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mri

Implementing MRI

Introduction

The objective of this tutorial is to extend basic L3 forwarding with a scaled-down version of In-Band Network Telemetry (INT), which we call Multi-Hop Route Inspection (MRI).

MRI allows users to track the path and the length of queues that every packet travels through. To support this functionality, you will need to write a P4 program that appends an ID and queue length to the header stack of every packet. At the destination, the sequence of switch IDs correspond to the path, and each ID is followed by the queue length of the port at switch.

As before, we have already defined the control plane rules, so you only need to implement the data plane logic of your P4 program.

Spoiler alert: There is a reference solution in the solution sub-directory. Feel free to compare your implementation to the reference.

Step 1: Run the (incomplete) starter code

The directory with this README also contains a skeleton P4 program, mri.p4, which initially implements L3 forwarding. Your job (in the next step) will be to extend it to properly prepend the MRI custom headers.

Before that, let's compile the incomplete mri.p4 and bring up a switch in Mininet to test its behavior.

  1. In your shell, run:

    make

    This will:

    • compile mri.p4, and
    • start a Mininet instance with three switches (s1, s2, s3) configured in a triangle. There are 5 hosts. h1 and h11 are connected to s1. h2 and h22 are connected to s2 and h3 is connected to s3.
    • The hosts are assigned IPs of 10.0.1.1, 10.0.2.2, etc (10.0.<Switchid>.<hostID>).
    • The control plane programs the P4 tables in each switch based on sx-runtime.json
  2. We want to send a low rate traffic from h1 to h2 and a high rate iperf traffic from h11 to h22. The link between s1 and s2 is common between the flows and is a bottleneck because we reduced its bandwidth to 512kbps in topology.json. Therefore, if we capture packets at h2, we should see high queue size for that link.

Setup

  1. You should now see a Mininet command prompt. Open four terminals for h1, h11, h2, h22, respectively:

    mininet> xterm h1 h11 h2 h22
  2. In h2's xterm, start the server that captures packets:

    ./receive.py
  3. in h22's xterm, start the iperf UDP server:

    iperf -s -u
  4. In h1's xterm, send one packet per second to h2 using send.py say for 30 seconds:

    ./send.py 10.0.2.2 "P4 is cool" 30

    The message "P4 is cool" should be received in h2's xterm,

  5. In h11's xterm, start iperf client sending for 15 seconds

    iperf -c 10.0.2.22 -t 15 -u
  6. At h2, the MRI header has no hop info (count=0)

  7. type exit to close each xterm window

You should see the message received at host h2, but without any information about the path the message took. Your job is to extend the code in mri.p4 to implement the MRI logic to record the path.

A note about the control plane

P4 programs define a packet-processing pipeline, but the rules governing packet processing are inserted into the pipeline by the control plane. When a rule matches a packet, its action is invoked with parameters supplied by the control plane as part of the rule.

In this exercise, the control plane logic has already been implemented. As part of bringing up the Mininet instance, the make script will install packet-processing rules in the tables of each switch. These are defined in the sX-runtime.json files, where X corresponds to the switch number.

Step 2: Implement MRI

The mri.p4 file contains a skeleton P4 program with key pieces of logic replaced by TODO comments. These should guide your implementation---replace each TODO with logic implementing the missing piece.

MRI will require two custom headers. The first header, mri_t, contains a single field count, which indicates the number of switch IDs that follow. The second header, switch_t, contains switch ID and Queue depth fields of each switch hop the packet goes through.

One of the biggest challenges in implementing MRI is handling the recursive logic for parsing these two headers. We will use a parser_metadata field, remaining, to keep track of how many switch_t headers we need to parse. In the parse_mri state, this field should be set to hdr.mri.count. In the parse_swtrace state, this field should be decremented. The parse_swtrace state will transition to itself until remaining is 0.

The MRI custom headers will be carried inside an IP Options header. The IP Options header contains a field, option, which indicates the type of the option. We will use a special type 31 to indicate the presence of the MRI headers.

Beyond the parser logic, you will add a table in egress, swtrace to store the switch ID and queue depth, and actions that increment the count field, and append a switch_t header.

A complete mri.p4 will contain the following components:

  1. Header type definitions for Ethernet (ethernet_t), IPv4 (ipv4_t), IP Options (ipv4_option_t), MRI (mri_t), and Switch (switch_t).
  2. Parsers for Ethernet, IPv4, IP Options, MRI, and Switch that will populate ethernet_t, ipv4_t, ipv4_option_t, mri_t, and switch_t.
  3. An action to drop a packet, using mark_to_drop().
  4. An action (called ipv4_forward), which will:
    1. Set the egress port for the next hop.
    2. Update the ethernet destination address with the address of the next hop.
    3. Update the ethernet source address with the address of the switch.
    4. Decrement the TTL.
  5. An ingress control that:
    1. Defines a table that will read an IPv4 destination address, and invoke either drop or ipv4_forward.
    2. An apply block that applies the table.
  6. At egress, an action (called add_swtrace) that will add the switch ID and queue depth.
  7. An egress control that applies a table (swtrace) to store the switch ID and queue depth, and calls add_swtrace.
  8. A deparser that selects the order in which fields inserted into the outgoing packet.
  9. A package instantiation supplied with the parser, control, checksum verification and recomputation and deparser.

Step 3: Run your solution

Follow the instructions from Step 1. This time, when your message from h1 is delivered to h2, you should see the sequence of switches through which the packet traveled plus the corresponding queue depths. The expected output will look like the following, which shows the MRI header, with a count of 2, and switch ids (swids) 2 and 1. The queue depth at the common link (from s1 to s2) is high.

got a packet
###[ Ethernet ]###
  dst       = 00:04:00:02:00:02
  src       = f2:ed:e6:df:4e:fa
  type      = 0x800
###[ IP ]###
     version   = 4L
     ihl       = 10L
     tos       = 0x0
     len       = 42
     id        = 1
     flags     =
     frag      = 0L
     ttl       = 62
     proto     = udp
     chksum    = 0x60c0
     src       = 10.0.1.1
     dst       = 10.0.2.2
     \options   \
      |###[ MRI ]###
      |  copy_flag = 0L
      |  optclass  = control
      |  option    = 31L
      |  length    = 20
      |  count     = 2
      |  \swtraces  \
      |   |###[ SwitchTrace ]###
      |   |  swid      = 2
      |   |  qdepth    = 0
      |   |###[ SwitchTrace ]###
      |   |  swid      = 1
      |   |  qdepth    = 17
###[ UDP ]###
        sport     = 1234
        dport     = 4321
        len       = 18
        chksum    = 0x1c7b
###[ Raw ]###
           load      = 'P4 is cool'

Troubleshooting

There are several ways that problems might manifest:

  1. mri.p4 fails to compile. In this case, make will report the error emitted from the compiler and stop.

  2. mri.p4 compiles but does not support the control plane rules in the sX-runtime.json files that make tries to install using a Python controller. In this case, make will log the controller output in the logs directory. Use these error messages to fix your mri.p4 implementation.

  3. mri.p4 compiles, and the control plane rules are installed, but the switch does not process packets in the desired way. The logs/sX.log files contain trace messages describing how each switch processes each packet. The output is detailed and can help pinpoint logic errors in your implementation. The build/<switch-name>-<interface-name>.pcap also contains the pcap of packets on each interface. Use tcpdump -r <filename> -xxx to print the hexdump of the packets.

  4. mri.p4 compiles and all rules are installed. Packets go through and the logs show that the queue length is always 0. Then either reduce the link bandwidth in topology.json.

Cleaning up Mininet

In the latter two cases above, make may leave a Mininet instance running in the background. Use the following command to clean up these instances:

make stop

Next Steps

Congratulations, your implementation works! Move on to Source Routing.

Relevant Documentation

The documentation for P4_16 and P4Runtime is available here

All excercises in this repository use the v1model architecture, the documentation for which is available at:

  1. The BMv2 Simple Switch target document accessible here talks mainly about the v1model architecture.
  2. The include file v1model.p4 has extensive comments and can be accessed here.