#gRPC Basics: C# #
This tutorial provides a basic C# programmer's introduction to working with gRPC. By walking through this example you'll learn how to:
It assumes that you have read the Getting started guide and are familiar with [protocol buffers] (https://developers.google.com/protocol-buffers/docs/overview). Note that the example in this tutorial only uses the proto2 version of the protocol buffers language, as proto3 support for C# is not ready yet (see protobuf C# README).
This isn't a comprehensive guide to using gRPC in C#: more reference documentation is coming soon.
Our example is a simple route mapping application that lets clients get information about features on their route, create a summary of their route, and exchange route information such as traffic updates with the server and other clients.
With gRPC we can define our service once in a .proto file and implement clients and servers in any of gRPC's supported languages, which in turn can be run in environments ranging from servers inside Google to your own tablet - all the complexity of communication between different languages and environments is handled for you by gRPC. We also get all the advantages of working with protocol buffers, including efficient serialization, a simple IDL, and easy interface updating.
The example code for our tutorial is in grpc/grpc-common/csharp/route_guide. To download the example, clone the grpc-common repository by running the following command:
$ git clone https://github.com/google/grpc-common.git
All the files for this tutorial are in the directory grpc-common/csharp/route_guide. Open the solution grpc-common/csharp/route_guide/RouteGuide.sln from Visual Studio (or Monodevelop on Linux).
On Windows, you should not need to do anything besides opening the solution. All the needed dependencies will be restored for you automatically by the Grpc NuGet package upon building the solution.
On Linux (or MacOS), you will first need to install protobuf and gRPC C Core using Linuxbrew (or Homebrew) tool in order to be able to generate the server and client interface code and run the examples. Follow the instructions for Linux or MacOS.
Our first step (as you'll know from Getting started) is to define the gRPC service and the method request and response types using [protocol buffers] (https://developers.google.com/protocol-buffers/docs/overview). You can see the complete .proto file in grpc-common/csharp/route_guide/RouteGuide/protos/route_guide.proto.
To define a service, you specify a named service in your .proto file:
service RouteGuide { ... }
Then you define rpc methods inside your service definition, specifying their request and response types. gRPC lets you define four kinds of service method, all of which are used in the RouteGuide service:
// Obtains the feature at a given position. rpc GetFeature(Point) returns (Feature) {}
stream keyword before the response type.// Obtains the Features available within the given Rectangle. Results are // streamed rather than returned at once (e.g. in a response message with a // repeated field), as the rectangle may cover a large area and contain a // huge number of features. rpc ListFeatures(Rectangle) returns (stream Feature) {}
stream keyword before the request type.// Accepts a stream of Points on a route being traversed, returning a // RouteSummary when traversal is completed. rpc RecordRoute(stream Point) returns (RouteSummary) {}
stream keyword before both the request and the response.// Accepts a stream of RouteNotes sent while a route is being traversed, // while receiving other RouteNotes (e.g. from other users). rpc RouteChat(stream RouteNote) returns (stream RouteNote) {}
Our .proto file also contains protocol buffer message type definitions for all the request and response types used in our service methods - for example, here's the Point message type:
// Points are represented as latitude-longitude pairs in the E7 representation // (degrees multiplied by 10**7 and rounded to the nearest integer). // Latitudes should be in the range +/- 90 degrees and longitude should be in // the range +/- 180 degrees (inclusive). message Point { int32 latitude = 1; int32 longitude = 2; }
Next we need to generate the gRPC client and server interfaces from our .proto service definition. We do this using the protocol buffer compiler protoc with a special gRPC C# plugin.
If you want to run this yourself, make sure you've installed protoc and gRPC C# plugin. The instructions vary based on your OS:
Grpc.Tools NuGet package contains the binaries you will need to generate the code.Once that's done, the following command can be used to generate the C# code.
To generate the code on Windows, we use protoc.exe and grpc_csharp_plugin.exe binaries that are shipped with the Grpc.Tools NuGet package under the tools directory. Normally you would need to add the Grpc.Tools package to the solution yourself, but in this tutorial it has been already done for you. Following command should be run from the csharp/route_guide directory:
> packages\Grpc.Tools.0.5.1\tools\protoc -I RouteGuide/protos --csharp_out=RouteGuide --grpc_out=RouteGuide --plugin=protoc-gen-grpc=packages\Grpc.Tools.0.5.1\tools\grpc_csharp_plugin.exe RouteGuide/protos/route_guide.proto
On Linux/MacOS, we rely on protoc and grpc_csharp_plugin being installed by Linuxbrew/Homebrew. Run this command from the route_guide directory:
$ protoc -I RouteGuide/protos --csharp_out=RouteGuide --grpc_out=RouteGuide --plugin=protoc-gen-grpc=`which grpc_csharp_plugin` RouteGuide/protos/route_guide.proto
Running one of the previous commands regenerates the following files in the RouteGuide directory:
RouteGuide/RouteGuide.cs defines a namespace examplesRouteGuide/RouteGuideGrpc.cs, provides stub and service classesRouteGuide.IRouteGuide to inherit from when defining RouteGuide service implementationsRouteGuide.RouteGuideClient that can be used to access remote RouteGuide instancesFirst let's look at how we create a RouteGuide server. If you're only interested in creating gRPC clients, you can skip this section and go straight to Creating the client (though you might find it interesting anyway!).
There are two parts to making our RouteGuide service do its job:
You can find our example RouteGuide server in grpc-common/csharp/route_guide/RouteGuideServer/RouteGuideImpl.cs. Let's take a closer look at how it works.
As you can see, our server has a RouteGuideImpl class that implements the generated RouteGuide.IRouteGuide:
// RouteGuideImpl provides an implementation of the RouteGuide service. public class RouteGuideImpl : RouteGuide.IRouteGuide
RouteGuideImpl implements all our service methods. Let's look at the simplest type first, GetFeature, which just gets a Point from the client and returns the corresponding feature information from its database in a Feature.
public Task<Feature> GetFeature(Grpc.Core.ServerCallContext context, Point request) { return Task.FromResult(CheckFeature(request)); }
The method is passed a context for the RPC (which is empty in the alpha release), the client's Point protocol buffer request, and returns a Feature protocol buffer. In the method we create the Feature with the appropriate information, and then return it. To allow asynchronous implementation, the method returns Task<Feature> rather than just Feature. You are free to perform your computations synchronously and return the result once you've finished, just as we do in the example.
Now let's look at something a bit more complicated - a streaming RPC. ListFeatures is a server-side streaming RPC, so we need to send back multiple Feature protocol buffers to our client.
// in RouteGuideImpl public async Task ListFeatures(Grpc.Core.ServerCallContext context, Rectangle request, Grpc.Core.IServerStreamWriter<Feature> responseStream) { int left = Math.Min(request.Lo.Longitude, request.Hi.Longitude); int right = Math.Max(request.Lo.Longitude, request.Hi.Longitude); int top = Math.Max(request.Lo.Latitude, request.Hi.Latitude); int bottom = Math.Min(request.Lo.Latitude, request.Hi.Latitude); foreach (var feature in features) { if (!RouteGuideUtil.Exists(feature)) { continue; } int lat = feature.Location.Latitude; int lon = feature.Location.Longitude; if (lon >= left && lon <= right && lat >= bottom && lat <= top) { await responseStream.WriteAsync(feature); } } }
As you can see, here the request object is a Rectangle in which our client wants to find Features, but instead of returning a simple response we need to write responses to an asynchronous stream IServerStreamWriter using async method WriteAsync.
Similarly, the client-side streaming method RecordRoute uses an IAsyncEnumerator, to read the stream of requests using the async method MoveNext and the Current property.
public async Task<RouteSummary> RecordRoute(Grpc.Core.ServerCallContext context, Grpc.Core.IAsyncStreamReader<Point> requestStream) { int pointCount = 0; int featureCount = 0; int distance = 0; Point previous = null; var stopwatch = new Stopwatch(); stopwatch.Start(); while (await requestStream.MoveNext()) { var point = requestStream.Current; pointCount++; if (RouteGuideUtil.Exists(CheckFeature(point))) { featureCount++; } if (previous != null) { distance += (int) CalcDistance(previous, point); } previous = point; } stopwatch.Stop(); return RouteSummary.CreateBuilder().SetPointCount(pointCount) .SetFeatureCount(featureCount).SetDistance(distance) .SetElapsedTime((int) (stopwatch.ElapsedMilliseconds / 1000)).Build(); }
Finally, let's look at our bidirectional streaming RPC RouteChat.
public async Task RouteChat(Grpc.Core.ServerCallContext context, Grpc.Core.IAsyncStreamReader<RouteNote> requestStream, Grpc.Core.IServerStreamWriter<RouteNote> responseStream) { while (await requestStream.MoveNext()) { var note = requestStream.Current; List<RouteNote> notes = GetOrCreateNotes(note.Location); List<RouteNote> prevNotes; lock (notes) { prevNotes = new List<RouteNote>(notes); } foreach (var prevNote in prevNotes) { await responseStream.WriteAsync(prevNote); } lock (notes) { notes.Add(note); } } }
Here the method receives both requestStream and responseStream arguments. Reading the requests is done the same way as in the client-side streaming method RecordRoute. Writing the responses is done the same way as in the server-side streaming method ListFeatures.
Once we've implemented all our methods, we also need to start up a gRPC server so that clients can actually use our service. The following snippet shows how we do this for our RouteGuide service:
var features = RouteGuideUtil.ParseFeatures(RouteGuideUtil.DefaultFeaturesFile); GrpcEnvironment.Initialize(); Server server = new Server(); server.AddServiceDefinition(RouteGuide.BindService(new RouteGuideImpl(features))); int port = server.AddListeningPort("localhost", 50052); server.Start(); Console.WriteLine("RouteGuide server listening on port " + port); Console.WriteLine("Press any key to stop the server..."); Console.ReadKey(); server.ShutdownAsync().Wait(); GrpcEnvironment.Shutdown();
As you can see, we build and start our server using Grpc.Core.Server class. To do this, we:
Grpc.Core.Server.RouteGuideImpl.AddServiceDefinition method and the generated method RouteGuide.BindService.AddListeningPort method.Start on the server instance to start an RPC server for our service.In this section, we'll look at creating a C# client for our RouteGuide service. You can see our complete example client code in grpc-common/csharp/route_guide/RouteGuideClient/Program.cs.
To call service methods, we first need to create a stub.
First, we need to create a gRPC client channel that will connect to gRPC server. Then, we use the RouteGuide.NewStub method of the RouteGuide class generated from our .proto.
GrpcEnvironment.Initialize(); using (Channel channel = new Channel("127.0.0.1:50052")) { var client = RouteGuide.NewStub(channel); // YOUR CODE GOES HERE } GrpcEnvironment.Shutdown();
Now let's look at how we call our service methods. gRPC C# provides asynchronous versions of each of the supported method types. For convenience, gRPC C# also provides a synchronous method stub, but only for simple (single request/single response) RPCs.
Calling the simple RPC GetFeature in a synchronous way is nearly as straightforward as calling a local method.
Point request = Point.CreateBuilder().SetLatitude(409146138).SetLongitude(-746188906).Build(); Feature feature = client.GetFeature(request);
As you can see, we create and populate a request protocol buffer object (in our case Point), and call the desired method on the client object, passing it the request. If the RPC finishes with success, the response protocol buffer (in our case Feature) will be returned. Otherwise, an exception of type RpcException will be thrown, indicating the status code of the problem.
Alternatively, if you are in async context, you can call an asynchronous version of the method (and use await keyword to await the result):
Point request = Point.CreateBuilder().SetLatitude(409146138).SetLongitude(-746188906).Build(); Feature feature = await client.GetFeatureAsync(request);
Now let's look at our streaming methods. If you've already read Creating the server some of this may look very familiar - streaming RPCs are implemented in a similar way on both sides. The difference with respect to simple call is that the client methods return an instance of a call object, that provides access to request/response streams and/or asynchronous result (depending on the streaming type you are using).
Here's where we call the server-side streaming method ListFeatures, which has property ReponseStream of type IAsyncEnumerator<Feature>
using (var call = client.ListFeatures(request)) { while (await call.ResponseStream.MoveNext()) { Feature feature = call.ResponseStream.Current; Console.WriteLine("Received " + feature.ToString()); } }
The client-side streaming method RecordRoute is similar, except we use the property RequestStream to write the requests one by one using WriteAsync and eventually signal that no more request will be send using CompleteAsync. The method result can be obtained through the property Result.
using (var call = client.RecordRoute()) { foreach (var point in points) { await call.RequestStream.WriteAsync(point); } await call.RequestStream.CompleteAsync(); RouteSummary summary = await call.Result; }
Finally, let's look at our bidirectional streaming RPC RouteChat. In this case, we write the request to RequestStream and receive the responses from ResponseStream. As you can see from the example, the streams are independent of each other.
using (var call = client.RouteChat()) { var responseReaderTask = Task.Run(async () => { while (await call.ResponseStream.MoveNext()) { var note = call.ResponseStream.Current; Console.WriteLine("Received " + note); } }); foreach (RouteNote request in requests) { await call.RequestStream.WriteAsync(request); } await call.RequestStream.CompleteAsync(); await responseReaderTask; }
Build client and server:
Open the solution grpc-common/csharp/route_guide/RouteGuide.sln from Visual Studio (or Monodevelop on Linux) and hit "Build".
Run the server, which will listen on port 50052:
> cd RouteGuideServer/bin/Debug > RouteGuideServer.exe
Run the client (in a different terminal):
> cd RouteGuideClient/bin/Debug > RouteGuideClient.exe
You can also run the server and client directly from Visual Studio.
On Linux or Mac, use mono RouteGuideServer.exe and mono RouteGuideClient.exe to run the server and client.