protoactor-go

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Published: May 9, 2017 License: Apache-2.0

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Cross platform actors

Introducing cross platform actor support between Go and C#.

Can I use this? The Go implementation is still in beta, there are users using Proto Actor for Go in production already. But be aware that the API might change over time until 1.0.

Sourcecode - Go

This is the Go repository for Proto Actor.

The C# implementation can be found here https://github.com/AsynkronIT/protoactor-dotnet

Design principles:

Minimalistic API - The API should be small and easy to use. Avoid enterprisey JVM like containers and configurations.

Build on existing technologies - There are already a lot of great tech for e.g. networking and clustering, build on those. e.g. gRPC streams for networking, Consul.IO for clustering.

Pass data, not objects - Serialization is an explicit concern, don't try to hide it. Protobuf all the way.

Be fast - Do not trade performance for magic API trickery.

Ultra fast remoting, Proto Actor currently manages to pass over two million messages per second between nodes using only two actors, while still preserving message order! This is six times more the new super advanced UDP based Artery transport for Scala Akka, and 30 times faster than Akka.NET.

:> node1.exe
2016/12/02 14:30:09 50000
2016/12/02 14:30:09 100000
2016/12/02 14:30:09 150000
... snip ...
2016/12/02 14:30:09 900000
2016/12/02 14:30:09 950000
2016/12/02 14:30:10 1000000
2016/12/02 14:30:10 Elapsed 999.9985ms
2016/12/02 14:30:10 Msg per sec 2000003 <--

History

As the creator of the Akka.NET project, I have come to some distinct conclusions while being involved in that project. In Akka.NET we created our own thread pool, our own networking layer, our own serialization support, our own configuration support etc. etc. This was all fun and challenging, it is however now my firm opinion that this is the wrong way to go about things.

If possible, software should be composed, not built, only add code to glue existing pieces together. This yields a much better time to market, and allows us to focus on solving the actual problem at hand, in this case concurrency and distributed programming.

Proto Actor builds on existing technologies, Protobuf for serialization, gRPC streams for network transport. This ensures cross platform compatibility, network protocol version tolerance and battle proven stability.

Another extremely important factor here is business agility and having an exit strategy. By being cross platform, your organization is no longer tied into a specific platform, if you are migrating from .NET to Go, This can be done while still allowing actor based services to communicate between platforms.

Reinvent by not reinventing.


Why Actors

batman

  • Decoupled Concurrency
  • Distributed by default
  • Fault tolerance

For a more indepth description of the differences, see this thread Actors vs. CSP

Building

You need to ensure that your $GOPATH variable is properly set.

Next, install the standard protocol buffer implementation and run the following commands to get all the neccessary tooling:

go get github.com/gogo/protobuf/proto
go get github.com/gogo/protobuf/protoc-gen-gogo
go get github.com/gogo/protobuf/gogoproto
go get github.com/gogo/protobuf/protoc-gen-gofast
go get google.golang.org/grpc
go get github.com/gogo/protobuf/protoc-gen-gogofast
go get github.com/gogo/protobuf/protoc-gen-gogofaster
go get github.com/gogo/protobuf/protoc-gen-gogoslick
go get github.com/Workiva/go-datastructures/queue
go get github.com/emirpasic/gods/stacks/linkedliststack
go get github.com/orcaman/concurrent-map
go get github.com/AsynkronIT/gonet
go get github.com/hashicorp/consul/api
go get github.com/AsynkronIT/goconsole
go get github.com/emirpasic/gods/sets/hashset
go get github.com/serialx/hashring
go get github.com/couchbase/gocb

Finally, run the make tool in the package's root to generate the protobuf definitions and build the packages.

Windows users can use Cygwin to run make: www.cygwin.com

Hello world

type Hello struct{ Who string }
type HelloActor struct{}

func (state *HelloActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case Hello:
        fmt.Printf("Hello %v\n", msg.Who)
    }
}

func main() {
    props := actor.FromInstance(&HelloActor{})
    pid := actor.Spawn(props)
    pid.Tell(Hello{Who: "Roger"})
    console.ReadLine()
}

State machines / SetBehavior, PushBehavior and PopBehavior

type Hello struct{ Who string }
type SetBehaviorActor struct{}

func (state *SetBehaviorActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case Hello:
        fmt.Printf("Hello %v\n", msg.Who)
        context.SetBehavior(state.Other)
    }
}

func (state *SetBehaviorActor) Other(context actor.Context) {
    switch msg := context.Message().(type) {
    case Hello:
        fmt.Printf("%v, ey we are now handling messages in another behavior", msg.Who)
    }
}

func NewSetBehaviorActor() actor.Actor {
    return &SetBehaviorActor{}
}

func main() {
    props := actor.FromProducer(NewSetBehaviorActor)
    pid := actor.Spawn(props)
    pid.Tell(Hello{Who: "Roger"})
    pid.Tell(Hello{Who: "Roger"})
    console.ReadLine()
}

Lifecycle events

Unlike Akka, Proto Actor uses messages for lifecycle events instead of OOP method overrides

type Hello struct{ Who string }
type HelloActor struct{}

func (state *HelloActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case *actor.Started:
        fmt.Println("Started, initialize actor here")
    case *actor.Stopping:
        fmt.Println("Stopping, actor is about shut down")
    case *actor.Stopped:
        fmt.Println("Stopped, actor and its children are stopped")
    case *actor.Restarting:
        fmt.Println("Restarting, actor is about restart")
    case Hello:
        fmt.Printf("Hello %v\n", msg.Who)
    }
}

func main() {
    props := actor.FromInstance(&HelloActor{})
    pid := actor.Spawn(props)
    actor.Tell(pid, Hello{Who: "Roger"})

    //why wait?
    //Stop is a system message and is not processed through the user message mailbox
    //thus, it will be handled _before_ any user message
    //we only do this to show the correct order of events in the console
    time.Sleep(1 * time.Second)
    pid.Stop()

    console.ReadLine()
}

Supervision

Root actors are supervised by the actor.DefaultSupervisionStrategy(), which always issues a actor.RestartDirective for failing actors Child actors are supervised by their parents. Parents can customize their child supervisor strategy using Proto Actor.Props

Example
type Hello struct{ Who string }
type ParentActor struct{}

func (state *ParentActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case Hello:
        props := actor.FromProducer(NewChildActor)
        child := context.Spawn(props)
        child.Tell(msg)
    }
}

func NewParentActor() actor.Actor {
    return &ParentActor{}
}

type ChildActor struct{}

func (state *ChildActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case *actor.Started:
        fmt.Println("Starting, initialize actor here")
    case *actor.Stopping:
        fmt.Println("Stopping, actor is about shut down")
    case *actor.Stopped:
        fmt.Println("Stopped, actor and its children are stopped")
    case *actor.Restarting:
        fmt.Println("Restarting, actor is about restart")
    case Hello:
        fmt.Printf("Hello %v\n", msg.Who)
        panic("Ouch")
    }
}

func NewChildActor() actor.Actor {
    return &ChildActor{}
}

func main() {
    decider := func(child *actor.PID, reason interface{}) actor.Directive {
        fmt.Println("handling failure for child")
        return actor.StopDirective
    }
    supervisor := actor.NewOneForOneStrategy(10, 1000, decider)
    props := actor.
        FromProducer(NewParentActor).
        WithSupervisor(supervisor)

    pid := actor.Spawn(props)
    pid.Tell(Hello{Who: "Roger"})

    console.ReadLine()
}

Networking / Remoting

Proto Actor's networking layer is built as a thin wrapper ontop of gRPC and message serialization is built on Protocol Buffers

Example
Node 1
type MyActor struct{
    count int
}

func (state *MyActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case *messages.Response:
        state.count++
        fmt.Println(state.count)
    }
}

func main() {
    remote.StartServer("localhost:8090")

    pid := actor.SpawnTemplate(&MyActor{})
    message := &messages.Echo{Message: "hej", Sender: pid}

    //this is the remote actor we want to communicate with
    remote := actor.NewPID("localhost:8091", "myactor")
    for i := 0; i < 10; i++ {
        remote.Tell(message)
    }

    console.ReadLine()
}
Node 2
type MyActor struct{}

func (*MyActor) Receive(context actor.Context) {
    switch msg := context.Message().(type) {
    case *messages.Echo:
        msg.Sender.Tell(&messages.Response{
            SomeValue: "result",
        })
    }
}

func main() {
    remote.StartServer("localhost:8091")
    pid := actor.SpawnTemplate(&MyActor{})

    //register a name for our local actor so that it can be discovered remotely
    actor.ProcessRegistry.Register("myactor", pid)
    console.ReadLine()
}
Message Contracts
syntax = "proto3";
package messages;
import "actor.proto"; //we need to import actor.proto, so our messages can include PID's

//this is the message the actor on node 1 will send to the remote actor on node 2
message Echo {
  actor.PID Sender = 1; //this is the PID the remote actor should reply to
  string Message = 2;
}

//this is the message the remote actor should reply with
message Response {
  string SomeValue = 1;
}

For more examples, see the example folder in this repository.

Directories

Path Synopsis
Package actor declares the types used to represent actors in the Actor Model.
Package actor declares the types used to represent actors in the Actor Model.
Package eventstream implements a publisher / subscriber.
Package eventstream implements a publisher / subscriber.
examples
chat/messages
Package messages is a generated protocol buffer package.
Package messages is a generated protocol buffer package.
cluster/shared
Package shared is a generated protocol buffer package.
Package shared is a generated protocol buffer package.
internal
queue/mpsc
Package mpsc provides an efficient implementation of a multi-producer, single-consumer lock-free queue.
Package mpsc provides an efficient implementation of a multi-producer, single-consumer lock-free queue.
Package log provides simple log interfaces
Package log provides simple log interfaces
Package mailbox implements mailbox queues and dispatching
Package mailbox implements mailbox queues and dispatching
protobuf
Package remote provides access to actors across a network or other I/O connection.
Package remote provides access to actors across a network or other I/O connection.

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