rsocket-go is an implementation of the RSocket protocol in Go. It is still under development, APIs are unstable and maybe change at any time until release of v1.0.0. Please do not use it in a production environment.
- Design For Golang
- Thin reactive-streams implementation.
Start an echo server
package main
import (
"github.com/rsocket/rsocket-go"
"github.com/rsocket/rsocket-go/payload"
"github.com/rsocket/rsocket-go/rx"
)
func main() {
// Create and serve
err := rsocket.Receive().
Acceptor(func(setup payload.SetupPayload, sendingSocket rsocket.RSocket) rsocket.RSocket {
// bind responder
return rsocket.NewAbstractSocket(rsocket.RequestResponse(func(msg payload.Payload) rx.Mono {
return rx.JustMono(msg)
}))
}).
Transport("127.0.0.1:7878").
Serve()
panic(err)
}Connect to echo server
package main
import (
"context"
"github.com/rsocket/rsocket-go"
"github.com/rsocket/rsocket-go/payload"
"github.com/rsocket/rsocket-go/rx"
"log"
)
func main() {
// Connect to server
client, err := rsocket.Connect().
SetupPayload(payload.NewString("Hello", "World")).
Transport("127.0.0.1:7878").
Start()
if err != nil {
panic(err)
}
defer client.Close()
// Send request
client.RequestResponse(payload.NewString("你好", "世界")).
DoOnSuccess(func(ctx context.Context, s rx.Subscription, elem payload.Payload) {
log.Println("receive response:", elem)
}).
Subscribe(context.Background())
}NOTICE: more server examples are Here
Mono and Flux are two parts of Reactor API.
Mono completes successfully by emitting an element, or with an error.
Here is a tiny example:
package main
import (
"context"
"github.com/rsocket/rsocket-go/payload"
"github.com/rsocket/rsocket-go/rx"
)
func main() {
// Create a Mono which produce a simple payload.
mono := rx.NewMono(func(sink rx.MonoProducer) {
sink.Success(payload.NewString("foo", "bar"))
})
done := make(chan struct{})
mono.
DoFinally(func(ctx context.Context, st rx.SignalType) {
close(done)
}).
DoOnSuccess(func(ctx context.Context, s rx.Subscription, elem payload.Payload) {
// Handle and consume payload.
// Do something here...
}).
SubscribeOn(rx.ElasticScheduler()).
Subscribe(context.Background())
<-done
}Flux emits 0 to N elements, and then completes (successfully or with an error).
Here is tiny example:
package main
import (
"context"
"github.com/rsocket/rsocket-go/payload"
"github.com/rsocket/rsocket-go/rx"
"time"
)
func main() {
// Create a Flux and produce 10 elements.
flux := rx.NewFlux(func(ctx context.Context, producer rx.Producer) {
for i := 0; i < 10; i++ {
producer.Next(payload.NewString("hello", time.Now().String()))
}
producer.Complete()
})
flux.
DoOnNext(func(ctx context.Context, s rx.Subscription, elem payload.Payload) {
// Handle and consume elements
// Do something here...
}).
Subscribe(context.Background())
}Flux support backpressure.
You can call func Request in Subscription or use LimitRate before subscribe.
flux.Subscribe(
context.Background(),
rx.OnSubscribe(func(ctx context.Context, s rx.Subscription) {
// Init Request 1 element.
s.Request(1)
}),
rx.OnNext(func(ctx context.Context, s rx.Subscription, elem payload.Payload) {
// Consume element, do something...
// Request for next one manually.
s.Request(1)
}),
)- TCP
- Websocket
- HTTP/2
- MetadataPush
- RequestFNF
- RequestResponse
- RequestStream
- RequestChannel (Improve is needed.)
- Tuning
- Keepalive
- Fragmentation
- Thin Reactor
- Cancel
- Error
- Flow Control: RequestN
- Flow Control: Lease
- Load Balance
- Reconnect