Get Started Building GraphQL APIs With Node
We all have a number of interests and passions. For example, I’m interested in JavaScript, 90’s indie rock and hip hop, obscure jazz, the city of Pittsburgh, pizza, coffee, and movies starring John Lurie. We also have family members, friends, acquaintances, classmates, and colleagues who also have their own social relationships, interests, and passions. Some of these relationships and interests overlap, like my friend Riley who shares my interest in 90’s hip hop and pizza. Others do not, like my colleague Harrison, who prefers Python to JavaScript, only drinks tea, and prefers current pop music. All together, we each have a connected graph of the people in our lives, and the ways that our relationships and interests overlap.
These types of interconnected data are exactly the challenge that GraphQL initially set out to solve in API development. By writing a GraphQL API we are able to efficiently connect data, which reduces the complexity and number of requests, while allowing us to serve the client precisely the data that it needs. (If you’re into more GraphQL metaphors, check out Meeting GraphQL at a Cocktail Mixer.)
In this article, we’ll build a GraphQL API in Node.js, using the Apollo Server package. To do so, we’ll explore fundamental GraphQL topics, write a GraphQL schema, develop code to resolve our schema functions, and access our API using the GraphQL Playground user interface.
What is GraphQL?
GraphQL is an open source query and data manipulation language for APIs. It was developed with the goal of providing single endpoints for data, allowing applications to request exactly the data that is needed. This has the benefit of not only simplifying our UI code, but also improving performance by limiting the amount of data that needs to be sent over the wire.
What we’re building
To follow along with this tutorial, you’ll need Node v8.x or later and some familiarity with working with the command line.
We’re going to build an API application for book highlights, allowing us to store memorable passages from the things that we read. Users of the API will be able to perform “CRUD” (create, read, update, delete) operations against their highlights:
- Create a new highlight
- Read an individual highlight as well as a list of highlights
- Update a highlight’s content
- Delete a highlight
Getting started
To get started, first create a new directory for our project, initialize a new node project, and install the dependencies that we’ll need:
# make the new directory
mkdir highlights-api
# change into the directory
cd highlights-api
# initiate a new node project
npm init -y
# install the project dependencies
npm install apollo-server graphql
# install the development dependencies
npm install nodemon --save-dev
Before moving on, let’s break down our dependencies:
apollo-server
is a library that enables us to work with GraphQL within our Node application. We’ll be using it as a standalone library, but the team at Apollo has also created middleware for working with existing Node web applications in Express, hapi, Fastify, and Koa.graphql
includes the GraphQL language and is a required peer dependency ofapollo-server
.nodemon
is a helpful library that will watch our project for changes and automatically restart our server.
With our packages installed, let’s next create our application’s root file, named index.js
. For now, we’ll console.log()
a message in this file:
console.log("📚 Hello Highlights");
To make our development process simpler, we’ll update the scripts
object within our package.json
file to make use of the nodemon
package:
"scripts": {
"start": "nodemon index.js"
},
Now, we can start our application by typing npm start
in the terminal application. If everything is working properly, you will see ? Hello Highlights
logged to your terminal.
GraphQL schema types
A schema is a written representation of our data and interactions. By requiring a schema, GraphQL enforces a strict plan for our API. This is because the API can only return data and perform interactions that are defined within the schema. The fundamental component of GraphQL schemas are object types. GraphQL contains five built-in types:
- String: A string with UTF-8 character encoding
- Boolean: A true or false value
- Int: A 32-bit integer
- Float: A floating-point value
- ID: A unique identifier
We can construct a schema for an API with these basic components. In a file named schema.js
, we can import the gql
library and prepare the file for our schema syntax:
const { gql } = require('apollo-server');
const typeDefs = gql`
# The schema will go here
`;
module.exports = typeDefs;
To write our schema, we first define the type. Let’s consider how we might define a schema for our highlights application. To begin, we would create a new type with a name of Highlight
:
const typeDefs = gql`
type Highlight {
}
`;
Each highlight will have a unique ID, some content, a title, and an author. The Highlight
schema will look something like this:
const typeDefs = gql`
type Highlight {
id: ID
content: String
title: String
author: String
}
`;
We can make some of these fields required by adding an exclamation point:
const typeDefs = gql`
type Highlight {
id: ID!
content: String!
title: String
author: String
}
`;
Though we’ve defined an object type for our highlights, we also need to provide a description of how a client will fetch that data. This is called a query
. We’ll dive more into queries shortly, but for now let’s describe in our schema the ways in which someone will retrieve highlights. When requesting all of our highlights, the data will be returned as an array (represented as [Highlight]
) and when we want to retrieve a single highlight we will need to pass an ID as a parameter.
const typeDefs = gql`
type Highlight {
id: ID!
content: String!
title: String
author: String
}
type Query {
highlights: [Highlight]!
highlight(id: ID!): Highlight
}
`;
Now, in the index.js
file, we can import our type definitions and set up Apollo Server:
const {ApolloServer } = require('apollo-server');
const typeDefs = require('./schema');
const server = new ApolloServer({ typeDefs });
server.listen().then(({ url }) => {
console.log(`📚 Highlights server ready at ${url}`);
});
If we’ve kept the node process running, the application will have automatically updated and relaunched, but if not, typing npm start
from the project’s directory in the terminal window will start the server. If we look at the terminal, we should see that nodemon
is watching our files and the server is running on a local port:
[nodemon] 2.0.2
[nodemon] to restart at any time, enter `rs`
[nodemon] watching dir(s): *.*
[nodemon] watching extensions: js,mjs,json
[nodemon] starting `node index.js`
📚 Highlights server ready at http://localhost:4000/
Visiting the URL in the browser will launch the GraphQL Playground application, which provides a user interface for interacting with our API.
GraphQL Resolvers
Though we’ve developed our project with an initial schema and Apollo Server setup, we can’t yet interact with our API. To do so, we’ll introduce resolvers. Resolvers perform exactly the action their name implies; they resolve the data that the API user has requested. We will write these resolvers by first defining them in our schema and then implementing the logic within our JavaScript code. Our API will contain two types of resolvers: queries and mutations.
Let’s first add some data to interact with. In an application, this would typically be data that we’re retrieving and writing to from a database, but for our example let’s use an array of objects. In the index.js
file add the following:
let highlights = [
{
id: '1',
content: 'One day I will find the right words, and they will be simple.',
title: 'Dharma Bums',
author: 'Jack Kerouac'
},
{
id: '2',
content: 'In the limits of a situation there is humor, there is grace, and everything else.',
title: 'Arbitrary Stupid Goal',
author: 'Tamara Shopsin'
}
]
Queries
A query requests specific data from an API, in its desired format. The query will then return an object, containing the data that the API user has requested. A query never modifies the data; it only accesses it. We’ve already written a two queries in our schema. The first returns an array of highlights and the second returns a specific highlight. The next step is to write the resolvers that will return the data.
In the index.js
file, we can add a resolvers object, which can contain our queries:
const resolvers = {
Query: {
highlights: () => highlights,
highlight: (parent, args) => {
return highlights.find(highlight => highlight.id === args.id);
}
}
};
The highlights
query returns the full array of highlights data. The highlight
query accepts two parameters: parent
and args
. The parent
is the first parameter of any GraqhQL query in Apollo Server and provides a way of accessing the context of the query. The args
parameter allows us to access the user provided arguments. In this case, users of the API will be supplying an id argument to access a specific highlight.
We can then update our Apollo Server configuration to include the resolvers:
const server = new ApolloServer({ typeDefs, resolvers });
With our query resolvers written and Apollo Server updated, we can now query API using the GraphQL Playground. To access the GraphQL Playground, visit http://localhost:4000
in your web browser.
A query is formatted as so:
query {
queryName {
field
field
}
}
With this in mind, we can write a query that requests the ID, content, title, and author for each our highlights:
query {
highlights {
id
content
title
author
}
}
Let’s say that we had a page in our UI that lists only the titles and authors of our highlighted texts. We wouldn’t need to retrieve the content for each of those highlights. Instead, we could write a query that only requests the data that we need:
query {
highlights {
title
author
}
}
We’ve also written a resolver to query for an individual note by including an ID parameter with our query. We can do so as follows:
query {
highlight(id: "1") {
content
}
}
Mutations
We use a mutation when we want to modify the data in our API. In our highlight example, we will want to write a mutation to create a new highlight, one to update an existing highlight, and a third to delete a highlight. Similar to a query, a mutation is also expected to return a result in the form of an object, typically the end result of the performed action.
The first step to updating anything in GraphQL is to write the schema. We can include mutations in our schema, by adding a mutation type to our schema.js
file:
type Mutation {
newHighlight (content: String! title: String author: String): Highlight!
updateHighlight(id: ID! content: String!): Highlight!
deleteHighlight(id: ID!): Highlight!
}
Our newHighlight
mutation will take the required value of content along with optional title
and author
values and return a Highlight
. The updateHighlight
mutation will require that a highlight id
and content
be passed as argument values and will return the updated Highlight
. Finally, the deleteHighligh
t mutation will accept an ID argument, and will return the deleted Highlight.
With the schema updated to include mutations, we can now update the resolvers
in our index.js
file to perform these actions. Each mutation will update our highlights
array of data.
const resolvers = {
Query: {
highlights: () => highlights,
highlight: (parent, args) => {
return highlights.find(highlight => highlight.id === args.id);
}
},
Mutation: {
newHighlight: (parent, args) => {
const highlight = {
id: String(highlights.length + 1),
title: args.title || '',
author: args.author || '',
content: args.content
};
highlights.push(highlight);
return highlight;
},
updateHighlight: (parent, args) => {
const index = highlights.findIndex(highlight => highlight.id === args.id);
const highlight = {
id: args.id,
content: args.content,
author: highlights[index].author,
title: highlights[index].title
};
highlights[index] = highlight;
return highlight;
},
deleteHighlight: (parent, args) => {
const deletedHighlight = highlights.find(
highlight => highlight.id === args.id
);
highlights = highlights.filter(highlight => highlight.id !== args.id);
return deletedHighlight;
}
}
};
With these mutations written, we can use the GraphQL Playground to practice mutating the data. The structure of a mutation is nearly identical to that of a query, specifying the name of the mutation, passing the argument values, and requesting specific data in return. Let’s start by adding a new highlight:
mutation {
newHighlight(author: "Adam Scott" title: "JS Everywhere" content: "GraphQL is awesome") {
id
author
title
content
}
}
We can then write mutations to update a highlight:
mutation {
updateHighlight(id: "3" content: "GraphQL is rad") {
id
content
}
}
And to delete a highlight:
mutation {
deleteHighlight(id: "3") {
id
}
}
Wrapping up
Congratulations! You’ve now successfully built a GraphQL API, using Apollo Server, and can run GraphQL queries and mutations against an in-memory data object. We’ve established a solid foundation for exploring the world of GraphQL API development.
Here are some potential next steps to level up:
- Learn about nested GraphQL queries and mutations.
- Follow along with the Apollo Full Stack tutorial.
- Update the example to include a database, such as MongoDB or PostgreSQL.
- Explore more of the great CSS-Tricks GraphQL articles.
- Use your newfound GraphQL knowledge to build static websites with Gatsby.
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