Generate repeatable pseudo random numbers and non-cryptographic hash numbers for usage in Node.js (>= 8) and browser environments (major browsers and IE >= 10).
- Update to version 4
- Usage
- Development
- Disclaimer
- Change
murmurHash
tomurmurhash2_x86_32
(same function since v2, alias now removed). - Non ASCII characters (e.g. chinese or emoji) are now handled properly. This can produce different results if these characters where used before inside an input hash for all murmur hash functions.
This library (7.89 KB, gzipped size: 3.1 KB) contains the following methods: one PRNG (pseudo random number generator) called Alea and four number hash generators, MurmurHash2 and MurmurHash3 for 32 and 128 bit (x86 and x64) hash strings.
More about the hash function MurmurHash can be found here on wikipedia.
Based on your package manager you can install it via:
# NPM
npm install number-generator
# Yarn
yarn add number-generator
# pnpm
pnpm add number-generator
After that you can import it either as a library, e.g.:
// ESM
import * as numberGenerator from "number-generator";
// CJS
const numberGenerator = require("number-generator");
Or as single functions:
// ESM
import aleaRNGFactory from "number-generator/lib/aleaRNGFactory";
import murmurhash2_x86_32 from "number-generator/lib/murmurhash2_x86_32";
import murmurhash3_x86_32 from "number-generator/lib/murmurhash3_x86_32";
import murmurhash3_x86_128 from "number-generator/lib/murmurhash3_x86_128";
import murmurhash3_x64_128 from "number-generator/lib/murmurhash3_x64_128";
// CJS
const aleaRNGFactory = require("number-generator/lib/aleaRNGFactory");
const murmurhash2_x86_32 = require("number-generator/lib/murmurhash2_x86_32");
const murmurhash3_x86_32 = require("number-generator/lib/murmurhash3_x86_32");
const murmurhash3_x86_128 = require("number-generator/lib/murmurhash3_x86_128");
const murmurhash3_x64_128 = require("number-generator/lib/murmurhash3_x64_128");
Also, the library can safely be tree shaked. If tree shaking is used in e.g. Rollup or Webpack this will only put the used function with helpers in your bundle:
import { aleaRNGFactory } from "number-generator";
For use with TypeScript take a look at the usage with typescript section of this document.
Remark: For direct browser usage you can use the exposed numberGenerator
global, e.g.:
// Direct browser usage e.g.:
numberGenerator.murmurhash2_x86_32("something");
All supported environments are listed under the support section.
You can use the aleaRNGFactory
method to generate (pseudo) random numbers based on a seed (default seed is 1
). Every seed produces the same result for the created getter method.
1
should not be used! It produces one duplicate at 4370 calls. This can be avoided by using a seed larger or equal to 2. Nevertheless, this is still included in the library to not break applications using the default behavior.
First step is to include the library functions you want to use in your application. If you only want to use the Alea implementation you can import it directly:
const aleaRNGFactory = require("number-generator/lib/aleaRNGFactory");
Now you can create a new generator by calling the function with a seed equal or larger to 2. The number 0
, float or negative numbers are not valid and will throw a TypeError
. See the remark at the beginning of this section on why to avoid 1 as a seed.
// Valid:
const generator1 = aleaRNGFactory(2);
const generator2 = aleaRNGFactory(4836325);
// Invalid:
const notValidGen1 = aleaRNGFactory(0);
const notValidGen2 = aleaRNGFactory(0.47);
const notValidGen3 = aleaRNGFactory(-1);
If you have a valid generator object you can use the uInt32
method to get a random unsigned integer. Call it multiple times to get new numbers.
const { uInt32 } = aleaRNGFactory(10);
uInt32(); // 20916391
uInt32(); // 1567221093
This will create the exact same result on your machine! You will always get the same value for the same seed.
This means if you create multiple generators with the same seed, you get the same result for the n-th call:
const generator1 = aleaRNGFactory(2);
const generator2 = aleaRNGFactory(2);
const value1 = generator1.uInt32();
const value2 = generator2.uInt32();
value1 === value2; // true
The same that works for the uInt32 method applies to the uFloat32
method, but this time you get an unsigned float.
const { uFloat32 } = aleaRNGFactory(5);
uFloat32(); // 0.0024349885061383247
uFloat32(); // 0.1826920467428863
Again, this will create the exact same result on your machine!
If you create multiple generators with the same seed, you get the same result for the n-th call:
const generator1 = aleaRNGFactory(4);
const generator2 = aleaRNGFactory(4);
const value1 = generator1.uFloat32();
const value2 = generator2.uFloat32();
value1 === value2; // true
You can change the seed used by the generator object with the setSeed
method.
const generator = aleaRNGFactory(2);
// Get some random numbers
generator.uInt32();
generator.uInt32();
// Change seed
generator.setSeed(3);
// Get some more random numbers
generator.uInt32();
generator.uInt32();
You can get and restore the internal state with getState
and setState
.
const generator = aleaRNGFactory(42);
generator.uInt32();
generator.uInt32();
const state = generator.getState(); // Get the generator state
const value1 = generator.uInt32();
generator.uInt32();
generator.uInt32();
generator.setState(state); // Restore the previous state
const value2 = generator.uInt32();
value1 === value2; // true
For TypeScript the state interface is NumberGeneratorState
.
import { aleaRNGFactory, NumberGeneratorState } from "number-generator";
const generator = aleaRNGFactory(2);
generator.uInt32();
const state: NumberGeneratorState = generator.getState();
You can set the state with setState
on two ways. Either you don't pass any parameter to the state function, where it will reset the state to the initial state. Or you can pass a state object to restore a previous state:
const generator = aleaRNGFactory(2);
generator.uInt32();
const state = generator.getState();
generator.setState(); // Reset the state
generator.uInt32(); // Get a new value
generator.setState(state); // Restore saved state
If you want something similar to Math.random()
(without generating duplicated values) you can use the JavaScript Date API with a timestamp and combine it with the uFloat32
method from the aleaRNGFactory
e.g.:
const { uFloat32: random } = aleaRNGFactory(Date.now());
// Get a random float number
random();
To generate a hash there are four functions, murmurhash2_x86_32
, murmurhash3_x86_32
, murmurhash3_x86_128
and murmurhash3_x64_128
. The "murmur hash" functions implement the MurmurHash algorithm for 32 and 128 bit in JavaScript (murmurhash2 and 3) for x86 and x64. They take a string and generate a non-cryptographic hash number as an unsigned integer with 32 bit or a string hash with 128 bit.
You can import the functions directly:
const murmurhash2_x86_32 = require("number-generator/lib/murmurhash2_x86_32");
const murmurhash3_x86_32 = require("number-generator/lib/murmurhash3_x86_32");
const murmurhash3_x86_128 = require("number-generator/lib/murmurhash3_x86_128");
const murmurhash3_x64_128 = require("number-generator/lib/murmurhash3_x64_128");
Both murmurhash2_x86_32
and murmurhash3_x86_32
will generate an unsigned 32-bit number. The murmurhash3_x86_128
and murmurhash3_x64_128
functions will generate a 128 bit string. To showcase the difference:
murmurhash2_x86_32("Hello"); // 1826530862
murmurhash3_x86_32("Hello"); // 316307400
murmurhash3_x86_128("Hello"); // "2360ae465e6336c6ad45b3f4ad45b3f4"
murmurhash3_x64_128("Hello"); // "35b974ff55d4c41ca000eacf29125544"
All murmur hash functions work the same. So the following examples will take the murmur hash 2 function to demonstrate the usage. To use it pass a string to generate the hash number. The default seed used is 0
.
const hash1 = murmurhash2_x86_32("My string.");
const hash2 = murmurhash2_x86_32("My string.", 0);
hash1; // 1836966117
hash1 === hash2; // true
This will create the exact same result on your machine!
Different seeds generate different results for the same input string. Only whole numbers are valid seeds for any murmur hash function!
const hash1 = murmurhash2_x86_32("My string.", 1);
const hash2 = murmurhash2_x86_32("My string.", 2);
hash1 === hash2; // false
A float number as a seed throws a TypeError
:
const hash = murmurhash2_x86_32("My string.", 0.7); // TypeError!
This package contains all the type definitions for TypeScript. Every murmur hash function implements the NumberHashGenerator
interface.
import {
NumberGenerator,
NumberHashGenerator,
aleaRNGFactory,
murmurhash2_x86_32,
murmurhash3_x86_32,
} from "number-generator";
const generator: NumberGenerator = aleaRNGFactory(2);
// const factory: () => NumberGenerator = aleaRNGFactory;
const hashFn1: NumberHashGenerator = murmurhash2_x86_32;
const hashFn2: NumberHashGenerator = murmurhash3_x86_32;
generator.uInt32();
hashFn1("What?", 42);
hashFn2("something", 14);
This library was tested on the following environments:
- Node >= 8
- All major browsers and IE >= 10
Disclaimer: The following benchmarks were created on a MacBook Pro, Processor 2,7 GHz Intel Core i5 with 8 GB 1867 MHz DDR3 memory and run under Node v14.15.1.
Comparison between uInt32
and uFloat32
methods:
// v4.0.1
aleaRNGFactory#uInt32() x 23,094,220 ops/sec
aleaRNGFactory#uFloat32() x 20,571,821 ops/sec
Comparison between murmurhash2_x86_32
, murmurhash3_x86_32
, murmurhash3_x86_128
and murmurhash3_x64_128
function:
// v4.0.1
murmurhash2_x86_32 x 834,241 ops/sec
murmurhash3_x86_32 x 827,462 ops/sec
murmurhash3_x86_128 x 300,153 ops/sec
murmurhash3_x64_128 x 188,581 ops/sec
To run them on your machine execute pnpm run test:benchmark
.
Do you want to contribute have a look at CONTRIBUTING.md
"Why pseudo random number generators and number hash functions" you may ask? Read more in this fantastic blog post about "A primer on repeatable random numbers" from Rune Skovbo Johansen.
Thanks to Johannes Baagøe for the Alea port and Ray Morgan for the MurmurHash2 algorithm implementation in JavaScript. Also thanks to Karan Lyons for the MurmurHash3 implementation.
Resources used to test against implementations in other languages are:
- JSON for modern C++ by Niels Lohmann: https://github.com/nlohmann/json
- MurmurHash2 and 3 in C++ by Austin Appleby: https://github.com/aappleby/smhasher
Big thanks as well to Alex Ciminian for raising the issue with non ASCII characters: https://cimi.io/murmurhash3js-revisited/