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My team is designing a scalable solution with micro-services architecture and planning to use gRPC as the transport communication between layers. And we've decided to use async grpc model. The design that example(greeter_async_server.cc) provides doesn't seem viable if I scale the number of RPC methods, because then I'll have to create a new class for every RPC method, and create their objects in HandleRpcs() like this. Pastebin (Short example code).

   void HandleRpcs() {
            new CallDataForRPC1(&service_, cq_.get());
            new CallDataForRPC2(&service_, cq_.get());
            new CallDataForRPC3(&service, cq_.get());
            // so on...
    }

It'll be hard-coded, all the flexibility will be lost.

I've around 300-400RPC methods to implement and having 300-400 classes will be cumbersome and inefficient when I'll have to handle more than 100K RPC requests/sec and this solution is a very bad design. I can't bear the overhead of creation of objects this way on every single request. Can somebody kindly provide me a workaround for this. Can async grpc c++ not be simple like its sync companion?

Edit: In favour of making the situation more clear, and for those who might be struggling to grasp the flow of this async example, I'm writing what I've understood so far, please make me correct if wrong somewhere.

In async grpc, every time we have to bind a unique-tag with the completion-queue so that when we poll, the server can give it back to us when the particular RPC will be hit by the client, and we infer from the returned unique-tag about the type of the call.

service_->RequestRPC2(&ctx_, &request_, &responder_, cq_, cq_,this); Here we're using the address of the current object as the unique-tag. This is like registering for our RPC call on the completion queue. Then we poll down in HandleRPCs() to see if the client hits the RPC, if so then cq_->Next(&tag, &OK) will fill the tag. The polling code snippet:

while (true) {
          GPR_ASSERT(cq_->Next(&tag, &ok));
          GPR_ASSERT(ok);
          static_cast<CallData*>(tag)->Proceed();
        }

Since, the unique-tag that we registered into the queue was the address of the CallData object so we're able to call Proceed(). This was fine for one RPC with its logic inside Proceed(). But with more RPCs each time we'll have all of them inside the CallData, then on polling, we'll be calling the only one Proceed() which will contain logic to (say) RPC1(postgres calls), RPC2(mongodb calls), .. so on. This is like writing all my program inside one function. So, to avoid this, I used a GenericCallData class with the virtual void Proceed() and made derived classes out of it, one class per RPC with their own logic inside their own Proceed(). This is a working solution but I want to avoid writing many classes.

Another solution I tried was keeping all RPC-function-logics out of the proceed() and into their own functions and maintaining a global std::map<long, std::function</*some params*/>> . So whenever I register an RPC with unique-tag onto the queue, I store its corresponding logic function (which I'll surely hard code into the statement and bind all the parameters required), then the unique-tag as key. On polling, when I get the &tag I do a lookup in the map for this key and call the corresponding saved function. Now, there's one more hurdle, I'll have to do this inside the function logic:

// pseudo code
void function(reply, responder, context, service)
{
    // register this RPC with another unique tag so to serve new incoming request of the same type on the completion queue
     service_->RequestRPC1(/*params*/, new_unique_id);
    // now again save this new_unique_id and current function into the map, so when tag will be returned we can do lookup
     map.emplace(new_unique_id, function);

    // now you're free to do your logic
    // do your logic
}

You see this, code has spread into another module now, and it's per RPC based. Hope it clears the situation. I thought if somebody could have implemented this type of server in a more easy way.

  • you can always make a template class with function pointer as template argument (or just contructor argument) and store all of them in a vector. Then adding new method is just implementing a method and methods.add(new Template<newMethod>()); – Krzysztof Skowronek Mar 16 '18 at 12:03
  • @KrzysztofSkowronek, I've edited the question with more explanation. And could you plz give a code snippet for the solution that you have proposed? – WhiteSword Mar 16 '18 at 19:16
  • 1
    if I get this correctly, the main hussle is that all those RPC1, RPC2, .. etc classes are exactly the same, with only difference being id // do your logic line. If so, make class RPC with function pointer as constructor argument and call that function in line // do your logic. If my understanding is wrong, I don't think I can help you :( – Krzysztof Skowronek Mar 16 '18 at 19:24
  • It's a valid suggestion and appears cleaner than the hassle I was doing. – WhiteSword Mar 16 '18 at 20:01

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