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

 // 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 net

 import (
 	"os"
 	"syscall"
 	"unsafe"
 )

 // If the ifindex is zero, interfaceTable returns mappings of all
 // network interfaces. Otherwise it returns a mapping of a specific
 // interface.
 func interfaceTable(ifindex int) ([]Interface, error) {
 	tab, err := syscall.NetlinkRIB(syscall.RTM_GETLINK, syscall.AF_UNSPEC)
 	if err != nil {
 		return nil, os.NewSyscallError("netlinkrib", err)
 	}
 	msgs, err := syscall.ParseNetlinkMessage(tab)
 	if err != nil {
 		return nil, os.NewSyscallError("parsenetlinkmessage", err)
 	}
 	var ift []Interface
 loop:
 	for _, m := range msgs {
 		switch m.Header.Type {
 		case syscall.NLMSG_DONE:
 			break loop
 		case syscall.RTM_NEWLINK:
 			ifim := (*syscall.IfInfomsg)(unsafe.Pointer(&m.Data[0]))
 			if ifindex == 0 || ifindex == int(ifim.Index) {
 				attrs, err := syscall.ParseNetlinkRouteAttr(&m)
 				if err != nil {
 					return nil, os.NewSyscallError("parsenetlinkrouteattr", err)
 				}
 				ift = append(ift, *newLink(ifim, attrs))
 				if ifindex == int(ifim.Index) {
 					break loop
 				}
 			}
 		}
 	}
 	return ift, nil
 }

 const (
 	// See linux/if_arp.h.
 	// Note that Linux doesn't support IPv4 over IPv6 tunneling.
 	sysARPHardwareIPv4IPv4 = 768 // IPv4 over IPv4 tunneling
 	sysARPHardwareIPv6IPv6 = 769 // IPv6 over IPv6 tunneling
 	sysARPHardwareIPv6IPv4 = 776 // IPv6 over IPv4 tunneling
 	sysARPHardwareGREIPv4  = 778 // any over GRE over IPv4 tunneling
 	sysARPHardwareGREIPv6  = 823 // any over GRE over IPv6 tunneling
 )

 func newLink(ifim *syscall.IfInfomsg, attrs []syscall.NetlinkRouteAttr) *Interface {
 	ifi := &Interface{Index: int(ifim.Index), Flags: linkFlags(ifim.Flags)}
 	for _, a := range attrs {
 		switch a.Attr.Type {
 		case syscall.IFLA_ADDRESS:
 			// We never return any /32 or /128 IP address
 			// prefix on any IP tunnel interface as the
 			// hardware address.
 			switch len(a.Value) {
 			case IPv4len:
 				switch ifim.Type {
 				case sysARPHardwareIPv4IPv4, sysARPHardwareGREIPv4, sysARPHardwareIPv6IPv4:
 					continue
 				}
 			case IPv6len:
 				switch ifim.Type {
 				case sysARPHardwareIPv6IPv6, sysARPHardwareGREIPv6:
 					continue
 				}
 			}
 			var nonzero bool
 			for _, b := range a.Value {
 				if b != 0 {
 					nonzero = true
 					break
 				}
 			}
 			if nonzero {
 				ifi.HardwareAddr = a.Value[:]
 			}
 		case syscall.IFLA_IFNAME:
 			ifi.Name = string(a.Value[:len(a.Value)-1])
 		case syscall.IFLA_MTU:
 			ifi.MTU = int(*(*uint32)(unsafe.Pointer(&a.Value[:4][0])))
 		}
 	}
 	return ifi
 }

 func linkFlags(rawFlags uint32) Flags {
 	var f Flags
 	if rawFlags&syscall.IFF_UP != 0 {
 		f |= FlagUp
 	}
 	if rawFlags&syscall.IFF_RUNNING != 0 {
 		f |= FlagRunning
 	}
 	if rawFlags&syscall.IFF_BROADCAST != 0 {
 		f |= FlagBroadcast
 	}
 	if rawFlags&syscall.IFF_LOOPBACK != 0 {
 		f |= FlagLoopback
 	}
 	if rawFlags&syscall.IFF_POINTOPOINT != 0 {
 		f |= FlagPointToPoint
 	}
 	if rawFlags&syscall.IFF_MULTICAST != 0 {
 		f |= FlagMulticast
 	}
 	return f
 }

 // If the ifi is nil, interfaceAddrTable returns addresses for all
 // network interfaces. Otherwise it returns addresses for a specific
 // interface.
 func interfaceAddrTable(ifi *Interface) ([]Addr, error) {
 	tab, err := syscall.NetlinkRIB(syscall.RTM_GETADDR, syscall.AF_UNSPEC)
 	if err != nil {
 		return nil, os.NewSyscallError("netlinkrib", err)
 	}
 	msgs, err := syscall.ParseNetlinkMessage(tab)
 	if err != nil {
 		return nil, os.NewSyscallError("parsenetlinkmessage", err)
 	}
 	var ift []Interface
 	if ifi == nil {
 		var err error
 		ift, err = interfaceTable(0)
 		if err != nil {
 			return nil, err
 		}
 	}
 	ifat, err := addrTable(ift, ifi, msgs)
 	if err != nil {
 		return nil, err
 	}
 	return ifat, nil
 }

 func addrTable(ift []Interface, ifi *Interface, msgs []syscall.NetlinkMessage) ([]Addr, error) {
 	var ifat []Addr
 loop:
 	for _, m := range msgs {
 		switch m.Header.Type {
 		case syscall.NLMSG_DONE:
 			break loop
 		case syscall.RTM_NEWADDR:
 			ifam := (*syscall.IfAddrmsg)(unsafe.Pointer(&m.Data[0]))
 			if len(ift) != 0 || ifi.Index == int(ifam.Index) {
 				if len(ift) != 0 {
 					var err error
 					ifi, err = interfaceByIndex(ift, int(ifam.Index))
 					if err != nil {
 						return nil, err
 					}
 				}
 				attrs, err := syscall.ParseNetlinkRouteAttr(&m)
 				if err != nil {
 					return nil, os.NewSyscallError("parsenetlinkrouteattr", err)
 				}
 				ifa := newAddr(ifam, attrs)
 				if ifa != nil {
 					ifat = append(ifat, ifa)
 				}
 			}
 		}
 	}
 	return ifat, nil
 }

 func newAddr(ifam *syscall.IfAddrmsg, attrs []syscall.NetlinkRouteAttr) Addr {
 	var ipPointToPoint bool
 	// Seems like we need to make sure whether the IP interface
 	// stack consists of IP point-to-point numbered or unnumbered
 	// addressing.
 	for _, a := range attrs {
 		if a.Attr.Type == syscall.IFA_LOCAL {
 			ipPointToPoint = true
 			break
 		}
 	}
 	for _, a := range attrs {
 		if ipPointToPoint && a.Attr.Type == syscall.IFA_ADDRESS {
 			continue
 		}
 		switch ifam.Family {
 		case syscall.AF_INET:
 			return &IPNet{IP: IPv4(a.Value[0], a.Value[1], a.Value[2], a.Value[3]), Mask: CIDRMask(int(ifam.Prefixlen), 8*IPv4len)}
 		case syscall.AF_INET6:
 			ifa := &IPNet{IP: make(IP, IPv6len), Mask: CIDRMask(int(ifam.Prefixlen), 8*IPv6len)}
 			copy(ifa.IP, a.Value[:])
 			return ifa
 		}
 	}
 	return nil
 }

 // interfaceMulticastAddrTable returns addresses for a specific
 // interface.
 func interfaceMulticastAddrTable(ifi *Interface) ([]Addr, error) {
 	ifmat4 := parseProcNetIGMP("/proc/net/igmp", ifi)
 	ifmat6 := parseProcNetIGMP6("/proc/net/igmp6", ifi)
 	return append(ifmat4, ifmat6...), nil
 }

 func parseProcNetIGMP(path string, ifi *Interface) []Addr {
 	fd, err := open(path)
 	if err != nil {
 		return nil
 	}
 	defer fd.close()
 	var (
 		ifmat []Addr
 		name  string
 	)
 	fd.readLine() // skip first line
 	b := make([]byte, IPv4len)
 	for l, ok := fd.readLine(); ok; l, ok = fd.readLine() {
 		f := splitAtBytes(l, " :\r\t\n")
 		if len(f) < 4 {
 			continue
 		}
 		switch {
 		case l[0] != ' ' && l[0] != '\t': // new interface line
 			name = f[1]
 		case len(f[0]) == 8:
 			if ifi == nil || name == ifi.Name {
 				// The Linux kernel puts the IP
 				// address in /proc/net/igmp in native
 				// endianness.
 				for i := 0; i+1 < len(f[0]); i += 2 {
 					b[i/2], _ = xtoi2(f[0][i:i+2], 0)
 				}
 				i := *(*uint32)(unsafe.Pointer(&b[:4][0]))
 				ifma := &IPAddr{IP: IPv4(byte(i>>24), byte(i>>16), byte(i>>8), byte(i))}
 				ifmat = append(ifmat, ifma)
 			}
 		}
 	}
 	return ifmat
 }

 func parseProcNetIGMP6(path string, ifi *Interface) []Addr {
 	fd, err := open(path)
 	if err != nil {
 		return nil
 	}
 	defer fd.close()
 	var ifmat []Addr
 	b := make([]byte, IPv6len)
 	for l, ok := fd.readLine(); ok; l, ok = fd.readLine() {
 		f := splitAtBytes(l, " \r\t\n")
 		if len(f) < 6 {
 			continue
 		}
 		if ifi == nil || f[1] == ifi.Name {
 			for i := 0; i+1 < len(f[2]); i += 2 {
 				b[i/2], _ = xtoi2(f[2][i:i+2], 0)
 			}
 			ifma := &IPAddr{IP: IP{b[0], b[1], b[2], b[3], b[4], b[5], b[6], b[7], b[8], b[9], b[10], b[11], b[12], b[13], b[14], b[15]}}
 			ifmat = append(ifmat, ifma)
 		}
 	}
 	return ifmat
 }
	// 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 net

	import (
	"os"
	"syscall"
	"unsafe"
	)

	// If the ifindex is zero, interfaceTable returns mappings of all
	// network interfaces. Otherwise it returns a mapping of a specific
	// interface.
	func interfaceTable(ifindex int) ([]Interface, error) {
	tab, err := syscall.NetlinkRIB(syscall.RTM_GETLINK, syscall.AF_UNSPEC)
	if err != nil {
	return nil, os.NewSyscallError("netlinkrib", err)
	}
	msgs, err := syscall.ParseNetlinkMessage(tab)
	if err != nil {
	return nil, os.NewSyscallError("parsenetlinkmessage", err)
	}
	var ift []Interface
	loop:
	for _, m := range msgs {
	switch m.Header.Type {
	case syscall.NLMSG_DONE:
	break loop
	case syscall.RTM_NEWLINK:
	ifim := (*syscall.IfInfomsg)(unsafe.Pointer(&m.Data[0]))
	if ifindex == 0 \|\| ifindex == int(ifim.Index) {
	attrs, err := syscall.ParseNetlinkRouteAttr(&m)
	if err != nil {
	return nil, os.NewSyscallError("parsenetlinkrouteattr", err)
	}
	ift = append(ift, *newLink(ifim, attrs))
	if ifindex == int(ifim.Index) {
	break loop
	}
	}
	}
	}
	return ift, nil
	}

	const (
	// See linux/if_arp.h.
	// Note that Linux doesn't support IPv4 over IPv6 tunneling.
	sysARPHardwareIPv4IPv4 = 768 // IPv4 over IPv4 tunneling
	sysARPHardwareIPv6IPv6 = 769 // IPv6 over IPv6 tunneling
	sysARPHardwareIPv6IPv4 = 776 // IPv6 over IPv4 tunneling
	sysARPHardwareGREIPv4 = 778 // any over GRE over IPv4 tunneling
	sysARPHardwareGREIPv6 = 823 // any over GRE over IPv6 tunneling
	)

	func newLink(ifim syscall.IfInfomsg, attrs []syscall.NetlinkRouteAttr) Interface {
	ifi := &Interface{Index: int(ifim.Index), Flags: linkFlags(ifim.Flags)}
	for _, a := range attrs {
	switch a.Attr.Type {
	case syscall.IFLA_ADDRESS:
	// We never return any /32 or /128 IP address
	// prefix on any IP tunnel interface as the
	// hardware address.
	switch len(a.Value) {
	case IPv4len:
	switch ifim.Type {
	case sysARPHardwareIPv4IPv4, sysARPHardwareGREIPv4, sysARPHardwareIPv6IPv4:
	continue
	}
	case IPv6len:
	switch ifim.Type {
	case sysARPHardwareIPv6IPv6, sysARPHardwareGREIPv6:
	continue
	}
	}
	var nonzero bool
	for _, b := range a.Value {
	if b != 0 {
	nonzero = true
	break
	}
	}
	if nonzero {
	ifi.HardwareAddr = a.Value[:]
	}
	case syscall.IFLA_IFNAME:
	ifi.Name = string(a.Value[:len(a.Value)-1])
	case syscall.IFLA_MTU:
	ifi.MTU = int((uint32)(unsafe.Pointer(&a.Value[:4][0])))
	}
	}
	return ifi
	}

	func linkFlags(rawFlags uint32) Flags {
	var f Flags
	if rawFlags&syscall.IFF_UP != 0 {
	f \|= FlagUp
	}
	if rawFlags&syscall.IFF_RUNNING != 0 {
	f \|= FlagRunning
	}
	if rawFlags&syscall.IFF_BROADCAST != 0 {
	f \|= FlagBroadcast
	}
	if rawFlags&syscall.IFF_LOOPBACK != 0 {
	f \|= FlagLoopback
	}
	if rawFlags&syscall.IFF_POINTOPOINT != 0 {
	f \|= FlagPointToPoint
	}
	if rawFlags&syscall.IFF_MULTICAST != 0 {
	f \|= FlagMulticast
	}
	return f
	}

	// If the ifi is nil, interfaceAddrTable returns addresses for all
	// network interfaces. Otherwise it returns addresses for a specific
	// interface.
	func interfaceAddrTable(ifi *Interface) ([]Addr, error) {
	tab, err := syscall.NetlinkRIB(syscall.RTM_GETADDR, syscall.AF_UNSPEC)
	if err != nil {
	return nil, os.NewSyscallError("netlinkrib", err)
	}
	msgs, err := syscall.ParseNetlinkMessage(tab)
	if err != nil {
	return nil, os.NewSyscallError("parsenetlinkmessage", err)
	}
	var ift []Interface
	if ifi == nil {
	var err error
	ift, err = interfaceTable(0)
	if err != nil {
	return nil, err
	}
	}
	ifat, err := addrTable(ift, ifi, msgs)
	if err != nil {
	return nil, err
	}
	return ifat, nil
	}

	func addrTable(ift []Interface, ifi *Interface, msgs []syscall.NetlinkMessage) ([]Addr, error) {
	var ifat []Addr
	loop:
	for _, m := range msgs {
	switch m.Header.Type {
	case syscall.NLMSG_DONE:
	break loop
	case syscall.RTM_NEWADDR:
	ifam := (*syscall.IfAddrmsg)(unsafe.Pointer(&m.Data[0]))
	if len(ift) != 0 \|\| ifi.Index == int(ifam.Index) {
	if len(ift) != 0 {
	var err error
	ifi, err = interfaceByIndex(ift, int(ifam.Index))
	if err != nil {
	return nil, err
	}
	}
	attrs, err := syscall.ParseNetlinkRouteAttr(&m)
	if err != nil {
	return nil, os.NewSyscallError("parsenetlinkrouteattr", err)
	}
	ifa := newAddr(ifam, attrs)
	if ifa != nil {
	ifat = append(ifat, ifa)
	}
	}
	}
	}
	return ifat, nil
	}

	func newAddr(ifam *syscall.IfAddrmsg, attrs []syscall.NetlinkRouteAttr) Addr {
	var ipPointToPoint bool
	// Seems like we need to make sure whether the IP interface
	// stack consists of IP point-to-point numbered or unnumbered
	// addressing.
	for _, a := range attrs {
	if a.Attr.Type == syscall.IFA_LOCAL {
	ipPointToPoint = true
	break
	}
	}
	for _, a := range attrs {
	if ipPointToPoint && a.Attr.Type == syscall.IFA_ADDRESS {
	continue
	}
	switch ifam.Family {
	case syscall.AF_INET:
	return &IPNet{IP: IPv4(a.Value[0], a.Value[1], a.Value[2], a.Value[3]), Mask: CIDRMask(int(ifam.Prefixlen), 8*IPv4len)}
	case syscall.AF_INET6:
	ifa := &IPNet{IP: make(IP, IPv6len), Mask: CIDRMask(int(ifam.Prefixlen), 8*IPv6len)}
	copy(ifa.IP, a.Value[:])
	return ifa
	}
	}
	return nil
	}

	// interfaceMulticastAddrTable returns addresses for a specific
	// interface.
	func interfaceMulticastAddrTable(ifi *Interface) ([]Addr, error) {
	ifmat4 := parseProcNetIGMP("/proc/net/igmp", ifi)
	ifmat6 := parseProcNetIGMP6("/proc/net/igmp6", ifi)
	return append(ifmat4, ifmat6...), nil
	}

	func parseProcNetIGMP(path string, ifi *Interface) []Addr {
	fd, err := open(path)
	if err != nil {
	return nil
	}
	defer fd.close()
	var (
	ifmat []Addr
	name string
	)
	fd.readLine() // skip first line
	b := make([]byte, IPv4len)
	for l, ok := fd.readLine(); ok; l, ok = fd.readLine() {
	f := splitAtBytes(l, " :\r\t\n")
	if len(f) < 4 {
	continue
	}
	switch {
	case l[0] != ' ' && l[0] != '\t': // new interface line
	name = f[1]
	case len(f[0]) == 8:
	if ifi == nil \|\| name == ifi.Name {
	// The Linux kernel puts the IP
	// address in /proc/net/igmp in native
	// endianness.
	for i := 0; i+1 < len(f[0]); i += 2 {
	b[i/2], _ = xtoi2(f[0][i:i+2], 0)
	}
	i := (uint32)(unsafe.Pointer(&b[:4][0]))
	ifma := &IPAddr{IP: IPv4(byte(i>>24), byte(i>>16), byte(i>>8), byte(i))}
	ifmat = append(ifmat, ifma)
	}
	}
	}
	return ifmat
	}

	func parseProcNetIGMP6(path string, ifi *Interface) []Addr {
	fd, err := open(path)
	if err != nil {
	return nil
	}
	defer fd.close()
	var ifmat []Addr
	b := make([]byte, IPv6len)
	for l, ok := fd.readLine(); ok; l, ok = fd.readLine() {
	f := splitAtBytes(l, " \r\t\n")
	if len(f) < 6 {
	continue
	}
	if ifi == nil \|\| f[1] == ifi.Name {
	for i := 0; i+1 < len(f[2]); i += 2 {
	b[i/2], _ = xtoi2(f[2][i:i+2], 0)
	}
	ifma := &IPAddr{IP: IP{b[0], b[1], b[2], b[3], b[4], b[5], b[6], b[7], b[8], b[9], b[10], b[11], b[12], b[13], b[14], b[15]}}
	ifmat = append(ifmat, ifma)
	}
	}
	return ifmat
	}