tools/origin_trials/third_party/ed25519/ed25519.py - chromium/src - Git at Google

 # The original version of this file was downloaded from
 # http://ed25519.cr.yp.to/software.html, and came with the following copyright
 # statement:
 # The Ed25519 software is in the public domain.

 import hashlib

 b = 256
 q = 2**255 - 19
 l = 2**252 + 27742317777372353535851937790883648493

 def H(m):
   return hashlib.sha512(m).digest()

 def expmod(b,e,m):
   if e == 0: return 1
   t = expmod(b,e/2,m)**2 % m
   if e & 1: t = (t*b) % m
   return t

 def inv(x):
   return expmod(x,q-2,q)

 d = -121665 * inv(121666)
 I = expmod(2,(q-1)/4,q)

 def xrecover(y):
   xx = (y*y-1) * inv(d*y*y+1)
   x = expmod(xx,(q+3)/8,q)
   if (x*x - xx) % q != 0: x = (x*I) % q
   if x % 2 != 0: x = q-x
   return x

 By = 4 * inv(5)
 Bx = xrecover(By)
 B = [Bx % q,By % q]

 def edwards(P,Q):
   x1 = P[0]
   y1 = P[1]
   x2 = Q[0]
   y2 = Q[1]
   x3 = (x1*y2+x2*y1) * inv(1+d*x1*x2*y1*y2)
   y3 = (y1*y2+x1*x2) * inv(1-d*x1*x2*y1*y2)
   return [x3 % q,y3 % q]

 def scalarmult(P,e):
   if e == 0: return [0,1]
   Q = scalarmult(P,e/2)
   Q = edwards(Q,Q)
   if e & 1: Q = edwards(Q,P)
   return Q

 def encodeint(y):
   bits = [(y >> i) & 1 for i in range(b)]
   return ''.join([chr(sum([bits[i * 8 + j] << j for j in range(8)])) for i in range(b/8)])

 def encodepoint(P):
   x = P[0]
   y = P[1]
   bits = [(y >> i) & 1 for i in range(b - 1)] + [x & 1]
   return ''.join([chr(sum([bits[i * 8 + j] << j for j in range(8)])) for i in range(b/8)])

 def bit(h,i):
   return (ord(h[i/8]) >> (i%8)) & 1

 def publickey(sk):
   h = H(sk)
   a = 2**(b-2) + sum(2**i * bit(h,i) for i in range(3,b-2))
   A = scalarmult(B,a)
   return encodepoint(A)

 def Hint(m):
   h = H(m)
   return sum(2**i * bit(h,i) for i in range(2*b))

 def signature(m,sk,pk):
   h = H(sk)
   a = 2**(b-2) + sum(2**i * bit(h,i) for i in range(3,b-2))
   r = Hint(''.join([h[i] for i in range(b/8,b/4)]) + m)
   R = scalarmult(B,r)
   S = (r + Hint(encodepoint(R) + pk + m) * a) % l
   return encodepoint(R) + encodeint(S)

 def isoncurve(P):
   x = P[0]
   y = P[1]
   return (-x*x + y*y - 1 - d*x*x*y*y) % q == 0

 def decodeint(s):
   return sum(2**i * bit(s,i) for i in range(0,b))

 def decodepoint(s):
   y = sum(2**i * bit(s,i) for i in range(0,b-1))
   x = xrecover(y)
   if x & 1 != bit(s,b-1): x = q-x
   P = [x,y]
   if not isoncurve(P): raise Exception("decoding point that is not on curve")
   return P

 def checkvalid(s,m,pk):
   if len(s) != b/4: raise Exception("signature length is wrong")
   if len(pk) != b/8: raise Exception("public-key length is wrong")
   R = decodepoint(s[0:b/8])
   A = decodepoint(pk)
   S = decodeint(s[b/8:b/4])
   h = Hint(encodepoint(R) + pk + m)
   if scalarmult(B,S) != edwards(R,scalarmult(A,h)):
     raise Exception("signature does not pass verification")
	# The original version of this file was downloaded from
	# http://ed25519.cr.yp.to/software.html, and came with the following copyright
	# statement:
	# The Ed25519 software is in the public domain.

	import hashlib

	b = 256
	q = 2**255 - 19
	l = 2**252 + 27742317777372353535851937790883648493

	def H(m):
	return hashlib.sha512(m).digest()

	def expmod(b,e,m):
	if e == 0: return 1
	t = expmod(b,e/2,m)**2 % m
	if e & 1: t = (t*b) % m
	return t

	def inv(x):
	return expmod(x,q-2,q)

	d = -121665 * inv(121666)
	I = expmod(2,(q-1)/4,q)

	def xrecover(y):
	xx = (yy-1) inv(dyy+1)
	x = expmod(xx,(q+3)/8,q)
	if (xx - xx) % q != 0: x = (xI) % q
	if x % 2 != 0: x = q-x
	return x

	By = 4 * inv(5)
	Bx = xrecover(By)
	B = [Bx % q,By % q]

	def edwards(P,Q):
	x1 = P[0]
	y1 = P[1]
	x2 = Q[0]
	y2 = Q[1]
	x3 = (x1y2+x2y1) * inv(1+dx1x2y1y2)
	y3 = (y1y2+x1x2) * inv(1-dx1x2y1y2)
	return [x3 % q,y3 % q]

	def scalarmult(P,e):
	if e == 0: return [0,1]
	Q = scalarmult(P,e/2)
	Q = edwards(Q,Q)
	if e & 1: Q = edwards(Q,P)
	return Q

	def encodeint(y):
	bits = [(y >> i) & 1 for i in range(b)]
	return ''.join([chr(sum([bits[i * 8 + j] << j for j in range(8)])) for i in range(b/8)])

	def encodepoint(P):
	x = P[0]
	y = P[1]
	bits = [(y >> i) & 1 for i in range(b - 1)] + [x & 1]
	return ''.join([chr(sum([bits[i * 8 + j] << j for j in range(8)])) for i in range(b/8)])

	def bit(h,i):
	return (ord(h[i/8]) >> (i%8)) & 1

	def publickey(sk):
	h = H(sk)
	a = 2(b-2) + sum(2i * bit(h,i) for i in range(3,b-2))
	A = scalarmult(B,a)
	return encodepoint(A)

	def Hint(m):
	h = H(m)
	return sum(2*i bit(h,i) for i in range(2*b))

	def signature(m,sk,pk):
	h = H(sk)
	a = 2(b-2) + sum(2i * bit(h,i) for i in range(3,b-2))
	r = Hint(''.join([h[i] for i in range(b/8,b/4)]) + m)
	R = scalarmult(B,r)
	S = (r + Hint(encodepoint(R) + pk + m) * a) % l
	return encodepoint(R) + encodeint(S)

	def isoncurve(P):
	x = P[0]
	y = P[1]
	return (-xx + yy - 1 - dxxyy) % q == 0

	def decodeint(s):
	return sum(2*i bit(s,i) for i in range(0,b))

	def decodepoint(s):
	y = sum(2*i bit(s,i) for i in range(0,b-1))
	x = xrecover(y)
	if x & 1 != bit(s,b-1): x = q-x
	P = [x,y]
	if not isoncurve(P): raise Exception("decoding point that is not on curve")
	return P

	def checkvalid(s,m,pk):
	if len(s) != b/4: raise Exception("signature length is wrong")
	if len(pk) != b/8: raise Exception("public-key length is wrong")
	R = decodepoint(s[0:b/8])
	A = decodepoint(pk)
	S = decodeint(s[b/8:b/4])
	h = Hint(encodepoint(R) + pk + m)
	if scalarmult(B,S) != edwards(R,scalarmult(A,h)):
	raise Exception("signature does not pass verification")