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mirror of https://github.com/FluuxIO/go-xmpp synced 2024-11-11 07:11:03 +00:00
go-xmpp/component.go
2020-03-06 17:52:52 +01:00

231 lines
6.6 KiB
Go

package xmpp
import (
"context"
"crypto/sha1"
"encoding/hex"
"encoding/xml"
"errors"
"fmt"
"gosrc.io/xmpp/stanza"
"io"
)
type ComponentOptions struct {
TransportConfiguration
// =================================
// Component Connection Info
// Domain is the XMPP server subdomain that the component will handle
Domain string
// Secret is the "password" used by the XMPP server to secure component access
Secret string
// =================================
// Component discovery
// Component human readable name, that will be shown in XMPP discovery
Name string
// Typical categories and types: https://xmpp.org/registrar/disco-categories.html
Category string
Type string
// =================================
// Communication with developer client / StreamManager
// Track and broadcast connection state
EventManager
}
// Component implements an XMPP extension allowing to extend XMPP server
// using external components. Component specifications are defined
// in XEP-0114, XEP-0355 and XEP-0356.
type Component struct {
ComponentOptions
router *Router
transport Transport
// read / write
socketProxy io.ReadWriter // TODO
ErrorHandler func(error)
}
func NewComponent(opts ComponentOptions, r *Router, errorHandler func(error)) (*Component, error) {
c := Component{ComponentOptions: opts, router: r, ErrorHandler: errorHandler}
return &c, nil
}
// Connect triggers component connection to XMPP server component port.
// TODO: Failed handshake should be a permanent error
func (c *Component) Connect() error {
return c.Resume()
}
func (c *Component) Resume() error {
var err error
var streamId string
if c.ComponentOptions.TransportConfiguration.Domain == "" {
c.ComponentOptions.TransportConfiguration.Domain = c.ComponentOptions.Domain
}
c.transport, err = NewComponentTransport(c.ComponentOptions.TransportConfiguration)
if err != nil {
c.updateState(StatePermanentError)
return NewConnError(err, true)
}
if streamId, err = c.transport.Connect(); err != nil {
c.updateState(StatePermanentError)
return NewConnError(err, true)
}
// Authentication
if err := c.sendWithWriter(c.transport, []byte(fmt.Sprintf("<handshake>%s</handshake>", c.handshake(streamId)))); err != nil {
c.updateState(StateStreamError)
return NewConnError(errors.New("cannot send handshake "+err.Error()), false)
}
// Check server response for authentication
val, err := stanza.NextPacket(c.transport.GetDecoder())
if err != nil {
c.updateState(StatePermanentError)
return NewConnError(err, true)
}
switch v := val.(type) {
case stanza.StreamError:
c.streamError("conflict", "no auth loop")
return NewConnError(errors.New("handshake failed "+v.Error.Local), true)
case stanza.Handshake:
// Start the receiver go routine
c.updateState(StateSessionEstablished)
go c.recv()
return err // Should be empty at this point
default:
c.updateState(StatePermanentError)
return NewConnError(errors.New("expecting handshake result, got "+v.Name()), true)
}
}
func (c *Component) Disconnect() error {
// TODO: Add a way to wait for stream close acknowledgement from the server for clean disconnect
if c.transport != nil {
return c.transport.Close()
}
// No transport so no connection.
return nil
}
func (c *Component) SetHandler(handler EventHandler) {
c.Handler = handler
}
// Receiver Go routine receiver
func (c *Component) recv() {
for {
val, err := stanza.NextPacket(c.transport.GetDecoder())
if err != nil {
c.updateState(StateDisconnected)
c.ErrorHandler(err)
return
}
// Handle stream errors
switch p := val.(type) {
case stanza.StreamError:
c.router.route(c, val)
c.streamError(p.Error.Local, p.Text)
c.ErrorHandler(errors.New("stream error: " + p.Error.Local))
// We don't return here, because we want to wait for the stream close tag from the server, or timeout.
c.Disconnect()
case stanza.StreamClosePacket:
// TCP messages should arrive in order, so we can expect to get nothing more after this occurs
c.transport.ReceivedStreamClose()
return
}
c.router.route(c, val)
}
}
// Send marshalls XMPP stanza and sends it to the server.
func (c *Component) Send(packet stanza.Packet) error {
transport := c.transport
if transport == nil {
return errors.New("component is not connected")
}
data, err := xml.Marshal(packet)
if err != nil {
return errors.New("cannot marshal packet " + err.Error())
}
if err := c.sendWithWriter(transport, data); err != nil {
return errors.New("cannot send packet " + err.Error())
}
return nil
}
func (c *Component) sendWithWriter(writer io.Writer, packet []byte) error {
var err error
_, err = writer.Write(packet)
return err
}
// SendIQ sends an IQ set or get stanza to the server. If a result is received
// the provided handler function will automatically be called.
//
// The provided context should have a timeout to prevent the client from waiting
// forever for an IQ result. For example:
//
// ctx, _ := context.WithTimeout(context.Background(), 30 * time.Second)
// result := <- client.SendIQ(ctx, iq)
//
func (c *Component) SendIQ(ctx context.Context, iq *stanza.IQ) (chan stanza.IQ, error) {
if iq.Attrs.Type != stanza.IQTypeSet && iq.Attrs.Type != stanza.IQTypeGet {
return nil, ErrCanOnlySendGetOrSetIq
}
if err := c.Send(iq); err != nil {
return nil, err
}
return c.router.NewIQResultRoute(ctx, iq.Attrs.Id), nil
}
// SendRaw sends an XMPP stanza as a string to the server.
// It can be invalid XML or XMPP content. In that case, the server will
// disconnect the component. It is up to the user of this method to
// carefully craft the XML content to produce valid XMPP.
func (c *Component) SendRaw(packet string) error {
transport := c.transport
if transport == nil {
return errors.New("component is not connected")
}
var err error
err = c.sendWithWriter(transport, []byte(packet))
return err
}
// handshake generates an authentication token based on StreamID and shared secret.
func (c *Component) handshake(streamId string) string {
// 1. Concatenate the Stream ID received from the server with the shared secret.
concatStr := streamId + c.Secret
// 2. Hash the concatenated string according to the SHA1 algorithm, i.e., SHA1( concat (sid, password)).
h := sha1.New()
h.Write([]byte(concatStr))
hash := h.Sum(nil)
// 3. Ensure that the hash output is in hexadecimal format, not binary or base64.
// 4. Convert the hash output to all lowercase characters.
encodedStr := hex.EncodeToString(hash)
return encodedStr
}
/*
TODO: Add support for discovery management directly in component
TODO: Support multiple identities on disco info
TODO: Support returning features on disco info
*/