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:

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

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.

`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 0:08nin [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`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`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`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 equaln/ 2**23 for some integernin [0, 2**23), and the values should appear with uniform distribution. – Eric Postpischil Feb 25 '18 at 0:568more comments