# v2.0 Upgrade Guide `ObjectType`, `Interface`, `InputObjectType`, `Scalar` and `Enum` implementations have been quite simplified, without the need to define a explicit Metaclass for each subtype. It also improves the field resolvers, [simplifying the code](#simpler-resolvers) the developer has to write to use them. **Deprecations:** * [`AbstractType`](#abstracttype-deprecated) * [`resolve_only_args`](#resolve_only_args) * [`Mutation.Input`](#mutationinput) **Breaking changes:** * [`Simpler Resolvers`](#simpler-resolvers) * [`Node Connections`](#node-connections) **New Features!** * [`InputObjectType`](#inputobjecttype) * [`Meta as Class arguments`](#meta-ass-class-arguments) (_only available for Python 3_) > The type metaclasses are now deleted as they are no longer necessary. If your code was depending > on this strategy for creating custom attrs, see an [example on how to do it in 2.0](https://github.com/graphql-python/graphene/blob/2.0/graphene/tests/issues/test_425.py). ## Deprecations ### Simpler resolvers All the resolvers in graphene have been simplified. Prior to Graphene `2.0`, all resolvers required four arguments: `(root, args, context, info)`. Now, resolver `args` are passed as keyword arguments to the function, and `context` argument dissapeared in favor of `info.context`. Before: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, args, context, info): my_arg = args.get('my_arg') return ... ``` With 2.0: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, info, my_arg): return ... ``` And, if you need the context in the resolver, you can use `info.context`: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, info, my_arg): context = info.context return ... ``` ### AbstractType deprecated AbstractType is deprecated in graphene 2.0, you can now use normal inheritance instead. Before: ```python class CommonFields(AbstractType): name = String() class Pet(CommonFields, Interface): pass ``` With 2.0: ```python class CommonFields(object): name = String() class Pet(CommonFields, Interface): pass ``` ### resolve\_only\_args `resolve_only_args` is now deprecated as the resolver API has been simplified. Before: ```python class User(ObjectType): name = String() @resolve_only_args def resolve_name(self): return self.name ``` With 2.0: ```python class User(ObjectType): name = String() def resolve_name(self, info): return self.name ``` ### Mutation.Input `Mutation.Input` is now deprecated in favor of using `Mutation.Arguments` (`ClientIDMutation` still uses `Input`). Before: ```python class User(Mutation): class Input: name = String() ``` With 2.0: ```python class User(Mutation): class Arguments: name = String() ``` ## Breaking Changes ### Simpler resolvers All the resolvers in graphene have been simplified. If before resolvers required four arguments `root`, `args`, `context` and `info`, now the `args` are passed as keyword arguments and `context` and `info` will only be passed if the function is annotated with it. Before: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, args, context, info): my_arg = args.get('my_arg') return ... ``` With 2.0: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, my_arg): return ... ``` And, if the resolver want to receive the context: ```python my_field = graphene.String(my_arg=graphene.String()) def resolve_my_field(self, context: graphene.Context, my_arg): return ... ``` which is equivalent in Python 2 to: ```python my_field = graphene.String(my_arg=graphene.String()) @annotate(context=graphene.Context) def resolve_my_field(self, context, my_arg): return ... ``` ### Node Connections Node types no longer have a `Connection` by default. In 2.0 and onwards `Connection`s should be defined explicitly. Before: ```python class User(ObjectType): class Meta: interfaces = [relay.Node] name = String() class Query(ObjectType): user_connection = relay.ConnectionField(User) ``` With 2.0: ```python class User(ObjectType): class Meta: interfaces = [relay.Node] name = String() class UserConnection(relay.Connection): class Meta: node = User class Query(ObjectType): user_connection = relay.ConnectionField(UserConnection) ``` ## Node.get_node The method `get_node` in `ObjectTypes` that have `Node` as interface, changes its API. From `def get_node(cls, id, context, info)` to `def get_node(cls, info, id)`. ```python class MyObject(ObjectType): class Meta: interfaces = (Node, ) @classmethod def get_node(cls, id, context, info): return ... ``` To: ```python class MyObject(ObjectType): class Meta: interfaces = (Node, ) @classmethod def get_node(cls, info, id): return ... ``` ## Mutation.mutate Now only receives (`root`, `info`, `**args`) ## ClientIDMutation.mutate_and_get_payload Now only receives (`root`, `info`, `**input`) ## New Features ### InputObjectType If you are using `InputObjectType`, you now can access its fields via `getattr` (`my_input.myattr`) when resolving, instead of the classic way `my_input['myattr']`. And also use custom defined properties on your input class. Example. Before: ```python class UserInput(InputObjectType): id = ID(required=True) def is_valid_input(input): return input.get('id').startswith('userid_') class Query(ObjectType): user = graphene.Field(User, input=UserInput()) @resolve_only_args def resolve_user(self, input): user_id = input.get('id') if is_valid_input(user_id): return get_user(user_id) ``` With 2.0: ```python class UserInput(InputObjectType): id = ID(required=True) @property def is_valid(self): return self.id.startswith('userid_') class Query(ObjectType): user = graphene.Field(User, input=UserInput()) def resolve_user(self, info, input): if input.is_valid: return get_user(input.id) ``` ### Meta as Class arguments Now you can use the meta options as class arguments (**ONLY PYTHON 3**). Before: ```python class Dog(ObjectType): class Meta: interfaces = [Pet] name = String() ``` With 2.0: ```python class Dog(ObjectType, interfaces=[Pet]): name = String() ``` ### Abstract types Now you can create abstact types super easily, without the need of subclassing the meta. ```python class Base(ObjectType): class Meta: abstract = True id = ID() def resolve_id(self, info): return "{type}_{id}".format( type=self.__class__.__name__, id=self.id ) ``` ### UUID Scalar In Graphene 2.0 there is a new dedicated scalar for UUIDs, `UUID`.