HoLyVieR · February 27, 2017 17:19
diff --git a/sponge.py b/sponge.py
 from Crypto.Cipher import AES
 from SocketServer import ThreadingMixIn
 from BaseHTTPServer import HTTPServer, BaseHTTPRequestHandler
 import sys
 import random
 import os

 class Hasher:
  def __init__(self):
    self.aes = AES.new('\x00'*16)

  def reset(self):
    self.state = '\x00'*16

  def ingest(self, block):
    """Ingest a block of 10 characters """
    block += '\x00'*6
    state = ""
    for i in range(16):
      state += chr(ord(self.state[i]) ^ ord(block[i]))

    print(state.encode("hex"))
    self.state = self.aes.encrypt(state)
    print(self.state.encode("hex"))

  def final_ingest(self, block):
    """Call this for the final ingestion.

    Calling this with a 0 length block is the same as calling it one round
    earlier with a 10 length block.
    """
    if len(block) == 10:
      self.ingest(block)
      self.ingest('\x80' + '\x00'*8 + '\x01')
    elif len(block) == 9:
      self.ingest(block + '\x81')
    else:
      self.ingest(block + '\x80' + '\x00'*(8-len(block)) + '\x01')

  def squeeze(self):
    """Output a block of hash information"""
    result = self.state[:10]
    self.state = self.aes.encrypt(self.state)
    return result

  def hash(self, s):
    """Hash an input of any length of bytes.  Return a 160-bit digest."""
    self.reset()
    blocks = len(s) // 10
    for i in range(blocks):
      self.ingest(s[10*i:10*(i+1)])
    self.final_ingest(s[blocks*10:])

    return self.squeeze() + self.squeeze()

 class HashHandler(BaseHTTPRequestHandler):
  def do_GET(self):
    if self.path in ['/favicon.ico', '/index.html']:
      # Stop.
      self.send_response(409)
      return

    try:
      to_hash = self.path[1:].decode('hex')
    except TypeError:
      # Bad hex.
      self.send_response(418)
      return

    if to_hash == GIVEN:
      # Nice try.
      self.send_response(451)
      return

    result = HASHER.hash(to_hash)
    if result != TARGET:
      # Wrong
      self.send_response(400)
      return
    self.send_response(200)
    self.end_headers()
    self.wfile.write(FLAG)

 class ThreadedHTTPServer(ThreadingMixIn, HTTPServer):
  pass

 # High-level solution
 # ------------------------------------------------------------------------
 # We basically find a collision for the last 6 bytes of the state. 
 # One is obtained forward starting with 10 random bytes and 6 null bytes
 # Other one is obtained with 9 random bytes \x81 and the last 6 bytes of the state of the message we need a collision.
 # This collision gives us the first block and third block of the collision.
 # The second block can computed with a XOR.

 # Code solution
 def enc(v):
  aes = AES.new('\x00'*16)
  return aes.encrypt(v)

 def xor(s1,s2):    
    return ''.join(chr(ord(a) ^ ord(b)) for a,b in zip(s1,s2))

 forward = {}

 # Building the Meet In The Middle forward lookup table 
 print "Forward ..."
 for i in xrange(2**24):
  if i % (2**16) == 0:
    print i
  aes = AES.new('\x00'*16)
  v = os.urandom(10) + '\x00'*6
  enc_ = aes.encrypt(v)
  forward[enc_[-6:]] = v

 # Find a match backward
 print "Backward ..."
 for j in xrange(2**40):
  aes = AES.new('\x00'*16)
  v = os.urandom(9) + '\xff\x77\x40\x56\x0a\x1d\x64' # 9 random bytes and 10th byte was computed so that it's \x81
  dec = aes.decrypt(v)

  if dec[-6:] in forward:
    print "Found !"
    print dec.encode("hex")
    print v.encode("hex")
    print forward[dec[-6:]].encode("hex")

    first_block = forward[dec[-6:]]
    first_block_enc = enc(forward[dec[-6:]])

    second_block = xor(first_block_enc, dec)
    second_block_enc = enc(dec)

    last_block = xor(second_block_enc, "ef43cd0580d0491c117e7740560a1d64".decode("hex"))

    print "Given"
    HASHER = Hasher()
    GIVEN = 'I love using sponges for crypto'
    given = HASHER.hash(GIVEN)


    print "Collision"
    HASHER = Hasher()
    collision = first_block[:10] + second_block[:10] + last_block[:9]
    coll_hash = HASHER.hash(collision)

    print "Collision sanity check"
    print given.encode("hex")
    print coll_hash.encode("hex")
    print (coll_hash == given)

    print "Solution !!!!"
    print collision.encode("hex")
	from Crypto.Cipher import AES
	from SocketServer import ThreadingMixIn
	from BaseHTTPServer import HTTPServer, BaseHTTPRequestHandler
	import sys
	import random
	import os

	class Hasher:
	def __init__(self):
	self.aes = AES.new('\x00'*16)

	def reset(self):
	self.state = '\x00'*16

	def ingest(self, block):
	"""Ingest a block of 10 characters """
	block += '\x00'*6
	state = ""
	for i in range(16):
	state += chr(ord(self.state[i]) ^ ord(block[i]))

	print(state.encode("hex"))
	self.state = self.aes.encrypt(state)
	print(self.state.encode("hex"))

	def final_ingest(self, block):
	"""Call this for the final ingestion.

	Calling this with a 0 length block is the same as calling it one round
	earlier with a 10 length block.
	"""
	if len(block) == 10:
	self.ingest(block)
	self.ingest('\x80' + '\x00'*8 + '\x01')
	elif len(block) == 9:
	self.ingest(block + '\x81')
	else:
	self.ingest(block + '\x80' + '\x00'*(8-len(block)) + '\x01')

	def squeeze(self):
	"""Output a block of hash information"""
	result = self.state[:10]
	self.state = self.aes.encrypt(self.state)
	return result

	def hash(self, s):
	"""Hash an input of any length of bytes. Return a 160-bit digest."""
	self.reset()
	blocks = len(s) // 10
	for i in range(blocks):
	self.ingest(s[10i:10(i+1)])
	self.final_ingest(s[blocks*10:])

	return self.squeeze() + self.squeeze()

	class HashHandler(BaseHTTPRequestHandler):
	def do_GET(self):
	if self.path in ['/favicon.ico', '/index.html']:
	# Stop.
	self.send_response(409)
	return

	try:
	to_hash = self.path[1:].decode('hex')
	except TypeError:
	# Bad hex.
	self.send_response(418)
	return

	if to_hash == GIVEN:
	# Nice try.
	self.send_response(451)
	return

	result = HASHER.hash(to_hash)
	if result != TARGET:
	# Wrong
	self.send_response(400)
	return
	self.send_response(200)
	self.end_headers()
	self.wfile.write(FLAG)

	class ThreadedHTTPServer(ThreadingMixIn, HTTPServer):
	pass

	# High-level solution
	# ------------------------------------------------------------------------
	# We basically find a collision for the last 6 bytes of the state.
	# One is obtained forward starting with 10 random bytes and 6 null bytes
	# Other one is obtained with 9 random bytes \x81 and the last 6 bytes of the state of the message we need a collision.
	# This collision gives us the first block and third block of the collision.
	# The second block can computed with a XOR.

	# Code solution
	def enc(v):
	aes = AES.new('\x00'*16)
	return aes.encrypt(v)

	def xor(s1,s2):
	return ''.join(chr(ord(a) ^ ord(b)) for a,b in zip(s1,s2))

	forward = {}

	# Building the Meet In The Middle forward lookup table
	print "Forward ..."
	for i in xrange(2**24):
	if i % (2**16) == 0:
	print i
	aes = AES.new('\x00'*16)
	v = os.urandom(10) + '\x00'*6
	enc_ = aes.encrypt(v)
	forward[enc_[-6:]] = v

	# Find a match backward
	print "Backward ..."
	for j in xrange(2**40):
	aes = AES.new('\x00'*16)
	v = os.urandom(9) + '\xff\x77\x40\x56\x0a\x1d\x64' # 9 random bytes and 10th byte was computed so that it's \x81
	dec = aes.decrypt(v)

	if dec[-6:] in forward:
	print "Found !"
	print dec.encode("hex")
	print v.encode("hex")
	print forward[dec[-6:]].encode("hex")

	first_block = forward[dec[-6:]]
	first_block_enc = enc(forward[dec[-6:]])

	second_block = xor(first_block_enc, dec)
	second_block_enc = enc(dec)

	last_block = xor(second_block_enc, "ef43cd0580d0491c117e7740560a1d64".decode("hex"))

	print "Given"
	HASHER = Hasher()
	GIVEN = 'I love using sponges for crypto'
	given = HASHER.hash(GIVEN)


	print "Collision"
	HASHER = Hasher()
	collision = first_block[:10] + second_block[:10] + last_block[:9]
	coll_hash = HASHER.hash(collision)

	print "Collision sanity check"
	print given.encode("hex")
	print coll_hash.encode("hex")
	print (coll_hash == given)

	print "Solution !!!!"
	print collision.encode("hex")