MultiNode API

MultiNode API

The LAVA MultiNode API provides a simple way to pass messages using the serial port connection which is already available through LAVA. The API is not intended for transfers of large amounts of data. Test definitions which need to transfer files, long messages or other large amounts of data need to set up their own network configuration, access and download methods and do the transfer in the test definition.

lava-self

Prints the hostname of the current device.

Note

The LAVA hostname of a device is the name of the device within LAVA - as visible via the web frontend. The same name is used whether the device itself has a network connection or not. There is no requirement that the LAVA hostname matches anything related to any network connection or network service. This means that the LAVA hostname is always available via lava-group and lava-self.

Usage: lava-self

lava-role

Usage: lava-role

Prints the role the current device is playing in a multi-node job.

Example. In a directory with several scripts, one for each role involved in the test:

$ ./run-$(lava-role)

Usage: lava-role list

Prints a list of all roles within this multi-node job, separated by whitespace.:

#!/bin/sh
for role in `lava-role list`; do
    echo $role
done

See Use Case Four - Iterating through devices using roles

lava-group

Usage: lava-group

This command will produce in its standard output a representation of the device group that is participating in the multi-node test job.

The output format contains one line per device, and each line contains the hostname and the role that device is playing in the test, separated by a TAB character:

panda01     client
highbank01  loadbalancer
highbank02  backend
highbank03  backend

Usage: lava-group role

This command will produce in its standard output a list of the device names assigned the specified role in the multi-node test job.

The output format contains one line per device assigned to the specified role with no whitespace. The matched role is not output.:

$ lava-group client
panda01
$ lava-group backend
highbank02
highbank03

If there is no matching role, exit non-zero and output nothing.:

$ lava-group server ; echo $?
1

If your test definition relies on a particular role, one of the first test cases should be to check this role has been defined:

- lava-test-case check-server-role --shell lava-group server

The output can be used to iterate over all devices with the specified role:

#!/bin/sh
for device in `lava-group backend`; do
    echo $device
done

See Use Case Four - Iterating through devices using roles

lava-send

Sends a message to the group, optionally passing associated key-value data pairs. Sending a message is a non-blocking operation. The message is guaranteed to be available to all members of the group, but some of them might never retrieve it.

The message-id will be persistent for the lifetime of the target group managing the entire multinode test job. Re-sending a different message with an existing message-id is not supported.

Usage: lava-send <message-id> [key1=val1 [key2=val2] ...]

Examples will be provided below, together with lava-wait and lava-wait-all.

lava-wait

Waits until any other device in the group sends a message with the given ID. This call will block until such message is sent.

Usage: lava-wait <message-id>

If there was data passed in the message, the key-value pairs will be printed in the cache file (/tmp/lava_multi_node_cache.txt in default), each in one line. If no key values were passed, nothing is printed.

The message ID data is persistent for the life of the MultiNode group. The data can be retrieved at any later stage using lava-wait and as the data is already available, there will be no waiting time for repeat calls. If devices continue to send data with the associated message ID, that data will continue to be added to the data for that message ID and will be returned by subsequent calls to lava-wait for that message ID. Use a different message ID to collate different message data.

See also Using a flow table to plan the job

lava-wait-all

lava-wait-all operates in two distinct ways - with or without a role.

lava-wait-all <message-id> [<role>]

If data was sent by the other devices with the message, the key-value pairs will be printed in the cache file (/tmp/lava_multi_node_cache.txt in default), each in one line, prefixed with the target name and a colon.

Some examples for lava-send, lava-wait and lava-wait-all are given below.

The message returned can include data from other devices which sent a message with the relevant message ID, only the wait is dependent on particular devices with a specified role.

As with lava-wait, the message ID is persistent for the duration of the MultiNode group.

lava-wait-all <message-id>

lava-wait-all <message-id>

lava-wait-all waits until all other devices in the group send a message with the given message ID. Every device in the group must use lava-send with the same message ID before entering lava-wait-all or any device using that test definition will wait forever (and eventually timeout, failing the job).

Using lava-sync or lava-wait-all in a test definition effectively makes all boards in the group run at the speed of the slowest board in the group up to the point where the sync or wait is called.

See also Using a flow table to plan the job

lava-wait-all <message-id> <role>

lava-wait-all <message-id> <role>

If <role> is used, only wait until all devices with that given role send a message with the matching message ID. Devices of the given role do not enter lava-wait, but just send the message and continue the test definition. Ensure the test continues for long enough for the devices using lava-wait-all to pick up the message and act on it. Typically, this involves using a lava-sync after the lava-send on devices with the given role and after the completion of the task on the devices which were waiting for the message.

Not all roles in the group need to send a message or wait for a message. One role will act as a sender, at least one role will act as a receiver and any other roles can continue as normal. This level of complexity is not usually needed. It is advisable to draw out the sequence in a table to ensure that the correct calls are made.

See also Using a flow table to plan the job

lava-sync

Global synchronization primitive. Sends a message, and waits for the same message from all of the other devices.

Usage: lava-sync <message>

lava-sync foo is effectively the same as lava-send foo followed by lava-wait-all foo.

See also Using a flow table to plan the job

lava-network

Helper script to broadcast IP data from the test image, wait for data to be received by the rest of the group (or one role within the group) and then provide an interface to retrieve IP data about the group on the command line.

Raising a suitable network interface is a job left for the designer of the test definition / image but once a network interface is available, lava-network can be asked to broadcast this information to the rest of the group. At a later stage of the test, before the IP details of the group need to be used, call lava-network collect to receive the same information about the rest of the group.

The key-value pairs will be printed in the cache file (/tmp/lava_multi_node_network_cache.txt in default), each in one line, prefixed with the target name and a colon.

The information broadcast about each interface is:

  • hostname - hostname -f if supported, or just hostname
  • netmask
  • broadcast
  • MAC address
  • nameserver entries in /etc/resolv.conf using the pattern dns_N, starting at one.
  • ipv4 address
  • ipv6 address (if any)
  • default-gateway

All usage of lava-network needs to use a broadcast (which wraps a call to lava-send) and a collect (which wraps a call to lava-wait-all). As a wrapper around lava-wait-all, collect will block until the rest of the group (or devices in the group with the specified role) has made a broadcast.

After the data has been collected, it can be queried for any board specified in the output of lava-group by specifying the parameter to query (as used in the broadcast):

lava-network query panda19 ipv4
192.168.3.56

lava-network query beaglexm04 ipv6
fe80::f2de:f1ff:fe46:8c21

lava-network query arndale02 hostname
server

lava-network query panda14 hostname-full
client.localdomain

lava-network query panda19 netmask
255.255.255.0

lava-network query panda14 default-gateway
192.168.1.1

lava-network query panda17 dns_2
8.8.8.8

lava-network query panda06 mac
52:54:30:10:34:56

lava-network hosts can be used to output the list of all boards in the group which have returned a fully qualified domain name in a format suitable for /etc/hosts, appending to the specified file:

10.1.1.2       staging-kvm01
10.1.1.6       staging-kvm02.localdomain
10.1.1.2       staging-kvm03
10.1.1.3       staging-kvm04

Usage:

broadcast: lava-network broadcast [interface]

collect: lava-network collect [interface] <role>

query: lava-network query [hostname] [option]

hosts: lava-network hosts [file]

lava-network alias-hosts is an optional extension which extends the lava-network hosts support to use the role of each device in the group as an alias in the output. See Creating an alias in /etc/hosts based on the role for more information on the limitations of using roles as aliases.

The hostname used in a query of lava-network is the LAVA hostname which may differ from the network hostname of the device (which is why lava-network supports querying the LAVA hostname to return the network hostname). See the note under lava-self.

Example 1: simple client-server multi-node test

Two devices, with roles client, server

LAVA Test Shell test definition (say, example1.yaml):

run:
    steps:
        - ./run-`lava-role`.sh

The test image or the test definition would then provide two scripts, with only one being run on each device, according to the role specified.

run-server.sh:

#!/bin/sh

lava-send server-ready free-space=`df -h | grep "/$" | awk '{print $4}'`

Notes:

  • To make use of the server-ready message, some kind of client needs to do a lava-wait server-ready

run-client.sh:

#!/bin/sh

lava-wait server-ready
free-space=$(cat /tmp/lava_multi_node_cache.txt | cut -d = -f 2)
echo "The free disk space on server is ${free-space}"

Notes:

  • The client waits for the server-ready message then get the data which was sent by server from /tmp/lava_multi_node_cache.txt

Example 2: iperf client-server test

Two devices, with roles client, server

LAVA Test Shell test definition (say, example1.yaml):

run:
    steps:
        - ./run-`lava-role`.sh

The test image or the test definition would then provide two scripts, with only one being run on each device, according to the role specified.

run-server.sh:

#!/bin/sh

iperf -s &
echo $! > /tmp/iperf-server.pid
lava-send server-ready server-ip=`ip route get 8.8.8.8 | head -n 1 | awk '{print $NF}'`
lava-wait client-done
kill -9 `cat /tmp/iperf-server.pid`

Notes:

  • iperf server process needs to be run in the background to wait for the connection from the client and the process id will be stored somewhere for later use.
  • To make use of the server-ready message, some kind of client needs to do a lava-wait server-ready
  • There needs to be a support on a client to do the lava-send client-done or the wait will fail on the server.
  • If there was more than one client, the server could call lava-wait-all client-done instead.
  • iperf server process must be killed after getting client-done message, otherwise the test job will not proceed.

run-client.sh:

#!/bin/sh

lava-wait server-ready
server=$(cat /tmp/lava_multi_node_cache.txt | cut -d = -f 2)
iperf -c $server
# ... do something with output ...
lava-send client-done

Notes:

  • The client waits for the server-ready message as it’s first task, then does some work, then sends a message so that the server can move on and do other tests.

Example 3: variable number of clients

run-server.sh:

#!/bin/sh

start-server
lava-sync ready
lava-sync done

run-client.sh:

#!/bin/sh

# refer to the server by name, assume internal DNS works
server=$(lava-group | grep 'server$' | cut -f 1)

lava-sync ready
run-client
lava-sync done

Example 4: peer-to-peer application

Single role: peer, any number of devices

run-peer.sh:

#!bin/sh

initialize-data
start-p2p-service
lava-sync running

push-data
for peer in $(lava-group | cut -f 1); then
    if [ $peer != $(lava-self) ]; then
        query-data $peer
    fi
fi

Example 5: using lava-network

If the available roles include server and there is a board named database:

#!/bin/sh
ifconfig eth0 up
# possibly do your own check that this worked
lava-network broadcast eth0
# do whatever other tasks may be suitable here, then wait...
lava-network collect eth0 server
# continue with tests and get the information.
lava-network query database ipv4

Using a flow table to plan the job

Synchronisation of any type needs to be planned and the simplest way to manage the messages between roles within a group is to set out a strict table of the flow.

Set out the call and leave blank rows until that call is matched by the appropriate roles, to represent the time that the devices with that role will block in a wait loop with the coordinator.

Server Client Observer
deploy & boot deploy & boot deploy & boot
lava-sync start lava-sync start lava-sync start
server_start.sh lava-wait-all ready server lava-sync fin
lava-send ready    
lava-sync fin client-tasks.sh  
  lava-sync fin  

In this overly simplistic table, the Observer role really has nothing useful to do but to demonstrate that it will spend most of it’s time in lava-sync fin.

All roles will wait in lava-sync start until all deploy and boot operations (or whatever other tasks are put ahead of the call to lava-sync) are complete. The flow table does not include this delay.

The Server role runs a script to start a service, sending ready when the script returns.

The Client role waits until all devices with the Server role have completed lava-send ready - Observer is unaffected and Server moves directly into the lava-sync fin. Once the Client completes lava-wait-all ready server, the Client can run the client tasks script. That script finally puts the devices with the Client role into lava-sync fin at which point, the Client role receives the message that everyone else is already in that sync, the sync completes and the flow table ends.

Tables like this also help visualize how long the timeouts need to be to allow the Observer role to wait for all the server tasks and all the client tasks to complete.