// Copyright 2011 The Go Authors. All rights reserved. // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file. package ldap import ( "crypto/tls" "errors" "log" "net" "sync" "time" "github.com/nmcclain/asn1-ber" ) const ( MessageQuit = 0 MessageRequest = 1 MessageResponse = 2 MessageFinish = 3 ) type messagePacket struct { Op int MessageID uint64 Packet *ber.Packet Channel chan *ber.Packet } // Conn represents an LDAP Connection type Conn struct { conn net.Conn isTLS bool Debug debugging chanConfirm chan bool chanResults map[uint64]chan *ber.Packet chanMessage chan *messagePacket chanMessageID chan uint64 wgSender sync.WaitGroup chanDone chan struct{} once sync.Once } // Dial connects to the given address on the given network using net.Dial // and then returns a new Conn for the connection. func Dial(network, addr string) (*Conn, error) { c, err := net.Dial(network, addr) if err != nil { return nil, NewError(ErrorNetwork, err) } conn := NewConn(c) conn.start() return conn, nil } // DialTimeout connects to the given address on the given network using net.DialTimeout // and then returns a new Conn for the connection. Acts like Dial but takes a timeout. func DialTimeout(network, addr string, timeout time.Duration) (*Conn, error) { c, err := net.DialTimeout(network, addr, timeout) if err != nil { return nil, NewError(ErrorNetwork, err) } conn := NewConn(c) conn.start() return conn, nil } // DialTLS connects to the given address on the given network using tls.Dial // and then returns a new Conn for the connection. func DialTLS(network, addr string, config *tls.Config) (*Conn, error) { c, err := tls.Dial(network, addr, config) if err != nil { return nil, NewError(ErrorNetwork, err) } conn := NewConn(c) conn.isTLS = true conn.start() return conn, nil } // DialTLSDialer connects to the given address on the given network using tls.DialWithDialer // and then returns a new Conn for the connection. func DialTLSDialer(network, addr string, config *tls.Config, dialer *net.Dialer) (*Conn, error) { c, err := tls.DialWithDialer(dialer, network, addr, config) if err != nil { return nil, NewError(ErrorNetwork, err) } conn := NewConn(c) conn.isTLS = true conn.start() return conn, nil } // NewConn returns a new Conn using conn for network I/O. func NewConn(conn net.Conn) *Conn { return &Conn{ conn: conn, chanConfirm: make(chan bool), chanMessageID: make(chan uint64), chanMessage: make(chan *messagePacket, 10), chanResults: map[uint64]chan *ber.Packet{}, chanDone: make(chan struct{}), } } func (l *Conn) start() { go l.reader() go l.processMessages() } // Close closes the connection. func (l *Conn) Close() { l.once.Do(func() { close(l.chanDone) l.wgSender.Wait() l.Debug.Printf("Sending quit message and waiting for confirmation") l.chanMessage <- &messagePacket{Op: MessageQuit} <-l.chanConfirm close(l.chanMessage) l.Debug.Printf("Closing network connection") if err := l.conn.Close(); err != nil { log.Print(err) } }) <-l.chanDone } // Returns the next available messageID func (l *Conn) nextMessageID() uint64 { if l.chanMessageID != nil { if messageID, ok := <-l.chanMessageID; ok { return messageID } } return 0 } // StartTLS sends the command to start a TLS session and then creates a new TLS Client func (l *Conn) StartTLS(config *tls.Config) error { messageID := l.nextMessageID() if l.isTLS { return NewError(ErrorNetwork, errors.New("ldap: already encrypted")) } packet := ber.Encode(ber.ClassUniversal, ber.TypeConstructed, ber.TagSequence, nil, "LDAP Request") packet.AppendChild(ber.NewInteger(ber.ClassUniversal, ber.TypePrimitive, ber.TagInteger, messageID, "MessageID")) request := ber.Encode(ber.ClassApplication, ber.TypeConstructed, ApplicationExtendedRequest, nil, "Start TLS") request.AppendChild(ber.NewString(ber.ClassContext, ber.TypePrimitive, 0, "1.3.6.1.4.1.1466.20037", "TLS Extended Command")) packet.AppendChild(request) l.Debug.PrintPacket(packet) _, err := l.conn.Write(packet.Bytes()) if err != nil { return NewError(ErrorNetwork, err) } packet, err = ber.ReadPacket(l.conn) if err != nil { return NewError(ErrorNetwork, err) } if l.Debug { if err := addLDAPDescriptions(packet); err != nil { return err } ber.PrintPacket(packet) } if packet.Children[1].Children[0].Value.(uint64) == 0 { conn := tls.Client(l.conn, config) l.isTLS = true l.conn = conn } return nil } func (l *Conn) closing() bool { select { case <-l.chanDone: return true default: return false } } func (l *Conn) sendMessage(packet *ber.Packet) (chan *ber.Packet, error) { if l.closing() { return nil, NewError(ErrorNetwork, errors.New("ldap: connection closed")) } out := make(chan *ber.Packet) message := &messagePacket{ Op: MessageRequest, MessageID: packet.Children[0].Value.(uint64), Packet: packet, Channel: out, } l.sendProcessMessage(message) return out, nil } func (l *Conn) finishMessage(messageID uint64) { if l.closing() { return } message := &messagePacket{ Op: MessageFinish, MessageID: messageID, } l.sendProcessMessage(message) } func (l *Conn) sendProcessMessage(message *messagePacket) bool { l.wgSender.Add(1) defer l.wgSender.Done() if l.closing() { return false } l.chanMessage <- message return true } func (l *Conn) processMessages() { defer func() { for messageID, channel := range l.chanResults { l.Debug.Printf("Closing channel for MessageID %d", messageID) close(channel) delete(l.chanResults, messageID) } close(l.chanMessageID) l.chanConfirm <- true close(l.chanConfirm) }() var messageID uint64 = 1 for { select { case l.chanMessageID <- messageID: messageID++ case messagePacket, ok := <-l.chanMessage: if !ok { l.Debug.Printf("Shutting down - message channel is closed") return } switch messagePacket.Op { case MessageQuit: l.Debug.Printf("Shutting down - quit message received") return case MessageRequest: // Add to message list and write to network l.Debug.Printf("Sending message %d", messagePacket.MessageID) l.chanResults[messagePacket.MessageID] = messagePacket.Channel // go routine buf := messagePacket.Packet.Bytes() _, err := l.conn.Write(buf) if err != nil { l.Debug.Printf("Error Sending Message: %s", err.Error()) break } case MessageResponse: l.Debug.Printf("Receiving message %d", messagePacket.MessageID) if chanResult, ok := l.chanResults[messagePacket.MessageID]; ok { chanResult <- messagePacket.Packet } else { log.Printf("Received unexpected message %d", messagePacket.MessageID) ber.PrintPacket(messagePacket.Packet) } case MessageFinish: // Remove from message list l.Debug.Printf("Finished message %d", messagePacket.MessageID) close(l.chanResults[messagePacket.MessageID]) delete(l.chanResults, messagePacket.MessageID) } } } } func (l *Conn) reader() { defer func() { l.Close() }() for { packet, err := ber.ReadPacket(l.conn) if err != nil { l.Debug.Printf("reader: %s", err.Error()) return } addLDAPDescriptions(packet) message := &messagePacket{ Op: MessageResponse, MessageID: packet.Children[0].Value.(uint64), Packet: packet, } if !l.sendProcessMessage(message) { return } } } // Use Abandon operation to perform connection keepalives func (l *Conn) Ping() error { messageID := l.nextMessageID() packet := ber.Encode(ber.ClassUniversal, ber.TypeConstructed, ber.TagSequence, nil, "LDAP Request") packet.AppendChild(ber.NewInteger(ber.ClassUniversal, ber.TypePrimitive, ber.TagInteger, messageID, "MessageID")) abandonRequest := ber.Encode(ber.ClassApplication, ber.TypePrimitive, ApplicationAbandonRequest, nil, "Abandon Request") packet.AppendChild(abandonRequest) if l.Debug { ber.PrintPacket(packet) } channel, err := l.sendMessage(packet) if err != nil { return err } if channel == nil { return NewError(ErrorNetwork, errors.New("ldap: could not send message")) } defer l.finishMessage(messageID) if l.Debug { if err := addLDAPDescriptions(packet); err != nil { return err } ber.PrintPacket(packet) } return nil }