soju/user.go
Simon Ser 55274d7213 Move network.clients to user
No need to have this list per-network.
2021-03-29 16:58:56 +02:00

633 lines
14 KiB
Go

package soju
import (
"crypto/sha256"
"encoding/binary"
"encoding/hex"
"fmt"
"time"
"gopkg.in/irc.v3"
)
type event interface{}
type eventUpstreamMessage struct {
msg *irc.Message
uc *upstreamConn
}
type eventUpstreamConnectionError struct {
net *network
err error
}
type eventUpstreamConnected struct {
uc *upstreamConn
}
type eventUpstreamDisconnected struct {
uc *upstreamConn
}
type eventUpstreamError struct {
uc *upstreamConn
err error
}
type eventDownstreamMessage struct {
msg *irc.Message
dc *downstreamConn
}
type eventDownstreamConnected struct {
dc *downstreamConn
}
type eventDownstreamDisconnected struct {
dc *downstreamConn
}
type eventChannelDetach struct {
uc *upstreamConn
name string
}
type eventStop struct{}
type deliveredClientMap map[string]string // client name -> msg ID
type network struct {
Network
user *user
stopped chan struct{}
conn *upstreamConn
channels channelCasemapMap
delivered deliveredCasemapMap
lastError error
casemap casemapping
}
func newNetwork(user *user, record *Network, channels []Channel) *network {
m := channelCasemapMap{newCasemapMap(0)}
for _, ch := range channels {
ch := ch
m.SetValue(ch.Name, &ch)
}
return &network{
Network: *record,
user: user,
stopped: make(chan struct{}),
channels: m,
delivered: deliveredCasemapMap{newCasemapMap(0)},
casemap: casemapRFC1459,
}
}
func (net *network) forEachDownstream(f func(*downstreamConn)) {
net.user.forEachDownstream(func(dc *downstreamConn) {
if dc.network != nil && dc.network != net {
return
}
f(dc)
})
}
func (net *network) isStopped() bool {
select {
case <-net.stopped:
return true
default:
return false
}
}
func userIdent(u *User) string {
// The ident is a string we will send to upstream servers in clear-text.
// For privacy reasons, make sure it doesn't expose any meaningful user
// metadata. We just use the base64-encoded hashed ID, so that people don't
// start relying on the string being an integer or following a pattern.
var b [64]byte
binary.LittleEndian.PutUint64(b[:], uint64(u.ID))
h := sha256.Sum256(b[:])
return hex.EncodeToString(h[:16])
}
func (net *network) run() {
var lastTry time.Time
for {
if net.isStopped() {
return
}
if dur := time.Now().Sub(lastTry); dur < retryConnectDelay {
delay := retryConnectDelay - dur
net.user.srv.Logger.Printf("waiting %v before trying to reconnect to %q", delay.Truncate(time.Second), net.Addr)
time.Sleep(delay)
}
lastTry = time.Now()
uc, err := connectToUpstream(net)
if err != nil {
net.user.srv.Logger.Printf("failed to connect to upstream server %q: %v", net.Addr, err)
net.user.events <- eventUpstreamConnectionError{net, fmt.Errorf("failed to connect: %v", err)}
continue
}
if net.user.srv.Identd != nil {
net.user.srv.Identd.Store(uc.RemoteAddr().String(), uc.LocalAddr().String(), userIdent(&net.user.User))
}
uc.register()
if err := uc.runUntilRegistered(); err != nil {
text := err.Error()
if regErr, ok := err.(registrationError); ok {
text = string(regErr)
}
uc.logger.Printf("failed to register: %v", text)
net.user.events <- eventUpstreamConnectionError{net, fmt.Errorf("failed to register: %v", text)}
uc.Close()
continue
}
// TODO: this is racy with net.stopped. If the network is stopped
// before the user goroutine receives eventUpstreamConnected, the
// connection won't be closed.
net.user.events <- eventUpstreamConnected{uc}
if err := uc.readMessages(net.user.events); err != nil {
uc.logger.Printf("failed to handle messages: %v", err)
net.user.events <- eventUpstreamError{uc, fmt.Errorf("failed to handle messages: %v", err)}
}
uc.Close()
net.user.events <- eventUpstreamDisconnected{uc}
if net.user.srv.Identd != nil {
net.user.srv.Identd.Delete(uc.RemoteAddr().String(), uc.LocalAddr().String())
}
}
}
func (net *network) stop() {
if !net.isStopped() {
close(net.stopped)
}
if net.conn != nil {
net.conn.Close()
}
}
func (net *network) detach(ch *Channel) {
if ch.Detached {
return
}
ch.Detached = true
net.user.srv.Logger.Printf("network %q: detaching channel %q", net.GetName(), ch.Name)
if net.conn != nil {
uch := net.conn.channels.Value(ch.Name)
if uch != nil {
uch.updateAutoDetach(0)
}
}
net.forEachDownstream(func(dc *downstreamConn) {
dc.SendMessage(&irc.Message{
Prefix: dc.prefix(),
Command: "PART",
Params: []string{dc.marshalEntity(net, ch.Name), "Detach"},
})
})
}
func (net *network) attach(ch *Channel) {
if !ch.Detached {
return
}
ch.Detached = false
net.user.srv.Logger.Printf("network %q: attaching channel %q", net.GetName(), ch.Name)
var uch *upstreamChannel
if net.conn != nil {
uch = net.conn.channels.Value(ch.Name)
net.conn.updateChannelAutoDetach(ch.Name)
}
net.forEachDownstream(func(dc *downstreamConn) {
dc.SendMessage(&irc.Message{
Prefix: dc.prefix(),
Command: "JOIN",
Params: []string{dc.marshalEntity(net, ch.Name)},
})
if uch != nil {
forwardChannel(dc, uch)
}
dc.sendTargetBacklog(net, ch.Name)
})
}
func (net *network) deleteChannel(name string) error {
ch := net.channels.Value(name)
if ch == nil {
return fmt.Errorf("unknown channel %q", name)
}
if net.conn != nil {
uch := net.conn.channels.Value(ch.Name)
if uch != nil {
uch.updateAutoDetach(0)
}
}
if err := net.user.srv.db.DeleteChannel(ch.ID); err != nil {
return err
}
net.channels.Delete(name)
return nil
}
func (net *network) updateCasemapping(newCasemap casemapping) {
net.casemap = newCasemap
net.channels.SetCasemapping(newCasemap)
net.delivered.SetCasemapping(newCasemap)
if net.conn != nil {
net.conn.channels.SetCasemapping(newCasemap)
for _, entry := range net.conn.channels.innerMap {
uch := entry.value.(*upstreamChannel)
uch.Members.SetCasemapping(newCasemap)
}
}
}
type user struct {
User
srv *Server
events chan event
done chan struct{}
networks []*network
downstreamConns []*downstreamConn
msgStore messageStore
clients map[string]struct{} // indexed by client name
// LIST commands in progress
pendingLISTs []pendingLIST
}
type pendingLIST struct {
downstreamID uint64
// list of per-upstream LIST commands not yet sent or completed
pendingCommands map[int64]*irc.Message
}
func newUser(srv *Server, record *User) *user {
var msgStore messageStore
if srv.LogPath != "" {
msgStore = newFSMessageStore(srv.LogPath, record.Username)
} else {
msgStore = newMemoryMessageStore()
}
return &user{
User: *record,
srv: srv,
events: make(chan event, 64),
done: make(chan struct{}),
msgStore: msgStore,
clients: make(map[string]struct{}),
}
}
func (u *user) forEachNetwork(f func(*network)) {
for _, network := range u.networks {
f(network)
}
}
func (u *user) forEachUpstream(f func(uc *upstreamConn)) {
for _, network := range u.networks {
if network.conn == nil {
continue
}
f(network.conn)
}
}
func (u *user) forEachDownstream(f func(dc *downstreamConn)) {
for _, dc := range u.downstreamConns {
f(dc)
}
}
func (u *user) getNetwork(name string) *network {
for _, network := range u.networks {
if network.Addr == name {
return network
}
if network.Name != "" && network.Name == name {
return network
}
}
return nil
}
func (u *user) getNetworkByID(id int64) *network {
for _, net := range u.networks {
if net.ID == id {
return net
}
}
return nil
}
func (u *user) run() {
defer func() {
if u.msgStore != nil {
if err := u.msgStore.Close(); err != nil {
u.srv.Logger.Printf("failed to close message store for user %q: %v", u.Username, err)
}
}
close(u.done)
}()
networks, err := u.srv.db.ListNetworks(u.ID)
if err != nil {
u.srv.Logger.Printf("failed to list networks for user %q: %v", u.Username, err)
return
}
for _, record := range networks {
record := record
channels, err := u.srv.db.ListChannels(record.ID)
if err != nil {
u.srv.Logger.Printf("failed to list channels for user %q, network %q: %v", u.Username, record.GetName(), err)
continue
}
network := newNetwork(u, &record, channels)
u.networks = append(u.networks, network)
go network.run()
}
for e := range u.events {
switch e := e.(type) {
case eventUpstreamConnected:
uc := e.uc
uc.network.conn = uc
uc.updateAway()
uc.forEachDownstream(func(dc *downstreamConn) {
dc.updateSupportedCaps()
sendServiceNOTICE(dc, fmt.Sprintf("connected to %s", uc.network.GetName()))
dc.updateNick()
})
uc.network.lastError = nil
case eventUpstreamDisconnected:
u.handleUpstreamDisconnected(e.uc)
case eventUpstreamConnectionError:
net := e.net
stopped := false
select {
case <-net.stopped:
stopped = true
default:
}
if !stopped && (net.lastError == nil || net.lastError.Error() != e.err.Error()) {
net.forEachDownstream(func(dc *downstreamConn) {
sendServiceNOTICE(dc, fmt.Sprintf("failed connecting/registering to %s: %v", net.GetName(), e.err))
})
}
net.lastError = e.err
case eventUpstreamError:
uc := e.uc
uc.forEachDownstream(func(dc *downstreamConn) {
sendServiceNOTICE(dc, fmt.Sprintf("disconnected from %s: %v", uc.network.GetName(), e.err))
})
uc.network.lastError = e.err
case eventUpstreamMessage:
msg, uc := e.msg, e.uc
if uc.isClosed() {
uc.logger.Printf("ignoring message on closed connection: %v", msg)
break
}
if err := uc.handleMessage(msg); err != nil {
uc.logger.Printf("failed to handle message %q: %v", msg, err)
}
case eventChannelDetach:
uc, name := e.uc, e.name
c := uc.network.channels.Value(name)
if c == nil || c.Detached {
continue
}
uc.network.detach(c)
if err := uc.srv.db.StoreChannel(uc.network.ID, c); err != nil {
u.srv.Logger.Printf("failed to store updated detached channel %q: %v", c.Name, err)
}
case eventDownstreamConnected:
dc := e.dc
if err := dc.welcome(); err != nil {
dc.logger.Printf("failed to handle new registered connection: %v", err)
break
}
u.downstreamConns = append(u.downstreamConns, dc)
dc.forEachNetwork(func(network *network) {
if network.lastError != nil {
sendServiceNOTICE(dc, fmt.Sprintf("disconnected from %s: %v", network.GetName(), network.lastError))
}
})
u.forEachUpstream(func(uc *upstreamConn) {
uc.updateAway()
})
u.clients[dc.clientName] = struct{}{}
case eventDownstreamDisconnected:
dc := e.dc
for i := range u.downstreamConns {
if u.downstreamConns[i] == dc {
u.downstreamConns = append(u.downstreamConns[:i], u.downstreamConns[i+1:]...)
break
}
}
u.forEachUpstream(func(uc *upstreamConn) {
uc.updateAway()
})
case eventDownstreamMessage:
msg, dc := e.msg, e.dc
if dc.isClosed() {
dc.logger.Printf("ignoring message on closed connection: %v", msg)
break
}
err := dc.handleMessage(msg)
if ircErr, ok := err.(ircError); ok {
ircErr.Message.Prefix = dc.srv.prefix()
dc.SendMessage(ircErr.Message)
} else if err != nil {
dc.logger.Printf("failed to handle message %q: %v", msg, err)
dc.Close()
}
case eventStop:
u.forEachDownstream(func(dc *downstreamConn) {
dc.Close()
})
for _, n := range u.networks {
n.stop()
}
return
default:
u.srv.Logger.Printf("received unknown event type: %T", e)
}
}
}
func (u *user) handleUpstreamDisconnected(uc *upstreamConn) {
uc.network.conn = nil
uc.endPendingLISTs(true)
for _, entry := range uc.channels.innerMap {
uch := entry.value.(*upstreamChannel)
uch.updateAutoDetach(0)
}
uc.forEachDownstream(func(dc *downstreamConn) {
dc.updateSupportedCaps()
})
if uc.network.lastError == nil {
uc.forEachDownstream(func(dc *downstreamConn) {
sendServiceNOTICE(dc, fmt.Sprintf("disconnected from %s", uc.network.GetName()))
})
}
}
func (u *user) addNetwork(network *network) {
u.networks = append(u.networks, network)
go network.run()
}
func (u *user) removeNetwork(network *network) {
network.stop()
u.forEachDownstream(func(dc *downstreamConn) {
if dc.network != nil && dc.network == network {
dc.Close()
}
})
for i, net := range u.networks {
if net == network {
u.networks = append(u.networks[:i], u.networks[i+1:]...)
return
}
}
panic("tried to remove a non-existing network")
}
func (u *user) createNetwork(record *Network) (*network, error) {
if record.ID != 0 {
panic("tried creating an already-existing network")
}
network := newNetwork(u, record, nil)
err := u.srv.db.StoreNetwork(u.ID, &network.Network)
if err != nil {
return nil, err
}
u.addNetwork(network)
return network, nil
}
func (u *user) updateNetwork(record *Network) (*network, error) {
if record.ID == 0 {
panic("tried updating a new network")
}
network := u.getNetworkByID(record.ID)
if network == nil {
panic("tried updating a non-existing network")
}
if err := u.srv.db.StoreNetwork(u.ID, record); err != nil {
return nil, err
}
// Most network changes require us to re-connect to the upstream server
channels := make([]Channel, 0, network.channels.Len())
for _, entry := range network.channels.innerMap {
ch := entry.value.(*Channel)
channels = append(channels, *ch)
}
updatedNetwork := newNetwork(u, record, channels)
// If we're currently connected, disconnect and perform the necessary
// bookkeeping
if network.conn != nil {
network.stop()
// Note: this will set network.conn to nil
u.handleUpstreamDisconnected(network.conn)
}
// Patch downstream connections to use our fresh updated network
u.forEachDownstream(func(dc *downstreamConn) {
if dc.network != nil && dc.network == network {
dc.network = updatedNetwork
}
})
// We need to remove the network after patching downstream connections,
// otherwise they'll get closed
u.removeNetwork(network)
// This will re-connect to the upstream server
u.addNetwork(updatedNetwork)
return updatedNetwork, nil
}
func (u *user) deleteNetwork(id int64) error {
network := u.getNetworkByID(id)
if network == nil {
panic("tried deleting a non-existing network")
}
if err := u.srv.db.DeleteNetwork(network.ID); err != nil {
return err
}
u.removeNetwork(network)
return nil
}
func (u *user) updatePassword(hashed string) error {
u.User.Password = hashed
return u.srv.db.StoreUser(&u.User)
}
func (u *user) stop() {
u.events <- eventStop{}
<-u.done
}