Developing > Unit Testing Framework

Unit Testing Framework

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Learn how to use Matchstick, a unit testing framework developed by LimeChain. Matchstick enables subgraph developers to test their mapping logic in a sandboxed environment and sucessfully deploy their subgraphs.

Benefits of Using Matchstick

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  • It's written in Rust and optimized for high performance.
  • It gives you access to developer features, including the ability to mock contract calls, make assertions about the store state, monitor subgraph failures, check test performance, and many more.

Getting Started

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Install Dependencies

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In order to use the test helper methods and run tests, you need to install the following dependencies:

yarn add --dev matchstick-as

Install PostgreSQL

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graph-node depends on PostgreSQL, so if you don't already have it, then you will need to install it.

Note: It's highly recommended to use the commands below to avoid unexpected errors.

Using MacOS

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Installation command:

brew install postgresql

Create a symlink to the latest libpq.5.lib You may need to create this dir first /usr/local/opt/postgresql/lib/

ln -sf /usr/local/opt/postgresql@14/lib/postgresql@14/libpq.5.dylib /usr/local/opt/postgresql/lib/libpq.5.dylib

Using Linux

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Installation command (depends on your distro):

sudo apt install postgresql

Using WSL (Windows Subsystem for Linux)

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You can use Matchstick on WSL both using the Docker approach and the binary approach. As WSL can be a bit tricky, here's a few tips in case you encounter issues like

static BYTES = Symbol("Bytes") SyntaxError: Unexpected token =

or

<PROJECT_PATH>/node_modules/gluegun/build/index.js:13 throw up;

Please make sure you're on a newer version of Node.js graph-cli doesn't support v10.19.0 anymore, and that is still the default version for new Ubuntu images on WSL. For instance Matchstick is confirmed to be working on WSL with v18.1.0, you can switch to it either via nvm or if you update your global Node.js. Don't forget to delete node_modules and to run npm install again after updating you nodejs! Then, make sure you have libpq installed, you can do that by running

sudo apt-get install libpq-dev

And finally, do not use graph test (which uses your global installation of graph-cli and for some reason that looks like it's broken on WSL currently), instead use yarn test or npm run test (that will use the local, project-level instance of graph-cli, which works like a charm). For that you would of course need to have a "test" script in your package.json file which can be something as simple as

{
"name": "demo-subgraph",
"version": "0.1.0",
"scripts": {
"test": "graph test",
...
},
"dependencies": {
"@graphprotocol/graph-cli": "^0.56.0",
"@graphprotocol/graph-ts": "^0.31.0",
"matchstick-as": "^0.6.0"
}
}

Using Matchstick

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To use Matchstick in your subgraph project just open up a terminal, navigate to the root folder of your project and simply run graph test [options] <datasource> - it downloads the latest Matchstick binary and runs the specified test or all tests in a test folder (or all existing tests if no datasource flag is specified).

CLI options

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This will run all tests in the test folder:

graph test

This will run a test named gravity.test.ts and/or all test inside of a folder named gravity:

graph test gravity

This will run only that specific test file:

graph test path/to/file.test.ts

Options:

-c, --coverage Run the tests in coverage mode
-d, --docker Run the tests in a docker container (Note: Please execute from the root folder of the subgraph)
-f, --force Binary: Redownloads the binary. Docker: Redownloads the Dockerfile and rebuilds the docker image.
-h, --help Show usage information
-l, --logs Logs to the console information about the OS, CPU model and download url (debugging purposes)
-r, --recompile Forces tests to be recompiled
-v, --version <tag> Choose the version of the rust binary that you want to be downloaded/used

From graph-cli 0.25.2, the graph test command supports running matchstick in a docker container with the -d flag. The docker implementation uses bind mount so it does not have to rebuild the docker image every time the graph test -d command is executed. Alternatively you can follow the instructions from the matchstick repository to run docker manually.

graph test -d forces docker run to run with flag -t. This must be removed to run inside non-interactive environments (like GitHub CI).

❗ If you have previously ran graph test you may encounter the following error during docker build:

error from sender: failed to xattr node_modules/binary-install-raw/bin/binary-<platform>: permission denied

In this case create a .dockerignore in the root folder and add node_modules/binary-install-raw/bin

Configuration

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Matchstick can be configured to use a custom tests, libs and manifest path via matchstick.yaml config file:

testsFolder: path/to/tests
libsFolder: path/to/libs
manifestPath: path/to/subgraph.yaml

Demo subgraph

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You can try out and play around with the examples from this guide by cloning the Demo Subgraph repo

Video tutorials

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Also you can check out the video series on "How to use Matchstick to write unit tests for your subgraphs"

Tests structure

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IMPORTANT: The test structure described below depens on matchstick-as version >=0.5.0

describe(name: String , () => {}) - Defines a test group.

Notes:

  • Describes are not mandatory. You can still use test() the old way, outside of the describe() blocks

Example:

import { describe, test } from "matchstick-as/assembly/index"
import { handleNewGravatar } from "../../src/gravity"
describe("handleNewGravatar()", () => {
test("Should create a new Gravatar entity", () => {
...
})
})

Nested describe() example:

import { describe, test } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar } from "../../src/gravity"
describe("handleUpdatedGravatar()", () => {
describe("When entity exists", () => {
test("updates the entity", () => {
...
})
})
describe("When entity does not exists", () => {
test("it creates a new entity", () => {
...
})
})
})

test(name: String, () =>, should_fail: bool) - Defines a test case. You can use test() inside of describe() blocks or independently.

Example:

import { describe, test } from "matchstick-as/assembly/index"
import { handleNewGravatar } from "../../src/gravity"
describe("handleNewGravatar()", () => {
test("Should create a new Entity", () => {
...
})
})

or

test("handleNewGravatar() should create a new entity", () => {
...
})

beforeAll()

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Runs a code block before any of the tests in the file. If beforeAll is declared inside of a describe block, it runs at the beginning of that describe block.

Examples:

Code inside beforeAll will execute once before all tests in the file.

import { describe, test, beforeAll } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
import { Gravatar } from "../../generated/schema"
beforeAll(() => {
let gravatar = new Gravatar("0x0")
gravatar.displayName = “First Gravatar”
gravatar.save()
...
})
describe("When the entity does not exist", () => {
test("it should create a new Gravatar with id 0x1", () => {
...
})
})
describe("When entity already exists", () => {
test("it should update the Gravatar with id 0x0", () => {
...
})
})

Code inside beforeAll will execute once before all tests in the first describe block

import { describe, test, beforeAll } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
import { Gravatar } from "../../generated/schema"
describe("handleUpdatedGravatar()", () => {
beforeAll(() => {
let gravatar = new Gravatar("0x0")
gravatar.displayName = “First Gravatar”
gravatar.save()
...
})
test("updates Gravatar with id 0x0", () => {
...
})
test("creates new Gravatar with id 0x1", () => {
...
})
})

Runs a code block after all of the tests in the file. If afterAll is declared inside of a describe block, it runs at the end of that describe block.

Example:

Code inside afterAll will execute once after all tests in the file.

import { describe, test, afterAll } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
import { store } from "@graphprotocol/graph-ts"
afterAll(() => {
store.remove("Gravatar", "0x0")
...
})
describe("handleNewGravatar, () => {
test("creates Gravatar with id 0x0", () => {
...
})
})
describe("handleUpdatedGravatar", () => {
test("updates Gravatar with id 0x0", () => {
...
})
})

Code inside afterAll will execute once after all tests in the first describe block

import { describe, test, afterAll, clearStore } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
describe("handleNewGravatar", () => {
afterAll(() => {
store.remove("Gravatar", "0x1")
...
})
test("It creates a new entity with Id 0x0", () => {
...
})
test("It creates a new entity with Id 0x1", () => {
...
})
})
describe("handleUpdatedGravatar", () => {
test("updates Gravatar with id 0x0", () => {
...
})
})

beforeEach()

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Runs a code block before every test. If beforeEach is declared inside of a describe block, it runs before each test in that describe block.

Examples: Code inside beforeEach will execute before each tests.

import { describe, test, beforeEach, clearStore } from "matchstick-as/assembly/index"
import { handleNewGravatars } from "./utils"
beforeEach(() => {
clearStore() // <-- clear the store before each test in the file
})
describe("handleNewGravatars, () => {
test("A test that requires a clean store", () => {
...
})
test("Second that requires a clean store", () => {
...
})
})
...

Code inside beforeEach will execute only before each test in the that describe

import { describe, test, beforeEach } from 'matchstick-as/assembly/index'
import { handleUpdatedGravatar, handleNewGravatar } from '../../src/gravity'
describe('handleUpdatedGravatars', () => {
beforeEach(() => {
let gravatar = new Gravatar('0x0')
gravatar.displayName = 'First Gravatar'
gravatar.imageUrl = ''
gravatar.save()
})
test('Upates the displayName', () => {
assert.fieldEquals('Gravatar', '0x0', 'displayName', 'First Gravatar')
// code that should update the displayName to 1st Gravatar
assert.fieldEquals('Gravatar', '0x0', 'displayName', '1st Gravatar')
store.remove('Gravatar', '0x0')
})
test('Updates the imageUrl', () => {
assert.fieldEquals('Gravatar', '0x0', 'imageUrl', '')
// code that should changes the imageUrl to https://www.gravatar.com/avatar/0x0
assert.fieldEquals('Gravatar', '0x0', 'imageUrl', 'https://www.gravatar.com/avatar/0x0')
store.remove('Gravatar', '0x0')
})
})

afterEach()

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Runs a code block after every test. If afterEach is declared inside of a describe block, it runs after each test in that describe block.

Examples:

Code inside afterEach will execute after every test.

import { describe, test, beforeEach, afterEach } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
beforeEach(() => {
let gravatar = new Gravatar("0x0")
gravatar.displayName = “First Gravatar”
gravatar.save()
})
afterEach(() => {
store.remove("Gravatar", "0x0")
})
describe("handleNewGravatar", () => {
...
})
describe("handleUpdatedGravatar", () => {
test("Upates the displayName", () => {
assert.fieldEquals("Gravatar", "0x0", "displayName", "First Gravatar")
// code that should update the displayName to 1st Gravatar
assert.fieldEquals("Gravatar", "0x0", "displayName", "1st Gravatar")
})
test("Updates the imageUrl", () => {
assert.fieldEquals("Gravatar", "0x0", "imageUrl", "")
// code that should changes the imageUrl to https://www.gravatar.com/avatar/0x0
assert.fieldEquals("Gravatar", "0x0", "imageUrl", "https://www.gravatar.com/avatar/0x0")
})
})

Code inside afterEach will execute after each test in that describe

import { describe, test, beforeEach, afterEach } from "matchstick-as/assembly/index"
import { handleUpdatedGravatar, handleNewGravatar } from "../../src/gravity"
describe("handleNewGravatar", () => {
...
})
describe("handleUpdatedGravatar", () => {
beforeEach(() => {
let gravatar = new Gravatar("0x0")
gravatar.displayName = "First Gravatar"
gravatar.imageUrl = ""
gravatar.save()
})
afterEach(() => {
store.remove("Gravatar", "0x0")
})
test("Upates the displayName", () => {
assert.fieldEquals("Gravatar", "0x0", "displayName", "First Gravatar")
// code that should update the displayName to 1st Gravatar
assert.fieldEquals("Gravatar", "0x0", "displayName", "1st Gravatar")
})
test("Updates the imageUrl", () => {
assert.fieldEquals("Gravatar", "0x0", "imageUrl", "")
// code that should changes the imageUrl to https://www.gravatar.com/avatar/0x0
assert.fieldEquals("Gravatar", "0x0", "imageUrl", "https://www.gravatar.com/avatar/0x0")
})
})
fieldEquals(entityType: string, id: string, fieldName: string, expectedVal: string)
equals(expected: ethereum.Value, actual: ethereum.Value)
notInStore(entityType: string, id: string)
addressEquals(address1: Address, address2: Address)
bytesEquals(bytes1: Bytes, bytes2: Bytes)
i32Equals(number1: i32, number2: i32)
bigIntEquals(bigInt1: BigInt, bigInt2: BigInt)
booleanEquals(bool1: boolean, bool2: boolean)
stringEquals(string1: string, string2: string)
arrayEquals(array1: Array<ethereum.Value>, array2: Array<ethereum.Value>)
tupleEquals(tuple1: ethereum.Tuple, tuple2: ethereum.Tuple)
assertTrue(value: boolean)
assertNull<T>(value: T)
assertNotNull<T>(value: T)
entityCount(entityType: string, expectedCount: i32)

As of version 0.6.0, asserts support custom error messages as well

assert.fieldEquals('Gravatar', '0x123', 'id', '0x123', 'Id should be 0x123')
assert.equals(ethereum.Value.fromI32(1), ethereum.Value.fromI32(1), 'Value should equal 1')
assert.notInStore('Gravatar', '0x124', 'Gravatar should not be in store')
assert.addressEquals(Address.zero(), Address.zero(), 'Address should be zero')
assert.bytesEquals(Bytes.fromUTF8('0x123'), Bytes.fromUTF8('0x123'), 'Bytes should be equal')
assert.i32Equals(2, 2, 'I32 should equal 2')
assert.bigIntEquals(BigInt.fromI32(1), BigInt.fromI32(1), 'BigInt should equal 1')
assert.booleanEquals(true, true, 'Boolean should be true')
assert.stringEquals('1', '1', 'String should equal 1')
assert.arrayEquals([ethereum.Value.fromI32(1)], [ethereum.Value.fromI32(1)], 'Arrays should be equal')
assert.tupleEquals(
changetype<ethereum.Tuple>([ethereum.Value.fromI32(1)]),
changetype<ethereum.Tuple>([ethereum.Value.fromI32(1)]),
'Tuples should be equal',
)
assert.assertTrue(true, 'Should be true')
assert.assertNull(null, 'Should be null')
assert.assertNotNull('not null', 'Should be not null')
assert.entityCount('Gravatar', 1, 'There should be 2 gravatars')
assert.dataSourceCount('GraphTokenLockWallet', 1, 'GraphTokenLockWallet template should have one data source')
assert.dataSourceExists(
'GraphTokenLockWallet',
Address.zero().toHexString(),
'GraphTokenLockWallet should have a data source for zero address',
)

Write a Unit Test

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Let's see how a simple unit test would look like using the Gravatar examples in the Demo Subgraph.

Assuming we have the following handler function (along with two helper functions to make our life easier):

export function handleNewGravatar(event: NewGravatar): void {
let gravatar = new Gravatar(event.params.id.toHex())
gravatar.owner = event.params.owner
gravatar.displayName = event.params.displayName
gravatar.imageUrl = event.params.imageUrl
gravatar.save()
}
export function handleNewGravatars(events: NewGravatar[]): void {
events.forEach((event) => {
handleNewGravatar(event)
})
}
export function createNewGravatarEvent(
id: i32,
ownerAddress: string,
displayName: string,
imageUrl: string,
): NewGravatar {
let mockEvent = newMockEvent()
let newGravatarEvent = new NewGravatar(
mockEvent.address,
mockEvent.logIndex,
mockEvent.transactionLogIndex,
mockEvent.logType,
mockEvent.block,
mockEvent.transaction,
mockEvent.parameters,
)
newGravatarEvent.parameters = new Array()
let idParam = new ethereum.EventParam('id', ethereum.Value.fromI32(id))
let addressParam = new ethereum.EventParam(
'ownderAddress',
ethereum.Value.fromAddress(Address.fromString(ownerAddress)),
)
let displayNameParam = new ethereum.EventParam('displayName', ethereum.Value.fromString(displayName))
let imageUrlParam = new ethereum.EventParam('imageUrl', ethereum.Value.fromString(imageUrl))
newGravatarEvent.parameters.push(idParam)
newGravatarEvent.parameters.push(addressParam)
newGravatarEvent.parameters.push(displayNameParam)
newGravatarEvent.parameters.push(imageUrlParam)
return newGravatarEvent
}

We first have to create a test file in our project. This is an example of how that might look like:

import { clearStore, test, assert } from 'matchstick-as/assembly/index'
import { Gravatar } from '../../generated/schema'
import { NewGravatar } from '../../generated/Gravity/Gravity'
import { createNewGravatarEvent, handleNewGravatars } from '../mappings/gravity'
test('Can call mappings with custom events', () => {
// Create a test entity and save it in the store as initial state (optional)
let gravatar = new Gravatar('gravatarId0')
gravatar.save()
// Create mock events
let newGravatarEvent = createNewGravatarEvent(12345, '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7', 'cap', 'pac')
let anotherGravatarEvent = createNewGravatarEvent(3546, '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7', 'cap', 'pac')
// Call mapping functions passing the events we just created
handleNewGravatars([newGravatarEvent, anotherGravatarEvent])
// Assert the state of the store
assert.fieldEquals('Gravatar', 'gravatarId0', 'id', 'gravatarId0')
assert.fieldEquals('Gravatar', '12345', 'owner', '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7')
assert.fieldEquals('Gravatar', '3546', 'displayName', 'cap')
// Clear the store in order to start the next test off on a clean slate
clearStore()
})
test('Next test', () => {
//...
})

That's a lot to unpack! First off, an important thing to notice is that we're importing things from matchstick-as, our AssemblyScript helper library (distributed as an npm module). You can find the repository here. matchstick-as provides us with useful testing methods and also defines the test() function which we will use to build our test blocks. The rest of it is pretty straightforward - here's what happens:

  • We're setting up our initial state and adding one custom Gravatar entity;
  • We define two NewGravatar event objects along with their data, using the createNewGravatarEvent() function;
  • We're calling out handler methods for those events - handleNewGravatars() and passing in the list of our custom events;
  • We assert the state of the store. How does that work? - We're passing a unique combination of Entity type and id. Then we check a specific field on that Entity and assert that it has the value we expect it to have. We're doing this both for the initial Gravatar Entity we added to the store, as well as the two Gravatar entities that gets added when the handler function is called;
  • And lastly - we're cleaning the store using clearStore() so that our next test can start with a fresh and empty store object. We can define as many test blocks as we want.

There we go - we've created our first test! 👏

Now in order to run our tests you simply need to run the following in your subgraph root folder:

graph test Gravity

And if all goes well you should be greeted with the following:

Matchstick saying “All tests passed!”

Common test scenarios

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Hydrating the store with a certain state

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Users are able to hydrate the store with a known set of entities. Here's an example to initialise the store with a Gravatar entity:

let gravatar = new Gravatar('entryId')
gravatar.save()

Calling a mapping function with an event

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A user can create a custom event and pass it to a mapping function that is bound to the store:

import { store } from 'matchstick-as/assembly/store'
import { NewGravatar } from '../../generated/Gravity/Gravity'
import { handleNewGravatars, createNewGravatarEvent } from './mapping'
let newGravatarEvent = createNewGravatarEvent(12345, '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7', 'cap', 'pac')
handleNewGravatar(newGravatarEvent)

Calling all of the mappings with event fixtures

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Users can call the mappings with test fixtures.

import { NewGravatar } from '../../generated/Gravity/Gravity'
import { store } from 'matchstick-as/assembly/store'
import { handleNewGravatars, createNewGravatarEvent } from './mapping'
let newGravatarEvent = createNewGravatarEvent(12345, '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7', 'cap', 'pac')
let anotherGravatarEvent = createNewGravatarEvent(3546, '0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7', 'cap', 'pac')
handleNewGravatars([newGravatarEvent, anotherGravatarEvent])
export function handleNewGravatars(events: NewGravatar[]): void {
events.forEach(event => {
handleNewGravatar(event);
});
}

Mocking contract calls

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Users can mock contract calls:

import { addMetadata, assert, createMockedFunction, clearStore, test } from 'matchstick-as/assembly/index'
import { Gravity } from '../../generated/Gravity/Gravity'
import { Address, BigInt, ethereum } from '@graphprotocol/graph-ts'
let contractAddress = Address.fromString('0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7')
let expectedResult = Address.fromString('0x90cBa2Bbb19ecc291A12066Fd8329D65FA1f1947')
let bigIntParam = BigInt.fromString('1234')
createMockedFunction(contractAddress, 'gravatarToOwner', 'gravatarToOwner(uint256):(address)')
.withArgs([ethereum.Value.fromSignedBigInt(bigIntParam)])
.returns([ethereum.Value.fromAddress(Address.fromString('0x90cBa2Bbb19ecc291A12066Fd8329D65FA1f1947'))])
let gravity = Gravity.bind(contractAddress)
let result = gravity.gravatarToOwner(bigIntParam)
assert.equals(ethereum.Value.fromAddress(expectedResult), ethereum.Value.fromAddress(result))

As demonstrated, in order to mock a contract call and hardcore a return value, the user must provide a contract address, function name, function signature, an array of arguments, and of course - the return value.

Users can also mock function reverts:

let contractAddress = Address.fromString('0x89205A3A3b2A69De6Dbf7f01ED13B2108B2c43e7')
createMockedFunction(contractAddress, 'getGravatar', 'getGravatar(address):(string,string)')
.withArgs([ethereum.Value.fromAddress(contractAddress)])
.reverts()

Mocking IPFS files (from matchstick 0.4.1)

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Users can mock IPFS files by using mockIpfsFile(hash, filePath) function. The function accepts two arguments, the first one is the IPFS file hash/path and the second one is the path to a local file.

NOTE: When testing ipfs.map/ipfs.mapJSON, the callback function must be exported from the test file in order for matchstck to detect it, like the processGravatar() function in the test example bellow:

.test.ts file:

import { assert, test, mockIpfsFile } from 'matchstick-as/assembly/index'
import { ipfs } from '@graphprotocol/graph-ts'
import { gravatarFromIpfs } from './utils'
// Export ipfs.map() callback in order for matchstck to detect it
export { processGravatar } from './utils'
test('ipfs.cat', () => {
mockIpfsFile('ipfsCatfileHash', 'tests/ipfs/cat.json')
assert.entityCount(GRAVATAR_ENTITY_TYPE, 0)
gravatarFromIpfs()
assert.entityCount(GRAVATAR_ENTITY_TYPE, 1)
assert.fieldEquals(GRAVATAR_ENTITY_TYPE, '1', 'imageUrl', 'https://i.ytimg.com/vi/MELP46s8Cic/maxresdefault.jpg')
clearStore()
})
test('ipfs.map', () => {
mockIpfsFile('ipfsMapfileHash', 'tests/ipfs/map.json')
assert.entityCount(GRAVATAR_ENTITY_TYPE, 0)
ipfs.map('ipfsMapfileHash', 'processGravatar', Value.fromString('Gravatar'), ['json'])
assert.entityCount(GRAVATAR_ENTITY_TYPE, 3)
assert.fieldEquals(GRAVATAR_ENTITY_TYPE, '1', 'displayName', 'Gravatar1')
assert.fieldEquals(GRAVATAR_ENTITY_TYPE, '2', 'displayName', 'Gravatar2')
assert.fieldEquals(GRAVATAR_ENTITY_TYPE, '3', 'displayName', 'Gravatar3')
})

utils.ts file:

import { Address, ethereum, JSONValue, Value, ipfs, json, Bytes } from "@graphprotocol/graph-ts"
import { Gravatar } from "../../generated/schema"
...
// ipfs.map callback
export function processGravatar(value: JSONValue, userData: Value): void {
// See the JSONValue documentation for details on dealing
// with JSON values
let obj = value.toObject()
let id = obj.get('id')
if (!id) {
return
}
// Callbacks can also created entities
let gravatar = new Gravatar(id.toString())
gravatar.displayName = userData.toString() + id.toString()
gravatar.save()
}
// function that calls ipfs.cat
export function gravatarFromIpfs(): void {
let rawData = ipfs.cat("ipfsCatfileHash")
if (!rawData) {
return
}
let jsonData = json.fromBytes(rawData as Bytes).toObject()
let id = jsonData.get('id')
let url = jsonData.get("imageUrl")
if (!id || !url) {
return
}
let gravatar = new Gravatar(id.toString())
gravatar.imageUrl = url.toString()
gravatar.save()
}

Asserting the state of the store

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Users are able to assert the final (or midway) state of the store through asserting entities. In order to do this, the user has to supply an Entity type, the specific ID of an Entity, a name of a field on that Entity, and the expected value of the field. Here's a quick example:

import { assert } from 'matchstick-as/assembly/index'
import { Gravatar } from '../generated/schema'
let gravatar = new Gravatar('gravatarId0')
gravatar.save()
assert.fieldEquals('Gravatar', 'gravatarId0', 'id', 'gravatarId0')

Running the assert.fieldEquals() function will check for equality of the given field against the given expected value. The test will fail and an error message will be outputted if the values are NOT equal. Otherwise the test will pass successfully.

Interacting with Event metadata

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Users can use default transaction metadata, which could be returned as an ethereum.Event by using the newMockEvent() function. The following example shows how you can read/write to those fields on the Event object:

// Read
let logType = newGravatarEvent.logType
// Write
let UPDATED_ADDRESS = '0xB16081F360e3847006dB660bae1c6d1b2e17eC2A'
newGravatarEvent.address = Address.fromString(UPDATED_ADDRESS)

Asserting variable equality

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assert.equals(ethereum.Value.fromString("hello"); ethereum.Value.fromString("hello"));

Asserting that an Entity is not in the store

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Users can assert that an entity does not exist in the store. The function takes an entity type and an id. If the entity is in fact in the store, the test will fail with a relevant error message. Here's a quick example of how to use this functionality:

assert.notInStore('Gravatar', '23')

Printing the whole store, or single entities from it (for debug purposes)

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You can print the whole store to the console using this helper function:

import { logStore } from 'matchstick-as/assembly/store'
logStore()

As of version 0.6.0, logStore no longer prints derived fields, instead users can use the new logEntity function. Of course logEntity can be used to print any entity, not just ones that have derived fields. logEntity takes the entity type, entity id and a showRelated flag to indicate if users want to print the related derived entities.

import { logEntity } from 'matchstick-as/assembly/store'
logEntity("Gravatar", 23, true)

Expected failure

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Users can have expected test failures, using the shouldFail flag on the test() functions:

test(
'Should throw an error',
() => {
throw new Error()
},
true,
)

If the test is marked with shouldFail = true but DOES NOT fail, that will show up as an error in the logs and the test block will fail. Also, if it's marked with shouldFail = false (the default state), the test executor will crash.

Having custom logs in the unit tests is exactly the same as logging in the mappings. The difference is that the log object needs to be imported from matchstick-as rather than graph-ts. Here's a simple example with all non-critical log types:

import { test } from "matchstick-as/assembly/index";
import { log } from "matchstick-as/assembly/log";
test("Success", () => {
log.success("Success!". []);
});
test("Error", () => {
log.error("Error :( ", []);
});
test("Debug", () => {
log.debug("Debugging...", []);
});
test("Info", () => {
log.info("Info!", []);
});
test("Warning", () => {
log.warning("Warning!", []);
});

Users can also simulate a critical failure, like so:

test('Blow everything up', () => {
log.critical('Boom!')
})

Logging critical errors will stop the execution of the tests and blow everything up. After all - we want to make sure you're code doesn't have critical logs in deployment, and you should notice right away if that were to happen.

Testing derived fields

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Testing derived fields is a feature which allows users to set a field on a certain entity and have another entity be updated automatically if it derives one of its fields from the first entity.

Before version 0.6.0 it was possible to get the derived entities by accessing them as entity fields/properties, like so:

let entity = ExampleEntity.load('id')
let derivedEntity = entity.derived_entity

As of version 0.6.0, this is done by using the loadRelated function of graph-node, the derived entities can be accessed the same way as in the handlers.

test('Derived fields example test', () => {
let mainAccount = GraphAccount.load('12')!
assert.assertNull(mainAccount.get('nameSignalTransactions'))
assert.assertNull(mainAccount.get('operatorOf'))
let operatedAccount = GraphAccount.load('1')!
operatedAccount.operators = [mainAccount.id]
operatedAccount.save()
mockNameSignalTransaction('1234', mainAccount.id)
mockNameSignalTransaction('2', mainAccount.id)
mainAccount = GraphAccount.load('12')!
assert.assertNull(mainAccount.get('nameSignalTransactions'))
assert.assertNull(mainAccount.get('operatorOf'))
const nameSignalTransactions = mainAccount.nameSignalTransactions.load()
const operatorsOfMainAccount = mainAccount.operatorOf.load()
assert.i32Equals(2, nameSignalTransactions.length)
assert.i32Equals(1, operatorsOfMainAccount.length)
assert.stringEquals('1', operatorsOfMainAccount[0].id)
mockNameSignalTransaction('2345', mainAccount.id)
let nst = NameSignalTransaction.load('1234')!
nst.signer = '11'
nst.save()
store.remove('NameSignalTransaction', '2')
mainAccount = GraphAccount.load('12')!
assert.i32Equals(1, mainAccount.nameSignalTransactions.load().length)
})

Testing loadInBlock

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As of version 0.6.0, users can test loadInBlock by using the mockInBlockStore, it allows mocking entities in the block cache.

import { afterAll, beforeAll, describe, mockInBlockStore, test } from 'matchstick-as'
import { Gravatar } from '../../generated/schema'
describe('loadInBlock', () => {
beforeAll(() => {
mockInBlockStore('Gravatar', 'gravatarId0', gravatar)
})
afterAll(() => {
clearInBlockStore()
})
test('Can use entity.loadInBlock() to retrieve entity from cache store in the current block', () => {
let retrievedGravatar = Gravatar.loadInBlock('gravatarId0')
assert.stringEquals('gravatarId0', retrievedGravatar!.get('id')!.toString())
})
test("Returns null when calling entity.loadInBlock() if an entity doesn't exist in the current block", () => {
let retrievedGravatar = Gravatar.loadInBlock('IDoNotExist')
assert.assertNull(retrievedGravatar)
})
})

Testing dynamic data sources

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Testing dynamic data sources can be be done by mocking the return value of the context(), address() and network() functions of the dataSource namespace. These functions currently return the following: context() - returns an empty entity (DataSourceContext), address() - returns 0x0000000000000000000000000000000000000000, network() - returns mainnet. The create(...) and createWithContext(...) functions are mocked to do nothing so they don't need to be called in the tests at all. Changes to the return values can be done through the functions of the dataSourceMock namespace in matchstick-as (version 0.3.0+).

Example below:

First we have the following event handler (which has been intentionally repurposed to showcase datasource mocking):

export function handleApproveTokenDestinations(event: ApproveTokenDestinations): void {
let tokenLockWallet = TokenLockWallet.load(dataSource.address().toHexString())!
if (dataSource.network() == 'rinkeby') {
tokenLockWallet.tokenDestinationsApproved = true
}
let context = dataSource.context()
if (context.get('contextVal')!.toI32() > 0) {
tokenLockWallet.setBigInt('tokensReleased', BigInt.fromI32(context.get('contextVal')!.toI32()))
}
tokenLockWallet.save()
}

And then we have the test using one of the methods in the dataSourceMock namespace to set a new return value for all of the dataSource functions:

import { assert, test, newMockEvent, dataSourceMock } from 'matchstick-as/assembly/index'
import { BigInt, DataSourceContext, Value } from '@graphprotocol/graph-ts'
import { handleApproveTokenDestinations } from '../../src/token-lock-wallet'
import { ApproveTokenDestinations } from '../../generated/templates/GraphTokenLockWallet/GraphTokenLockWallet'
import { TokenLockWallet } from '../../generated/schema'
test('Data source simple mocking example', () => {
let addressString = '0xA16081F360e3847006dB660bae1c6d1b2e17eC2A'
let address = Address.fromString(addressString)
let wallet = new TokenLockWallet(address.toHexString())
wallet.save()
let context = new DataSourceContext()
context.set('contextVal', Value.fromI32(325))
dataSourceMock.setReturnValues(addressString, 'rinkeby', context)
let event = changetype<ApproveTokenDestinations>(newMockEvent())
assert.assertTrue(!wallet.tokenDestinationsApproved)
handleApproveTokenDestinations(event)
wallet = TokenLockWallet.load(address.toHexString())!
assert.assertTrue(wallet.tokenDestinationsApproved)
assert.bigIntEquals(wallet.tokensReleased, BigInt.fromI32(325))
dataSourceMock.resetValues()
})

Notice that dataSourceMock.resetValues() is called at the end. That's because the values are remembered when they are changed and need to be reset if you want to go back to the default values.

Testing dynamic data source creation

Link to this section

As of version 0.6.0, it is possible to test if a new data source has been created from a template. This feature supports both ethereum/contract and file/ipfs templates. There are four functions for this:

  • assert.dataSourceCount(templateName, expectedCount) can be used to assert the expected count of data sources from the specified template
  • assert.dataSourceExists(templateName, address/ipfsHash) asserts that a data source with the specified identifier (could be a contract address or IPFS file hash) from a specified template was created
  • logDataSources(templateName) prints all data sources from the specified template to the console for debugging purposes
  • readFile(path) reads a JSON file that represents an IPFS file and returns the content as Bytes

Testing ethereum/contract templates

Link to this section
test('ethereum/contract dataSource creation example', () => {
// Assert there are no dataSources created from GraphTokenLockWallet template
assert.dataSourceCount('GraphTokenLockWallet', 0)
// Create a new GraphTokenLockWallet datasource with address 0xA16081F360e3847006dB660bae1c6d1b2e17eC2A
GraphTokenLockWallet.create(Address.fromString('0xA16081F360e3847006dB660bae1c6d1b2e17eC2A'))
// Assert the dataSource has been created
assert.dataSourceCount('GraphTokenLockWallet', 1)
// Add a second dataSource with context
let context = new DataSourceContext()
context.set('contextVal', Value.fromI32(325))
GraphTokenLockWallet.createWithContext(Address.fromString('0xA16081F360e3847006dB660bae1c6d1b2e17eC2B'), context)
// Assert there are now 2 dataSources
assert.dataSourceCount('GraphTokenLockWallet', 2)
// Assert that a dataSource with address "0xA16081F360e3847006dB660bae1c6d1b2e17eC2B" was created
// Keep in mind that `Address` type is transformed to lower case when decoded, so you have to pass the address as all lower case when asserting if it exists
assert.dataSourceExists('GraphTokenLockWallet', '0xA16081F360e3847006dB660bae1c6d1b2e17eC2B'.toLowerCase())
logDataSources('GraphTokenLockWallet')
})
Example logDataSource output
Link to this section
🛠 {
"0xa16081f360e3847006db660bae1c6d1b2e17ec2a": {
"kind": "ethereum/contract",
"name": "GraphTokenLockWallet",
"address": "0xa16081f360e3847006db660bae1c6d1b2e17ec2a",
"context": null
},
"0xa16081f360e3847006db660bae1c6d1b2e17ec2b": {
"kind": "ethereum/contract",
"name": "GraphTokenLockWallet",
"address": "0xa16081f360e3847006db660bae1c6d1b2e17ec2b",
"context": {
"contextVal": {
"type": "Int",
"data": 325
}
}
}
}

Testing file/ipfs templates

Link to this section

Similarly to contract dynamic data sources, users can test test file datas sources and their handlers

Example subgraph.yaml
Link to this section
...
templates:
- kind: file/ipfs
name: GraphTokenLockMetadata
network: mainnet
mapping:
kind: ethereum/events
apiVersion: 0.0.6
language: wasm/assemblyscript
file: ./src/token-lock-wallet.ts
handler: handleMetadata
entities:
- TokenLockMetadata
abis:
- name: GraphTokenLockWallet
file: ./abis/GraphTokenLockWallet.json
Example schema.graphql
Link to this section
"""
Token Lock Wallets which hold locked GRT
"""
type TokenLockMetadata @entity {
"The address of the token lock wallet"
id: ID!
"Start time of the release schedule"
startTime: BigInt!
"End time of the release schedule"
endTime: BigInt!
"Number of periods between start time and end time"
periods: BigInt!
"Time when the releases start"
releaseStartTime: BigInt!
}
Example metadata.json
Link to this section
{
"startTime": 1,
"endTime": 1,
"periods": 1,
"releaseStartTime": 1
}
Example handler
Link to this section
export function handleMetadata(content: Bytes): void {
// dataSource.stringParams() returns the File DataSource CID
// stringParam() will be mocked in the handler test
// for more info https://thegraph.com/docs/en/developing/creating-a-subgraph/#create-a-new-handler-to-process-files
let tokenMetadata = new TokenLockMetadata(dataSource.stringParam())
const value = json.fromBytes(content).toObject()
if (value) {
const startTime = value.get('startTime')
const endTime = value.get('endTime')
const periods = value.get('periods')
const releaseStartTime = value.get('releaseStartTime')
if (startTime && endTime && periods && releaseStartTime) {
tokenMetadata.startTime = startTime.toBigInt()
tokenMetadata.endTime = endTime.toBigInt()
tokenMetadata.periods = periods.toBigInt()
tokenMetadata.releaseStartTime = releaseStartTime.toBigInt()
}
tokenMetadata.save()
}
}
Example test
Link to this section
import { assert, test, dataSourceMock, readFile } from 'matchstick-as'
import { Address, BigInt, Bytes, DataSourceContext, ipfs, json, store, Value } from '@graphprotocol/graph-ts'
import { handleMetadata } from '../../src/token-lock-wallet'
import { TokenLockMetadata } from '../../generated/schema'
import { GraphTokenLockMetadata } from '../../generated/templates'
test('file/ipfs dataSource creation example', () => {
// Generate the dataSource CID from the ipfsHash + ipfs path file
// For example QmaXzZhcYnsisuue5WRdQDH6FDvqkLQX1NckLqBYeYYEfm/example.json
const ipfshash = 'QmaXzZhcYnsisuue5WRdQDH6FDvqkLQX1NckLqBYeYYEfm'
const CID = `${ipfshash}/example.json`
// Create a new dataSource using the generated CID
GraphTokenLockMetadata.create(CID)
// Assert the dataSource has been created
assert.dataSourceCount('GraphTokenLockMetadata', 1)
assert.dataSourceExists('GraphTokenLockMetadata', CID)
logDataSources('GraphTokenLockMetadata')
// Now we have to mock the dataSource metadata and specifically dataSource.stringParam()
// dataSource.stringParams actually uses the value of dataSource.address(), so we will mock the address using dataSourceMock from matchstick-as
// First we will reset the values and then use dataSourceMock.setAddress() to set the CID
dataSourceMock.resetValues()
dataSourceMock.setAddress(CID)
// Now we need to generate the Bytes to pass to the dataSource handler
// For this case we introduced a new function readFile, that reads a local json and returns the content as Bytes
const content = readFile(`path/to/metadata.json`)
handleMetadata(content)
// Now we will test if a TokenLockMetadata was created
const metadata = TokenLockMetadata.load(CID)
assert.bigIntEquals(metadata!.endTime, BigInt.fromI32(1))
assert.bigIntEquals(metadata!.periods, BigInt.fromI32(1))
assert.bigIntEquals(metadata!.releaseStartTime, BigInt.fromI32(1))
assert.bigIntEquals(metadata!.startTime, BigInt.fromI32(1))
})

Test Coverage

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Using Matchstick, subgraph developers are able to run a script that will calculate the test coverage of the written unit tests.

The test coverage tool takes the compiled test wasm binaries and converts them to wat files, which can then be easily inspected to see whether or not the handlers defined in subgraph.yaml have been called. Since code coverage (and testing as whole) is in very early stages in AssemblyScript and WebAssembly, Matchstick cannot check for branch coverage. Instead we rely on the assertion that if a given handler has been called, the event/function for it have been properly mocked.

Prerequisites

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To run the test coverage functionality provided in Matchstick, there are a few things you need to prepare beforehand:

Export your handlers

Link to this section

In order for Matchstick to check which handlers are being run, those handlers need to be exported from the test file. So for instance in our example, in our gravity.test.ts file we have the following handler being imported:

import { handleNewGravatar } from '../../src/gravity'

In order for that function to be visible (for it to be included in the wat file by name) we need to also export it, like this:

export { handleNewGravatar }

Once that's all set up, to run the test coverage tool, simply run:

graph test -- -c

You could also add a custom coverage command to your package.json file, like so:

"scripts": {
/.../
"coverage": "graph test -- -c"
},

That will execute the coverage tool and you should see something like this in the terminal:

$ graph test -c
Skipping download/install step because binary already exists at /Users/petko/work/demo-subgraph/node_modules/binary-install-raw/bin/0.4.0
___ ___ _ _ _ _ _
| \/ | | | | | | | (_) | |
| . . | __ _| |_ ___| |__ ___| |_ _ ___| | __
| |\/| |/ _` | __/ __| '_ \/ __| __| |/ __| |/ /
| | | | (_| | || (__| | | \__ \ |_| | (__| <
\_| |_/\__,_|\__\___|_| |_|___/\__|_|\___|_|\_\
Compiling...
Running in coverage report mode.
Reading generated test modules... 🔎️
Generating coverage report 📝
Handlers for source 'Gravity':
Handler 'handleNewGravatar' is tested.
Handler 'handleUpdatedGravatar' is not tested.
Handler 'handleCreateGravatar' is tested.
Test coverage: 66.7% (2/3 handlers).
Handlers for source 'GraphTokenLockWallet':
Handler 'handleTokensReleased' is not tested.
Handler 'handleTokensWithdrawn' is not tested.
Handler 'handleTokensRevoked' is not tested.
Handler 'handleManagerUpdated' is not tested.
Handler 'handleApproveTokenDestinations' is not tested.
Handler 'handleRevokeTokenDestinations' is not tested.
Test coverage: 0.0% (0/6 handlers).
Global test coverage: 22.2% (2/9 handlers).

Test run time duration in the log output

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The log output includes the test run duration. Here's an example:

[Thu, 31 Mar 2022 13:54:54 +0300] Program executed in: 42.270ms.

Common compiler errors

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Critical: Could not create WasmInstance from valid module with context: unknown import: wasi_snapshot_preview1::fd_write has not been defined

This means you have used console.log in your code, which is not supported by AssemblyScript. Please consider using the Logging API

ERROR TS2554: Expected ? arguments, but got ?.

return new ethereum.Block(defaultAddressBytes, defaultAddressBytes, defaultAddressBytes, defaultAddress, defaultAddressBytes, defaultAddressBytes, defaultAddressBytes, defaultBigInt, defaultBigInt, defaultBigInt, defaultBigInt, defaultBigInt, defaultBigInt, defaultBigInt, defaultBigInt);

in ~lib/matchstick-as/assembly/defaults.ts(18,12)

ERROR TS2554: Expected ? arguments, but got ?.

return new ethereum.Transaction(defaultAddressBytes, defaultBigInt, defaultAddress, defaultAddress, defaultBigInt, defaultBigInt, defaultBigInt, defaultAddressBytes, defaultBigInt);

in ~lib/matchstick-as/assembly/defaults.ts(24,12)

The mismatch in arguments is caused by mismatch in graph-ts and matchstick-as. The best way to fix issues like this one is to update everything to the latest released version.

Additional Resources

Link to this section

For any additional support, check out this demo subgraph repo using Matchstick.

If you have any questions, feedback, feature requests or just want to reach out, the best place would be The Graph Discord where we have a dedicated channel for Matchstick, called 🔥| unit-testing.

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