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It looks like Math.random() generates a 64-bit floating point number in the range [0,1) while the new crypto.getRandomValues() API only returns ints. What would be the ideal way to produce a number in [0,1) using this API?

This seems to work but seems suboptimal:

ints = new Uint32Array(2)
return ints[0] / 0xffffffff * ints[1] / 0xffffffff

EDIT: To clarify, I am trying to produce better results than Math.random(). From my understanding of floating point, it should be possible to get a fully random fraction for 52 bits of randomness. (?)

EDIT 2: To give a little more background, I'm not trying to do anything cryptographically secure but there are a lot of anecdotal stories about Math.random() being implemented poorly (e.g. so where a better alternative is available I'd like to use it.

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I tried your code in Chrome, and I also get values > 1, e.g. 2.5.... – Šime Vidas Dec 4 '12 at 1:27
Why Math.abs()? From what I see in Chrome, the random numbers are positive. – Šime Vidas Dec 4 '12 at 1:30
@ŠimeVidas Indeed, they must necessarily be positive, because the OP is using a Uint (unsigned int) buffer view. crypto.getRandomValues just generates a random binary buffer that is contextualized into numbers by whatever type of view is used. – apsillers Dec 4 '12 at 1:32
@apsillers I see. I tried with Int32Array and got negative numbers indeed. – Šime Vidas Dec 4 '12 at 1:34
Why that expression? Wouldn't just ints[0] / 0xffffffff produce a random [0,1) value? – Šime Vidas Dec 4 '12 at 1:37
up vote 4 down vote accepted

Remember that floating point numbers are just a mantissa coefficient, multiplied by 2 raised to an exponent:

floating_point_value = mantissa * (2 ^ exponent)

With Math.random, you generate floating points that have a 32-bit random mantissa and always have an exponent of -32, so that the decimal place is bit shift to the left 32 places, so the mantissa never has any part to the left of the decimal place.

mantissa =         10011000111100111111101000110001 (some random 32-bit int)
mantissa * 2^-32 = 0.10011000111100111111101000110001

Try running Math.random().toString(2) a few times to verify that this is the case.

Solution: you can just generate a random 32-bit mantissa and multiply it by Math.pow(2,-32):

var arr = new Uint32Array(1);
var result = arr[0] * Math.pow(2,-32);
// or just   arr[0] * (0xffffffff + 1);

Note that floating points do not have an even distribution (the possible values become sparser the larger the numbers become, due to a lack of precision in the mantissa), making them ill-suited for cryptographic applications or other domains which require very strong random numbers. For that, you should use the raw integer values provided to you by crypto.getRandomValues().


The mantissa in JavaScript is 52 bits, so you could get 52 bits of randomness:

var arr = new Uint32Array(2);

// keep all 32 bits of the the first, top 20 of the second for 52 random bits
var mantissa = (arr[0] * Math.pow(2,20)) + (arr[1] >>> 12)

// shift all 52 bits to the right of the decimal point
var result = mantissa * Math.pow(2,-52);

So, all in all, no, this isn't ant shorter than your own solution, but I think it's the best you can hope to do. You must generate 52 random bits, which needs to be built from 32-bit blocks, and then it need to be shifted back down to below 1.

share|improve this answer
That's equivalent to var result = arr[0] / ( 0xffffffff + 1 );, right? – Šime Vidas Dec 4 '12 at 1:47
I should clarify that I'm looking for the same interface as Math.random() but better, i.e. 52 bits of randomness. – svachalek Dec 4 '12 at 1:54
@ŠimeVidas Yes, and that's better than computing Math.pow each time, too. Thanks, added to my answer. – apsillers Dec 4 '12 at 1:59
@svachalek Edited with a solution, but it's not any shorter than your own, I'm afraid! – apsillers Dec 4 '12 at 2:24
I think it's better due to the lack of random bits multiplying with each other; I'm not much of a mathematician but that strikes me as reducing randomness somehow. I think it's probably faster using constants over Math.pow though: (ints[0] * 0x100000 + (ints[1] & 0xfffff)) / 0xfffffffffffff – svachalek Dec 4 '12 at 2:56

Well, that is as optimal as it should be in case you really need the number in the range [0,1).

The problem with that code is that the odds for differents numbers are not the same anymore.

With that code is more likely for example to get an 0.5 (1*0.5,0.5*1,0.75*0.666) than a 1 (1*1).

share|improve this answer
But OP's code also produces values larger than 1! – Šime Vidas Dec 4 '12 at 1:35
@ŠimeVidas True it did; I fixed the bad example code but I think the spec was clear. – svachalek Dec 4 '12 at 2:05

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