The GraphQL specification is edited in the markdown files found in /spec
the latest release of which is published at http://facebook.github.io/graphql/.
The latest draft specification can be found at http://facebook.github.io/graphql/draft/ which tracks the latest commit to the master branch in this repository.
Previous releases of the GraphQL specification can be found at permalinks that match their release tag. For example, http://facebook.github.io/graphql/October2016/. If you are linking directly to the GraphQL specification, it's best to link to a tagged permalink for the particular referenced version.
yarn
yarn update-schema
yarn relay
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This is a Working Draft of the Specification for GraphQL, a query language for APIs created by Facebook.
The target audience for this specification is not the client developer, but those who have, or are actively interested in, building their own GraphQL implementations and tools.
In order to be broadly adopted, GraphQL will have to target a wide variety of backends, frameworks, and languages, which will necessitate a collaborative effort across projects and organizations. This specification serves as a point of coordination for this effort.
Looking for help? Find resources from the community.
GraphQL consists of a type system, query language and execution semantics, static validation, and type introspection, each outlined below. To guide you through each of these components, we've written an example designed to illustrate the various pieces of GraphQL.
This example is not comprehensive, but it is designed to quickly introduce the core concepts of GraphQL, to provide some context before diving into the more detailed specification or the GraphQL.js reference implementation.
The premise of the example is that we want to use GraphQL to query for information about characters and locations in the original Star Wars trilogy.
At the heart of any GraphQL implementation is a description of what types of objects it can return, described in a GraphQL type system and returned in the GraphQL Schema.
For our Star Wars example, the starWarsSchema.js file in GraphQL.js defines this type system.
The most basic type in the system will be Human
, representing characters
like Luke, Leia, and Han. All humans in our type system will have a name,
so we define the Human
type to have a field called "name". This returns
a String, and we know that it is not null (since all Human
s have a name),
so we will define the "name" field to be a non-nullable String. Using a
shorthand notation that we will use throughout the spec and documentation,
we would describe the human type as:
type Human {
name: String
}
This shorthand is convenient for describing the basic shape of a type system; the JavaScript implementation is more full-featured, and allows types and fields to be documented. It also sets up the mapping between the type system and the underlying data; for a test case in GraphQL.js, the underlying data is a set of JavaScript objects, but in most cases the backing data will be accessed through some service, and this type system layer will be responsible for mapping from types and fields to that service.
A common pattern in many APIs, and indeed in GraphQL is to give objects an ID that can be used to refetch the object. So let's add that to our Human type. We'll also add a string for their home planet.
type Human {
id: String
name: String
homePlanet: String
}
Since we're talking about the Star Wars trilogy, it would be useful to describe the episodes in which each character appears. To do so, we'll first define an enum, which lists the three episodes in the trilogy:
enum Episode { NEWHOPE, EMPIRE, JEDI }
Now we want to add a field to Human
describing what episodes they
were in. This will return a list of Episode
s:
type Human {
id: String
name: String
appearsIn: [Episode]
homePlanet: String
}
Now, let's introduce another type, Droid
:
type Droid {
id: String
name: String
appearsIn: [Episode]
primaryFunction: String
}
Now we have two types! Let's add a way of going between them: humans and droids both have friends. But humans can be friends with both humans and droids. How do we refer to either a human or a droid?
If we look, we note that there's common functionality between
humans and droids; they both have IDs, names, and episodes in which
they appear. So we'll add an interface, Character
, and make
both Human
and Droid
implement it. Once we have that, we can
add the friends
field, that returns a list of Character
s.
Our type system so far is:
enum Episode { NEWHOPE, EMPIRE, JEDI }
interface Character {
id: String
name: String
friends: [Character]
appearsIn: [Episode]
}
type Human implements Character {
id: String
name: String
friends: [Character]
appearsIn: [Episode]
homePlanet: String
}
type Droid implements Character {
id: String
name: String
friends: [Character]
appearsIn: [Episode]
primaryFunction: String
}
One question we might ask, though, is whether any of those fields can return
null
. By default, null
is a permitted value for any type in GraphQL,
since fetching data to fulfill a GraphQL query often requires talking
to different services that may or may not be available. However, if the
type system can guarantee that a type is never null, then we can mark
it as Non Null in the type system. We indicate that in our shorthand
by adding an "!" after the type. We can update our type system to note
that the id
is never null.
Note that while in our current implementation, we can guarantee that more fields are non-null (since our current implementation has hard-coded data), we didn't mark them as non-null. One can imagine we would eventually replace our hardcoded data with a backend service, which might not be perfectly reliable; by leaving these fields as nullable, we allow ourselves the flexibility to eventually return null to indicate a backend error, while also telling the client that the error occurred.
enum Episode { NEWHOPE, EMPIRE, JEDI }
interface Character {
id: String!
name: String
friends: [Character]
appearsIn: [Episode]
}
type Human implements Character {
id: String!
name: String
friends: [Character]
appearsIn: [Episode]
homePlanet: String
}
type Droid implements Character {
id: String!
name: String
friends: [Character]
appearsIn: [Episode]
primaryFunction: String
}
We're missing one last piece: an entry point into the type system.
When we define a schema, we define an object type that is the basis for all
queries. The name of this type is Query
by convention, and it describes
our public, top-level API. Our Query
type for this example will look like
this:
type Query {
hero(episode: Episode): Character
human(id: String!): Human
droid(id: String!): Droid
}
In this example, there are three top-level operations that can be done on our schema:
hero
returns theCharacter
who is the hero of the Star Wars trilogy; it takes an optional argument that allows us to fetch the hero of a specific episode instead.human
accepts a non-null string as a query argument, a human's ID, and returns the human with that ID.droid
does the same for droids.
These fields demonstrate another feature of the type system, the ability for a field to specify arguments that configure their behavior.
When we package the whole type system together, defining the Query
type
above as our entry point for queries, this creates a GraphQL Schema.
This example just scratched the surface of the type system. The specification goes into more detail about this topic in the "Type System" section, and the type directory in GraphQL.js contains code implementing a specification-compliant GraphQL type system.
GraphQL queries declaratively describe what data the issuer wishes to fetch from whoever is fulfilling the GraphQL query.
For our Star Wars example, the starWarsQueryTests.js file in the GraphQL.js repository contains a number of queries and responses. That file is a test file that uses the schema discussed above and a set of sample data, located in starWarsData.js. This test file can be run to exercise the reference implementation.
An example query on the above schema would be:
query HeroNameQuery {
hero {
name
}
}
The initial line, query HeroNameQuery
, defines a query with the operation
name HeroNameQuery
that starts with the schema's root query type; in this
case, Query
. As defined above, Query
has a hero
field that returns a
Character
, so we'll query for that. Character
then has a name
field that
returns a String
, so we query for that, completing our query. The result of
this query would then be:
{
"hero": {
"name": "R2-D2"
}
}
Specifying the query
keyword and an operation name is only required when a
GraphQL document defines multiple operations. We therefore could have written
the previous query with the query shorthand:
{
hero {
name
}
}
Assuming that the backing data for the GraphQL server identified R2-D2 as the hero. The response continues to vary based on the request; if we asked for R2-D2's ID and friends with this query:
query HeroNameAndFriendsQuery {
hero {
id
name
friends {
id
name
}
}
}
then we'll get back a response like this:
{
"hero": {
"id": "2001",
"name": "R2-D2",
"friends": [
{
"id": "1000",
"name": "Luke Skywalker"
},
{
"id": "1002",
"name": "Han Solo"
},
{
"id": "1003",
"name": "Leia Organa"
}
]
}
}
One of the key aspects of GraphQL is its ability to nest queries. In the above query, we asked for R2-D2's friends, but we can ask for more information about each of those objects. So let's construct a query that asks for R2-D2's friends, gets their name and episode appearances, then asks for each of their friends.
query NestedQuery {
hero {
name
friends {
name
appearsIn
friends {
name
}
}
}
}
which will give us the nested response
{
"hero": {
"name": "R2-D2",
"friends": [
{
"name": "Luke Skywalker",
"appearsIn": ["NEWHOPE", "EMPIRE", "JEDI"],
"friends": [
{ "name": "Han Solo" },
{ "name": "Leia Organa" },
{ "name": "C-3PO" },
{ "name": "R2-D2" }
]
},
{
"name": "Han Solo",
"appearsIn": ["NEWHOPE", "EMPIRE", "JEDI"],
"friends": [
{ "name": "Luke Skywalker" },
{ "name": "Leia Organa" },
{ "name": "R2-D2" }
]
},
{
"name": "Leia Organa",
"appearsIn": ["NEWHOPE", "EMPIRE", "JEDI"],
"friends": [
{ "name": "Luke Skywalker" },
{ "name": "Han Solo" },
{ "name": "C-3PO" },
{ "name": "R2-D2" }
]
}
]
}
}
The Query
type above defined a way to fetch a human given their
ID. We can use it by hardcoding the ID in the query:
query FetchLukeQuery {
human(id: "1000") {
name
}
}
to get
{
"human": {
"name": "Luke Skywalker"
}
}
Alternately, we could have defined the query to have a query parameter:
query FetchSomeIDQuery($someId: String!) {
human(id: $someId) {
name
}
}
This query is now parameterized by $someId
; to run it, we must provide
that ID. If we ran it with $someId
set to "1000", we would get Luke;
set to "1002", we would get Han. If we passed an invalid ID here,
we would get null
back for the human
, indicating that no such object
exists.
Notice that the key in the response is the name of the field, by default. It is sometimes useful to change this key, for clarity or to avoid key collisions when fetching the same field with different arguments.
We can do that with field aliases, as demonstrated in this query:
query FetchLukeAliased {
luke: human(id: "1000") {
name
}
}
We aliased the result of the human
field to the key luke
. Now the response
is:
{
"luke": {
"name": "Luke Skywalker"
}
}
Notice the key is "luke" and not "human", as it was in our previous example where we did not use the alias.
This is particularly useful if we want to use the same field twice with different arguments, as in the following query:
query FetchLukeAndLeiaAliased {
luke: human(id: "1000") {
name
}
leia: human(id: "1003") {
name
}
}
We aliased the result of the first human
field to the key
luke
, and the second to leia
. So the result will be:
{
"luke": {
"name": "Luke Skywalker"
},
"leia": {
"name": "Leia Organa"
}
}
Now imagine we wanted to ask for Luke and Leia's home planets. We could do so with this query:
query DuplicateFields {
luke: human(id: "1000") {
name
homePlanet
}
leia: human(id: "1003") {
name
homePlanet
}
}
but we can already see that this could get unwieldy, since we have to add new fields to both parts of the query. Instead, we can extract out the common fields into a fragment, and include the fragment in the query, like this:
query UseFragment {
luke: human(id: "1000") {
...HumanFragment
}
leia: human(id: "1003") {
...HumanFragment
}
}
fragment HumanFragment on Human {
name
homePlanet
}
Both of those queries give this result:
{
"luke": {
"name": "Luke Skywalker",
"homePlanet": "Tatooine"
},
"leia": {
"name": "Leia Organa",
"homePlanet": "Alderaan"
}
}
The UseFragment
and DuplicateFields
queries will both get the same result, but
UseFragment
is less verbose; if we wanted to add more fields, we could add
it to the common fragment rather than copying it into multiple places.
We defined the type system above, so we know the type of each object
in the output; the query can ask for that type using the special
field __typename
, defined on every object.
query CheckTypeOfR2 {
hero {
__typename
name
}
}
Since R2-D2 is a droid, this will return
{
"hero": {
"__typename": "Droid",
"name": "R2-D2"
}
}
This was particularly useful because hero
was defined to return a Character
,
which is an interface; we might want to know what concrete type was actually
returned. If we instead asked for the hero of Episode V:
query CheckTypeOfLuke {
hero(episode: EMPIRE) {
__typename
name
}
}
We would find that it was Luke, who is a Human:
{
"hero": {
"__typename": "Human",
"name": "Luke Skywalker"
}
}
As with the type system, this example just scratched the surface of the query language. The specification goes into more detail about this topic in the "Language" section, and the language directory in GraphQL.js contains code implementing a specification-compliant GraphQL query language parser and lexer.
By using the type system, it can be predetermined whether a GraphQL query is valid or not. This allows servers and clients to effectively inform developers when an invalid query has been created, without having to rely on runtime checks.
For our Star Wars example, the file starWarsValidationTests.js contains a number of queries demonstrating various invalidities, and is a test file that can be run to exercise the reference implementation's validator.
To start, let's take a complex valid query. This is the NestedQuery
example
from the above section, but with the duplicated fields factored out into
a fragment:
query NestedQueryWithFragment {
hero {
...NameAndAppearances
friends {
...NameAndAppearances
friends {
...NameAndAppearances
}
}
}
}
fragment NameAndAppearances on Character {
name
appearsIn
}
And this query is valid. Let's take a look at some invalid queries!
When we query for fields, we have to query for a field that exists on the
given type. So as hero
returns a Character
, we have to query for a field
on Character
. That type does not have a favoriteSpaceship
field, so this
query:
# INVALID: favoriteSpaceship does not exist on Character
query HeroSpaceshipQuery {
hero {
favoriteSpaceship
}
}
is invalid.
Whenever we query for a field and it returns something other than a scalar
or an enum, we need to specify what data we want to get back from the field.
Hero returns a Character
, and we've been requesting fields like name
and
appearsIn
on it; if we omit that, the query will not be valid:
# INVALID: hero is not a scalar, so fields are needed
query HeroNoFieldsQuery {
hero
}
Similarly, if a field is a scalar, it doesn't make sense to query for additional fields on it, and doing so will make the query invalid:
# INVALID: name is a scalar, so fields are not permitted
query HeroFieldsOnScalarQuery {
hero {
name {
firstCharacterOfName
}
}
}
Earlier, it was noted that a query can only query for fields on the type
in question; when we query for hero
which returns a Character
, we
can only query for fields that exist on Character
. What happens if we
want to query for R2-D2s primary function, though?
# INVALID: primaryFunction does not exist on Character
query DroidFieldOnCharacter {
hero {
name
primaryFunction
}
}
That query is invalid, because primaryFunction
is not a field on Character
.
We want some way of indicating that we wish to fetch primaryFunction
if the
Character
is a Droid
, and to ignore that field otherwise. We can use
the fragments we introduced earlier to do this. By setting up a fragment defined
on Droid
and including it, we ensure that we only query for primaryFunction
where it is defined.
query DroidFieldInFragment {
hero {
name
...DroidFields
}
}
fragment DroidFields on Droid {
primaryFunction
}
This query is valid, but it's a bit verbose; named fragments were valuable above when we used them multiple times, but we're only using this one once. Instead of using a named fragment, we can use an inline fragment; this still allows us to indicate the type we are querying on, but without naming a separate fragment:
query DroidFieldInInlineFragment {
hero {
name
... on Droid {
primaryFunction
}
}
}
This has just scratched the surface of the validation system; there are a number of validation rules in place to ensure that a GraphQL query is semantically meaningful. The specification goes into more detail about this topic in the "Validation" section, and the validation directory in GraphQL.js contains code implementing a specification-compliant GraphQL validator.
It's often useful to ask a GraphQL schema for information about what queries it supports. GraphQL allows us to do so using the introspection system!
For our Star Wars example, the file starWarsIntrospectionTests.js contains a number of queries demonstrating the introspection system, and is a test file that can be run to exercise the reference implementation's introspection system.
We designed the type system, so we know what types are available, but if
we didn't, we can ask GraphQL, by querying the __schema
field, always
available on the root type of a Query. Let's do so now, and ask what types
are available.
query IntrospectionTypeQuery {
__schema {
types {
name
}
}
}
and we get back:
{
"__schema": {
"types": [
{
"name": "Query"
},
{
"name": "Character"
},
{
"name": "Human"
},
{
"name": "String"
},
{
"name": "Episode"
},
{
"name": "Droid"
},
{
"name": "__Schema"
},
{
"name": "__Type"
},
{
"name": "__TypeKind"
},
{
"name": "Boolean"
},
{
"name": "__Field"
},
{
"name": "__InputValue"
},
{
"name": "__EnumValue"
},
{
"name": "__Directive"
}
]
}
}
Wow, that's a lot of types! What are they? Let's group them:
- Query, Character, Human, Episode, Droid - These are the ones that we defined in our type system.
- String, Boolean - These are built-in scalars that the type system provided.
- __Schema, __Type, __TypeKind, __Field, __InputValue, __EnumValue, __Directive - These all are preceded with a double underscore, indicating that they are part of the introspection system.
Now, let's try and figure out a good place to start exploring what queries are available. When we designed our type system, we specified what type all queries would start at; let's ask the introspection system about that!
query IntrospectionQueryTypeQuery {
__schema {
queryType {
name
}
}
}
and we get back:
{
"__schema": {
"queryType": {
"name": "Query"
}
}
}
And that matches what we said in the type system section, that
the Query
type is where we will start! Note that the naming here
was just by convention; we could have named our Query
type anything
else, and it still would have been returned here if we had specified it
as the starting type for queries. Naming it Query
, though, is a useful
convention.
It is often useful to examine one specific type. Let's take a look at
the Droid
type:
query IntrospectionDroidTypeQuery {
__type(name: "Droid") {
name
}
}
and we get back:
{
"__type": {
"name": "Droid"
}
}
What if we want to know more about Droid, though? For example, is it an interface or an object?
query IntrospectionDroidKindQuery {
__type(name: "Droid") {
name
kind
}
}
and we get back:
{
"__type": {
"name": "Droid",
"kind": "OBJECT"
}
}
kind
returns a __TypeKind
enum, one of whose values is OBJECT
. If
we asked about Character
instead:
query IntrospectionCharacterKindQuery {
__type(name: "Character") {
name
kind
}
}
and we get back:
{
"__type": {
"name": "Character",
"kind": "INTERFACE"
}
}
We'd find that it is an interface.
It's useful for an object to know what fields are available, so let's
ask the introspection system about Droid
:
query IntrospectionDroidFieldsQuery {
__type(name: "Droid") {
name
fields {
name
type {
name
kind
}
}
}
}
and we get back:
{
"__type": {
"name": "Droid",
"fields": [
{
"name": "id",
"type": {
"name": null,
"kind": "NON_NULL"
}
},
{
"name": "name",
"type": {
"name": "String",
"kind": "SCALAR"
}
},
{
"name": "friends",
"type": {
"name": null,
"kind": "LIST"
}
},
{
"name": "appearsIn",
"type": {
"name": null,
"kind": "LIST"
}
},
{
"name": "primaryFunction",
"type": {
"name": "String",
"kind": "SCALAR"
}
}
]
}
}
Those are our fields that we defined on Droid
!
id
looks a bit weird there, it has no name for the type. That's
because it's a "wrapper" type of kind NON_NULL
. If we queried for
ofType
on that field's type, we would find the String
type there,
telling us that this is a non-null String.
Similarly, both friends
and appearsIn
have no name, since they are the
LIST
wrapper type. We can query for ofType
on those types, which will
tell us what these are lists of.
query IntrospectionDroidWrappedFieldsQuery {
__type(name: "Droid") {
name
fields {
name
type {
name
kind
ofType {
name
kind
}
}
}
}
}
and we get back:
{
"__type": {
"name": "Droid",
"fields": [
{
"name": "id",
"type": {
"name": null,
"kind": "NON_NULL",
"ofType": {
"name": "String",
"kind": "SCALAR"
}
}
},
{
"name": "name",
"type": {
"name": "String",
"kind": "SCALAR",
"ofType": null
}
},
{
"name": "friends",
"type": {
"name": null,
"kind": "LIST",
"ofType": {
"name": "Character",
"kind": "INTERFACE"
}
}
},
{
"name": "appearsIn",
"type": {
"name": null,
"kind": "LIST",
"ofType": {
"name": "Episode",
"kind": "ENUM"
}
}
},
{
"name": "primaryFunction",
"type": {
"name": "String",
"kind": "SCALAR",
"ofType": null
}
}
]
}
}
Let's end with a feature of the introspection system particularly useful for tooling; let's ask the system for documentation!
query IntrospectionDroidDescriptionQuery {
__type(name: "Droid") {
name
description
}
}
yields
{
"__type": {
"name": "Droid",
"description": "A mechanical creature in the Star Wars universe."
}
}
So we can access the documentation about the type system using introspection, and create documentation browsers, or rich IDE experiences.
This has just scratched the surface of the introspection system; we can query for enum values, what interfaces a type implements, and more. We can even introspect on the introspection system itself. The specification goes into more detail about this topic in the "Introspection" section, and the introspection file in GraphQL.js contains code implementing a specification-compliant GraphQL query introspection system.
This README walked through the GraphQL.js reference implementation's type system, query execution, validation, and introspection systems. There's more in both GraphQL.js and specification, including a description and implementation for executing queries, how to format a response, explaining how a type system maps to an underlying implementation, and how to format a GraphQL response, as well as the grammar for GraphQL.