Other two answers using module fastecdsa are correct, but you may want to implement elliptic curve arithmetics from scratch without any external non-standard modules, for educational purposes and just for fun of learning.

So did I, below I present my code that implements Elliptic Curve Points Addition and Multiplication (read linked Wiki, it has all math described) from scratch, without using any non-standard modules. Mathematics of elliptic curves is quite simple and can be fully implemented in few dozens lines of code in Python.

Params of standard curve `secp256k1`

I've taken from BitCoin wiki page, also this curve params and other curves like `secp256r1`

, `secp384r1`

, `secp521r1`

are taken from public SECG pdf. These params give coordinate and params of so called base point.

Afterwards public key is just base point (standard curve point) multiplied by private key (integer). While private key is simple big integer, public key is elliptic curve point represented by two integer coordinates (X, Y) and standard non-modifiable params (A, B, P, Q).

In my code you can uncomment `#import gmpy2`

line if you want for some reason use external gmpy2 library and have installed it through `python -m pip install gmpy2`

. This library gives around `2x`

speedup of all curves mathematics. But you don't need to uncomment this line, usage of this library is non-compulsory, my code works with just standard Python modules pretty fast.

Code below as an example computes private key presented in your question, prints it, computes public key and prints X and Y coordinates of public key. As you can see obtained public key is identical to public key printed in other answer, obtained through fastecdsa.

Console output of my program (printed private and public keys) can be seen after the code.

Try it online!

```
class ECPoint:
gmpy2 = None
#import gmpy2
import random
class InvError(Exception):
def __init__(self, *pargs):
self.value = pargs
@classmethod
def Int(cls, x):
return int(x) if cls.gmpy2 is None else cls.gmpy2.mpz(x)
@classmethod
def std_point(cls, t):
if t == 'secp256k1':
# https://en.bitcoin.it/wiki/Secp256k1
# https://www.secg.org/sec2-v2.pdf
p = 0xFFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFE_FFFFFC2F
a = 0
b = 7
x = 0x79BE667E_F9DCBBAC_55A06295_CE870B07_029BFCDB_2DCE28D9_59F2815B_16F81798
y = 0x483ADA77_26A3C465_5DA4FBFC_0E1108A8_FD17B448_A6855419_9C47D08F_FB10D4B8
q = 0xFFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFE_BAAEDCE6_AF48A03B_BFD25E8C_D0364141
elif t == 'secp256r1':
# https://www.secg.org/sec2-v2.pdf
p = 0xFFFFFFFF_00000001_00000000_00000000_00000000_FFFFFFFF_FFFFFFFF_FFFFFFFF
a = 0xFFFFFFFF_00000001_00000000_00000000_00000000_FFFFFFFF_FFFFFFFF_FFFFFFFC
b = 0x5AC635D8_AA3A93E7_B3EBBD55_769886BC_651D06B0_CC53B0F6_3BCE3C3E_27D2604B
x = 0x6B17D1F2_E12C4247_F8BCE6E5_63A440F2_77037D81_2DEB33A0_F4A13945_D898C296
y = 0x4FE342E2_FE1A7F9B_8EE7EB4A_7C0F9E16_2BCE3357_6B315ECE_CBB64068_37BF51F5
q = 0xFFFFFFFF_00000000_FFFFFFFF_FFFFFFFF_BCE6FAAD_A7179E84_F3B9CAC2_FC632551
elif t == 'secp384r1':
# https://www.secg.org/sec2-v2.pdf
p = 0xFFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFE_FFFFFFFF_00000000_00000000_FFFFFFFF
a = 0xFFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFE_FFFFFFFF_00000000_00000000_FFFFFFFC
b = 0xB3312FA7_E23EE7E4_988E056B_E3F82D19_181D9C6E_FE814112_0314088F_5013875A_C656398D_8A2ED19D_2A85C8ED_D3EC2AEF
x = 0xAA87CA22_BE8B0537_8EB1C71E_F320AD74_6E1D3B62_8BA79B98_59F741E0_82542A38_5502F25D_BF55296C_3A545E38_72760AB7
y = 0x3617DE4A_96262C6F_5D9E98BF_9292DC29_F8F41DBD_289A147C_E9DA3113_B5F0B8C0_0A60B1CE_1D7E819D_7A431D7C_90EA0E5F
q = 0xFFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_C7634D81_F4372DDF_581A0DB2_48B0A77A_ECEC196A_CCC52973
elif t == 'secp521r1':
# https://www.secg.org/sec2-v2.pdf
p = 2 ** 521 - 1
a = 2 ** 521 - 4
b = 0x0051_953EB961_8E1C9A1F_929A21A0_B68540EE_A2DA725B_99B315F3_B8B48991_8EF109E1_56193951_EC7E937B_1652C0BD_3BB1BF07_3573DF88_3D2C34F1_EF451FD4_6B503F00
x = 0x00C6_858E06B7_0404E9CD_9E3ECB66_2395B442_9C648139_053FB521_F828AF60_6B4D3DBA_A14B5E77_EFE75928_FE1DC127_A2FFA8DE_3348B3C1_856A429B_F97E7E31_C2E5BD66
y = 0x0118_39296A78_9A3BC004_5C8A5FB4_2C7D1BD9_98F54449_579B4468_17AFBD17_273E662C_97EE7299_5EF42640_C550B901_3FAD0761_353C7086_A272C240_88BE9476_9FD16650
q = 0x01FF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFF_FFFFFFFA_51868783_BF2F966B_7FCC0148_F709A5D0_3BB5C9B8_899C47AE_BB6FB71E_91386409
else:
assert False
return ECPoint(a, b, p, x, y, q = q)
def __init__(self, A, B, N, x, y, *, q = 0, prepare = True):
if prepare:
N = self.Int(N)
A, B, x, y, q = [self.Int(e) % N for e in [A, B, x, y, q]]
assert (4 * A ** 3 + 27 * B ** 2) % N != 0
assert (y ** 2 - x ** 3 - A * x - B) % N == 0, (hex(N), hex((y ** 2 - x ** 3 - A * x) % N))
assert N % 4 == 3
assert y == pow(x ** 3 + A * x + B, (N + 1) // 4, N)
self.A, self.B, self.N, self.x, self.y, self.q = A, B, N, x, y, q
def __add__(self, other):
A, B, N = self.A, self.B, self.N
Px, Py, Qx, Qy = self.x, self.y, other.x, other.y
if Px == Qx and Py == Qy:
s = ((Px * Px * 3 + A) * self.inv(Py * 2, N)) % N
else:
s = ((Py - Qy) * self.inv(Px - Qx, N)) % N
x = (s * s - Px - Qx) % N
y = (s * (Px - x) - Py) % N
return ECPoint(A, B, N, x, y, prepare = False)
def __rmul__(self, other):
assert other >= 1
if other == 1:
return self
other = self.Int(other - 1)
r = self
while True:
if other & 1:
r = r + self
if other == 1:
return r
other >>= 1
self = self + self
@classmethod
def inv(cls, a, n):
a %= n
if cls.gmpy2 is None:
try:
return pow(a, -1, n)
except ValueError:
import math
raise cls.InvError(math.gcd(a, n), a, n)
else:
g, s, t = cls.gmpy2.gcdext(a, n)
if g != 1:
raise cls.InvError(g, a, n)
return s % n
def __repr__(self):
return str(dict(x = self.x, y = self.y, A = self.A, B = self.B, N = self.N, q = self.q))
def __eq__(self, other):
for i, (a, b) in enumerate([(self.x, other.x), (self.y, other.y), (self.A, other.A),
(self.B, other.B), (self.N, other.N), (self.q, other.q)]):
if a != b:
return False
return True
def get_pub(priv_key):
bp = ECPoint.std_point('secp256k1')
pub = priv_key * bp
return pub.x, pub.y
def main():
import hashlib
priv_key = int(hashlib.sha3_256(b"Led Zeppelin - No Quarter").hexdigest(), 16)
print('priv key :', hex(priv_key))
pubx, puby = get_pub(priv_key)
print('pub key x:', hex(pubx))
print('pub key y:', hex(puby))
main()
```

Output:

```
priv key : 0xc0b279f18074de51d075b152c8ce78b7bddb284e8cfde19896162abec0a0acce
pub key x: 0xbaa41af234cb2744ddaa039929c6ff21f0d5ab5ebce045d4a7513236f9bd429a
pub key y: 0x30252bd111b42e5195355f7fbcb5d6586ae76facbb4b7118fa96a2e99b40f716
```