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packet.go
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packet.go
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package pcap
import (
"encoding/binary"
"fmt"
"reflect"
"strings"
"time"
)
type PacketTime struct {
Sec int32
Usec int32
}
// Packet is a single packet parsed from a pcap file.
type Packet struct {
// porting from 'pcap_pkthdr' struct
Time time.Time // packet send/receive time
Caplen uint32 // bytes stored in the file (caplen <= len)
Len uint32 // bytes sent/received
Data []byte // packet data
Type int // protocol type, see LINKTYPE_*
DestMac uint64
SrcMac uint64
Headers []interface{} // decoded headers, in order
Payload []byte // remaining non-header bytes
}
// Decode decodes the headers of a Packet.
func (p *Packet) Decode() {
p.Type = int(binary.BigEndian.Uint16(p.Data[12:14]))
p.DestMac = decodemac(p.Data[0:6])
p.SrcMac = decodemac(p.Data[6:12])
p.Payload = p.Data[14:]
switch p.Type {
case TYPE_IP:
p.decodeIp()
case TYPE_IP6:
p.decodeIp6()
case TYPE_ARP:
p.decodeArp()
}
}
func (p *Packet) headerString(headers []interface{}) string {
// If there's just one header, return that.
if len(headers) == 1 {
if hdr, ok := headers[0].(fmt.Stringer); ok {
return hdr.String()
}
}
// If there are two headers (IPv4/IPv6 -> TCP/UDP/IP..)
if len(headers) == 2 {
// Commonly the first header is an address.
if addr, ok := p.Headers[0].(addrHdr); ok {
if hdr, ok := p.Headers[1].(addrStringer); ok {
return fmt.Sprintf("%s %s", p.Time, hdr.String(addr))
}
}
}
// For IP in IP, we do a recursive call.
if len(headers) >= 2 {
if addr, ok := headers[0].(addrHdr); ok {
if _, ok := headers[1].(addrHdr); ok {
return fmt.Sprintf("%s > %s IP in IP: ",
addr.SrcAddr(), addr.DestAddr(), p.headerString(headers[1:]))
}
}
}
var typeNames []string
for _, hdr := range headers {
typeNames = append(typeNames, reflect.TypeOf(hdr).String())
}
return fmt.Sprintf("unknown [%s]", strings.Join(typeNames, ","))
}
// String prints a one-line representation of the packet header.
// The output is suitable for use in a tcpdump program.
func (p *Packet) String() string {
// If there are no headers, print "unsupported protocol".
if len(p.Headers) == 0 {
return fmt.Sprintf("%s unsupported protocol %d", p.Time, int(p.Type))
}
return fmt.Sprintf("%s %s", p.Time, p.headerString(p.Headers))
}
func (p *Packet) decodeArp() {
pkt := p.Payload
arp := new(Arphdr)
arp.Addrtype = binary.BigEndian.Uint16(pkt[0:2])
arp.Protocol = binary.BigEndian.Uint16(pkt[2:4])
arp.HwAddressSize = pkt[4]
arp.ProtAddressSize = pkt[5]
arp.Operation = binary.BigEndian.Uint16(pkt[6:8])
arp.SourceHwAddress = pkt[8 : 8+arp.HwAddressSize]
arp.SourceProtAddress = pkt[8+arp.HwAddressSize : 8+arp.HwAddressSize+arp.ProtAddressSize]
arp.DestHwAddress = pkt[8+arp.HwAddressSize+arp.ProtAddressSize : 8+2*arp.HwAddressSize+arp.ProtAddressSize]
arp.DestProtAddress = pkt[8+2*arp.HwAddressSize+arp.ProtAddressSize : 8+2*arp.HwAddressSize+2*arp.ProtAddressSize]
p.Headers = append(p.Headers, arp)
p.Payload = p.Payload[8+2*arp.HwAddressSize+2*arp.ProtAddressSize:]
}
func (p *Packet) decodeIp() {
if len(p.Payload) < 20 {
return
}
pkt := p.Payload
ip := new(Iphdr)
ip.Version = uint8(pkt[0]) >> 4
ip.Ihl = uint8(pkt[0]) & 0x0F
ip.Tos = pkt[1]
ip.Length = binary.BigEndian.Uint16(pkt[2:4])
ip.Id = binary.BigEndian.Uint16(pkt[4:6])
flagsfrags := binary.BigEndian.Uint16(pkt[6:8])
ip.Flags = uint8(flagsfrags >> 13)
ip.FragOffset = flagsfrags & 0x1FFF
ip.Ttl = pkt[8]
ip.Protocol = pkt[9]
ip.Checksum = binary.BigEndian.Uint16(pkt[10:12])
ip.SrcIp = pkt[12:16]
ip.DestIp = pkt[16:20]
pEnd := int(ip.Length)
if pEnd > len(pkt) {
pEnd = len(pkt)
}
pIhl := int(ip.Ihl) * 4
if pIhl > pEnd {
pIhl = pEnd
}
p.Payload = pkt[pIhl:pEnd]
p.Headers = append(p.Headers, ip)
switch ip.Protocol {
case IP_TCP:
p.decodeTcp()
case IP_UDP:
p.decodeUdp()
case IP_ICMP:
p.decodeIcmp()
case IP_INIP:
p.decodeIp()
}
}
func (p *Packet) decodeTcp() {
pLenPayload := len(p.Payload)
if pLenPayload < 20 {
return
}
pkt := p.Payload
tcp := new(Tcphdr)
tcp.SrcPort = binary.BigEndian.Uint16(pkt[0:2])
tcp.DestPort = binary.BigEndian.Uint16(pkt[2:4])
tcp.Seq = binary.BigEndian.Uint32(pkt[4:8])
tcp.Ack = binary.BigEndian.Uint32(pkt[8:12])
tcp.DataOffset = (pkt[12] & 0xF0) >> 4
tcp.Flags = binary.BigEndian.Uint16(pkt[12:14]) & 0x1FF
tcp.Window = binary.BigEndian.Uint16(pkt[14:16])
tcp.Checksum = binary.BigEndian.Uint16(pkt[16:18])
tcp.Urgent = binary.BigEndian.Uint16(pkt[18:20])
pDataOffset := int(tcp.DataOffset * 4)
if pDataOffset > pLenPayload {
pDataOffset = pLenPayload
}
p.Payload = pkt[pDataOffset:]
p.Headers = append(p.Headers, tcp)
}
func (p *Packet) decodeUdp() {
if len(p.Payload) < 8 {
return
}
pkt := p.Payload
udp := new(Udphdr)
udp.SrcPort = binary.BigEndian.Uint16(pkt[0:2])
udp.DestPort = binary.BigEndian.Uint16(pkt[2:4])
udp.Length = binary.BigEndian.Uint16(pkt[4:6])
udp.Checksum = binary.BigEndian.Uint16(pkt[6:8])
p.Headers = append(p.Headers, udp)
p.Payload = pkt[8:]
}
func (p *Packet) decodeIcmp() *Icmphdr {
if len(p.Payload) < 8 {
return nil
}
pkt := p.Payload
icmp := new(Icmphdr)
icmp.Type = pkt[0]
icmp.Code = pkt[1]
icmp.Checksum = binary.BigEndian.Uint16(pkt[2:4])
icmp.Id = binary.BigEndian.Uint16(pkt[4:6])
icmp.Seq = binary.BigEndian.Uint16(pkt[6:8])
p.Payload = pkt[8:]
p.Headers = append(p.Headers, icmp)
return icmp
}
func (p *Packet) decodeIp6() {
if len(p.Payload) < 40 {
return
}
pkt := p.Payload
ip6 := new(Ip6hdr)
ip6.Version = uint8(pkt[0]) >> 4
ip6.TrafficClass = uint8((binary.BigEndian.Uint16(pkt[0:2]) >> 4) & 0x00FF)
ip6.FlowLabel = binary.BigEndian.Uint32(pkt[0:4]) & 0x000FFFFF
ip6.Length = binary.BigEndian.Uint16(pkt[4:6])
ip6.NextHeader = pkt[6]
ip6.HopLimit = pkt[7]
ip6.SrcIp = pkt[8:24]
ip6.DestIp = pkt[24:40]
p.Payload = pkt[40:]
p.Headers = append(p.Headers, ip6)
switch ip6.NextHeader {
case IP_TCP:
p.decodeTcp()
case IP_UDP:
p.decodeUdp()
case IP_ICMP:
p.decodeIcmp()
case IP_INIP:
p.decodeIp()
}
}