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bigint-mod-arith
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Fixed eslint problem with BigInt. It's also good for its use with webpack/babel

This commit is contained in:
Juan Hernández Serrano 2019-03-25 18:10:40 +01:00
parent 1ede4f712c
commit 1c5039b827
2 changed files with 85 additions and 82 deletions
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3
.eslintrc.json
View File

@ -23,5 +23,8 @@
"error",
"always"
]
},
"globals": {
"BigInt": "readonly"
}
}

164
src/main.js
View File

@ -8,8 +8,8 @@
* @returns {bigint} the absolute value of a
*/
const abs = function (a) {
a = BigInt(a);
return (a >= 0n) ? a : -a;
a = BigInt(a);
return (a >= BigInt(0)) ? a : -a;
};
/**
@ -21,27 +21,27 @@ const abs = function (a) {
* @returns {bigint} The greatest common divisor of a and b
*/
const gcd = function (a, b) {
a = abs(a);
b = abs(b);
let shift = 0n;
while (!((a | b) & 1n)) {
a >>= 1n;
b >>= 1n;
shift++;
}
while (!(a & 1n)) a >>= 1n;
do {
while (!(b & 1n)) b >>= 1n;
if (a > b) {
let x = a;
a = b;
b = x;
}
b -= a;
} while (b);
a = abs(a);
b = abs(b);
let shift = BigInt(0);
while (!((a | b) & BigInt(1))) {
a >>= BigInt(1);
b >>= BigInt(1);
shift++;
}
while (!(a & BigInt(1))) a >>= BigInt(1);
do {
while (!(b & BigInt(1))) b >>= BigInt(1);
if (a > b) {
let x = a;
a = b;
b = x;
}
b -= a;
} while (b);
// rescale
return a << shift;
// rescale
return a << shift;
};
/**
@ -52,9 +52,9 @@ const gcd = function (a, b) {
* @returns {bigint} The least common multiple of a and b
*/
const lcm = function (a, b) {
a = BigInt(a);
b = BigInt(b);
return abs(a * b) / gcd(a, b);
a = BigInt(a);
b = BigInt(b);
return abs(a * b) / gcd(a, b);
};
/**
@ -65,9 +65,9 @@ const lcm = function (a, b) {
* @returns {bigint} The smallest positive representation of a in modulo n
*/
const toZn = function (a, n) {
n = BigInt(n);
a = BigInt(a) % n;
return (a < 0) ? a + n : a;
n = BigInt(n);
a = BigInt(a) % n;
return (a < 0) ? a + n : a;
};
/**
@ -86,30 +86,30 @@ const toZn = function (a, n) {
* @returns {egcdReturn}
*/
const eGcd = function (a, b) {
a = BigInt(a);
b = BigInt(b);
let x = 0n;
let y = 1n;
let u = 1n;
let v = 0n;
a = BigInt(a);
b = BigInt(b);
let x = BigInt(0);
let y = BigInt(1);
let u = BigInt(1);
let v = BigInt(0);
while (a !== 0n) {
let q = b / a;
let r = b % a;
let m = x - (u * q);
let n = y - (v * q);
b = a;
a = r;
x = u;
y = v;
u = m;
v = n;
}
return {
b: b,
x: x,
y: y
}
while (a !== BigInt(0)) {
let q = b / a;
let r = b % a;
let m = x - (u * q);
let n = y - (v * q);
b = a;
a = r;
x = u;
y = v;
u = m;
v = n;
}
return {
b: b,
x: x,
y: y
};
};
/**
@ -121,12 +121,12 @@ const eGcd = function (a, b) {
* @returns {bigint} the inverse modulo n
*/
const modInv = function (a, n) {
let egcd = eGcd(a, n);
if (egcd.b !== 1n) {
return null; // modular inverse does not exist
} else {
return toZn(egcd.x, n);
}
let egcd = eGcd(a, n);
if (egcd.b !== BigInt(1)) {
return null; // modular inverse does not exist
} else {
return toZn(egcd.x, n);
}
};
/**
@ -138,32 +138,32 @@ const modInv = function (a, n) {
* @returns {bigint} a**b mod n
*/
const modPow = function (a, b, n) {
// See Knuth, volume 2, section 4.6.3.
n = BigInt(n);
a = toZn(a, n);
b = BigInt(b);
if (b < 0n) {
return modInv(modPow(a, abs(b), n), n);
}
let result = 1n;
let x = a;
while (b > 0) {
var leastSignificantBit = b % 2n;
b = b / 2n;
if (leastSignificantBit == 1n) {
result = result * x;
result = result % n;
}
x = x * x;
x = x % n;
}
return result;
// See Knuth, volume 2, section 4.6.3.
n = BigInt(n);
a = toZn(a, n);
b = BigInt(b);
if (b < BigInt(0)) {
return modInv(modPow(a, abs(b), n), n);
}
let result = BigInt(1);
let x = a;
while (b > 0) {
var leastSignificantBit = b % BigInt(2);
b = b / BigInt(2);
if (leastSignificantBit == BigInt(1)) {
result = result * x;
result = result % n;
}
x = x * x;
x = x % n;
}
return result;
};
module.exports = {
abs: abs,
gcd: gcd,
lcm: lcm,
modInv: modInv,
modPow: modPow
abs: abs,
gcd: gcd,
lcm: lcm,
modInv: modInv,
modPow: modPow
};