import socket import time import sha import struct import StringIO import binascii import random import pygtk pygtk.require('2.0') import gtk, gobject def _stringify_sha(sha): print_sha = "" for char in sha: print_sha = print_sha + binascii.b2a_hex(char) return print_sha def _sha_data(data): sha_hash = sha.new() sha_hash.update(data) return sha_hash.digest() _UDP_DATAGRAM_SIZE = 512 class SegmentBase(object): _MAGIC = 0xbaea4304 # 4: magic (0xbaea4304) # 1: type # 2: segment number # 2: total segments # 2: message sequence number #20: total data sha1 _HEADER_TEMPLATE = "! IbHHH20s" _HEADER_LEN = struct.calcsize(_HEADER_TEMPLATE) _MTU = _UDP_DATAGRAM_SIZE - _HEADER_LEN # Message segment packet types _SEGMENT_TYPE_DATA = 0 _SEGMENT_TYPE_RETRANSMIT = 1 def magic(): return SegmentBase._MAGIC magic = staticmethod(magic) def header_template(): return SegmentBase._HEADER_TEMPLATE header_template = staticmethod(header_template) def type_data(): return SegmentBase._SEGMENT_TYPE_DATA type_data = staticmethod(type_data) def type_retransmit(): return SegmentBase._SEGMENT_TYPE_RETRANSMIT type_retransmit = staticmethod(type_retransmit) def header_len(): """Return the header size of SegmentBase packets.""" return SegmentBase._HEADER_LEN header_len = staticmethod(header_len) def mtu(): """Return the SegmentBase packet MTU.""" return SegmentBase._MTU mtu = staticmethod(mtu) def __init__(self, segno, total_segs, msg_seq_num, master_sha): self._type = None self._transmits = 0 self._last_transmit = 0 self._data = None self._data_len = 0 self.userdata = None self._stime = time.time() self._addr = None # Sanity checks on the message attributes if not segno or type(segno) != type(1): raise ValueError("Segment number must be in integer.") if segno < 1 or segno > 65535: raise ValueError("Segment number must be between 1 and 65535 inclusive.") if not total_segs or type(total_segs) != type(1): raise ValueError("Message segment total must be an integer.") if total_segs < 1 or total_segs > 65535: raise ValueError("Message must have between 1 and 65535 segments inclusive.") if segno > total_segs: raise ValueError("Segment number cannot be larger than message segment total.") if not msg_seq_num or type(msg_seq_num) != type(1): raise ValueError("Message sequnce number must be an integer.") if msg_seq_num < 1 or msg_seq_num > 65535: raise ValueError("Message sequence number must be between 1 and 65535 inclusive.") if not master_sha or type(master_sha) != type("") or len(master_sha) != 20: raise ValueError("Message SHA1 checksum invalid.") self._segno = segno self._total_segs = total_segs self._msg_seq_num = msg_seq_num self._master_sha = master_sha def new_from_data(addr, data): """Static constructor for creation from a packed data stream.""" if not addr or type(addr) != type(()): raise ValueError("Address must be a tuple.") if len(addr) != 2 or type(addr[0]) != type("") or type(addr[1]) != type(1): raise ValueError("Address format was invalid.") if addr[1] < 1 or addr[1] > 65535: raise ValueError("Address port was invalid.") # Verify minimum length if not data: raise ValueError("Segment data is invalid.") data_len = len(data) if data_len < SegmentBase.header_len() + 1: raise ValueError("Segment is less then minimum required length") if data_len > _UDP_DATAGRAM_SIZE: raise ValueError("Segment data is larger than allowed.") stream = StringIO.StringIO(data) # Determine and verify the length of included data stream.seek(0, 2) data_len = stream.tell() - SegmentBase._HEADER_LEN stream.seek(0) if data_len < 1: raise ValueError("Segment must have some data.") if data_len > SegmentBase._MTU: raise ValueError("Data length must not be larger than the MTU (%s)." % SegmentBase._MTU) # Read the first header attributes (magic, seg_type, segno, total_segs, msg_seq_num, master_sha) = struct.unpack(SegmentBase._HEADER_TEMPLATE, stream.read(SegmentBase._HEADER_LEN)) # Sanity checks on the message attributes if magic != SegmentBase._MAGIC: raise ValueError("Segment does not have the correct magic.") # if the segment is the only one in the message, validate the data if segno == 1 and total_segs == 1: data_sha = _sha_data(stream.read(data_len)) if data_sha != master_sha: raise ValueError("Single segment message SHA checksums didn't match.") stream.seek(SegmentBase._HEADER_LEN) if seg_type == SegmentBase._SEGMENT_TYPE_DATA: segment = DataSegment(segno, total_segs, msg_seq_num, master_sha) elif seg_type == SegmentBase._SEGMENT_TYPE_RETRANSMIT: segment = RetransmitSegment(segno, total_segs, msg_seq_num, master_sha) else: raise ValueError("Segment has invalid type.") # Segment specific data interpretation segment._addr = addr segment._unpack_data(stream, data_len) return segment new_from_data = staticmethod(new_from_data) def stime(self): return self._stime def addr(self): return self._addr def segment_number(self): return self._segno def total_segments(self): return self._total_segs def message_sequence_number(self): return self._msg_seq_num def data(self): return self._data def master_sha(self): return self._master_sha def segment_type(self): return self._type def packetize(self): """Return a correctly formatted message that can be immediately sent.""" header = struct.pack(self._HEADER_TEMPLATE, self._MAGIC, self._type, self._segno, self._total_segs, self._msg_seq_num, self._master_sha) return header + self._data def transmits(self): return self._transmits def inc_transmits(self): self._transmits = self._transmits + 1 self._last_transmit = time.time() def last_transmit(self): return self._last_transmit class DataSegment(SegmentBase): """A message segment that encapsulates random data.""" def __init__(self, segno, total_segs, msg_seq_num, master_sha): SegmentBase.__init__(self, segno, total_segs, msg_seq_num, master_sha) self._type = SegmentBase._SEGMENT_TYPE_DATA def _get_template_for_len(length): return "! %ds" % length _get_template_for_len = staticmethod(_get_template_for_len) def _unpack_data(self, stream, data_len): """Unpack the data stream, called by constructor.""" self._data_len = data_len template = DataSegment._get_template_for_len(self._data_len) self._data = struct.unpack(template, stream.read(self._data_len))[0] def new_from_parts(segno, total_segs, msg_seq_num, master_sha, data): """Construct a new message segment from individual attributes.""" if not data: raise ValueError("Must have valid data.") segment = DataSegment(segno, total_segs, msg_seq_num, master_sha) segment._data_len = len(data) template = DataSegment._get_template_for_len(segment._data_len) segment._data = struct.pack(template, data) return segment new_from_parts = staticmethod(new_from_parts) class RetransmitSegment(SegmentBase): """A message segment that encapsulates a retransmission request.""" # Retransmission data format: # 2: message sequence number # 20: total data sha1 # 2: segment number _RT_DATA_TEMPLATE = "! H20sH" def __init__(self, segno, total_segs, msg_seq_num, master_sha): """Should not be called directly.""" if segno != 1 or total_segs != 1: raise ValueError("Retransmission request messages must have only one segment.") SegmentBase.__init__(self, segno, total_segs, msg_seq_num, master_sha) self._type = SegmentBase._SEGMENT_TYPE_DATA def _make_rtms_data(rt_msg_seq_num, rt_master_sha, rt_segment_number): """Pack retransmission request payload.""" data = struct.pack(RetransmitSegment._RT_DATA_TEMPLATE, rt_msg_seq_num, rt_master_sha, rt_segment_number) return (data, _sha_data(data), struct.calcsize(RetransmitSegment._RT_DATA_TEMPLATE)) _make_rtms_data = staticmethod(_make_rtms_data) def new_from_parts(msg_seq_num, rt_msg_seq_num, rt_master_sha, rt_segment_number): """Static constructor for creation from individual attributes.""" (data, data_sha, data_len) = segment._make_rtms_data() segment = RetransmitSegment(1, 1, msg_seq_num, data_sha) segment._data_len = data_len segment._data = data segment._rt_msg_seq_num = rt_msg_seq_num segment._rt_master_sha = rt_master_sha segment._rt_segment_number = rt_segment_number return segment new_from_parts = staticmethod(new_from_parts) def _unpack_data(self, stream, data_len): if data_len != struct.calcsize(self._RT_DATA_TEMPLATE): raise ValueError("Retransmission request data had invalid length.") self._data_len = data_len (rt_msg_seq_num, rt_master_sha, rt_seg_no) = struct.unpack(self._RT_DATA_TEMPLATE, stream.read(self._data_len)) self._data = struct.pack(self._RT_DATA_TEMPLATE, rt_msg_seq_num, rt_master_sha, rt_seg_no) self._rt_msg_seq_num = rt_msg_seq_num self._rt_master_sha = rt_master_sha self._rt_segment_number = rt_seg_no def rt_msg_seq_num(self): return self._rt_msg_seq_num def rt_master_sha(self): return self._rt_master_sha def rt_segment_number(self): return self._rt_segment_number class MostlyReliablePipe(object): """Implement Mostly-Reliable UDP. We don't actually care about guaranteeing delivery or receipt, just a better effort than no effort at all.""" _UDP_MSG_SIZE = SegmentBase.mtu() + SegmentBase.header_len() _SEGMENT_TTL = 120 # 2 minutes def __init__(self, local_addr, remote_addr, port, data_cb, user_data=None): self._local_addr = local_addr self._remote_addr = remote_addr self._port = port self._data_cb = data_cb self._user_data = user_data self._started = False self._worker = 0 self._seq_counter = 0 self._outgoing = [] self._sent = {} self._incoming = {} # (message sha, # of segments) -> [segment1, segment2, ...] self._setup_listener() self._setup_sender() def _setup_sender(self): """Setup the send socket for multicast.""" self._send_sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM) # Make the socket multicast-aware, and set TTL. self._send_sock.setsockopt(socket.IPPROTO_IP, socket.IP_MULTICAST_TTL, 20) # Change TTL (=20) to suit def _setup_listener(self): """Set up the listener socket for multicast traffic.""" # Listener socket self._listen_sock = socket.socket(socket.AF_INET, socket.SOCK_DGRAM) # Set some options to make it multicast-friendly self._listen_sock.setsockopt(socket.SOL_SOCKET, socket.SO_REUSEADDR, 1) self._listen_sock.setsockopt(socket.SOL_IP, socket.IP_MULTICAST_TTL, 20) self._listen_sock.setsockopt(socket.SOL_IP, socket.IP_MULTICAST_LOOP, 1) def start(self): """Let the listener socket start listening for network data.""" # Set some more multicast options self._listen_sock.bind((self._local_addr, self._port)) # Bind to all interfaces self._listen_sock.settimeout(2) intf = socket.gethostbyname(socket.gethostname()) self._listen_sock.setsockopt(socket.SOL_IP, socket.IP_MULTICAST_IF, socket.inet_aton(intf) + socket.inet_aton('0.0.0.0')) self._listen_sock.setsockopt(socket.SOL_IP, socket.IP_ADD_MEMBERSHIP, socket.inet_aton(self._remote_addr) + socket.inet_aton('0.0.0.0')) # Watch the listener socket for data gobject.io_add_watch(self._listen_sock, gobject.IO_IN, self._handle_incoming_data) gobject.timeout_add(self._SEGMENT_TTL * 1000, self._segment_ttl_worker) self._started = True def _segment_ttl_worker(self): """Cull already-sent message segments that are past their TTL.""" now = time.time() for segment in self._sent[:]: if segment.stime() < now - self._SEGMENT_TTL: self._sent.remove(segment) return True def _dispatch_message(self, addr, message): """Send complete message data to the owner's data callback.""" self._data_cb(addr, message, self._user_data) def _process_incoming_data(self, segment): """Handle a new message segment. First checks if there is only one segment to the message, and if the checksum from the header matches that computed from the data, dispatches it. Otherwise, it adds the new segment to the list of other segments for that message, and checks to see if the message is complete. If all segments are present, the message is reassembled and dispatched.""" string_sha = _stringify_sha(segment.master_sha()) nsegs = segment.total_segments() addr = segment.addr() segno = segment.segment_number() # Short-circuit single-segment messages if segno == 1 and nsegs == 1: # Ensure the header's master sha actually equals the data's sha if string_sha == _stringify_sha(_sha_data(segment.data())): self._dispatch_message(addr, segment.data()) return # Otherwise, track the new segment msg_seq_num = segment.message_sequence_number() msg_key = (addr[0], msg_seq_num, string_sha, nsegs) if not self._incoming.has_key(msg_key): self._incoming[msg_key] = {} # Look for a dupe, and if so, drop the new segment if self._incoming[msg_key].has_key(segno): return self._incoming[msg_key][segno] = segment # Dispatch the message if all segments are present and the sha is correct if len(self._incoming[msg_key]) == nsegs: all_data = '' for i in range(1, nsegs + 1): all_data = all_data + self._incoming[msg_key][i].data() if string_sha == _stringify_sha(_sha_data(all_data)): self._dispatch_message(addr, all_data) del self._incoming[msg_key] _STD_RETRANSMIT_INTERVAL = 500 # 1/2 second (in milliseconds) def _calc_next_retransmit(self, segment, now): """Calculate the next time (in seconds) that a packet can be retransmitted.""" num_retrans = segment.transmits() - 1 interval = num_retrans * self._STD_RETRANSMIT_INTERVAL randomness = num_retrans * random.randint(-4, 11) real_interval = max(self._STD_RETRANSMIT_INTERVAL, interval + randomness) return max(now, segment.last_transmit() + (real_interval * .001)) def _segment_retransmit_cb(self, segment): """Add a segment ot the outgoing queue and schedule its transmission.""" del self._sent[key] self._outgoing.append(segment) self._schedule_send_worker() return False def _schedule_segment_retransmit(self, segment, when): """Schedule retransmission of a segment if one is not already scheduled.""" if segment.userdata: # Already scheduled for retransmit return if when == 0: # Immediate retransmission segment.userdata = gobject.idle_add(self._segment_retransmit_cb, segment) else: # convert time to milliseconds timeout = int((when - time.time()) * 1000) segment.userdata = gobject.timeout_add(timeout, self._segment_retransmit_cb, segment) def _process_retransmit_request(self, segment): """Validate and process a retransmission request.""" key = (segment.rt_msg_seq_num(), segment.rt_master_sha(), segment.rt_segment_number()) if not self._sent.has_key(key): # Either we don't know about the segment, or it was already culled return # Calculate next retransmission time and schedule packet for retransmit segment = self._sent[key] now = time.time() next_retrans = self._calc_next_retransmit(segment, now) self._schedule_segment_retransmit(segment, next_retrans - now) def _handle_incoming_data(self, source, condition): """Handle incoming network data by making a message segment out of it sending it off to the processing function.""" if not (condition & gobject.IO_IN): return True msg = {} data, addr = source.recvfrom(self._UDP_MSG_SIZE) try: segment = SegmentBase.new_from_data(addr, data) stype = segment.segment_type() if stype == SegmentBase.type_data(): self._process_incoming_data(segment) elif stype == SegmentBase.type_retransmit(): self._process_retransmit_request(segment) except ValueError, exc: print "Bad segment: %s" % exc return True def send(self, data): """Break data up into chunks and queue for later transmission.""" if not self._started: raise Exception("Can't send anything until started!") self._seq_counter = self._seq_counter + 1 if self._seq_counter > 65535: self._seq_counter = 1 # Pack the data into network byte order template = "! %ds" % len(data) data = struct.pack(template, data) master_sha = _sha_data(data) # Split up the data into segments left = length = len(data) mtu = SegmentBase.mtu() nmessages = length / mtu if length % mtu > 0: nmessages = nmessages + 1 msg_num = 1 while left > 0: seg = DataSegment.new_from_parts(msg_num, nmessages, self._seq_counter, master_sha, data[:mtu]) self._outgoing.append(seg) msg_num = msg_num + 1 data = data[mtu:] left = left - mtu self._schedule_send_worker() def _schedule_send_worker(self): if len(self._outgoing) > 0 and self._worker == 0: self._worker = gobject.idle_add(self._send_worker) def _send_worker(self): """Send all queued segments that have yet to be transmitted.""" self._worker = 0 for segment in self._outgoing: packet = segment.packetize() segment.inc_transmits() self._send_sock.sendto(packet, (self._remote_addr, self._port)) segment.userdata = None # Retransmission GSource key = (segment.message_sequence_number(), segment.master_sha(), segment.segment_number()) self._sent[key] = segment self._outgoing = [] return False ################################################################# # Tests ################################################################# import unittest class SegmentBaseTestCase(unittest.TestCase): _DEF_SEGNO = 1 _DEF_TOT_SEGS = 5 _DEF_MSG_SEQ_NUM = 4556 _DEF_MASTER_SHA = "12345678901234567890" _DEF_SEG_TYPE = 0 _DEF_ADDRESS = ('123.3.2.1', 3333) _SEG_MAGIC = 0xbaea4304 class SegmentBaseInitTestCase(SegmentBaseTestCase): def _test_init_fail(self, segno, total_segs, msg_seq_num, master_sha, fail_msg): try: seg = SegmentBase(segno, total_segs, msg_seq_num, master_sha) except ValueError, exc: pass else: self.fail("expected a ValueError for %s." % fail_msg) def testSegmentBase(self): assert SegmentBase.magic() == self._SEG_MAGIC, "Segment magic wasn't correct!" assert SegmentBase.header_len() > 0, "header size was not greater than zero." assert SegmentBase.mtu() > 0, "MTU was not greater than zero." assert SegmentBase.mtu() + SegmentBase.header_len() == _UDP_DATAGRAM_SIZE, "MTU + header size didn't equal expected %d." % _UDP_DATAGRAM_SIZE def testGoodInit(self): seg = SegmentBase(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA) assert seg.stime() < time.time(), "segment start time is less than now!" assert not seg.addr(), "Segment address was not None after init." assert seg.segment_number() == self._DEF_SEGNO, "Segment number wasn't correct after init." assert seg.total_segments() == self._DEF_TOT_SEGS, "Total segments wasn't correct after init." assert seg.message_sequence_number() == self._DEF_MSG_SEQ_NUM, "Message sequence number wasn't correct after init." assert seg.master_sha() == self._DEF_MASTER_SHA, "Message master SHA wasn't correct after init." assert seg.segment_type() == None, "Segment type was not None after init." assert seg.transmits() == 0, "Segment transmits was not 0 after init." assert seg.last_transmit() == 0, "Segment last transmit was not 0 after init." assert seg.data() == None, "Segment data was not None after init." def testSegmentNumber(self): self._test_init_fail(0, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid segment number") self._test_init_fail(65536, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid segment number") self._test_init_fail(None, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid segment number") self._test_init_fail("", self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid segment number") def testTotalMessageSegmentNumber(self): self._test_init_fail(self._DEF_SEGNO, 0, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid total segments") self._test_init_fail(self._DEF_SEGNO, 65536, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid total segments") self._test_init_fail(self._DEF_SEGNO, None, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid total segments") self._test_init_fail(self._DEF_SEGNO, "", self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, "invalid total segments") def testMessageSequenceNumber(self): self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, 0, self._DEF_MASTER_SHA, "invalid message sequence number") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, 65536, self._DEF_MASTER_SHA, "invalid message sequence number") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, None, self._DEF_MASTER_SHA, "invalid message sequence number") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, "", self._DEF_MASTER_SHA, "invalid message sequence number") def testMasterSHA(self): self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, "1" * 19, "invalid SHA1 data hash") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, "1" * 21, "invalid SHA1 data hash") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, None, "invalid SHA1 data hash") self._test_init_fail(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, 1234, "invalid SHA1 data hash") def _testNewFromDataFail(self, addr, data, fail_msg): try: seg = SegmentBase.new_from_data(addr, data) except ValueError, exc: pass else: self.fail("expected a ValueError about %s." % fail_msg) def testNewFromDataAddress(self): self._testNewFromDataFail(None, None, "bad address") self._testNewFromDataFail('', None, "bad address") self._testNewFromDataFail((''), None, "bad address") self._testNewFromDataFail((1), None, "bad address") self._testNewFromDataFail(('', ''), None, "bad address") self._testNewFromDataFail((1, 3333), None, "bad address") self._testNewFromDataFail(('', 0), None, "bad address") self._testNewFromDataFail(('', 65536), None, "bad address") def testNewFromDataData(self): """Only test generic new_from_data() bits, not type-specific ones.""" self._testNewFromDataFail(self._DEF_ADDRESS, None, "invalid data") really_short_data = "111" self._testNewFromDataFail(self._DEF_ADDRESS, really_short_data, "data too short") only_header_data = "1" * SegmentBase.header_len() self._testNewFromDataFail(self._DEF_ADDRESS, only_header_data, "data too short") too_much_data = "1" * (_UDP_DATAGRAM_SIZE + 1) self._testNewFromDataFail(self._DEF_ADDRESS, too_much_data, "too much data") header_template = SegmentBase.header_template() bad_magic_data = struct.pack(header_template, 0x12345678, self._DEF_SEG_TYPE, self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA) self._testNewFromDataFail(self._DEF_ADDRESS, bad_magic_data, "invalid magic") bad_type_data = struct.pack(header_template, self._SEG_MAGIC, -1, self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA) self._testNewFromDataFail(self._DEF_ADDRESS, bad_type_data, "invalid segment type") # Test master_sha that doesn't match data's SHA header = struct.pack(header_template, self._SEG_MAGIC, self._DEF_SEG_TYPE, 1, 1, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA) data = struct.pack("! 15s", "7" * 15) self._testNewFromDataFail(self._DEF_ADDRESS, header + data, "single-segment message SHA mismatch") def addToSuite(suite): suite.addTest(SegmentBaseInitTestCase("testGoodInit")) suite.addTest(SegmentBaseInitTestCase("testSegmentNumber")) suite.addTest(SegmentBaseInitTestCase("testTotalMessageSegmentNumber")) suite.addTest(SegmentBaseInitTestCase("testMessageSequenceNumber")) suite.addTest(SegmentBaseInitTestCase("testMasterSHA")) suite.addTest(SegmentBaseInitTestCase("testNewFromDataAddress")) suite.addTest(SegmentBaseInitTestCase("testNewFromDataData")) addToSuite = staticmethod(addToSuite) class DataSegmentTestCase(SegmentBaseTestCase): """Test DataSegment class specific initialization and stuff.""" def testInit(self): seg = DataSegment(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA) assert seg.segment_type() == SegmentBase.type_data(), "Segment wasn't a data segment." def testNewFromParts(self): try: seg = DataSegment.new_from_parts(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, None) except ValueError, exc: pass else: self.fail("Expected ValueError about invalid data.") # Ensure message data is same as we stuff in after object is instantiated payload = "How are you today?" seg = DataSegment.new_from_parts(self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, self._DEF_MASTER_SHA, payload) assert seg.data() == payload, "Data after segment creation didn't match expected." def testNewFromData(self): """Test DataSegment's new_from_data() functionality.""" # Make sure something valid actually works header_template = SegmentBase.header_template() payload_str = "How are you today?" payload = struct.pack("! %ds" % len(payload_str), payload_str) payload_sha = _sha_data(payload) header = struct.pack(header_template, self._SEG_MAGIC, SegmentBase.type_data(), self._DEF_SEGNO, self._DEF_TOT_SEGS, self._DEF_MSG_SEQ_NUM, payload_sha) seg = SegmentBase.new_from_data(self._DEF_ADDRESS, header + payload) assert seg.addr() == self._DEF_ADDRESS, "Segment address did not match expected." assert seg.segment_type() == SegmentBase.type_data(), "Segment type did not match expected." assert seg.segment_number() == self._DEF_SEGNO, "Segment number did not match expected." assert seg.total_segments() == self._DEF_TOT_SEGS, "Total segments did not match expected." assert seg.message_sequence_number() == self._DEF_MSG_SEQ_NUM, "Message sequence number did not match expected." assert seg.master_sha() == payload_sha, "Message master SHA did not match expected." assert seg.data() == payload, "Segment data did not match expected payload." def addToSuite(suite): suite.addTest(DataSegmentTestCase("testInit")) suite.addTest(DataSegmentTestCase("testNewFromParts")) suite.addTest(DataSegmentTestCase("testNewFromData")) addToSuite = staticmethod(addToSuite) class SHAUtilsTestCase(unittest.TestCase): def testSHA(self): data = "235jklqt3hjwasdv879wfe89723rqjh32tr3hwaejksdvd89udsv89dsgiougjktqjhk23tjht23hjt3qhjewagthjasgdgsd" data_sha = _sha_data(data) assert len(data_sha) == 20, "SHA wasn't correct size." known_sha = "\xee\x9e\xb9\x1d\xe8\x96\x75\xcb\x12\xf1\x25\x22\x0f\x76\xf7\xf3\xc8\x4e\xbf\xcd" assert data_sha == known_sha, "SHA didn't match known SHA." def testStringifySHA(self): data = "jlkwjlkaegdjlksgdjklsdgajklganjtwn23n325n23tjwgeajkga nafDA fwqnjlqtjkl23tjk2365jlk235jkl2356jlktjkltewjlktewjklewtjklaggsda" data_known_sha = "9650c23db78092a0ffda4577c87ebf36d25c868e" assert _stringify_sha(_sha_data(data)) == data_known_sha, "SHA stringify didn't return correct SHA." # Do it twice for kicks assert _stringify_sha(_sha_data(data)) == data_known_sha, "SHA stringify didn't return correct SHA." def addToSuite(suite): suite.addTest(SHAUtilsTestCase("testSHA")) suite.addTest(SHAUtilsTestCase("testStringifySHA")) addToSuite = staticmethod(addToSuite) def main(): suite = unittest.TestSuite() SegmentBaseInitTestCase.addToSuite(suite) DataSegmentTestCase.addToSuite(suite) SHAUtilsTestCase.addToSuite(suite) runner = unittest.TextTestRunner() runner.run(suite) def got_data(addr, data, user_data=None): print "Data (%s): %s" % (addr, data) def foobar(): pipe = MostlyReliablePipe('', '224.0.0.222', 2293, got_data) pipe.start() pipe.send('The quick brown fox jumps over the lazy dog') try: gtk.main() except KeyboardInterrupt: pass if __name__ == "__main__": main()