Add existing GAM 3.21 code

gdata/Crypto/Protocol/Chaffing.py

@@ -0,0 +1,229 @@
+"""This file implements the chaffing algorithm.
+
+Winnowing and chaffing is a technique for enhancing privacy without requiring
+strong encryption.  In short, the technique takes a set of authenticated
+message blocks (the wheat) and adds a number of chaff blocks which have
+randomly chosen data and MAC fields.  This means that to an adversary, the
+chaff blocks look as valid as the wheat blocks, and so the authentication
+would have to be performed on every block.  By tailoring the number of chaff
+blocks added to the message, the sender can make breaking the message
+computationally infeasible.  There are many other interesting properties of
+the winnow/chaff technique.
+
+For example, say Alice is sending a message to Bob.  She packetizes the
+message and performs an all-or-nothing transformation on the packets.  Then
+she authenticates each packet with a message authentication code (MAC).  The
+MAC is a hash of the data packet, and there is a secret key which she must
+share with Bob (key distribution is an exercise left to the reader).  She then
+adds a serial number to each packet, and sends the packets to Bob.
+
+Bob receives the packets, and using the shared secret authentication key,
+authenticates the MACs for each packet.  Those packets that have bad MACs are
+simply discarded.  The remainder are sorted by serial number, and passed
+through the reverse all-or-nothing transform.  The transform means that an
+eavesdropper (say Eve) must acquire all the packets before any of the data can
+be read.  If even one packet is missing, the data is useless.
+
+There's one twist: by adding chaff packets, Alice and Bob can make Eve's job
+much harder, since Eve now has to break the shared secret key, or try every
+combination of wheat and chaff packet to read any of the message.  The cool
+thing is that Bob doesn't need to add any additional code; the chaff packets
+are already filtered out because their MACs don't match (in all likelihood --
+since the data and MACs for the chaff packets are randomly chosen it is
+possible, but very unlikely that a chaff MAC will match the chaff data).  And
+Alice need not even be the party adding the chaff!  She could be completely
+unaware that a third party, say Charles, is adding chaff packets to her
+messages as they are transmitted.
+
+For more information on winnowing and chaffing see this paper:
+
+Ronald L. Rivest, "Chaffing and Winnowing: Confidentiality without Encryption"
+http://theory.lcs.mit.edu/~rivest/chaffing.txt
+
+"""
+
+__revision__ = "$Id: Chaffing.py,v 1.7 2003/02/28 15:23:21 akuchling Exp $"
+
+from Crypto.Util.number import bytes_to_long
+
+class Chaff:
+    """Class implementing the chaff adding algorithm.
+
+    Methods for subclasses:
+
+            _randnum(size):
+                Returns a randomly generated number with a byte-length equal
+                to size.  Subclasses can use this to implement better random
+                data and MAC generating algorithms.  The default algorithm is
+                probably not very cryptographically secure.  It is most
+                important that the chaff data does not contain any patterns
+                that can be used to discern it from wheat data without running
+                the MAC.
+
+    """
+
+    def __init__(self, factor=1.0, blocksper=1):
+        """Chaff(factor:float, blocksper:int)
+
+        factor is the number of message blocks to add chaff to,
+        expressed as a percentage between 0.0 and 1.0.  blocksper is
+        the number of chaff blocks to include for each block being
+        chaffed.  Thus the defaults add one chaff block to every
+        message block.  By changing the defaults, you can adjust how
+        computationally difficult it could be for an adversary to
+        brute-force crack the message.  The difficulty is expressed
+        as:
+
+            pow(blocksper, int(factor * number-of-blocks))
+
+        For ease of implementation, when factor < 1.0, only the first
+        int(factor*number-of-blocks) message blocks are chaffed.
+        """
+
+        if not (0.0<=factor<=1.0):
+            raise ValueError, "'factor' must be between 0.0 and 1.0"
+        if blocksper < 0:
+            raise ValueError, "'blocksper' must be zero or more"
+
+        self.__factor = factor
+        self.__blocksper = blocksper
+
+
+    def chaff(self, blocks):
+        """chaff( [(serial-number:int, data:string, MAC:string)] )
+        : [(int, string, string)]
+
+        Add chaff to message blocks.  blocks is a list of 3-tuples of the
+        form (serial-number, data, MAC).
+
+        Chaff is created by choosing a random number of the same
+        byte-length as data, and another random number of the same
+        byte-length as MAC.  The message block's serial number is
+        placed on the chaff block and all the packet's chaff blocks
+        are randomly interspersed with the single wheat block.  This
+        method then returns a list of 3-tuples of the same form.
+        Chaffed blocks will contain multiple instances of 3-tuples
+        with the same serial number, but the only way to figure out
+        which blocks are wheat and which are chaff is to perform the
+        MAC hash and compare values.
+        """
+
+        chaffedblocks = []
+
+        # count is the number of blocks to add chaff to.  blocksper is the
+        # number of chaff blocks to add per message block that is being
+        # chaffed.
+        count = len(blocks) * self.__factor
+        blocksper = range(self.__blocksper)
+        for i, wheat in map(None, range(len(blocks)), blocks):
+            # it shouldn't matter which of the n blocks we add chaff to, so for
+            # ease of implementation, we'll just add them to the first count
+            # blocks
+            if i < count:
+                serial, data, mac = wheat
+                datasize = len(data)
+                macsize = len(mac)
+                addwheat = 1
+                # add chaff to this block
+                for j in blocksper:
+                    import sys
+                    chaffdata = self._randnum(datasize)
+                    chaffmac = self._randnum(macsize)
+                    chaff = (serial, chaffdata, chaffmac)
+                    # mix up the order, if the 5th bit is on then put the
+                    # wheat on the list
+                    if addwheat and bytes_to_long(self._randnum(16)) & 0x40:
+                        chaffedblocks.append(wheat)
+                        addwheat = 0
+                    chaffedblocks.append(chaff)
+                if addwheat:
+                    chaffedblocks.append(wheat)
+            else:
+                # just add the wheat
+                chaffedblocks.append(wheat)
+        return chaffedblocks
+
+    def _randnum(self, size):
+        # TBD: Not a very secure algorithm.
+        # TBD: size * 2 to work around possible bug in RandomPool
+        from Crypto.Util import randpool
+        import time
+        pool = randpool.RandomPool(size * 2)
+        while size > pool.entropy:
+            pass
+
+        # we now have enough entropy in the pool to get size bytes of random
+        # data... well, probably
+        return pool.get_bytes(size)
+
+
+
+if __name__ == '__main__':
+    text = """\
+We hold these truths to be self-evident, that all men are created equal, that
+they are endowed by their Creator with certain unalienable Rights, that among
+these are Life, Liberty, and the pursuit of Happiness. That to secure these
+rights, Governments are instituted among Men, deriving their just powers from
+the consent of the governed. That whenever any Form of Government becomes
+destructive of these ends, it is the Right of the People to alter or to
+abolish it, and to institute new Government, laying its foundation on such
+principles and organizing its powers in such form, as to them shall seem most
+likely to effect their Safety and Happiness.
+"""
+    print 'Original text:\n=========='
+    print text
+    print '=========='
+
+    # first transform the text into packets
+    blocks = [] ; size = 40
+    for i in range(0, len(text), size):
+        blocks.append( text[i:i+size] )
+
+    # now get MACs for all the text blocks.  The key is obvious...
+    print 'Calculating MACs...'
+    from Crypto.Hash import HMAC, SHA
+    key = 'Jefferson'
+    macs = [HMAC.new(key, block, digestmod=SHA).digest()
+            for block in blocks]
+
+    assert len(blocks) == len(macs)
+
+    # put these into a form acceptable as input to the chaffing procedure
+    source = []
+    m = map(None, range(len(blocks)), blocks, macs)
+    print m
+    for i, data, mac in m:
+        source.append((i, data, mac))
+
+    # now chaff these
+    print 'Adding chaff...'
+    c = Chaff(factor=0.5, blocksper=2)
+    chaffed = c.chaff(source)
+
+    from base64 import encodestring
+
+    # print the chaffed message blocks.  meanwhile, separate the wheat from
+    # the chaff
+
+    wheat = []
+    print 'chaffed message blocks:'
+    for i, data, mac in chaffed:
+        # do the authentication
+        h = HMAC.new(key, data, digestmod=SHA)
+        pmac = h.digest()
+        if pmac == mac:
+            tag = '-->'
+            wheat.append(data)
+        else:
+            tag = '   '
+        # base64 adds a trailing newline
+        print tag, '%3d' % i, \
+              repr(data), encodestring(mac)[:-1]
+
+    # now decode the message packets and check it against the original text
+    print 'Undigesting wheat...'
+    newtext = "".join(wheat)
+    if newtext == text:
+        print 'They match!'
+    else:
+        print 'They differ!'