12 KiB
ws
RFC6455 WebSocket implementation in Go.
Features
- Zero-copy upgrade
- No intermediate allocations during I/O
- Low-level API which allows to build your own logic of packet handling and buffers reuse
- High-level wrappers and helpers around API in
wsutil
package, which allow to start fast without digging the protocol internals
Documentation
Why
Existing WebSocket implementations do not allow users to reuse I/O buffers between connections in clear way. This library aims to export efficient low-level interface for working with the protocol without forcing only one way it could be used.
By the way, if you want get the higher-level tools, you can use wsutil
package.
Status
Library is tagged as v1*
so its API must not be broken during some
improvements or refactoring.
This implementation of RFC6455 passes Autobahn Test Suite and currently has about 78% coverage.
Examples
Example applications using ws
are developed in separate repository
ws-examples.
Usage
The higher-level example of WebSocket echo server:
package main
import (
"net/http"
"github.com/gobwas/ws"
"github.com/gobwas/ws/wsutil"
)
func main() {
http.ListenAndServe(":8080", http.HandlerFunc(func(w http.ResponseWriter, r *http.Request) {
conn, _, _, err := ws.UpgradeHTTP(r, w)
if err != nil {
// handle error
}
go func() {
defer conn.Close()
for {
msg, op, err := wsutil.ReadClientData(conn)
if err != nil {
// handle error
}
err = wsutil.WriteServerMessage(conn, op, msg)
if err != nil {
// handle error
}
}
}()
}))
}
Lower-level, but still high-level example:
import (
"net/http"
"io"
"github.com/gobwas/ws"
"github.com/gobwas/ws/wsutil"
)
func main() {
http.ListenAndServe(":8080", http.HandlerFunc(func(w http.ResponseWriter, r *http.Request) {
conn, _, _, err := ws.UpgradeHTTP(r, w)
if err != nil {
// handle error
}
go func() {
defer conn.Close()
var (
state = ws.StateServerSide
reader = wsutil.NewReader(conn, state)
writer = wsutil.NewWriter(conn, state, ws.OpText)
)
for {
header, err := reader.NextFrame()
if err != nil {
// handle error
}
// Reset writer to write frame with right operation code.
writer.Reset(conn, state, header.OpCode)
if _, err = io.Copy(writer, reader); err != nil {
// handle error
}
if err = writer.Flush(); err != nil {
// handle error
}
}
}()
}))
}
We can apply the same pattern to read and write structured responses through a JSON encoder and decoder.:
...
var (
r = wsutil.NewReader(conn, ws.StateServerSide)
w = wsutil.NewWriter(conn, ws.StateServerSide, ws.OpText)
decoder = json.NewDecoder(r)
encoder = json.NewEncoder(w)
)
for {
hdr, err = r.NextFrame()
if err != nil {
return err
}
if hdr.OpCode == ws.OpClose {
return io.EOF
}
var req Request
if err := decoder.Decode(&req); err != nil {
return err
}
var resp Response
if err := encoder.Encode(&resp); err != nil {
return err
}
if err = w.Flush(); err != nil {
return err
}
}
...
The lower-level example without wsutil
:
package main
import (
"net"
"io"
"github.com/gobwas/ws"
)
func main() {
ln, err := net.Listen("tcp", "localhost:8080")
if err != nil {
log.Fatal(err)
}
for {
conn, err := ln.Accept()
if err != nil {
// handle error
}
_, err = ws.Upgrade(conn)
if err != nil {
// handle error
}
go func() {
defer conn.Close()
for {
header, err := ws.ReadHeader(conn)
if err != nil {
// handle error
}
payload := make([]byte, header.Length)
_, err = io.ReadFull(conn, payload)
if err != nil {
// handle error
}
if header.Masked {
ws.Cipher(payload, header.Mask, 0)
}
// Reset the Masked flag, server frames must not be masked as
// RFC6455 says.
header.Masked = false
if err := ws.WriteHeader(conn, header); err != nil {
// handle error
}
if _, err := conn.Write(payload); err != nil {
// handle error
}
if header.OpCode == ws.OpClose {
return
}
}
}()
}
}
Zero-copy upgrade
Zero-copy upgrade helps to avoid unnecessary allocations and copying while handling HTTP Upgrade request.
Processing of all non-websocket headers is made in place with use of registered user callbacks whose arguments are only valid until callback returns.
The simple example looks like this:
package main
import (
"net"
"log"
"github.com/gobwas/ws"
)
func main() {
ln, err := net.Listen("tcp", "localhost:8080")
if err != nil {
log.Fatal(err)
}
u := ws.Upgrader{
OnHeader: func(key, value []byte) (err error) {
log.Printf("non-websocket header: %q=%q", key, value)
return
},
}
for {
conn, err := ln.Accept()
if err != nil {
// handle error
}
_, err = u.Upgrade(conn)
if err != nil {
// handle error
}
}
}
Usage of ws.Upgrader
here brings ability to control incoming connections on
tcp level and simply not to accept them by some logic.
Zero-copy upgrade is for high-load services which have to control many resources such as connections buffers.
The real life example could be like this:
package main
import (
"fmt"
"io"
"log"
"net"
"net/http"
"runtime"
"github.com/gobwas/httphead"
"github.com/gobwas/ws"
)
func main() {
ln, err := net.Listen("tcp", "localhost:8080")
if err != nil {
// handle error
}
// Prepare handshake header writer from http.Header mapping.
header := ws.HandshakeHeaderHTTP(http.Header{
"X-Go-Version": []string{runtime.Version()},
})
u := ws.Upgrader{
OnHost: func(host []byte) error {
if string(host) == "github.com" {
return nil
}
return ws.RejectConnectionError(
ws.RejectionStatus(403),
ws.RejectionHeader(ws.HandshakeHeaderString(
"X-Want-Host: github.com\r\n",
)),
)
},
OnHeader: func(key, value []byte) error {
if string(key) != "Cookie" {
return nil
}
ok := httphead.ScanCookie(value, func(key, value []byte) bool {
// Check session here or do some other stuff with cookies.
// Maybe copy some values for future use.
return true
})
if ok {
return nil
}
return ws.RejectConnectionError(
ws.RejectionReason("bad cookie"),
ws.RejectionStatus(400),
)
},
OnBeforeUpgrade: func() (ws.HandshakeHeader, error) {
return header, nil
},
}
for {
conn, err := ln.Accept()
if err != nil {
log.Fatal(err)
}
_, err = u.Upgrade(conn)
if err != nil {
log.Printf("upgrade error: %s", err)
}
}
}
Compression
There is a ws/wsflate
package to support Permessage-Deflate Compression
Extension.
It provides minimalistic I/O wrappers to be used in conjunction with any deflate implementation (for example, the standard library's compress/flate).
It is also compatible with wsutil
's reader and writer by providing
wsflate.MessageState
type, which implements wsutil.SendExtension
and
wsutil.RecvExtension
interfaces.
package main
import (
"bytes"
"log"
"net"
"github.com/gobwas/ws"
"github.com/gobwas/ws/wsflate"
)
func main() {
ln, err := net.Listen("tcp", "localhost:8080")
if err != nil {
// handle error
}
e := wsflate.Extension{
// We are using default parameters here since we use
// wsflate.{Compress,Decompress}Frame helpers below in the code.
// This assumes that we use standard compress/flate package as flate
// implementation.
Parameters: wsflate.DefaultParameters,
}
u := ws.Upgrader{
Negotiate: e.Negotiate,
}
for {
conn, err := ln.Accept()
if err != nil {
log.Fatal(err)
}
// Reset extension after previous upgrades.
e.Reset()
_, err = u.Upgrade(conn)
if err != nil {
log.Printf("upgrade error: %s", err)
continue
}
if _, ok := e.Accepted(); !ok {
log.Printf("didn't negotiate compression for %s", conn.RemoteAddr())
conn.Close()
continue
}
go func() {
defer conn.Close()
for {
frame, err := ws.ReadFrame(conn)
if err != nil {
// Handle error.
return
}
frame = ws.UnmaskFrameInPlace(frame)
if wsflate.IsCompressed(frame.Header) {
// Note that even after successful negotiation of
// compression extension, both sides are able to send
// non-compressed messages.
frame, err = wsflate.DecompressFrame(frame)
if err != nil {
// Handle error.
return
}
}
// Do something with frame...
ack := ws.NewTextFrame([]byte("this is an acknowledgement"))
// Compress response unconditionally.
ack, err = wsflate.CompressFrame(ack)
if err != nil {
// Handle error.
return
}
if err = ws.WriteFrame(conn, ack); err != nil {
// Handle error.
return
}
}
}()
}
}
You can use compression with wsutil
package this way:
// Upgrade somehow and negotiate compression to get the conn...
// Initialize flate reader. We are using nil as a source io.Reader because
// we will Reset() it in the message i/o loop below.
fr := wsflate.NewReader(nil, func(r io.Reader) wsflate.Decompressor {
return flate.NewReader(r)
})
// Initialize flate writer. We are using nil as a destination io.Writer
// because we will Reset() it in the message i/o loop below.
fw := wsflate.NewWriter(nil, func(w io.Writer) wsflate.Compressor {
f, _ := flate.NewWriter(w, 9)
return f
})
// Declare compression message state variable.
//
// It has two goals:
// - Allow users to check whether received message is compressed or not.
// - Help wsutil.Reader and wsutil.Writer to set/unset appropriate
// WebSocket header bits while writing next frame to the wire (it
// implements wsutil.RecvExtension and wsutil.SendExtension).
var msg wsflate.MessageState
// Initialize WebSocket reader as previously.
// Please note the use of Reader.Extensions field as well as
// of ws.StateExtended flag.
rd := &wsutil.Reader{
Source: conn,
State: ws.StateServerSide | ws.StateExtended,
Extensions: []wsutil.RecvExtension{
&msg,
},
}
// Initialize WebSocket writer with ws.StateExtended flag as well.
wr := wsutil.NewWriter(conn, ws.StateServerSide|ws.StateExtended, 0)
// Use the message state as wsutil.SendExtension.
wr.SetExtensions(&msg)
for {
h, err := rd.NextFrame()
if err != nil {
// handle error.
}
if h.OpCode.IsControl() {
// handle control frame.
}
if !msg.IsCompressed() {
// handle uncompressed frame (skipped for the sake of example
// simplicity).
}
// Reset the writer to echo same op code.
wr.Reset(h.OpCode)
// Reset both flate reader and writer to start the new round of i/o.
fr.Reset(rd)
fw.Reset(wr)
// Copy whole message from reader to writer decompressing it and
// compressing again.
if _, err := io.Copy(fw, fr); err != nil {
// handle error.
}
// Flush any remaining buffers from flate writer to WebSocket writer.
if err := fw.Close(); err != nil {
// handle error.
}
// Flush the whole WebSocket message to the wire.
if err := wr.Flush(); err != nil {
// handle error.
}
}