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I am currently working on importance sampling, and for testing purposes I need to be able to generate all possible values that uniform_real_distribution<float> may generate for the interval [0,1] (yes it is closed from the right too). My idea was to generate integer numbers which I can then convert to floating point numbers. From the tests I made it seems that there is a perfect bijection between uniform single-precision floats in [0,1] and integers in [0,2^24] (I am a bit bothered by the fact that it is not [0,2^24-1] and I am still trying to figure out why, my best guess is that 0 is simply special for floats and 1 to 2^24 all result in floats that have the same exponent). My question is whether the floats generated this way are exactly the floats that can be generated from uniform_real_distribution<float>. You can find my integer <-> float tests below:

void floatIntegerBitsBijectionTest()
{
    uint32 two24 = 1 << 24;
    bool bij24Bits = true;
    float delta = float(1.0) / float(two24);
    float prev = float(0) / float(two24);
    for (uint32 i = 1; i <= two24; ++i)
    {
        float uintMap = float(i) / float(two24);
        if (uintMap - prev != delta || uint32(uintMap*float(two24)) != i)
        {
            std::cout << "No bijection exists between uniform floats in [0,1] and integers in [0,2^24].\n";
            bij24Bits = false;
            break;
        }
        prev = uintMap;
    }
    if(bij24Bits) std::cout << "A bijection exists between uniform floats in [0,1] and integers in [0,2^24].\n";
    std::cout << "\n";

    uint32 two25 = 1 << 25;
    bool bij25Bits = true;
    delta = float(1.0) / float(two25);
    prev = float(0) / float(two25);
    for (uint32 i = 1; i <= two25; ++i)
    {
        float uintMap = float(i) / float(two25);
        if (uintMap - prev != delta || uint32(uintMap*float(two25)) != i)
        {
            std::cout << "No bijection exists between uniform floats in [0,1] and integers in [0,2^25].\n";
            if (i == ((1 << 24) + 1)) std::cout << "The first non-uniformly distributed float corresponds to the integer 2^24+1.\n";

            bij25Bits = false;
            break;
        }
        prev = uintMap;
    }
    if (bij25Bits) std::cout << "A bijection exists between uniform floats in [0,1] and integers in [0,2^25].\n";
    std::cout << "\n";


    bool bij25BitsS = true;
    delta = 1.0f / float(two24);
    prev = float(-two24) / float(two24);
    for (int i = -two24+1; i <= two24; ++i)
    {
        float uintMap = float(i) / float(two24);
        if (uintMap - prev != delta || int(uintMap*float(two24)) != i)
        {
            std::cout << i << " " << uintMap - prev << " " << delta << "\n";
            std::cout << "No bijection exists between uniform floats in [-1,1] and integers in [-2^24,2^24].\n";
            bij25BitsS = false;
            break;
        }
        prev = uintMap;
    }
    if (bij25BitsS) std::cout << "A bijection exists between uniform floats in [-1,1] and integers in [-2^24,2^24].\n";
}

EDIT:

Somewhat relevant:

https://crypto.stackexchange.com/questions/31657/uniformly-distributed-secure-floating-point-numbers-in-0-1

http://xoroshiro.di.unimi.it/random_real.c

https://www.reddit.com/r/programming/comments/29ducz/obtaining_uniform_random_floats_is_trickier_than/

https://lemire.me/blog/2017/02/28/how-many-floating-point-numbers-are-in-the-interval-01/

EDIT 2:

I finally managed to figure out what uniform_real_distribution<float> does at least when used with the mt19937 engine when used with its default template arguments (I am talking about the implementation that comes with VS2017). Sadly, it simply generates a random integer number in [0,2^32-1] casts it to float and then divides it by 2^32. Needless to say this produces non-uniformly distributed floating point numbers. I am guessing, however, that this works for most practical purposes unless one is working close to the precision of the deltas between generated numbers.

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  • (a) The properties of float are implementation-dependent. (b) In IEEE 754 32-bit floating-point, there are about 2**30 representable values in [0, 1], so there is no bijection with the integers in [0, 2**24]. There is a bijection with a subset of the representable values in [0, 1]. (c) No, not all representable values in (0, 1] have the same exponent. They have exponents ranging from −126 to 0, along with the special cases that are the subnormals. (d) The specification of uniform_real_distribution looks inadequate to determine how it deals with floating-point granularity. – Eric Postpischil Feb 25 '18 at 0:08
  • Of course, given as many representable floating-point values as integers in [0, 2**24], there is necessarily a bijection. But, more particularly, for each integer n in [0, 2**24], n / 2**24 is a value representable in IEEE-754 32-bit binary floating-point. – Eric Postpischil Feb 25 '18 at 0:10
  • (b), (d) Take notice of the "uniform" part, while there are many floating point numbers in [0,1] only a subset of those are uniformly distributed, since uniform_real_distribution is supposed to produce uniform values, I do not expect it would produce any output outside the uniform floats in [0,1]. I just want to make sure that this subset is exactly n/2^24, where n is in [0,2^24]. – lightxbulb Feb 25 '18 at 0:15
  • Consider a simplified floating-point format that had representable values 0, 1/32, 1/16, 1/8, 1/4, and 1/2. How would uniform_real_distribution(0, 1/2) work? First, it is obviously impossible for it to return any values in (1/8, 1/4), so it generates numbers in that interval with zero probability, which contradicts the requirement that it generate numbers with probability equal to that for the interval (0, 1/8). Second, if that is resolved in some way, there is a question of how to attempts to apportion the probabilities among these values with differing spacing. – Eric Postpischil Feb 25 '18 at 0:16
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    In IEEE-754 32-bit binary floating-point, the representable values from 1 to 2 are regularly spaced at distances of 2**−23. Assuming your implementation uses IEEE-754 32-bit binary floating-point for float and uniform_real_distribution is well implemented, if you define x with std::uniform_real_distribution<float> x(1, 2);, then x(generator)-1 will generate values in [0, 1) with regular spacing. That is, every value will equal n / 2**23 for some integer n in [0, 2**23), and the values should appear with uniform distribution. – Eric Postpischil Feb 25 '18 at 0:56
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I will assume the C++ implementation uses the IEEE-754 32-bit basic binary format for float. In this format, the representable floating-point values in [1, 2] are regularly spaced, at a distance of 2−23.

Define x with:

std::uniform_real_distribution<float> x(1, 2);

Then, assuming uniform_real_distribution is well implemented and a proper engine is used, x(engine) - 1 will generate values equal to n / 223 for integers n in [0, 223), with uniform distribution.

Notes

I have misgivings about the specification of uniform_real_distribution in C++. It is defined in terms of real arithmetic. The requirement that it return values with constant probability density requires a continuous set of numbers, which the floating-point format does not provide. Additionally, I am not sure how implementations will handle endpoints.

Since the distribution has been forced to be discrete, one might as well use uniform_int_distribution and multiply the samples by 2−23 (available as numeric_limits<float>::epsilon()). The has the benefit of clarifying the endpoints and easily supporting intervals of [0, 1) or [0, 1], as desired.

Even if the C++ standard does not use IEEE-754, representable values in [1, 2] should be evenly spaced, due to the description in the C++ standard of floating-point values as represented by some number of digits in a certain base, multiplied by the base raised to some power. For the power zero, the values from 1 to 2 would be spaced according to the value of the least significant digit in the format. As above, that distance would be numeric_limits<float>::epsilon().

Footnotes

1 The C++ standard uses legacy term “mantissa,” but the preferred term is “significand.”

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  • How does std::numeric_limits<float>::radix figure into the calculation, if at all, for float with radix != 2? – Jive Dadson Feb 25 '18 at 2:09
  • @Eric: Please note that while uniform_int_distribution provides numbers on a closed range, uniform_real_distribution gives numbers on a half-open range. – Nicol Bolas Feb 25 '18 at 3:45
  • @NicolBolas: See notes: en.cppreference.com/w/cpp/numeric/random/… – lightxbulb Feb 25 '18 at 8:54
  • Can you confirm that my assumption that the largest uniformly distributed set of 32 bit IEEE-754 floats in [2^j, 2^(j+1)] (j in [1,23]) is exactly the set { 2^j + n/2^(23-j) | n in [0,2^(23-j)] } is correct? Also for [0,1] it should be { n/2^24 | n in [0,2^24] }. So if one wants to generate uniform float numbers in [a,b], one needs to consider in which interval b falls, and based on that choose the corresponding set. I have provided an example related to my question: coliru.stacked-crooked.com/a/2bda63c95419b060 – lightxbulb Feb 25 '18 at 10:21
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    @lightxbulb: In fact, the representable values in [2^j, 2^(j+1)] are exactly { 2^j + n/2^(23-j) | n in [0, 2^(23-j)] }, except when you reach the high or low end of the format, so it is the largest set of anything in that interval. This is also true for [½, 1], which shows why for [0, 1] it is { n/2^24 | n in [0, 2^24] }—one is simply taking the union of { ½ + n/2^24 | n in [0, 2^23] } with { n/2^24 | n in [0, 2^23] }. The former is all the representable values in [½, 1], and the latter is the a subset of the representable values in [0, ½]. – Eric Postpischil Feb 25 '18 at 11:39
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You could force the issue. Roll your own random float generator.

EDIT: I just discovered std::generate_canonical<float>(), which does the same thing, but does not depend on the magic number 24. It works that out from std::numerical_limits<float>::digits, etc...

#include <random>

static const unsigned long big = 1 << 24;
static std::default_random_engine re;
static std::uniform_int_distribution<unsigned long> uint(0, big - 1);

float rand_float() {
    return uint(re) / static_cast<float>(big);
}
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  • Sadly I do not have the option of rolling my own float generator, since I am working with code that uses uniform_real_distribution that I shouldn't really modify. – lightxbulb Feb 25 '18 at 0:46
  • Btw your code generates floats in [0,1), not [0,1]. If the you remove the -1, it should work correctly for [0,1]. – lightxbulb Feb 25 '18 at 0:49
  • That was intentional. Canonical uniform floats are conventionally defined on [0,1). Things just work out better that way. In this case, there are 2^24 distinct values. – Jive Dadson Feb 25 '18 at 0:51
  • Added the remark just in case somebody copy-pastes it for [0,1], since my question was referring to the [0,1] interval. I agree however that even uniform_real_distribution defines the [a,b) interval with (a,b) as constructor arguments, unless you make use of std::nextafter as a workaround. – lightxbulb Feb 25 '18 at 0:59
  • Come to think of it, you better use big = 1<<23 for IEEE floats. I reckon any good implementation of uniform_real_distribution<float> is going to do that behind the curtains. – Jive Dadson Feb 25 '18 at 1:15

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