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yggdrasil-go/src/yggdrasil/icmpv6.go
Neil Alexander 0ec5f1c02c
Version 0.2.1 (#130)
* switch address range from fd00::/8 to the deprecated 0200::/7 range

* Fix launchd script path and amend debian control file

* fix address/prefix code, platform specific parts still need testing

* macos

* cleanup old ugly session MTU code that only mattered with lossy UDP fragments

* Fix debian control file

* Let's try this again

* tcp/socks cleanup

* comment

* avoid the proxy.SOCK5 connection attempt unless we're actually going to use the dialer

* Update generate.sh

* prevent parent nodes from forcing coord oscillation, have dht.handleRes clean up the old request info immediately

* address range changes

* Update README.md

Consistently remove leading zeros from addresses in the readme.

* Update yggdrasil.go

* Collect yggdrasilctl during CI build

* Fix CircleCI after fat-fingered copypasta

* Fix for Windows

* clean up main yggdrasil.go imports and run gofmt
2018-06-15 11:02:45 +01:00

269 lines
7.6 KiB
Go

package yggdrasil
// The ICMPv6 module implements functions to easily create ICMPv6
// packets. These functions, when mixed with the built-in Go IPv6
// and ICMP libraries, can be used to send control messages back
// to the host. Examples include:
// - NDP messages, when running in TAP mode
// - Packet Too Big messages, when packets exceed the session MTU
// - Destination Unreachable messages, when a session prohibits
// incoming traffic
import (
"encoding/binary"
"errors"
"net"
"golang.org/x/net/icmp"
"golang.org/x/net/ipv6"
)
type macAddress [6]byte
const len_ETHER = 14
type icmpv6 struct {
tun *tunDevice
peermac macAddress
peerlladdr net.IP
mylladdr net.IP
mymac macAddress
}
// Marshal returns the binary encoding of h.
func ipv6Header_Marshal(h *ipv6.Header) ([]byte, error) {
b := make([]byte, 40)
b[0] |= byte(h.Version) << 4
b[0] |= byte(h.TrafficClass) >> 4
b[1] |= byte(h.TrafficClass) << 4
b[1] |= byte(h.FlowLabel >> 16)
b[2] = byte(h.FlowLabel >> 8)
b[3] = byte(h.FlowLabel)
binary.BigEndian.PutUint16(b[4:6], uint16(h.PayloadLen))
b[6] = byte(h.NextHeader)
b[7] = byte(h.HopLimit)
copy(b[8:24], h.Src)
copy(b[24:40], h.Dst)
return b, nil
}
// Initialises the ICMPv6 module by assigning our link-local IPv6 address and
// our MAC address. ICMPv6 messages will always appear to originate from these
// addresses.
func (i *icmpv6) init(t *tunDevice) {
i.tun = t
// Our MAC address and link-local address
copy(i.mymac[:], []byte{
0x02, 0x00, 0x00, 0x00, 0x00, 0x02})
i.mylladdr = net.IP{
0xFE, 0x80, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x80, 0xFE}
}
// Parses an incoming ICMPv6 packet. The packet provided may be either an
// ethernet frame containing an IP packet, or the IP packet alone. This is
// determined by whether the TUN/TAP adapter is running in TUN (layer 3) or
// TAP (layer 2) mode.
func (i *icmpv6) parse_packet(datain []byte) {
var response []byte
var err error
// Parse the frame/packet
if i.tun.iface.IsTAP() {
response, err = i.parse_packet_tap(datain)
} else {
response, err = i.parse_packet_tun(datain)
}
if err != nil {
return
}
// Write the packet to TUN/TAP
i.tun.iface.Write(response)
}
// Unwraps the ethernet headers of an incoming ICMPv6 packet and hands off
// the IP packet to the parse_packet_tun function for further processing.
// A response buffer is also created for the response message, also complete
// with ethernet headers.
func (i *icmpv6) parse_packet_tap(datain []byte) ([]byte, error) {
// Store the peer MAC address
copy(i.peermac[:6], datain[6:12])
// Ignore non-IPv6 frames
if binary.BigEndian.Uint16(datain[12:14]) != uint16(0x86DD) {
return nil, nil
}
// Hand over to parse_packet_tun to interpret the IPv6 packet
ipv6packet, err := i.parse_packet_tun(datain[len_ETHER:])
if err != nil {
return nil, err
}
// Create the response buffer
dataout := make([]byte, len_ETHER+ipv6.HeaderLen+32)
// Populate the response ethernet headers
copy(dataout[:6], datain[6:12])
copy(dataout[6:12], i.mymac[:])
binary.BigEndian.PutUint16(dataout[12:14], uint16(0x86DD))
// Copy the returned packet to our response ethernet frame
copy(dataout[len_ETHER:], ipv6packet)
return dataout, nil
}
// Unwraps the IP headers of an incoming IPv6 packet and performs various
// sanity checks on the packet - i.e. is the packet an ICMPv6 packet, does the
// ICMPv6 message match a known expected type. The relevant handler function
// is then called and a response packet may be returned.
func (i *icmpv6) parse_packet_tun(datain []byte) ([]byte, error) {
// Parse the IPv6 packet headers
ipv6Header, err := ipv6.ParseHeader(datain[:ipv6.HeaderLen])
if err != nil {
return nil, err
}
// Check if the packet is IPv6
if ipv6Header.Version != ipv6.Version {
return nil, err
}
// Check if the packet is ICMPv6
if ipv6Header.NextHeader != 58 {
return nil, err
}
// Store the peer link local address, it will come in useful later
copy(i.peerlladdr[:], ipv6Header.Src[:])
// Parse the ICMPv6 message contents
icmpv6Header, err := icmp.ParseMessage(58, datain[ipv6.HeaderLen:])
if err != nil {
return nil, err
}
// Check for a supported message type
switch icmpv6Header.Type {
case ipv6.ICMPTypeNeighborSolicitation:
{
response, err := i.handle_ndp(datain[ipv6.HeaderLen:])
if err == nil {
// Create our ICMPv6 response
responsePacket, err := i.create_icmpv6_tun(
ipv6Header.Src, i.mylladdr,
ipv6.ICMPTypeNeighborAdvertisement, 0,
&icmp.DefaultMessageBody{Data: response})
if err != nil {
return nil, err
}
// Send it back
return responsePacket, nil
} else {
return nil, err
}
}
}
return nil, errors.New("ICMPv6 type not matched")
}
// Creates an ICMPv6 packet based on the given icmp.MessageBody and other
// parameters, complete with ethernet and IP headers, which can be written
// directly to a TAP adapter.
func (i *icmpv6) create_icmpv6_tap(dstmac macAddress, dst net.IP, src net.IP, mtype ipv6.ICMPType, mcode int, mbody icmp.MessageBody) ([]byte, error) {
// Pass through to create_icmpv6_tun
ipv6packet, err := i.create_icmpv6_tun(dst, src, mtype, mcode, mbody)
if err != nil {
return nil, err
}
// Create the response buffer
dataout := make([]byte, len_ETHER+len(ipv6packet))
// Populate the response ethernet headers
copy(dataout[:6], dstmac[:6])
copy(dataout[6:12], i.mymac[:])
binary.BigEndian.PutUint16(dataout[12:14], uint16(0x86DD))
// Copy the returned packet to our response ethernet frame
copy(dataout[len_ETHER:], ipv6packet)
return dataout, nil
}
// Creates an ICMPv6 packet based on the given icmp.MessageBody and other
// parameters, complete with IP headers only, which can be written directly to
// a TUN adapter, or called directly by the create_icmpv6_tap function when
// generating a message for TAP adapters.
func (i *icmpv6) create_icmpv6_tun(dst net.IP, src net.IP, mtype ipv6.ICMPType, mcode int, mbody icmp.MessageBody) ([]byte, error) {
// Create the ICMPv6 message
icmpMessage := icmp.Message{
Type: mtype,
Code: mcode,
Body: mbody,
}
// Convert the ICMPv6 message into []byte
icmpMessageBuf, err := icmpMessage.Marshal(icmp.IPv6PseudoHeader(src, dst))
if err != nil {
return nil, err
}
// Create the IPv6 header
ipv6Header := ipv6.Header{
Version: ipv6.Version,
NextHeader: 58,
PayloadLen: len(icmpMessageBuf),
HopLimit: 255,
Src: src,
Dst: dst,
}
// Convert the IPv6 header into []byte
ipv6HeaderBuf, err := ipv6Header_Marshal(&ipv6Header)
if err != nil {
return nil, err
}
// Construct the packet
responsePacket := make([]byte, ipv6.HeaderLen+ipv6Header.PayloadLen)
copy(responsePacket[:ipv6.HeaderLen], ipv6HeaderBuf)
copy(responsePacket[ipv6.HeaderLen:], icmpMessageBuf)
// Send it back
return responsePacket, nil
}
// Generates a response to an NDP discovery packet. This is effectively called
// when the host operating system generates an NDP request for any address in
// the fd00::/8 range, so that the operating system knows to route that traffic
// to the Yggdrasil TAP adapter.
func (i *icmpv6) handle_ndp(in []byte) ([]byte, error) {
// Ignore NDP requests for anything outside of fd00::/8
var source address
copy(source[:], in[8:])
var snet subnet
copy(snet[:], in[8:])
switch {
case source.isValid():
case snet.isValid():
default:
return nil, errors.New("Not an NDP for 0200::/7")
}
// Create our NDP message body response
body := make([]byte, 28)
binary.BigEndian.PutUint32(body[:4], uint32(0x20000000))
copy(body[4:20], in[8:24]) // Target address
body[20] = uint8(2)
body[21] = uint8(1)
copy(body[22:28], i.mymac[:6])
// Send it back
return body, nil
}