GraphQL Stitching for Ruby
GraphQL stitching composes a single schema from multiple underlying GraphQL resources, then smartly proxies portions of incoming requests to their respective locations in dependency order and returns the merged results. This allows an entire location graph to be queried through one combined GraphQL surface area.
Supports:
- All operation types: query, mutation, and subscription.
- Merged object and abstract types.
- Shared objects, fields, enums, and inputs across locations.
- Multiple and composite type keys.
- Combining local and remote schemas.
- File uploads via multipart forms.
- Tested with all minor versions of
graphql-ruby
.
NOT Supported:
- Computed fields (ie: federation-style
@requires
). - Defer/stream.
This Ruby implementation is a sibling to GraphQL Tools (JS) and Bramble (Go), and its capabilities fall somewhere in between them. GraphQL stitching is similar in concept to Apollo Federation, though more generic. The opportunity here is for a Ruby application to stitch its local schemas together or onto remote sources without requiring an additional proxy service running in another language. If your goal is to build a purely high-throughput federated reverse proxy, consider not using Ruby.
Getting started
Add to your Gemfile:
gem "graphql-stitching"
Run bundle install
, then require unless running an autoloading framework (Rails, etc):
require "graphql/stitching"
Usage
The Client
component builds a stitched graph wrapped in an executable workflow (with optional query plan caching hooks):
movies_schema = <<~GRAPHQL
type Movie { id: ID! name: String! }
type Query { movie(id: ID!): Movie }
GRAPHQL
showtimes_schema = <<~GRAPHQL
type Showtime { id: ID! time: String! }
type Query { showtime(id: ID!): Showtime }
GRAPHQL
client = GraphQL::Stitching::Client.new(locations: {
movies: {
schema: GraphQL::Schema.from_definition(movies_schema),
executable: GraphQL::Stitching::HttpExecutable.new(url: "http://localhost:3000"),
},
showtimes: {
schema: GraphQL::Schema.from_definition(showtimes_schema),
executable: GraphQL::Stitching::HttpExecutable.new(url: "http://localhost:3001"),
},
my_local: {
schema: MyLocal::GraphQL::Schema,
},
})
result = client.execute(
query: "query FetchFromAll($movieId:ID!, $showtimeId:ID!){
movie(id:$movieId) { name }
showtime(id:$showtimeId): { time }
myLocalField
}",
variables: { "movieId" => "1", "showtimeId" => "2" },
operation_name: "FetchFromAll"
)
Schemas provided in location settings may be class-based schemas with local resolvers (locally-executable schemas), or schemas built from SDL strings (schema definition language parsed using GraphQL::Schema.from_definition
) and mapped to remote locations via executables.
While Client
is sufficient for most usecases, the library offers several discrete components that can be assembled into tailored workflows:
- Composer - merges and validates many schemas into one supergraph.
- Supergraph - manages the combined schema, location routing maps, and executable resources. Can be exported, cached, and rehydrated.
- Request - manages the lifecycle of a stitched GraphQL request.
- HttpExecutable - proxies requests to remotes with multipart file upload support.
Merged types
Object
and Interface
types may exist with different fields in different graph locations, and will get merged together in the combined schema.
To facilitate this merging of types, stitching must know how to cross-reference and fetch each variant of a type from its source location using type resolver queries. For those in an Apollo ecosystem, there's also limited support for merging types though a federation _entities
protocol.
Merged type resolver queries
Types merge through resolver queries identified by a @stitch
directive:
directive @stitch(key: String!, arguments: String) repeatable on FIELD_DEFINITION
This directive (or static configuration) is applied to root queries where a merged type may be accessed in each location, and a key
argument specifies a field needed from other locations to be used as a query argument.
products_schema = <<~GRAPHQL
directive @stitch(key: String!, arguments: String) repeatable on FIELD_DEFINITION
type Product {
id: ID!
name: String!
}
type Query {
product(id: ID!): Product @stitch(key: "id")
}
GRAPHQL
catalog_schema = <<~GRAPHQL
directive @stitch(key: String!, arguments: String) repeatable on FIELD_DEFINITION
type Product {
id: ID!
price: Float!
}
type Query {
products(ids: [ID!]!): [Product]! @stitch(key: "id")
}
GRAPHQL
client = GraphQL::Stitching::Client.new(locations: {
products: {
schema: GraphQL::Schema.from_definition(products_schema),
executable: GraphQL::Stitching::HttpExecutable.new(url: "http://localhost:3001"),
},
catalog: {
schema: GraphQL::Schema.from_definition(catalog_schema),
executable: GraphQL::Stitching::HttpExecutable.new(url: "http://localhost:3002"),
},
})
Focusing on the @stitch
directive usage:
type Product {
id: ID!
name: String!
}
type Query {
product(id: ID!): Product @stitch(key: "id")
}
- The
@stitch
directive is applied to a root query where the merged type may be accessed. The merged type identity is inferred from the field return. - The
key: "id"
parameter indicates that an{ id }
must be selected from prior locations so it may be submitted as an argument to this query. The query argument used to send the key is inferred when possible (more on arguments later).
Each location that provides a unique variant of a type must provide at least one resolver query for the type. The exception to this requirement are outbound-only types and/or foreign key types that contain no exclusive data:
type Product {
id: ID!
}
The above representation of a Product
type contains nothing but a key that is available in other locations. Therefore, this representation will never require an inbound request to fetch it, and its resolver query may be omitted.
List queries
It's okay (even preferable in most circumstances) to provide a list accessor as a resolver query. The only requirement is that both the field argument and return type must be lists, and the query results are expected to be a mapped set with null
holding the position of missing results.
type Query {
products(ids: [ID!]!): [Product]! @stitch(key: "id")
}
# input: ["1", "2", "3"]
# result: [{ id: "1" }, null, { id: "3" }]
See error handling tips for list queries.
Abstract queries
It's okay for resolver queries to be implemented through abstract types. An abstract query will provide access to all of its possible types by default, each of which must implement the key.
interface Node {
id: ID!
}
type Product implements Node {
id: ID!
name: String!
}
type Query {
nodes(ids: [ID!]!): [Node]! @stitch(key: "id")
}
To customize which types an abstract query provides and their respective keys, you may extend the @stitch
directive with a typeName
constraint. This can be repeated to select multiple types.
directive @stitch(key: String!, arguments: String, typeName: String) repeatable on FIELD_DEFINITION
type Product { sku: ID! }
type Order { id: ID! }
type Customer { id: ID! } # << not stitched
union Entity = Product | Order | Customer
type Query {
entity(key: ID!): Entity
@stitch(key: "sku", typeName: "Product")
@stitch(key: "id", typeName: "Order")
}
Argument shapes
Stitching infers which argument to use for queries with a single argument, or when the key name matches its intended argument. For custom mappings, the arguments
option may specify a template of GraphQL arguments that insert key selections:
type Product {
id: ID!
}
type Query {
product(byId: ID, bySku: ID): Product
@stitch(key: "id", arguments: "byId: $.id")
}
Key insertions are prefixed by $
and specify a dot-notation path to any selections made by the resolver key, or __typename
. This syntax allows sending multiple arguments that intermix stitching keys with complex input shapes and other static values:
type Product {
id: ID!
}
union Entity = Product
input EntityKey {
id: ID!
type: String!
}
enum EntitySource {
DATABASE
CACHE
}
type Query {
entities(keys: [EntityKey!]!, source: EntitySource = DATABASE): [Entity]!
@stitch(key: "id", arguments: "keys: { id: $.id, type: $.__typename }, source: CACHE")
}
See resolver arguments for full documentation on shaping input.
Composite type keys
Resolver keys may make composite selections for multiple key fields and/or nested scopes, for example:
interface FieldOwner {
id: ID!
type: String!
}
type CustomField {
owner: FieldOwner!
key: String!
value: String
}
input CustomFieldLookup {
ownerId: ID!
ownerType: String!
key: String!
}
type Query {
customFields(lookups: [CustomFieldLookup!]!): [CustomField]! @stitch(
key: "owner { id type } key",
arguments: "lookups: { ownerId: $.owner.id, ownerType: $.owner.type, key: $.key }"
)
}
Note that composite key selections may not be distributed across locations. The complete selection criteria must be available in each location that provides the key.
Multiple type keys
A type may exist in multiple locations across the graph using different keys, for example:
type Product { id:ID! } # storefronts location
type Product { id:ID! sku:ID! } # products location
type Product { sku:ID! } # catelog location
In the above graph, the storefronts
and catelog
locations have different keys that join through an intermediary. This pattern is perfectly valid and resolvable as long as the intermediary provides resolver queries for each possible key:
type Product {
id: ID!
sku: ID!
}
type Query {
productById(id: ID!): Product @stitch(key: "id")
productBySku(sku: ID!): Product @stitch(key: "sku")
}
The @stitch
directive is also repeatable, allowing a single query to associate with multiple keys:
type Product {
id: ID!
sku: ID!
}
type Query {
product(id: ID, sku: ID): Product @stitch(key: "id") @stitch(key: "sku")
}
Class-based schemas
The @stitch
directive can be added to class-based schemas with a directive class:
class StitchingResolver < GraphQL::Schema::Directive
graphql_name "stitch"
locations FIELD_DEFINITION
repeatable true
argument :key, String, required: true
argument :arguments, String, required: false
end
class Query < GraphQL::Schema::Object
field :product, Product, null: false do
directive StitchingResolver, key: "id"
argument :id, ID, required: true
end
end
The @stitch
directive can be exported from a class-based schema to an SDL string by calling schema.to_definition
.
SDL-based schemas
A clean schema may also have stitching directives applied via static configuration by passing a stitch
array in location settings:
sdl_string = <<~GRAPHQL
type Product {
id: ID!
sku: ID!
}
type Query {
productById(id: ID!): Product
productBySku(sku: ID!): Product
}
GRAPHQL
supergraph = GraphQL::Stitching::Composer.new.perform({
products: {
schema: GraphQL::Schema.from_definition(sdl_string),
executable: ->() { ... },
stitch: [
{ field_name: "productById", key: "id" },
{ field_name: "productBySku", key: "sku", arguments: "mySku: $.sku" },
]
},
# ...
})
Custom directive names
The library is configured to use a @stitch
directive by default. You may customize this by setting a new name during initialization:
GraphQL::Stitching.stitch_directive = "resolver"
Executables
An executable resource performs location-specific GraphQL requests. Executables may be GraphQL::Schema
classes, or any object that responds to .call(request, source, variables)
and returns a raw GraphQL response:
class MyExecutable
def call(request, source, variables)
# process a GraphQL request...
return {
"data" => { ... },
"errors" => [ ... ],
}
end
end
A Supergraph is composed with executable resources provided for each location. Any location that omits the executable
option will use the provided schema
as its default executable:
supergraph = GraphQL::Stitching::Composer.new.perform({
first: {
schema: FirstSchema,
# executable:^^^^^^ delegates to FirstSchema,
},
second: {
schema: SecondSchema,
executable: GraphQL::Stitching::HttpExecutable.new(url: "http://localhost:3001", headers: { ... }),
},
third: {
schema: ThirdSchema,
executable: MyExecutable.new,
},
fourth: {
schema: FourthSchema,
executable: ->(req, query, vars) { ... },
},
})
The GraphQL::Stitching::HttpExecutable
class is provided as a simple executable wrapper around Net::HTTP.post
with file upload support. You should build your own executables to leverage your existing libraries and to add instrumentation. Note that you must manually assign all executables to a Supergraph
when rehydrating it from cache (see docs).
Batching
The stitching executor automatically batches subgraph requests so that only one request is made per location per generation of data. This is done using batched queries that combine all data access for a given a location. For example:
query MyOperation_2($_0_key:[ID!]!, $_1_0_key:ID!, $_1_1_key:ID!, $_1_2_key:ID!) {
_0_result: widgets(ids: $_0_key) { ... } # << 3 Widget
_1_0_result: sprocket(id: $_1_0_key) { ... } # << 1 Sprocket
_1_1_result: sprocket(id: $_1_1_key) { ... } # << 1 Sprocket
_1_2_result: sprocket(id: $_1_2_key) { ... } # << 1 Sprocket
}
Tips:
- List queries (like the
widgets
selection above) are generally preferable as resolver queries because they keep the batched document consistent regardless of set size, and make for smaller documents that parse and validate faster. - Assure that root field resolvers across your subgraph implement batching to anticipate cases like the three
sprocket
selections above.
Otherwise, there's no developer intervention necessary (or generally possible) to improve upon data access. Note that multiple generations of data may still force the executor to return to a previous location for more data.
Concurrency
The Executor component builds atop the Ruby fiber-based implementation of GraphQL::Dataloader
. Non-blocking concurrency requires setting a fiber scheduler via Fiber.set_scheduler
, see graphql-ruby docs. You may also need to build your own remote clients using corresponding HTTP libraries.
Additional topics
- Modeling foreign keys for stitching
- Deploying a stitched schema
- Schema composition merge patterns
- Subscriptions tutorial
- Field selection routing
- Root selection routing
- Stitched errors
- Null results
Examples
This repo includes working examples of stitched schemas running across small Rack servers. Clone the repo, cd
into each example and try running it following its README instructions.
Tests
bundle install
bundle exec rake test [TEST=path/to/test.rb]