Stability: 2 - Stable
The node:test
module facilitates the creation of JavaScript tests.
To access it:
import test from 'node:test';
const test = require('node:test');
This module is only available under the node:
scheme. The following will not
work:
import test from 'test';
const test = require('test');
Tests created via the test
module consist of a single function that is
processed in one of three ways:
- A synchronous function that is considered failing if it throws an exception, and is considered passing otherwise.
- A function that returns a
Promise
that is considered failing if thePromise
rejects, and is considered passing if thePromise
fulfills. - A function that receives a callback function. If the callback receives any
truthy value as its first argument, the test is considered failing. If a
falsy value is passed as the first argument to the callback, the test is
considered passing. If the test function receives a callback function and
also returns a
Promise
, the test will fail.
The following example illustrates how tests are written using the
test
module.
test('synchronous passing test', (t) => {
// This test passes because it does not throw an exception.
assert.strictEqual(1, 1);
});
test('synchronous failing test', (t) => {
// This test fails because it throws an exception.
assert.strictEqual(1, 2);
});
test('asynchronous passing test', async (t) => {
// This test passes because the Promise returned by the async
// function is settled and not rejected.
assert.strictEqual(1, 1);
});
test('asynchronous failing test', async (t) => {
// This test fails because the Promise returned by the async
// function is rejected.
assert.strictEqual(1, 2);
});
test('failing test using Promises', (t) => {
// Promises can be used directly as well.
return new Promise((resolve, reject) => {
setImmediate(() => {
reject(new Error('this will cause the test to fail'));
});
});
});
test('callback passing test', (t, done) => {
// done() is the callback function. When the setImmediate() runs, it invokes
// done() with no arguments.
setImmediate(done);
});
test('callback failing test', (t, done) => {
// When the setImmediate() runs, done() is invoked with an Error object and
// the test fails.
setImmediate(() => {
done(new Error('callback failure'));
});
});
If any tests fail, the process exit code is set to 1
.
The test context's test()
method allows subtests to be created.
It allows you to structure your tests in a hierarchical manner,
where you can create nested tests within a larger test.
This method behaves identically to the top level test()
function.
The following example demonstrates the creation of a
top level test with two subtests.
test('top level test', async (t) => {
await t.test('subtest 1', (t) => {
assert.strictEqual(1, 1);
});
await t.test('subtest 2', (t) => {
assert.strictEqual(2, 2);
});
});
Note:
beforeEach
andafterEach
hooks are triggered between each subtest execution.
In this example, await
is used to ensure that both subtests have completed.
This is necessary because tests do not wait for their subtests to
complete, unlike tests created within suites.
Any subtests that are still outstanding when their parent finishes
are cancelled and treated as failures. Any subtest failures cause the parent
test to fail.
Individual tests can be skipped by passing the skip
option to the test, or by
calling the test context's skip()
method as shown in the
following example.
// The skip option is used, but no message is provided.
test('skip option', { skip: true }, (t) => {
// This code is never executed.
});
// The skip option is used, and a message is provided.
test('skip option with message', { skip: 'this is skipped' }, (t) => {
// This code is never executed.
});
test('skip() method', (t) => {
// Make sure to return here as well if the test contains additional logic.
t.skip();
});
test('skip() method with message', (t) => {
// Make sure to return here as well if the test contains additional logic.
t.skip('this is skipped');
});
Individual tests can be marked as flaky or incomplete by passing the todo
option to the test, or by calling the test context's todo()
method, as shown
in the following example. These tests represent a pending implementation or bug
that needs to be fixed. TODO tests are executed, but are not treated as test
failures, and therefore do not affect the process exit code. If a test is marked
as both TODO and skipped, the TODO option is ignored.
// The todo option is used, but no message is provided.
test('todo option', { todo: true }, (t) => {
// This code is executed, but not treated as a failure.
throw new Error('this does not fail the test');
});
// The todo option is used, and a message is provided.
test('todo option with message', { todo: 'this is a todo test' }, (t) => {
// This code is executed.
});
test('todo() method', (t) => {
t.todo();
});
test('todo() method with message', (t) => {
t.todo('this is a todo test and is not treated as a failure');
throw new Error('this does not fail the test');
});
Suites and tests can also be written using the describe()
and it()
functions. describe()
is an alias for suite()
, and it()
is an
alias for test()
.
describe('A thing', () => {
it('should work', () => {
assert.strictEqual(1, 1);
});
it('should be ok', () => {
assert.strictEqual(2, 2);
});
describe('a nested thing', () => {
it('should work', () => {
assert.strictEqual(3, 3);
});
});
});
describe()
and it()
are imported from the node:test
module.
import { describe, it } from 'node:test';
const { describe, it } = require('node:test');
If Node.js is started with the --test-only
command-line option, it is
possible to skip all tests except for a selected subset by passing
the only
option to the tests that should run. When a test with the only
option is set, all subtests are also run.
If a suite has the only
option set, all tests within the suite are run,
unless it has descendants with the only
option set, in which case only those
tests are run.
When using subtests within a test()
/it()
, it is required to mark
all ancestor tests with the only
option to run only a
selected subset of tests.
The test context's runOnly()
method can be used to implement the same behavior at the subtest level. Tests
that are not executed are omitted from the test runner output.
// Assume Node.js is run with the --test-only command-line option.
// The suite's 'only' option is set, so these tests are run.
test('this test is run', { only: true }, async (t) => {
// Within this test, all subtests are run by default.
await t.test('running subtest');
// The test context can be updated to run subtests with the 'only' option.
t.runOnly(true);
await t.test('this subtest is now skipped');
await t.test('this subtest is run', { only: true });
// Switch the context back to execute all tests.
t.runOnly(false);
await t.test('this subtest is now run');
// Explicitly do not run these tests.
await t.test('skipped subtest 3', { only: false });
await t.test('skipped subtest 4', { skip: true });
});
// The 'only' option is not set, so this test is skipped.
test('this test is not run', () => {
// This code is not run.
throw new Error('fail');
});
describe('a suite', () => {
// The 'only' option is set, so this test is run.
it('this test is run', { only: true }, () => {
// This code is run.
});
it('this test is not run', () => {
// This code is not run.
throw new Error('fail');
});
});
describe.only('a suite', () => {
// The 'only' option is set, so this test is run.
it('this test is run', () => {
// This code is run.
});
it('this test is run', () => {
// This code is run.
});
});
The --test-name-pattern
command-line option can be used to only run
tests whose name matches the provided pattern, and the
--test-skip-pattern
option can be used to skip tests whose name
matches the provided pattern. Test name patterns are interpreted as
JavaScript regular expressions. The --test-name-pattern
and
--test-skip-pattern
options can be specified multiple times in order to run
nested tests. For each test that is executed, any corresponding test hooks,
such as beforeEach()
, are also run. Tests that are not executed are omitted
from the test runner output.
Given the following test file, starting Node.js with the
--test-name-pattern="test [1-3]"
option would cause the test runner to execute
test 1
, test 2
, and test 3
. If test 1
did not match the test name
pattern, then its subtests would not execute, despite matching the pattern. The
same set of tests could also be executed by passing --test-name-pattern
multiple times (e.g. --test-name-pattern="test 1"
,
--test-name-pattern="test 2"
, etc.).
test('test 1', async (t) => {
await t.test('test 2');
await t.test('test 3');
});
test('Test 4', async (t) => {
await t.test('Test 5');
await t.test('test 6');
});
Test name patterns can also be specified using regular expression literals. This
allows regular expression flags to be used. In the previous example, starting
Node.js with --test-name-pattern="/test [4-5]/i"
(or --test-skip-pattern="/test [4-5]/i"
)
would match Test 4
and Test 5
because the pattern is case-insensitive.
To match a single test with a pattern, you can prefix it with all its ancestor test names separated by space, to ensure it is unique. For example, given the following test file:
describe('test 1', (t) => {
it('some test');
});
describe('test 2', (t) => {
it('some test');
});
Starting Node.js with --test-name-pattern="test 1 some test"
would match
only some test
in test 1
.
Test name patterns do not change the set of files that the test runner executes.
If both --test-name-pattern
and --test-skip-pattern
are supplied,
tests must satisfy both requirements in order to be executed.
Once a test function finishes executing, the results are reported as quickly as possible while maintaining the order of the tests. However, it is possible for the test function to generate asynchronous activity that outlives the test itself. The test runner handles this type of activity, but does not delay the reporting of test results in order to accommodate it.
In the following example, a test completes with two setImmediate()
operations still outstanding. The first setImmediate()
attempts to create a
new subtest. Because the parent test has already finished and output its
results, the new subtest is immediately marked as failed, and reported later
to the {TestsStream}.
The second setImmediate()
creates an uncaughtException
event.
uncaughtException
and unhandledRejection
events originating from a completed
test are marked as failed by the test
module and reported as diagnostic
warnings at the top level by the {TestsStream}.
test('a test that creates asynchronous activity', (t) => {
setImmediate(() => {
t.test('subtest that is created too late', (t) => {
throw new Error('error1');
});
});
setImmediate(() => {
throw new Error('error2');
});
// The test finishes after this line.
});
Stability: 1 - Experimental
The Node.js test runner supports running in watch mode by passing the --watch
flag:
node --test --watch
In watch mode, the test runner will watch for changes to test files and their dependencies. When a change is detected, the test runner will rerun the tests affected by the change. The test runner will continue to run until the process is terminated.
The Node.js test runner can be invoked from the command line by passing the
--test
flag:
node --test
By default, Node.js will run all files matching these patterns:
**/*.test.?(c|m)js
**/*-test.?(c|m)js
**/*_test.?(c|m)js
**/test-*.?(c|m)js
**/test.?(c|m)js
**/test/**/*.?(c|m)js
Alternatively, one or more glob patterns can be provided as the
final argument(s) to the Node.js command, as shown below.
Glob patterns follow the behavior of glob(7)
.
The glob patterns should be enclosed in double quotes on the command line to
prevent shell expansion, which can reduce portability across systems.
node --test "**/*.test.js" "**/*.spec.js"
Matching files are executed as test files. More information on the test file execution can be found in the test runner execution model section.
Each matching test file is executed in a separate child process. The maximum
number of child processes running at any time is controlled by the
--test-concurrency
flag. If the child process finishes with an exit code
of 0, the test is considered passing. Otherwise, the test is considered to be a
failure. Test files must be executable by Node.js, but are not required to use
the node:test
module internally.
Each test file is executed as if it was a regular script. That is, if the test
file itself uses node:test
to define tests, all of those tests will be
executed within a single application thread, regardless of the value of the
concurrency
option of test()
.
Stability: 1 - Experimental
When Node.js is started with the --experimental-test-coverage
command-line flag, code coverage is collected and statistics are reported once
all tests have completed. If the NODE_V8_COVERAGE
environment variable is
used to specify a code coverage directory, the generated V8 coverage files are
written to that directory. Node.js core modules and files within
node_modules/
directories are not included in the coverage report. If
coverage is enabled, the coverage report is sent to any test reporters via
the 'test:coverage'
event.
Coverage can be disabled on a series of lines using the following comment syntax:
/* node:coverage disable */
if (anAlwaysFalseCondition) {
// Code in this branch will never be executed, but the lines are ignored for
// coverage purposes. All lines following the 'disable' comment are ignored
// until a corresponding 'enable' comment is encountered.
console.log('this is never executed');
}
/* node:coverage enable */
Coverage can also be disabled for a specified number of lines. After the specified number of lines, coverage will be automatically reenabled. If the number of lines is not explicitly provided, a single line is ignored.
/* node:coverage ignore next */
if (anAlwaysFalseCondition) { console.log('this is never executed'); }
/* node:coverage ignore next 3 */
if (anAlwaysFalseCondition) {
console.log('this is never executed');
}
The tap and spec reporters will print a summary of the coverage statistics. There is also an lcov reporter that will generate an lcov file which can be used as an in depth coverage report.
node --test --experimental-test-coverage --test-reporter=lcov --test-reporter-destination=lcov.info
The test runner's code coverage functionality does not support excluding specific files or directories from the coverage report.
The node:test
module supports mocking during testing via a top-level mock
object. The following example creates a spy on a function that adds two numbers
together. The spy is then used to assert that the function was called as
expected.
import assert from 'node:assert';
import { mock, test } from 'node:test';
test('spies on a function', () => {
const sum = mock.fn((a, b) => {
return a + b;
});
assert.strictEqual(sum.mock.calls.length, 0);
assert.strictEqual(sum(3, 4), 7);
assert.strictEqual(sum.mock.calls.length, 1);
const call = sum.mock.calls[0];
assert.deepStrictEqual(call.arguments, [3, 4]);
assert.strictEqual(call.result, 7);
assert.strictEqual(call.error, undefined);
// Reset the globally tracked mocks.
mock.reset();
});
'use strict';
const assert = require('node:assert');
const { mock, test } = require('node:test');
test('spies on a function', () => {
const sum = mock.fn((a, b) => {
return a + b;
});
assert.strictEqual(sum.mock.calls.length, 0);
assert.strictEqual(sum(3, 4), 7);
assert.strictEqual(sum.mock.calls.length, 1);
const call = sum.mock.calls[0];
assert.deepStrictEqual(call.arguments, [3, 4]);
assert.strictEqual(call.result, 7);
assert.strictEqual(call.error, undefined);
// Reset the globally tracked mocks.
mock.reset();
});
The same mocking functionality is also exposed on the TestContext
object
of each test. The following example creates a spy on an object method using the
API exposed on the TestContext
. The benefit of mocking via the test context is
that the test runner will automatically restore all mocked functionality once
the test finishes.
test('spies on an object method', (t) => {
const number = {
value: 5,
add(a) {
return this.value + a;
},
};
t.mock.method(number, 'add');
assert.strictEqual(number.add.mock.calls.length, 0);
assert.strictEqual(number.add(3), 8);
assert.strictEqual(number.add.mock.calls.length, 1);
const call = number.add.mock.calls[0];
assert.deepStrictEqual(call.arguments, [3]);
assert.strictEqual(call.result, 8);
assert.strictEqual(call.target, undefined);
assert.strictEqual(call.this, number);
});
Mocking timers is a technique commonly used in software testing to simulate and
control the behavior of timers, such as setInterval
and setTimeout
,
without actually waiting for the specified time intervals.
Refer to the MockTimers
class for a full list of methods and features.
This allows developers to write more reliable and predictable tests for time-dependent functionality.
The example below shows how to mock setTimeout
.
Using .enable({ apis: ['setTimeout'] });
it will mock the setTimeout
functions in the node:timers and
node:timers/promises modules,
as well as from the Node.js global context.
Note: Destructuring functions such as
import { setTimeout } from 'node:timers'
is currently not supported by this API.
import assert from 'node:assert';
import { mock, test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', () => {
const fn = mock.fn();
// Optionally choose what to mock
mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
// Reset the globally tracked mocks.
mock.timers.reset();
// If you call reset mock instance, it will also reset timers instance
mock.reset();
});
const assert = require('node:assert');
const { mock, test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', () => {
const fn = mock.fn();
// Optionally choose what to mock
mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
// Reset the globally tracked mocks.
mock.timers.reset();
// If you call reset mock instance, it will also reset timers instance
mock.reset();
});
The same mocking functionality is also exposed in the mock property on the TestContext
object
of each test. The benefit of mocking via the test context is
that the test runner will automatically restore all mocked timers
functionality once the test finishes.
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
});
The mock timers API also allows the mocking of the Date
object. This is a
useful feature for testing time-dependent functionality, or to simulate
internal calendar functions such as Date.now()
.
The dates implementation is also part of the MockTimers
class. Refer to it
for a full list of methods and features.
Note: Dates and timers are dependent when mocked together. This means that
if you have both the Date
and setTimeout
mocked, advancing the time will
also advance the mocked date as they simulate a single internal clock.
The example below show how to mock the Date
object and obtain the current
Date.now()
value.
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks the Date object', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'] });
// If not specified, the initial date will be based on 0 in the UNIX epoch
assert.strictEqual(Date.now(), 0);
// Advance in time will also advance the date
context.mock.timers.tick(9999);
assert.strictEqual(Date.now(), 9999);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks the Date object', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'] });
// If not specified, the initial date will be based on 0 in the UNIX epoch
assert.strictEqual(Date.now(), 0);
// Advance in time will also advance the date
context.mock.timers.tick(9999);
assert.strictEqual(Date.now(), 9999);
});
If there is no initial epoch set, the initial date will be based on 0 in the
Unix epoch. This is January 1st, 1970, 00:00:00 UTC. You can set an initial date
by passing a now
property to the .enable()
method. This value will be used
as the initial date for the mocked Date
object. It can either be a positive
integer, or another Date object.
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks the Date object with initial time', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'], now: 100 });
assert.strictEqual(Date.now(), 100);
// Advance in time will also advance the date
context.mock.timers.tick(200);
assert.strictEqual(Date.now(), 300);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks the Date object with initial time', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'], now: 100 });
assert.strictEqual(Date.now(), 100);
// Advance in time will also advance the date
context.mock.timers.tick(200);
assert.strictEqual(Date.now(), 300);
});
You can use the .setTime()
method to manually move the mocked date to another
time. This method only accepts a positive integer.
Note: This method will execute any mocked timers that are in the past from the new time.
In the below example we are setting a new time for the mocked date.
import assert from 'node:assert';
import { test } from 'node:test';
test('sets the time of a date object', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'], now: 100 });
assert.strictEqual(Date.now(), 100);
// Advance in time will also advance the date
context.mock.timers.setTime(1000);
context.mock.timers.tick(200);
assert.strictEqual(Date.now(), 1200);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('sets the time of a date object', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['Date'], now: 100 });
assert.strictEqual(Date.now(), 100);
// Advance in time will also advance the date
context.mock.timers.setTime(1000);
context.mock.timers.tick(200);
assert.strictEqual(Date.now(), 1200);
});
If you have any timer that's set to run in the past, it will be executed as if
the .tick()
method has been called. This is useful if you want to test
time-dependent functionality that's already in the past.
import assert from 'node:assert';
import { test } from 'node:test';
test('runs timers as setTime passes ticks', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const fn = context.mock.fn();
setTimeout(fn, 1000);
context.mock.timers.setTime(800);
// Timer is not executed as the time is not yet reached
assert.strictEqual(fn.mock.callCount(), 0);
assert.strictEqual(Date.now(), 800);
context.mock.timers.setTime(1200);
// Timer is executed as the time is now reached
assert.strictEqual(fn.mock.callCount(), 1);
assert.strictEqual(Date.now(), 1200);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('runs timers as setTime passes ticks', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const fn = context.mock.fn();
setTimeout(fn, 1000);
context.mock.timers.setTime(800);
// Timer is not executed as the time is not yet reached
assert.strictEqual(fn.mock.callCount(), 0);
assert.strictEqual(Date.now(), 800);
context.mock.timers.setTime(1200);
// Timer is executed as the time is now reached
assert.strictEqual(fn.mock.callCount(), 1);
assert.strictEqual(Date.now(), 1200);
});
Using .runAll()
will execute all timers that are currently in the queue. This
will also advance the mocked date to the time of the last timer that was
executed as if the time has passed.
import assert from 'node:assert';
import { test } from 'node:test';
test('runs timers as setTime passes ticks', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const fn = context.mock.fn();
setTimeout(fn, 1000);
setTimeout(fn, 2000);
setTimeout(fn, 3000);
context.mock.timers.runAll();
// All timers are executed as the time is now reached
assert.strictEqual(fn.mock.callCount(), 3);
assert.strictEqual(Date.now(), 3000);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('runs timers as setTime passes ticks', (context) => {
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const fn = context.mock.fn();
setTimeout(fn, 1000);
setTimeout(fn, 2000);
setTimeout(fn, 3000);
context.mock.timers.runAll();
// All timers are executed as the time is now reached
assert.strictEqual(fn.mock.callCount(), 3);
assert.strictEqual(Date.now(), 3000);
});
Stability: 1.0 - Early development
Snapshot tests allow arbitrary values to be serialized into string values and
compared against a set of known good values. The known good values are known as
snapshots, and are stored in a snapshot file. Snapshot files are managed by the
test runner, but are designed to be human readable to aid in debugging. Best
practice is for snapshot files to be checked into source control along with your
test files. In order to enable snapshot testing, Node.js must be started with
the --experimental-test-snapshots
command-line flag.
Snapshot files are generated by starting Node.js with the
--test-update-snapshots
command-line flag. A separate snapshot file is
generated for each test file. By default, the snapshot file has the same name
as process.argv[1]
with a .snapshot
file extension. This behavior can be
configured using the snapshot.setResolveSnapshotPath()
function. Each
snapshot assertion corresponds to an export in the snapshot file.
An example snapshot test is shown below. The first time this test is executed, it will fail because the corresponding snapshot file does not exist.
// test.js
suite('suite of snapshot tests', () => {
test('snapshot test', (t) => {
t.assert.snapshot({ value1: 1, value2: 2 });
t.assert.snapshot(5);
});
});
Generate the snapshot file by running the test file with
--test-update-snapshots
. The test should pass, and a file named
test.js.snapshot
is created in the same directory as the test file. The
contents of the snapshot file are shown below. Each snapshot is identified by
the full name of test and a counter to differentiate between snapshots in the
same test.
exports[`suite of snapshot tests > snapshot test 1`] = `
{
"value1": 1,
"value2": 2
}
`;
exports[`suite of snapshot tests > snapshot test 2`] = `
5
`;
Once the snapshot file is created, run the tests again without the
--test-update-snapshots
flag. The tests should pass now.
The node:test
module supports passing --test-reporter
flags for the test runner to use a specific reporter.
The following built-reporters are supported:
-
tap
Thetap
reporter outputs the test results in the TAP format. -
spec
Thespec
reporter outputs the test results in a human-readable format. -
dot
Thedot
reporter outputs the test results in a compact format, where each passing test is represented by a.
, and each failing test is represented by aX
. -
junit
The junit reporter outputs test results in a jUnit XML format -
lcov
Thelcov
reporter outputs test coverage when used with the--experimental-test-coverage
flag.
When stdout
is a TTY, the spec
reporter is used by default.
Otherwise, the tap
reporter is used by default.
The exact output of these reporters is subject to change between versions of Node.js, and should not be relied on programmatically. If programmatic access to the test runner's output is required, use the events emitted by the {TestsStream}.
The reporters are available via the node:test/reporters
module:
import { tap, spec, dot, junit, lcov } from 'node:test/reporters';
const { tap, spec, dot, junit, lcov } = require('node:test/reporters');
--test-reporter
can be used to specify a path to custom reporter.
A custom reporter is a module that exports a value
accepted by stream.compose.
Reporters should transform events emitted by a {TestsStream}
Example of a custom reporter using {stream.Transform}:
import { Transform } from 'node:stream';
const customReporter = new Transform({
writableObjectMode: true,
transform(event, encoding, callback) {
switch (event.type) {
case 'test:dequeue':
callback(null, `test ${event.data.name} dequeued`);
break;
case 'test:enqueue':
callback(null, `test ${event.data.name} enqueued`);
break;
case 'test:watch:drained':
callback(null, 'test watch queue drained');
break;
case 'test:start':
callback(null, `test ${event.data.name} started`);
break;
case 'test:pass':
callback(null, `test ${event.data.name} passed`);
break;
case 'test:fail':
callback(null, `test ${event.data.name} failed`);
break;
case 'test:plan':
callback(null, 'test plan');
break;
case 'test:diagnostic':
case 'test:stderr':
case 'test:stdout':
callback(null, event.data.message);
break;
case 'test:coverage': {
const { totalLineCount } = event.data.summary.totals;
callback(null, `total line count: ${totalLineCount}\n`);
break;
}
}
},
});
export default customReporter;
const { Transform } = require('node:stream');
const customReporter = new Transform({
writableObjectMode: true,
transform(event, encoding, callback) {
switch (event.type) {
case 'test:dequeue':
callback(null, `test ${event.data.name} dequeued`);
break;
case 'test:enqueue':
callback(null, `test ${event.data.name} enqueued`);
break;
case 'test:watch:drained':
callback(null, 'test watch queue drained');
break;
case 'test:start':
callback(null, `test ${event.data.name} started`);
break;
case 'test:pass':
callback(null, `test ${event.data.name} passed`);
break;
case 'test:fail':
callback(null, `test ${event.data.name} failed`);
break;
case 'test:plan':
callback(null, 'test plan');
break;
case 'test:diagnostic':
case 'test:stderr':
case 'test:stdout':
callback(null, event.data.message);
break;
case 'test:coverage': {
const { totalLineCount } = event.data.summary.totals;
callback(null, `total line count: ${totalLineCount}\n`);
break;
}
}
},
});
module.exports = customReporter;
Example of a custom reporter using a generator function:
export default async function * customReporter(source) {
for await (const event of source) {
switch (event.type) {
case 'test:dequeue':
yield `test ${event.data.name} dequeued`;
break;
case 'test:enqueue':
yield `test ${event.data.name} enqueued`;
break;
case 'test:watch:drained':
yield 'test watch queue drained';
break;
case 'test:start':
yield `test ${event.data.name} started\n`;
break;
case 'test:pass':
yield `test ${event.data.name} passed\n`;
break;
case 'test:fail':
yield `test ${event.data.name} failed\n`;
break;
case 'test:plan':
yield 'test plan';
break;
case 'test:diagnostic':
case 'test:stderr':
case 'test:stdout':
yield `${event.data.message}\n`;
break;
case 'test:coverage': {
const { totalLineCount } = event.data.summary.totals;
yield `total line count: ${totalLineCount}\n`;
break;
}
}
}
}
module.exports = async function * customReporter(source) {
for await (const event of source) {
switch (event.type) {
case 'test:dequeue':
yield `test ${event.data.name} dequeued`;
break;
case 'test:enqueue':
yield `test ${event.data.name} enqueued`;
break;
case 'test:watch:drained':
yield 'test watch queue drained';
break;
case 'test:start':
yield `test ${event.data.name} started\n`;
break;
case 'test:pass':
yield `test ${event.data.name} passed\n`;
break;
case 'test:fail':
yield `test ${event.data.name} failed\n`;
break;
case 'test:plan':
yield 'test plan\n';
break;
case 'test:diagnostic':
case 'test:stderr':
case 'test:stdout':
yield `${event.data.message}\n`;
break;
case 'test:coverage': {
const { totalLineCount } = event.data.summary.totals;
yield `total line count: ${totalLineCount}\n`;
break;
}
}
}
};
The value provided to --test-reporter
should be a string like one used in an
import()
in JavaScript code, or a value provided for --import
.
The --test-reporter
flag can be specified multiple times to report test
results in several formats. In this situation
it is required to specify a destination for each reporter
using --test-reporter-destination
.
Destination can be stdout
, stderr
, or a file path.
Reporters and destinations are paired according
to the order they were specified.
In the following example, the spec
reporter will output to stdout
,
and the dot
reporter will output to file.txt
:
node --test-reporter=spec --test-reporter=dot --test-reporter-destination=stdout --test-reporter-destination=file.txt
When a single reporter is specified, the destination will default to stdout
,
unless a destination is explicitly provided.
options
{Object} Configuration options for running tests. The following properties are supported:concurrency
{number|boolean} If a number is provided, then that many test processes would run in parallel, where each process corresponds to one test file. Iftrue
, it would runos.availableParallelism() - 1
test files in parallel. Iffalse
, it would only run one test file at a time. Default:false
.files
: {Array} An array containing the list of files to run. Default matching files from test runner execution model.forceExit
: {boolean} Configures the test runner to exit the process once all known tests have finished executing even if the event loop would otherwise remain active. Default:false
.inspectPort
{number|Function} Sets inspector port of test child process. This can be a number, or a function that takes no arguments and returns a number. If a nullish value is provided, each process gets its own port, incremented from the primary'sprocess.debugPort
. Default:undefined
.only
: {boolean} If truthy, the test context will only run tests that have theonly
option setsetup
{Function} A function that accepts theTestsStream
instance and can be used to setup listeners before any tests are run. Default:undefined
.signal
{AbortSignal} Allows aborting an in-progress test execution.testNamePatterns
{string|RegExp|Array} A String, RegExp or a RegExp Array, that can be used to only run tests whose name matches the provided pattern. Test name patterns are interpreted as JavaScript regular expressions. For each test that is executed, any corresponding test hooks, such asbeforeEach()
, are also run. Default:undefined
.timeout
{number} A number of milliseconds the test execution will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.watch
{boolean} Whether to run in watch mode or not. Default:false
.shard
{Object} Running tests in a specific shard. Default:undefined
.index
{number} is a positive integer between 1 and<total>
that specifies the index of the shard to run. This option is required.total
{number} is a positive integer that specifies the total number of shards to split the test files to. This option is required.
- Returns: {TestsStream}
Note: shard
is used to horizontally parallelize test running across
machines or processes, ideal for large-scale executions across varied
environments. It's incompatible with watch
mode, tailored for rapid
code iteration by automatically rerunning tests on file changes.
import { tap } from 'node:test/reporters';
import { run } from 'node:test';
import process from 'node:process';
import path from 'node:path';
run({ files: [path.resolve('./tests/test.js')] })
.on('test:fail', () => {
process.exitCode = 1;
})
.compose(tap)
.pipe(process.stdout);
const { tap } = require('node:test/reporters');
const { run } = require('node:test');
const path = require('node:path');
run({ files: [path.resolve('./tests/test.js')] })
.on('test:fail', () => {
process.exitCode = 1;
})
.compose(tap)
.pipe(process.stdout);
name
{string} The name of the suite, which is displayed when reporting test results. Default: Thename
property offn
, or'<anonymous>'
iffn
does not have a name.options
{Object} Optional configuration options for the suite. This supports the same options astest([name][, options][, fn])
.fn
{Function|AsyncFunction} The suite function declaring nested tests and suites. The first argument to this function is aSuiteContext
object. Default: A no-op function.- Returns: {Promise} Immediately fulfilled with
undefined
.
The suite()
function is imported from the node:test
module.
Shorthand for skipping a suite. This is the same as
suite([name], { skip: true }[, fn])
.
Shorthand for marking a suite as TODO
. This is the same as
suite([name], { todo: true }[, fn])
.
Shorthand for marking a suite as only
. This is the same as
suite([name], { only: true }[, fn])
.
name
{string} The name of the test, which is displayed when reporting test results. Default: Thename
property offn
, or'<anonymous>'
iffn
does not have a name.options
{Object} Configuration options for the test. The following properties are supported:concurrency
{number|boolean} If a number is provided, then that many tests would run in parallel within the application thread. Iftrue
, all scheduled asynchronous tests run concurrently within the thread. Iffalse
, only one test runs at a time. If unspecified, subtests inherit this value from their parent. Default:false
.only
{boolean} If truthy, and the test context is configured to runonly
tests, then this test will be run. Otherwise, the test is skipped. Default:false
.signal
{AbortSignal} Allows aborting an in-progress test.skip
{boolean|string} If truthy, the test is skipped. If a string is provided, that string is displayed in the test results as the reason for skipping the test. Default:false
.todo
{boolean|string} If truthy, the test marked asTODO
. If a string is provided, that string is displayed in the test results as the reason why the test isTODO
. Default:false
.timeout
{number} A number of milliseconds the test will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.plan
{number} The number of assertions and subtests expected to be run in the test. If the number of assertions run in the test does not match the number specified in the plan, the test will fail. Default:undefined
.
fn
{Function|AsyncFunction} The function under test. The first argument to this function is aTestContext
object. If the test uses callbacks, the callback function is passed as the second argument. Default: A no-op function.- Returns: {Promise} Fulfilled with
undefined
once the test completes, or immediately if the test runs within a suite.
The test()
function is the value imported from the test
module. Each
invocation of this function results in reporting the test to the {TestsStream}.
The TestContext
object passed to the fn
argument can be used to perform
actions related to the current test. Examples include skipping the test, adding
additional diagnostic information, or creating subtests.
test()
returns a Promise
that fulfills once the test completes.
if test()
is called within a suite, it fulfills immediately.
The return value can usually be discarded for top level tests.
However, the return value from subtests should be used to prevent the parent
test from finishing first and cancelling the subtest
as shown in the following example.
test('top level test', async (t) => {
// The setTimeout() in the following subtest would cause it to outlive its
// parent test if 'await' is removed on the next line. Once the parent test
// completes, it will cancel any outstanding subtests.
await t.test('longer running subtest', async (t) => {
return new Promise((resolve, reject) => {
setTimeout(resolve, 1000);
});
});
});
The timeout
option can be used to fail the test if it takes longer than
timeout
milliseconds to complete. However, it is not a reliable mechanism for
canceling tests because a running test might block the application thread and
thus prevent the scheduled cancellation.
Shorthand for skipping a test,
same as test([name], { skip: true }[, fn])
.
Shorthand for marking a test as TODO
,
same as test([name], { todo: true }[, fn])
.
Shorthand for marking a test as only
,
same as test([name], { only: true }[, fn])
.
Alias for suite()
.
The describe()
function is imported from the node:test
module.
Shorthand for skipping a suite. This is the same as
describe([name], { skip: true }[, fn])
.
Shorthand for marking a suite as TODO
. This is the same as
describe([name], { todo: true }[, fn])
.
Shorthand for marking a suite as only
. This is the same as
describe([name], { only: true }[, fn])
.
Alias for test()
.
The it()
function is imported from the node:test
module.
Shorthand for skipping a test,
same as it([name], { skip: true }[, fn])
.
Shorthand for marking a test as TODO
,
same as it([name], { todo: true }[, fn])
.
Shorthand for marking a test as only
,
same as it([name], { only: true }[, fn])
.
fn
{Function|AsyncFunction} The hook function. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function creates a hook that runs before executing a suite.
describe('tests', async () => {
before(() => console.log('about to run some test'));
it('is a subtest', () => {
assert.ok('some relevant assertion here');
});
});
fn
{Function|AsyncFunction} The hook function. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function creates a hook that runs after executing a suite.
describe('tests', async () => {
after(() => console.log('finished running tests'));
it('is a subtest', () => {
assert.ok('some relevant assertion here');
});
});
Note: The after
hook is guaranteed to run,
even if tests within the suite fail.
fn
{Function|AsyncFunction} The hook function. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function creates a hook that runs before each test in the current suite.
describe('tests', async () => {
beforeEach(() => console.log('about to run a test'));
it('is a subtest', () => {
assert.ok('some relevant assertion here');
});
});
fn
{Function|AsyncFunction} The hook function. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function creates a hook that runs after each test in the current suite.
The afterEach()
hook is run even if the test fails.
describe('tests', async () => {
afterEach(() => console.log('finished running a test'));
it('is a subtest', () => {
assert.ok('some relevant assertion here');
});
});
Stability: 1.0 - Early development
An object whose methods are used to configure default snapshot settings in the
current process. It is possible to apply the same configuration to all files by
placing common configuration code in a module preloaded with --require
or
--import
.
Stability: 1.0 - Early development
serializers
{Array} An array of synchronous functions used as the default serializers for snapshot tests.
This function is used to customize the default serialization mechanism used by
the test runner. By default, the test runner performs serialization by calling
JSON.stringify(value, null, 2)
on the provided value. JSON.stringify()
does
have limitations regarding circular structures and supported data types. If a
more robust serialization mechanism is required, this function should be used.
Stability: 1.0 - Early development
fn
{Function} A function used to compute the location of the snapshot file. The function receives the path of the test file as its only argument. If theprocess.argv[1]
is not associated with a file (for example in the REPL), the input is undefined.fn()
must return a string specifying the location of the snapshot file.
This function is used to customize the location of the snapshot file used for
snapshot testing. By default, the snapshot filename is the same as the entry
point filename with a .snapshot
file extension.
The MockFunctionContext
class is used to inspect or manipulate the behavior of
mocks created via the MockTracker
APIs.
- {Array}
A getter that returns a copy of the internal array used to track calls to the mock. Each entry in the array is an object with the following properties.
arguments
{Array} An array of the arguments passed to the mock function.error
{any} If the mocked function threw then this property contains the thrown value. Default:undefined
.result
{any} The value returned by the mocked function.stack
{Error} AnError
object whose stack can be used to determine the callsite of the mocked function invocation.target
{Function|undefined} If the mocked function is a constructor, this field contains the class being constructed. Otherwise this will beundefined
.this
{any} The mocked function'sthis
value.
- Returns: {integer} The number of times that this mock has been invoked.
This function returns the number of times that this mock has been invoked. This
function is more efficient than checking ctx.calls.length
because ctx.calls
is a getter that creates a copy of the internal call tracking array.
implementation
{Function|AsyncFunction} The function to be used as the mock's new implementation.
This function is used to change the behavior of an existing mock.
The following example creates a mock function using t.mock.fn()
, calls the
mock function, and then changes the mock implementation to a different function.
test('changes a mock behavior', (t) => {
let cnt = 0;
function addOne() {
cnt++;
return cnt;
}
function addTwo() {
cnt += 2;
return cnt;
}
const fn = t.mock.fn(addOne);
assert.strictEqual(fn(), 1);
fn.mock.mockImplementation(addTwo);
assert.strictEqual(fn(), 3);
assert.strictEqual(fn(), 5);
});
implementation
{Function|AsyncFunction} The function to be used as the mock's implementation for the invocation number specified byonCall
.onCall
{integer} The invocation number that will useimplementation
. If the specified invocation has already occurred then an exception is thrown. Default: The number of the next invocation.
This function is used to change the behavior of an existing mock for a single
invocation. Once invocation onCall
has occurred, the mock will revert to
whatever behavior it would have used had mockImplementationOnce()
not been
called.
The following example creates a mock function using t.mock.fn()
, calls the
mock function, changes the mock implementation to a different function for the
next invocation, and then resumes its previous behavior.
test('changes a mock behavior once', (t) => {
let cnt = 0;
function addOne() {
cnt++;
return cnt;
}
function addTwo() {
cnt += 2;
return cnt;
}
const fn = t.mock.fn(addOne);
assert.strictEqual(fn(), 1);
fn.mock.mockImplementationOnce(addTwo);
assert.strictEqual(fn(), 3);
assert.strictEqual(fn(), 4);
});
Resets the call history of the mock function.
Resets the implementation of the mock function to its original behavior. The mock can still be used after calling this function.
Stability: 1.0 - Early development
The MockModuleContext
class is used to manipulate the behavior of module mocks
created via the MockTracker
APIs.
Resets the implementation of the mock module.
The MockTracker
class is used to manage mocking functionality. The test runner
module provides a top level mock
export which is a MockTracker
instance.
Each test also provides its own MockTracker
instance via the test context's
mock
property.
original
{Function|AsyncFunction} An optional function to create a mock on. Default: A no-op function.implementation
{Function|AsyncFunction} An optional function used as the mock implementation fororiginal
. This is useful for creating mocks that exhibit one behavior for a specified number of calls and then restore the behavior oforiginal
. Default: The function specified byoriginal
.options
{Object} Optional configuration options for the mock function. The following properties are supported:times
{integer} The number of times that the mock will use the behavior ofimplementation
. Once the mock function has been calledtimes
times, it will automatically restore the behavior oforiginal
. This value must be an integer greater than zero. Default:Infinity
.
- Returns: {Proxy} The mocked function. The mocked function contains a special
mock
property, which is an instance ofMockFunctionContext
, and can be used for inspecting and changing the behavior of the mocked function.
This function is used to create a mock function.
The following example creates a mock function that increments a counter by one
on each invocation. The times
option is used to modify the mock behavior such
that the first two invocations add two to the counter instead of one.
test('mocks a counting function', (t) => {
let cnt = 0;
function addOne() {
cnt++;
return cnt;
}
function addTwo() {
cnt += 2;
return cnt;
}
const fn = t.mock.fn(addOne, addTwo, { times: 2 });
assert.strictEqual(fn(), 2);
assert.strictEqual(fn(), 4);
assert.strictEqual(fn(), 5);
assert.strictEqual(fn(), 6);
});
This function is syntax sugar for MockTracker.method
with options.getter
set to true
.
object
{Object} The object whose method is being mocked.methodName
{string|symbol} The identifier of the method onobject
to mock. Ifobject[methodName]
is not a function, an error is thrown.implementation
{Function|AsyncFunction} An optional function used as the mock implementation forobject[methodName]
. Default: The original method specified byobject[methodName]
.options
{Object} Optional configuration options for the mock method. The following properties are supported:getter
{boolean} Iftrue
,object[methodName]
is treated as a getter. This option cannot be used with thesetter
option. Default: false.setter
{boolean} Iftrue
,object[methodName]
is treated as a setter. This option cannot be used with thegetter
option. Default: false.times
{integer} The number of times that the mock will use the behavior ofimplementation
. Once the mocked method has been calledtimes
times, it will automatically restore the original behavior. This value must be an integer greater than zero. Default:Infinity
.
- Returns: {Proxy} The mocked method. The mocked method contains a special
mock
property, which is an instance ofMockFunctionContext
, and can be used for inspecting and changing the behavior of the mocked method.
This function is used to create a mock on an existing object method. The following example demonstrates how a mock is created on an existing object method.
test('spies on an object method', (t) => {
const number = {
value: 5,
subtract(a) {
return this.value - a;
},
};
t.mock.method(number, 'subtract');
assert.strictEqual(number.subtract.mock.calls.length, 0);
assert.strictEqual(number.subtract(3), 2);
assert.strictEqual(number.subtract.mock.calls.length, 1);
const call = number.subtract.mock.calls[0];
assert.deepStrictEqual(call.arguments, [3]);
assert.strictEqual(call.result, 2);
assert.strictEqual(call.error, undefined);
assert.strictEqual(call.target, undefined);
assert.strictEqual(call.this, number);
});
Stability: 1.0 - Early development
specifier
{string} A string identifying the module to mock.options
{Object} Optional configuration options for the mock module. The following properties are supported:cache
{boolean} Iffalse
, each call torequire()
orimport()
generates a new mock module. Iftrue
, subsequent calls will return the same module mock, and the mock module is inserted into the CommonJS cache. Default: false.defaultExport
{any} An optional value used as the mocked module's default export. If this value is not provided, ESM mocks do not include a default export. If the mock is a CommonJS or builtin module, this setting is used as the value ofmodule.exports
. If this value is not provided, CJS and builtin mocks use an empty object as the value ofmodule.exports
.namedExports
{Object} An optional object whose keys and values are used to create the named exports of the mock module. If the mock is a CommonJS or builtin module, these values are copied ontomodule.exports
. Therefore, if a mock is created with both named exports and a non-object default export, the mock will throw an exception when used as a CJS or builtin module.
- Returns: {MockModuleContext} An object that can be used to manipulate the mock.
This function is used to mock the exports of ECMAScript modules, CommonJS modules, and Node.js builtin modules. Any references to the original module prior to mocking are not impacted. The following example demonstrates how a mock is created for a module.
test('mocks a builtin module in both module systems', async (t) => {
// Create a mock of 'node:readline' with a named export named 'fn', which
// does not exist in the original 'node:readline' module.
const mock = t.mock.module('node:readline', {
namedExports: { fn() { return 42; } },
});
let esmImpl = await import('node:readline');
let cjsImpl = require('node:readline');
// cursorTo() is an export of the original 'node:readline' module.
assert.strictEqual(esmImpl.cursorTo, undefined);
assert.strictEqual(cjsImpl.cursorTo, undefined);
assert.strictEqual(esmImpl.fn(), 42);
assert.strictEqual(cjsImpl.fn(), 42);
mock.restore();
// The mock is restored, so the original builtin module is returned.
esmImpl = await import('node:readline');
cjsImpl = require('node:readline');
assert.strictEqual(typeof esmImpl.cursorTo, 'function');
assert.strictEqual(typeof cjsImpl.cursorTo, 'function');
assert.strictEqual(esmImpl.fn, undefined);
assert.strictEqual(cjsImpl.fn, undefined);
});
This function restores the default behavior of all mocks that were previously
created by this MockTracker
and disassociates the mocks from the
MockTracker
instance. Once disassociated, the mocks can still be used, but the
MockTracker
instance can no longer be used to reset their behavior or
otherwise interact with them.
After each test completes, this function is called on the test context's
MockTracker
. If the global MockTracker
is used extensively, calling this
function manually is recommended.
This function restores the default behavior of all mocks that were previously
created by this MockTracker
. Unlike mock.reset()
, mock.restoreAll()
does
not disassociate the mocks from the MockTracker
instance.
This function is syntax sugar for MockTracker.method
with options.setter
set to true
.
Stability: 1 - Experimental
Mocking timers is a technique commonly used in software testing to simulate and
control the behavior of timers, such as setInterval
and setTimeout
,
without actually waiting for the specified time intervals.
MockTimers is also able to mock the Date
object.
The MockTracker
provides a top-level timers
export
which is a MockTimers
instance.
Enables timer mocking for the specified timers.
enableOptions
{Object} Optional configuration options for enabling timer mocking. The following properties are supported:apis
{Array} An optional array containing the timers to mock. The currently supported timer values are'setInterval'
,'setTimeout'
,'setImmediate'
, and'Date'
. Default:['setInterval', 'setTimeout', 'setImmediate', 'Date']
. If no array is provided, all time related APIs ('setInterval'
,'clearInterval'
,'setTimeout'
,'clearTimeout'
,'setImmediate'
,'clearImmediate'
, and'Date'
) will be mocked by default.now
{number | Date} An optional number or Date object representing the initial time (in milliseconds) to use as the value forDate.now()
. Default:0
.
Note: When you enable mocking for a specific timer, its associated clear function will also be implicitly mocked.
Note: Mocking Date
will affect the behavior of the mocked timers
as they use the same internal clock.
Example usage without setting initial time:
import { mock } from 'node:test';
mock.timers.enable({ apis: ['setInterval'] });
const { mock } = require('node:test');
mock.timers.enable({ apis: ['setInterval'] });
The above example enables mocking for the setInterval
timer and
implicitly mocks the clearInterval
function. Only the setInterval
and clearInterval
functions from node:timers,
node:timers/promises, and
globalThis
will be mocked.
Example usage with initial time set
import { mock } from 'node:test';
mock.timers.enable({ apis: ['Date'], now: 1000 });
const { mock } = require('node:test');
mock.timers.enable({ apis: ['Date'], now: 1000 });
Example usage with initial Date object as time set
import { mock } from 'node:test';
mock.timers.enable({ apis: ['Date'], now: new Date() });
const { mock } = require('node:test');
mock.timers.enable({ apis: ['Date'], now: new Date() });
Alternatively, if you call mock.timers.enable()
without any parameters:
All timers ('setInterval'
, 'clearInterval'
, 'setTimeout'
, 'clearTimeout'
,
'setImmediate'
, and 'clearImmediate'
) will be mocked. The setInterval
,
clearInterval
, setTimeout
, clearTimeout
, setImmediate
, and
clearImmediate
functions from node:timers
, node:timers/promises
, and
globalThis
will be mocked. As well as the global Date
object.
This function restores the default behavior of all mocks that were previously
created by this MockTimers
instance and disassociates the mocks
from the MockTracker
instance.
Note: After each test completes, this function is called on
the test context's MockTracker
.
import { mock } from 'node:test';
mock.timers.reset();
const { mock } = require('node:test');
mock.timers.reset();
Calls timers.reset()
.
Advances time for all mocked timers.
milliseconds
{number} The amount of time, in milliseconds, to advance the timers. Default:1
.
Note: This diverges from how setTimeout
in Node.js behaves and accepts
only positive numbers. In Node.js, setTimeout
with negative numbers is
only supported for web compatibility reasons.
The following example mocks a setTimeout
function and
by using .tick
advances in
time triggering all pending timers.
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
});
Alternatively, the .tick
function can be called many times
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout'] });
const nineSecs = 9000;
setTimeout(fn, nineSecs);
const threeSeconds = 3000;
context.mock.timers.tick(threeSeconds);
context.mock.timers.tick(threeSeconds);
context.mock.timers.tick(threeSeconds);
assert.strictEqual(fn.mock.callCount(), 1);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout'] });
const nineSecs = 9000;
setTimeout(fn, nineSecs);
const threeSeconds = 3000;
context.mock.timers.tick(threeSeconds);
context.mock.timers.tick(threeSeconds);
context.mock.timers.tick(threeSeconds);
assert.strictEqual(fn.mock.callCount(), 1);
});
Advancing time using .tick
will also advance the time for any Date
object
created after the mock was enabled (if Date
was also set to be mocked).
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
assert.strictEqual(Date.now(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
assert.strictEqual(Date.now(), 9999);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
setTimeout(fn, 9999);
assert.strictEqual(fn.mock.callCount(), 0);
assert.strictEqual(Date.now(), 0);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(fn.mock.callCount(), 1);
assert.strictEqual(Date.now(), 9999);
});
As mentioned, all clear functions from timers (clearTimeout
, clearInterval
,and
clearImmediate
) are implicitly mocked. Take a look at this example using setTimeout
:
import assert from 'node:assert';
import { test } from 'node:test';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
const id = setTimeout(fn, 9999);
// Implicitly mocked as well
clearTimeout(id);
context.mock.timers.tick(9999);
// As that setTimeout was cleared the mock function will never be called
assert.strictEqual(fn.mock.callCount(), 0);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', (context) => {
const fn = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
const id = setTimeout(fn, 9999);
// Implicitly mocked as well
clearTimeout(id);
context.mock.timers.tick(9999);
// As that setTimeout was cleared the mock function will never be called
assert.strictEqual(fn.mock.callCount(), 0);
});
Once you enable mocking timers, node:timers, node:timers/promises modules, and timers from the Node.js global context are enabled:
Note: Destructuring functions such as
import { setTimeout } from 'node:timers'
is currently
not supported by this API.
import assert from 'node:assert';
import { test } from 'node:test';
import nodeTimers from 'node:timers';
import nodeTimersPromises from 'node:timers/promises';
test('mocks setTimeout to be executed synchronously without having to actually wait for it', async (context) => {
const globalTimeoutObjectSpy = context.mock.fn();
const nodeTimerSpy = context.mock.fn();
const nodeTimerPromiseSpy = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(globalTimeoutObjectSpy, 9999);
nodeTimers.setTimeout(nodeTimerSpy, 9999);
const promise = nodeTimersPromises.setTimeout(9999).then(nodeTimerPromiseSpy);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(globalTimeoutObjectSpy.mock.callCount(), 1);
assert.strictEqual(nodeTimerSpy.mock.callCount(), 1);
await promise;
assert.strictEqual(nodeTimerPromiseSpy.mock.callCount(), 1);
});
const assert = require('node:assert');
const { test } = require('node:test');
const nodeTimers = require('node:timers');
const nodeTimersPromises = require('node:timers/promises');
test('mocks setTimeout to be executed synchronously without having to actually wait for it', async (context) => {
const globalTimeoutObjectSpy = context.mock.fn();
const nodeTimerSpy = context.mock.fn();
const nodeTimerPromiseSpy = context.mock.fn();
// Optionally choose what to mock
context.mock.timers.enable({ apis: ['setTimeout'] });
setTimeout(globalTimeoutObjectSpy, 9999);
nodeTimers.setTimeout(nodeTimerSpy, 9999);
const promise = nodeTimersPromises.setTimeout(9999).then(nodeTimerPromiseSpy);
// Advance in time
context.mock.timers.tick(9999);
assert.strictEqual(globalTimeoutObjectSpy.mock.callCount(), 1);
assert.strictEqual(nodeTimerSpy.mock.callCount(), 1);
await promise;
assert.strictEqual(nodeTimerPromiseSpy.mock.callCount(), 1);
});
In Node.js, setInterval
from node:timers/promises
is an AsyncGenerator
and is also supported by this API:
import assert from 'node:assert';
import { test } from 'node:test';
import nodeTimersPromises from 'node:timers/promises';
test('should tick five times testing a real use case', async (context) => {
context.mock.timers.enable({ apis: ['setInterval'] });
const expectedIterations = 3;
const interval = 1000;
const startedAt = Date.now();
async function run() {
const times = [];
for await (const time of nodeTimersPromises.setInterval(interval, startedAt)) {
times.push(time);
if (times.length === expectedIterations) break;
}
return times;
}
const r = run();
context.mock.timers.tick(interval);
context.mock.timers.tick(interval);
context.mock.timers.tick(interval);
const timeResults = await r;
assert.strictEqual(timeResults.length, expectedIterations);
for (let it = 1; it < expectedIterations; it++) {
assert.strictEqual(timeResults[it - 1], startedAt + (interval * it));
}
});
const assert = require('node:assert');
const { test } = require('node:test');
const nodeTimersPromises = require('node:timers/promises');
test('should tick five times testing a real use case', async (context) => {
context.mock.timers.enable({ apis: ['setInterval'] });
const expectedIterations = 3;
const interval = 1000;
const startedAt = Date.now();
async function run() {
const times = [];
for await (const time of nodeTimersPromises.setInterval(interval, startedAt)) {
times.push(time);
if (times.length === expectedIterations) break;
}
return times;
}
const r = run();
context.mock.timers.tick(interval);
context.mock.timers.tick(interval);
context.mock.timers.tick(interval);
const timeResults = await r;
assert.strictEqual(timeResults.length, expectedIterations);
for (let it = 1; it < expectedIterations; it++) {
assert.strictEqual(timeResults[it - 1], startedAt + (interval * it));
}
});
Triggers all pending mocked timers immediately. If the Date
object is also
mocked, it will also advance the Date
object to the furthest timer's time.
The example below triggers all pending timers immediately, causing them to execute without any delay.
import assert from 'node:assert';
import { test } from 'node:test';
test('runAll functions following the given order', (context) => {
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const results = [];
setTimeout(() => results.push(1), 9999);
// Notice that if both timers have the same timeout,
// the order of execution is guaranteed
setTimeout(() => results.push(3), 8888);
setTimeout(() => results.push(2), 8888);
assert.deepStrictEqual(results, []);
context.mock.timers.runAll();
assert.deepStrictEqual(results, [3, 2, 1]);
// The Date object is also advanced to the furthest timer's time
assert.strictEqual(Date.now(), 9999);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('runAll functions following the given order', (context) => {
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const results = [];
setTimeout(() => results.push(1), 9999);
// Notice that if both timers have the same timeout,
// the order of execution is guaranteed
setTimeout(() => results.push(3), 8888);
setTimeout(() => results.push(2), 8888);
assert.deepStrictEqual(results, []);
context.mock.timers.runAll();
assert.deepStrictEqual(results, [3, 2, 1]);
// The Date object is also advanced to the furthest timer's time
assert.strictEqual(Date.now(), 9999);
});
Note: The runAll()
function is specifically designed for
triggering timers in the context of timer mocking.
It does not have any effect on real-time system
clocks or actual timers outside of the mocking environment.
Sets the current Unix timestamp that will be used as reference for any mocked
Date
objects.
import assert from 'node:assert';
import { test } from 'node:test';
test('runAll functions following the given order', (context) => {
const now = Date.now();
const setTime = 1000;
// Date.now is not mocked
assert.deepStrictEqual(Date.now(), now);
context.mock.timers.enable({ apis: ['Date'] });
context.mock.timers.setTime(setTime);
// Date.now is now 1000
assert.strictEqual(Date.now(), setTime);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('setTime replaces current time', (context) => {
const now = Date.now();
const setTime = 1000;
// Date.now is not mocked
assert.deepStrictEqual(Date.now(), now);
context.mock.timers.enable({ apis: ['Date'] });
context.mock.timers.setTime(setTime);
// Date.now is now 1000
assert.strictEqual(Date.now(), setTime);
});
Dates and timer objects are dependent on each other. If you use setTime()
to
pass the current time to the mocked Date
object, the set timers with
setTimeout
and setInterval
will not be affected.
However, the tick
method will advanced the mocked Date
object.
import assert from 'node:assert';
import { test } from 'node:test';
test('runAll functions following the given order', (context) => {
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const results = [];
setTimeout(() => results.push(1), 9999);
assert.deepStrictEqual(results, []);
context.mock.timers.setTime(12000);
assert.deepStrictEqual(results, []);
// The date is advanced but the timers don't tick
assert.strictEqual(Date.now(), 12000);
});
const assert = require('node:assert');
const { test } = require('node:test');
test('runAll functions following the given order', (context) => {
context.mock.timers.enable({ apis: ['setTimeout', 'Date'] });
const results = [];
setTimeout(() => results.push(1), 9999);
assert.deepStrictEqual(results, []);
context.mock.timers.setTime(12000);
assert.deepStrictEqual(results, []);
// The date is advanced but the timers don't tick
assert.strictEqual(Date.now(), 12000);
});
- Extends {Readable}
A successful call to run()
method will return a new {TestsStream}
object, streaming a series of events representing the execution of the tests.
TestsStream
will emit events, in the order of the tests definition
Some of the events are guaranteed to be emitted in the same order as the tests are defined, while others are emitted in the order that the tests execute.
data
{Object}summary
{Object} An object containing the coverage report.files
{Array} An array of coverage reports for individual files. Each report is an object with the following schema:path
{string} The absolute path of the file.totalLineCount
{number} The total number of lines.totalBranchCount
{number} The total number of branches.totalFunctionCount
{number} The total number of functions.coveredLineCount
{number} The number of covered lines.coveredBranchCount
{number} The number of covered branches.coveredFunctionCount
{number} The number of covered functions.coveredLinePercent
{number} The percentage of lines covered.coveredBranchPercent
{number} The percentage of branches covered.coveredFunctionPercent
{number} The percentage of functions covered.functions
{Array} An array of functions representing function coverage.name
{string} The name of the function.line
{number} The line number where the function is defined.count
{number} The number of times the function was called.
branches
{Array} An array of branches representing branch coverage.line
{number} The line number where the branch is defined.count
{number} The number of times the branch was taken.
lines
{Array} An array of lines representing line numbers and the number of times they were covered.line
{number} The line number.count
{number} The number of times the line was covered.
totals
{Object} An object containing a summary of coverage for all files.totalLineCount
{number} The total number of lines.totalBranchCount
{number} The total number of branches.totalFunctionCount
{number} The total number of functions.coveredLineCount
{number} The number of covered lines.coveredBranchCount
{number} The number of covered branches.coveredFunctionCount
{number} The number of covered functions.coveredLinePercent
{number} The percentage of lines covered.coveredBranchPercent
{number} The percentage of branches covered.coveredFunctionPercent
{number} The percentage of functions covered.
workingDirectory
{string} The working directory when code coverage began. This is useful for displaying relative path names in case the tests changed the working directory of the Node.js process.
nesting
{number} The nesting level of the test.
Emitted when code coverage is enabled and all tests have completed.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.details
{Object} Additional execution metadata.passed
{boolean} Whether the test passed or not.duration_ms
{number} The duration of the test in milliseconds.error
{Error|undefined} An error wrapping the error thrown by the test if it did not pass.cause
{Error} The actual error thrown by the test.
type
{string|undefined} The type of the test, used to denote whether this is a suite.
file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.testNumber
{number} The ordinal number of the test.todo
{string|boolean|undefined} Present ifcontext.todo
is calledskip
{string|boolean|undefined} Present ifcontext.skip
is called
Emitted when a test completes its execution.
This event is not emitted in the same order as the tests are
defined.
The corresponding declaration ordered events are 'test:pass'
and 'test:fail'
.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.
Emitted when a test is dequeued, right before it is executed.
This event is not guaranteed to be emitted in the same order as the tests are
defined. The corresponding declaration ordered event is 'test:start'
.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.message
{string} The diagnostic message.nesting
{number} The nesting level of the test.
Emitted when context.diagnostic
is called.
This event is guaranteed to be emitted in the same order as the tests are
defined.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.
Emitted when a test is enqueued for execution.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.details
{Object} Additional execution metadata.duration_ms
{number} The duration of the test in milliseconds.error
{Error} An error wrapping the error thrown by the test.cause
{Error} The actual error thrown by the test.
type
{string|undefined} The type of the test, used to denote whether this is a suite.
file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.testNumber
{number} The ordinal number of the test.todo
{string|boolean|undefined} Present ifcontext.todo
is calledskip
{string|boolean|undefined} Present ifcontext.skip
is called
Emitted when a test fails.
This event is guaranteed to be emitted in the same order as the tests are
defined.
The corresponding execution ordered event is 'test:complete'
.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.details
{Object} Additional execution metadata.duration_ms
{number} The duration of the test in milliseconds.type
{string|undefined} The type of the test, used to denote whether this is a suite.
file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.testNumber
{number} The ordinal number of the test.todo
{string|boolean|undefined} Present ifcontext.todo
is calledskip
{string|boolean|undefined} Present ifcontext.skip
is called
Emitted when a test passes.
This event is guaranteed to be emitted in the same order as the tests are
defined.
The corresponding execution ordered event is 'test:complete'
.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.nesting
{number} The nesting level of the test.count
{number} The number of subtests that have ran.
Emitted when all subtests have completed for a given test. This event is guaranteed to be emitted in the same order as the tests are defined.
data
{Object}column
{number|undefined} The column number where the test is defined, orundefined
if the test was run through the REPL.file
{string|undefined} The path of the test file,undefined
if test was run through the REPL.line
{number|undefined} The line number where the test is defined, orundefined
if the test was run through the REPL.name
{string} The test name.nesting
{number} The nesting level of the test.
Emitted when a test starts reporting its own and its subtests status.
This event is guaranteed to be emitted in the same order as the tests are
defined.
The corresponding execution ordered event is 'test:dequeue'
.
data
{Object}file
{string} The path of the test file.message
{string} The message written tostderr
.
Emitted when a running test writes to stderr
.
This event is only emitted if --test
flag is passed.
This event is not guaranteed to be emitted in the same order as the tests are
defined.
data
{Object}file
{string} The path of the test file.message
{string} The message written tostdout
.
Emitted when a running test writes to stdout
.
This event is only emitted if --test
flag is passed.
This event is not guaranteed to be emitted in the same order as the tests are
defined.
Emitted when no more tests are queued for execution in watch mode.
An instance of TestContext
is passed to each test function in order to
interact with the test runner. However, the TestContext
constructor is not
exposed as part of the API.
fn
{Function|AsyncFunction} The hook function. The first argument to this function is aTestContext
object. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function is used to create a hook running before subtest of the current test.
fn
{Function|AsyncFunction} The hook function. The first argument to this function is aTestContext
object. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function is used to create a hook running before each subtest of the current test.
test('top level test', async (t) => {
t.beforeEach((t) => t.diagnostic(`about to run ${t.name}`));
await t.test(
'This is a subtest',
(t) => {
assert.ok('some relevant assertion here');
},
);
});
fn
{Function|AsyncFunction} The hook function. The first argument to this function is aTestContext
object. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function is used to create a hook that runs after the current test finishes.
test('top level test', async (t) => {
t.after((t) => t.diagnostic(`finished running ${t.name}`));
assert.ok('some relevant assertion here');
});
fn
{Function|AsyncFunction} The hook function. The first argument to this function is aTestContext
object. If the hook uses callbacks, the callback function is passed as the second argument. Default: A no-op function.options
{Object} Configuration options for the hook. The following properties are supported:signal
{AbortSignal} Allows aborting an in-progress hook.timeout
{number} A number of milliseconds the hook will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.
This function is used to create a hook running after each subtest of the current test.
test('top level test', async (t) => {
t.afterEach((t) => t.diagnostic(`finished running ${t.name}`));
await t.test(
'This is a subtest',
(t) => {
assert.ok('some relevant assertion here');
},
);
});
An object containing assertion methods bound to context
. The top-level
functions from the node:assert
module are exposed here for the purpose of
creating test plans.
test('test', (t) => {
t.plan(1);
t.assert.strictEqual(true, true);
});
Stability: 1.0 - Early development
value
{any} A value to serialize to a string. If Node.js was started with the--test-update-snapshots
flag, the serialized value is written to the snapshot file. Otherwise, the serialized value is compared to the corresponding value in the existing snapshot file.options
{Object} Optional configuration options. The following properties are supported:serializers
{Array} An array of synchronous functions used to serializevalue
into a string.value
is passed as the only argument to the first serializer function. The return value of each serializer is passed as input to the next serializer. Once all serializers have run, the resulting value is coerced to a string. Default: If no serializers are provided, the test runner's default serializers are used.
This function implements assertions for snapshot testing.
test('snapshot test with default serialization', (t) => {
t.assert.snapshot({ value1: 1, value2: 2 });
});
test('snapshot test with custom serialization', (t) => {
t.assert.snapshot({ value3: 3, value4: 4 }, {
serializers: [(value) => JSON.stringify(value)]
});
});
message
{string} Message to be reported.
This function is used to write diagnostics to the output. Any diagnostic information is included at the end of the test's results. This function does not return a value.
test('top level test', (t) => {
t.diagnostic('A diagnostic message');
});
The name of the test and each of its ancestors, separated by >
.
The name of the test.
Stability: 1 - Experimental
count
{number} The number of assertions and subtests that are expected to run.
This function is used to set the number of assertions and subtests that are expected to run within the test. If the number of assertions and subtests that run does not match the expected count, the test will fail.
Note: To make sure assertions are tracked,
t.assert
must be used instead ofassert
directly.
test('top level test', (t) => {
t.plan(2);
t.assert.ok('some relevant assertion here');
t.test('subtest', () => {});
});
When working with asynchronous code, the plan
function can be used to ensure that the
correct number of assertions are run:
test('planning with streams', (t, done) => {
function* generate() {
yield 'a';
yield 'b';
yield 'c';
}
const expected = ['a', 'b', 'c'];
t.plan(expected.length);
const stream = Readable.from(generate());
stream.on('data', (chunk) => {
t.assert.strictEqual(chunk, expected.shift());
});
stream.on('end', () => {
done();
});
});
shouldRunOnlyTests
{boolean} Whether or not to runonly
tests.
If shouldRunOnlyTests
is truthy, the test context will only run tests that
have the only
option set. Otherwise, all tests are run. If Node.js was not
started with the --test-only
command-line option, this function is a
no-op.
test('top level test', (t) => {
// The test context can be set to run subtests with the 'only' option.
t.runOnly(true);
return Promise.all([
t.test('this subtest is now skipped'),
t.test('this subtest is run', { only: true }),
]);
});
- Type: {AbortSignal}
Can be used to abort test subtasks when the test has been aborted.
test('top level test', async (t) => {
await fetch('some/uri', { signal: t.signal });
});
message
{string} Optional skip message.
This function causes the test's output to indicate the test as skipped. If
message
is provided, it is included in the output. Calling skip()
does
not terminate execution of the test function. This function does not return a
value.
test('top level test', (t) => {
// Make sure to return here as well if the test contains additional logic.
t.skip('this is skipped');
});
message
{string} OptionalTODO
message.
This function adds a TODO
directive to the test's output. If message
is
provided, it is included in the output. Calling todo()
does not terminate
execution of the test function. This function does not return a value.
test('top level test', (t) => {
// This test is marked as `TODO`
t.todo('this is a todo');
});
name
{string} The name of the subtest, which is displayed when reporting test results. Default: Thename
property offn
, or'<anonymous>'
iffn
does not have a name.options
{Object} Configuration options for the subtest. The following properties are supported:concurrency
{number|boolean|null} If a number is provided, then that many tests would run in parallel within the application thread. Iftrue
, it would run all subtests in parallel. Iffalse
, it would only run one test at a time. If unspecified, subtests inherit this value from their parent. Default:null
.only
{boolean} If truthy, and the test context is configured to runonly
tests, then this test will be run. Otherwise, the test is skipped. Default:false
.signal
{AbortSignal} Allows aborting an in-progress test.skip
{boolean|string} If truthy, the test is skipped. If a string is provided, that string is displayed in the test results as the reason for skipping the test. Default:false
.todo
{boolean|string} If truthy, the test marked asTODO
. If a string is provided, that string is displayed in the test results as the reason why the test isTODO
. Default:false
.timeout
{number} A number of milliseconds the test will fail after. If unspecified, subtests inherit this value from their parent. Default:Infinity
.plan
{number} The number of assertions and subtests expected to be run in the test. If the number of assertions run in the test does not match the number specified in the plan, the test will fail. Default:undefined
.
fn
{Function|AsyncFunction} The function under test. The first argument to this function is aTestContext
object. If the test uses callbacks, the callback function is passed as the second argument. Default: A no-op function.- Returns: {Promise} Fulfilled with
undefined
once the test completes.
This function is used to create subtests under the current test. This function
behaves in the same fashion as the top level test()
function.
test('top level test', async (t) => {
await t.test(
'This is a subtest',
{ only: false, skip: false, concurrency: 1, todo: false, plan: 4 },
(t) => {
assert.ok('some relevant assertion here');
},
);
});
An instance of SuiteContext
is passed to each suite function in order to
interact with the test runner. However, the SuiteContext
constructor is not
exposed as part of the API.
The name of the suite.
- Type: {AbortSignal}
Can be used to abort test subtasks when the test has been aborted.