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Fast Pseudorandom number generators (aka PRNG) with purity in mind!

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Getting started

Install it in node via:

npm install pure-rand or yarn add pure-rand

Use it in browser by doing:

import * as prand from 'https://unpkg.com/pure-rand/lib/esm/pure-rand.js';

Usage

Simple usage

import prand from 'pure-rand';

const seed = 42;
const rng = prand.xoroshiro128plus(seed);
const firstDiceValue = prand.unsafeUniformIntDistribution(1, 6, rng); // value in {1..6}, here: 2
const secondDiceValue = prand.unsafeUniformIntDistribution(1, 6, rng); // value in {1..6}, here: 4
const thirdDiceValue = prand.unsafeUniformIntDistribution(1, 6, rng); // value in {1..6}, here: 6

Pure usage

Pure means that the instance rng will never be altered in-place. It can be called again and again and it will always return the same value. But it will also return the next rng. Here is an example showing how the code above can be translated into its pure version:

import prand from 'pure-rand';

const seed = 42;
const rng1 = prand.xoroshiro128plus(seed);
const [firstDiceValue, rng2] = prand.uniformIntDistribution(1, 6, rng1); // value in {1..6}, here: 2
const [secondDiceValue, rng3] = prand.uniformIntDistribution(1, 6, rng2); // value in {1..6}, here: 4
const [thirdDiceValue, rng4] = prand.uniformIntDistribution(1, 6, rng3); // value in {1..6}, here: 6

// You can call: prand.uniformIntDistribution(1, 6, rng1);
// over and over it will always give you back the same value along with a new rng (always producing the same values too).

Independent simulations

In order to produce independent simulations it can be tempting to instanciate several PRNG based on totally different seeds. While it would produce distinct set of values, the best way to ensure fully unrelated sequences is rather to use jumps. Jump just consists into moving far away from the current position in the generator (eg.: jumping in Xoroshiro 128+ will move you 264 generations away from the current one on a generator having a sequence of 2128 elements).

import prand from 'pure-rand';

const seed = 42;
const rngSimulation1 = prand.xoroshiro128plus(seed);
const rngSimulation2 = rngSimulation1.jump(); // not in-place, creates a new instance
const rngSimulation3 = rngSimulation2.jump(); // not in-place, creates a new instance

const diceSim1Value = prand.unsafeUniformIntDistribution(1, 6, rngSimulation1); // value in {1..6}, here: 2
const diceSim2Value = prand.unsafeUniformIntDistribution(1, 6, rngSimulation2); // value in {1..6}, here: 5
const diceSim3Value = prand.unsafeUniformIntDistribution(1, 6, rngSimulation3); // value in {1..6}, here: 6

Non-uniform usage

While not recommended as non-uniform distribution implies that one or several values from the range will be more likely than others, it might be tempting for people wanting to maximize the throughput.

import prand from 'pure-rand';

const seed = 42;
const rng = prand.xoroshiro128plus(seed);
const rand = (min, max) => {
  const out = (rng.unsafeNext() >>> 0) / 0x100000000;
  return min + Math.floor(out * (max - min + 1));
};
const firstDiceValue = rand(1, 6); // value in {1..6}, here: 6

Select your seed

While not perfect, here is a rather simple way to generate a seed for your PNRG.

const seed = Date.now() ^ (Math.random() * 0x100000000);

Documentation

Pseudorandom number generators

In computer science most random number generators(1) are pseudorandom number generators (abbreviated: PRNG). In other words, they are fully deterministic and given the original seed one can rebuild the whole sequence.

Each PRNG algorithm has to deal with tradeoffs in terms of randomness quality, speed, length of the sequence(2)... In other words, it's important to compare relative speed of libraries with that in mind. Indeed, a Mersenne Twister PRNG will not have the same strenghts and weaknesses as a Xoroshiro PRNG, so depending on what you need exactly you might prefer one PRNG over another even if it will be slower.

4 PRNGs come with pure-rand:

  • congruential32: Linear Congruential generator — [more]
  • mersenne: Mersenne Twister generator — [more]
  • xorshift128plus: Xorshift 128+ generator — [more]
  • xoroshiro128plus: Xoroshiro 128+ generator — [more]

Our recommendation is xoroshiro128plus. But if you want to use another one, you can replace it by any other PRNG provided by pure-rand in the examples above.

Distributions

Once you are able to generate random values, next step is to scale them into the range you want. Indeed, you probably don't want a floating point value between 0 (included) and 1 (excluded) but rather an integer value between 1 and 6 if you emulate a dice or any other range based on your needs.

At this point, simple way would be to do min + floor(random() * (max - min + 1)) but actually it will not generate the values with equal probabilities even if you use the best PRNG in the world to back random(). In order to have equal probabilities you need to rely on uniform distributions(3) which comes built-in in some PNRG libraries.

pure-rand provides 3 built-in functions for uniform distributions of values:

  • uniformIntDistribution(min, max, rng)
  • uniformBigIntDistribution(min, max, rng) - with min and max being bigint
  • uniformArrayIntDistribution(min, max, rng) - with min and max being instances of ArrayInt = {sign, data} ie. sign either 1 or -1 and data an array of numbers between 0 (included) and 0xffffffff (included)

And their unsafe equivalents to change the PRNG in-place.

Extra helpers

Some helpers are also provided in order to ease the use of RandomGenerator instances:

  • prand.generateN(rng: RandomGenerator, num: number): [number[], RandomGenerator]: generates num random values using rng and return the next RandomGenerator
  • prand.skipN(rng: RandomGenerator, num: number): RandomGenerator: skips num random values and return the next RandomGenerator

Comparison

Summary

The chart has been split into three sections:

  • section 1: native Math.random()
  • section 2: without uniform distribution of values
  • section 3: with uniform distribution of values (not supported by all libraries)

Comparison against other libraries

Process

In order to compare the performance of the libraries, we aked them to shuffle an array containing 1,000,000 items (see code).

We then split the measurements into two sections:

  • one for non-uniform distributions — known to be slower as it implies re-asking for other values to the PRNG until the produced value fall into the acceptable range of values
  • one for uniform distributions

The recommended setup for pure-rand is to rely on our Xoroshiro128+. It provides a long enough sequence of random values, has built-in support for jump, is really efficient while providing a very good quality of randomness.

Performance

Non-Uniform

Library Algorithm Mean time (ms) Compared to pure-rand
native (node 16.19.1) Xorshift128+ 33.3 1.4x slower
pure-rand @6.0.0 Xoroshiro128+ 24.5 reference
pure-rand @6.0.0 Xorshift128+ 25.0 similar
pure-rand @6.0.0 Mersenne Twister 30.8 1.3x slower
pure-rand @6.0.0 Congruential‍ 22.6 1.1x faster
seedrandom @3.0.5 Alea 28.1 1.1x slower
seedrandom @3.0.5 Xorshift128 28.8 1.2x slower
seedrandom @3.0.5 Tyche-i 28.6 1.2x slower
seedrandom @3.0.5 Xorwow 32.0 1.3x slower
seedrandom @3.0.5 Xor4096 32.2 1.3x slower
seedrandom @3.0.5 Xorshift7 33.5 1.4x slower
@faker-js/faker @7.6.0 Mersenne Twister 109.1 4.5x slower
chance @1.1.10 Mersenne Twister 142.9 5.8x slower

Uniform

Library Algorithm Mean time (ms) Compared to pure-rand
pure-rand @6.0.0 Xoroshiro128+ 53.5 reference
pure-rand @6.0.0 Xorshift128+ 52.2 similar
pure-rand @6.0.0 Mersenne Twister 61.6 1.2x slower
pure-rand @6.0.0 Congruential‍ 57.6 1.1x slower
random-js @2.1.0 Mersenne Twister 119.6 2.2x slower

System details:

  • OS: Linux 5.15 Ubuntu 22.04.2 LTS 22.04.2 LTS (Jammy Jellyfish)
  • CPU: (2) x64 Intel(R) Xeon(R) Platinum 8272CL CPU @ 2.60GHz
  • Memory: 5.88 GB / 6.78 GB
  • Container: Yes
  • Node: 16.19.1 - /opt/hostedtoolcache/node/16.19.1/x64/bin/node

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(1) — Not all as there are also hardware-based random number generator.

(2) — How long it takes to reapeat itself?

(3) — While most users don't really think of it, uniform distribution is key! Without it entries might be biased towards some values and make some others less probable. The naive rand() % numValues is a good example of biased version as if rand() is uniform in 0, 1, 2 and numValues is 2, the probabilities are: P(0) = 67%, P(1) = 33% causing 1 to be less probable than 0

Advanced patterns

Generate 32-bit floating point numbers

The following snippet is responsible for generating 32-bit floating point numbers that spread uniformly between 0 (included) and 1 (excluded).

import prand from 'pure-rand';

function generateFloat32(rng) {
  const g1 = prand.unsafeUniformIntDistribution(0, (1 << 24) - 1, rng);
  const value = g1 / (1 << 24);
  return value;
}

const seed = 42;
const rng = prand.xoroshiro128plus(seed);

const float32Bits1 = generateFloat32(rng);
const float32Bits2 = generateFloat32(rng);

Generate 64-bit floating point numbers

The following snippet is responsible for generating 64-bit floating point numbers that spread uniformly between 0 (included) and 1 (excluded).

import prand from 'pure-rand';

function generateFloat64(rng) {
  const g1 = prand.unsafeUniformIntDistribution(0, (1 << 26) - 1, rng);
  const g2 = prand.unsafeUniformIntDistribution(0, (1 << 27) - 1, rng);
  const value = (g1 * Math.pow(2, 27) + g2) * Math.pow(2, -53);
  return value;
}

const seed = 42;
const rng = prand.xoroshiro128plus(seed);

const float64Bits1 = generateFloat64(rng);
const float64Bits2 = generateFloat64(rng);