Container dispatch¶

• Table of contents
• Container dispatch
  • Summary
  • Pseudocode
  • Examples
  • Arvados API support
  • Non-responsibilities
  • Additional notes
  • Cloud Container Services

Summary¶

A dispatcher uses available compute resources to execute queued containers.

Dispatch is meant to be a small simple component rather than a pluggable framework: e.g., "slurm dispatch" can be a small standalone program, rather than a plugin for a big generic dispatch program.

Pseudocode¶

• Notice there is a queued container
• Decide whether the required resources are available to run the container
• Lock the container (this avoids races with other dispatch processes)
• Translate the container's runtime constraints and priority to instructions for the lower-level scheduler, if any
• Invoke the "crunch2 run" executor
• When the priority changes on a container taken by this dispatch process, update the lower-level scheduler accordingly (cancel if priority is zero)
• If the lower-level scheduler indicates the container is finished or abandoned, but the Container record is locked by this dispatcher and has state=Running, fail the container

Examples¶

slurm batch mode

• Use "sinfo" to determine whether it is possible to run the container
• Submit a batch job to the queue: "echo crunch-run --job {uuid} | sbatch -N1"
• When container priority changes, use scontrol and scancel to propagate changes to slurm
• Use strigger to run a cleanup script when a container exits

standalone worker

• Inspect /proc/meminfo, /proc/cpuinfo, "docker ps", etc. to determine local capacity
• Invoke crunch-run as a child process (or perhaps a detached daemon process)
• Signal crunch-run to stop if container priority changes to zero

Arvados API support¶

Each dispatch process has an Arvados API token that allows it to see queued containers.

• No two dispatch processes can run at the same time with the same token. One way to achieve this is to make a user record for each dispatch service.

Container APIs relevant to a dispatch program:

• List Queued containers (might be a subset of Queued containers)
• List containers with state=Locked or state=Running associated with current token
  • arvados.v1.containers.current (equivalent to filters=[["dispatch_auth_uuid","=",current_client_auth.uuid]])
• Receive event when container is created or modified and state is Queued (it might become runnable)
• Change state Queued->Locked
• Change state Locked->Queued
• Change state Locked->Running
• Change state Running->Complete
• Receive event when priority changes
• Receive event when state changes to Complete
• Retrieve an API token to pass into the container and its arv-mount process (via crunch-run)
  • Token is automatically created/assigned when container state changes to Locked
  • Token is automatically expired/destroyed when container state changes away from Running
  • arvados.v1.containers.container_auth(uuid=container.uuid) → returns an api_client_authorization record
• Create events/logs
  • Decided not to run this container
  • Decided to run this container (e.g., no node with those resources)
  • Lock failed
  • Dispatched to crunch-run
  • Cleaned up crashed crunch-run (lower-level scheduler indicates the job finished, but crunch-run didn't leave the container in a final state)
  • Cleaned up abandoned container (container belongs to this process, but dispatch and lower-level scheduler don't know about it)

Non-responsibilities¶

Dispatch doesn't retry failed containers. If something needs to be reattempted, a new container will appear in the queue.

Dispatch doesn't fail a container that it can't run. It doesn't know whether other dispatchers will be able to run it.

Additional notes¶

(see also #6429 and #6518 and #8028)

Using websockets to listen for container events (new containers added, priority changes) will benefit from some Go SDK support.

Cloud Container Services¶

Cloud providers now offer container execution services. However, rather than being just an API to run containers (similar to Crunch) these take the form of preconfigured clusters set up with a container orchestration system.

AWS offers Elastic Container Service. It appears that the leader runs on AWS infrastructure (?) and you spin up worker VMs which run the ECS Agent: https://github.com/aws/amazon-ecs-agent

Google Container Engine provides a preconfigured Kubernetes cluster.

Azure provides a preconfigured Mesos or Docker Swarm cluster.