#! /usr/bin/python ## IP resequencing + protocol reversing skeleton ## 2008 Massive Blowout import StringIO import struct import socket import warnings import heapq import gapstr import time import UserDict from __init__ import * def unpack_nybbles(byte): return (byte >> 4, byte & 0x0F) ICMP = 1 TCP = 6 UDP = 17 class Frame: """Turn an ethernet frame into relevant parts""" def __init__(self, pkt): ((self.time, _, _), frame) = pkt # Ethernet (self.eth_dhost, self.eth_shost, self.eth_type, p) = unpack('!6s6sH', frame) if self.eth_type == 0x0806: # ARP self.name = 'ARP' (self.ar_hrd, self.ar_pro, self.ar_hln, self.ar_pln, self.ar_op, self.ar_sha, self.ar_sip, self.ar_tha, self.ar_tip, p) = unpack('!HHBBH6si6si', p) self.saddr = self.ar_sip self.daddr = self.ar_tip self.__repr__ = self.__arp_repr__ elif self.eth_type == 0x0800: # IP (self.ihlvers, self.tos, self.tot_len, self.id, self.frag_off, self.ttl, self.protocol, self.check, self.saddr, self.daddr, p) = unpack("!BBHHHBBHii", p) if self.protocol == TCP: self.name = 'TCP/IP' (self.sport, self.dport, self.seq, self.ack, x2off, self.flags, self.win, self.sum, self.urp, p) = unpack("!HHLLBBHHH", p) (self.off, th_x2) = unpack_nybbles(x2off) opt_length = self.off * 4 self.options, p = p[:opt_length - 20], p[opt_length - 20:] self.payload = p[:self.tot_len - opt_length - 20] elif self.protocol == UDP: self.name = 'UDP/IP' (self.sport, self.dport, self.ulen, self.sum, p) = unpack("!HHHH", p) self.payload = p[:self.ulen - 8] elif self.protocol == ICMP: self.name = 'ICMP/IP' self.sport = self.dport = None (self.type, self.code, self.cheksum, self.id, self.seq, p) = unpack('!BBHHH', p) self.payload = p[:self.tot_len - 8] else: self.name = 'IP Protocol %d' % self.protocol self.sport = self.dport = None self.payload = p # Nice formatting self.src = (self.saddr, self.sport) self.dst = (self.daddr, self.dport) # This hash is the same for both sides of the transaction self.hash = (self.saddr ^ (self.sport or 0) ^ self.daddr ^ (self.dport or 0)) else: self.name = 'Ethernet type %d' % self.eth_type def get_src_addr(self): saddr = struct.pack('!i', self.saddr) self.src_addr = socket.inet_ntoa(saddr) return self.src_addr src_addr = property(get_src_addr) def get_dst_addr(self): daddr = struct.pack('!i', self.daddr) self.dst_addr = socket.inet_ntoa(daddr) return self.dst_addr dst_addr = property(get_dst_addr) def __repr__(self): return ' %s:%r length %d>' % (self.name, self.src_addr, self.sport, self.dst_addr, self.dport, len(self.payload)) def __arp_repr__(self): return ' %s(%s)>' % (self.name, self.ar_sha.encode('hex'), self.src_addr, self.ar_tha.encode('hex'), self.dst_addr) class Chunk: """Chunk of frames, possibly with gaps. """ def __init__(self, seq=None): self.collection = {} self.length = 0 self.seq = seq self.first = None def add(self, frame): if not self.first: self.first = frame if self.seq is None: self.seq = frame.seq assert frame.seq >= self.seq, (frame.seq, self.seq) self.collection[frame.seq] = frame end = frame.seq - self.seq + len(frame.payload) self.length = max(self.length, long(end)) def __len__(self): return int(self.length) def __repr__(self): if self.first: return ' %s:%d length %d (0x%x)>' % (self.first.src_addr, self.first.sport, self.first.dst_addr, self.first.dport, len(self), len(self)) else: return '' def gapstr(self, drop='?'): """Return contents as a GapString""" ret = gapstr.GapString(drop=drop) while len(ret) < self.length: f = self.collection.get(self.seq + len(ret)) if f: ret.append(f.payload) else: # This is where to fix big inefficiency for dropped packets. l = 1 while ((len(ret) + l < self.length) and (not (self.seq + len(ret) + l) in self.collection)): l += 1 ret.append(l) return ret def __str__(self): return str(self.gapstr()) def extend(self, other): self.seq = min(self.seq or other.seq, other.seq) self.length = self.length + other.length if not self.first: self.first = other.first self.collection.update(other.collection) def __add__(self, next): new = self.__class__(self.seq) new.extend(self) new.extend(next) return new FIN = 1 SYN = 2 RST = 4 PSH = 8 ACK = 16 class TCP_Resequence: """TCP session resequencer. >>> p = pcap.open('whatever.pcap') >>> s = TCP_Resequence() >>> while True: ... pkt = p.read() ... if not pkt: ... break ... f = Frame(pkt) ... r = s.handle(f) ... if r: ... print ('chunk', r) This returns things in sequence. So you get both sides of the conversation in the order that they happened. Doesn't (yet) handle fragments or dropped packets. Does handle out of order packets. """ def __init__(self): self.cli = None self.srv = None self.seq = [None, None] self.first = None self.pending = [{}, {}] self.frames = 0 self.closed = 0 self.handle = self.handle_handshake def handle(self, pkt): """Stub. This function will never be called, it is immediately overridden by __init__. The current value of this function is the state. """ pass def handle_handshake(self, pkt): self.frames += 1 if not self.first: self.first = pkt if pkt.flags == SYN: self.cli, self.srv = pkt.src, pkt.dst elif pkt.flags == (SYN | ACK): assert (pkt.src == (self.srv or pkt.src)) self.cli, self.srv = pkt.dst, pkt.src self.seq = [pkt.ack, pkt.seq + 1] elif pkt.flags == ACK: assert (pkt.src == (self.cli or pkt.src)) self.cli, self.srv = pkt.src, pkt.dst self.seq = [pkt.seq, pkt.ack] self.handle = self.handle_packet else: # In the middle of a session, do the best we can self.cli, self.srv = pkt.src, pkt.dst self.seq = [pkt.seq, pkt.ack] self.handle = self.handle_packet self.handle(pkt) def handle_packet(self, pkt): ret = None self.frames += 1 # Which way is this going? 0 == from client idx = int(pkt.src == self.srv) xdi = 1 - idx # Does this ACK after the last output sequence number? seq = self.seq[xdi] if pkt.ack > seq: ret = Chunk(seq) pending = self.pending[xdi] for key in pending.keys(): if key >= pkt.ack: continue if key >= seq: ret.add(pending[key]) else: warnings.warn('Dropping %r from mid-stream session' % pending[key]) del pending[key] self.seq[xdi] = pkt.ack # If it has a payload, stick it into pending if pkt.payload: self.pending[idx][pkt.seq] = pkt # Is it a FIN or RST? if pkt.flags & (FIN | RST): self.closed += 1 if self.closed == 2: # Warn about any unhandled packets if self.pending[0] or self.pending[1]: warnings.warn('Dropping unhandled frames after shutdown' % pkt) self.handle = self.handle_drop return ret def handle_drop(self, pkt): """Warn about any unhandled packets""" if pkt.payload: warnings.warn('Spurious frame after shutdown: %r %d' % (pkt, pkt.flags)) def resequence(pc): """Re-sequence from a pcap stream. >>> p = pcap.open('whatever.pcap') >>> for chunk in resequence(p): ... print `chunk` """ sessions = {} for pkt in pc: f = Frame(pkt) if f.protocol == TCP: # compute TCP session hash s = sessions.get(f.hash) if not s: s = TCP_Resequence() sessions[f.hash] = s chunk = s.handle(f) if chunk: yield chunk def demux(*pcs): """Demultiplex pcap objects based on time. This is iterable just like a pcap object, so you could for instance do: >>> resequence(demux(pcap1, pcap2, pcap3)) """ tops = [] for pc in pcs: frame = pc.read() if frame: heapq.heappush(tops, (frame, pc)) while tops: frame, pc = heapq.heappop(tops) yield frame frame = pc.read() if frame: heapq.heappush(tops, (frame, pc)) ## ## Binary protocol stuff ## class NeedMoreData(Exception): pass class Packet(UserDict.DictMixin): """Base class for a packet from a binary protocol. This is a base class for making protocol reverse-engineering easier. """ opcodes = {} def __init__(self, firstframe=None): self.firstframe = firstframe self.opcode = None self.opcode_desc = None self.parts = [] self.params = {} self.payload = None def __repr__(self): r = '<%s packet opcode=%s' % (self.__class__.__name__, self.opcode) if self.opcode_desc: r += '(%s)' % self.opcode_desc keys = self.params.keys() keys.sort() for k in keys: r += ' %s=%s' % (k, self.params[k]) r += '>' return r ## Dict methods def __setitem__(self, k, v): self.params[k] = v def __getitem__(self, k): return self.params[k] def __contains__(self, k): return k in self.params def __iter__(self): return self.params.__iter__() def has_key(self, k): return self.params.has_key(k) def keys(self): return self.params.keys() ## def assert_in(self, a, *b): if len(b) == 1: assert a == b[0], ('%r != %r' % (a, b[0])) else: assert a in b, ('%r not in %r' % (a, b)) def show(self): print '%s %3s: %s' % (self.__class__.__name__, self.opcode, self.opcode_desc) if self.firstframe: print ' %s:%d -> %s:%d (%s)' % (self.firstframe.src_addr, self.firstframe.sport, self.firstframe.dst_addr, self.firstframe.dport, time.ctime(self.firstframe.time)) if self.parts: dl = len(self.parts[-1]) p = [] for x in self.parts[:-1]: if x == dl: p.append('%3d!' % x) else: p.append('%3d' % x) print ' parts: (%s) +%d bytes' % (','.join(p), dl) keys = self.params.keys() keys.sort() for k in keys: print ' %12s: %s' % (k, self.params[k]) if self.payload: try: self.payload.hexdump() except AttributeError: print ' payload: %r' % self.payload def parse(self, data): """Parse a chunk of data (possibly a GapString). Anything returned is not part of this packet and will be passed in to a subsequent packet. """ self.parts = [data] return None def handle(self, data): """Handle data from a Session class.""" data = self.parse(data) if self.opcode <> None: try: f = getattr(self, 'opcode_%s' % self.opcode) except AttributeError: f = self.opcode_unknown if not self.opcode_desc and f.__doc__: self.opcode_desc = f.__doc__.split('\n')[0] f() return data def opcode_unknown(self): """Unknown opcode""" raise AttributeError('Opcode %d unknown' % self.opcode) class Session: """Base class for a binary protocol session.""" # Override this, duh Packet = Packet def __init__(self): self.pending = {} def handle(self, chunk): """Handle a data burst. Pass in a chunk. """ saddr = chunk.first.saddr try: (first, data) = self.pending.pop(saddr) except KeyError: first = chunk.first data = gapstr.GapString() data.extend(chunk.gapstr()) try: while data: p = self.Packet(first) data = p.handle(data) self.process(p) except NeedMoreData: self.pending[saddr] = (first, data) def process(self, packet): """Process a packet. When you first start out, this probably does exactly what you want: print out packets as they come in. As you progress you'll probably want to override it with something more sophisticated. That will of course vary wildly between protocols. """ packet.show() def done(self): """Called when all packets have been handled""" return def handle_packets(self, collection): """Handle a collection of packets""" for chunk in resequence(collection): self.handle(chunk) self.done()