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packet.go
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packet.go
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package main
import (
"bufio"
"bytes"
"net"
"net/http"
"strconv"
"github.com/google/gopacket"
"github.com/google/gopacket/layers"
"github.com/sirupsen/logrus"
)
type multicastPacket struct {
packet gopacket.Packet
srcMAC *net.HardwareAddr
dstMAC *net.HardwareAddr
srcIP *net.IP
dstIP *net.IP
srcPort *layers.UDPPort
dstPort *layers.UDPPort
isIPv6 bool
vlanTag *uint16
isDNSQuery bool
isDNSResponse bool
isSSDPQuery bool
isSSDPAdvertisement bool
isSSDPResponse bool
maxWaitTime uint8
}
func parsePacketsLazily(source *gopacket.PacketSource) chan multicastPacket {
// Process packets, and forward Bonjour traffic to the returned channel
// Set decoding to Lazy
source.DecodeOptions = gopacket.DecodeOptions{Lazy: true}
packetChan := make(chan multicastPacket, 100)
go func() {
for packet := range source.Packets() {
tag := parseVLANTag(packet)
// Get source and destination mac addresses
srcMAC, dstMAC := parseEthernetLayer(packet)
// Check IP protocol version
isIPv6, srcIP, dstIP := parseIPLayer(packet)
// Get UDP payload
payload, srcPort, dstPort := parseUDPLayer(packet)
// Check if DNS query
isDNSQuery, isDNSResponse := false, false
if dstPort != nil && *dstPort == 5353 {
isDNSQuery, isDNSResponse = parseDNSPayload(payload)
}
// Check if SSDP query
isSSDPQuery, isSSDPAdvertisement, isSSDPResponse, maxWaitTime := false, false, false, uint8(ssdpSessionDuration)
if dstPort != nil && *dstPort == 1900 {
isSSDPQuery, isSSDPAdvertisement, maxWaitTime = parseSSDPQuery(payload)
} else if !isDNSQuery && !isDNSResponse {
isSSDPResponse = parseSSDPResponse(payload)
}
// Pass on the packet for its next adventure
packetChan <- multicastPacket{
packet: packet,
vlanTag: tag,
srcMAC: srcMAC,
dstMAC: dstMAC,
srcIP: srcIP,
dstIP: dstIP,
srcPort: srcPort,
dstPort: dstPort,
isIPv6: isIPv6,
isDNSQuery: isDNSQuery,
isDNSResponse: isDNSResponse,
isSSDPQuery: isSSDPQuery,
isSSDPAdvertisement: isSSDPAdvertisement,
isSSDPResponse: isSSDPResponse,
maxWaitTime: maxWaitTime,
}
}
}()
return packetChan
}
func parseEthernetLayer(packet gopacket.Packet) (srcMAC, dstMAC *net.HardwareAddr) {
if parsedEth := packet.Layer(layers.LayerTypeEthernet); parsedEth != nil {
srcMAC = &parsedEth.(*layers.Ethernet).SrcMAC
dstMAC = &parsedEth.(*layers.Ethernet).DstMAC
}
return
}
func parseVLANTag(packet gopacket.Packet) (tag *uint16) {
if parsedTag := packet.Layer(layers.LayerTypeDot1Q); parsedTag != nil {
tag = &parsedTag.(*layers.Dot1Q).VLANIdentifier
}
return
}
func parseIPLayer(packet gopacket.Packet) (isIPv6 bool, srcIP *net.IP, dstIP *net.IP) {
if parsedIP := packet.Layer(layers.LayerTypeIPv4); parsedIP != nil {
isIPv6 = false
srcIP = &parsedIP.(*layers.IPv4).SrcIP
dstIP = &parsedIP.(*layers.IPv4).DstIP
}
if parsedIP := packet.Layer(layers.LayerTypeIPv6); parsedIP != nil {
isIPv6 = true
srcIP = &parsedIP.(*layers.IPv6).SrcIP
dstIP = &parsedIP.(*layers.IPv6).DstIP
}
return
}
func parseUDPLayer(packet gopacket.Packet) (payload []byte, srcPort *layers.UDPPort, dstPort *layers.UDPPort) {
if parsedUDP := packet.Layer(layers.LayerTypeUDP); parsedUDP != nil {
payload = parsedUDP.(*layers.UDP).Payload
srcPort = &parsedUDP.(*layers.UDP).SrcPort
dstPort = &parsedUDP.(*layers.UDP).DstPort
}
return
}
func parseDNSPayload(payload []byte) (isDNSQuery bool, isDNSResponse bool) {
packet := gopacket.NewPacket(payload, layers.LayerTypeDNS, gopacket.Default)
if parsedDNS := packet.Layer(layers.LayerTypeDNS); parsedDNS != nil {
isDNSResponse = parsedDNS.(*layers.DNS).QR
isDNSQuery = !isDNSResponse
}
return
}
func parseSSDPQuery(payload []byte) (isSSDPQuery bool, isSSDPAdvertisement bool, maxWaitTime uint8) {
// SSDP packets are HTTP-like, so we can parse them as such
// https://tools.ietf.org/html/draft-cai-ssdp-v1-03
// Check if the packet is a valid HTTP request
parsedHTTP, err := http.ReadRequest(bufio.NewReader(bytes.NewReader(payload)))
if err != nil {
return
}
isSSDPQuery = parsedHTTP.Method == "M-SEARCH" &&
parsedHTTP.RequestURI == "*" &&
parsedHTTP.Header.Get("MAN") == `"ssdp:discover"`
isSSDPAdvertisement = parsedHTTP.Method == "NOTIFY" &&
parsedHTTP.RequestURI == "*" &&
parsedHTTP.Header.Get("NT") != "" &&
(parsedHTTP.Header.Get("NTS") == "ssdp:alive" || parsedHTTP.Header.Get("NTS") == "ssdp:byebye")
if isSSDPQuery {
if mx, err := strconv.Atoi(parsedHTTP.Header.Get("MX")); err == nil {
if mx >= 1 && mx <= 120 {
maxWaitTime = uint8(mx)
} else if mx > 120 {
maxWaitTime = 120
}
} else {
isSSDPQuery = false
}
}
parsedHTTP.Body.Close()
return
}
func parseSSDPResponse(payload []byte) (isSSDPResponse bool) {
// SSDP packets are HTTP-like, so we can parse them as such
// https://tools.ietf.org/html/draft-cai-ssdp-v1-03
// Check if the packet is a valid HTTP response
parsedHTTP, err := http.ReadResponse(bufio.NewReader(bytes.NewReader(payload)), nil)
if err != nil {
return
}
isSSDPResponse = parsedHTTP.Header.Get("CACHE-CONTROL") != "" &&
parsedHTTP.Header.Get("LOCATION") != "" &&
parsedHTTP.Header.Get("ST") != "" &&
parsedHTTP.Header.Get("USN") != ""
parsedHTTP.Body.Close()
return
}
type packetWriter interface {
WritePacketData([]byte) error
}
func sendPacket(handle packetWriter, packet *multicastPacket, tag uint16, srcMACAddress net.HardwareAddr, dstMacAddress net.HardwareAddr, srcIP net.IP, dstIP net.IP) {
*packet.vlanTag = tag
*packet.srcMAC = srcMACAddress
*packet.dstMAC = dstMacAddress
buf := gopacket.NewSerializeBuffer()
serializeOptions := gopacket.SerializeOptions{}
if srcIP != nil || dstIP != nil {
serializeOptions = gopacket.SerializeOptions{ComputeChecksums: true}
if srcIP != nil {
*packet.srcIP = srcIP
}
if dstIP != nil {
*packet.dstIP = dstIP
}
// We recalculate the checksum since the IP was modified
if packet.isIPv6 {
if parsedIP := packet.packet.Layer(layers.LayerTypeIPv6); parsedIP != nil {
if parsedUDP := packet.packet.Layer(layers.LayerTypeUDP); parsedUDP != nil {
parsedUDP.(*layers.UDP).SetNetworkLayerForChecksum(parsedIP.(*layers.IPv6))
}
}
} else {
if parsedIP := packet.packet.Layer(layers.LayerTypeIPv4); parsedIP != nil {
if parsedUDP := packet.packet.Layer(layers.LayerTypeUDP); parsedUDP != nil {
parsedUDP.(*layers.UDP).SetNetworkLayerForChecksum(parsedIP.(*layers.IPv4))
}
}
}
}
gopacket.SerializePacket(buf, serializeOptions, packet.packet)
handle.WritePacketData(buf.Bytes())
logrus.Debugf("Packet sent:\n%s", packet.packet.String())
}