Generated-code reference
Generated-code reference
This page describes the code generated with the grpc plugin to protoc-gen-go
when compiling .proto
files with protoc
.
You can find out how to define a gRPC service in a .proto
file in Service definition.
Thread-safety: note that client-side RPC invocations and server-side RPC handlers are thread-safe and are meant to be run on concurrent goroutines. But also note that for individual streams, incoming and outgoing data is bi-directional but serial; so e.g. individual streams do not support concurrent reads or concurrent writes (but reads are safely concurrent with writes).
Methods on generated server interfaces
On the server side, each service Bar
in the .proto
file results in the function:
func RegisterBarServer(s *grpc.Server, srv BarServer)
The application can define a concrete implementation of the BarServer
interface and register it with a grpc.Server
instance
(before starting the server instance) by using this function.
Unary methods
These methods have the following signature on the generated service interface:
Foo(context.Context, *MsgA) (*MsgB, error)
In this context, MsgA
is the protobuf message sent from the client, and MsgB
is the protobuf message sent back from the server.
Server-streaming methods
These methods have the following signature on the generated service interface:
Foo(*MsgA, <ServiceName>_FooServer) error
In this context, MsgA
is the single request from the client, and the <ServiceName>_FooServer
parameter represents the server-to-client stream
of MsgB
messages.
<ServiceName>_FooServer
has an embedded grpc.ServerStream
and the following interface:
type <ServiceName>_FooServer interface {
Send(*MsgB) error
grpc.ServerStream
}
The server-side handler can send a stream of protobuf messages to the client through this parameter’s Send
method. End-of-stream for the server-to-client
stream is caused by the return
of the handler method.
Client-streaming methods
These methods have the following signature on the generated service interface:
Foo(<ServiceName>_FooServer) error
In this context, <ServiceName>_FooServer
can be used both to read the client-to-server message stream and to send the single server response message.
<ServiceName>_FooServer
has an embedded grpc.ServerStream
and the following interface:
type <ServiceName>_FooServer interface {
SendAndClose(*MsgA) error
Recv() (*MsgB, error)
grpc.ServerStream
}
The server-side handler can repeatedly call Recv
on this parameter in order to receive the full stream of
messages from the client. Recv
returns (nil, io.EOF)
once it has reached the end of the stream.
The single response message from the server is sent by calling the SendAndClose
method on this <ServiceName>_FooServer
parameter.
Note that SendAndClose
must be called once and only once.
Bidi-streaming methods
These methods have the following signature on the generated service interface:
Foo(<ServiceName>_FooServer) error
In this context, <ServiceName>_FooServer
can be used to access both the client-to-server message stream and the server-to-client message stream.
<ServiceName>_FooServer
has an embedded grpc.ServerStream
and the following interface:
type <ServiceName>_FooServer interface {
Send(*MsgA) error
Recv() (*MsgB, error)
grpc.ServerStream
}
The server-side handler can repeatedly call Recv
on this parameter in order to read the client-to-server message stream.
Recv
returns (nil, io.EOF)
once it has reached the end of the client-to-server stream.
The response server-to-client message stream is sent by repeatedly calling the Send
method of on this ServiceName>_FooServer
parameter.
End-of-stream for the server-to-client stream is indicated by the return
of the bidi method handler.
Methods on generated client interfaces
For client side usage, each service Bar
in the .proto
file also results in the function: func BarClient(cc *grpc.ClientConn) BarClient
, which
returns a concrete implementation of the BarClient
interface (this concrete implementation also lives in the generated .pb.go
file).
Unary Methods
These methods have the following signature on the generated client stub:
(ctx context.Context, in *MsgA, opts ...grpc.CallOption) (*MsgB, error)
In this context, MsgA
is the single request from client to server, and MsgB
contains the response sent back from the server.
Server-Streaming methods
These methods have the following signature on the generated client stub:
Foo(ctx context.Context, in *MsgA, opts ...grpc.CallOption) (<ServiceName>_FooClient, error)
In this context, <ServiceName>_FooClient
represents the server-to-client stream
of MsgB
messages.
This stream has an embedded grpc.ClientStream
and the following interface:
type <ServiceName>_FooClient interface {
Recv() (*MsgB, error)
grpc.ClientStream
}
The stream begins when the client calls the Foo
method on the stub.
The client can then repeatedly call the Recv
method on the returned <ServiceName>_FooClient
stream in order to read the server-to-client response stream.
This Recv
method returns (nil, io.EOF)
once the server-to-client stream has been completely read through.
Client-Streaming methods
These methods have the following signature on the generated client stub:
Foo(ctx context.Context, opts ...grpc.CallOption) (<ServiceName>_FooClient, error)
In this context, <ServiceName>_FooClient
represents the client-to-server stream
of MsgA
messages.
<ServiceName>_FooClient
has an embedded grpc.ClientStream
and the following interface:
type <ServiceName>_FooClient interface {
Send(*MsgA) error
CloseAndRecv() (*MsgB, error)
grpc.ClientStream
}
The stream begins when the client calls the Foo
method on the stub.
The client can then repeatedly call the Send
method on the returned <ServiceName>_FooClient
stream in order to send the client-to-server message stream.
The CloseAndRecv
method on this stream must be called once and only once, in order to both close the client-to-server stream
and receive the single response message from the server.
Bidi-Streaming methods
These methods have the following signature on the generated client stub:
Foo(ctx context.Context, opts ...grpc.CallOption) (<ServiceName>_FooClient, error)
In this context, <ServiceName>_FooClient
represents both the client-to-server and server-to-client message streams.
<ServiceName>_FooClient
has an embedded grpc.ClientStream
and the following interface:
type <ServiceName>_FooClient interface {
Send(*MsgA) error
Recv() (*MsgB, error)
grpc.ClientStream
}
The stream begins when the client calls the Foo
method on the stub.
The client can then repeatedly call the Send
method on the returned <SericeName>_FooClient
stream in order to send the
client-to-server message stream. The client can also repeatedly call Recv
on this stream in order to
receive the full server-to-client message stream.
End-of-stream for the server-to-client stream is indicated by a return value of (nil, io.EOF)
on the Recv
method of the stream.
End-of-stream for the client-to-server stream can be indicated from the client by calling the CloseSend
method on the stream.
Packages and Namespaces
When the protoc
compiler is invoked with --go_out=plugins=grpc:
, the proto package
to Go package translation
works the same as when the protoc-gen-go
plugin is used without the grpc
plugin.
So, for example, if foo.proto
declares itself to be in package foo
, then the generated foo.pb.go
file will also be in
the Go package foo
.