Install Node 10 LTS and yarn. Older or newer versions may or may not work. (Recommend nvm and brew install yarn --without-node on mac.)
Install Docker.app. Our database and other services are configured to run in docker.
Symlink .env.example to .env, which sets up your environment to run from Docker. You can copy and modify .env.example to .env if the defaults won't work for you.
Start postgres with: docker-compose up. This will set up a postgres docker image and start it.
Run yarn to install dependencies.
Run yarn db:create to create development and test databases.
Run yarn build to build the application, including supporting scripts.
Note: Start docker-compose up and leave it running any time you want to run the app/tests.
Running the app
This repository includes a simple redux/graphql-based app. If you'd like to play around with this example, here's how to start it up:
Run yarn build to, among other things, create generated types and scripts.
Run yarn db:migrate:latest to migrate your development and test databases.
Optionally run yarn db:migrate-and-seed to add some test data to your dev database.
Run yarn dev to start the hot-reloading dev server, which can be visited on port 3000.
See the interactive style guide and component tests by running yarn dev:storybook and visit localhost:9001.
To run unit tests, run yarn test:unit or yarn test:unit --watch for the interactive jest-based test runner.
For this project, we have decided not to check in the generated GraphQL types. This means that
you'll need to run yarn build before you begin viewing or editing the source code, lest you see
spurious type errors and failed imports.
Stack
This project is a single-page webapp using the following technologies:
TypeScript – a type-safe variant of JavaScript from Microsoft which reduces errors and improves IDE/editor support over regular JavaScript.
Node.js – powers our server, and is pinned to the latest LTS release.
Express – our HTTP server, which is lightly used only to host our GraphQL API.
GraphQL – an alternative to REST apis which supports a demand-driven architecture. Our GraphQL server is Apollo GraphQL server.
This repository is structured to encourage a view of the whole repository as one application. The client and server are “just” different entry points, and we use webpack to elide libraries and code that are irrelevant to a particular entry point.
There are a few key directories:
entry – contains the primary entry points of the application. If you want to see what happens when you start up the client or server, start there. These are also the entry points for webpack.
webpack contains a webpack configuration for each entry point, as well as webpack-dev-server.js which sets up the dev server used during development.
modules contains all of the code. Each module is a self-contained concept that may be used by other modules, command-line scripts, etc.
config contains configuration files for our various environments. The default config is set up as a twelve-factor app to be hosted in heroku. Most variables can be controlled via the environment – see config/default.js.
dist is where webpack stores compiled slices of the app.
Default modules:
client – React/redux front-end.
db – core knex database connection helpers
records – database record types and repositories, with base record and repository classes in record. Depends on db
graphql – Graphql schema and implementation. Depends on records and db
server – express.js server that serves the client and graphql api. Depends on graphql
helpers – generic helpers that can be used in any other module – no dependencies
Environment Variables
This app is set up as a 12-factor app, configurable via environment variables.
The supported environment variables are:
NODE_ENV – test, development, or production
DATABASE_URL – the url of the postgres database.
PORT – port for the server to bind to. Defaults to 3001
PUBLIC_HOST – the public facing domain name to include in e.g. links.
REQUIRE_SSL – if this is not false, all requests are redirected to HTTPS.
WEB_CONCURRENCY – # of workers to use in clustered mode. Clustering disabled if value is 1.
NODE_MAX_OLD_SIZE - limit node process size to a given amount. Defaults to 460 MB to work well in 512MB containers, such as heroku.
DEV_SERVER_DISABLE_HOST_CHECK - disables the host check in webpack dev server, to allow testing from a VM or other host.
Running locally
Run yarn dev to start up both the server and client at the same time.
yarn dev runs:
webpack in watch mode to hot recompile the server
nodemon to run the server on port 3001 and restart the server on recompilation.
webpack-dev-server to run the client on port 3000, with proxy through to the server
nodemon processes to regenerate typescript types corresponding to graphql files on change.
The dev server watches for changes and restarts express each time a dependency file changes.
The dev client is using the webpack-dev-server to hot reload the client whenever a file changes. Our webpack dev server is configured in webpack/webpack-dev-server.js.
To build for production, run:
NODE_ENV=production yarn build
This will build the entire app into ./dist/.
Tests
We are using Jest for unit testing, and colocating tests with the modules they’re testing.
Unit tests for a module are located in a __tests__ directory in the same directory as the file being tested. Tests for module.ts should be named module.test.ts. Index files should be named after their parent directory. some-module/index.ts should be tested in some-module/__tests__/module.test.ts.
Running Unit Tests
To run unit tests, run yarn jest. This simply runs jest in the current directory, which will use config in the jest section of package.json.
To run jest in watch mode, and have it automatically rerun tests when files change:
yarn jest --watch
To see other jest options, you can run:
yarn jest -- --help
yarn test:unit is an alias for running jest directly.
Component tests
We are testing react components with Enzyme . See that for more information.
These tests are included in the Jest (unit) tests (above.)
Acceptance tests
Acceptance tests are written using Nightmare. See the test:acceptence tasks for more.
Linting
We are using tslint for linting. It is run automatically before unit tests.
Property testing
We have experimentally included JSVerify for property-based testing. Property-based testing is based on generating arbitrary inputs for functions and asserting that properties are invariant across those inputs. If an input is found which violates the property, the library will automatically simplify it to the minimal case that reproduces the error.
Styleguide
We are using React Storybook to generate a styleguide for our react components.
You can run the style guide with yarn dev:storybook
GraphQL and Code Generation
We're generating type definitions from our graphql schema, queries, and mutations. This allows us to get static type safety between our graphql code and typescript implementations.
To enable this, we're storing all graphql code in individual .graphql files. Our build process and dev server look for these and use them to generate the appropriate type definitions.
Query – containing the return types for each query
UsersByIdQueryArgs – the expected arguments for the usersById query
User – the straightforward typescript definition for User.
Note that we make liberal use of ! in the query definition to disallow null values as appropriate. ! should not be used when the operation may fail. Graphql prefers null returns in that case in most circumstances.
To make use of these types, we import them into our modules/graphql/index.ts for our resolver definition.
In particular, we would define our usersById resolver as:
Note that we use UsersByIdQueryArgs to tell typescript that this should be consistent with the defined schema arguments. We could use an inline type or separate interface, but doing so would defeat TypeScript's ability to tell us when we change the schema that our implementation is no longer compatible.
Similarly, we define the return type to be Promise<Query['usersById']>. Query['usersById'] is TypeScript syntax that means "whatever tye type of usersById on in the Query type is". By using this type subscripting syntax, we get static validation that our resolver is compatible with our schema.
GraphQL in the client
In the client we generate types for our graphql queries and mutations.
Entries will be added to modules/client/graphql-types.ts:
exportinterfaceUsersQueryVariables{foo: number;}exportinterfaceUsersQuery{// Returns all of the users in the system (canned results)usersById: Array<{id: number;name: string;}>;}
The types and query can be used with Apollo by require-ing the .grahql file directly from typescript and passing it in where a query is expected. The UsersQuery
The build:graphql task generates all type files. It:
Generates modules/graphql/schema.json from the schema.graphql. This is used by subsequent steps.
Generates schema-types.ts in the graphql module
Generates graphql-types.ts in the client
The dev:graphql task – which is run automatically by dev – watches for changes to any .graphql file and reruns build:graphql
Client Overview
The client has the following capabilities built-in:
Apollo Client for GraphQL queries/mutations.
Redux Saga for asynchronous workflows.
A small lens library for state selectors/updates.
Apollo Client is a smart graphql client with automatic caching and higher-order components for wiring presentation components to graphql queries.
Redux Sagas uses ES7 generator functions to support high level declaration and coordination of asynchronous workflows.
See modules/client/sagas/index.ts for an example redux saga which uses the apollo client to execute graphql queries.
Accessing/updating functional state in TypeScript requires a different solution from many of the common solutions in JavaScripot – immutable-helper, for example, is fundamentally untypable.
This starter-kit includes a library of functional lenses which are simple read/write helpers for accessing and updating substate of another object. A lens can be used as a function to get something out of an object, or can have .set or .update called on it to create an updated copy of an object.
The lens library is defined in modules/helpers/lenses.ts. See the tests for examples, as well as use in sagas/index.ts and reducers/index.ts.
CSS
CSS is implemented using the Trello CSS Guide naming conventions.
We are using the Bourbon stack as our CSS framework.
Organization
Instead of one monolithic stylesheet, each component should have its own styles.css which it requires in it’s main module. This approach eases maintainability, as each react component has its own stylesheet, and webpack will only package up CSS for the components we actually use.
React components should be named with semantic, specific names. However, the CSS classes used for a React component should be as generic as possible.
Prefer using an existing component class name with a new mod- modifier to specify the behavior of your component versus adding a new css class per react component.
For example, it is better to have one btn class that has a different mod-foo modifier for the FooButton react component, than make a foo-button class.
See the Trello CSS guide for more info.
DB
The database is postgres and is preconfigured to run in Docker.
To connect via a postgres client:
Host: 127.0.0.1
Port: 5432
Username: root
No Password
Database names:
development
test
To start: docker-compose up and leave running
To create dev/test databases: yarn db:create
To run psql shell against development DB: yarn db:run -- development
CI
The project is configured to run in CircleCI (see .circleci/config.yml). It's possible to run locally with circleci local execute. Warning: the tests may hang after completion if there aren't enough concurrent workers. Fix this by cranking up your cores in Docker or by specifying Jest's --maxWorkers. (We'd prefer not to check in a maxWorkers setting; we want test concurrency to be elastic with the number of hardware threads available.)
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