A Taskcluster client library for (server-side) JS.

This library is a complete interface to Taskcluster in JavaScript. It provides an asynchronous interface for all Taskcluster API methods. This library is used within Taskcluster itself for inter-service communication.

For a general guide to using Taskcluster clients, see Calling Taskcluster APIs.

Before calling an API end-point, you'll need to create a client instance. There is a class for each service, e.g., Queue and Auth. Each takes the same options, shown in the example below. Note that only rootUrl is required, and it's unusual to configure any other options aside from credentials.

import taskcluster from 'taskcluster-client';

// Instantiate the Queue Client class
const queue = new taskcluster.Queue({
  // rootUrl for this Taskcluster instance (required)
  rootUrl: 'https://taskcluster.myproject.org',

  // Taskcluster credentials (required only for API methods that require scopes)
  credentials: {
    clientId:     '...',
    accessToken:  '...',
    // Certificate must also be provided if using temporary credentials,
    // this can be either a JSON object or a JSON string.
    certificate:  {...}   // Only applicable for temporary credentials
  }

  // timeout for _each_ invidual http request
  timeout: 30 * 1000,

  // maximum number of retries for transient errors (default 5)
  retries: 5,

  // Multiplier for computation of retry delay: 2 ^ retry * delayFactor,
  // 100 ms is solid for servers, and 500ms - 1s is suitable for background
  // processes
  delayFactor: 100,

  // Randomization factor added as.
  // delay = delay * random([1 - randomizationFactor; 1 + randomizationFactor])
  randomizationFactor: 0.25,

  // Maximum retry delay (defaults to 30 seconds)
  maxDelay: 30 * 1000,

  // By default we share a global HTTP agent. If you specify one, your instance
  // will have its own agent with the given options...
  agent: undefined,

  // Fake methods, for testing (see below)
  fake: null,

  // authorized scopes for use in requests by this client
  authorizedScopes: undefined,

  // (optional) If set, this will be added to requests as a `x-taskcluster-trace-id` header
  traceId: undefined

  // (optional) This supports different ways of finding Taskcluster services. Currently only
  //            values are `default` and `k8s-dns`. The latter of which is for Taskcluster
  //            internal use only.
  serviceDiscoveryScheme: 'default'
});

If you need to create a client similar to a existing client, but with some options changed, use client.use(options):

queue
  .use({retries: 0}) // disable retries for this request
  .createTask(..)
  .then(..);

This replaces any given options with new values. For traceId in particular, you can use

queue.taskclusterPerRequestInstance({traceId});

Which is a special interface mostly useful for Taskcluster internal use.

You can automatically read credentials and rootUrl from the standard TASKCLUSTER_… environment variables with taskcluster.fromEnvVars() with fromEnvVars:

const auth = new taskcluster.Auth({
  ...taskcluster.fromEnvVars(),
});

Note that this function does not respect TASKCLUSTER_PROXY_URL. To use the Taskcluster Proxy from within a task:

const auth = new taskcluster.Auth({
  rootUrl: process.env.TASKCLUSTER_PROXY_URL,
});

You may also provide credentials directly. For example:

const auth = new taskcluster.Auth({
  credentials: {
    clientId:     '...',
    accessToken:  '...'
  }
});

If the clientId and accessToken are not given, no credentials will be used.

You can set any of these values as global configuration options:

// Configure default options
taskcluster.config({
  rootUrl: "https://somesite.com",
  credentials: {
    clientId:     '...',
    accessToken:  '...'
  }
});

// No rootUrl needed here
const auth = new taskcluster.Auth();

If you wish to perform requests on behalf of a third-party that has small set of scopes than you do. You can specify which scopes your request should be allowed to use, in the authorizedScopes option. See example below:

// Create a Queue Client class can only define tasks for a specific workerType
const queue = new taskcluster.Queue({
  // Credentials that can define tasks for any provisioner and workerType.
  credentials: {
    clientId:       '...',
    accessToken:    '...'
  },
  // Restricting this instance of the Queue client to only one scope
  authorizedScopes: ['queue:create-task:highest:my-provisioner/my-worker-type']
});

// This request will only be successful, if the task posted is aimed at
// "my-worker-type/my-provisioner".
await queue.createTask(taskId taskDefinition).then(function(result) {
  // ...
});

Once you have a client object, calling API methods is as simple as invoking a method on the object. All API methods are async, and their function signatures match those in the reference documentation. In general, URL arguments are positional JS arguments, and any request payload is provided in a JSON object in the final argument.

Some API end-points may take query-string options. This is indicated in the signature in the reference documentation as [options]. These options are always optional, commonly used for continuation tokens when paging a list.

// Create task using the queue client
const taskId = '...';
const result = await queue.createTask(taskId, payload);
console.log(result.status);
});

For the following section, there are 2 internal and 2 external functions. The external functions should be used when a built url is leaving the deployment. One example would be when it results in a redirect to an artifact for users. This distinction is only important when using a non-default service discovery scheme; with the default scheme, internal and external functions behave the same.

| | Unsigned | Signed | | Internal | buildUrl | buildSignedUrl | | External | externalBuildUrl | externalBuildSignedUrl |

You can build a URL for any API method, although this feature is mostly useful for request that don't require any authentication. To construct a url for a request use the buildUrl/externalBuildUrl method, as illustrated in the following example:

// Create queue instance
const queue = new taskcluster.Queue(...);

// Build url to get a specific task
const url = queue.buildUrl(
  queue.getTask,    // Method to build url for.
  taskId            // First parameter for the method, in this case taskId
);

It's possible to build signed URLs, including authentication information, for all GET requests. A signed url contains a query-string parameter called bewit, this parameter holds expiration time, signature and scope restrictions (if applied). The signature covers the following parameters:

• Expiration time,
• Url and query-string, and
• scope restrictions (if applied)

These signed urls are very convenient if you want to grant somebody access to specific resource without proxying the request or sharing your credentials. For example it's fairly safe to provide someone with a signed url for a specific artifact that is protected by a scope. See example below.

// Create queue instance
const queue = new taskcluster.Queue(...);

// Build signed url
const signedUrl = queue.buildSignedUrl(
  queue.getArtifactFromRun,   // method to build signed url for.
  taskId,                     // TaskId parameter
  runId,                      // RunId parameter
  artifactName,               // Artifact name parameter
  {
    expiration:     60 * 10   // Expiration time in seconds
});

Please, note that the payload parameter cannot be encoded in the signed url and must be sent as request payload. This should work fine, just remember that it's only possible to make signed urls for GET requests, which in most cases don't take a payload.

Also please consider using a relatively limited expiration time, as it's not possible to retract a signed url without revoking your credentials. For more technical details on signed urls, see bewit urls in mozilla/hawk.

If you have non-temporary taskcluster credentials you can generate a set of temporary credentials as follows. Notice that the credentials cannot last more than 31 days, and you can only revoke them by revoking the credentials that was used to issue them (this takes up to one hour).

const credentials = taskcluster.createTemporaryCredentials({
  // Name of temporary credential (optional)
  clientId:           '...',
  // Validity of temporary credentials starts here
  start:              new Date(),
  // Expiration of temporary credentials
  expiry:             new Date(new Date().getTime() + 5 * 60 * 1000),
  // Scopes to grant the temporary credentials
  scopes:             ['ScopeA', 'ScopeB', ...]
  credentials: {      // Non-temporary taskcluster credentials
    clientId:         '...'
    accessToken:      '...'
  }
});

You cannot use temporary credentials to issue new temporary credentials. You must have auth:create-client:<name> to create a named temporary credential, but unnamed temporary credentials can be created regardless of your scopes.

A lot of taskcluster APIs requires ISO 8601 time stamps offset into the future as way of providing expiration, deadlines, etc. These can be easily created using new Date().toJSON(), however, it can be rather error prone and tedious to offset Date objects into the future. Therefore this library comes with two utility functions for this purposes.

const dateObject = taskcluster.fromNow("2 days 3 hours 1 minute");
const dateString = taskcluster.fromNowJSON("2 days 3 hours 1 minute");
assert(dateObject.toJSON() === dateString);
// dateObject = now() + 2 days 2 hours and 1 minute
assert(new Date().getTime() < dateObject.getTime());

By default it will offset the date time into the future, if the offset strings are prefixed minus (-) the date object will be offset into the past. This is useful in some corner cases.

const dateObject = taskcluster.fromNow("- 1 year 2 months 3 weeks 5 seconds");
// dateObject = now() - 1 year, 2 months, 3 weeks and 5 seconds
assert(new Date().getTime() > dateObject.getTime());

The offset string is ignorant of whitespace and case insensitive. It may also optionally be prefixed plus + (if not prefixed minus), any + prefix will be ignored. However, entries in the offset string must be given in order from high to low, ie. 2 years 1 day. Additionally, various shorthands may be employed, as illustrated below.

  years,    year,   yr,   y
  months,   month,  mo
  weeks,    week,   wk,   w
  days,     day,          d
  hours,    hour,   hr,   h
  minutes,  minute, min
  seconds,  second, sec,  s

The fromNow method may also be given a date to be relative to as a second argument. This is useful if offset the task expiration relative to the the task deadline or doing something similar.

const dateObject1 = taskcluster.fromNow("2 days 3 hours");
// dateObject1  = now() + 2 days and 3 hours
const dateObject2 = taskcluster.fromNow("1 year", dateObject1);
// dateObject2  = now() + 1 year, 2 days and 3 hours

In node you can rely on the slugid module to generate slugids, but we already need it in taskcluster-client and expose the preferred slugid generation function as taskcluster.slugid().

import taskcluster from 'taskcluster-client';

// Generate new taskId
const taskId = taskcluster.slugid();

The generates nice random slugids, refer to slugid module for further details.

The Object service provides an API for reliable uploads and downloads of large objects. These are most frequently used to store artifacts on behalf of the Queue service. This library provides convenience methods to implement the client portion of those APIs, providing well-tested, resilient upload and download functionality. These methods will negotiate the appropriate method with the object service and perform the required steps to transfer the data.

In either case, you will need to provide a configured Object instance with appropriate credentials for the operation. You must also provide a streamFactory which, on each call, returns a Readable or Writable stream to handle the object data. This function may be async (return a Promise). In the event of retries, this function may be called several times, and should return a fresh stream on each invocation.

Both upload and download support the same retry configuration as clients, as described above, with the same defaults. Note that these parameters apply only to the data-transfer portion of the process. The calls to Object service endpoints will be governed by the retry configuration of the given Object instance.

For upload:

await taskcluster.upload({
  // paramters for the createObject endpoint
  projectId,
  name,
  expires,
  uploadId, // optional; will be generated randomly if omitted

  // metadata about the data being uploaded
  contentType,
  contentLength,

  // see above
  object,
  streamFactory,
  retries.,
  delayFactor.,
  randomizationFactor.,
  maxDelay.,
});

For downloading objects, returning the content type:

let contentType = await taskcluster.download({
  // the object to download
  name,

  // see above
  object,
  streamFactory,
  retries.,
  delayFactor.,
  randomizationFactor.,
  maxDelay.,
});

For example:

const object = new taskcluster.Object(taskcluster.fromEnvVars());
const contentType = await taskcluster.download({
  name: 'testing/data.tgz',
  object,
  streamFactory: () => fs.createWriteStream('data.tgz'),
});

And, wrapping that to support downloading artifacts:

let contentType = await taskcluster.downloadArtifact({
  // the artifact to download
  taskId,
  runId, // optional, defaulting to the latest run
  name,

  queue, // Queue instance with appropriate credentials to read the artifact
  // (the queue will supply object-service credentials if necessary)

  // see above
  streamFactory,
  retries.,
  delayFactor.,
  randomizationFactor.,
  maxDelay.,
});

Your users may find the options for Taskcluster credentials overwhelming. You can help by interpreting the credentials for them.

The credentialInformation(rootUrl, credentials) function returns a promise with information about the given credentials:

{
   clientId: "..",      // name of the credential
   type: "..",          // type of credential, e.g., "temporary"
   active: "..",        // active (valid, not disabled, etc.)
   start: "..",         // validity start time (if applicable)
   expiry: "..",        // validity end time (if applicable)
   scopes: ["..."],     // associated scopes (if available)
}

The resulting information should only be used for presentation purposes, and never for access control. This function may fail unexpectedly with invalid credentials, and performs no cryptographic checks. It is acceptable to use the scopes result to determine whether to display UI elements associated with a particular scope, as long as the underlying API performs more reliable authorization checks.

NOTE PulseListener is no longer included in taskcluster-client; instead, use PulseConsumer from taskcluster-lib-pulse.

However, this library helpfully includes bindings for exchanges declared by various Taskcluster services. To use these with taskcluster-lib-pulse, create an ..Events instance, call the apprporiate methods on it to construct a binding, and pass that to pulse.consume:

import taskcluster from 'taskcluster-client';

// Instantiate the QueueEvents Client class
const queueEvents = new taskcluster.QueueEvents({rootUrl: ..});

let pc = await pulse.consume({
  bindings: [
    // Bind to task-completed events from queue that matches routing key pattern:
    //   'primary.<myTaskId>.*.*.*.*.*.#'
    queueEvents.taskCompleted({taskId: myTaskId});
  ], ..);

In testing, it is useful to be able to "fake out" client methods so that they do not try to communicate with an actual, external service. The normal client argument checking still takes place, and a function of your design will be called instead of calling the external service.

This is set up when constructing the client. Typically, this occurs in a taskcluster-lib-loader entry.

setup(function () {
  // inject the dependency with a stickyLoader from taskcluster-lib-testing
  helper.load.inject('secrets', new taskcluster.Secrets({
    fake: {
      get: (name) => 'my-hardcoded-secret',
    },
  });
});

test('test the thing', async function() {
  // Get secrets from injection above
  let secrets = await helper.load('secrets');

  // Do something with the secrets object
  let s = await secrets.get('thing-to-read');
  assume(s).is.a('string');

  // Make assertions over recorded calls
  assume(secrets.fakeCalls.get).deep.contains({
    name: 'thing-to-read',
  });

  try {
    await secrets.remove('...', {}); // throws and error because we didn't fake it
  } catch (err) {
    // pass
  }
});

You can create a Client class from a reference JSON object as illustrated below. This is unusual, as generally the latest version of the library contains pre-defined classes for all Taskcluster services.

const reference = {...}; // JSON from <rootUrl>/references/<serviceName>/<apiVersion>/api.json

// Create Client class
const MyClient = taskcluster.createClient(reference);

// Instantiate an instance of MyClient
const myClient = new MyClient(options);

// Make a request with a method on myClient
myClient.myMethod(arg1, arg2, payload).then(function(result) {
  // ...
});

To allow for more efficient routing between Taskcluster services running alongside each other in a Kubernetes cluster, this library has configurable support for using DNS for Services and Pods. To configure this on all clients created from this library, use taskcluster.setServiceDiscoveryScheme('k8s-dns'). To configure this for an instantiation of a client class or to override the setting back to default you can new taskcluster.Auth({..., serviceDiscoveryScheme: 'k8s-dns'});. The value for default behavior is default.

This library is co-versioned with Taskcluster itself. That is, a client with version x.y.z contains API methods corresponding to Taskcluster version x.y.z. Taskcluster is careful to maintain API compatibility, and guarantees it within a major version. That means that any client with version x.* will work against any Taskcluster services at version x.*, and is very likely to work for many other major versions of the Taskcluster services. Any incompatibilities are noted in the Changelog.