package tcp import ( "context" "net" "time" logging "github.com/ipfs/go-log" "github.com/libp2p/go-libp2p-core/peer" "github.com/libp2p/go-libp2p-core/transport" tptu "github.com/libp2p/go-libp2p-transport-upgrader" rtpt "github.com/libp2p/go-reuseport-transport" ma "github.com/multiformats/go-multiaddr" mafmt "github.com/multiformats/go-multiaddr-fmt" manet "github.com/multiformats/go-multiaddr-net" ) // DefaultConnectTimeout is the (default) maximum amount of time the TCP // transport will spend on the initial TCP connect before giving up. var DefaultConnectTimeout = 5 * time.Second var log = logging.Logger("tcp-tpt") // try to set linger on the connection, if possible. func tryLinger(conn net.Conn, sec int) { type canLinger interface { SetLinger(int) error } if lingerConn, ok := conn.(canLinger); ok { _ = lingerConn.SetLinger(sec) } } type lingerListener struct { manet.Listener sec int } func (ll *lingerListener) Accept() (manet.Conn, error) { c, err := ll.Listener.Accept() if err != nil { return nil, err } tryLinger(c, ll.sec) return c, nil } // TcpTransport is the TCP transport. type TcpTransport struct { // Connection upgrader for upgrading insecure stream connections to // secure multiplex connections. Upgrader *tptu.Upgrader // Explicitly disable reuseport. DisableReuseport bool // TCP connect timeout ConnectTimeout time.Duration reuse rtpt.Transport } var _ transport.Transport = &TcpTransport{} // NewTCPTransport creates a tcp transport object that tracks dialers and listeners // created. It represents an entire tcp stack (though it might not necessarily be) func NewTCPTransport(upgrader *tptu.Upgrader) *TcpTransport { return &TcpTransport{Upgrader: upgrader, ConnectTimeout: DefaultConnectTimeout} } // CanDial returns true if this transport believes it can dial the given // multiaddr. func (t *TcpTransport) CanDial(addr ma.Multiaddr) bool { return mafmt.TCP.Matches(addr) } func (t *TcpTransport) maDial(ctx context.Context, raddr ma.Multiaddr) (manet.Conn, error) { // Apply the deadline iff applicable if t.ConnectTimeout > 0 { deadline := time.Now().Add(t.ConnectTimeout) if d, ok := ctx.Deadline(); !ok || deadline.Before(d) { var cancel func() ctx, cancel = context.WithDeadline(ctx, deadline) defer cancel() } } if t.UseReuseport() { return t.reuse.DialContext(ctx, raddr) } var d manet.Dialer return d.DialContext(ctx, raddr) } // Dial dials the peer at the remote address. func (t *TcpTransport) Dial(ctx context.Context, raddr ma.Multiaddr, p peer.ID) (transport.CapableConn, error) { conn, err := t.maDial(ctx, raddr) if err != nil { return nil, err } // Set linger to 0 so we never get stuck in the TIME-WAIT state. When // linger is 0, connections are _reset_ instead of closed with a FIN. // This means we can immediately reuse the 5-tuple and reconnect. tryLinger(conn, 0) return t.Upgrader.UpgradeOutbound(ctx, t, conn, p) } // UseReuseport returns true if reuseport is enabled and available. func (t *TcpTransport) UseReuseport() bool { return !t.DisableReuseport && ReuseportIsAvailable() } func (t *TcpTransport) maListen(laddr ma.Multiaddr) (manet.Listener, error) { if t.UseReuseport() { return t.reuse.Listen(laddr) } return manet.Listen(laddr) } // Listen listens on the given multiaddr. func (t *TcpTransport) Listen(laddr ma.Multiaddr) (transport.Listener, error) { list, err := t.maListen(laddr) if err != nil { return nil, err } list = &lingerListener{list, 0} return t.Upgrader.UpgradeListener(t, list), nil } // Protocols returns the list of terminal protocols this transport can dial. func (t *TcpTransport) Protocols() []int { return []int{ma.P_TCP} } // Proxy always returns false for the TCP transport. func (t *TcpTransport) Proxy() bool { return false } func (t *TcpTransport) String() string { return "TCP" }