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xpk (Accelerated Processing Kit, pronounced x-p-k,) is a software tool to help Cloud developers to orchestrate training jobs on accelerators such as TPUs and GPUs on GKE.

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Overview

xpk (Accelerated Processing Kit, pronounced x-p-k,) is a software tool to help Cloud developers to orchestrate training jobs on accelerators such as TPUs and GPUs on GKE. xpk handles the "multihost pods" of TPUs, GPUs (HGX H100) and CPUs (n2-standard-32) as first class citizens.

xpk decouples provisioning capacity from running jobs. There are two structures: clusters (provisioned VMs) and workloads (training jobs). Clusters represent the physical resources you have available. Workloads represent training jobs -- at any time some of these will be completed, others will be running and some will be queued, waiting for cluster resources to become available.

The ideal workflow starts by provisioning the clusters for all of the ML hardware you have reserved. Then, without re-provisioning, submit jobs as needed. By eliminating the need for re-provisioning between jobs, using Docker containers with pre-installed dependencies and cross-ahead of time compilation, these queued jobs run with minimal start times. Further, because workloads return the hardware back to the shared pool when they complete, developers can achieve better use of finite hardware resources. And automated tests can run overnight while resources tend to be underutilized.

xpk supports the following TPU types:

  • v4
  • v5e
  • v5p
  • Trillium (v6e)

and the following GPU types:

  • a100
  • a3 (h100)

and the following CPU types:

  • n2-standard-32

Cloud Console Permissions on the user or service account needed to run XPK:

  • Artifact Registry Writer
  • Compute Admin
  • Kubernetes Engine Admin
  • Logging Admin
  • Monitoring Admin
  • Service Account User
  • Storage Admin
  • Vertex AI Administrator

Prerequisites

xpk uses many tool to provide all neccessary functionalities. User must install following tools:

  • python >= 3.10 (download from here)
  • gcloud (install from here)
  • kubectl (install from here)
  • kueuectl (install from here)
  • kjob (installation instructions here)

Installation

To install xpk, run the following command:

pip install xpk

If you are running XPK by cloning GitHub repository, first run the following commands to begin using XPK commands:

git clone https://github.com/google/xpk.git
cd xpk
# Install dependencies such as cloud-accelerator-diagnostics
pip install .

If you see an error saying: This environment is externally managed, please use a virtual environment.

Example:

  ## One time step of creating the venv
  VENV_DIR=~/venvp3
  python3 -m venv $VENV_DIR
  ## Enter your venv.
  source $VENV_DIR/bin/activate
  ## Clone the repository and installing dependencies.
  git clone https://github.com/google/xpk.git
  cd xpk
  # Install dependencies such as cloud-accelerator-diagnostics
  pip install .

XPK for Large Scale (>1k VMs)

Follow user instructions in xpk-large-scale-guide.sh to use xpk for a GKE cluster greater than 1000 VMs. Run these steps to set up a GKE cluster with large scale training and high throughput support with XPK, and run jobs with XPK. We recommend you manually copy commands per step and verify the outputs of each step.

Example usages:

To get started, be sure to set your GCP Project and Zone as usual via gcloud config set.

Below are reference commands. A typical journey starts with a Cluster Create followed by many Workload Creates. To understand the state of the system you might want to use Cluster List or Workload List commands. Finally, you can cleanup with a Cluster Delete.

If you have failures with workloads not running, use xpk inspector to investigate more.

Cluster Create

First set the project and zone through gcloud config or xpk arguments.

PROJECT_ID=my-project-id
ZONE=us-east5-b
# gcloud config:
gcloud config set project $PROJECT_ID
gcloud config set compute/zone $ZONE
# xpk arguments
xpk .. --zone $ZONE --project $PROJECT_ID

The cluster created is a regional cluster to enable the GKE control plane across all zones.

  • Cluster Create (provision reserved capacity):

    # Find your reservations
    gcloud compute reservations list --project=$PROJECT_ID
    # Run cluster create with reservation.
    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-256 \
    --num-slices=2 \
    --reservation=$RESERVATION_ID
  • Cluster Create (provision on-demand capacity):

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=4 --on-demand
  • Cluster Create (provision spot / preemptable capacity):

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=4 --spot
  • Cluster Create for Pathways: Pathways compatible cluster can be created using cluster create-pathways.

    python3 xpk.py cluster create-pathways \
    --cluster xpk-pw-test \
    --num-slices=4 --on-demand \
    --tpu-type=v5litepod-16
  • Cluster Create can be called again with the same --cluster name to modify the number of slices or retry failed steps.

    For example, if a user creates a cluster with 4 slices:

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=4  --reservation=$RESERVATION_ID

    and recreates the cluster with 8 slices. The command will rerun to create 4 new slices:

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=8  --reservation=$RESERVATION_ID

    and recreates the cluster with 6 slices. The command will rerun to delete 2 slices. The command will warn the user when deleting slices. Use --force to skip prompts.

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=6  --reservation=$RESERVATION_ID
    
    # Skip delete prompts using --force.
    
    python3 xpk.py cluster create --force \
    --cluster xpk-test --tpu-type=v5litepod-16 \
    --num-slices=6  --reservation=$RESERVATION_ID

    and recreates the cluster with 4 slices of v4-8. The command will rerun to delete 6 slices of v5litepod-16 and create 4 slices of v4-8. The command will warn the user when deleting slices. Use --force to skip prompts.

    python3 xpk.py cluster create \
    --cluster xpk-test --tpu-type=v4-8 \
    --num-slices=4  --reservation=$RESERVATION_ID
    
    # Skip delete prompts using --force.
    
    python3 xpk.py cluster create --force \
    --cluster xpk-test --tpu-type=v4-8 \
    --num-slices=4  --reservation=$RESERVATION_ID

Create Private Cluster

XPK allows you to create a private GKE cluster for enhanced security. In a private cluster, nodes and pods are isolated from the public internet, providing an additional layer of protection for your workloads.

To create a private cluster, use the following arguments:

--private

This flag enables the creation of a private GKE cluster. When this flag is set:

  • Nodes and pods are isolated from the direct internet access.
  • master_authorized_networks is automatically enabled.
  • Access to the cluster's control plane is restricted to your current machine's IP address by default.

--authorized-networks

This argument allows you to specify additional IP ranges (in CIDR notation) that are authorized to access the private cluster's control plane and perform kubectl commands.

  • Even if this argument is not set when you have --private, your current machine's IP address will always be given access to the control plane.
  • If this argument is used with an existing private cluster, it will replace the existing authorized networks.

Example Usage:

  • To create a private cluster and allow access to Control Plane only to your current machine:

    python3 xpk.py cluster create \
      --cluster=xpk-private-cluster \
      --tpu-type=v4-8 --num-slices=2 \
      --private
  • To create a private cluster and allow access to Control Plane only to your current machine and the IP ranges 1.2.3.0/24 and 1.2.4.5/32:

    python3 xpk.py cluster create \
      --cluster=xpk-private-cluster \
      --tpu-type=v4-8 --num-slices=2 \
      --authorized-networks 1.2.3.0/24 1.2.4.5/32
    
      # --private is optional when you set --authorized-networks

Important Notes:

  • The argument --private is only applicable when creating new clusters. You cannot convert an existing public cluster to a private cluster using these flags.
  • The argument --authorized-networks is applicable when creating new clusters or using an existing private cluster. You cannot convert an existing public cluster to a private cluster using these flags.
  • You need to set up a Cluster NAT for your VPC network so that the Nodes and Pods have outbound access to the internet. This is required because XPK installs and configures components such as kueue that need access to external sources like registry.k8.io.

Create Vertex AI Tensorboard

Note: This feature is available in XPK >= 0.4.0. Enable Vertex AI API in your Google Cloud console to use this feature. Make sure you have Vertex AI Administrator role assigned to your user account.

Vertex AI Tensorboard is a fully managed version of open-source Tensorboard. To learn more about Vertex AI Tensorboard, visit this. Note that Vertex AI Tensorboard is only available in these regions.

You can create a Vertex AI Tensorboard for your cluster with Cluster Create command. XPK will create a single Vertex AI Tensorboard instance per cluster.

  • Create Vertex AI Tensorboard in default region with default Tensorboard name:
python3 xpk.py cluster create \
--cluster xpk-test --num-slices=1 --tpu-type=v4-8 \
--create-vertex-tensorboard

will create a Vertex AI Tensorboard with the name xpk-test-tb-instance (<args.cluster>-tb-instance) in us-central1 (default region).

  • Create Vertex AI Tensorboard in user-specified region with default Tensorboard name:
python3 xpk.py cluster create \
--cluster xpk-test --num-slices=1 --tpu-type=v4-8 \
--create-vertex-tensorboard --tensorboard-region=us-west1

will create a Vertex AI Tensorboard with the name xpk-test-tb-instance (<args.cluster>-tb-instance) in us-west1.

  • Create Vertex AI Tensorboard in default region with user-specified Tensorboard name:
python3 xpk.py cluster create \
--cluster xpk-test --num-slices=1 --tpu-type=v4-8 \
--create-vertex-tensorboard --tensorboard-name=tb-testing

will create a Vertex AI Tensorboard with the name tb-testing in us-central1.

  • Create Vertex AI Tensorboard in user-specified region with user-specified Tensorboard name:
python3 xpk.py cluster create \
--cluster xpk-test --num-slices=1 --tpu-type=v4-8 \
--create-vertex-tensorboard --tensorboard-region=us-west1 --tensorboard-name=tb-testing

will create a Vertex AI Tensorboard instance with the name tb-testing in us-west1.

  • Create Vertex AI Tensorboard in an unsupported region:
python3 xpk.py cluster create \
--cluster xpk-test --num-slices=1 --tpu-type=v4-8 \
--create-vertex-tensorboard --tensorboard-region=us-central2

will fail the cluster creation process because Vertex AI Tensorboard is not supported in us-central2.

Cluster Delete

  • Cluster Delete (deprovision capacity):

    python3 xpk.py cluster delete \
    --cluster xpk-test

Cluster List

  • Cluster List (see provisioned capacity):

    python3 xpk.py cluster list

Cluster Describe

  • Cluster Describe (see capacity):

    python3 xpk.py cluster describe \
    --cluster xpk-test

Cluster Cacheimage

  • Cluster Cacheimage (enables faster start times):

    python3 xpk.py cluster cacheimage \
    --cluster xpk-test --docker-image gcr.io/your_docker_image \
    --tpu-type=v5litepod-16

Workload Create

  • Workload Create (submit training job):

    python3 xpk.py workload create \
    --workload xpk-test-workload --command "echo goodbye" \
    --cluster xpk-test \
    --tpu-type=v5litepod-16
  • Workload Create for Pathways: Pathways workload can be submitted using workload create-pathways on a Pathways enabled cluster (created with cluster create-pathways)

    Pathways workload example:

    python3 xpk.py workload create-pathways \
    --workload xpk-pw-test \
    --num-slices=1 \
    --tpu-type=v5litepod-16 \
    --cluster xpk-pw-test \
    --docker-name='user-workload' \
    --docker-image=<maxtext docker image> \
    --command='python3 MaxText/train.py MaxText/configs/base.yml base_output_directory=<output directory> dataset_path=<dataset path> per_device_batch_size=1 enable_checkpointing=false enable_profiler=false remat_policy=full global_parameter_scale=4 steps=300 max_target_length=2048 use_iota_embed=true reuse_example_batch=1 dataset_type=synthetic attention=flash gcs_metrics=True run_name=$(USER)-pw-xpk-test-1'

    Regular workload can also be submitted on a Pathways enabled cluster (created with cluster create-pathways)

    Pathways workload example:

    python3 xpk.py workload create-pathways \
    --workload xpk-regular-test \
    --num-slices=1 \
    --tpu-type=v5litepod-16 \
    --cluster xpk-pw-test \
    --docker-name='user-workload' \
    --docker-image=<maxtext docker image> \
    --command='python3 MaxText/train.py MaxText/configs/base.yml base_output_directory=<output directory> dataset_path=<dataset path> per_device_batch_size=1 enable_checkpointing=false enable_profiler=false remat_policy=full global_parameter_scale=4 steps=300 max_target_length=2048 use_iota_embed=true reuse_example_batch=1 dataset_type=synthetic attention=flash gcs_metrics=True run_name=$(USER)-pw-xpk-test-1'

    Pathways in headless mode - Pathways now offers the capability to run JAX workloads in Vertex AI notebooks or in GCE VMs! Specify --headless with workload create-pathways when the user workload is not provided in a docker container.

    python3 xpk.py workload create-pathways --headless \
    --workload xpk-pw-headless \
    --num-slices=1 \
    --tpu-type=v5litepod-16 \
    --cluster xpk-pw-test

    Executing the command above would provide the address of the proxy that the user job should connect to.

    kubectl get pods
    kubectl port-forward pod/<proxy-pod-name> 29000:29000
    JAX_PLATFORMS=proxy JAX_BACKEND_TARGET=grpc://127.0.0.1:29000 python -c 'import pathwaysutils; import jax; print(jax.devices())'

    Specify JAX_PLATFORMS=proxy and JAX_BACKEND_TARGET=<proxy address from above> and import pathwaysutils to establish this connection between the user's JAX code and the Pathways proxy. Execute Pathways workloads interactively on Vertex AI notebooks!

Set max-restarts for production jobs

  • --max-restarts <value>: By default, this is 0. This will restart the job "" times when the job terminates. For production jobs, it is recommended to increase this to a large number, say 50. Real jobs can be interrupted due to hardware failures and software updates. We assume your job has implemented checkpointing so the job restarts near where it was interrupted.

Workload Priority and Preemption

  • Set the priority level of your workload with --priority=LEVEL

    We have five priorities defined: [very-low, low, medium, high, very-high]. The default priority is medium.

    Priority determines:

    1. Order of queued jobs.

      Queued jobs are ordered by very-low < low < medium < high < very-high

    2. Preemption of lower priority workloads.

      A higher priority job will evict lower priority jobs. Evicted jobs are brought back to the queue and will re-hydrate appropriately.

    General Example:

    python3 xpk.py workload create \
    --workload xpk-test-medium-workload --command "echo goodbye" --cluster \
    xpk-test --tpu-type=v5litepod-16 --priority=medium

Create Vertex AI Experiment to upload data to Vertex AI Tensorboard

Note: This feature is available in XPK >= 0.4.0. Enable Vertex AI API in your Google Cloud console to use this feature. Make sure you have Vertex AI Administrator role assigned to your user account and to the Compute Engine Service account attached to the node pools in the cluster.

Vertex AI Experiment is a tool that helps to track and analyze an experiment run on Vertex AI Tensorboard. To learn more about Vertex AI Experiments, visit this.

XPK will create a Vertex AI Experiment in workload create command and attach the Vertex AI Tensorboard created for the cluster during cluster create. If there is a cluster created before this feature is released, there will be no Vertex AI Tensorboard created for the cluster and workload create will fail. Re-run cluster create to create a Vertex AI Tensorboard and then run workload create again to schedule your workload.

  • Create Vertex AI Experiment with default Experiment name:
python3 xpk.py workload create \
--cluster xpk-test --workload xpk-workload \
--use-vertex-tensorboard

will create a Vertex AI Experiment with the name xpk-test-xpk-workload (<args.cluster>-<args.workload>).

  • Create Vertex AI Experiment with user-specified Experiment name:
python3 xpk.py workload create \
--cluster xpk-test --workload xpk-workload \
--use-vertex-tensorboard --experiment-name=test-experiment

will create a Vertex AI Experiment with the name test-experiment.

Check out MaxText example on how to update your workload to automatically upload logs collected in your Tensorboard directory to the Vertex AI Experiment created by workload create.

Workload Delete

  • Workload Delete (delete training job):

    python3 xpk.py workload delete \
    --workload xpk-test-workload --cluster xpk-test

    This will only delete xpk-test-workload workload in xpk-test cluster.

  • Workload Delete (delete all training jobs in the cluster):

    python3 xpk.py workload delete \
    --cluster xpk-test

    This will delete all the workloads in xpk-test cluster. Deletion will only begin if you type y or yes at the prompt. Multiple workload deletions are processed in batches for optimized processing.

  • Workload Delete supports filtering. Delete a portion of jobs that match user criteria. Multiple workload deletions are processed in batches for optimized processing.

    • Filter by Job: filter-by-job
    python3 xpk.py workload delete \
    --cluster xpk-test --filter-by-job=$USER

    This will delete all the workloads in xpk-test cluster whose names start with $USER. Deletion will only begin if you type y or yes at the prompt.

    • Filter by Status: filter-by-status
    python3 xpk.py workload delete \
    --cluster xpk-test --filter-by-status=QUEUED

    This will delete all the workloads in xpk-test cluster that have the status as Admitted or Evicted, and the number of running VMs is 0. Deletion will only begin if you type y or yes at the prompt. Status can be: EVERYTHING,FINISHED, RUNNING, QUEUED, FAILED, SUCCESSFUL.

Workload List

  • Workload List (see training jobs):

    python3 xpk.py workload list \
    --cluster xpk-test
  • Example Workload List Output:

    The below example shows four jobs of different statuses:

    • user-first-job-failed: filter-status is FINISHED and FAILED.
    • user-second-job-success: filter-status is FINISHED and SUCCESSFUL.
    • user-third-job-running: filter-status is RUNNING.
    • user-forth-job-in-queue: filter-status is QUEUED.
    • user-fifth-job-in-queue-preempted: filter-status is QUEUED.
    Jobset Name                     Created Time           Priority   TPU VMs Needed   TPU VMs Running/Ran   TPU VMs Done      Status     Status Message                                                  Status Time
    user-first-job-failed           2023-1-1T1:00:00Z      medium     4                4                     <none>            Finished   JobSet failed                                                   2023-1-1T1:05:00Z
    user-second-job-success         2023-1-1T1:10:00Z      medium     4                4                     4                 Finished   JobSet finished successfully                                    2023-1-1T1:14:00Z
    user-third-job-running          2023-1-1T1:15:00Z      medium     4                4                     <none>            Admitted   Admitted by ClusterQueue cluster-queue                          2023-1-1T1:16:00Z
    user-forth-job-in-queue         2023-1-1T1:16:05Z      medium     4                <none>                <none>            Admitted   couldn't assign flavors to pod set slice-job: insufficient unused quota for google.com/tpu in flavor 2xv4-8, 4 more need   2023-1-1T1:16:10Z
    user-fifth-job-preempted        2023-1-1T1:10:05Z      low        4                <none>                <none>            Evicted    Preempted to accommodate a higher priority Workload             2023-1-1T1:10:00Z
    
  • Workload List supports filtering. Observe a portion of jobs that match user criteria.

    • Filter by Status: filter-by-status

    Filter the workload list by the status of respective jobs. Status can be: EVERYTHING,FINISHED, RUNNING, QUEUED, FAILED, SUCCESSFUL

    • Filter by Job: filter-by-job

    Filter the workload list by the name of a job.

    python3 xpk.py workload list \
    --cluster xpk-test --filter-by-job=$USER
  • Workload List supports waiting for the completion of a specific job. XPK will follow an existing job until it has finished or the timeout, if provided, has been reached and then list the job. If no timeout is specified, the default value is set to the max value, 1 week. You may also set timeout=0 to poll the job once. (Note: restart-on-user-code-failure must be set when creating the workload otherwise the workload will always finish with Completed status.)

    Wait for a job to complete.

    python3 xpk.py workload list \
    --cluster xpk-test --wait-for-job-completion=xpk-test-workload

    Wait for a job to complete with a timeout of 300 seconds.

    python3 xpk.py workload list \
    --cluster xpk-test --wait-for-job-completion=xpk-test-workload \
    --timeout=300

    Return codes 0: Workload finished and completed successfully. 124: Timeout was reached before workload finished. 125: Workload finished but did not complete successfully. 1: Other failure.

Inspector

  • Inspector provides debug info to understand cluster health, and why workloads are not running. Inspector output is saved to a file.

    python3 xpk.py inspector \
      --cluster $CLUSTER_NAME \
      --project $PROJECT_ID \
      --zone $ZONE
  • Optional Arguments

    • --print-to-terminal: Print command output to terminal as well as a file.
    • --workload $WORKLOAD_NAME Inspector will write debug info related to the workload:$WORKLOAD_NAME
  • Example Output:

    The output of xpk inspector is in /tmp/tmp0pd6_k1o in this example.

    [XPK] Starting xpk
    [XPK] Task: `Set Cluster` succeeded.
    [XPK] Task: `Local Setup: gcloud version` is implemented by `gcloud version`, hiding output unless there is an error.
    [XPK] Task: `Local Setup: Project / Zone / Region` is implemented by `gcloud config get project; gcloud config get compute/zone; gcloud config get compute/region`, hiding output unless there is an error.
    [XPK] Task: `GKE: Cluster Details` is implemented by `gcloud beta container clusters list --project $PROJECT --region $REGION | grep -e NAME -e $CLUSTER_NAME`, hiding output unless there is an error.
    [XPK] Task: `GKE: Node pool Details` is implemented by `gcloud beta container node-pools list --cluster $CLUSTER_NAME  --project=$PROJECT --region=$REGION`, hiding output unless there is an error.
    [XPK] Task: `Kubectl: All Nodes` is implemented by `kubectl get node -o custom-columns='NODE_NAME:metadata.name, READY_STATUS:.status.conditions[?(@.type=="Ready")].status, NODEPOOL:metadata.labels.cloud\.google\.com/gke-nodepool'`, hiding output unless there is an error.
    [XPK] Task: `Kubectl: Number of Nodes per Node Pool` is implemented by `kubectl get node -o custom-columns=':metadata.labels.cloud\.google\.com/gke-nodepool' | sort | uniq -c`, hiding output unless there is an error.
    [XPK] Task: `Kubectl: Healthy Node Count Per Node Pool` is implemented by `kubectl get node -o custom-columns='NODE_NAME:metadata.name, READY_STATUS:.status.conditions[?(@.type=="Ready")].status, NODEPOOL:metadata.labels.cloud\.google\.com/gke-nodepool' | grep -w True | awk {'print $3'} | sort | uniq -c`, hiding output unless there is an error.
    [XPK] Task: `Kueue: ClusterQueue Details` is implemented by `kubectl describe ClusterQueue cluster-queue`, hiding output unless there is an error.
    [XPK] Task: `Kueue: LocalQueue Details` is implemented by `kubectl describe LocalQueue multislice-queue`, hiding output unless there is an error.
    [XPK] Task: `Kueue: Kueue Deployment Details` is implemented by `kubectl describe Deployment kueue-controller-manager -n kueue-system`, hiding output unless there is an error.
    [XPK] Task: `Jobset: Deployment Details` is implemented by `kubectl describe Deployment jobset-controller-manager -n jobset-system`, hiding output unless there is an error.
    [XPK] Task: `Kueue Manager Logs` is implemented by `kubectl logs deployment/kueue-controller-manager -n kueue-system --tail=100 --prefix=True`, hiding output unless there is an error.
    [XPK] Task: `Jobset Manager Logs` is implemented by `kubectl logs deployment/jobset-controller-manager -n jobset-system --tail=100 --prefix=True`, hiding output unless there is an error.
    [XPK] Task: `List Jobs with filter-by-status=EVERYTHING with filter-by-jobs=None` is implemented by `kubectl get workloads -o=custom-columns="Jobset Name:.metadata.ownerReferences[0].name,Created Time:.metadata.creationTimestamp,Priority:.spec.priorityClassName,TPU VMs Needed:.spec.podSets[0].count,TPU VMs Running/Ran:.status.admission.podSetAssignments[-1].count,TPU VMs Done:.status.reclaimablePods[0].count,Status:.status.conditions[-1].type,Status Message:.status.conditions[-1].message,Status Time:.status.conditions[-1].lastTransitionTime"  `, hiding output unless there is an error.
    [XPK] Task: `List Jobs with filter-by-status=QUEUED with filter-by-jobs=None` is implemented by `kubectl get workloads -o=custom-columns="Jobset Name:.metadata.ownerReferences[0].name,Created Time:.metadata.creationTimestamp,Priority:.spec.priorityClassName,TPU VMs Needed:.spec.podSets[0].count,TPU VMs Running/Ran:.status.admission.podSetAssignments[-1].count,TPU VMs Done:.status.reclaimablePods[0].count,Status:.status.conditions[-1].type,Status Message:.status.conditions[-1].message,Status Time:.status.conditions[-1].lastTransitionTime"  | awk -e 'NR == 1 || ($7 ~ "Admitted|Evicted|QuotaReserved" && ($5 ~ "<none>" || $5 == 0)) {print $0}' `, hiding output unless there is an error.
    [XPK] Task: `List Jobs with filter-by-status=RUNNING with filter-by-jobs=None` is implemented by `kubectl get workloads -o=custom-columns="Jobset Name:.metadata.ownerReferences[0].name,Created Time:.metadata.creationTimestamp,Priority:.spec.priorityClassName,TPU VMs Needed:.spec.podSets[0].count,TPU VMs Running/Ran:.status.admission.podSetAssignments[-1].count,TPU VMs Done:.status.reclaimablePods[0].count,Status:.status.conditions[-1].type,Status Message:.status.conditions[-1].message,Status Time:.status.conditions[-1].lastTransitionTime"  | awk -e 'NR == 1 || ($7 ~ "Admitted|Evicted" && $5 ~ /^[0-9]+$/ && $5 > 0) {print $0}' `, hiding output unless there is an error.
    [XPK] Find xpk inspector output file: /tmp/tmp0pd6_k1o
    [XPK] Exiting XPK cleanly

GPU usage

In order to use XPK for GPU, you can do so by using device-type flag.

  • Cluster Create (provision reserved capacity):

    # Find your reservations
    gcloud compute reservations list --project=$PROJECT_ID
    
    # Run cluster create with reservation.
    python3 xpk.py cluster create \
    --cluster xpk-test --device-type=h100-80gb-8 \
    --num-nodes=2 \
    --reservation=$RESERVATION_ID
  • Cluster Delete (deprovision capacity):

    python3 xpk.py cluster delete \
    --cluster xpk-test
  • Cluster List (see provisioned capacity):

    python3 xpk.py cluster list
  • Cluster Describe (see capacity):

    python3 xpk.py cluster describe \
    --cluster xpk-test
  • Cluster Cacheimage (enables faster start times):

    python3 xpk.py cluster cacheimage \
    --cluster xpk-test --docker-image gcr.io/your_docker_image \
    --device-type=h100-80gb-8
  • Install NVIDIA GPU device drivers

    # List available driver versions
    gcloud compute ssh $NODE_NAME --command "sudo cos-extensions list"
    
    # Install the default driver
    gcloud compute ssh $NODE_NAME --command "sudo cos-extensions install gpu"
    # OR install a specific version of the driver
    gcloud compute ssh $NODE_NAME --command "sudo cos-extensions install gpu -- -version=DRIVER_VERSION"
  • Run a workload:

    # Submit a workload
    python3 xpk.py workload create \
    --cluster xpk-test --device-type h100-80gb-8 \
    --workload xpk-test-workload \
    --command="echo hello world"
  • Workload Delete (delete training job):

    python3 xpk.py workload delete \
    --workload xpk-test-workload --cluster xpk-test

    This will only delete xpk-test-workload workload in xpk-test cluster.

  • Workload Delete (delete all training jobs in the cluster):

    python3 xpk.py workload delete \
    --cluster xpk-test

    This will delete all the workloads in xpk-test cluster. Deletion will only begin if you type y or yes at the prompt.

  • Workload Delete supports filtering. Delete a portion of jobs that match user criteria.

    • Filter by Job: filter-by-job
    python3 xpk.py workload delete \
    --cluster xpk-test --filter-by-job=$USER

    This will delete all the workloads in xpk-test cluster whose names start with $USER. Deletion will only begin if you type y or yes at the prompt.

    • Filter by Status: filter-by-status
    python3 xpk.py workload delete \
    --cluster xpk-test --filter-by-status=QUEUED

    This will delete all the workloads in xpk-test cluster that have the status as Admitted or Evicted, and the number of running VMs is 0. Deletion will only begin if you type y or yes at the prompt. Status can be: EVERYTHING,FINISHED, RUNNING, QUEUED, FAILED, SUCCESSFUL.

CPU usage

In order to use XPK for CPU, you can do so by using device-type flag.

  • Cluster Create (provision on-demand capacity):

    # Run cluster create with on demand capacity.
    python3 xpk.py cluster create \
    --cluster xpk-test \
    --device-type=n2-standard-32-256 \
    --num-slices=1 \
    --default-pool-cpu-machine-type=n2-standard-32 \
    --on-demand

    Note that device-type for CPUs is of the format -, thus in the above example, user requests for 256 VMs of type n2-standard-32. Currently workloads using < 1000 VMs are supported.

  • Run a workload:

    # Submit a workload
    python3 xpk.py workload create \
    --cluster xpk-test \
    --num-slices=1 \
    --device-type=n2-standard-32-256 \
    --workload xpk-test-workload \
    --command="echo hello world"

Autoprovisioning with XPK

XPK can dynamically allocate cluster capacity using Node Auto Provisioning, (NAP) support.

Allow several topology sizes to be supported from one XPK cluster, and be dynamically provisioned based on incoming workload requests. XPK users will not need to re-provision the cluster manually.

Enabling autoprovisioning will take the cluster around initially up to 30 minutes to upgrade.

Create a cluster with autoprovisioning:

Autoprovisioning will be enabled on the below cluster with [0, 8] chips of v4 TPU (up to 1xv4-16) to scale between.

XPK doesn't currently support different generations of accelerators in the same cluster (like v4 and v5p TPUs).

CLUSTER_NAME=my_cluster
NUM_SLICES=2
DEVICE_TYPE=v4-8
RESERVATION=reservation_id
PROJECT=my_project
ZONE=us-east5-b

python3 xpk.py cluster create \
  --cluster $CLUSTER_NAME \
  --num-slices=$NUM_SLICES \
    --device-type=$DEVICE_TYPE \
  --zone=$ZONE \
  --project=$PROJECT \
  --reservation=$RESERVATION \
  --enable-autoprovisioning
  1. Define the starting accelerator configuration and capacity type.

    --device-type=$DEVICE_TYPE \
    --num-slice=$NUM_SLICES
  2. Optionally set custom minimum / maximum chips. NAP will rescale the cluster with maximum - minimum chips. By default, maximum is set to the current cluster configuration size, and minimum is set to 0. This allows NAP to rescale with all the resources.

    --autoprovisioning-min-chips=$MIN_CHIPS \
    --autoprovisioning-max-chips=$MAX_CHIPS
  3. FEATURE TO COME SOON: Set the timeout period for when node pools will automatically be deleted if no incoming workloads are run. This is 10 minutes currently.

  4. FEATURE TO COME: Set the timeout period to infinity. This will keep the idle node pool configuration always running until updated by new workloads.

Update a cluster with autoprovisioning:

CLUSTER_NAME=my_cluster
NUM_SLICES=2
DEVICE_TYPE=v4-8
RESERVATION=reservation_id
PROJECT=my_project
ZONE=us-east5-b

python3 xpk.py cluster create \
  --cluster $CLUSTER_NAME \
  --num-slices=$NUM_SLICES \
    --device-type=$DEVICE_TYPE \
  --zone=$ZONE \
  --project=$PROJECT \
  --reservation=$RESERVATION \
  --enable-autoprovisioning

Update a previously autoprovisioned cluster with different amount of chips:

  • Option 1: By creating a new cluster nodepool configuration.
CLUSTER_NAME=my_cluster
NUM_SLICES=2
DEVICE_TYPE=v4-16
RESERVATION=reservation_id
PROJECT=my_project
ZONE=us-east5-b

# This will create 2x v4-16 node pools and set the max autoprovisioned chips to 16.
python3 xpk.py cluster create \
  --cluster $CLUSTER_NAME \
  --num-slices=$NUM_SLICES \
    --device-type=$DEVICE_TYPE \
  --zone=$ZONE \
  --project=$PROJECT \
  --reservation=$RESERVATION \
  --enable-autoprovisioning
  • Option 2: By increasing the --autoprovisioning-max-chips.
CLUSTER_NAME=my_cluster
NUM_SLICES=0
DEVICE_TYPE=v4-16
RESERVATION=reservation_id
PROJECT=my_project
ZONE=us-east5-b

# This will clear the node pools if they exist in the cluster and set the max autoprovisioned chips to 16
python3 xpk.py cluster create \
  --cluster $CLUSTER_NAME \
  --num-slices=$NUM_SLICES \
    --device-type=$DEVICE_TYPE \
  --zone=$ZONE \
  --project=$PROJECT \
  --reservation=$RESERVATION \
  --enable-autoprovisioning \
  --autoprovisioning-max-chips 16

Run workloads on the cluster with autoprovisioning:

Reconfigure the --device-type and --num-slices

CLUSTER_NAME=my_cluster
NUM_SLICES=2
DEVICE_TYPE=v4-8
NEW_RESERVATION=new_reservation_id
PROJECT=my_project
ZONE=us-east5-b
# Create a 2x v4-8 TPU workload.
python3 xpk.py workload create \
  --cluster $CLUSTER \
  --workload ${USER}-nap-${NUM_SLICES}x${DEVICE_TYPE}_$(date +%H-%M-%S) \
  --command "echo hello world from $NUM_SLICES $DEVICE_TYPE" \
  --device-type=$DEVICE_TYPE \
  --num-slices=$NUM_SLICES \
  --zone=$ZONE \
  --project=$PROJECT

NUM_SLICES=1
DEVICE_TYPE=v4-16

# Create a 1x v4-16 TPU workload.
python3 xpk.py workload create \
  --cluster $CLUSTER \
  --workload ${USER}-nap-${NUM_SLICES}x${DEVICE_TYPE}_$(date +%H-%M-%S) \
  --command "echo hello world from $NUM_SLICES $DEVICE_TYPE" \
  --device-type=$DEVICE_TYPE \
  --num-slices=$NUM_SLICES \
  --zone=$ZONE \
  --project=$PROJECT

# Use a different reservation from what the cluster was created with.
python3 xpk.py workload create \
  --cluster $CLUSTER \
  --workload ${USER}-nap-${NUM_SLICES}x${DEVICE_TYPE}_$(date +%H-%M-%S) \
  --command "echo hello world from $NUM_SLICES $DEVICE_TYPE" \
  --device-type=$DEVICE_TYPE \
  --num-slices=$NUM_SLICES \
  --zone=$ZONE \
  --project=$PROJECT \
  --reservation=$NEW_RESERVATION
  1. (Optional) Define the capacity type. By default, the capacity type will match with what the cluster was created with.

    --reservation=my-reservation-id | --on-demand | --spot
  2. Set the topology of your workload using --device-type.

    NUM_SLICES=1
    DEVICE_TYPE=v4-8
    --device-type=$DEVICE_TYPE \
    --num-slices=$NUM_SLICES \

How to add docker images to a xpk workload

The default behavior is xpk workload create will layer the local directory (--script-dir) into the base docker image (--base-docker-image) and run the workload command. If you don't want this layering behavior, you can directly use --docker-image. Do not mix arguments from the two flows in the same command.

Recommended / Default Docker Flow: --base-docker-image and --script-dir

This flow pulls the --script-dir into the --base-docker-image and runs the new docker image.

  • The below arguments are optional by default. xpk will pull the local directory with a generic base docker image.

    • --base-docker-image sets the base image that xpk will start with.

    • --script-dir sets which directory to pull into the image. This defaults to the current working directory.

    See python3 xpk.py workload create --help for more info.

  • Example with defaults which pulls the local directory into the base image:

    echo -e '#!/bin/bash \n echo "Hello world from a test script!"' > test.sh
    python3 xpk.py workload create --cluster xpk-test \
    --workload xpk-test-workload-base-image --command "bash test.sh" \
    --tpu-type=v5litepod-16 --num-slices=1
  • Recommended Flow For Normal Sized Jobs (fewer than 10k accelerators):

    python3 xpk.py workload create --cluster xpk-test \
    --workload xpk-test-workload-base-image --command "bash custom_script.sh" \
    --base-docker-image=gcr.io/your_dependencies_docker_image \
    --tpu-type=v5litepod-16 --num-slices=1

Optional Direct Docker Image Configuration: --docker-image

If a user wants to directly set the docker image used and not layer in the current working directory, set --docker-image to the image to be use in the workload.

  • Running with --docker-image:

    python3 xpk.py workload create --cluster xpk-test \
    --workload xpk-test-workload-base-image --command "bash test.sh" \
    --tpu-type=v5litepod-16 --num-slices=1 --docker-image=gcr.io/your_docker_image
  • Recommended Flow For Large Sized Jobs (more than 10k accelerators):

    python3 xpk.py cluster cacheimage \
    --cluster xpk-test --docker-image gcr.io/your_docker_image
    # Run workload create with the same image.
    python3 xpk.py workload create --cluster xpk-test \
    --workload xpk-test-workload-base-image --command "bash test.sh" \
    --tpu-type=v5litepod-16 --num-slices=1 --docker-image=gcr.io/your_docker_image

More advanced facts:

  • Workload create has two mutually exclusive ways to override the environment of a workload:

    • a --env flag to specify each environment variable separately. The format is:

      --env VARIABLE1=value --env VARIABLE2=value

    • a --env-file flag to allow specifying the container's environment from a file. Usage is the same as Docker's --env-file flag

    Example Env File:

    LIBTPU_INIT_ARGS=--my-flag=true --performance=high
    MY_ENV_VAR=hello
  • Workload create accepts a --debug-dump-gcs flag which is a path to GCS bucket. Passing this flag sets the XLA_FLAGS='--xla_dump_to=/tmp/xla_dump/' and uploads hlo dumps to the specified GCS bucket for each worker.

Integration Test Workflows

The repository code is tested through Github Workflows and Actions. Currently three kinds of tests are performed:

  • A nightly build that runs every 24 hours
  • A build that runs on push to main branch
  • A build that runs for every PR approval

More information is documented here

Troubleshooting

Invalid machine type for CPUs.

XPK will create a regional GKE cluster. If you see issues like

Invalid machine type e2-standard-32 in zone $ZONE_NAME

Please select a CPU type that exists in all zones in the region.

# Find CPU Types supported in zones.
gcloud compute machine-types list --zones=$ZONE_LIST
# Adjust default cpu machine type.
python3 xpk.py cluster create --default-pool-cpu-machine-type=CPU_TYPE ...

Workload creation fails

Some XPK cluster configuration might be missing, if workload creation fails with the below error.

[XPK] b'error: the server doesn\'t have a resource type "workloads"\n'

Mitigate this error by re-running your xpk.py cluster create ... command, to refresh the cluster configurations.

Permission Issues: requires one of ["permission_name"] permission(s).

  1. Determine the role needed based on the permission error:

    # For example: `requires one of ["container.*"] permission(s)`
    # Add [Kubernetes Engine Admin](https://cloud.google.com/iam/docs/understanding-roles#kubernetes-engine-roles) to your user.
  2. Add the role to the user in your project.

    Go to iam-admin or use gcloud cli:

    PROJECT_ID=my-project-id
    CURRENT_GKE_USER=$(gcloud config get account)
    ROLE=roles/container.admin  # container.admin is the role needed for Kubernetes Engine Admin
    gcloud projects add-iam-policy-binding $PROJECT_ID --member user:$CURRENT_GKE_USER --role=$ROLE
  3. Check the permissions are correct for the users.

    Go to iam-admin or use gcloud cli:

    PROJECT_ID=my-project-id
    CURRENT_GKE_USER=$(gcloud config get account)
    gcloud projects get-iam-policy $PROJECT_ID --filter="bindings.members:$CURRENT_GKE_USER" --flatten="bindings[].members"
  4. Confirm you have logged in locally with the correct user.

    gcloud auth login

Roles needed based on permission errors:

  • requires one of ["container.*"] permission(s)

    Add Kubernetes Engine Admin to your user.

  • ERROR: (gcloud.monitoring.dashboards.list) User does not have permission to access projects instance (or it may not exist)

    Add Monitoring Viewer to your user.

Reservation Troubleshooting:

How to determine your reservation and its size / utilization:

PROJECT_ID=my-project
ZONE=us-east5-b
RESERVATION=my-reservation-name
# Find the reservations in your project
gcloud beta compute reservations list --project=$PROJECT_ID
# Find the tpu machine type and current utilization of a reservation.
gcloud beta compute reservations describe $RESERVATION --project=$PROJECT_ID --zone=$ZONE

TPU Workload Debugging

Verbose Logging

If you are having trouble with your workload, try setting the --enable-debug-logs when you schedule it. This will give you more detailed logs to help pinpoint the issue. For example:

python3 xpk.py workload create \
--cluster --workload xpk-test-workload \
--command="echo hello world" --enable-debug-logs

Please check libtpu logging and Tensorflow logging for more information about the flags that are enabled to get the logs.

Collect Stack Traces

cloud-tpu-diagnostics PyPI package can be used to generate stack traces for workloads running in GKE. This package dumps the Python traces when a fault such as segmentation fault, floating-point exception, or illegal operation exception occurs in the program. Additionally, it will also periodically collect stack traces to help you debug situations when the program is unresponsive. You must make the following changes in the docker image running in a Kubernetes main container to enable periodic stack trace collection.

# main.py

from cloud_tpu_diagnostics import diagnostic
from cloud_tpu_diagnostics.configuration import debug_configuration
from cloud_tpu_diagnostics.configuration import diagnostic_configuration
from cloud_tpu_diagnostics.configuration import stack_trace_configuration

stack_trace_config = stack_trace_configuration.StackTraceConfig(
                      collect_stack_trace = True,
                      stack_trace_to_cloud = True)
debug_config = debug_configuration.DebugConfig(
                stack_trace_config = stack_trace_config)
diagnostic_config = diagnostic_configuration.DiagnosticConfig(
                      debug_config = debug_config)

with diagnostic.diagnose(diagnostic_config):
	main_method()  # this is the main method to run

This configuration will start collecting stack traces inside the /tmp/debugging directory on each Kubernetes Pod.

Explore Stack Traces

To explore the stack traces collected in a temporary directory in Kubernetes Pod, you can run the following command to configure a sidecar container that will read the traces from /tmp/debugging directory.

python3 xpk.py workload create \
 --workload xpk-test-workload --command "python3 main.py" --cluster \
 xpk-test --tpu-type=v5litepod-16 --deploy-stacktrace-sidecar

Get information about jobs, queues and resources.

To list available resources and queues use xpk info command. It allows to see localqueues and clusterqueues and check for available resources.

To see queues with usage and workload info use:

python3 xpk.py info --cluster my-cluster

You can specify what kind of resources(clusterqueue or localqueue) you want to see using flags --clusterqueue or --localqueue.

python3 xpk.py info --cluster my-cluster --localqueue

Other advanced usage

Use a Jupyter notebook to interact with a Cloud TPU cluster

About

xpk (Accelerated Processing Kit, pronounced x-p-k,) is a software tool to help Cloud developers to orchestrate training jobs on accelerators such as TPUs and GPUs on GKE.

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