Section 3 -- Type System.md

Type System

The GraphQL Type system describes the capabilities of a GraphQL service and is used to determine if a requested operation is valid, to guarantee the type of response results, and describes the input types of variables to determine if values provided at request time are valid.

TypeSystemDocument : TypeSystemDefinition+

TypeSystemDefinition :

• SchemaDefinition
• TypeDefinition
• DirectiveDefinition

The GraphQL language includes an IDL used to describe a GraphQL service's type system. Tools may use this definition language to provide utilities such as client code generation or service boot-strapping.

GraphQL tools or services which only seek to execute GraphQL requests and not construct a new GraphQL schema may choose not to allow {TypeSystemDefinition}. Tools which only seek to produce schema and not execute requests may choose to only allow {TypeSystemDocument} and not allow {ExecutableDefinition} or {TypeSystemExtension} but should provide a descriptive error if present.

Note: The type system definition language is used throughout the remainder of this specification document when illustrating example type systems.

Type System Extensions

TypeSystemExtensionDocument : TypeSystemDefinitionOrExtension+

TypeSystemDefinitionOrExtension :

• TypeSystemDefinition
• TypeSystemExtension

TypeSystemExtension :

• SchemaExtension
• TypeExtension

Type system extensions are used to represent a GraphQL type system which has been extended from some original type system. For example, this might be used by a local service to represent data a GraphQL client only accesses locally, or by a GraphQL service which is itself an extension of another GraphQL service.

Tools which only seek to produce and extend schema and not execute requests may choose to only allow {TypeSystemExtensionDocument} and not allow {ExecutableDefinition} but should provide a descriptive error if present.

Descriptions

Description : StringValue

Documentation is a first-class feature of GraphQL type systems. To ensure the documentation of a GraphQL service remains consistent with its capabilities, descriptions of GraphQL definitions are provided alongside their definitions and made available via introspection.

To allow GraphQL service designers to easily publish documentation alongside the capabilities of a GraphQL service, GraphQL descriptions are defined using the Markdown syntax (as specified by CommonMark). In the type system definition language, these description strings (often {BlockString}) occur immediately before the definition they describe.

GraphQL schema and all other definitions (e.g. types, fields, arguments, etc.) which can be described should provide a {Description} unless they are considered self descriptive.

As an example, this simple GraphQL schema is well described:

"""
A simple GraphQL schema which is well described.
"""
schema {
  query: Query
}

"""
Root type for all your query operations
"""
type Query {
  """
  Translates a string from a given language into a different language.
  """
  translate(
    "The original language that `text` is provided in."
    fromLanguage: Language

    "The translated language to be returned."
    toLanguage: Language

    "The text to be translated."
    text: String
  ): String
}

"""
The set of languages supported by `translate`.
"""
enum Language {
  "English"
  EN

  "French"
  FR

  "Chinese"
  CH
}

Schema

SchemaDefinition : Description? schema Directives[Const]? { RootOperationTypeDefinition+ }

RootOperationTypeDefinition : OperationType : NamedType

A GraphQL service's collective type system capabilities are referred to as that service's "schema". A schema is defined in terms of the types and directives it supports as well as the root operation types for each kind of operation: query, mutation, and subscription; this determines the place in the type system where those operations begin.

A GraphQL schema must itself be internally valid. This section describes the rules for this validation process where relevant.

All types within a GraphQL schema must have unique names. No two provided types may have the same name. No provided type may have a name which conflicts with any built in types (including Scalar and Introspection types).

All directives within a GraphQL schema must have unique names.

All types and directives defined within a schema must not have a name which begins with {"__"} (two underscores), as this is used exclusively by GraphQL's introspection system.

Root Operation Types

A schema defines the initial root operation type for each kind of operation it supports: query, mutation, and subscription; this determines the place in the type system where those operations begin.

The {query} root operation type must be provided and must be an Object type.

The {mutation} root operation type is optional; if it is not provided, the service does not support mutations. If it is provided, it must be an Object type.

Similarly, the {subscription} root operation type is also optional; if it is not provided, the service does not support subscriptions. If it is provided, it must be an Object type.

The {query}, {mutation}, and {subscription} root types must all be different types if provided.

The fields on the {query} root operation type indicate what fields are available at the top level of a GraphQL query operation.

For example, this example operation:

query {
  myName
}

is only valid when the {query} root operation type has a field named "myName":

type Query {
  myName: String
}

Similarly, the following mutation is only valid if the {mutation} root operation type has a field named "setName".

mutation {
  setName(name: "Zuck") {
    newName
  }
}

When using the type system definition language, a document must include at most one {schema} definition.

In this example, a GraphQL schema is defined with both query and mutation root operation types:

schema {
  query: MyQueryRootType
  mutation: MyMutationRootType
}

type MyQueryRootType {
  someField: String
}

type MyMutationRootType {
  setSomeField(to: String): String
}

Default Root Operation Type Names

While any type can be the root operation type for a GraphQL operation, the type system definition language can omit the schema definition when the {query}, {mutation}, and {subscription} root types are named {"Query"}, {"Mutation"}, and {"Subscription"} respectively.

Likewise, when representing a GraphQL schema using the type system definition language, a schema definition should be omitted if it only uses the default root operation type names.

This example describes a valid complete GraphQL schema, despite not explicitly including a {schema} definition. The {"Query"} type is presumed to be the {query} root operation type of the schema.

type Query {
  someField: String
}

Schema Extension

SchemaExtension :

• extend schema Directives[Const]? { RootOperationTypeDefinition+ }
• extend schema Directives[Const] [lookahead != {]

Schema extensions are used to represent a schema which has been extended from an original schema. For example, this might be used by a GraphQL service which adds additional operation types, or additional directives to an existing schema.

Note: Schema extensions without additional operation type definitions must not be followed by a {{} (such as a query shorthand) to avoid parsing ambiguity. The same limitation applies to the type definitions and extensions below.

Schema Validation

Schema extensions have the potential to be invalid if incorrectly defined.

1. The Schema must already be defined.
2. Any non-repeatable directives provided must not already apply to the original Schema.

Types

TypeDefinition :

• ScalarTypeDefinition
• ObjectTypeDefinition
• InterfaceTypeDefinition
• UnionTypeDefinition
• EnumTypeDefinition
• InputObjectTypeDefinition

The fundamental unit of any GraphQL Schema is the type. There are six kinds of named type definitions in GraphQL, and two wrapping types.

The most basic type is a Scalar. A scalar represents a primitive value, like a string or an integer. Oftentimes, the possible responses for a scalar field are enumerable. GraphQL offers an Enum type in those cases, where the type specifies the space of valid responses.

Scalars and Enums form the leaves in response trees; the intermediate levels are Object types, which define a set of fields, where each field is another type in the system, allowing the definition of arbitrary type hierarchies.

GraphQL supports two abstract types: interfaces and unions.

An Interface defines a list of fields; Object types and other Interface types which implement this Interface are guaranteed to implement those fields. Whenever a field claims it will return an Interface type, it will return a valid implementing Object type during execution.

A Union defines a list of possible types; similar to interfaces, whenever the type system claims a union will be returned, one of the possible types will be returned.

Finally, oftentimes it is useful to provide complex structs as inputs to GraphQL field arguments or variables; the Input Object type allows the schema to define exactly what data is expected.

Wrapping Types

All of the types so far are assumed to be both nullable and singular: e.g. a scalar string returns either null or a singular string.

A GraphQL schema may describe that a field represents a list of another type; the List type is provided for this reason, and wraps another type.

Similarly, the Non-Null type wraps another type, and denotes that the resulting value will never be {null} (and that a field error cannot result in a {null} value).

These two types are referred to as "wrapping types"; non-wrapping types are referred to as "named types". A wrapping type has an underlying named type, found by continually unwrapping the type until a named type is found.

Input and Output Types

Types are used throughout GraphQL to describe both the values accepted as input to arguments and variables as well as the values output by fields. These two uses categorize types as input types and output types. Some kinds of types, like Scalar and Enum types, can be used as both input types and output types; other kinds of types can only be used in one or the other. Input Object types can only be used as input types. Object, Interface, and Union types can only be used as output types. Lists and Non-Null types may be used as input types or output types depending on how the wrapped type may be used.

IsInputType(type) :

• If {type} is a List type or Non-Null type:
  • Let {unwrappedType} be the unwrapped type of {type}.
  • Return IsInputType({unwrappedType})
• If {type} is a Scalar, Enum, or Input Object type:
  • Return {true}
• Return {false}

IsOutputType(type) :

• If {type} is a List type or Non-Null type:
  • Let {unwrappedType} be the unwrapped type of {type}.
  • Return IsOutputType({unwrappedType})
• If {type} is a Scalar, Object, Interface, Union, or Enum type:
  • Return {true}
• Return {false}

Type Extensions

TypeExtension :

• ScalarTypeExtension
• ObjectTypeExtension
• InterfaceTypeExtension
• UnionTypeExtension
• EnumTypeExtension
• InputObjectTypeExtension

Type extensions are used to represent a GraphQL type which has been extended from some original type. For example, this might be used by a local service to represent additional fields a GraphQL client only accesses locally.

Scalars

ScalarTypeDefinition : Description? scalar Name Directives[Const]?

Scalar types represent primitive leaf values in a GraphQL type system. GraphQL responses take the form of a hierarchical tree; the leaves of this tree are typically GraphQL Scalar types (but may also be Enum types or {null} values).

GraphQL provides a number of built-in scalars which are fully defined in the sections below, however type systems may also add additional custom scalars to introduce additional semantic meaning.

Built-in Scalars

GraphQL specifies a basic set of well-defined Scalar types: {Int}, {Float}, {String}, {Boolean}, and {ID}. A GraphQL framework should support all of these types, and a GraphQL service which provides a type by these names must adhere to the behavior described for them in this document. As an example, a service must not include a type called {Int} and use it to represent 64-bit numbers, internationalization information, or anything other than what is defined in this document.

When returning the set of types from the __Schema introspection type, all referenced built-in scalars must be included. If a built-in scalar type is not referenced anywhere in a schema (there is no field, argument, or input field of that type) then it must not be included.

When representing a GraphQL schema using the type system definition language, all built-in scalars must be omitted for brevity.

Custom Scalars

GraphQL services may use custom scalar types in addition to the built-in scalars. For example, a GraphQL service could define a scalar called UUID which, while serialized as a string, conforms to RFC 4122. When querying a field of type UUID, you can then rely on the ability to parse the result with a RFC 4122 compliant parser. Another example of a potentially useful custom scalar is URL, which serializes as a string, but is guaranteed by the server to be a valid URL.

When defining a custom scalar, GraphQL services should provide a specification URL via the @specifiedBy directive or the specifiedByURL introspection field. This URL must link to a human-readable specification of the data format, serialization, and coercion rules for the scalar. For example, a GraphQL service providing a UUID scalar may link to RFC 4122, or some custom document defining a reasonable subset of that RFC. If a scalar specification URL is present, systems and tools that are aware of it should conform to its described rules.

scalar UUID @specifiedBy(url: "https://tools.ietf.org/html/rfc4122")
scalar URL @specifiedBy(url: "https://tools.ietf.org/html/rfc3986")

Custom scalar specifications should provide a single, stable format to avoid ambiguity. If the linked specification is in flux, the service should link to a fixed version rather than to a resource which might change.

Custom scalar specification URLs should not be changed once defined. Doing so would likely disrupt tooling or could introduce breaking changes within the linked specification's contents.

Built-in scalar types must not provide a specification URL as they are specified by this document.

Note: Custom scalars should also summarize the specified format and provide examples in their description.

Result Coercion and Serialization

A GraphQL service, when preparing a field of a given scalar type, must uphold the contract the scalar type describes, either by coercing the value or producing a field error if a value cannot be coerced or if coercion may result in data loss.

A GraphQL service may decide to allow coercing different internal types to the expected return type. For example when coercing a field of type {Int} a boolean {true} value may produce {1} or a string value {"123"} may be parsed as base-10 {123}. However if internal type coercion cannot be reasonably performed without losing information, then it must raise a field error.

Since this coercion behavior is not observable to clients of the GraphQL service, the precise rules of coercion are left to the implementation. The only requirement is that the service must yield values which adhere to the expected Scalar type.

GraphQL scalars are serialized according to the serialization format being used. There may be a most appropriate serialized primitive for each given scalar type, and the service should produce each primitive where appropriate.

See Serialization Format for more detailed information on the serialization of scalars in common JSON and other formats.

Input Coercion

If a GraphQL service expects a scalar type as input to an argument, coercion is observable and the rules must be well defined. If an input value does not match a coercion rule, a request error must be raised (input values are validated before execution begins).

GraphQL has different constant literals to represent integer and floating-point input values, and coercion rules may apply differently depending on which type of input value is encountered. GraphQL may be parameterized by variables, the values of which are often serialized when sent over a transport like HTTP. Since some common serializations (ex. JSON) do not discriminate between integer and floating-point values, they are interpreted as an integer input value if they have an empty fractional part (ex. 1.0) and otherwise as floating-point input value.

For all types below, with the exception of Non-Null, if the explicit value {null} is provided, then the result of input coercion is {null}.

Int

The Int scalar type represents a signed 32-bit numeric non-fractional value. Response formats that support a 32-bit integer or a number type should use that type to represent this scalar.

Result Coercion

Fields returning the type {Int} expect to encounter 32-bit integer internal values.

GraphQL services may coerce non-integer internal values to integers when reasonable without losing information, otherwise they must raise a field error. Examples of this may include returning 1 for the floating-point number 1.0, or returning 123 for the string "123". In scenarios where coercion may lose data, raising a field error is more appropriate. For example, a floating-point number 1.2 should raise a field error instead of being truncated to 1.

If the integer internal value represents a value less than -2³¹ or greater than or equal to 2³¹, a field error should be raised.

Input Coercion

When expected as an input type, only integer input values are accepted. All other input values, including strings with numeric content, must raise a request error indicating an incorrect type. If the integer input value represents a value less than -2³¹ or greater than or equal to 2³¹, a request error should be raised.

Note: Numeric integer values larger than 32-bit should either use String or a custom-defined Scalar type, as not all platforms and transports support encoding integer numbers larger than 32-bit.

Float

The Float scalar type represents signed double-precision finite values as specified by IEEE 754. Response formats that support an appropriate double-precision number type should use that type to represent this scalar.

Result Coercion

Fields returning the type {Float} expect to encounter double-precision floating-point internal values.

GraphQL services may coerce non-floating-point internal values to {Float} when reasonable without losing information, otherwise they must raise a field error. Examples of this may include returning 1.0 for the integer number 1, or 123.0 for the string "123".

Non-finite floating-point internal values ({NaN} and {Infinity}) cannot be coerced to {Float} and must raise a field error.

Input Coercion

When expected as an input type, both integer and float input values are accepted. Integer input values are coerced to Float by adding an empty fractional part, for example 1.0 for the integer input value 1. All other input values, including strings with numeric content, must raise a request error indicating an incorrect type. If the input value otherwise represents a value not representable by finite IEEE 754 (e.g. {NaN}, {Infinity}, or a value outside the available precision), a request error must be raised.

String

The String scalar type represents textual data, represented as UTF-8 character sequences. The String type is most often used by GraphQL to represent free-form human-readable text. All response formats must support string representations, and that representation must be used here.

Result Coercion

Fields returning the type {String} expect to encounter UTF-8 string internal values.

GraphQL services may coerce non-string raw values to {String} when reasonable without losing information, otherwise they must raise a field error. Examples of this may include returning the string "true" for a boolean true value, or the string "1" for the integer 1.

Input Coercion

When expected as an input type, only valid UTF-8 string input values are accepted. All other input values must raise a request error indicating an incorrect type.

Boolean

The Boolean scalar type represents true or false. Response formats should use a built-in boolean type if supported; otherwise, they should use their representation of the integers 1 and 0.

Result Coercion

Fields returning the type {Boolean} expect to encounter boolean internal values.

GraphQL services may coerce non-boolean raw values to {Boolean} when reasonable without losing information, otherwise they must raise a field error. Examples of this may include returning true for non-zero numbers.

Input Coercion

When expected as an input type, only boolean input values are accepted. All other input values must raise a request error indicating an incorrect type.

ID

The ID scalar type represents a unique identifier, often used to refetch an object or as the key for a cache. The ID type is serialized in the same way as a {String}; however, it is not intended to be human-readable. While it is often numeric, it should always serialize as a {String}.

Result Coercion

GraphQL is agnostic to ID format, and serializes to string to ensure consistency across many formats ID could represent, from small auto-increment numbers, to large 128-bit random numbers, to base64 encoded values, or string values of a format like GUID.

GraphQL services should coerce as appropriate given the ID formats they expect. When coercion is not possible they must raise a field error.

Input Coercion

When expected as an input type, any string (such as "4") or integer (such as 4 or -4) input value should be coerced to ID as appropriate for the ID formats a given GraphQL service expects. Any other input value, including float input values (such as 4.0), must raise a request error indicating an incorrect type.

Scalar Extensions

ScalarTypeExtension :

• extend scalar Name Directives[Const]

Scalar type extensions are used to represent a scalar type which has been extended from some original scalar type. For example, this might be used by a GraphQL tool or service which adds directives to an existing scalar.

Type Validation

Scalar type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be a Scalar type.
2. Any non-repeatable directives provided must not already apply to the original Scalar type.

Objects

ObjectTypeDefinition :

• Description? type Name ImplementsInterfaces? Directives[Const]? FieldsDefinition
• Description? type Name ImplementsInterfaces? Directives[Const]? [lookahead != {]

ImplementsInterfaces :

• ImplementsInterfaces & NamedType
• implements &? NamedType

FieldsDefinition : { FieldDefinition+ }

FieldDefinition : Description? Name ArgumentsDefinition? : Type Directives[Const]?

GraphQL operations are hierarchical and composed, describing a tree of information. While Scalar types describe the leaf values of these hierarchical operations, Objects describe the intermediate levels.

GraphQL Objects represent a list of named fields, each of which yield a value of a specific type. Object values should be serialized as ordered maps, where the selected field names (or aliases) are the keys and the result of evaluating the field is the value, ordered by the order in which they appear in the selection set.

All fields defined within an Object type must not have a name which begins with {"__"} (two underscores), as this is used exclusively by GraphQL's introspection system.

For example, a type Person could be described as:

type Person {
  name: String
  age: Int
  picture: Url
}

Where name is a field that will yield a {String} value, and age is a field that will yield an {Int} value, and picture is a field that will yield a Url value.

A query of an object value must select at least one field. This selection of fields will yield an ordered map containing exactly the subset of the object queried, which should be represented in the order in which they were queried. Only fields that are declared on the object type may validly be queried on that object.

For example, selecting all the fields of Person:

{
  name
  age
  picture
}

Would yield the object:

{
  "name": "Mark Zuckerberg",
  "age": 30,
  "picture": "http://some.cdn/picture.jpg"
}

While selecting a subset of fields:

{
  age
  name
}

Must only yield exactly that subset:

{
  "age": 30,
  "name": "Mark Zuckerberg"
}

A field of an Object type may be a Scalar, Enum, another Object type, an Interface, or a Union. Additionally, it may be any wrapping type whose underlying base type is one of those five.

For example, the Person type might include a relationship:

type Person {
  name: String
  age: Int
  picture: Url
  relationship: Person
}

Valid operations must supply a nested field set for any field that returns an object, so this operation is not valid:

{
  name
  relationship
}

However, this example is valid:

{
  name
  relationship {
    name
  }
}

And will yield the subset of each object type queried:

{
  "name": "Mark Zuckerberg",
  "relationship": {
    "name": "Priscilla Chan"
  }
}

Field Ordering

When querying an Object, the resulting mapping of fields are conceptually ordered in the same order in which they were encountered during execution, excluding fragments for which the type does not apply and fields or fragments that are skipped via @skip or @include directives. This ordering is correctly produced when using the {CollectFields()} algorithm.

Response serialization formats capable of representing ordered maps should maintain this ordering. Serialization formats which can only represent unordered maps (such as JSON) should retain this order textually. That is, if two fields {foo, bar} were queried in that order, the resulting JSON serialization should contain {"foo": "...", "bar": "..."} in the same order.

Producing a response where fields are represented in the same order in which they appear in the request improves human readability during debugging and enables more efficient parsing of responses if the order of properties can be anticipated.

If a fragment is spread before other fields, the fields that fragment specifies occur in the response before the following fields.

{
  foo
  ...Frag
  qux
}

fragment Frag on Query {
  bar
  baz
}

Produces the ordered result:

{
  "foo": 1,
  "bar": 2,
  "baz": 3,
  "qux": 4
}

If a field is queried multiple times in a selection, it is ordered by the first time it is encountered. However fragments for which the type does not apply does not affect ordering.

{
  foo
  ...Ignored
  ...Matching
  bar
}

fragment Ignored on UnknownType {
  qux
  baz
}

fragment Matching on Query {
  bar
  qux
  foo
}

Produces the ordered result:

{
  "foo": 1,
  "bar": 2,
  "qux": 3
}

Also, if directives result in fields being excluded, they are not considered in the ordering of fields.

{
  foo @skip(if: true)
  bar
  foo
}

Produces the ordered result:

{
  "bar": 1,
  "foo": 2
}

Result Coercion

Determining the result of coercing an object is the heart of the GraphQL executor, so this is covered in that section of the spec.

Input Coercion

Objects are never valid inputs.

Type Validation

Object types have the potential to be invalid if incorrectly defined. This set of rules must be adhered to by every Object type in a GraphQL schema.

1. An Object type must define one or more fields.
2. For each field of an Object type:
   1. The field must have a unique name within that Object type; no two fields may share the same name.
   2. The field must not have a name which begins with the characters {"__"} (two underscores).
   3. The field must return a type where {IsOutputType(fieldType)} returns {true}.
   4. For each argument of the field:
      1. The argument must not have a name which begins with the characters {"__"} (two underscores).
      2. The argument must accept a type where {IsInputType(argumentType)} returns {true}.
3. An object type may declare that it implements one or more unique interfaces.
4. An object type must be a super-set of all interfaces it implements:
   1. Let this object type be {objectType}.
   2. For each interface declared implemented as {interfaceType}, {IsValidImplementation(objectType, interfaceType)} must be {true}.

IsValidImplementation(type, implementedType):

1. If {implementedType} declares it implements any interfaces, {type} must also declare it implements those interfaces.
2. {type} must include a field of the same name for every field defined in {implementedType}.
   1. Let {field} be that named field on {type}.
   2. Let {implementedField} be that named field on {implementedType}.
   3. {field} must include an argument of the same name for every argument defined in {implementedField}.
      1. That named argument on {field} must accept the same type (invariant) as that named argument on {implementedField}.
   4. {field} may include additional arguments not defined in {implementedField}, but any additional argument must not be required, e.g. must not be of a non-nullable type.
   5. {field} must return a type which is equal to or a sub-type of (covariant) the return type of {implementedField} field's return type:
      1. Let {fieldType} be the return type of {field}.
      2. Let {implementedFieldType} be the return type of {implementedField}.
      3. {IsValidImplementationFieldType(fieldType, implementedFieldType)} must be {true}.

IsValidImplementationFieldType(fieldType, implementedFieldType):

1. If {fieldType} is a Non-Null type:
   1. Let {nullableType} be the unwrapped nullable type of {fieldType}.
   2. Let {implementedNullableType} be the unwrapped nullable type of {implementedFieldType} if it is a Non-Null type, otherwise let it be {implementedFieldType} directly.
   3. Return {IsValidImplementationFieldType(nullableType, implementedNullableType)}.
2. If {fieldType} is a List type and {implementedFieldType} is also a List type:
   1. Let {itemType} be the unwrapped item type of {fieldType}.
   2. Let {implementedItemType} be the unwrapped item type of {implementedFieldType}.
   3. Return {IsValidImplementationFieldType(itemType, implementedItemType)}.
3. If {fieldType} is the same type as {implementedFieldType} then return {true}.
4. If {fieldType} is an Object type and {implementedFieldType} is a Union type and {fieldType} is a possible type of {implementedFieldType} then return {true}.
5. If {fieldType} is an Object or Interface type and {implementedFieldType} is an Interface type and {fieldType} declares it implements {implementedFieldType} then return {true}.
6. Otherwise return {false}.

Field Arguments

ArgumentsDefinition : ( InputValueDefinition+ )

InputValueDefinition : Description? Name : Type DefaultValue? Directives[Const]?

Object fields are conceptually functions which yield values. Occasionally object fields can accept arguments to further specify the return value. Object field arguments are defined as a list of all possible argument names and their expected input types.

All arguments defined within a field must not have a name which begins with {"__"} (two underscores), as this is used exclusively by GraphQL's introspection system.

For example, a Person type with a picture field could accept an argument to determine what size of an image to return.

type Person {
  name: String
  picture(size: Int): Url
}

Operations can optionally specify arguments to their fields to provide these arguments.

This example operation:

{
  name
  picture(size: 600)
}

May return the result:

{
  "name": "Mark Zuckerberg",
  "picture": "http://some.cdn/picture_600.jpg"
}

The type of an object field argument must be an input type (any type except an Object, Interface, or Union type).

Field Deprecation

Fields in an object may be marked as deprecated as deemed necessary by the application. It is still legal to include these fields in a selection set (to ensure existing clients are not broken by the change), but the fields should be appropriately treated in documentation and tooling.

When using the type system definition language, @deprecated directives are used to indicate that a field is deprecated:

type ExampleType {
  oldField: String @deprecated
}

Object Extensions

ObjectTypeExtension :

• extend type Name ImplementsInterfaces? Directives[Const]? FieldsDefinition
• extend type Name ImplementsInterfaces? Directives[Const] [lookahead != {]
• extend type Name ImplementsInterfaces [lookahead != {]

Object type extensions are used to represent a type which has been extended from some original type. For example, this might be used to represent local data, or by a GraphQL service which is itself an extension of another GraphQL service.

In this example, a local data field is added to a Story type:

extend type Story {
  isHiddenLocally: Boolean
}

Object type extensions may choose not to add additional fields, instead only adding interfaces or directives.

In this example, a directive is added to a User type without adding fields:

extend type User @addedDirective

Type Validation

Object type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be an Object type.
2. The fields of an Object type extension must have unique names; no two fields may share the same name.
3. Any fields of an Object type extension must not be already defined on the original Object type.
4. Any non-repeatable directives provided must not already apply to the original Object type.
5. Any interfaces provided must not be already implemented by the original Object type.
6. The resulting extended object type must be a super-set of all interfaces it implements.

Interfaces

InterfaceTypeDefinition :

• Description? interface Name ImplementsInterfaces? Directives[Const]? FieldsDefinition
• Description? interface Name ImplementsInterfaces? Directives[Const]? [lookahead != {]

GraphQL interfaces represent a list of named fields and their arguments. GraphQL objects and interfaces can then implement these interfaces which requires that the implementing type will define all fields defined by those interfaces.

Fields on a GraphQL interface have the same rules as fields on a GraphQL object; their type can be Scalar, Object, Enum, Interface, or Union, or any wrapping type whose base type is one of those five.

For example, an interface NamedEntity may describe a required field and types such as Person or Business may then implement this interface to guarantee this field will always exist.

Types may also implement multiple interfaces. For example, Business implements both the NamedEntity and ValuedEntity interfaces in the example below.

interface NamedEntity {
  name: String
}

interface ValuedEntity {
  value: Int
}

type Person implements NamedEntity {
  name: String
  age: Int
}

type Business implements NamedEntity & ValuedEntity {
  name: String
  value: Int
  employeeCount: Int
}

Fields which yield an interface are useful when one of many Object types are expected, but some fields should be guaranteed.

To continue the example, a Contact might refer to NamedEntity.

type Contact {
  entity: NamedEntity
  phoneNumber: String
  address: String
}

This allows us to write a selection set for a Contact that can select the common fields.

{
  entity {
    name
  }
  phoneNumber
}

When selecting fields on an interface type, only those fields declared on the interface may be queried. In the above example, entity returns a NamedEntity, and name is defined on NamedEntity, so it is valid. However, the following would not be a valid selection set against Contact:

{
  entity {
    name
    age
  }
  phoneNumber
}

because entity refers to a NamedEntity, and age is not defined on that interface. Querying for age is only valid when the result of entity is a Person; this can be expressed using a fragment or an inline fragment:

{
  entity {
    name
    ... on Person {
      age
    }
  }
  phoneNumber
}

Interfaces Implementing Interfaces

When defining an interface that implements another interface, the implementing interface must define each field that is specified by the implemented interface. For example, the interface Resource must define the field id to implement the Node interface:

interface Node {
  id: ID!
}

interface Resource implements Node {
  id: ID!
  url: String
}

Transitively implemented interfaces (interfaces implemented by the interface that is being implemented) must also be defined on an implementing type or interface. For example, Image cannot implement Resource without also implementing Node:

interface Node {
  id: ID!
}

interface Resource implements Node {
  id: ID!
  url: String
}

interface Image implements Resource & Node {
  id: ID!
  url: String
  thumbnail: String
}

Interface definitions must not contain cyclic references nor implement themselves. This example is invalid because Node and Named implement themselves and each other:

interface Node implements Named & Node {
  id: ID!
  name: String
}

interface Named implements Node & Named {
  id: ID!
  name: String
}

Result Coercion

The interface type should have some way of determining which object a given result corresponds to. Once it has done so, the result coercion of the interface is the same as the result coercion of the object.

Input Coercion

Interfaces are never valid inputs.

Type Validation

Interface types have the potential to be invalid if incorrectly defined.

1. An Interface type must define one or more fields.
2. For each field of an Interface type:
   1. The field must have a unique name within that Interface type; no two fields may share the same name.
   2. The field must not have a name which begins with the characters {"__"} (two underscores).
   3. The field must return a type where {IsOutputType(fieldType)} returns {true}.
   4. For each argument of the field:
      1. The argument must not have a name which begins with the characters {"__"} (two underscores).
      2. The argument must accept a type where {IsInputType(argumentType)} returns {true}.
3. An interface type may declare that it implements one or more unique interfaces, but may not implement itself.
4. An interface type must be a super-set of all interfaces it implements:
   1. Let this interface type be {implementingType}.
   2. For each interface declared implemented as {implementedType}, {IsValidImplementation(implementingType, implementedType)} must be {true}.

Interface Extensions

InterfaceTypeExtension :

• extend interface Name ImplementsInterfaces? Directives[Const]? FieldsDefinition
• extend interface Name ImplementsInterfaces? Directives[Const] [lookahead != {]
• extend interface Name ImplementsInterfaces [lookahead != {]

Interface type extensions are used to represent an interface which has been extended from some original interface. For example, this might be used to represent common local data on many types, or by a GraphQL service which is itself an extension of another GraphQL service.

In this example, an extended data field is added to a NamedEntity type along with the types which implement it:

extend interface NamedEntity {
  nickname: String
}

extend type Person {
  nickname: String
}

extend type Business {
  nickname: String
}

Interface type extensions may choose not to add additional fields, instead only adding directives.

In this example, a directive is added to a NamedEntity type without adding fields:

extend interface NamedEntity @addedDirective

Type Validation

Interface type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be an Interface type.
2. The fields of an Interface type extension must have unique names; no two fields may share the same name.
3. Any fields of an Interface type extension must not be already defined on the original Interface type.
4. Any Object or Interface type which implemented the original Interface type must also be a super-set of the fields of the Interface type extension (which may be due to Object type extension).
5. Any non-repeatable directives provided must not already apply to the original Interface type.
6. The resulting extended Interface type must be a super-set of all Interfaces it implements.

Unions

UnionTypeDefinition : Description? union Name Directives[Const]? UnionMemberTypes?

UnionMemberTypes :

• UnionMemberTypes | NamedType
• = |? NamedType

GraphQL Unions represent an object that could be one of a list of GraphQL Object types, but provides for no guaranteed fields between those types. They also differ from interfaces in that Object types declare what interfaces they implement, but are not aware of what unions contain them.

With interfaces and objects, only those fields defined on the type can be queried directly; to query other fields on an interface, typed fragments must be used. This is the same as for unions, but unions do not define any fields, so no fields may be queried on this type without the use of type refining fragments or inline fragments (with the exception of the meta-field {__typename}).

For example, we might define the following types:

union SearchResult = Photo | Person

type Person {
  name: String
  age: Int
}

type Photo {
  height: Int
  width: Int
}

type SearchQuery {
  firstSearchResult: SearchResult
}

In this example, a query operation wants the name if the result was a Person, and the height if it was a photo. However because a union itself defines no fields, this could be ambiguous and is invalid.

{
  firstSearchResult {
    name
    height
  }
}

A valid operation includes typed fragments (in this example, inline fragments):

{
  firstSearchResult {
    ... on Person {
      name
    }
    ... on Photo {
      height
    }
  }
}

Union members may be defined with an optional leading | character to aid formatting when representing a longer list of possible types:

union SearchResult =
  | Photo
  | Person

Result Coercion

The union type should have some way of determining which object a given result corresponds to. Once it has done so, the result coercion of the union is the same as the result coercion of the object.

Input Coercion

Unions are never valid inputs.

Type Validation

Union types have the potential to be invalid if incorrectly defined.

1. A Union type must include one or more unique member types.
2. The member types of a Union type must all be Object base types; Scalar, Interface and Union types must not be member types of a Union. Similarly, wrapping types must not be member types of a Union.

Union Extensions

UnionTypeExtension :

• extend union Name Directives[Const]? UnionMemberTypes
• extend union Name Directives[Const]

Union type extensions are used to represent a union type which has been extended from some original union type. For example, this might be used to represent additional local data, or by a GraphQL service which is itself an extension of another GraphQL service.

Type Validation

Union type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be a Union type.
2. The member types of a Union type extension must all be Object base types; Scalar, Interface and Union types must not be member types of a Union. Similarly, wrapping types must not be member types of a Union.
3. All member types of a Union type extension must be unique.
4. All member types of a Union type extension must not already be a member of the original Union type.
5. Any non-repeatable directives provided must not already apply to the original Union type.

Enums

EnumTypeDefinition :

• Description? enum Name Directives[Const]? EnumValuesDefinition
• Description? enum Name Directives[Const]? [lookahead != {]

EnumValuesDefinition : { EnumValueDefinition+ }

EnumValueDefinition : Description? EnumValue Directives[Const]?

GraphQL Enum types, like Scalar types, also represent leaf values in a GraphQL type system. However Enum types describe the set of possible values.

Enums are not references for a numeric value, but are unique values in their own right. They may serialize as a string: the name of the represented value.

In this example, an Enum type called Direction is defined:

enum Direction {
  NORTH
  EAST
  SOUTH
  WEST
}

Result Coercion

GraphQL services must return one of the defined set of possible values. If a reasonable coercion is not possible they must raise a field error.

Input Coercion

GraphQL has a constant literal to represent enum input values. GraphQL string literals must not be accepted as an enum input and instead raise a request error.

Variable transport serializations which have a different representation for non-string symbolic values (for example, EDN) should only allow such values as enum input values. Otherwise, for most transport serializations that do not, strings may be interpreted as the enum input value with the same name.

Type Validation

Enum types have the potential to be invalid if incorrectly defined.

1. An Enum type must define one or more unique enum values.

Enum Extensions

EnumTypeExtension :

• extend enum Name Directives[Const]? EnumValuesDefinition
• extend enum Name Directives[Const] [lookahead != {]

Enum type extensions are used to represent an enum type which has been extended from some original enum type. For example, this might be used to represent additional local data, or by a GraphQL service which is itself an extension of another GraphQL service.

Type Validation

Enum type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be an Enum type.
2. All values of an Enum type extension must be unique.
3. All values of an Enum type extension must not already be a value of the original Enum.
4. Any non-repeatable directives provided must not already apply to the original Enum type.

Input Objects

InputObjectTypeDefinition :

• Description? input Name Directives[Const]? InputFieldsDefinition
• Description? input Name Directives[Const]? [lookahead != {]

InputFieldsDefinition : { InputValueDefinition+ }

Fields may accept arguments to configure their behavior. These inputs are often scalars or enums, but they sometimes need to represent more complex values.

A GraphQL Input Object defines a set of input fields; the input fields are either scalars, enums, or other input objects. This allows arguments to accept arbitrarily complex structs.

In this example, an Input Object called Point2D describes x and y inputs:

input Point2D {
  x: Float
  y: Float
}

Note: The GraphQL Object type ({ObjectTypeDefinition}) defined above is inappropriate for re-use here, because Object types can contain fields that define arguments or contain references to interfaces and unions, neither of which is appropriate for use as an input argument. For this reason, input objects have a separate type in the system.

Circular References

Input Objects are allowed to reference other Input Objects as field types. A circular reference occurs when an Input Object references itself either directly or through referenced Input Objects.

Circular references are generally allowed, however they may not be defined as an unbroken chain of Non-Null singular fields. Such Input Objects are invalid because there is no way to provide a legal value for them.

This example of a circularly-referenced input type is valid as the field self may be omitted or the value {null}.

input Example {
  self: Example
  value: String
}

This example is also valid as the field self may be an empty List.

input Example {
  self: [Example!]!
  value: String
}

This example of a circularly-referenced input type is invalid as the field self cannot be provided a finite value.

input Example {
  value: String
  self: Example!
}

This example is also invalid, as there is a non-null singular circular reference via the First.second and Second.first fields.

input First {
  second: Second!
  value: String
}

input Second {
  first: First!
  value: String
}

Result Coercion

An input object is never a valid result. Input Object types cannot be the return type of an Object or Interface field.

Input Coercion

The value for an input object should be an input object literal or an unordered map supplied by a variable, otherwise a request error must be raised. In either case, the input object literal or unordered map must not contain any entries with names not defined by a field of this input object type, otherwise a response error must be raised.

The result of coercion is an unordered map with an entry for each field both defined by the input object type and for which a value exists. The resulting map is constructed with the following rules:

• If no value is provided for a defined input object field and that field definition provides a default value, the default value should be used. If no default value is provided and the input object field's type is non-null, an error should be raised. Otherwise, if the field is not required, then no entry is added to the coerced unordered map.

• If the value {null} was provided for an input object field, and the field's type is not a non-null type, an entry in the coerced unordered map is given the value {null}. In other words, there is a semantic difference between the explicitly provided value {null} versus having not provided a value.

• If a literal value is provided for an input object field, an entry in the coerced unordered map is given the result of coercing that value according to the input coercion rules for the type of that field.

• If a variable is provided for an input object field, the runtime value of that variable must be used. If the runtime value is {null} and the field type is non-null, a field error must be raised. If no runtime value is provided, the variable definition's default value should be used. If the variable definition does not provide a default value, the input object field definition's default value should be used.

Following are examples of input coercion for an input object type with a String field a and a required (non-null) Int! field b:

input ExampleInputObject {
  a: String
  b: Int!
}

Literal Value	Variables	Coerced Value
{ a: "abc", b: 123 }	{}	{ a: "abc", b: 123 }
{ a: null, b: 123 }	{}	{ a: null, b: 123 }
{ b: 123 }	{}	{ b: 123 }
{ a: $var, b: 123 }	{ var: null }	{ a: null, b: 123 }
{ a: $var, b: 123 }	{}	{ b: 123 }
{ b: $var }	{ var: 123 }	{ b: 123 }
$var	{ var: { b: 123 } }	{ b: 123 }
"abc123"	{}	Error: Incorrect value
$var	{ var: "abc123" }	Error: Incorrect value
{ a: "abc", b: "123" }	{}	Error: Incorrect value for field {b}
{ a: "abc" }	{}	Error: Missing required field {b}
{ b: $var }	{}	Error: Missing required field {b}.
$var	{ var: { a: "abc" } }	Error: Missing required field {b}
{ a: "abc", b: null }	{}	Error: {b} must be non-null.
{ b: $var }	{ var: null }	Error: {b} must be non-null.
{ b: 123, c: "xyz" }	{}	Error: Unexpected field {c}

Type Validation

1. An Input Object type must define one or more input fields.
2. For each input field of an Input Object type:
   1. The input field must have a unique name within that Input Object type; no two input fields may share the same name.
   2. The input field must not have a name which begins with the characters {"__"} (two underscores).
   3. The input field must accept a type where {IsInputType(inputFieldType)} returns {true}.
3. If an Input Object references itself either directly or through referenced Input Objects, at least one of the fields in the chain of references must be either a nullable or a List type.

Input Object Extensions

InputObjectTypeExtension :

• extend input Name Directives[Const]? InputFieldsDefinition
• extend input Name Directives[Const] [lookahead != {]

Input object type extensions are used to represent an input object type which has been extended from some original input object type. For example, this might be used by a GraphQL service which is itself an extension of another GraphQL service.

Type Validation

Input object type extensions have the potential to be invalid if incorrectly defined.

1. The named type must already be defined and must be a Input Object type.
2. All fields of an Input Object type extension must have unique names.
3. All fields of an Input Object type extension must not already be a field of the original Input Object.
4. Any non-repeatable directives provided must not already apply to the original Input Object type.

List

A GraphQL list is a special collection type which declares the type of each item in the List (referred to as the item type of the list). List values are serialized as ordered lists, where each item in the list is serialized as per the item type.

To denote that a field uses a List type the item type is wrapped in square brackets like this: pets: [Pet]. Nesting lists is allowed: matrix: [[Int]].

Result Coercion

GraphQL services must return an ordered list as the result of a list type. Each item in the list must be the result of a result coercion of the item type. If a reasonable coercion is not possible it must raise a field error. In particular, if a non-list is returned, the coercion should fail, as this indicates a mismatch in expectations between the type system and the implementation.

If a list's item type is nullable, then errors occurring during preparation or coercion of an individual item in the list must result in a the value {null} at that position in the list along with a field error added to the response. If a list's item type is non-null, a field error occurring at an individual item in the list must result in a field error for the entire list.

Note: See Handling Field Errors for more about this behavior.

Input Coercion

When expected as an input, list values are accepted only when each item in the list can be accepted by the list's item type.

If the value passed as an input to a list type is not a list and not the {null} value, then the result of input coercion is a list of size one, where the single item value is the result of input coercion for the list's item type on the provided value (note this may apply recursively for nested lists).

This allows inputs which accept one or many arguments (sometimes referred to as "var args") to declare their input type as a list while for the common case of a single value, a client can just pass that value directly rather than constructing the list.

Following are examples of input coercion with various list types and values:

Expected Type	Provided Value	Coerced Value
[Int]	[1, 2, 3]	[1, 2, 3]
[Int]	[1, "b", true]	Error: Incorrect item value
[Int]	1	[1]
[Int]	null	null
[[Int]]	[[1], [2, 3]]	[[1], [2, 3]]
[[Int]]	[1, 2, 3]	Error: Incorrect item value
[[Int]]	1	[[1]]
[[Int]]	null	null

Non-Null

By default, all types in GraphQL are nullable; the {null} value is a valid response for all of the above types. To declare a type that disallows null, the GraphQL Non-Null type can be used. This type wraps an underlying type, and this type acts identically to that wrapped type, with the exception that {null} is not a valid response for the wrapping type. A trailing exclamation mark is used to denote a field that uses a Non-Null type like this: name: String!.

Nullable vs. Optional

Fields are always optional within the context of a selection set, a field may be omitted and the selection set is still valid. However fields that return Non-Null types will never return the value {null} if queried.

Inputs (such as field arguments), are always optional by default. However a non-null input type is required. In addition to not accepting the value {null}, it also does not accept omission. For the sake of simplicity nullable types are always optional and non-null types are always required.

Result Coercion

In all of the above result coercions, {null} was considered a valid value. To coerce the result of a Non-Null type, the coercion of the wrapped type should be performed. If that result was not {null}, then the result of coercing the Non-Null type is that result. If that result was {null}, then a field error must be raised.

Note: When a field error is raised on a non-null value, the error propagates to the parent field. For more information on this process, see "Errors and Non-Nullability" within the Execution section.

Input Coercion

If an argument or input-object field of a Non-Null type is not provided, is provided with the literal value {null}, or is provided with a variable that was either not provided a value at runtime, or was provided the value {null}, then a request error must be raised.

If the value provided to the Non-Null type is provided with a literal value other than {null}, or a Non-Null variable value, it is coerced using the input coercion for the wrapped type.

A non-null argument cannot be omitted:

{
  fieldWithNonNullArg
}

The value {null} cannot be provided to a non-null argument:

{
  fieldWithNonNullArg(nonNullArg: null)
}

A variable of a nullable type cannot be provided to a non-null argument:

query withNullableVariable($var: String) {
  fieldWithNonNullArg(nonNullArg: $var)
}

Note: The Validation section defines providing a nullable variable type to a non-null input type as invalid.

Type Validation

1. A Non-Null type must not wrap another Non-Null type.

Combining List and Non-Null

The List and Non-Null wrapping types can compose, representing more complex types. The rules for result coercion and input coercion of Lists and Non-Null types apply in a recursive fashion.

For example if the inner item type of a List is Non-Null (e.g. [T!]), then that List may not contain any {null} items. However if the inner type of a Non-Null is a List (e.g. [T]!), then {null} is not accepted however an empty list is accepted.

Following are examples of result coercion with various types and values:

Expected Type	Internal Value	Coerced Result
[Int]	[1, 2, 3]	[1, 2, 3]
[Int]	null	null
[Int]	[1, 2, null]	[1, 2, null]
[Int]	[1, 2, Error]	[1, 2, null] (With logged error)
[Int]!	[1, 2, 3]	[1, 2, 3]
[Int]!	null	Error: Value cannot be null
[Int]!	[1, 2, null]	[1, 2, null]
[Int]!	[1, 2, Error]	[1, 2, null] (With logged error)
[Int!]	[1, 2, 3]	[1, 2, 3]
[Int!]	null	null
[Int!]	[1, 2, null]	null (With logged coercion error)
[Int!]	[1, 2, Error]	null (With logged error)
[Int!]!	[1, 2, 3]	[1, 2, 3]
[Int!]!	null	Error: Value cannot be null
[Int!]!	[1, 2, null]	Error: Item cannot be null
[Int!]!	[1, 2, Error]	Error: Error occurred in item

Directives

DirectiveDefinition : Description? directive @ Name ArgumentsDefinition? repeatable? on DirectiveLocations

DirectiveLocations :

• DirectiveLocations | DirectiveLocation
• |? DirectiveLocation

DirectiveLocation :

• ExecutableDirectiveLocation
• TypeSystemDirectiveLocation

ExecutableDirectiveLocation : one of

• QUERY
• MUTATION
• SUBSCRIPTION
• FIELD
• FRAGMENT_DEFINITION
• FRAGMENT_SPREAD
• INLINE_FRAGMENT
• VARIABLE_DEFINITION

TypeSystemDirectiveLocation : one of

• SCHEMA
• SCALAR
• OBJECT
• FIELD_DEFINITION
• ARGUMENT_DEFINITION
• INTERFACE
• UNION
• ENUM
• ENUM_VALUE
• INPUT_OBJECT
• INPUT_FIELD_DEFINITION

A GraphQL schema describes directives which are used to annotate various parts of a GraphQL document as an indicator that they should be evaluated differently by a validator, executor, or client tool such as a code generator.

GraphQL implementations should provide the @skip and @include directives.

GraphQL implementations that support the type system definition language must provide the @deprecated directive if representing deprecated portions of the schema.

GraphQL implementations that support the type system definition language should provide the @specifiedBy directive if representing custom scalar definitions.

When representing a GraphQL schema using the type system definition language, built in directives (any defined in this specification) should be omitted for brevity. Custom directives in use must be specified.

Custom Directives

GraphQL services and client tooling may provide additional directives beyond those defined in this document. Directives are the preferred way to extend GraphQL with custom or experimental behavior.

Note: When defining a directive, it is recommended to prefix the directive's name to make its scope of usage clear and to prevent a collision with directives which may be specified by future versions of this document (which will not include _ in their name). For example, a custom directive used by Facebook's GraphQL service should be named @fb_auth instead of @auth. This is especially recommended for proposed additions to this specification which can change during the RFC process. For example a work in progress version of @live should be named @rfc_live.

Directives must only be used in the locations they are declared to belong in. In this example, a directive is defined which can be used to annotate a field:

directive @example on FIELD

fragment SomeFragment on SomeType {
  field @example
}

Directive locations may be defined with an optional leading | character to aid formatting when representing a longer list of possible locations:

directive @example on
  | FIELD
  | FRAGMENT_SPREAD
  | INLINE_FRAGMENT

Directives can also be used to annotate the type system definition language as well, which can be a useful tool for supplying additional metadata in order to generate GraphQL execution services, produce client generated runtime code, or many other useful extensions of the GraphQL semantics.

In this example, the directive @example annotates field and argument definitions:

directive @example on FIELD_DEFINITION | ARGUMENT_DEFINITION

type SomeType {
  field(arg: Int @example): String @example
}

A directive may be defined as repeatable by including the "repeatable" keyword. Repeatable directives are often useful when the same directive should be used with different arguments at a single location, especially in cases where additional information needs to be provided to a type or schema extension via a directive:

directive @delegateField(name: String!) repeatable on OBJECT | INTERFACE

type Book @delegateField(name: "pageCount") @delegateField(name: "author") {
  id: ID!
}

extend type Book @delegateField(name: "index")

While defining a directive, it must not reference itself directly or indirectly:

directive @invalidExample(arg: String @invalidExample) on ARGUMENT_DEFINITION

Note: The order in which directives appear may be significant, including repeatable directives.

Validation

1. A directive definition must not contain the use of a directive which references itself directly.
2. A directive definition must not contain the use of a directive which references itself indirectly by referencing a Type or Directive which transitively includes a reference to this directive.
3. The directive must not have a name which begins with the characters {"__"} (two underscores).
4. For each argument of the directive:
   1. The argument must not have a name which begins with the characters {"__"} (two underscores).
   2. The argument must accept a type where {IsInputType(argumentType)} returns {true}.

@skip

directive @skip(if: Boolean!) on FIELD | FRAGMENT_SPREAD | INLINE_FRAGMENT

The @skip directive may be provided for fields, fragment spreads, and inline fragments, and allows for conditional exclusion during execution as described by the if argument.

In this example experimentalField will only be queried if the variable $someTest has the value false.

query myQuery($someTest: Boolean!) {
  experimentalField @skip(if: $someTest)
}

@include

directive @include(if: Boolean!) on FIELD | FRAGMENT_SPREAD | INLINE_FRAGMENT

The @include directive may be provided for fields, fragment spreads, and inline fragments, and allows for conditional inclusion during execution as described by the if argument.

In this example experimentalField will only be queried if the variable $someTest has the value true

query myQuery($someTest: Boolean!) {
  experimentalField @include(if: $someTest)
}

Note: Neither @skip nor @include has precedence over the other. In the case that both the @skip and @include directives are provided on the same field or fragment, it must be queried only if the @skip condition is false and the @include condition is true. Stated conversely, the field or fragment must not be queried if either the @skip condition is true or the @include condition is false.

@deprecated

directive @deprecated(
  reason: String = "No longer supported"
) on FIELD_DEFINITION | ENUM_VALUE

The @deprecated directive is used within the type system definition language to indicate deprecated portions of a GraphQL service's schema, such as deprecated fields on a type or deprecated enum values.

Deprecations include a reason for why it is deprecated, which is formatted using Markdown syntax (as specified by CommonMark).

In this example type definition, oldField is deprecated in favor of using newField.

type ExampleType {
  newField: String
  oldField: String @deprecated(reason: "Use `newField`.")
}

@specifiedBy

directive @specifiedBy(url: String!) on SCALAR

The @specifiedBy directive is used within the type system definition language to provide a URL for specifying the behavior of custom scalar types. The URL should point to a human-readable specification of the data format, serialization, and coercion rules. It must not appear on built-in scalar types.

In this example, a custom scalar type for UUID is defined with a URL pointing to the relevant IETF specification.

scalar UUID @specifiedBy(url: "https://tools.ietf.org/html/rfc4122")