GraphQL-Java is a great library, but its syntax is a little bit verbose. This library offers an annotations-based syntax for GraphQL schema definition.
If you would like to use a tool that creates a graphql spring boot server using graphql-java-annotations, you can view the graphql-spring-annotations library.
- Getting Started
- GraphQLAnnotations class
- Annotations Schema Creator
- Defining Objects
- Defining Interfaces
- Defining Unions
- Fields
- Type Extensions
- Type Inference
- Directives
- Relay Support
(Gradle syntax)
dependencies {
compile "io.github.graphql-java:graphql-java-annotations:8.3"
}
(Maven syntax)
<dependency>
<groupId>io.github.graphql-java</groupId>
<artifactId>graphql-java-annotations</artifactId>
<version>8.3</version>
</dependency>
The graphql-java-annotations library is able to create GraphQLType objects out of your Java classes. These GraphQLType objects can be later injected into the graphql-java schema.
graphql-java-annotations also allows you to wire your objects with data fetchers and type resolvers while annotating your fields/types. The result of this process will be a GraphQLCodeRegistry.Builder
object that can be later built and injected to the graphql-java schema.
You can create an instance of the GraphQLAnnotations
class in order to create the GraphQL types.
GraphQLAnnotations graphqlAnnotations = new GraphQLAnnotations();
Using this object, you will be able to create the GraphQL types.
There are few types that can be generated - a GraphQLObjectType
, a GraphQLInterfaceType
and a GraphQLDirective
.
GraphQLObjectType query = graphqlAnnotations.object(Query.class);
GraphQLDirective upperDirective = graphqlAnnotations.directive(UpperDirective.class);
GraphQLInterfaceType myInterface = graphqlAnnotations.generateInterface(MyInterface.class);
Then you can use these types in order to create a graphql-java schema.
But, in order to create a graphql-java schema, you need also the GraphQLCodeRegistry
, which contains all the data fetchers mapped to their fields (and also type resolvers).
You can obtain the code registry this way:
graphqlAnnotations.getContainer().getCodeRegistryBuilder().build();
Using the GraphQLAnnotations
processor object can be a little bit confusing if you wish to use it to create a GraphQL schema.
So we created a util class to help you create your desired GraphQL schema, in a syntax similiar to the graphql-java syntax.
In order to do so you can use the AnnotationsSchemaCreator.Builder
in the following way:
GraphQLSchema schema = AnnotationsSchemaCreator.newAnnotationsSchema()
.query(Query.class) // to create you query object
.mutation(Mutation.class) // to create your mutation object
.subscription(Subscription.class) // to create your subscription object
.directive(UpperDirective.class) // to create a directive
.additionalType(AdditionalType.class) // to create some additional type and add it to the schema
.typeFunction(CustomType.class) // to add a typefunction
.setAlwaysPrettify(true) // to set the global prettifier of field names (removes get/set/is prefixes from names)
.setRelay(customRelay) // to add a custom relay object
.build();
Of course you can use this builder with only some of the properties, but the query class must be provided. note - The GraphQLSchema is a graphql-java type.
Continue reading in order to understand how your java classes should look in order to be provided to the annotations schema creator.
Any regular Java class can be converted to a GraphQL object type. Fields can
be defined with a @GraphQLField
(see more on fields below) annotation:
public class SomeObject {
@GraphQLField
public String field;
}
// ...
GraphQLAnnotations graphQLAnnotations = new GraphQLAnnotations();
GraphQLObjectType object = graphQLAnnotations.object(SomeObject.class);
This is very similar to defining objects, with the addition of type resolver :
@GraphQLTypeResolver(MyTypeResolver.class)
public interface SomeInterface {
@GraphQLField
String field();
}
public class MyTypeResolver implements TypeResolver {
GraphQLObjectType getType(TypeResolutionEnvironment env) { ... }
}
// ...
GraphQLAnnotations graphQLAnnotations = new GraphQLAnnotations();
GraphQLInterfaceType object = graphQLAnnotations.generateInterface(SomeInterface.class);
An instance of the type resolver will be created from the specified class. If a getInstance
method is present on the
class, it will be used instead of the default constructor.
To have a union, you must annotate an interface with @GraphQLUnion
. In the annotation, you must declare all the
possible types of the union, and a type resolver.
If no type resolver is specified, UnionTypeResolver
is used. It follows this algorithm:
The resolver assumes the the DB entity's name is the same as the API entity's name.
If so, it takes the result from the dataFetcher and decides to which
API entity it should be mapped (according to the name).
Example: If you have a Pet
union type, and the dataFetcher returns Dog
, the typeResolver
will check for each API entity if its name is equal to Dog
, and returns if it finds something
@GraphQLUnion(possibleTypes={Dog.class, Cat.class})
public interface Pet {}
and an example with custom TypeResovler
:
@GraphQLUnion(possibleTypes={DogApi.class, Cat.class}, typeResolver = PetTypeResolver.class)
public interface Pet {}
public class PetTypeResolver implements TypeResolver {
@Override
GraphQLObjectType getType(TypeResolutionEnvironment env) {
Object obj = env.getObject();
if(obj instanceof DogDB) {
return (GraphQLObjectType) env.getSchema().getType("DogApi");
}
else {
return (GraphQLObjectType) env.getSchema().getType("Cat");
}
}
}
NOTE: you can have (but not mandatory) a type resolver with constructor that has Class<?>[]
as the first parameter and
ProcessingElementsContainer
as the second. the Class<?>[]
parameter contains the possibleTypes class
and ProcessingElementsContainer
has all sorts of utils (you can check UnionTypeResolver
to see how we use it there)
In addition to specifying a field over a Java class field, a field can be defined over a method:
public class SomeObject {
@GraphQLField
public String field() {
return "field";
}
}
Or a method with arguments:
public class SomeObject {
@GraphQLField
public String field(String value) {
return value;
}
}
Note: You need to use
-parameters
javac option to compile, which makes argument name as the default GraphQL name. Otherwise, you will need to add the@GraphQLName("value")
annotation to specify one.
You can also inject DataFetchingEnvironment
as an argument, at any position:
public class SomeObject {
@GraphQLField
public String field(DataFetchingEnvironment env, String value) {
return value;
}
}
Additionally, @GraphQLName
can be used to override field name. You can use @GraphQLDescription
to set a description.
These can also be used for field parameters:
public String field(@GraphQLName("val") String value) {
return value;
}
In addition, @GraphQLDefaultValue
can be used to set a default value to a parameter. Due to limitations of annotations, the default value has to be provided by a class that implements Supplier<Object>
:
public static class DefaultValue implements Supplier<Object> {
@Override
public Object get() {
return "default";
}
}
@GraphQLField
public String field(@GraphQLDefaultValue(DefaultValue.class) String value) {
return value;
}
The DefaultValue
class can define a getInstance
method that will be called instead of the default constructor.
@GraphQLDeprecate
and Java's @Deprecated
can be used to specify a deprecated
field or method.
You can specify a custom data fetcher for a field with @GraphQLDataFetcher
. The annotation will reference a class name,
which will be used as data fetcher.
An instance of the data fetcher will be created. The args
attribute on the annotation can be used to specify a list of
String arguments to pass to the constructor, allowing to reuse the same class on different fields, with different parameter.
The firstArgIsTargetName
attribute can also be set on @GraphQLDataFetcher
to pass the field name as a single parameter of the constructor.
Assuming you are using @GraphQLDataFetcher
this way:
@GraphQLField
@GraphQLDataFetcher(value = HelloWorldDataFetcher.class, args = { "arg1", "arg2" })
public String getHelloWorld(){
return null;
}
Then the class that extends from DataFetcher.class
will get this args to two supported constructors
Or to a constructor that expecting String array that's way (String[] args
or String... args
) or for a constructor that expecting the same number of args that you send with in the annotation.
You get to choose which implementation you want.
public class HelloWorldDataFetcher implements DataFetcher<String> {
public HelloWorldDataFetcher(String[] args){
// Do something with your args
}
// Note that you need to expect the same number of args as you send with in the annotation args
public HelloWorldDataFetcher(String arg1, String arg2){
// Do something with your args
}
@Override
public String get(DataFetchingEnvironment environment) {
return "something";
}
}
If no argument is needed and a getInstance
method is present, this method will be called instead of the constructor.
Having one single class declaring all fields in a graphQL object type is not always possible, or can lead to huge classes.
Modularizing the schema by defining fields in different classes allows you to split it in smaller chunks of codes.
In IDL, this is usually written by using the extend
keyword on top of a type definition. So you have a type defined like this :
type Human {
id: ID!
name: String!
}
It would be possible to extend it later on by using the following syntax :
extend type Human {
homePlanet: String
}
This is possible when using annotations by registering "extensions" classes, corresponding to extend
clauses, before creating the objects with the GraphQLAnnotationsProcessor.
Extension classes are simple classes, using the same annotations, with an additional @GraphQLTypeExtension
on the class itself. The annotation value is required and will be the class that it actually extends.
So the previous schema could be defined by the following classes :
@GraphQLName("Human")
public class Human {
@GraphQLField
public String name() { }
}
@GraphQLTypeExtension(Human.class)
public class HumanExtension {
@GraphQLField
public String homePlanet() { }
}
Classes marked as "extensions" will actually not define a new type, but rather set new fields on the class it extends when it will be created. All GraphQL annotations can be used on extension classes.
Extensions are registered in GraphQLAnnotations object by using registerTypeExtension
. Note that extensions must be registered before the type itself is requested with getObject()
:
// Register extensions
graphqlAnnotations.registerTypeExtension(HumanExtension.class);
// Create type
GraphQLObjectType type = processor.getObject(Human.class);
As opposed to standard annotated classes mapped to GraphQL types, no instance of the extensions are created by default.
In DataFetcher, the source object will still be an instance of the extended class.
It is however possible to provide a constructor taking the extended class as parameter. This constructor will be used to create an instance of the extension class when a field with the default DataFetcher (without @DataFetcher
) will be queried.
If no such constructor is provided, the field must either be declared as static
or marked as @GraphQLInvokeDetached
. Original source object can be found in the DataFetchingEnvironment
.
@GraphQLTypeExtension(Human.class)
public class HumanExtension {
public HumanExtension(Human human) {
this.human = human;
}
@GraphQLField
public String homePlanet() {
// get value somehow from human object
}
}
By default, standard GraphQL types (String, Integer, Long, Float, Boolean, Enum, List) will be inferred from Java types. Also, it will respect @GraphQLNonNull
with respect to value's nullability
Stream type is also supported and treated as a list.
If you want to register an additional type (for example, UUID), you have to create a new class implementing TypeFunction
for it:
public class UUIDTypeFunction implements TypeFunction {
...
}
And register it with GraphQLAnnotations
:
graphqlAnnotations.registerType(new UUIDTypeFunction())
// or if not using a static version of GraphQLAnnotations:
// new GraphQLAnnotations().registerType(new UUIDTypeFunction())
You can also specify custom type function for any field with @GraphQLType
annotation.
In GraphQL, you can add directives to your schema. Directive is a way of adding some logic to your schema or changing your schema.
For example, we can create a @upper
directive, that if we add it to string fields in our schema, they will be transformed to upper cases (its an example, you need to implement it).
There are multiple ways to declare a directive in your schema using graphql-java-annotations.
This is the most recommended way of creating a directive, because it is very easy to use later in your schema. In order to declare a directive using a java annotation, you first have to create the java annotation, and annotate it with special annotations.
For example, we wish to create a directive that adds suffix to graphql fields.
@GraphQLName("suffix")
@GraphQLDescription("this directive adds suffix to a string type")
@GraphQLDirectiveDefinition(wiring = SuffixWiring.class)
@DirectiveLocations({Introspection.DirectiveLocation.FIELD_DEFINITION, Introspection.DirectiveLocation.INTERFACE})
@Retention(RetentionPolicy.RUNTIME)
@interface Suffix {
@GraphQLName("suffixToAdd")
@GraphQLDescription("the suffix to add to your type")
boolean suffixToAdd() default true;
}
- must be annotated with
@GraphQLDirectiveDefinition
and to supply a wiring class to it (will be explained later) - the name of the directive will be taken from the class name (
Suffix
) or if annotated with@GraphQLName
- from its value - the description is taken from the
@GraphQLDescription
annotation - must be annotated with
@Retention
with aRUNTIME
policy - must be annotated with
@DirectiveLocations
in order to specify where we can put this directive on (for example - field definition, interface)
You can see that we also defined a sufixToAdd
argument for the directive. We can also use @GraphQLName
and @GraphQLDescription
annotations in there.
In order to define a default value for the argument, use the default
keyword like in the example.
After you created the class, you will be able to create the GraphQLDirective
object using the following code:
GraphQLDirective directive = graphqlAnnotations.directive(Suffix.class);
You can also declare an annotation via a method declaration inside some class. For example, we will create a class of directive declarations:
class DirectiveDeclarations{
@GraphQLName("upper")
@GraphQLDescription("upper directive")
@GraphQLDirectiveDefinition(wiring = UpperWiring.class)
@DirectiveLocations({Introspection.DirectiveLocation.FIELD_DEFINITION, Introspection.DirectiveLocation.INTERFACE})
public void upperDirective(@GraphQLName("isActive") @GraphQLDescription("is active") boolean isActive) {
}
@GraphQLName("suffix")
@GraphQLDescription("suffix directive")
@GraphQLDirectiveDefinition(wiring = SuffixWiring.class)
@DirectiveLocations({Introspection.DirectiveLocation.FIELD_DEFINITION, Introspection.DirectiveLocation.INTERFACE})
public void suffixDirective(@GraphQLName("suffix") @GraphQLDescription("the suffix") String suffix) {
}
}
- The methods has to be annotated with the
@GraphQLDirectiveDefinition
annotation, and to be supplied with a wiring class - The methods has to be annotated with the
@DirectiveLocations
annotation - Can be used:
@GraphQLName
and@GraphQLDescription
- also inside method parameters (that will be transformed into arguments of the directive)
Notice that method params cannot have default values - so the directive arguments will not have default values.
In order to create the directives, you need to write:
Set<GraphQLDirective> set = graphqlAnnotations.directives(DirectiveDeclarations.class);
Another way is to declare the directive using a class.
For example:
@GraphQLName("upper")
@GraphQLDescription("upper")
@DirectiveLocations({Introspection.DirectiveLocation.FIELD_DEFINITION, Introspection.DirectiveLocation.INTERFACE})
@GraphQLDirectiveDefinition(wiring = UpperWiring.class)
public static class UpperDirective {
@GraphQLName("isActive")
private boolean isActive = true;
}
The name of the directive will be taken from the @GraphQLName
annotation (if not specified, the name will be the class's name).
The description of the directive will be taken from the @GraphQLDescription
annotation's value.
The valid locations of the directive (locations which the directive can be applied on) will be taken from @DirectiveLocations
.
The arguments of the directive will be taken from the fields defined in the class - notice that you can only use primitive types as arguments of a directive.
For example, we defined an isActive
field - which is boolean, and its default value is true. That's how the argument of the directive will be defined.
You can also use @GraphQLName
and @GraphQLDescription
annotations on the field.
After you created the class, you will be able to create the GraphQLDirective
object using the following code:
GraphQLDirective directive = graphqlAnnotations.directive(UpperDirective.class);
In order to define the wiring logic (what will be executed on top of the graphql type annotated with the directive) we have to create wiring class.
In order to define a wiring functionality, you have to create a Wiring class matching one of your directives. For example:
public class UpperWiring implements AnnotationsDirectiveWiring {
@Override
public GraphQLFieldDefinition onField(AnnotationsWiringEnvironment environment) {
GraphQLFieldDefinition field = (GraphQLFieldDefinition) environment.getElement();
boolean isActive = (boolean) environment.getDirective().getArgument("isActive").getValue();
CodeRegistryUtil.wrapDataFetcher(field, environment, (((dataFetchingEnvironment, value) -> {
if (value instanceof String && isActive) {
return ((String) value).toUpperCase();
}
return value;
})));
return field;
}
}
In this example we wrap the data fetcher of the field in order to make the resolved value upper case.
You can also use the field.transform
method in order to change some of the field's properties.
This class turns your string field to upper case if the directive argument "isActive" is set to true.
Put this class inside the @GraphQLDirectiveDefinition(wiring = UpperWiring.class)
annotation where you declare your directive (see directive declaration section above).
There are 2 ways of using the directives in your graphql types.
This way only works if you declared your directive as a java annotation.
In the example above, we created the @Suffix
annotation as a directive.
So now we can put it on top of our graphql field.
For example:
@GraphQLField
@Suffix(suffixToAdd = " is cool")
public String name(){
return "yarin";
}
Now every time the field will be executed, the suffix " is cool" will be added to it. You can also use directive on field arguments, interfaces, etc.
This way works in the 3 methods of declaring directives, but is less recommended because its more complicated and not so nice.
You can annotate your graphql field with the @GraphQLDirectives
annotation and supply it with the directives to use and the arguments values you want to supply.
For example:
@GraphQLField
@GraphQLDirectives(@Directive(name = "upperCase", argumentsValues = {"true"}))
public String name() {
return "yarin";
}
We now wired the field "name" - so it will turn upper case when calling the field.
The Directive
annotations requires the name of the directive, the wiring class (the UpperWiring
class defined earlier), and the values of the arguments. If an argument has a default value, you don't have to supply a value in the arguments values.
Notice that in any way, the directives are sequential, so the first annotated directive will happen before the second one.
If put both java annotation directive and @GraphQLDirectives
annotation directives, the java annotation directive will be applied first.
You can use @GraphQLRelayMutation
annotation to make mutation adhere to
Relay specification for mutations
You can use @GraphQLConnection
annotation to make a field iterable in adherence to Relay Connection specification.
If a field is annotated with the annotation, the associated dataFetcher must return an instance of PaginatedData
.
The PaginatedData
class holds the result of the connection:
- The data of the page
- Whether or not there is a next page and a previous page
- A method that returns for each entity the encoded cursor of the entity (it returns string)
For you convenience, there is AbstractPaginatedData
that can be extended.
If you want to use you own implementation of connection, that's fine, just give a value to connection().
Please note that if you do so, you also have to specify your own connection validator that implements ConnectionValidator
(and should throw @GraphQLConnectionException
if something is wrong)
NOTE: because PropertyDataFetcher
and FieldDataFetcher
can't handle connection, this annotation cant be used on a field that doesn't have a dataFetcher
By default, GraphQLAnnotations will use the graphql.relay.Relay
class to create the Relay specific schema types (Mutations, Connections, Edges, PageInfo, ...).
It is possible to set a custom implementation of the Relay class with graphqlAnnotations.setRelay
method. The class should inherit from graphql.relay.Relay
and
can redefine methods that create Relay types.
It is also possible to specify for every connection which relay do you want to use, by giving a value to the annotation:
@GraphQLConnection(connectionType = customRelay.class)
. If you do that, please also give values to connectionFetcher
and validator
.
There is also a support for simple paging, without "Nodes" and "Edges". To use it, annotate you connection like that:
@GraphQLConnection(connectionFetcher = SimplePaginatedDataConnectionFetcher.class, connectionType = SimpleRelay.class, validator = SimplePaginatedDataConnectionTypeValidator.class)
and the return type must be of type SimplePaginatedData
.
It has 2 methods:
getTotalCount
- how many elements are there in totalgetData
- get the data
For you convenience, there are two classes that you can use: AbstractSimplePaginatedData
and SimplePaginatedDataImpl
For examples, look at the tests