPILE=arm-linux-gnueabihf- \
	AFXDP=1 SYSROOT="path to RFS"

Along with plget binary, the xsock_dispatch.o ebpf prog has to be copied on target board, if rx-lat mode is being used.

HELP

Possible packet/sock types, set with -t key:

  • -t raw_ptpl2 socket(AF_PACKET, SOCK_RAW, 0)
  • -t xdp_ptpl2 socket(AF_XDP, SOCK_RAW, 0)
  • -t ptpl2 socket(AF_PACKET, SOCK_DGRAM, ETH_P_1588)
  • -t avtp socket(AF_PACKET, SOCK_DGRAM, ETH_P_TSN)
  • -t ptpl4 socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP)
  • -t udp socket(AF_INET, SOCK_DGRAM, IPPROTO_UDP)

For aggressive packet retrieve use combinations of -w and -o "sw_poll" options.

More info is here:

:~# plget -h

PRINTOUTS

Printout can be tuned with -f option. "hwts" means print h/w timestamps (if they are present ofc) normalized to first packet timestamp, as absolute time is not relevant, "ipgap" means time between neighbor h/w timestamps and useful to see how h/w shaping behaves in case of several streams etc. The "lat" is set by default, but only if -f option is not used. All can be used in one line "-f lat,hwts,ipgap". Also, if stack latency before entering packet scheduler is needed, -f "sched" can be used, relevant only for modes with TX, like echo-lat, rtt, tx-lat. Also if no worries about printing progress bar while measurements, the -o "rt_print" can be set.

To get plots and histograms for measured data just run from plget_plot:

:~# plgist plget_stdout_file

EXAMPLES

RX LATENCY EXAMPLES

				examples scheme
  +-----------------+      +-------------------------------------------------+
  |  WORKSTATION    |      |                   TARGET BOARD                  |
  |-----------------|      |---------------------------+---------------------|
  |                 |      |        Kernel space       |     User space      |
  |                 |      |------------+--------------+---------------------|
  |                 |      | NIC driver | Net stack    | RT application      |
  |                 |      |---+        +---+          +---+                 |
  | client          |      |ts1|        |ts2|          |ts3| plget -m rx-lat |
  | pkt generator   |=====>|   |------->|   |--------->|   |            ...  |
  | plget -m tx-lat |      |PHC|        |SYS|          |SYS|                 |
  |            ...  |      |CLK|        |CLK|          |CLK|                 |
  |                 |      |---\        +---\          +---\                 |
  |                 |      |    \       |    \         |    \  phc2sys       |
  |                 |      |     \______|_____\________|_____\___            |
  |                 |      |            |              |       sync          |
  +-----------------+      +-------------------------------------------------+

For all examples run phc2sys, to keep PHC and system clock in sync, if h/w timestamping is supported ofc:

:~# phc2sys -s CLOCK_REALTIME -c eth0 -m -O 0 > /dev/null &

Use "-f lat,hwts,ipgap" if more printouts are needed, see "plget -h", as for the target board as for the server (if you need server latency too).

Example 1: UDP RX latency


Measure RX latency for UDP packets, port 385.

On target board (192.168.3.16):

:~# plget -i eth0 -t udp -u 385 -m rx-lat -n 16

On client side generate appropriate packets:

:~# plget -i eth0 -t udp -u 385 -m tx-lat -n 16 -s 100 -l 512 -a 192.168.3.16

Example 2: PTP l4 RX latency


Measure RX latency for PTP l4 packets (port 319), useful if the driver supports h/w timestamping only for PTP kind packets.

On target board (192.168.3.16):

:~# plget -i eth0 -t udp -u 319 -m rx-lat -n 16
or
:~# plget -i eth0 -t ptpl4 -m rx-lat -n 16

On client side generate appropriate packets:

:~# plget -i eth0 -t udp -u 319 -m tx-lat -n 16 -s 100 -l 512 -a 192.168.3.16
or
:~# plget -i eth0 -t ptpl4 -m tx-lat -n 16 -s 100 -l 512 -a 192.168.3.16

Example 3: AVTP RX latency


Measure RX latency for avtp packets (IEEE 1722)

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t avtp -m rx-lat -n 16

On client side generate appropriate packets:

:~# plget -i eth0 -t avtp -m tx-lat -n 16 -s 100 -l 512 -a c8:a0:30:b4:94:03

Example 4: PTP l2 RX latency


Measure RX latency for ptpl2 packets (IEEE 1588)

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t ptpl2 -m rx-lat -n 1600

On client side generate appropriate packets:

:~# plget -i eth0 -t ptpl2 -m pkt-gen -n 1600 -l 512 -s 400 -a 74:da:ea:47:7d:9d

If address is not set for pkt-gen or tx-lat modes then default multicast address is used: 01:1B:19:00:00:00 in this case rx-lat should set address explicitly.

Example 5: PTP l2 RX latency using raw sockets


Measure RX latency for ptpl2 packets (IEEE 1588)

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t raw_ptpl2 -m rx-lat -n 1600
or
:~# plget -i eth0 -t xdp_ptpl2 -m rx-lat -n 1600

On client side generate appropriate packets:

:~# plget -i eth0 -t ptpl2 -m pkt-gen -n 1600 -l 512 -s 400 -a 74:da:ea:47:7d:9d

If address is not set for pkt-gen or tx-lat modes then default multicast address is used: 01:1B:19:00:00:00 in this case rx-lat should set address explicitly.

TX LATENCY EXAMPLES

		  examples scheme
+-------------------------------------------------+
|                   TARGET BOARD                  |
|---------------------+---------------------------|
|     User space      |        Kernel space       |
|---------------------+--------------+------------|
| RT application      | Net stack    | NIC driver |
|                 +---|          +---|        +---|
|                 |ts1|          |ts2|        |ts3|
| plget -m tx-lat |   |--------->|   |------->|   |====> Eth
|                 |SYS|          |SYS|        |PHC|
|                 |CLK|          |CLK|        |CLK|
|                 /---|          /---|        /---|
|       phc2sys  /    |         /    |       /    |
|       ________/_____|________/_____|______/     |
|       sync          |              |            |
+-------------------------------------------------+

No need in any additional network nodes to be involved. For all examples run phc2sys, to keep PHC and system clock in sync, if h/w timestamping is supported ofc:

:~# phc2sys -s CLOCK_REALTIME -c eth0 -m -O 0 > /dev/null &

Use "-f lat,hwts,ipgap" if more printouts are needed, see "plget -h".

Example 1: UDP TX latency


Measure TX latency for UDP packets, port 385.

:~# plget -i eth0 -t udp -u 385 -m tx-lat -n 16 -s 100 -l 512 -a 192.168.2.1

Example 2: PTP l4 TX latency


Measure TX latency for PTP l4 packets (port 319), useful if a driver supports h/w timestamping only for PTP kind packets.

:~# plget -i eth0 -t udp -u 319 -m tx-lat -n 16 -s 100 -l 512

Example 3: AVTP TX latency


Measure TX latency for avtp packets (IEEE 1722).

:~# plget -i eth0 -t avtp -m tx-lat -n 16 -s 10 -l 512 -a 74:da:ea:47:7d:9d

Example 4: PTP l2 TX latency


Measure TX latency for ptpl2 packets (IEEE 1588)

:~# plget -i eth0 -t ptpl2 -m tx-lat -n 160 -l 512 -s 10 -a 74:da:ea:47:7d:9d

If address is not specified then 01:1B:19:00:00:00 is used.

Example 5: PTP l2 TX latency and its packet scheduler part


Measure TX latency for ptpl2 packet, but also get latency in packet scheduler (IEEE 1588)

:~# plget -if=eth0 --type=ptpl2 --mode=tx-lat --pkt-num=16 --frame-size=512 \
--format=sched,lat --pps=100

or if vlan is used (one more sched ts):

:~# plget -if=eth0.100 --type=ptpl2 --mode=tx-lat --pkt-num=16 \
--frame-size=512 --format=sched,lat --pps=100 --dev-deep=2

Example 6: PTP l2 TX latency using raw sockets


Measure TX latency for ptpl2 packets (IEEE 1588)

:~# plget -i eth0 -t raw_ptpl2 -m tx-lat -n 160 -l 512 -s 10 -a 74:da:ea:47:7d:9d
or
:~# plget -i eth0 -t xdp_ptpl2 -m tx-lat -n 160 -l 512 -s 10 -a 74:da:ea:47:7d:9d

If address is not specified then 01:1B:19:00:00:00 is used.

RTT and ECHO LATENCY EXAMPLES

		     examples scheme
+--------------------------------------------------+
|                    TARGET BOARD 1                |
|----------------------+---------------------------|
|     User space       |        Kernel space       |
|----------------------+--------------+------------|
| RT app               | Net stack    | NIC driver |
|                  +---|          +---|        +---|
|                  |ts1|          |ts2|        |ts3|
| plget -m rtt     |   |--------->|   |------->|   |
|                  |SYS|          |SYS|        |PHC|<===> Eth
|                  |CLK|<---------|CLK|<-------|CLK|
|                  |   |          |   |        |   |
|                  |ts6|          |ts5|        |ts4|
|                  /---|          /---|        /---|
|        phc2sys  /    |         /    |       /    |
|        ________/_____|________/_____|______/     |
|        sync          |              |            |
+--------------------------------------------------+


      +--------------------------------------------------+
      |            TARGET BOARD 2 (ECHO)                 |
      |---------------------------+----------------------|
      |        Kernel space       |     User space       |
      |------------+--------------+----------------------|
      | NIC driver | Net stack    | RT app               |
      |---+        +---+          +---+                  |
      |ts1|        |ts2|          |ts3| plget -m echo-lat|
 Eth  |   |------->|   |--------->|   |----+      ...    |
<====>|PHC|        |SYS|          |SYS|    |             |
      |CLK|<-------|CLK|<---------|CLK|<---+             |
      |   |        |   |          |   |                  |
      |ts6|        |ts5|          |ts4|                  |
      |---\        +---\          +---\                  |
      |    \       |    \         |    \  phc2sys        |
      |     \______|_____\________|_____\___             |
      |            |              |       sync           |
      +--------------------------------------------------+

In this case plget has to be running on workstation and on testing board. It measures round trip time based on NICs h/w timestamps. And in the same time the latencies on board itself are also measured, both TX and RX, as packet is echoed with testing board. Packets are sent in order, the new packet is not sent till last packet has not been received back. Can be useful if TX and RX latencies should be measured for 2 different boards, twice faster.

For all examples run phc2sys, to keep PHC and system clock in sync, if h/w timestamping is supported ofc:

:~# phc2sys -s CLOCK_REALTIME -c eth0 -m -O 0 > /dev/null &

Use "-f lat,hwts,ipgap" if more printouts are needed, see "plget -h".

Example 1: UDP TX, RX latencies and RTT


Measure TX, RX latencies and rtt for UDP packets, port 385.

On board 1 (192.168.3.16):

:~# plget -i eth0 -t udp -u 385 -m rtt -n 16 -l 512 -a 192.168.3.20

On board 2 (192.168.3.20):

:~# plget -i eth0 -t udp -u 385 -m echo-lat -n 16 -a 192.168.3.16

Example 2: PTP l4 TX, RX latencies and RTT


Measure TX, RX latencies and RTT for PTP l4.

On workstation (client):

:~# plget -i eth0 -t udp -u 319 -m rtt -n 16 -l 512
or
:~# plget -i eth0 -t ptpl4 -m rtt -n 16 -l 512

On target board:

:~# plget -i eth0 -t udp -u 319 -m echo-lat -n 16
or
:~# plget -i eth0 -t ptpl4 -m echo-lat -n 16

By default multicast 224.0.1.129 address is used. In case the other is needed, use smth like -a 224.0.1.130 as for taget board as for client.

Example 3: AVTP TX, RX latencies and RTT


Measure TX, RX latencies and RTT for avtp packets (IEEE 1722)

On workstation (client 74:da:ea:47:7d:9d):

:~# plget -i eth0 -t avtp -m rtt -n 16 -l 512 -a c8:a0:30:b4:94:03

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t avtp -m echo-lat -n 16 -a 74:da:ea:47:7d:9d

Example 4: PTP l2 TX, RX latencies and RTT


Measure TX, RX latencies and RTT for ptpl2 packets (IEEE 1588)

On workstation (client 74:da:ea:47:7d:9d):

:~# plget -i eth0 -t ptpl2 -m rtt -n 16 -l 512 -a c8:a0:30:b4:94:03

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t ptpl2 -m echo-lat -n 16 -a 74:da:ea:47:7d:9d

Or use default multicast group and run appropriately:

:~# plget -i eth0 -t ptpl2 -m rtt -n 16 -l 512
:~# plget -i eth0 -t ptpl2 -m echo-lat -n 16

Example 5: PTP l2 TX, RX latencies and RTT using raw sockets


Measure TX, RX latencies and RTT for ptpl2 packets (IEEE 1588)

On workstation (client 74:da:ea:47:7d:9d):

:~# plget -i eth0 -t raw_ptpl2 -m rtt -n 16 -l 512 -a c8:a0:30:b4:94:03
or
:~# plget -i eth0 -t xdp_ptpl2 -m rtt -n 16 -l 512 -a c8:a0:30:b4:94:03

On target board (c8:a0:30:b4:94:03):

:~# plget -i eth0 -t raw_ptpl2 -m echo-lat -n 16 -a 74:da:ea:47:7d:9d
or
:~# plget -i eth0 -t xdp_ptpl2 -m echo-lat -n 16 -a 74:da:ea:47:7d:9d
or
:~# plget -i eth0 -t ptpl2 -m echo-lat -n 16 -a 74:da:ea:47:7d:9d

Or use default multicast group and run appropriately:

:~# plget -i eth0 -t raw_ptpl2 -m rtt -n 16 -l 512
:~# plget -i eth0 -t raw_ptpl2 -m echo-lat -n 16

RECEIVE RATE AND PACKET GEN MODES EXAMPLE

On one side run packet generator, on another plget tool in "rx-rate" mode. pkt-gen mode, in comparison to tx-lat mode, doesn't print any latencies or timestamps.

Example:


On workstation, packet generator:

:~# plget -i eth0 -t udp -u 385 -m pkt-gen -n 1600 -l 512 -s 103 -a 192.168.3.16

On target board (192.168.3.16), measure periodically rate:

:~# plget -i eth0 -t udp -u 385 -m rx-rate

By default rate is measured once a second, but can be tuned with -s. For measurements h/w timestamps are used if possible, otherwise software.

"HWTS" or/and "IPGAP" EXAMPLE

For next examples, replace or add "ipgap" to -f command to get interpacket gap.

Example 1:


Get plot, how packets are put on line:

:~# plget -i eth0 -t ptpl2 -m tx-lat -n 16 -s 100 -l 512 -f hwts

Packets are shown in relative to first packet ts time.

Example 2:


To measure tx-lat or hwts with several applications in parallel, and print plots for two applications on the same time line (not relative to first ts time) the following script can be used:

#!/bin/sh
# get hardware timestamps for both streams to observe inter streams impact

# get common time base running plget w/o arguments, to present readable
# timestamps in one time line.

BASE_TIME=$(./plget)

# run stream 1 with prio 3 and stream id = 0 to get hwts to tss1 file
plget -i eth0 -t ptpl2 -m tx-lat -n 16 -s 100 -l 512 -f hwts -p 3 \
	-r $BASE_TIME -k 0 > tss1&

# run stream 2 with prio 2 and stream id = 1 to get hwts to tss2 file
plget -i eth0 -t ptpl2 -m tx-lat -n 16 -s 100 -l 512 -f hwts -p 2 \
	-r $BASE_TIME -k 1 > tss2

All this can be done getting in parallel "latency" and "ipgap"

About

plget is a tool used to measure latency packets spent in network stack, NIC driver and on the wire, trace interpacket gap, based as on h/w as on sw timestamping, as for rx as for tx path, measure speed and more ...

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