src/lib/net/net.go - go - Git at Google

 // Copyright 2009 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 net

 import (
 	"net";
 	"os";
 	"strconv";
 	"syscall";
 )

 var (
 	BadAddress = os.NewError("malformed address");
 	MissingAddress = os.NewError("missing address");
 	UnknownNetwork = os.NewError("unknown network");
 	UnknownHost = os.NewError("unknown host");
 	UnknownSocketFamily = os.NewError("unknown socket family");
 )

 func LookupHost(name string) (cname string, addrs []string, err os.Error)

 // Split "host:port" into "host" and "port".
 // Host cannot contain colons unless it is bracketed.
 func splitHostPort(hostport string) (host, port string, err os.Error) {
 	// The port starts after the last colon.
 	var i int;
 	for i = len(hostport)-1; i >= 0; i-- {
 		if hostport[i] == ':' {
 			break
 		}
 	}
 	if i < 0 {
 		return "", "", BadAddress
 	}

 	host = hostport[0:i];
 	port = hostport[i+1:len(hostport)];

 	// Can put brackets around host ...
 	if len(host) > 0 && host[0] == '[' && host[len(host)-1] == ']' {
 		host = host[1:len(host)-1]
 	} else {
 		// ... but if there are no brackets, no colons.
 		if byteIndex(host, ':') >= 0 {
 			return "", "", BadAddress
 		}
 	}
 	return host, port, nil
 }

 // Join "host" and "port" into "host:port".
 // If host contains colons, will join into "[host]:port".
 func joinHostPort(host, port string) string {
 	// If host has colons, have to bracket it.
 	if byteIndex(host, ':') >= 0 {
 		return "[" + host + "]:" + port
 	}
 	return host + ":" + port
 }

 // Convert "host:port" into IP address and port.
 // For now, host and port must be numeric literals.
 // Eventually, we'll have name resolution.
 func hostPortToIP(net, hostport, mode string) (ip []byte, iport int, err os.Error) {
 	var host, port string;
 	host, port, err = splitHostPort(hostport);
 	if err != nil {
 		return nil, 0, err
 	}

 	var addr []byte;
 	if host == "" {
 		if mode == "listen" {
 			addr = IPzero;	// wildcard - listen to all
 		} else {
 			return nil, 0, MissingAddress;
 		}
 	}

 	// Try as an IP address.
 	if addr == nil {
 		addr = ParseIP(host);
 	}
 	if addr == nil {
 		// Not an IP address.  Try as a DNS name.
 		hostname, addrs, err := LookupHost(host);
 		if err != nil {
 			return nil, 0, err
 		}
 		if len(addrs) == 0 {
 			return nil, 0, UnknownHost
 		}
 		addr = ParseIP(addrs[0]);
 		if addr == nil {
 			// should not happen
 			return nil, 0, BadAddress
 		}
 	}

 	p, i, ok := dtoi(port, 0);
 	if !ok || i != len(port) {
 		p, err = LookupPort(net, port);
 		if err != nil {
 			return nil, 0, err
 		}
 	}
 	if p < 0 || p > 0xFFFF {
 		return nil, 0, BadAddress
 	}

 	return addr, p, nil
 }

 // Convert socket address into "host:port".
 func sockaddrToHostPort(sa *syscall.Sockaddr) (hostport string, err os.Error) {
 	switch sa.Family {
 	case syscall.AF_INET, syscall.AF_INET6:
 		addr, port, e := sockaddrToIP(sa);
 		if e != nil {
 			return "", e
 		}
 		host := addr.String();
 		return joinHostPort(host, strconv.Itoa(port)), nil;
 	default:
 		return "", UnknownSocketFamily
 	}
 	return "", nil // not reached
 }

 // Boolean to int.
 func boolint(b bool) int {
 	if b {
 		return 1
 	}
 	return 0
 }

 // Generic socket creation.
 func socket(net, laddr, raddr string, f, p, t int64, la, ra *syscall.Sockaddr)
 	(fd *netFD, err os.Error)
 {
 	// See ../syscall/exec.go for description of ForkLock.
 	syscall.ForkLock.RLock();
 	s, e := syscall.Socket(f, p, t);
 	if e != 0 {
 		syscall.ForkLock.RUnlock();
 		return nil, os.ErrnoToError(e)
 	}
 	syscall.CloseOnExec(s);
 	syscall.ForkLock.RUnlock();

 	// Allow reuse of recently-used addresses.
 	syscall.Setsockopt_int(s, syscall.SOL_SOCKET, syscall.SO_REUSEADDR, 1);

 	var r int64;
 	if la != nil {
 		r, e = syscall.Bind(s, la);
 		if e != 0 {
 			syscall.Close(s);
 			return nil, os.ErrnoToError(e)
 		}
 	}

 	if ra != nil {
 		r, e = syscall.Connect(s, ra);
 		if e != 0 {
 			syscall.Close(s);
 			return nil, os.ErrnoToError(e)
 		}
 	}

 	fd, err = newFD(s, net, laddr, raddr);
 	if err != nil {
 		syscall.Close(s);
 		return nil, err
 	}

 	return fd, nil
 }


 // Generic implementation of Conn interface; not exported.
 type connBase struct {
 	fd *netFD;
 	raddr string;
 }

 func (c *connBase) File() *os.File {
 	if c == nil {
 		return nil
 	}
 	return c.fd.file;
 }

 func (c *connBase) sysFD() int64 {
 	if c == nil || c.fd == nil {
 		return -1;
 	}
 	return c.fd.fd;
 }

 func (c *connBase) Read(b []byte) (n int, err os.Error) {
 	n, err = c.fd.Read(b);
 	return n, err
 }

 func (c *connBase) Write(b []byte) (n int, err os.Error) {
 	n, err = c.fd.Write(b);
 	return n, err
 }

 func (c *connBase) ReadFrom(b []byte) (n int, raddr string, err os.Error) {
 	if c == nil {
 		return -1, "", os.EINVAL
 	}
 	n, err = c.Read(b);
 	return n, c.raddr, err
 }

 func (c *connBase) WriteTo(raddr string, b []byte) (n int, err os.Error) {
 	if c == nil {
 		return -1, os.EINVAL
 	}
 	if raddr != c.raddr {
 		return -1, os.EINVAL
 	}
 	n, err = c.Write(b);
 	return n, err
 }

 func (c *connBase) Close() os.Error {
 	if c == nil {
 		return os.EINVAL
 	}
 	return c.fd.Close()
 }


 func setsockopt_int(fd, level, opt int64, value int) os.Error {
 	return os.ErrnoToError(syscall.Setsockopt_int(fd, level, opt, value));
 }

 func setsockopt_tv(fd, level, opt int64, nsec int64) os.Error {
 	return os.ErrnoToError(syscall.Setsockopt_tv(fd, level, opt, nsec));
 }

 func (c *connBase) SetReadBuffer(bytes int) os.Error {
 	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_RCVBUF, bytes);
 }

 func (c *connBase) SetWriteBuffer(bytes int) os.Error {
 	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_SNDBUF, bytes);
 }

 func (c *connBase) SetReadTimeout(nsec int64) os.Error {
 	c.fd.rdeadline_delta = nsec;
 	return nil;
 }

 func (c *connBase) SetWriteTimeout(nsec int64) os.Error {
 	c.fd.wdeadline_delta = nsec;
 	return nil;
 }

 func (c *connBase) SetTimeout(nsec int64) os.Error {
 	if e := c.SetReadTimeout(nsec); e != nil {
 		return e
 	}
 	return c.SetWriteTimeout(nsec)
 }

 func (c *connBase) SetReuseAddr(reuse bool) os.Error {
 	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_REUSEADDR, boolint(reuse));
 }

 func (c *connBase) BindToDevice(dev string) os.Error {
 	// TODO(rsc): call setsockopt with null-terminated string pointer
 	return os.EINVAL
 }

 func (c *connBase) SetDontRoute(dontroute bool) os.Error {
 	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_DONTROUTE, boolint(dontroute));
 }

 func (c *connBase) SetKeepAlive(keepalive bool) os.Error {
 	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_KEEPALIVE, boolint(keepalive));
 }

 func (c *connBase) SetLinger(sec int) os.Error {
 	e := syscall.Setsockopt_linger(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_LINGER, sec);
 	return os.ErrnoToError(e);
 }


 // Internet sockets (TCP, UDP)

 // Should we try to use the IPv4 socket interface if we're
 // only dealing with IPv4 sockets?  As long as the host system
 // understands IPv6, it's okay to pass IPv4 addresses to the IPv6
 // interface.  That simplifies our code and is most general.
 // If we need to build on a system without IPv6 support, setting
 // preferIPv4 here should fall back to the IPv4 socket interface when possible.
 const preferIPv4 = false

 func internetSocket(net, laddr, raddr string, proto int64, mode string)
 	(fd *netFD, err os.Error)
 {
 	// Parse addresses (unless they are empty).
 	var lip, rip IP;
 	var lport, rport int;
 	var lerr, rerr os.Error;

 	if laddr != "" {
 		lip, lport, lerr = hostPortToIP(net, laddr, mode);
 		if lerr != nil {
 			return nil, lerr
 		}
 	}
 	if raddr != "" {
 		rip, rport, rerr = hostPortToIP(net, raddr, mode);
 		if rerr != nil {
 			return nil, rerr
 		}
 	}

 	// Figure out IP version.
 	// If network has a suffix like "tcp4", obey it.
 	vers := 0;
 	switch net[len(net)-1] {
 	case '4':
 		vers = 4;
 	case '6':
 		vers = 6;
 	default:
 		// Otherwise, guess.
 		// If the addresses are IPv4 and we prefer IPv4, use 4; else 6.
 		if preferIPv4 && lip.To4() != nil && rip.To4() != nil {
 			vers = 4
 		} else {
 			vers = 6
 		}
 	}

 	var cvt func(addr []byte, port int) (sa *syscall.Sockaddr, err os.Error);
 	var family int64;
 	if vers == 4 {
 		cvt = v4ToSockaddr;
 		family = syscall.AF_INET
 	} else {
 		cvt = v6ToSockaddr;
 		family = syscall.AF_INET6
 	}

 	var la, ra *syscall.Sockaddr;
 	if lip != nil {
 		la, lerr = cvt(lip, lport);
 		if lerr != nil {
 			return nil, lerr
 		}
 	}
 	if rip != nil {
 		ra, rerr = cvt(rip, rport);
 		if rerr != nil {
 			return nil, rerr
 		}
 	}

 	fd, err = socket(net, laddr, raddr, family, proto, 0, la, ra);
 	return fd, err
 }


 // TCP connections.

 type ConnTCP struct {
 	connBase
 }

 func (c *ConnTCP) SetNoDelay(nodelay bool) os.Error {
 	if c == nil {
 		return os.EINVAL
 	}
 	return setsockopt_int(c.sysFD(), syscall.IPPROTO_TCP, syscall.TCP_NODELAY, boolint(nodelay))
 }

 func newConnTCP(fd *netFD, raddr string) *ConnTCP {
 	c := new(ConnTCP);
 	c.fd = fd;
 	c.raddr = raddr;
 	c.SetNoDelay(true);
 	return c
 }

 func DialTCP(net, laddr, raddr string) (c *ConnTCP, err os.Error) {
 	if raddr == "" {
 		return nil, MissingAddress
 	}
 	fd, e := internetSocket(net, laddr, raddr, syscall.SOCK_STREAM, "dial");
 	if e != nil {
 		return nil, e
 	}
 	return newConnTCP(fd, raddr), nil
 }


 // UDP connections.

 // TODO(rsc): UDP headers mode

 type ConnUDP struct {
 	connBase
 }

 func newConnUDP(fd *netFD, raddr string) *ConnUDP {
 	c := new(ConnUDP);
 	c.fd = fd;
 	c.raddr = raddr;
 	return c
 }

 func DialUDP(net, laddr, raddr string) (c *ConnUDP, err os.Error) {
 	if raddr == "" {
 		return nil, MissingAddress
 	}
 	fd, e := internetSocket(net, laddr, raddr, syscall.SOCK_DGRAM, "dial");
 	if e != nil {
 		return nil, e
 	}
 	return newConnUDP(fd, raddr), nil
 }


 // TODO: raw IP connections

 // TODO: raw ethernet connections

 // A Conn is a generic network connection.
 type Conn interface {
 	// Read blocks until data is ready from the connection
 	// and then reads into b.  It returns the number
 	// of bytes read, or 0 if the connection has been closed.
 	Read(b []byte) (n int, err os.Error);

 	// Write writes the data in b to the connection.
 	Write(b []byte) (n int, err os.Error);

 	// Close closes the connection.
 	Close() os.Error;

 	// For packet-based protocols such as UDP,
 	// ReadFrom reads the next packet from the network,
 	// returning the number of bytes read and the remote
 	// address that sent them.
 	ReadFrom(b []byte) (n int, addr string, err os.Error);

 	// For packet-based protocols such as UDP,
 	// WriteTo writes the byte buffer b to the network
 	// as a single payload, sending it to the target address.
 	WriteTo(addr string, b []byte) (n int, err os.Error);

 	// SetReadBuffer sets the size of the operating system's
 	// receive buffer associated with the connection.
 	SetReadBuffer(bytes int) os.Error;

 	// SetReadBuffer sets the size of the operating system's
 	// transmit buffer associated with the connection.
 	SetWriteBuffer(bytes int) os.Error;

 	// SetTimeout sets the read and write deadlines associated
 	// with the connection.
 	SetTimeout(nsec int64) os.Error;

 	// SetReadTimeout sets the time (in nanoseconds) that
 	// Read will wait for data before returning os.EAGAIN.
 	// Setting nsec == 0 (the default) disables the deadline.
 	SetReadTimeout(nsec int64) os.Error;

 	// SetWriteTimeout sets the time (in nanoseconds) that
 	// Write will wait to send its data before returning os.EAGAIN.
 	// Setting nsec == 0 (the default) disables the deadline.
 	// Even if write times out, it may return n > 0, indicating that
 	// some of the data was successfully written.
 	SetWriteTimeout(nsec int64) os.Error;

 	// SetLinger sets the behavior of Close() on a connection
 	// which still has data waiting to be sent or to be acknowledged.
 	//
 	// If sec < 0 (the default), Close returns immediately and
 	// the operating system finishes sending the data in the background.
 	//
 	// If sec == 0, Close returns immediately and the operating system
 	// discards any unsent or unacknowledged data.
 	//
 	// If sec > 0, Close blocks for at most sec seconds waiting for
 	// data to be sent and acknowledged.
 	SetLinger(sec int) os.Error;

 	// SetReuseAddr sets whether it is okay to reuse addresses
 	// from recent connections that were not properly closed.
 	SetReuseAddr(reuseaddr bool) os.Error;

 	// SetDontRoute sets whether outgoing messages should
 	// bypass the system routing tables.
 	SetDontRoute(dontroute bool) os.Error;

 	// SetKeepAlive sets whether the operating system should send
 	// keepalive messages on the connection.
 	SetKeepAlive(keepalive bool) os.Error;

 	// BindToDevice binds a connection to a particular network device.
 	BindToDevice(dev string) os.Error;
 }

 // Dial connects to the remote address raddr on the network net.
 // If the string laddr is not empty, it is used as the local address
 // for the connection.
 //
 // Known networks are "tcp", "tcp4" (IPv4-only), "tcp6" (IPv6-only),
 // "udp", "udp4" (IPv4-only), and "udp6" (IPv6-only).
 //
 // For IP networks, addresses have the form host:port.  If host is
 // a literal IPv6 address, it must be enclosed in square brackets.
 //
 // Examples:
 //	Dial("tcp", "", "12.34.56.78:80")
 //	Dial("tcp", "", "google.com:80")
 //	Dial("tcp", "", "[de:ad:be:ef::ca:fe]:80")
 //	Dial("tcp", "127.0.0.1:123", "127.0.0.1:88")
 func Dial(net, laddr, raddr string) (c Conn, err os.Error) {
 	switch net {
 	case "tcp", "tcp4", "tcp6":
 		c, err := DialTCP(net, laddr, raddr);
 		if err != nil {
 			return nil, err
 		}
 		return c, nil;
 	case "udp", "udp4", "upd6":
 		c, err := DialUDP(net, laddr, raddr);
 		return c, err;
 /*
 	case "ether":
 		c, err := DialEther(net, laddr, raddr);
 		return c, err;
 	case "ipv4":
 		c, err := DialIPv4(net, laddr, raddr);
 		return c, err;
 	case "ipv6":
 		c, err := DialIPv6(net, laddr, raddr);
 		return c, err
 */
 	}
 	return nil, UnknownNetwork
 }

 // A Listener is a generic network listener.
 // Accept waits for the next connection and Close closes the connection.
 type Listener interface {
 	Accept() (c Conn, raddr string, err os.Error);
 	Close() os.Error;
 }

 // ListenerTCP is a TCP network listener.
 // Clients should typically use variables of type Listener
 // instead of assuming TCP.
 type ListenerTCP struct {
 	fd *netFD;
 	laddr string
 }

 // ListenTCP announces on the TCP address laddr and returns a TCP listener.
 // Net must be "tcp", "tcp4", or "tcp6".
 func ListenTCP(net, laddr string) (l *ListenerTCP, err os.Error) {
 	fd, e := internetSocket(net, laddr, "", syscall.SOCK_STREAM, "listen");
 	if e != nil {
 		return nil, e
 	}
 	r, e1 := syscall.Listen(fd.fd, listenBacklog());
 	if e1 != 0 {
 		syscall.Close(fd.fd);
 		return nil, os.ErrnoToError(e1)
 	}
 	l = new(ListenerTCP);
 	l.fd = fd;
 	return l, nil
 }

 // AcceptTCP accepts the next incoming call and returns the new connection
 // and the remote address.
 func (l *ListenerTCP) AcceptTCP() (c *ConnTCP, raddr string, err os.Error) {
 	if l == nil || l.fd == nil || l.fd.fd < 0 {
 		return nil, "", os.EINVAL
 	}
 	var sa syscall.Sockaddr;
 	fd, e := l.fd.Accept(&sa);
 	if e != nil {
 		return nil, "", e
 	}
 	raddr, err = sockaddrToHostPort(&sa);
 	if err != nil {
 		fd.Close();
 		return nil, "", err
 	}
 	return newConnTCP(fd, raddr), raddr, nil
 }

 // Accept implements the accept method in the Listener interface;
 // it waits for the next call and returns a generic Conn.
 func (l *ListenerTCP) Accept() (c Conn, raddr string, err os.Error) {
 	c1, r1, e1 := l.AcceptTCP();
 	if e1 != nil {
 		return nil, "", e1
 	}
 	return c1, r1, nil
 }

 // Close stops listening on the TCP address.
 // Already Accepted connections are not closed.
 func (l *ListenerTCP) Close() os.Error {
 	if l == nil || l.fd == nil {
 		return os.EINVAL
 	}
 	return l.fd.Close()
 }

 // Listen announces on the local network address laddr.
 // The network string net must be "tcp", "tcp4", or "tcp6".
 func Listen(net, laddr string) (l Listener, err os.Error) {
 	switch net {
 	case "tcp", "tcp4", "tcp6":
 		l, err := ListenTCP(net, laddr);
 		if err != nil {
 			return nil, err
 		}
 		return l, nil
 /*
 	more here
 */
 	// BUG(rsc): Listen should support UDP.
 	}
 	return nil, UnknownNetwork
 }
	// Copyright 2009 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 net

	import (
	"net";
	"os";
	"strconv";
	"syscall";
	)

	var (
	BadAddress = os.NewError("malformed address");
	MissingAddress = os.NewError("missing address");
	UnknownNetwork = os.NewError("unknown network");
	UnknownHost = os.NewError("unknown host");
	UnknownSocketFamily = os.NewError("unknown socket family");
	)

	func LookupHost(name string) (cname string, addrs []string, err os.Error)

	// Split "host:port" into "host" and "port".
	// Host cannot contain colons unless it is bracketed.
	func splitHostPort(hostport string) (host, port string, err os.Error) {
	// The port starts after the last colon.
	var i int;
	for i = len(hostport)-1; i >= 0; i-- {
	if hostport[i] == ':' {
	break
	}
	}
	if i < 0 {
	return "", "", BadAddress
	}

	host = hostport[0:i];
	port = hostport[i+1:len(hostport)];

	// Can put brackets around host ...
	if len(host) > 0 && host[0] == '[' && host[len(host)-1] == ']' {
	host = host[1:len(host)-1]
	} else {
	// ... but if there are no brackets, no colons.
	if byteIndex(host, ':') >= 0 {
	return "", "", BadAddress
	}
	}
	return host, port, nil
	}

	// Join "host" and "port" into "host:port".
	// If host contains colons, will join into "[host]:port".
	func joinHostPort(host, port string) string {
	// If host has colons, have to bracket it.
	if byteIndex(host, ':') >= 0 {
	return "[" + host + "]:" + port
	}
	return host + ":" + port
	}

	// Convert "host:port" into IP address and port.
	// For now, host and port must be numeric literals.
	// Eventually, we'll have name resolution.
	func hostPortToIP(net, hostport, mode string) (ip []byte, iport int, err os.Error) {
	var host, port string;
	host, port, err = splitHostPort(hostport);
	if err != nil {
	return nil, 0, err
	}

	var addr []byte;
	if host == "" {
	if mode == "listen" {
	addr = IPzero; // wildcard - listen to all
	} else {
	return nil, 0, MissingAddress;
	}
	}

	// Try as an IP address.
	if addr == nil {
	addr = ParseIP(host);
	}
	if addr == nil {
	// Not an IP address. Try as a DNS name.
	hostname, addrs, err := LookupHost(host);
	if err != nil {
	return nil, 0, err
	}
	if len(addrs) == 0 {
	return nil, 0, UnknownHost
	}
	addr = ParseIP(addrs[0]);
	if addr == nil {
	// should not happen
	return nil, 0, BadAddress
	}
	}

	p, i, ok := dtoi(port, 0);
	if !ok \|\| i != len(port) {
	p, err = LookupPort(net, port);
	if err != nil {
	return nil, 0, err
	}
	}
	if p < 0 \|\| p > 0xFFFF {
	return nil, 0, BadAddress
	}

	return addr, p, nil
	}

	// Convert socket address into "host:port".
	func sockaddrToHostPort(sa *syscall.Sockaddr) (hostport string, err os.Error) {
	switch sa.Family {
	case syscall.AF_INET, syscall.AF_INET6:
	addr, port, e := sockaddrToIP(sa);
	if e != nil {
	return "", e
	}
	host := addr.String();
	return joinHostPort(host, strconv.Itoa(port)), nil;
	default:
	return "", UnknownSocketFamily
	}
	return "", nil // not reached
	}

	// Boolean to int.
	func boolint(b bool) int {
	if b {
	return 1
	}
	return 0
	}

	// Generic socket creation.
	func socket(net, laddr, raddr string, f, p, t int64, la, ra *syscall.Sockaddr)
	(fd *netFD, err os.Error)
	{
	// See ../syscall/exec.go for description of ForkLock.
	syscall.ForkLock.RLock();
	s, e := syscall.Socket(f, p, t);
	if e != 0 {
	syscall.ForkLock.RUnlock();
	return nil, os.ErrnoToError(e)
	}
	syscall.CloseOnExec(s);
	syscall.ForkLock.RUnlock();

	// Allow reuse of recently-used addresses.
	syscall.Setsockopt_int(s, syscall.SOL_SOCKET, syscall.SO_REUSEADDR, 1);

	var r int64;
	if la != nil {
	r, e = syscall.Bind(s, la);
	if e != 0 {
	syscall.Close(s);
	return nil, os.ErrnoToError(e)
	}
	}

	if ra != nil {
	r, e = syscall.Connect(s, ra);
	if e != 0 {
	syscall.Close(s);
	return nil, os.ErrnoToError(e)
	}
	}

	fd, err = newFD(s, net, laddr, raddr);
	if err != nil {
	syscall.Close(s);
	return nil, err
	}

	return fd, nil
	}


	// Generic implementation of Conn interface; not exported.
	type connBase struct {
	fd *netFD;
	raddr string;
	}

	func (c connBase) File() os.File {
	if c == nil {
	return nil
	}
	return c.fd.file;
	}

	func (c *connBase) sysFD() int64 {
	if c == nil \|\| c.fd == nil {
	return -1;
	}
	return c.fd.fd;
	}

	func (c *connBase) Read(b []byte) (n int, err os.Error) {
	n, err = c.fd.Read(b);
	return n, err
	}

	func (c *connBase) Write(b []byte) (n int, err os.Error) {
	n, err = c.fd.Write(b);
	return n, err
	}

	func (c *connBase) ReadFrom(b []byte) (n int, raddr string, err os.Error) {
	if c == nil {
	return -1, "", os.EINVAL
	}
	n, err = c.Read(b);
	return n, c.raddr, err
	}

	func (c *connBase) WriteTo(raddr string, b []byte) (n int, err os.Error) {
	if c == nil {
	return -1, os.EINVAL
	}
	if raddr != c.raddr {
	return -1, os.EINVAL
	}
	n, err = c.Write(b);
	return n, err
	}

	func (c *connBase) Close() os.Error {
	if c == nil {
	return os.EINVAL
	}
	return c.fd.Close()
	}


	func setsockopt_int(fd, level, opt int64, value int) os.Error {
	return os.ErrnoToError(syscall.Setsockopt_int(fd, level, opt, value));
	}

	func setsockopt_tv(fd, level, opt int64, nsec int64) os.Error {
	return os.ErrnoToError(syscall.Setsockopt_tv(fd, level, opt, nsec));
	}

	func (c *connBase) SetReadBuffer(bytes int) os.Error {
	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_RCVBUF, bytes);
	}

	func (c *connBase) SetWriteBuffer(bytes int) os.Error {
	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_SNDBUF, bytes);
	}

	func (c *connBase) SetReadTimeout(nsec int64) os.Error {
	c.fd.rdeadline_delta = nsec;
	return nil;
	}

	func (c *connBase) SetWriteTimeout(nsec int64) os.Error {
	c.fd.wdeadline_delta = nsec;
	return nil;
	}

	func (c *connBase) SetTimeout(nsec int64) os.Error {
	if e := c.SetReadTimeout(nsec); e != nil {
	return e
	}
	return c.SetWriteTimeout(nsec)
	}

	func (c *connBase) SetReuseAddr(reuse bool) os.Error {
	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_REUSEADDR, boolint(reuse));
	}

	func (c *connBase) BindToDevice(dev string) os.Error {
	// TODO(rsc): call setsockopt with null-terminated string pointer
	return os.EINVAL
	}

	func (c *connBase) SetDontRoute(dontroute bool) os.Error {
	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_DONTROUTE, boolint(dontroute));
	}

	func (c *connBase) SetKeepAlive(keepalive bool) os.Error {
	return setsockopt_int(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_KEEPALIVE, boolint(keepalive));
	}

	func (c *connBase) SetLinger(sec int) os.Error {
	e := syscall.Setsockopt_linger(c.sysFD(), syscall.SOL_SOCKET, syscall.SO_LINGER, sec);
	return os.ErrnoToError(e);
	}


	// Internet sockets (TCP, UDP)

	// Should we try to use the IPv4 socket interface if we're
	// only dealing with IPv4 sockets? As long as the host system
	// understands IPv6, it's okay to pass IPv4 addresses to the IPv6
	// interface. That simplifies our code and is most general.
	// If we need to build on a system without IPv6 support, setting
	// preferIPv4 here should fall back to the IPv4 socket interface when possible.
	const preferIPv4 = false

	func internetSocket(net, laddr, raddr string, proto int64, mode string)
	(fd *netFD, err os.Error)
	{
	// Parse addresses (unless they are empty).
	var lip, rip IP;
	var lport, rport int;
	var lerr, rerr os.Error;

	if laddr != "" {
	lip, lport, lerr = hostPortToIP(net, laddr, mode);
	if lerr != nil {
	return nil, lerr
	}
	}
	if raddr != "" {
	rip, rport, rerr = hostPortToIP(net, raddr, mode);
	if rerr != nil {
	return nil, rerr
	}
	}

	// Figure out IP version.
	// If network has a suffix like "tcp4", obey it.
	vers := 0;
	switch net[len(net)-1] {
	case '4':
	vers = 4;
	case '6':
	vers = 6;
	default:
	// Otherwise, guess.
	// If the addresses are IPv4 and we prefer IPv4, use 4; else 6.
	if preferIPv4 && lip.To4() != nil && rip.To4() != nil {
	vers = 4
	} else {
	vers = 6
	}
	}

	var cvt func(addr []byte, port int) (sa *syscall.Sockaddr, err os.Error);
	var family int64;
	if vers == 4 {
	cvt = v4ToSockaddr;
	family = syscall.AF_INET
	} else {
	cvt = v6ToSockaddr;
	family = syscall.AF_INET6
	}

	var la, ra *syscall.Sockaddr;
	if lip != nil {
	la, lerr = cvt(lip, lport);
	if lerr != nil {
	return nil, lerr
	}
	}
	if rip != nil {
	ra, rerr = cvt(rip, rport);
	if rerr != nil {
	return nil, rerr
	}
	}

	fd, err = socket(net, laddr, raddr, family, proto, 0, la, ra);
	return fd, err
	}


	// TCP connections.

	type ConnTCP struct {
	connBase
	}

	func (c *ConnTCP) SetNoDelay(nodelay bool) os.Error {
	if c == nil {
	return os.EINVAL
	}
	return setsockopt_int(c.sysFD(), syscall.IPPROTO_TCP, syscall.TCP_NODELAY, boolint(nodelay))
	}

	func newConnTCP(fd netFD, raddr string) ConnTCP {
	c := new(ConnTCP);
	c.fd = fd;
	c.raddr = raddr;
	c.SetNoDelay(true);
	return c
	}

	func DialTCP(net, laddr, raddr string) (c *ConnTCP, err os.Error) {
	if raddr == "" {
	return nil, MissingAddress
	}
	fd, e := internetSocket(net, laddr, raddr, syscall.SOCK_STREAM, "dial");
	if e != nil {
	return nil, e
	}
	return newConnTCP(fd, raddr), nil
	}


	// UDP connections.

	// TODO(rsc): UDP headers mode

	type ConnUDP struct {
	connBase
	}

	func newConnUDP(fd netFD, raddr string) ConnUDP {
	c := new(ConnUDP);
	c.fd = fd;
	c.raddr = raddr;
	return c
	}

	func DialUDP(net, laddr, raddr string) (c *ConnUDP, err os.Error) {
	if raddr == "" {
	return nil, MissingAddress
	}
	fd, e := internetSocket(net, laddr, raddr, syscall.SOCK_DGRAM, "dial");
	if e != nil {
	return nil, e
	}
	return newConnUDP(fd, raddr), nil
	}


	// TODO: raw IP connections

	// TODO: raw ethernet connections

	// A Conn is a generic network connection.
	type Conn interface {
	// Read blocks until data is ready from the connection
	// and then reads into b. It returns the number
	// of bytes read, or 0 if the connection has been closed.
	Read(b []byte) (n int, err os.Error);

	// Write writes the data in b to the connection.
	Write(b []byte) (n int, err os.Error);

	// Close closes the connection.
	Close() os.Error;

	// For packet-based protocols such as UDP,
	// ReadFrom reads the next packet from the network,
	// returning the number of bytes read and the remote
	// address that sent them.
	ReadFrom(b []byte) (n int, addr string, err os.Error);

	// For packet-based protocols such as UDP,
	// WriteTo writes the byte buffer b to the network
	// as a single payload, sending it to the target address.
	WriteTo(addr string, b []byte) (n int, err os.Error);

	// SetReadBuffer sets the size of the operating system's
	// receive buffer associated with the connection.
	SetReadBuffer(bytes int) os.Error;

	// SetReadBuffer sets the size of the operating system's
	// transmit buffer associated with the connection.
	SetWriteBuffer(bytes int) os.Error;

	// SetTimeout sets the read and write deadlines associated
	// with the connection.
	SetTimeout(nsec int64) os.Error;

	// SetReadTimeout sets the time (in nanoseconds) that
	// Read will wait for data before returning os.EAGAIN.
	// Setting nsec == 0 (the default) disables the deadline.
	SetReadTimeout(nsec int64) os.Error;

	// SetWriteTimeout sets the time (in nanoseconds) that
	// Write will wait to send its data before returning os.EAGAIN.
	// Setting nsec == 0 (the default) disables the deadline.
	// Even if write times out, it may return n > 0, indicating that
	// some of the data was successfully written.
	SetWriteTimeout(nsec int64) os.Error;

	// SetLinger sets the behavior of Close() on a connection
	// which still has data waiting to be sent or to be acknowledged.
	//
	// If sec < 0 (the default), Close returns immediately and
	// the operating system finishes sending the data in the background.
	//
	// If sec == 0, Close returns immediately and the operating system
	// discards any unsent or unacknowledged data.
	//
	// If sec > 0, Close blocks for at most sec seconds waiting for
	// data to be sent and acknowledged.
	SetLinger(sec int) os.Error;

	// SetReuseAddr sets whether it is okay to reuse addresses
	// from recent connections that were not properly closed.
	SetReuseAddr(reuseaddr bool) os.Error;

	// SetDontRoute sets whether outgoing messages should
	// bypass the system routing tables.
	SetDontRoute(dontroute bool) os.Error;

	// SetKeepAlive sets whether the operating system should send
	// keepalive messages on the connection.
	SetKeepAlive(keepalive bool) os.Error;

	// BindToDevice binds a connection to a particular network device.
	BindToDevice(dev string) os.Error;
	}

	// Dial connects to the remote address raddr on the network net.
	// If the string laddr is not empty, it is used as the local address
	// for the connection.
	//
	// Known networks are "tcp", "tcp4" (IPv4-only), "tcp6" (IPv6-only),
	// "udp", "udp4" (IPv4-only), and "udp6" (IPv6-only).
	//
	// For IP networks, addresses have the form host:port. If host is
	// a literal IPv6 address, it must be enclosed in square brackets.
	//
	// Examples:
	// Dial("tcp", "", "12.34.56.78:80")
	// Dial("tcp", "", "google.com:80")
	// Dial("tcp", "", "[de:ad:be:ef::ca:fe]:80")
	// Dial("tcp", "127.0.0.1:123", "127.0.0.1:88")
	func Dial(net, laddr, raddr string) (c Conn, err os.Error) {
	switch net {
	case "tcp", "tcp4", "tcp6":
	c, err := DialTCP(net, laddr, raddr);
	if err != nil {
	return nil, err
	}
	return c, nil;
	case "udp", "udp4", "upd6":
	c, err := DialUDP(net, laddr, raddr);
	return c, err;
	/*
	case "ether":
	c, err := DialEther(net, laddr, raddr);
	return c, err;
	case "ipv4":
	c, err := DialIPv4(net, laddr, raddr);
	return c, err;
	case "ipv6":
	c, err := DialIPv6(net, laddr, raddr);
	return c, err
	*/
	}
	return nil, UnknownNetwork
	}

	// A Listener is a generic network listener.
	// Accept waits for the next connection and Close closes the connection.
	type Listener interface {
	Accept() (c Conn, raddr string, err os.Error);
	Close() os.Error;
	}

	// ListenerTCP is a TCP network listener.
	// Clients should typically use variables of type Listener
	// instead of assuming TCP.
	type ListenerTCP struct {
	fd *netFD;
	laddr string
	}

	// ListenTCP announces on the TCP address laddr and returns a TCP listener.
	// Net must be "tcp", "tcp4", or "tcp6".
	func ListenTCP(net, laddr string) (l *ListenerTCP, err os.Error) {
	fd, e := internetSocket(net, laddr, "", syscall.SOCK_STREAM, "listen");
	if e != nil {
	return nil, e
	}
	r, e1 := syscall.Listen(fd.fd, listenBacklog());
	if e1 != 0 {
	syscall.Close(fd.fd);
	return nil, os.ErrnoToError(e1)
	}
	l = new(ListenerTCP);
	l.fd = fd;
	return l, nil
	}

	// AcceptTCP accepts the next incoming call and returns the new connection
	// and the remote address.
	func (l ListenerTCP) AcceptTCP() (c ConnTCP, raddr string, err os.Error) {
	if l == nil \|\| l.fd == nil \|\| l.fd.fd < 0 {
	return nil, "", os.EINVAL
	}
	var sa syscall.Sockaddr;
	fd, e := l.fd.Accept(&sa);
	if e != nil {
	return nil, "", e
	}
	raddr, err = sockaddrToHostPort(&sa);
	if err != nil {
	fd.Close();
	return nil, "", err
	}
	return newConnTCP(fd, raddr), raddr, nil
	}

	// Accept implements the accept method in the Listener interface;
	// it waits for the next call and returns a generic Conn.
	func (l *ListenerTCP) Accept() (c Conn, raddr string, err os.Error) {
	c1, r1, e1 := l.AcceptTCP();
	if e1 != nil {
	return nil, "", e1
	}
	return c1, r1, nil
	}

	// Close stops listening on the TCP address.
	// Already Accepted connections are not closed.
	func (l *ListenerTCP) Close() os.Error {
	if l == nil \|\| l.fd == nil {
	return os.EINVAL
	}
	return l.fd.Close()
	}

	// Listen announces on the local network address laddr.
	// The network string net must be "tcp", "tcp4", or "tcp6".
	func Listen(net, laddr string) (l Listener, err os.Error) {
	switch net {
	case "tcp", "tcp4", "tcp6":
	l, err := ListenTCP(net, laddr);
	if err != nil {
	return nil, err
	}
	return l, nil
	/*
	more here
	*/
	// BUG(rsc): Listen should support UDP.
	}
	return nil, UnknownNetwork
	}