robocar-steering/vendor/github.com/eclipse/paho.mqtt.golang/net.go

471 lines
18 KiB
Go

/*
* Copyright (c) 2021 IBM Corp and others.
*
* All rights reserved. This program and the accompanying materials
* are made available under the terms of the Eclipse Public License v2.0
* and Eclipse Distribution License v1.0 which accompany this distribution.
*
* The Eclipse Public License is available at
* https://www.eclipse.org/legal/epl-2.0/
* and the Eclipse Distribution License is available at
* http://www.eclipse.org/org/documents/edl-v10.php.
*
* Contributors:
* Seth Hoenig
* Allan Stockdill-Mander
* Mike Robertson
* Matt Brittan
*/
package mqtt
import (
"errors"
"io"
"net"
"reflect"
"strings"
"sync"
"time"
"github.com/eclipse/paho.mqtt.golang/packets"
)
const closedNetConnErrorText = "use of closed network connection" // error string for closed conn (https://golang.org/src/net/error_test.go)
// ConnectMQTT takes a connected net.Conn and performs the initial MQTT handshake. Parameters are:
// conn - Connected net.Conn
// cm - Connect Packet with everything other than the protocol name/version populated (historical reasons)
// protocolVersion - The protocol version to attempt to connect with
//
// Note that, for backward compatibility, ConnectMQTT() suppresses the actual connection error (compare to connectMQTT()).
func ConnectMQTT(conn net.Conn, cm *packets.ConnectPacket, protocolVersion uint) (byte, bool) {
rc, sessionPresent, _ := connectMQTT(conn, cm, protocolVersion)
return rc, sessionPresent
}
func connectMQTT(conn io.ReadWriter, cm *packets.ConnectPacket, protocolVersion uint) (byte, bool, error) {
switch protocolVersion {
case 3:
DEBUG.Println(CLI, "Using MQTT 3.1 protocol")
cm.ProtocolName = "MQIsdp"
cm.ProtocolVersion = 3
case 0x83:
DEBUG.Println(CLI, "Using MQTT 3.1b protocol")
cm.ProtocolName = "MQIsdp"
cm.ProtocolVersion = 0x83
case 0x84:
DEBUG.Println(CLI, "Using MQTT 3.1.1b protocol")
cm.ProtocolName = "MQTT"
cm.ProtocolVersion = 0x84
default:
DEBUG.Println(CLI, "Using MQTT 3.1.1 protocol")
cm.ProtocolName = "MQTT"
cm.ProtocolVersion = 4
}
if err := cm.Write(conn); err != nil {
ERROR.Println(CLI, err)
return packets.ErrNetworkError, false, err
}
rc, sessionPresent, err := verifyCONNACK(conn)
return rc, sessionPresent, err
}
// This function is only used for receiving a connack
// when the connection is first started.
// This prevents receiving incoming data while resume
// is in progress if clean session is false.
func verifyCONNACK(conn io.Reader) (byte, bool, error) {
DEBUG.Println(NET, "connect started")
ca, err := packets.ReadPacket(conn)
if err != nil {
ERROR.Println(NET, "connect got error", err)
return packets.ErrNetworkError, false, err
}
if ca == nil {
ERROR.Println(NET, "received nil packet")
return packets.ErrNetworkError, false, errors.New("nil CONNACK packet")
}
msg, ok := ca.(*packets.ConnackPacket)
if !ok {
ERROR.Println(NET, "received msg that was not CONNACK")
return packets.ErrNetworkError, false, errors.New("non-CONNACK first packet received")
}
DEBUG.Println(NET, "received connack")
return msg.ReturnCode, msg.SessionPresent, nil
}
// inbound encapsulates the output from startIncoming.
// err - If != nil then an error has occurred
// cp - A control packet received over the network link
type inbound struct {
err error
cp packets.ControlPacket
}
// startIncoming initiates a goroutine that reads incoming messages off the wire and sends them to the channel (returned).
// If there are any issues with the network connection then the returned channel will be closed and the goroutine will exit
// (so closing the connection will terminate the goroutine)
func startIncoming(conn io.Reader) <-chan inbound {
var err error
var cp packets.ControlPacket
ibound := make(chan inbound)
DEBUG.Println(NET, "incoming started")
go func() {
for {
if cp, err = packets.ReadPacket(conn); err != nil {
// We do not want to log the error if it is due to the network connection having been closed
// elsewhere (i.e. after sending DisconnectPacket). Detecting this situation is the subject of
// https://github.com/golang/go/issues/4373
if !strings.Contains(err.Error(), closedNetConnErrorText) {
ibound <- inbound{err: err}
}
close(ibound)
DEBUG.Println(NET, "incoming complete")
return
}
DEBUG.Println(NET, "startIncoming Received Message")
ibound <- inbound{cp: cp}
}
}()
return ibound
}
// incomingComms encapsulates the possible output of the incomingComms routine. If err != nil then an error has occurred and
// the routine will have terminated; otherwise one of the other members should be non-nil
type incomingComms struct {
err error // If non-nil then there has been an error (ignore everything else)
outbound *PacketAndToken // Packet (with token) than needs to be sent out (e.g. an acknowledgement)
incomingPub *packets.PublishPacket // A new publish has been received; this will need to be passed on to our user
}
// startIncomingComms initiates incoming communications; this includes starting a goroutine to process incoming
// messages.
// Accepts a channel of inbound messages from the store (persisted messages); note this must be closed as soon as
// everything in the store has been sent.
// Returns a channel that will be passed any received packets; this will be closed on a network error (and inboundFromStore closed)
func startIncomingComms(conn io.Reader,
c commsFns,
inboundFromStore <-chan packets.ControlPacket,
) <-chan incomingComms {
ibound := startIncoming(conn) // Start goroutine that reads from network connection
output := make(chan incomingComms)
DEBUG.Println(NET, "startIncomingComms started")
go func() {
for {
if inboundFromStore == nil && ibound == nil {
close(output)
DEBUG.Println(NET, "startIncomingComms goroutine complete")
return // As soon as ibound is closed we can exit (should have already processed an error)
}
DEBUG.Println(NET, "logic waiting for msg on ibound")
var msg packets.ControlPacket
var ok bool
select {
case msg, ok = <-inboundFromStore:
if !ok {
DEBUG.Println(NET, "startIncomingComms: inboundFromStore complete")
inboundFromStore = nil // should happen quickly as this is only for persisted messages
continue
}
DEBUG.Println(NET, "startIncomingComms: got msg from store")
case ibMsg, ok := <-ibound:
if !ok {
DEBUG.Println(NET, "startIncomingComms: ibound complete")
ibound = nil
continue
}
DEBUG.Println(NET, "startIncomingComms: got msg on ibound")
// If the inbound comms routine encounters any issues it will send us an error.
if ibMsg.err != nil {
output <- incomingComms{err: ibMsg.err}
continue // Usually the channel will be closed immediately after sending an error but safer that we do not assume this
}
msg = ibMsg.cp
c.persistInbound(msg)
c.UpdateLastReceived() // Notify keepalive logic that we recently received a packet
}
switch m := msg.(type) {
case *packets.PingrespPacket:
DEBUG.Println(NET, "startIncomingComms: received pingresp")
c.pingRespReceived()
case *packets.SubackPacket:
DEBUG.Println(NET, "startIncomingComms: received suback, id:", m.MessageID)
token := c.getToken(m.MessageID)
if t, ok := token.(*SubscribeToken); ok {
DEBUG.Println(NET, "startIncomingComms: granted qoss", m.ReturnCodes)
for i, qos := range m.ReturnCodes {
t.subResult[t.subs[i]] = qos
}
}
token.flowComplete()
c.freeID(m.MessageID)
case *packets.UnsubackPacket:
DEBUG.Println(NET, "startIncomingComms: received unsuback, id:", m.MessageID)
c.getToken(m.MessageID).flowComplete()
c.freeID(m.MessageID)
case *packets.PublishPacket:
DEBUG.Println(NET, "startIncomingComms: received publish, msgId:", m.MessageID)
output <- incomingComms{incomingPub: m}
case *packets.PubackPacket:
DEBUG.Println(NET, "startIncomingComms: received puback, id:", m.MessageID)
c.getToken(m.MessageID).flowComplete()
c.freeID(m.MessageID)
case *packets.PubrecPacket:
DEBUG.Println(NET, "startIncomingComms: received pubrec, id:", m.MessageID)
prel := packets.NewControlPacket(packets.Pubrel).(*packets.PubrelPacket)
prel.MessageID = m.MessageID
output <- incomingComms{outbound: &PacketAndToken{p: prel, t: nil}}
case *packets.PubrelPacket:
DEBUG.Println(NET, "startIncomingComms: received pubrel, id:", m.MessageID)
pc := packets.NewControlPacket(packets.Pubcomp).(*packets.PubcompPacket)
pc.MessageID = m.MessageID
c.persistOutbound(pc)
output <- incomingComms{outbound: &PacketAndToken{p: pc, t: nil}}
case *packets.PubcompPacket:
DEBUG.Println(NET, "startIncomingComms: received pubcomp, id:", m.MessageID)
c.getToken(m.MessageID).flowComplete()
c.freeID(m.MessageID)
}
}
}()
return output
}
// startOutgoingComms initiates a go routine to transmit outgoing packets.
// Pass in an open network connection and channels for outbound messages (including those triggered
// directly from incoming comms).
// Returns a channel that will receive details of any errors (closed when the goroutine exits)
// This function wil only terminate when all input channels are closed
func startOutgoingComms(conn net.Conn,
c commsFns,
oboundp <-chan *PacketAndToken,
obound <-chan *PacketAndToken,
oboundFromIncoming <-chan *PacketAndToken,
) <-chan error {
errChan := make(chan error)
DEBUG.Println(NET, "outgoing started")
go func() {
for {
DEBUG.Println(NET, "outgoing waiting for an outbound message")
// This goroutine will only exits when all of the input channels we receive on have been closed. This approach is taken to avoid any
// deadlocks (if the connection goes down there are limited options as to what we can do with anything waiting on us and
// throwing away the packets seems the best option)
if oboundp == nil && obound == nil && oboundFromIncoming == nil {
DEBUG.Println(NET, "outgoing comms stopping")
close(errChan)
return
}
select {
case pub, ok := <-obound:
if !ok {
obound = nil
continue
}
msg := pub.p.(*packets.PublishPacket)
DEBUG.Println(NET, "obound msg to write", msg.MessageID)
writeTimeout := c.getWriteTimeOut()
if writeTimeout > 0 {
if err := conn.SetWriteDeadline(time.Now().Add(writeTimeout)); err != nil {
ERROR.Println(NET, "SetWriteDeadline ", err)
}
}
if err := msg.Write(conn); err != nil {
ERROR.Println(NET, "outgoing obound reporting error ", err)
pub.t.setError(err)
// report error if it's not due to the connection being closed elsewhere
if !strings.Contains(err.Error(), closedNetConnErrorText) {
errChan <- err
}
continue
}
if writeTimeout > 0 {
// If we successfully wrote, we don't want the timeout to happen during an idle period
// so we reset it to infinite.
if err := conn.SetWriteDeadline(time.Time{}); err != nil {
ERROR.Println(NET, "SetWriteDeadline to 0 ", err)
}
}
if msg.Qos == 0 {
pub.t.flowComplete()
}
DEBUG.Println(NET, "obound wrote msg, id:", msg.MessageID)
case msg, ok := <-oboundp:
if !ok {
oboundp = nil
continue
}
DEBUG.Println(NET, "obound priority msg to write, type", reflect.TypeOf(msg.p))
if err := msg.p.Write(conn); err != nil {
ERROR.Println(NET, "outgoing oboundp reporting error ", err)
if msg.t != nil {
msg.t.setError(err)
}
errChan <- err
continue
}
if _, ok := msg.p.(*packets.DisconnectPacket); ok {
msg.t.(*DisconnectToken).flowComplete()
DEBUG.Println(NET, "outbound wrote disconnect, closing connection")
// As per the MQTT spec "After sending a DISCONNECT Packet the Client MUST close the Network Connection"
// Closing the connection will cause the goroutines to end in sequence (starting with incoming comms)
_ = conn.Close()
}
case msg, ok := <-oboundFromIncoming: // message triggered by an inbound message (PubrecPacket or PubrelPacket)
if !ok {
oboundFromIncoming = nil
continue
}
DEBUG.Println(NET, "obound from incoming msg to write, type", reflect.TypeOf(msg.p), " ID ", msg.p.Details().MessageID)
if err := msg.p.Write(conn); err != nil {
ERROR.Println(NET, "outgoing oboundFromIncoming reporting error", err)
if msg.t != nil {
msg.t.setError(err)
}
errChan <- err
continue
}
}
c.UpdateLastSent() // Record that a packet has been received (for keepalive routine)
}
}()
return errChan
}
// commsFns provide access to the client state (messageids, requesting disconnection and updating timing)
type commsFns interface {
getToken(id uint16) tokenCompletor // Retrieve the token for the specified messageid (if none then a dummy token must be returned)
freeID(id uint16) // Release the specified messageid (clearing out of any persistent store)
UpdateLastReceived() // Must be called whenever a packet is received
UpdateLastSent() // Must be called whenever a packet is successfully sent
getWriteTimeOut() time.Duration // Return the writetimeout (or 0 if none)
persistOutbound(m packets.ControlPacket) // add the packet to the outbound store
persistInbound(m packets.ControlPacket) // add the packet to the inbound store
pingRespReceived() // Called when a ping response is received
}
// startComms initiates goroutines that handles communications over the network connection
// Messages will be stored (via commsFns) and deleted from the store as necessary
// It returns two channels:
//
// packets.PublishPacket - Will receive publish packets received over the network.
// Closed when incoming comms routines exit (on shutdown or if network link closed)
// error - Any errors will be sent on this channel. The channel is closed when all comms routines have shut down
//
// Note: The comms routines monitoring oboundp and obound will not shutdown until those channels are both closed. Any messages received between the
// connection being closed and those channels being closed will generate errors (and nothing will be sent). That way the chance of a deadlock is
// minimised.
func startComms(conn net.Conn, // Network connection (must be active)
c commsFns, // getters and setters to enable us to cleanly interact with client
inboundFromStore <-chan packets.ControlPacket, // Inbound packets from the persistence store (should be closed relatively soon after startup)
oboundp <-chan *PacketAndToken,
obound <-chan *PacketAndToken) (
<-chan *packets.PublishPacket, // Publishpackages received over the network
<-chan error, // Any errors (should generally trigger a disconnect)
) {
// Start inbound comms handler; this needs to be able to transmit messages so we start a go routine to add these to the priority outbound channel
ibound := startIncomingComms(conn, c, inboundFromStore)
outboundFromIncoming := make(chan *PacketAndToken) // Will accept outgoing messages triggered by startIncomingComms (e.g. acknowledgements)
// Start the outgoing handler. It is important to note that output from startIncomingComms is fed into startOutgoingComms (for ACK's)
oboundErr := startOutgoingComms(conn, c, oboundp, obound, outboundFromIncoming)
DEBUG.Println(NET, "startComms started")
// Run up go routines to handle the output from the above comms functions - these are handled in separate
// go routines because they can interact (e.g. ibound triggers an ACK to obound which triggers an error)
var wg sync.WaitGroup
wg.Add(2)
outPublish := make(chan *packets.PublishPacket)
outError := make(chan error)
// Any messages received get passed to the appropriate channel
go func() {
for ic := range ibound {
if ic.err != nil {
outError <- ic.err
continue
}
if ic.outbound != nil {
outboundFromIncoming <- ic.outbound
continue
}
if ic.incomingPub != nil {
outPublish <- ic.incomingPub
continue
}
ERROR.Println(STR, "startComms received empty incomingComms msg")
}
// Close channels that will not be written to again (allowing other routines to exit)
close(outboundFromIncoming)
close(outPublish)
wg.Done()
}()
// Any errors will be passed out to our caller
go func() {
for err := range oboundErr {
outError <- err
}
wg.Done()
}()
// outError is used by both routines so can only be closed when they are both complete
go func() {
wg.Wait()
close(outError)
DEBUG.Println(NET, "startComms closing outError")
}()
return outPublish, outError
}
// ackFunc acknowledges a packet
// WARNING the function returned must not be called if the comms routine is shutting down or not running
// (it needs outgoing comms in order to send the acknowledgement). Currently this is only called from
// matchAndDispatch which will be shutdown before the comms are
func ackFunc(oboundP chan *PacketAndToken, persist Store, packet *packets.PublishPacket) func() {
return func() {
switch packet.Qos {
case 2:
pr := packets.NewControlPacket(packets.Pubrec).(*packets.PubrecPacket)
pr.MessageID = packet.MessageID
DEBUG.Println(NET, "putting pubrec msg on obound")
oboundP <- &PacketAndToken{p: pr, t: nil}
DEBUG.Println(NET, "done putting pubrec msg on obound")
case 1:
pa := packets.NewControlPacket(packets.Puback).(*packets.PubackPacket)
pa.MessageID = packet.MessageID
DEBUG.Println(NET, "putting puback msg on obound")
persistOutbound(persist, pa)
oboundP <- &PacketAndToken{p: pa, t: nil}
DEBUG.Println(NET, "done putting puback msg on obound")
case 0:
// do nothing, since there is no need to send an ack packet back
}
}
}