.. | ||
__snapshots__ | ||
bdd_examples | ||
mock_examples | ||
_diff_test.ts | ||
_diff.ts | ||
_format_test.ts | ||
_format.ts | ||
_test_suite.ts | ||
_test_utils.ts | ||
_time.ts | ||
asserts_test.ts | ||
asserts.ts | ||
bdd_test.ts | ||
bdd.ts | ||
chai_example.ts | ||
fast_check_example.ts | ||
mock_test.ts | ||
mock.ts | ||
README.md | ||
sinon_example.ts | ||
snapshot_test.ts | ||
snapshot.ts | ||
time_test.ts | ||
time.ts |
Testing
This module provides a few basic utilities to make testing easier and consistent in Deno.
Usage
testing/asserts.ts
module provides range of assertion helpers. If the
assertion is false an AssertionError
will be thrown which will result in
pretty-printed diff of failing assertion.
equal()
- Deep comparison function, whereactual
andexpected
are compared deeply, and if they vary,equal
returnsfalse
.assert()
- Expects a boolean value, throws if the value isfalse
.assertFalse()
- Expects a boolean value, throws if the value istrue
.assertEquals()
- Uses theequal
comparison and throws if theactual
andexpected
are not equal.assertNotEquals()
- Uses theequal
comparison and throws if theactual
andexpected
are equal.assertStrictEquals()
- Comparesactual
andexpected
strictly, therefore for non-primitives the values must reference the same instance.assertAlmostEquals()
- Make an assertion thatactual
is almost equal toexpected
, according to a givenepsilon
(defaults to1e-7
)assertInstanceOf()
- Make an assertion thatactual
is an instance ofexpectedType
.assertNotInstanceOf()
- Make an assertion thatactual
is not an instance ofexpectedType
.assertStringIncludes()
- Make an assertion thatactual
includesexpected
.assertMatch()
- Make an assertion thatactual
match RegExpexpected
.assertNotMatch()
- Make an assertion thatactual
not match RegExpexpected
.assertArrayIncludes()
- Make an assertion thatactual
array includes theexpected
values.assertObjectMatch()
- Make an assertion thatactual
object matchexpected
subset objectassertSnapshot()
- Make an assertion thatactual
matches a snapshotassertThrows()
- Expects the passedfn
to throw. Iffn
does not throw, this function does. Also compares any errors thrown to an optional expectedError
class and checks that the error.message
includes an optional string. If there is caught error, it gets returned.assertRejects()
- Expects the passedfn
to be async and return aPromiseLike
object that rejects. If thefn
does not reject, this function will reject (⚠️ you should normally await this assertion). Also optionally accepts an Error class which the expected error must be an instance of, and a string which must be a substring of the error's.message
. If there is caught error, it gets returned.unimplemented()
- Use this to stub out methods that will throw when invoked.unreachable()
- Used to assert unreachable code.
Basic usage:
import { assertEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
Deno.test({
name: "testing example",
fn(): void {
assertEquals("world", "world");
assertEquals({ hello: "world" }, { hello: "world" });
},
});
Short syntax (named function instead of object):
import { assertEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
Deno.test("example", function (): void {
assertEquals("world", "world");
assertEquals({ hello: "world" }, { hello: "world" });
});
Using assertStrictEquals()
:
import { assertStrictEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
Deno.test("isStrictlyEqual", function (): void {
const a = {};
const b = a;
assertStrictEquals(a, b);
});
// This test fails
Deno.test("isNotStrictlyEqual", function (): void {
const a = {};
const b = {};
assertStrictEquals(a, b);
});
Using assertSnapshot()
:
For more usage information, see Snapshot Testing.
import { assertSnapshot } from "https://deno.land/std@$STD_VERSION/testing/snapshot.ts";
Deno.test("isSnapshotMatch", async function (t): Promise<void> {
const a = {
hello: "world!",
example: 123,
};
await assertSnapshot(t, a);
});
Using assertThrows()
:
import { assertThrows } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
Deno.test("doesThrow", function (): void {
assertThrows((): void => {
throw new TypeError("hello world!");
});
assertThrows((): void => {
throw new TypeError("hello world!");
}, TypeError);
assertThrows(
(): void => {
throw new TypeError("hello world!");
},
TypeError,
"hello",
);
});
// This test will not pass.
Deno.test("fails", function (): void {
assertThrows((): void => {
console.log("Hello world");
});
});
Using assertRejects()
:
import { assertRejects } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
Deno.test("doesThrow", async function () {
await assertRejects(
async () => {
throw new TypeError("hello world!");
},
);
await assertRejects(async () => {
throw new TypeError("hello world!");
}, TypeError);
await assertRejects(
async () => {
throw new TypeError("hello world!");
},
TypeError,
"hello",
);
await assertRejects(
async () => {
return Promise.reject(new Error());
},
);
});
// This test will not pass.
Deno.test("fails", async function () {
await assertRejects(
async () => {
console.log("Hello world");
},
);
});
Snapshot Testing
Basic usage:
The assertSnapshot
function will create a snapshot of a value and compare it
to a reference snapshot, which is stored alongside the test file in the
__snapshots__
directory.
// example_test.ts
import { assertSnapshot } from "https://deno.land/std@$STD_VERSION/testing/snapshot.ts";
Deno.test("isSnapshotMatch", async function (t): Promise<void> {
const a = {
hello: "world!",
example: 123,
};
await assertSnapshot(t, a);
});
// __snapshots__/example_test.ts.snap
export const snapshot = {};
snapshot[`isSnapshotMatch 1`] = `
{
example: 123,
hello: "world!",
}
`;
Calling assertSnapshot
in a test will throw an AssertionError
, causing the
test to fail, if the snapshot created during the test does not match the one in
the snapshot file.
Updating Snapshots:
When adding new snapshot assertions to your test suite, or when intentionally
making changes which cause your snapshots to fail, you can update your snapshots
by running the snapshot tests in update mode. Tests can be run in update mode by
passing the --update
or -u
flag as an argument when running the test. When
this flag is passed, then any snapshots which do not match will be updated.
deno test --allow-all -- --update
Note: In Powershell, you need to quote --
.
deno test --allow-all "--" --update
Additionally, new snapshots will only be created when this flag is present.
Permissions:
When running snapshot tests, the --allow-read
permission must be enabled, or
else any calls to assertSnapshot
will fail due to insufficient permissions.
Additionally, when updating snapshots, the --allow-write
permission must also
be enabled, as this is required in order to update snapshot files.
The assertSnapshot
function will only attempt to read from and write to
snapshot files. As such, the allow list for --allow-read
and --allow-write
can be limited to only include existing snapshot files, if so desired.
Options:
The assertSnapshot
function optionally accepts an options object.
// example_test.ts
import { assertSnapshot } from "https://deno.land/std@$STD_VERSION/testing/snapshot.ts";
Deno.test("isSnapshotMatch", async function (t): Promise<void> {
const a = {
hello: "world!",
example: 123,
};
await assertSnapshot(t, a, {
// options
});
});
You can also configure default options for assertSnapshot
.
// example_test.ts
import { createAssertSnapshot } from "https://deno.land/std@$STD_VERSION/testing/snapshot.ts";
const assertSnapshot = createAssertSnapshot({
// options
});
When configuring default options like this, the resulting assertSnapshot
function will function the same as the default function exported from the
snapshot module. If passed an optional options object, this will take precedence
over the default options, where the value provded for an option differs.
It is possible to "extend" an assertSnapshot
function which has been
configured with default options.
// example_test.ts
import { createAssertSnapshot } from "https://deno.land/std@$STD_VERSION/testing/snapshot.ts";
import { stripColor } from "https://deno.land/std@$STD_VERSION/fmt/colors.ts";
const assertSnapshot = createAssertSnapshot({
dir: ".snaps",
});
const assertMonochromeSnapshot = createAssertSnapshot<string>(
{ serializer: stripColor },
assertSnapshot,
);
Deno.test("isSnapshotMatch", async function (t): Promise<void> {
const a = "\x1b[32mThis green text has had it's colours stripped\x1b[39m";
await assertMonochromeSnapshot(t, a);
});
// .snaps/example_test.ts.snap
export const snapshot = {};
snapshot[`isSnapshotMatch 1`] = `This green text has had it's colours stripped`;
Version Control:
Snapshot testing works best when changes to snapshot files are comitted alongside other code changes. This allows for changes to reference snapshots to be reviewed along side the code changes that caused them, and ensures that when others pull your changes, their tests will pass without needing to update snapshots locally.
Behavior-driven development
With the bdd.ts
module you can write your tests in a familiar format for
grouping tests and adding setup/teardown hooks used by other JavaScript testing
frameworks like Jasmine, Jest, and Mocha.
The describe
function creates a block that groups together several related
tests. The it
function registers an individual test case.
Hooks
There are 4 types of hooks available for test suites. A test suite can have
multiples of each type of hook, they will be called in the order that they are
registered. The afterEach
and afterAll
hooks will be called whether or not
the test case passes. The *All hooks will be called once for the whole group
while the *Each hooks will be called for each individual test case.
beforeAll
: Runs before all of the tests in the test suite.afterAll
: Runs after all of the tests in the test suite finish.beforeEach
: Runs before each of the individual test cases in the test suite.afterEach
: Runs after each of the individual test cases in the test suite.
If a hook is registered at the top level, a global test suite will be registered and all tests will belong to it. Hooks registered at the top level must be registered before any individual test cases or test suites.
Focusing tests
If you would like to run only specific test cases, you can do so by calling
it.only
instead of it
. If you would like to run only specific test suites,
you can do so by calling describe.only
instead of describe
.
There is one limitation to this when using the flat test grouping style. When
describe
is called without being nested, it registers the test with
Deno.test
. If a child test case or suite is registered with it.only
or
describe.only
, it will be scoped to the top test suite instead of the file. To
make them the only tests that run in the file, you would need to register the
top test suite with describe.only
too.
Ignoring tests
If you would like to not run specific individual test cases, you can do so by
calling it.ignore
instead of it
. If you would like to not run specific test
suites, you can do so by calling describe.ignore
instead of describe
.
Sanitization options
Like Deno.TestDefinition
, the DescribeDefinition
and ItDefinition
have
sanitization options. They work in the same way.
sanitizeExit
: Ensure the test case does not prematurely cause the process to exit, for example via a call to Deno.exit. Defaults to true.sanitizeOps
: Check that the number of async completed ops after the test is the same as number of dispatched ops. Defaults to true.sanitizeResources
: Ensure the test case does not "leak" resources - ie. the resource table after the test has exactly the same contents as before the test. Defaults to true.
Permissions option
Like Deno.TestDefinition
, the DescribeDefintion
and ItDefinition
have a
permissions
option. They specify the permissions that should be used to run an
individual test case or test suite. Set this to "inherit"
to keep the calling
thread's permissions. Set this to "none"
to revoke all permissions.
This setting defaults to "inherit"
.
There is currently one limitation to this, you cannot use the permissions option
on an individual test case or test suite that belongs to another test suite.
That's because internally those tests are registered with t.step
which does
not support the permissions option.
Comparing to Deno.test
The default way of writing tests is using Deno.test
and t.step
. The
describe
and it
functions have similar call signatures to Deno.test
,
making it easy to switch between the default style and the behavior-driven
development style of writing tests. Internally, describe
and it
are
registering tests with Deno.test
and t.step
.
Below is an example of a test file using Deno.test
and t.step
. In the
following sections there are examples of how the same test could be written with
describe
and it
using nested test grouping, flat test grouping, or a mix of
both styles.
// https://deno.land/std@$STD_VERSION/testing/bdd_examples/user_test.ts
import {
assertEquals,
assertStrictEquals,
assertThrows,
} from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import { User } from "https://deno.land/std@$STD_VERSION/testing/bdd_examples/user.ts";
Deno.test("User.users initially empty", () => {
assertEquals(User.users.size, 0);
});
Deno.test("User constructor", () => {
try {
const user = new User("Kyle");
assertEquals(user.name, "Kyle");
assertStrictEquals(User.users.get("Kyle"), user);
} finally {
User.users.clear();
}
});
Deno.test("User age", async (t) => {
const user = new User("Kyle");
await t.step("getAge", () => {
assertThrows(() => user.getAge(), Error, "Age unknown");
user.age = 18;
assertEquals(user.getAge(), 18);
});
await t.step("setAge", () => {
user.setAge(18);
assertEquals(user.getAge(), 18);
});
});
Nested test grouping
Tests created within the callback of a describe
function call will belong to
the new test suite it creates. The hooks can be created within it or be added to
the options argument for describe.
// https://deno.land/std@$STD_VERSION/testing/bdd_examples/user_nested_test.ts
import {
assertEquals,
assertStrictEquals,
assertThrows,
} from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
afterEach,
beforeEach,
describe,
it,
} from "https://deno.land/std@$STD_VERSION/testing/bdd.ts";
import { User } from "https://deno.land/std@$STD_VERSION/testing/bdd_examples/user.ts";
describe("User", () => {
it("users initially empty", () => {
assertEquals(User.users.size, 0);
});
it("constructor", () => {
try {
const user = new User("Kyle");
assertEquals(user.name, "Kyle");
assertStrictEquals(User.users.get("Kyle"), user);
} finally {
User.users.clear();
}
});
describe("age", () => {
let user: User;
beforeEach(() => {
user = new User("Kyle");
});
afterEach(() => {
User.users.clear();
});
it("getAge", function () {
assertThrows(() => user.getAge(), Error, "Age unknown");
user.age = 18;
assertEquals(user.getAge(), 18);
});
it("setAge", function () {
user.setAge(18);
assertEquals(user.getAge(), 18);
});
});
});
Flat test grouping
The describe
function returns a unique symbol that can be used to reference
the test suite for adding tests to it without having to create them within a
callback. The gives you the ability to have test grouping without any extra
indentation in front of the grouped tests.
// https://deno.land/std@$STD_VERSION/testing/bdd_examples/user_flat_test.ts
import {
assertEquals,
assertStrictEquals,
assertThrows,
} from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
describe,
it,
} from "https://deno.land/std@$STD_VERSION/testing/bdd.ts";
import { User } from "https://deno.land/std@$STD_VERSION/testing/bdd_examples/user.ts";
const userTests = describe("User");
it(userTests, "users initially empty", () => {
assertEquals(User.users.size, 0);
});
it(userTests, "constructor", () => {
try {
const user = new User("Kyle");
assertEquals(user.name, "Kyle");
assertStrictEquals(User.users.get("Kyle"), user);
} finally {
User.users.clear();
}
});
const ageTests = describe({
name: "age",
suite: userTests,
beforeEach(this: { user: User }) {
this.user = new User("Kyle");
},
afterEach() {
User.users.clear();
},
});
it(ageTests, "getAge", function () {
const { user } = this;
assertThrows(() => user.getAge(), Error, "Age unknown");
user.age = 18;
assertEquals(user.getAge(), 18);
});
it(ageTests, "setAge", function () {
const { user } = this;
user.setAge(18);
assertEquals(user.getAge(), 18);
});
Mixed test grouping
Both nested test grouping and flat test grouping can be used together. This can be useful if you'd like to create deep groupings without all the extra indentation in front of each line.
// https://deno.land/std@$STD_VERSION/testing/bdd_examples/user_mixed_test.ts
import {
assertEquals,
assertStrictEquals,
assertThrows,
} from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
describe,
it,
} from "https://deno.land/std@$STD_VERSION/testing/bdd.ts";
import { User } from "https://deno.land/std@$STD_VERSION/testing/bdd_examples/user.ts";
describe("User", () => {
it("users initially empty", () => {
assertEquals(User.users.size, 0);
});
it("constructor", () => {
try {
const user = new User("Kyle");
assertEquals(user.name, "Kyle");
assertStrictEquals(User.users.get("Kyle"), user);
} finally {
User.users.clear();
}
});
const ageTests = describe({
name: "age",
beforeEach(this: { user: User }) {
this.user = new User("Kyle");
},
afterEach() {
User.users.clear();
},
});
it(ageTests, "getAge", function () {
const { user } = this;
assertThrows(() => user.getAge(), Error, "Age unknown");
user.age = 18;
assertEquals(user.getAge(), 18);
});
it(ageTests, "setAge", function () {
const { user } = this;
user.setAge(18);
assertEquals(user.getAge(), 18);
});
});
Mocking
Test spies are function stand-ins that are used to assert if a function's internal behavior matches expectations. Test spies on methods keep the original behavior but allow you to test how the method is called and what it returns. Test stubs are an extension of test spies that also replaces the original methods behavior.
Spying
Say we have two functions, square
and multiply
, if we want to assert that
the multiply
function is called during execution of the square
function we
need a way to spy on the multiply
function. There are a few ways to achieve
this with Spies, one is to have the square
function take the multiply
multiply as a parameter.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/parameter_injection.ts
export function multiply(a: number, b: number): number {
return a * b;
}
export function square(
multiplyFn: (a: number, b: number) => number,
value: number,
): number {
return multiplyFn(value, value);
}
This way, we can call square(multiply, value)
in the application code or wrap
a spy function around the multiply
function and call
square(multiplySpy, value)
in the testing code.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/parameter_injection_test.ts
import {
assertSpyCall,
assertSpyCalls,
spy,
} from "https://deno.land/std@$STD_VERSION/testing/mock.ts";
import { assertEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
multiply,
square,
} from "https://deno.land/std@$STD_VERSION/testing/mock_examples/parameter_injection.ts";
Deno.test("square calls multiply and returns results", () => {
const multiplySpy = spy(multiply);
assertEquals(square(multiplySpy, 5), 25);
// asserts that multiplySpy was called at least once and details about the first call.
assertSpyCall(multiplySpy, 0, {
args: [5, 5],
returned: 25,
});
// asserts that multiplySpy was only called once.
assertSpyCalls(multiplySpy, 1);
});
If you prefer not adding additional parameters for testing purposes only, you
can use spy to wrap a method on an object instead. In the following example, the
exported _internals
object has the multiply
function we want to call as a
method and the square
function calls _internals.multiply
instead of
multiply
.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/internals_injection.ts
export function multiply(a: number, b: number): number {
return a * b;
}
export function square(value: number): number {
return _internals.multiply(value, value);
}
export const _internals = { multiply };
This way, we can call square(value)
in both the application code and testing
code. Then spy on the multiply
method on the _internals
object in the
testing code to be able to spy on how the square
function calls the multiply
function.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/internals_injection_test.ts
import {
assertSpyCall,
assertSpyCalls,
spy,
} from "https://deno.land/std@$STD_VERSION/testing/mock.ts";
import { assertEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
_internals,
square,
} from "https://deno.land/std@$STD_VERSION/testing/mock_examples/internals_injection.ts";
Deno.test("square calls multiply and returns results", () => {
const multiplySpy = spy(_internals, "multiply");
try {
assertEquals(square(5), 25);
} finally {
// unwraps the multiply method on the _internals object
multiplySpy.restore();
}
// asserts that multiplySpy was called at least once and details about the first call.
assertSpyCall(multiplySpy, 0, {
args: [5, 5],
returned: 25,
});
// asserts that multiplySpy was only called once.
assertSpyCalls(multiplySpy, 1);
});
One difference you may have noticed between these two examples is that in the
second we call the restore
method on multiplySpy
function. That is needed to
remove the spy wrapper from the _internals
object's multiply
method. The
restore
method is called in a finally block to ensure that it is restored
whether or not the assertion in the try block is successful. The restore
method didn't need to be called in the first example because the multiply
function was not modified in any way like the _internals
object was in the
second example.
Stubbing
Say we have two functions, randomMultiple
and randomInt
, if we want to
assert that randomInt
is called during execution of randomMultiple
we need a
way to spy on the randomInt
function. That could be done with either of the
spying techniques previously mentioned. To be able to verify that the
randomMultiple
function returns the value we expect it to for what randomInt
returns, the easiest way would be to replace the randomInt
function's behavior
with more predictable behavior.
You could use the first spying technique to do that but that would require
adding a randomInt
parameter to the randomMultiple
function.
You could also use the second spying technique to do that, but your assertions
would not be as predictable due to the randomInt
function returning random
values.
Say we want to verify it returns correct values for both negative and positive
random integers. We could easily do that with stubbing. The below example is
similar to the second spying technique example but instead of passing the call
through to the original randomInt
function, we are going to replace
randomInt
with a function that returns pre-defined values.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/random.ts
export function randomInt(lowerBound: number, upperBound: number): number {
return lowerBound + Math.floor(Math.random() * (upperBound - lowerBound));
}
export function randomMultiple(value: number): number {
return value * _internals.randomInt(-10, 10);
}
export const _internals = { randomInt };
The mock module includes some helper functions to make creating common stubs
easy. The returnsNext
function takes an array of values we want it to return
on consecutive calls.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/random_test.ts
import {
assertSpyCall,
assertSpyCalls,
returnsNext,
stub,
} from "https://deno.land/std@$STD_VERSION/testing/mock.ts";
import { assertEquals } from "https://deno.land/std@$STD_VERSION/testing/asserts.ts";
import {
_internals,
randomMultiple,
} from "https://deno.land/std@$STD_VERSION/testing/mock_examples/random.ts";
Deno.test("randomMultiple uses randomInt to generate random multiples between -10 and 10 times the value", () => {
const randomIntStub = stub(_internals, "randomInt", returnsNext([-3, 3]));
try {
assertEquals(randomMultiple(5), -15);
assertEquals(randomMultiple(5), 15);
} finally {
// unwraps the randomInt method on the _internals object
randomIntStub.restore();
}
// asserts that randomIntStub was called at least once and details about the first call.
assertSpyCall(randomIntStub, 0, {
args: [-10, 10],
returned: -3,
});
// asserts that randomIntStub was called at least twice and details about the second call.
assertSpyCall(randomIntStub, 1, {
args: [-10, 10],
returned: 3,
});
// asserts that randomIntStub was only called twice.
assertSpyCalls(randomIntStub, 2);
});
Faking time
Say we have a function that has time based behavior that we would like to test. With real time, that could cause tests to take much longer than they should. If you fake time, you could simulate how your function would behave over time starting from any point in time. Below is an example where we want to test that the callback is called every second.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/interval.ts
export function secondInterval(cb: () => void): number {
return setInterval(cb, 1000);
}
With FakeTime
we can do that. When the FakeTime
instance is created, it
splits from real time. The Date
, setTimeout
, clearTimeout
, setInterval
and clearInterval
globals are replaced with versions that use the fake time
until real time is restored. You can control how time ticks forward with the
tick
method on the FakeTime
instance.
// https://deno.land/std@$STD_VERSION/testing/mock_examples/interval_test.ts
import {
assertSpyCalls,
spy,
} from "https://deno.land/std@$STD_VERSION/testing/mock.ts";
import { FakeTime } from "https://deno.land/std@$STD_VERSION/testing/time.ts";
import { secondInterval } from "https://deno.land/std@$STD_VERSION/testing/mock_examples/interval.ts";
Deno.test("secondInterval calls callback every second and stops after being cleared", () => {
const time = new FakeTime();
try {
const cb = spy();
const intervalId = secondInterval(cb);
assertSpyCalls(cb, 0);
time.tick(500);
assertSpyCalls(cb, 0);
time.tick(500);
assertSpyCalls(cb, 1);
time.tick(3500);
assertSpyCalls(cb, 4);
clearInterval(intervalId);
time.tick(1000);
assertSpyCalls(cb, 4);
} finally {
time.restore();
}
});