package fasthttp import ( "errors" "net" "strconv" "sync" "sync/atomic" "time" ) // Dial dials the given TCP addr using tcp4. // // This function has the following additional features comparing to net.Dial: // // * It reduces load on DNS resolver by caching resolved TCP addressed // for DefaultDNSCacheDuration. // * It dials all the resolved TCP addresses in round-robin manner until // connection is established. This may be useful if certain addresses // are temporarily unreachable. // * It returns ErrDialTimeout if connection cannot be established during // DefaultDialTimeout seconds. Use DialTimeout for customizing dial timeout. // // This dialer is intended for custom code wrapping before passing // to Client.Dial or HostClient.Dial. // // For instance, per-host counters and/or limits may be implemented // by such wrappers. // // The addr passed to the function must contain port. Example addr values: // // * foobar.baz:443 // * foo.bar:80 // * aaa.com:8080 func Dial(addr string) (net.Conn, error) { return getDialer(DefaultDialTimeout, false)(addr) } // DialTimeout dials the given TCP addr using tcp4 using the given timeout. // // This function has the following additional features comparing to net.Dial: // // * It reduces load on DNS resolver by caching resolved TCP addressed // for DefaultDNSCacheDuration. // * It dials all the resolved TCP addresses in round-robin manner until // connection is established. This may be useful if certain addresses // are temporarily unreachable. // // This dialer is intended for custom code wrapping before passing // to Client.Dial or HostClient.Dial. // // For instance, per-host counters and/or limits may be implemented // by such wrappers. // // The addr passed to the function must contain port. Example addr values: // // * foobar.baz:443 // * foo.bar:80 // * aaa.com:8080 func DialTimeout(addr string, timeout time.Duration) (net.Conn, error) { return getDialer(timeout, false)(addr) } // DialDualStack dials the given TCP addr using both tcp4 and tcp6. // // This function has the following additional features comparing to net.Dial: // // * It reduces load on DNS resolver by caching resolved TCP addressed // for DefaultDNSCacheDuration. // * It dials all the resolved TCP addresses in round-robin manner until // connection is established. This may be useful if certain addresses // are temporarily unreachable. // * It returns ErrDialTimeout if connection cannot be established during // DefaultDialTimeout seconds. Use DialDualStackTimeout for custom dial // timeout. // // This dialer is intended for custom code wrapping before passing // to Client.Dial or HostClient.Dial. // // For instance, per-host counters and/or limits may be implemented // by such wrappers. // // The addr passed to the function must contain port. Example addr values: // // * foobar.baz:443 // * foo.bar:80 // * aaa.com:8080 func DialDualStack(addr string) (net.Conn, error) { return getDialer(DefaultDialTimeout, true)(addr) } // DialDualStackTimeout dials the given TCP addr using both tcp4 and tcp6 // using the given timeout. // // This function has the following additional features comparing to net.Dial: // // * It reduces load on DNS resolver by caching resolved TCP addressed // for DefaultDNSCacheDuration. // * It dials all the resolved TCP addresses in round-robin manner until // connection is established. This may be useful if certain addresses // are temporarily unreachable. // // This dialer is intended for custom code wrapping before passing // to Client.Dial or HostClient.Dial. // // For instance, per-host counters and/or limits may be implemented // by such wrappers. // // The addr passed to the function must contain port. Example addr values: // // * foobar.baz:443 // * foo.bar:80 // * aaa.com:8080 func DialDualStackTimeout(addr string, timeout time.Duration) (net.Conn, error) { return getDialer(timeout, true)(addr) } func getDialer(timeout time.Duration, dualStack bool) DialFunc { if timeout <= 0 { timeout = DefaultDialTimeout } timeoutRounded := int(timeout.Seconds()*10 + 9) m := dialMap if dualStack { m = dialDualStackMap } dialMapLock.Lock() d := m[timeoutRounded] if d == nil { dialer := dialerStd if dualStack { dialer = dialerDualStack } d = dialer.NewDial(timeout) m[timeoutRounded] = d } dialMapLock.Unlock() return d } var ( dialerStd = &tcpDialer{} dialerDualStack = &tcpDialer{DualStack: true} dialMap = make(map[int]DialFunc) dialDualStackMap = make(map[int]DialFunc) dialMapLock sync.Mutex ) type tcpDialer struct { DualStack bool tcpAddrsLock sync.Mutex tcpAddrsMap map[string]*tcpAddrEntry concurrencyCh chan struct{} once sync.Once } const maxDialConcurrency = 1000 func (d *tcpDialer) NewDial(timeout time.Duration) DialFunc { d.once.Do(func() { d.concurrencyCh = make(chan struct{}, maxDialConcurrency) d.tcpAddrsMap = make(map[string]*tcpAddrEntry) go d.tcpAddrsClean() }) return func(addr string) (net.Conn, error) { addrs, idx, err := d.getTCPAddrs(addr) if err != nil { return nil, err } network := "tcp4" if d.DualStack { network = "tcp" } var conn net.Conn n := uint32(len(addrs)) deadline := time.Now().Add(timeout) for n > 0 { conn, err = tryDial(network, &addrs[idx%n], deadline, d.concurrencyCh) if err == nil { return conn, nil } if err == ErrDialTimeout { return nil, err } idx++ n-- } return nil, err } } func tryDial(network string, addr *net.TCPAddr, deadline time.Time, concurrencyCh chan struct{}) (net.Conn, error) { timeout := -time.Since(deadline) if timeout <= 0 { return nil, ErrDialTimeout } select { case concurrencyCh <- struct{}{}: default: tc := acquireTimer(timeout) isTimeout := false select { case concurrencyCh <- struct{}{}: case <-tc.C: isTimeout = true } releaseTimer(tc) if isTimeout { return nil, ErrDialTimeout } } timeout = -time.Since(deadline) if timeout <= 0 { <-concurrencyCh return nil, ErrDialTimeout } chv := dialResultChanPool.Get() if chv == nil { chv = make(chan dialResult, 1) } ch := chv.(chan dialResult) go func() { var dr dialResult dr.conn, dr.err = net.DialTCP(network, nil, addr) ch <- dr <-concurrencyCh }() var ( conn net.Conn err error ) tc := acquireTimer(timeout) select { case dr := <-ch: conn = dr.conn err = dr.err dialResultChanPool.Put(ch) case <-tc.C: err = ErrDialTimeout } releaseTimer(tc) return conn, err } var dialResultChanPool sync.Pool type dialResult struct { conn net.Conn err error } // ErrDialTimeout is returned when TCP dialing is timed out. var ErrDialTimeout = errors.New("dialing to the given TCP address timed out") // DefaultDialTimeout is timeout used by Dial and DialDualStack // for establishing TCP connections. const DefaultDialTimeout = 3 * time.Second type tcpAddrEntry struct { addrs []net.TCPAddr addrsIdx uint32 resolveTime time.Time pending bool } // DefaultDNSCacheDuration is the duration for caching resolved TCP addresses // by Dial* functions. const DefaultDNSCacheDuration = time.Minute func (d *tcpDialer) tcpAddrsClean() { expireDuration := 2 * DefaultDNSCacheDuration for { time.Sleep(time.Second) t := time.Now() d.tcpAddrsLock.Lock() for k, e := range d.tcpAddrsMap { if t.Sub(e.resolveTime) > expireDuration { delete(d.tcpAddrsMap, k) } } d.tcpAddrsLock.Unlock() } } func (d *tcpDialer) getTCPAddrs(addr string) ([]net.TCPAddr, uint32, error) { d.tcpAddrsLock.Lock() e := d.tcpAddrsMap[addr] if e != nil && !e.pending && time.Since(e.resolveTime) > DefaultDNSCacheDuration { e.pending = true e = nil } d.tcpAddrsLock.Unlock() if e == nil { addrs, err := resolveTCPAddrs(addr, d.DualStack) if err != nil { d.tcpAddrsLock.Lock() e = d.tcpAddrsMap[addr] if e != nil && e.pending { e.pending = false } d.tcpAddrsLock.Unlock() return nil, 0, err } e = &tcpAddrEntry{ addrs: addrs, resolveTime: time.Now(), } d.tcpAddrsLock.Lock() d.tcpAddrsMap[addr] = e d.tcpAddrsLock.Unlock() } idx := uint32(0) if len(e.addrs) > 0 { idx = atomic.AddUint32(&e.addrsIdx, 1) } return e.addrs, idx, nil } func resolveTCPAddrs(addr string, dualStack bool) ([]net.TCPAddr, error) { host, portS, err := net.SplitHostPort(addr) if err != nil { return nil, err } port, err := strconv.Atoi(portS) if err != nil { return nil, err } ips, err := net.LookupIP(host) if err != nil { return nil, err } n := len(ips) addrs := make([]net.TCPAddr, 0, n) for i := 0; i < n; i++ { ip := ips[i] if !dualStack && ip.To4() == nil { continue } addrs = append(addrs, net.TCPAddr{ IP: ip, Port: port, }) } return addrs, nil }