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# Copyright (c) 2022-2023 The Bitcoin Core developers
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# Distributed under the MIT software license, see the accompanying
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# file COPYING or http://www.opensource.org/licenses/mit-license.php.
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"""Test-only implementation of low-level secp256k1 field and group arithmetic
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It is designed for ease of understanding, not performance.
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WARNING: This code is slow and trivially vulnerable to side channel attacks. Do not use for
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anything but tests.
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Exports:
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* FE: class for secp256k1 field elements
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* GE: class for secp256k1 group elements
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* G: the secp256k1 generator point
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"""
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class FE:
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"""Objects of this class represent elements of the field GF(2**256 - 2**32 - 977).
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They are represented internally in numerator / denominator form, in order to delay inversions.
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"""
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# The size of the field (also its modulus and characteristic).
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SIZE = 2**256 - 2**32 - 977
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def __init__(self, a=0, b=1):
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"""Initialize a field element a/b; both a and b can be ints or field elements."""
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if isinstance(a, FE):
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num = a._num
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den = a._den
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else:
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num = a % FE.SIZE
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den = 1
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if isinstance(b, FE):
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den = (den * b._num) % FE.SIZE
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num = (num * b._den) % FE.SIZE
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else:
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den = (den * b) % FE.SIZE
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assert den != 0
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if num == 0:
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den = 1
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self._num = num
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self._den = den
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def __add__(self, a):
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"""Compute the sum of two field elements (second may be int)."""
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if isinstance(a, FE):
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return FE(self._num * a._den + self._den * a._num, self._den * a._den)
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return FE(self._num + self._den * a, self._den)
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def __radd__(self, a):
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"""Compute the sum of an integer and a field element."""
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return FE(a) + self
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def __sub__(self, a):
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"""Compute the difference of two field elements (second may be int)."""
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if isinstance(a, FE):
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return FE(self._num * a._den - self._den * a._num, self._den * a._den)
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return FE(self._num - self._den * a, self._den)
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def __rsub__(self, a):
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"""Compute the difference of an integer and a field element."""
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return FE(a) - self
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def __mul__(self, a):
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"""Compute the product of two field elements (second may be int)."""
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if isinstance(a, FE):
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return FE(self._num * a._num, self._den * a._den)
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return FE(self._num * a, self._den)
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def __rmul__(self, a):
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"""Compute the product of an integer with a field element."""
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return FE(a) * self
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def __truediv__(self, a):
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"""Compute the ratio of two field elements (second may be int)."""
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return FE(self, a)
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def __pow__(self, a):
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"""Raise a field element to an integer power."""
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return FE(pow(self._num, a, FE.SIZE), pow(self._den, a, FE.SIZE))
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def __neg__(self):
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"""Negate a field element."""
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return FE(-self._num, self._den)
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def __int__(self):
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"""Convert a field element to an integer in range 0..p-1. The result is cached."""
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if self._den != 1:
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self._num = (self._num * pow(self._den, -1, FE.SIZE)) % FE.SIZE
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self._den = 1
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return self._num
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def sqrt(self):
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"""Compute the square root of a field element if it exists (None otherwise).
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Due to the fact that our modulus is of the form (p % 4) == 3, the Tonelli-Shanks
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algorithm (https://en.wikipedia.org/wiki/Tonelli-Shanks_algorithm) is simply
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raising the argument to the power (p + 1) / 4.
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To see why: (p-1) % 2 = 0, so 2 divides the order of the multiplicative group,
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and thus only half of the non-zero field elements are squares. An element a is
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a (nonzero) square when Euler's criterion, a^((p-1)/2) = 1 (mod p), holds. We're
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looking for x such that x^2 = a (mod p). Given a^((p-1)/2) = 1, that is equivalent
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to x^2 = a^(1 + (p-1)/2) mod p. As (1 + (p-1)/2) is even, this is equivalent to
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x = a^((1 + (p-1)/2)/2) mod p, or x = a^((p+1)/4) mod p."""
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v = int(self)
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s = pow(v, (FE.SIZE + 1) // 4, FE.SIZE)
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if s**2 % FE.SIZE == v:
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return FE(s)
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return None
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def is_square(self):
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"""Determine if this field element has a square root."""
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# A more efficient algorithm is possible here (Jacobi symbol).
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return self.sqrt() is not None
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def is_even(self):
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"""Determine whether this field element, represented as integer in 0..p-1, is even."""
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return int(self) & 1 == 0
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def __eq__(self, a):
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"""Check whether two field elements are equal (second may be an int)."""
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if isinstance(a, FE):
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return (self._num * a._den - self._den * a._num) % FE.SIZE == 0
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return (self._num - self._den * a) % FE.SIZE == 0
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def to_bytes(self):
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"""Convert a field element to a 32-byte array (BE byte order)."""
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return int(self).to_bytes(32, 'big')
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@staticmethod
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def from_bytes(b):
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"""Convert a 32-byte array to a field element (BE byte order, no overflow allowed)."""
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v = int.from_bytes(b, 'big')
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if v >= FE.SIZE:
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return None
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return FE(v)
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def __str__(self):
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"""Convert this field element to a 64 character hex string."""
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return f"{int(self):064x}"
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def __repr__(self):
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"""Get a string representation of this field element."""
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return f"FE(0x{int(self):x})"
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class GE:
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"""Objects of this class represent secp256k1 group elements (curve points or infinity)
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Normal points on the curve have fields:
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* x: the x coordinate (a field element)
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* y: the y coordinate (a field element, satisfying y^2 = x^3 + 7)
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* infinity: False
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The point at infinity has field:
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* infinity: True
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"""
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# Order of the group (number of points on the curve, plus 1 for infinity)
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ORDER = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141
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# Number of valid distinct x coordinates on the curve.
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ORDER_HALF = ORDER // 2
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def __init__(self, x=None, y=None):
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"""Initialize a group element with specified x and y coordinates, or infinity."""
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if x is None:
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# Initialize as infinity.
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assert y is None
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self.infinity = True
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else:
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# Initialize as point on the curve (and check that it is).
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fx = FE(x)
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fy = FE(y)
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assert fy**2 == fx**3 + 7
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self.infinity = False
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self.x = fx
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self.y = fy
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def __add__(self, a):
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"""Add two group elements together."""
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# Deal with infinity: a + infinity == infinity + a == a.
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if self.infinity:
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return a
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if a.infinity:
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return self
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if self.x == a.x:
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if self.y != a.y:
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# A point added to its own negation is infinity.
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assert self.y + a.y == 0
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return GE()
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else:
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# For identical inputs, use the tangent (doubling formula).
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lam = (3 * self.x**2) / (2 * self.y)
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else:
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# For distinct inputs, use the line through both points (adding formula).
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lam = (self.y - a.y) / (self.x - a.x)
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# Determine point opposite to the intersection of that line with the curve.
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x = lam**2 - (self.x + a.x)
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y = lam * (self.x - x) - self.y
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return GE(x, y)
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@staticmethod
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def mul(*aps):
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"""Compute a (batch) scalar group element multiplication.
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GE.mul((a1, p1), (a2, p2), (a3, p3)) is identical to a1*p1 + a2*p2 + a3*p3,
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but more efficient."""
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# Reduce all the scalars modulo order first (so we can deal with negatives etc).
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naps = [(a % GE.ORDER, p) for a, p in aps]
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# Start with point at infinity.
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r = GE()
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# Iterate over all bit positions, from high to low.
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for i in range(255, -1, -1):
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# Double what we have so far.
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r = r + r
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# Add then add the points for which the corresponding scalar bit is set.
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for (a, p) in naps:
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if (a >> i) & 1:
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r += p
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return r
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def __rmul__(self, a):
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"""Multiply an integer with a group element."""
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if self == G:
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return FAST_G.mul(a)
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return GE.mul((a, self))
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def __neg__(self):
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"""Compute the negation of a group element."""
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if self.infinity:
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return self
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return GE(self.x, -self.y)
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def to_bytes_compressed(self):
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"""Convert a non-infinite group element to 33-byte compressed encoding."""
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assert not self.infinity
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return bytes([3 - self.y.is_even()]) + self.x.to_bytes()
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def to_bytes_uncompressed(self):
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"""Convert a non-infinite group element to 65-byte uncompressed encoding."""
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assert not self.infinity
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return b'\x04' + self.x.to_bytes() + self.y.to_bytes()
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def to_bytes_xonly(self):
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"""Convert (the x coordinate of) a non-infinite group element to 32-byte xonly encoding."""
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assert not self.infinity
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return self.x.to_bytes()
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@staticmethod
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def lift_x(x):
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"""Return group element with specified field element as x coordinate (and even y)."""
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y = (FE(x)**3 + 7).sqrt()
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if y is None:
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return None
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if not y.is_even():
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y = -y
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return GE(x, y)
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@staticmethod
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def from_bytes(b):
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"""Convert a compressed or uncompressed encoding to a group element."""
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assert len(b) in (33, 65)
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if len(b) == 33:
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if b[0] != 2 and b[0] != 3:
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return None
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x = FE.from_bytes(b[1:])
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if x is None:
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return None
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r = GE.lift_x(x)
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if r is None:
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return None
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if b[0] == 3:
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r = -r
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return r
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else:
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if b[0] != 4:
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return None
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x = FE.from_bytes(b[1:33])
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y = FE.from_bytes(b[33:])
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if y**2 != x**3 + 7:
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return None
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return GE(x, y)
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@staticmethod
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def from_bytes_xonly(b):
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"""Convert a point given in xonly encoding to a group element."""
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assert len(b) == 32
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x = FE.from_bytes(b)
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if x is None:
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return None
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return GE.lift_x(x)
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@staticmethod
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def is_valid_x(x):
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"""Determine whether the provided field element is a valid X coordinate."""
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return (FE(x)**3 + 7).is_square()
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def __str__(self):
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"""Convert this group element to a string."""
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if self.infinity:
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return "(inf)"
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return f"({self.x},{self.y})"
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def __repr__(self):
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"""Get a string representation for this group element."""
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if self.infinity:
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return "GE()"
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return f"GE(0x{int(self.x):x},0x{int(self.y):x})"
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# The secp256k1 generator point
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G = GE.lift_x(0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798)
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class FastGEMul:
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"""Table for fast multiplication with a constant group element.
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Speed up scalar multiplication with a fixed point P by using a precomputed lookup table with
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its powers of 2:
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table = [P, 2*P, 4*P, (2^3)*P, (2^4)*P, ..., (2^255)*P]
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During multiplication, the points corresponding to each bit set in the scalar are added up,
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i.e. on average ~128 point additions take place.
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"""
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def __init__(self, p):
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self.table = [p] # table[i] = (2^i) * p
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for _ in range(255):
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p = p + p
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self.table.append(p)
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def mul(self, a):
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result = GE()
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a = a % GE.ORDER
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for bit in range(a.bit_length()):
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if a & (1 << bit):
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result += self.table[bit]
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return result
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# Precomputed table with multiples of G for fast multiplication
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FAST_G = FastGEMul(G)
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