Edit: So basically what I'm trying to write is a 1 bit hash for double.

I want to map a double to true or false with a 50/50 chance. For that I wrote code that picks some random numbers (just as an example, I want to use this on data with regularities and still get a 50/50 result), checks their last bit and increments y if it is 1, or n if it is 0.

However, this code constantly results in 25% y and 75% n. Why is it not 50/50? And why such a weird, but straight-forward (1/3) distribution?

public class DoubleToBoolean {
    public void test() {

        int y = 0;
        int n = 0;
        Random r = new Random();
        for (int i = 0; i < 1000000; i++) {
            double randomValue = r.nextDouble();
            long lastBit = Double.doubleToLongBits(randomValue) & 1;
            if (lastBit == 1) {
            } else {
        System.out.println(y + " " + n);

Example output:

250167 749833
  • 43
    I'm really hoping the answer is something fascinating about random generation of floating-point variates, rather than "LCG has low entropy in the low bits".
    – Sneftel
    Dec 23, 2014 at 18:00
  • 4
    I am very curious, what is the purpose of a "1 bit hash for double"? I seriously can't think of any legitimate application of such a requirement.
    – corsiKa
    Dec 23, 2014 at 22:29
  • 3
    @corsiKa In geometry computations there are often two cases we're looking for to choose from two possible answers (e.g. is point to the left or to the right of the line?), and sometimes it introduces the third, degenerate case (point is right on the line), but you only have two available answers, so you have to pseudorandomly choose one of the available answers in that case. The best way I could think of is to take a 1 bit hash of one of the given double values (remember, those are geometry computations, so there are doubles all over the place).
    – gvlasov
    Dec 23, 2014 at 22:47
  • 2
    @corsiKa (comment divided into two because it is too long) We could start at something simpler like doubleValue % 1 > 0.5, but that would be too coarse-grained since it can introduce visible regularities in some cases (all the values are within range of length 1). If that's too coarse-grained, then should we probably try smaller ranges, like doubleValue % 1e-10 > 0.5e-10? Well, yes. And taking just the last bit as a hash of a double is what happens when you follow this approach till the end, with the least possible modulo.
    – gvlasov
    Dec 23, 2014 at 22:48
  • 1
    @kmote then you'd still have the heavily biased least significant bit, and the other bit doesn't compensate for it - in fact it is also biased towards zero (but less so), for exactly the same reason. So the distribution would be about 50, 12.5, 25, 12.5. (lastbit & 3) == 0 would work though, odd as it is.
    – harold
    Dec 31, 2014 at 10:35

3 Answers 3


Because nextDouble works like this: (source)

public double nextDouble()
    return (((long) next(26) << 27) + next(27)) / (double) (1L << 53);

next(x) makes x random bits.

Now why does this matter? Because about half the numbers generated by the first part (before the division) are less than 1L << 52, and therefore their significand doesn't entirely fill the 53 bits that it could fill, meaning the least significant bit of the significand is always zero for those.

Because of the amount of attention this is receiving, here's some extra explanation of what a double in Java (and many other languages) really looks like and why it mattered in this question.

Basically, a double looks like this: (source)

double layout

A very important detail not visible in this picture is that numbers are "normalized"1 such that the 53 bit fraction starts with a 1 (by choosing the exponent such that it is so), that 1 is then omitted. That is why the picture shows 52 bits for the fraction (significand) but there are effectively 53 bits in it.

The normalization means that if in the code for nextDouble the 53rd bit is set, that bit is the implicit leading 1 and it goes away, and the other 52 bits are copied literally to the significand of the resulting double. If that bit is not set however, the remaining bits must be shifted left until it becomes set.

On average, half the generated numbers fall into the case where the significand was not shifted left at all (and about half those have a 0 as their least significant bit), and the other half is shifted by at least 1 (or is just completely zero) so their least significant bit is always 0.

1: not always, clearly it cannot be done for zero, which has no highest 1. These numbers are called denormal or subnormal numbers, see wikipedia:denormal number.

  • 16
    Hooray! Just what I was hoping for.
    – Sneftel
    Dec 23, 2014 at 18:06
  • 3
    @Matt Presumably it's a speed optimization. The alternative would be to generate the exponent with a geometric distribution, and then the mantissa separately.
    – Sneftel
    Dec 23, 2014 at 18:09
  • 7
    @Matt: Define "best." random.nextDouble() is typically the "best" way for what it's intended for, but most people are not trying to produce a 1-bit hash from their random double. Are you looking for uniform distribution, resistance to cryptanalysis, or what? Dec 23, 2014 at 18:10
  • 1
    This answer suggests that if OP had multiplied the random number by 2^53 and checked whether the resulting integer was odd, there would have been a 50/50 distribution.
    – rici
    Dec 25, 2014 at 1:21
  • 4
    @The111 it says here that next must return an int, so it can only have up to 32 bits anyway
    – harold
    Dec 25, 2014 at 12:18

From the docs:

The method nextDouble is implemented by class Random as if by:

public double nextDouble() {
  return (((long)next(26) << 27) + next(27))
      / (double)(1L << 53);

But it also states the following (emphasis mine):

[In early versions of Java, the result was incorrectly calculated as:

 return (((long)next(27) << 27) + next(27))
     / (double)(1L << 54);

This might seem to be equivalent, if not better, but in fact it introduced a large nonuniformity because of the bias in the rounding of floating-point numbers: it was three times as likely that the low-order bit of the significand would be 0 than that it would be 1! This nonuniformity probably doesn't matter much in practice, but we strive for perfection.]

This note has been there since Java 5 at least (docs for Java <= 1.4 are behind a loginwall, too lazy to check). This is interesting, because the problem apparently still exists even in Java 8. Perhaps the "fixed" version was never tested?

  • 4
    Strange. I just reproduced this on Java 8.
    – aioobe
    Dec 23, 2014 at 18:11
  • 1
    Now that's interesting, because I just argued that the bias still applies to the new method. Am I wrong?
    – harold
    Dec 23, 2014 at 18:16
  • 3
    @harold: No, I think you're right and whoever tried to fix this bias might have made a mistake.
    – Thomas
    Dec 23, 2014 at 18:18
  • 6
    @harold Time to send an email to the Java guys.
    – Daniel
    Dec 23, 2014 at 18:26
  • 8
    "Perhaps the fixed version was never tested?" Actually, on rereading this, I think the doc was about a different problem. Note that it mentions rounding, which suggests that they didn't consider the "three times as likely" to be the problem, directly, but rather that this leads to a non-uniform distribution when the values are rounded. Note that in my answer, the values I list are uniformly distributed, but the low-order bit as represented in IEEE format are not uniform. I think the problem they fixed had to do with the overall uniformity, not the uniformity of the low bit.
    – ajb
    Dec 24, 2014 at 5:29

This result doesn't surprise me given how floating-point numbers are represented. Let's suppose we had a very short floating-point type with only 4 bits of precision. If we were to generate a random number between 0 and 1, distributed uniformly, there would be 16 possible values:


If that's how they looked in the machine, you could test the low-order bit to get a 50/50 distribution. However, IEEE floats are represented as a power of 2 times a mantissa; one field in the float is the power of 2 (plus a fixed offset). The power of 2 is selected so that the "mantissa" part is always a number >= 1.0 and < 2.0. This means that, in effect, the numbers other than 0.0000 would be represented like this:

0.0001 = 2^(-4) x 1.000
0.0010 = 2^(-3) x 1.000
0.0011 = 2^(-3) x 1.100
0.0100 = 2^(-2) x 1.000
0.0111 = 2^(-2) x 1.110
0.1000 = 2^(-1) x 1.000
0.1001 = 2^(-1) x 1.001
0.1110 = 2^(-1) x 1.110
0.1111 = 2^(-1) x 1.111

(The 1 before the binary point is an implied value; for 32- and 64-bit floats, no bit is actually allocated to hold this 1.)

But looking at the above should demonstrate why, if you convert the representation to bits and look at the low bit, you will get zero 75% of the time. This is due to all values less than 0.5 (binary 0.1000), which is half the possible values, having their mantissas shifted over, causing 0 to appear in the low bit. The situation is essentially the same when the mantissa has 52 bits (not including the implied 1) as a double does.

(Actually, as @sneftel suggested in a comment, we could include more than 16 possible values in the distribution, by generating:

0.0001000 with probability 1/128
0.0001001 with probability 1/128
0.0001111 with probability 1/128
0.001000  with probability 1/64
0.001001  with probability 1/64
0.01111   with probability 1/32 
0.1000    with probability 1/16
0.1001    with probability 1/16
0.1110    with probability 1/16
0.1111    with probability 1/16

But I'm not sure it's the kind of distribution most programmers would expect, so it probably isn't worthwhile. Plus it doesn't gain you much when the values are used to generate integers, as random floating-point values often are.)


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