# BigInteger.js [![Build Status][travis-img]][travis-url] [![Coverage Status][coveralls-img]][coveralls-url] [![Monthly Downloads][downloads-img]][downloads-url] [travis-url]: https://travis-ci.org/peterolson/BigInteger.js [travis-img]: https://travis-ci.org/peterolson/BigInteger.js.svg?branch=master [coveralls-url]: https://coveralls.io/github/peterolson/BigInteger.js?branch=master [coveralls-img]: https://coveralls.io/repos/peterolson/BigInteger.js/badge.svg?branch=master&service=github [downloads-url]: https://www.npmjs.com/package/big-integer [downloads-img]: https://img.shields.io/npm/dm/big-integer.svg **BigInteger.js** is an arbitrary-length integer library for Javascript, allowing arithmetic operations on integers of unlimited size, notwithstanding memory and time limitations. ## Installation If you are using a browser, you can download [BigInteger.js from GitHub](http://peterolson.github.com/BigInteger.js/BigInteger.min.js) or just hotlink to it: If you are using node, you can install BigInteger with [npm](https://npmjs.org/). npm install big-integer Then you can include it in your code: var bigInt = require("big-integer"); ## Usage ### `bigInt(number, [base])` You can create a bigInt by calling the `bigInt` function. You can pass in - a string, which it will parse as an bigInt and throw an `"Invalid integer"` error if the parsing fails. - a Javascript number, which it will parse as an bigInt and throw an `"Invalid integer"` error if the parsing fails. - another bigInt. - nothing, and it will return `bigInt.zero`. If you provide a second parameter, then it will parse `number` as a number in base `base`. Note that `base` can be any bigInt (even negative or zero). The letters "a-z" and "A-Z" will be interpreted as the numbers 10 to 35. Higher digits can be specified in angle brackets (`<` and `>`). Examples: var zero = bigInt(); var ninetyThree = bigInt(93); var largeNumber = bigInt("75643564363473453456342378564387956906736546456235345"); var googol = bigInt("1e100"); var bigNumber = bigInt(largeNumber); var maximumByte = bigInt("FF", 16); var fiftyFiveGoogol = bigInt("<55>0", googol); Note that Javascript numbers larger than `9007199254740992` and smaller than `-9007199254740992` are not precisely represented numbers and will not produce exact results. If you are dealing with numbers outside that range, it is better to pass in strings. ### Method Chaining Note that bigInt operations return bigInts, which allows you to chain methods, for example: var salary = bigInt(dollarsPerHour).times(hoursWorked).plus(randomBonuses) ### Constants There are three named constants already stored that you do not have to construct with the `bigInt` function yourself: - `bigInt.one`, equivalent to `bigInt(1)` - `bigInt.zero`, equivalent to `bigInt(0)` - `bigInt.minusOne`, equivalent to `bigInt(-1)` The numbers from -999 to 999 are also already prestored and can be accessed using `bigInt[index]`, for example: - `bigInt[-999]`, equivalent to `bigInt(-999)` - `bigInt[256]`, equivalent to `bigInt(256)` ### Methods #### `abs()` Returns the absolute value of a bigInt. - `bigInt(-45).abs()` => `45` - `bigInt(45).abs()` => `45` #### `add(number)` Performs addition. - `bigInt(5).add(7)` => `12` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Addition) #### `and(number)` Performs the bitwise AND operation. The operands are treated as if they were represented using [two's complement representation](http://en.wikipedia.org/wiki/Two%27s_complement). - `bigInt(6).and(3)` => `2` - `bigInt(6).and(-3)` => `4` #### `compare(number)` Performs a comparison between two numbers. If the numbers are equal, it returns `0`. If the first number is greater, it returns `1`. If the first number is lesser, it returns `-1`. - `bigInt(5).compare(5)` => `0` - `bigInt(5).compare(4)` => `1` - `bigInt(4).compare(5)` => `-1` #### `compareAbs(number)` Performs a comparison between the absolute value of two numbers. - `bigInt(5).compareAbs(-5)` => `0` - `bigInt(5).compareAbs(4)` => `1` - `bigInt(4).compareAbs(-5)` => `-1` #### `compareTo(number)` Alias for the `compare` method. #### `divide(number)` Performs integer division, disregarding the remainder. - `bigInt(59).divide(5)` => `11` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Division) #### `divmod(number)` Performs division and returns an object with two properties: `quotient` and `remainder`. The sign of the remainder will match the sign of the dividend. - `bigInt(59).divmod(5)` => `{quotient: bigInt(11), remainder: bigInt(4) }` - `bigInt(-5).divmod(2)` => `{quotient: bigInt(-2), remainder: bigInt(-1) }` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Division) #### `eq(number)` Alias for the `equals` method. #### `equals(number)` Checks if two numbers are equal. - `bigInt(5).equals(5)` => `true` - `bigInt(4).equals(7)` => `false` #### `geq(number)` Alias for the `greaterOrEquals` method. #### `greater(number)` Checks if the first number is greater than the second. - `bigInt(5).greater(6)` => `false` - `bigInt(5).greater(5)` => `false` - `bigInt(5).greater(4)` => `true` #### `greaterOrEquals(number)` Checks if the first number is greater than or equal to the second. - `bigInt(5).greaterOrEquals(6)` => `false` - `bigInt(5).greaterOrEquals(5)` => `true` - `bigInt(5).greaterOrEquals(4)` => `true` #### `gt(number)` Alias for the `greater` method. #### `isDivisibleBy(number)` Returns `true` if the first number is divisible by the second number, `false` otherwise. - `bigInt(999).isDivisibleBy(333)` => `true` - `bigInt(99).isDivisibleBy(5)` => `false` #### `isEven()` Returns `true` if the number is even, `false` otherwise. - `bigInt(6).isEven()` => `true` - `bigInt(3).isEven()` => `false` #### `isNegative()` Returns `true` if the number is negative, `false` otherwise. Returns `false` for `0` and `-0`. - `bigInt(-23).isNegative()` => `true` - `bigInt(50).isNegative()` => `false` #### `isOdd()` Returns `true` if the number is odd, `false` otherwise. - `bigInt(13).isOdd()` => `true` - `bigInt(40).isOdd()` => `false` #### `isPositive()` Return `true` if the number is positive, `false` otherwise. Returns `false` for `0` and `-0`. - `bigInt(54).isPositive()` => `true` - `bigInt(-1).isPositive()` => `false` #### `isPrime()` Returns `true` if the number is prime, `false` otherwise. - `bigInt(5).isPrime()` => `true` - `bigInt(6).isPrime()` => `false` #### `isProbablePrime([iterations])` Returns `true` if the number is very likely to be prime, `false` otherwise. Argument is optional and determines the amount of iterations of the test (default: `5`). The more iterations, the lower chance of getting a false positive. This uses the [Fermat primality test](https://en.wikipedia.org/wiki/Fermat_primality_test). - `bigInt(5).isProbablePrime()` => `true` - `bigInt(49).isProbablePrime()` => `false` - `bigInt(1729).isProbablePrime(50)` => `false` Note that this function is not deterministic, since it relies on random sampling of factors, so the result for some numbers is not always the same. [Carmichael numbers](https://en.wikipedia.org/wiki/Carmichael_number) are particularly prone to give unreliable results. For example, `bigInt(1729).isProbablePrime()` returns `false` about 76% of the time and `true` about 24% of the time. The correct result is `false`. #### `isUnit()` Returns `true` if the number is `1` or `-1`, `false` otherwise. - `bigInt.one.isUnit()` => `true` - `bigInt.minusOne.isUnit()` => `true` - `bigInt(5).isUnit()` => `false` #### `isZero()` Return `true` if the number is `0` or `-0`, `false` otherwise. - `bigInt.zero.isZero()` => `true` - `bigInt("-0").isZero()` => `true` - `bigInt(50).isZero()` => `false` #### `leq(number)` Alias for the `lesserOrEquals` method. #### `lesser(number)` Checks if the first number is lesser than the second. - `bigInt(5).lesser(6)` => `true` - `bigInt(5).lesser(5)` => `false` - `bigInt(5).lesser(4)` => `false` #### `lesserOrEquals(number)` Checks if the first number is less than or equal to the second. - `bigInt(5).lesserOrEquals(6)` => `true` - `bigInt(5).lesserOrEquals(5)` => `true` - `bigInt(5).lesserOrEquals(4)` => `false` #### `lt(number)` Alias for the `lesser` method. #### `minus(number)` Alias for the `subtract` method. - `bigInt(3).minus(5)` => `-2` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Subtraction) #### `mod(number)` Performs division and returns the remainder, disregarding the quotient. The sign of the remainder will match the sign of the dividend. - `bigInt(59).mod(5)` => `4` - `bigInt(-5).mod(2)` => `-1` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Division) #### `modInv(mod)` Finds the [multiplicative inverse](https://en.wikipedia.org/wiki/Modular_multiplicative_inverse) of the number modulo `mod`. - `bigInt(3).modInv(11)` => `4` - `bigInt(42).modInv(2017)` => `1969` #### `modPow(exp, mod)` Takes the number to the power `exp` modulo `mod`. - `bigInt(10).modPow(3, 30)` => `10` #### `multiply(number)` Performs multiplication. - `bigInt(111).multiply(111)` => `12321` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Multiplication) #### `neq(number)` Alias for the `notEquals` method. #### `next()` Adds one to the number. - `bigInt(6).next()` => `7` #### `not()` Performs the bitwise NOT operation. The operands are treated as if they were represented using [two's complement representation](http://en.wikipedia.org/wiki/Two%27s_complement). - `bigInt(10).not()` => `-11` - `bigInt(0).not()` => `-1` #### `notEquals(number)` Checks if two numbers are not equal. - `bigInt(5).notEquals(5)` => `false` - `bigInt(4).notEquals(7)` => `true` #### `or(number)` Performs the bitwise OR operation. The operands are treated as if they were represented using [two's complement representation](http://en.wikipedia.org/wiki/Two%27s_complement). - `bigInt(13).or(10)` => `15` - `bigInt(13).or(-8)` => `-3` #### `over(number)` Alias for the `divide` method. - `bigInt(59).over(5)` => `11` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Division) #### `plus(number)` Alias for the `add` method. - `bigInt(5).plus(7)` => `12` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Addition) #### `pow(number)` Performs exponentiation. If the exponent is less than `0`, `pow` returns `0`. `bigInt.zero.pow(0)` returns `1`. - `bigInt(16).pow(16)` => `18446744073709551616` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Exponentiation) #### `prev(number)` Subtracts one from the number. - `bigInt(6).prev()` => `5` #### `remainder(number)` Alias for the `mod` method. [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Division) #### `shiftLeft(n)` Shifts the number left by `n` places in its binary representation. If a negative number is provided, it will shift right. Throws an error if `n` is outside of the range `[-9007199254740992, 9007199254740992]`. - `bigInt(8).shiftLeft(2)` => `32` - `bigInt(8).shiftLeft(-2)` => `2` #### `shiftRight(n)` Shifts the number right by `n` places in its binary representation. If a negative number is provided, it will shift left. Throws an error if `n` is outside of the range `[-9007199254740992, 9007199254740992]`. - `bigInt(8).shiftRight(2)` => `2` - `bigInt(8).shiftRight(-2)` => `32` #### `square()` Squares the number - `bigInt(3).square()` => `9` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Squaring) #### `subtract(number)` Performs subtraction. - `bigInt(3).subtract(5)` => `-2` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Subtraction) #### `times(number)` Alias for the `multiply` method. - `bigInt(111).times(111)` => `12321` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#Multiplication) #### `toJSNumber()` Converts a bigInt into a native Javascript number. Loses precision for numbers outside the range `[-9007199254740992, 9007199254740992]`. - `bigInt("18446744073709551616").toJSNumber()` => `18446744073709552000` #### `xor(number)` Performs the bitwise XOR operation. The operands are treated as if they were represented using [two's complement representation](http://en.wikipedia.org/wiki/Two%27s_complement). - `bigInt(12).xor(5)` => `9` - `bigInt(12).xor(-5)` => `-9` ### Static Methods #### `fromArray(digits, base = 10, isNegative?)` Constructs a bigInt from an array of digits in base `base`. The optional `isNegative` flag will make the number negative. - `bigInt.fromArray([1, 2, 3, 4, 5], 10)` => `12345` - `bigInt.fromArray([1, 0, 0], 2, true)` => `-4` #### `gcd(a, b)` Finds the greatest common denominator of `a` and `b`. - `bigInt.gcd(42,56)` => `14` #### `isInstance(x)` Returns `true` if `x` is a BigInteger, `false` otherwise. - `bigInt.isInstance(bigInt(14))` => `true` - `bigInt.isInstance(14)` => `false` #### `lcm(a,b)` Finds the least common multiple of `a` and `b`. - `bigInt.lcm(21, 6)` => `42` #### `max(a,b)` Returns the largest of `a` and `b`. - `bigInt.max(77, 432)` => `432` #### `min(a,b)` Returns the smallest of `a` and `b`. - `bigInt.min(77, 432)` => `77` #### `randBetween(min, max)` Returns a random number between `min` and `max`. - `bigInt.randBetween("-1e100", "1e100")` => (for example) `8494907165436643479673097939554427056789510374838494147955756275846226209006506706784609314471378745` ### Override Methods #### `toString(radix = 10)` Converts a bigInt to a string. There is an optional radix parameter (which defaults to 10) that converts the number to the given radix. Digits in the range `10-35` will use the letters `a-z`. - `bigInt("1e9").toString()` => `"1000000000"` - `bigInt("1e9").toString(16)` => `"3b9aca00"` **Note that arithmetical operators will trigger the `valueOf` function rather than the `toString` function.** When converting a bigInteger to a string, you should use the `toString` method or the `String` function instead of adding the empty string. - `bigInt("999999999999999999").toString()` => `"999999999999999999"` - `String(bigInt("999999999999999999"))` => `"999999999999999999"` - `bigInt("999999999999999999") + ""` => `1000000000000000000` Bases larger than 36 are supported. If a digit is greater than or equal to 36, it will be enclosed in angle brackets. - `bigInt(567890).toString(100)` => `"<56><78><90>"` Negative bases are also supported. - `bigInt(12345).toString(-10)` => `"28465"` Base 1 and base -1 are also supported. - `bigInt(-15).toString(1)` => `"-111111111111111"` - `bigInt(-15).toString(-1)` => `"101010101010101010101010101010"` Base 0 is only allowed for the number zero. - `bigInt(0).toString(0)` => `0` - `bigInt(1).toString(0)` => `Error: Cannot convert nonzero numbers to base 0.` [View benchmarks for this method](http://peterolson.github.io/BigInteger.js/benchmark/#toString) #### `valueOf()` Converts a bigInt to a native Javascript number. This override allows you to use native arithmetic operators without explicit conversion: - `bigInt("100") + bigInt("200") === 300; //true` ## Contributors To contribute, just fork the project, make some changes, and submit a pull request. Please verify that the unit tests pass before submitting. The unit tests are contained in the `spec/spec.js` file. You can run them locally by opening the `spec/SpecRunner.html` or file or running `npm test`. You can also [run the tests online from GitHub](http://peterolson.github.io/BigInteger.js/spec/SpecRunner.html). There are performance benchmarks that can be viewed from the `benchmarks/index.html` page. You can [run them online from GitHub](http://peterolson.github.io/BigInteger.js/benchmark/). ## License This project is public domain. For more details, read about the [Unlicense](http://unlicense.org/).