alexxuyang/curve.py

## curve.py
from dataclasses import dataclass

from field import FieldElement, PrimeGaloisField


@dataclass
class EllipticCurve:
    a: int
    b: int

    field: PrimeGaloisField

    def __contains__(self, point: "Point") -> bool:
        x, y = point.x, point.y
        return y ** 2 == x ** 3 + self.a * x + self.b

    def __post_init__(self):
        # Encapsulate int parameters in FieldElement
        self.a = FieldElement(self.a, self.field)
        self.b = FieldElement(self.b, self.field)

        # Check for membership of curve parameters in the field.
        if self.a not in self.field or self.b not in self.field:
            raise ValueError


# Ref: https://en.bitcoin.it/wiki/Secp256k1
# secp256k1 elliptic curve equation: y² = x³ + 7

# Prime of the finite field
P: int = (0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F)
field = PrimeGaloisField(prime=P)

# Elliptic curve parameters A and B of the curve : y² = x³ Ax + B
A: int = 0
B: int = 7

secp256k1 = EllipticCurve(a=A, b=B, field=field)

## field.py
from dataclasses import dataclass


@dataclass
class PrimeGaloisField:
    prime: int

    def __contains__(self, field_value: "FieldElement") -> bool:
        # called whenever you do: <FieldElement> in <PrimeGaloisField>
        return 0 <= field_value.value < self.prime


@dataclass
class FieldElement:
    value: int
    field: PrimeGaloisField

    def __repr__(self):
        return "0x" + f"{self.value:x}".zfill(64)

    @property
    def P(self) -> int:
        return self.field.prime

    def __add__(self, other: "FieldElement") -> "FieldElement":
        return FieldElement(value=(self.value + other.value) % self.P, field=self.field)

    def __sub__(self, other: "FieldElement") -> "FieldElement":
        return FieldElement(value=(self.value - other.value) % self.P, field=self.field)

    def __rmul__(self, scalar: int) -> "FieldValue":
        return FieldElement(value=(self.value * scalar) % self.P, field=self.field)

    def __mul__(self, other: "FieldElement") -> "FieldElement":
        return FieldElement(value=(self.value * other.value) % self.P, field=self.field)

    def __pow__(self, exponent: int) -> "FieldElement":
        return FieldElement(value=pow(self.value, exponent, self.P), field=self.field)

    def __truediv__(self, other: "FieldElement") -> "FieldElement":
        other_inv = other ** -1
        return self * other_inv

## point.py
from dataclasses import dataclass

from curve import EllipticCurve, secp256k1
from field import FieldElement

inf = float("inf")


@dataclass
class Point:
    x: int
    y: int

    curve: EllipticCurve

    def __post_init__(self):
        # Ignore validation for I
        if self.x is None and self.y is None:
            return

        # Encapsulate int coordinates in FieldElement
        self.x = FieldElement(self.x, self.curve.field)
        self.y = FieldElement(self.y, self.curve.field)

        # Verify if the point satisfies the curve equation
        if self not in self.curve:
            raise ValueError

    def __add__(self, other):
        #################################################################
        # Point Addition for P₁ or P₂ = I   (identity)                  #
        #                                                               #
        # Formula:                                                      #
        #     P + I = P                                                 #
        #     I + P = P                                                 #
        #################################################################
        if self == I:
            return other

        if other == I:
            return self

        #################################################################
        # Point Addition for X₁ = X₂   (additive inverse)               #
        #                                                               #
        # Formula:                                                      #
        #     P + (-P) = I                                              #
        #     (-P) + P = I                                              #
        #################################################################
        if self.x == other.x and self.y == (-1 * other.y):
            return I

        #################################################################
        # Point Addition for X₁ ≠ X₂   (line with slope)                #
        #                                                               #
        # Formula:                                                      #
        #     S = (Y₂ - Y₁) / (X₂ - X₁)                                 #
        #     X₃ = S² - X₁ - X₂                                         #
        #     Y₃ = S(X₁ - X₃) - Y₁                                      #
        #################################################################
        if self.x != other.x:
            x1, x2 = self.x, other.x
            y1, y2 = self.y, other.y

            s = (y2 - y1) / (x2 - x1)
            x3 = s ** 2 - x1 - x2
            y3 = s * (x1 - x3) - y1

            return self.__class__(x=x3.value, y=y3.value, curve=secp256k1)

        #################################################################
        # Point Addition for P₁ = P₂   (vertical tangent)               #
        #                                                               #
        # Formula:                                                      #
        #     S = ∞                                                     #
        #     (X₃, Y₃) = I                                              #
        #################################################################
        if self == other and self.y == inf:
            return I

        #################################################################
        # Point Addition for P₁ = P₂   (tangent with slope)             #
        #                                                               #
        # Formula:                                                      #
        #     S = (3X₁² + a) / 2Y₁         .. ∂(Y²) = ∂(X² + aX + b)    #
        #     X₃ = S² - 2X₁                                             #
        #     Y₃ = S(X₁ - X₃) - Y₁                                      #
        #################################################################
        if self == other:
            x1, y1, a = self.x, self.y, self.curve.a

            s = (3 * x1 ** 2 + a) / (2 * y1)
            x3 = s ** 2 - 2 * x1
            y3 = s * (x1 - x3) - y1

            return self.__class__(x=x3.value, y=y3.value, curve=secp256k1)

    def __rmul__(self, scalar: int) -> "Point":
        # Naive approach:
        #
        # result = I
        # for _ in range(scalar):  # or range(scalar % N)
        #     result = result + self
        # return result

        # Optimized approach using binary expansion
        current = self
        result = I
        while scalar:
            if scalar & 1:  # same as scalar % 2
                result = result + current
            current = current + current  # point doubling
            scalar >>= 1  # same as scalar / 2
        return result


# Generator point of the abelian group used in Bitcoin
G = Point(
    x=0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798,
    y=0x483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8,
    curve=secp256k1,
)

# Order of the group generated by G, such that nG = I
N = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141

I = Point(x=None, y=None, curve=secp256k1)

## signature.py
from dataclasses import dataclass
from random import randint

from point import G, N, Point


@dataclass
class PrivateKey:
    secret: int

    def sign(self, z: int) -> "Signature":
        e = self.secret
        k = randint(0, N)
        R = k * G
        r = R.x.value
        k_inv = pow(k, -1, N)  # Python 3.8+
        s = ((z + r * e) * k_inv) % N

        return Signature(r, s)


@dataclass
class Signature:
    r: int
    s: int

    def verify(self, z: int, pub_key: Point) -> bool:
        s_inv = pow(self.s, -1, N)  # Python 3.8+
        u = (z * s_inv) % N
        v = (self.r * s_inv) % N

        return (u * G + v * pub_key).x.value == self.r

## tests.py
from random import randint

from curve import secp256k1
from point import G, I, N, Point
from signature import PrivateKey, Signature

# Test case 1
assert N * G == I

# Test case 2
pub = Point(
    x=0x9577FF57C8234558F293DF502CA4F09CBC65A6572C842B39B366F21717945116,
    y=0x10B49C67FA9365AD7B90DAB070BE339A1DAF9052373EC30FFAE4F72D5E66D053,
    curve=secp256k1,
)
e: int = 2 ** 240 + 2 ** 31
assert e * G == pub

#  Test case 3
pub = Point(
    x=0x887387E452B8EACC4ACFDE10D9AAF7F6D9A0F975AABB10D006E4DA568744D06C,
    y=0x61DE6D95231CD89026E286DF3B6AE4A894A3378E393E93A0F45B666329A0AE34,
    curve=secp256k1,
)

# Test case 3.1: verify authenticity
z = 0xEC208BAA0FC1C19F708A9CA96FDEFF3AC3F230BB4A7BA4AEDE4942AD003C0F60
r = 0xAC8D1C87E51D0D441BE8B3DD5B05C8795B48875DFFE00B7FFCFAC23010D3A395
s = 0x68342CEFF8935EDEDD102DD876FFD6BA72D6A427A3EDB13D26EB0781CB423C4

assert Signature(r, s).verify(z, pub)

# Test case 3.2: verify authenticity for different signature w/ same P
z = 0x7C076FF316692A3D7EB3C3BB0F8B1488CF72E1AFCD929E29307032997A838A3D
r = 0xEFF69EF2B1BD93A66ED5219ADD4FB51E11A840F404876325A1E8FFE0529A2C
s = 0xC7207FEE197D27C618AEA621406F6BF5EF6FCA38681D82B2F06FDDBDCE6FEAB6
assert Signature(r, s).verify(z, pub)

# Test case 3.3: sign and verify
e = PrivateKey(randint(0, N))  # generate a private key
pub = e.secret * G  # public point corresponding to e
z = randint(0, 2 ** 256)  # generate a random message for testing
signature: Signature = e.sign(z)
assert signature.verify(z, pub)
	from dataclasses import dataclass

	from field import FieldElement, PrimeGaloisField


	@dataclass
	class EllipticCurve:
	a: int
	b: int

	field: PrimeGaloisField

	def __contains__(self, point: "Point") -> bool:
	x, y = point.x, point.y
	return y 2 == x 3 + self.a * x + self.b

	def __post_init__(self):
	# Encapsulate int parameters in FieldElement
	self.a = FieldElement(self.a, self.field)
	self.b = FieldElement(self.b, self.field)

	# Check for membership of curve parameters in the field.
	if self.a not in self.field or self.b not in self.field:
	raise ValueError


	# Ref: https://en.bitcoin.it/wiki/Secp256k1
	# secp256k1 elliptic curve equation: y² = x³ + 7

	# Prime of the finite field
	P: int = (0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F)
	field = PrimeGaloisField(prime=P)

	# Elliptic curve parameters A and B of the curve : y² = x³ Ax + B
	A: int = 0
	B: int = 7

	secp256k1 = EllipticCurve(a=A, b=B, field=field)
	from dataclasses import dataclass


	@dataclass
	class PrimeGaloisField:
	prime: int

	def __contains__(self, field_value: "FieldElement") -> bool:
	# called whenever you do: <FieldElement> in <PrimeGaloisField>
	return 0 <= field_value.value < self.prime


	@dataclass
	class FieldElement:
	value: int
	field: PrimeGaloisField

	def __repr__(self):
	return "0x" + f"{self.value:x}".zfill(64)

	@property
	def P(self) -> int:
	return self.field.prime

	def __add__(self, other: "FieldElement") -> "FieldElement":
	return FieldElement(value=(self.value + other.value) % self.P, field=self.field)

	def __sub__(self, other: "FieldElement") -> "FieldElement":
	return FieldElement(value=(self.value - other.value) % self.P, field=self.field)

	def __rmul__(self, scalar: int) -> "FieldValue":
	return FieldElement(value=(self.value * scalar) % self.P, field=self.field)

	def __mul__(self, other: "FieldElement") -> "FieldElement":
	return FieldElement(value=(self.value * other.value) % self.P, field=self.field)

	def __pow__(self, exponent: int) -> "FieldElement":
	return FieldElement(value=pow(self.value, exponent, self.P), field=self.field)

	def __truediv__(self, other: "FieldElement") -> "FieldElement":
	other_inv = other ** -1
	return self * other_inv
	from dataclasses import dataclass

	from curve import EllipticCurve, secp256k1
	from field import FieldElement

	inf = float("inf")


	@dataclass
	class Point:
	x: int
	y: int

	curve: EllipticCurve

	def __post_init__(self):
	# Ignore validation for I
	if self.x is None and self.y is None:
	return

	# Encapsulate int coordinates in FieldElement
	self.x = FieldElement(self.x, self.curve.field)
	self.y = FieldElement(self.y, self.curve.field)

	# Verify if the point satisfies the curve equation
	if self not in self.curve:
	raise ValueError

	def __add__(self, other):
	#################################################################
	# Point Addition for P₁ or P₂ = I (identity) #
	# #
	# Formula: #
	# P + I = P #
	# I + P = P #
	#################################################################
	if self == I:
	return other

	if other == I:
	return self

	#################################################################
	# Point Addition for X₁ = X₂ (additive inverse) #
	# #
	# Formula: #
	# P + (-P) = I #
	# (-P) + P = I #
	#################################################################
	if self.x == other.x and self.y == (-1 * other.y):
	return I

	#################################################################
	# Point Addition for X₁ ≠ X₂ (line with slope) #
	# #
	# Formula: #
	# S = (Y₂ - Y₁) / (X₂ - X₁) #
	# X₃ = S² - X₁ - X₂ #
	# Y₃ = S(X₁ - X₃) - Y₁ #
	#################################################################
	if self.x != other.x:
	x1, x2 = self.x, other.x
	y1, y2 = self.y, other.y

	s = (y2 - y1) / (x2 - x1)
	x3 = s ** 2 - x1 - x2
	y3 = s * (x1 - x3) - y1

	return self.__class__(x=x3.value, y=y3.value, curve=secp256k1)

	#################################################################
	# Point Addition for P₁ = P₂ (vertical tangent) #
	# #
	# Formula: #
	# S = ∞ #
	# (X₃, Y₃) = I #
	#################################################################
	if self == other and self.y == inf:
	return I

	#################################################################
	# Point Addition for P₁ = P₂ (tangent with slope) #
	# #
	# Formula: #
	# S = (3X₁² + a) / 2Y₁ .. ∂(Y²) = ∂(X² + aX + b) #
	# X₃ = S² - 2X₁ #
	# Y₃ = S(X₁ - X₃) - Y₁ #
	#################################################################
	if self == other:
	x1, y1, a = self.x, self.y, self.curve.a

	s = (3 * x1 ** 2 + a) / (2 * y1)
	x3 = s ** 2 - 2 * x1
	y3 = s * (x1 - x3) - y1

	return self.__class__(x=x3.value, y=y3.value, curve=secp256k1)

	def __rmul__(self, scalar: int) -> "Point":
	# Naive approach:
	#
	# result = I
	# for _ in range(scalar): # or range(scalar % N)
	# result = result + self
	# return result

	# Optimized approach using binary expansion
	current = self
	result = I
	while scalar:
	if scalar & 1: # same as scalar % 2
	result = result + current
	current = current + current # point doubling
	scalar >>= 1 # same as scalar / 2
	return result


	# Generator point of the abelian group used in Bitcoin
	G = Point(
	x=0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798,
	y=0x483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8,
	curve=secp256k1,
	)

	# Order of the group generated by G, such that nG = I
	N = 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141

	I = Point(x=None, y=None, curve=secp256k1)
	from dataclasses import dataclass
	from random import randint

	from point import G, N, Point


	@dataclass
	class PrivateKey:
	secret: int

	def sign(self, z: int) -> "Signature":
	e = self.secret
	k = randint(0, N)
	R = k * G
	r = R.x.value
	k_inv = pow(k, -1, N) # Python 3.8+
	s = ((z + r * e) * k_inv) % N

	return Signature(r, s)


	@dataclass
	class Signature:
	r: int
	s: int

	def verify(self, z: int, pub_key: Point) -> bool:
	s_inv = pow(self.s, -1, N) # Python 3.8+
	u = (z * s_inv) % N
	v = (self.r * s_inv) % N

	return (u * G + v * pub_key).x.value == self.r
	from random import randint

	from curve import secp256k1
	from point import G, I, N, Point
	from signature import PrivateKey, Signature

	# Test case 1
	assert N * G == I

	# Test case 2
	pub = Point(
	x=0x9577FF57C8234558F293DF502CA4F09CBC65A6572C842B39B366F21717945116,
	y=0x10B49C67FA9365AD7B90DAB070BE339A1DAF9052373EC30FFAE4F72D5E66D053,
	curve=secp256k1,
	)
	e: int = 2 240 + 2 31
	assert e * G == pub

	# Test case 3
	pub = Point(
	x=0x887387E452B8EACC4ACFDE10D9AAF7F6D9A0F975AABB10D006E4DA568744D06C,
	y=0x61DE6D95231CD89026E286DF3B6AE4A894A3378E393E93A0F45B666329A0AE34,
	curve=secp256k1,
	)

	# Test case 3.1: verify authenticity
	z = 0xEC208BAA0FC1C19F708A9CA96FDEFF3AC3F230BB4A7BA4AEDE4942AD003C0F60
	r = 0xAC8D1C87E51D0D441BE8B3DD5B05C8795B48875DFFE00B7FFCFAC23010D3A395
	s = 0x68342CEFF8935EDEDD102DD876FFD6BA72D6A427A3EDB13D26EB0781CB423C4

	assert Signature(r, s).verify(z, pub)

	# Test case 3.2: verify authenticity for different signature w/ same P
	z = 0x7C076FF316692A3D7EB3C3BB0F8B1488CF72E1AFCD929E29307032997A838A3D
	r = 0xEFF69EF2B1BD93A66ED5219ADD4FB51E11A840F404876325A1E8FFE0529A2C
	s = 0xC7207FEE197D27C618AEA621406F6BF5EF6FCA38681D82B2F06FDDBDCE6FEAB6
	assert Signature(r, s).verify(z, pub)

	# Test case 3.3: sign and verify
	e = PrivateKey(randint(0, N)) # generate a private key
	pub = e.secret * G # public point corresponding to e
	z = randint(0, 2 ** 256) # generate a random message for testing
	signature: Signature = e.sign(z)
	assert signature.verify(z, pub)