Job Queue#

SkyPilot’s job queue allows multiple jobs to be scheduled on a cluster.

Getting started#

Each task submitted by sky exec is automatically queued and scheduled for execution on an existing cluster:

# Launch the job 5 times.
sky exec mycluster task.yaml -d
sky exec mycluster task.yaml -d
sky exec mycluster task.yaml -d
sky exec mycluster task.yaml -d
sky exec mycluster task.yaml -d

The -d / --detach flag detaches logging from the terminal, which is useful for launching many long-running jobs concurrently.

To show a cluster’s jobs and their statuses:

# Show a cluster's jobs (job IDs, statuses).
sky queue mycluster

To show the output for each job:

# Stream the outputs of a job.
sky logs mycluster JOB_ID

To cancel a job:

# Cancel a job.
sky cancel mycluster JOB_ID

# Cancel all jobs on a cluster.
sky cancel mycluster --all

Multi-node jobs#

Jobs that run on multiple nodes are also supported by the job queue.

First, create a cluster.yaml to specify the desired cluster:

num_nodes: 4
resources:
  accelerators: V100:8

workdir: ...
setup: |
  # Install dependencies.
  ...

Use sky launch -c mycluster cluster.yaml to provision a 4-node (each having 8 V100 GPUs) cluster. The num_nodes field is used to specify how many nodes are required.

Next, create a task.yaml to specify each task:

num_nodes: 2
resources:
  accelerators: V100:4

run: |
  # Run training script.
  ...

This specifies a task that needs to be run on 2 nodes, each of which must have 4 free V100s.

Use sky exec mycluster task.yaml to submit this task, which will be scheduled correctly by the job queue.

See Distributed Jobs on Many VMs for more details.

Using CUDA_VISIBLE_DEVICES#

The environment variable CUDA_VISIBLE_DEVICES will be automatically set to the devices allocated to each task on each node. This variable is set when a task’s run commands are invoked.

For example, task.yaml above launches a 4-GPU task on each node that has 8 GPUs, so the task’s run commands will be invoked with CUDA_VISIBLE_DEVICES populated with 4 device IDs.

If your run commands use Docker/docker run, simply pass --gpus=all; the correct environment variable would be set inside the container (only the allocated device IDs will be set).

Example: Fractional GPUs#

To run multiple trials per GPU, use fractional GPUs in the resource requirement. For example, use --gpus V100:0.5 to make 2 trials share 1 GPU:

$ sky exec mycluster --gpus V100:0.5 -d -- python train.py --lr 1e-3
$ sky exec mycluster --gpus V100:0.5 -d -- python train.py --lr 3e-3
...

When sharing a GPU, ensure that the GPU’s memory is not oversubscribed (otherwise, out-of-memory errors could occur).

Scheduling behavior#

SkyPilot’s scheduler serves two goals:

  1. Preventing resource oversubscription: SkyPilot schedules jobs on a cluster using their resource requirements—either specified in a task YAML’s resources field, or via the --gpus option of the sky exec CLI command. SkyPilot honors these resource requirements while ensuring that no resource in the cluster is oversubscribed. For example, if a node has 4 GPUs, it cannot host a combination of tasks whose sum of GPU requirements exceeds 4.

  2. Minimizing resource idleness: If a resource is idle, SkyPilot will schedule a queued job that can utilize that resource.

We illustrate the scheduling behavior by revisiting Tutorial: DNN Training. In that tutorial, we have a task YAML that specifies these resource requirements:

# dnn.yaml
...
resources:
  accelerators: V100:4
...

Since a new cluster was created when we ran sky launch -c lm-cluster dnn.yaml, SkyPilot provisioned the cluster with exactly the same resources as those required for the task. Thus, lm-cluster has 4 V100 GPUs.

While this initial job is running, let us submit more tasks:

$ # Launch 4 jobs, perhaps with different hyperparameters.
$ # You can override the task name with `-n` (optional) and
$ # the resource requirement with `--gpus` (optional).
$ sky exec lm-cluster dnn.yaml -d -n job2 --gpus=V100:1
$ sky exec lm-cluster dnn.yaml -d -n job3 --gpus=V100:1
$ sky exec lm-cluster dnn.yaml -d -n job4 --gpus=V100:4
$ sky exec lm-cluster dnn.yaml -d -n job5 --gpus=V100:2

Because the cluster has only 4 V100 GPUs, we will see the following sequence of events:

  • The initial sky launch job is running and occupies 4 GPUs; all other jobs are pending (no free GPUs).

  • The first two sky exec jobs (job2, job3) then start running and occupy 1 GPU each.

  • The third job (job4) will be pending, since it requires 4 GPUs and there is only 2 free GPUs left.

  • The fourth job (job5) will start running, since its requirement is fulfilled with the 2 free GPUs.

  • Once all but job5 finish, the cluster’s 4 GPUs become free again and job4 will transition from pending to running.

Thus, we may see the following job statuses on this cluster:

$ sky queue lm-cluster

 ID  NAME         USER  SUBMITTED    STARTED     STATUS
 5   job5         user  10 mins ago  10 mins ago RUNNING
 4   job4         user  10 mins ago  -           PENDING
 3   job3         user  10 mins ago  9 mins ago  RUNNING
 2   job2         user  10 mins ago  9 mins ago  RUNNING
 1   huggingface  user  10 mins ago  1 min ago   SUCCEEDED