# How many random numbers does std::uniform_real_distribution use?

I was surprised to see that the output of this program:

``````#include <iostream>
#include <random>

int main()
{
std::mt19937 rng1;
std::mt19937 rng2;
std::uniform_real_distribution<double> dist;

double random = dist(rng1);

std::cout << (rng1() - rng2()) << "\n";

return 0;
}
``````

is `0` - i.e. `std::uniform_real_distribution` uses two random numbers to produce a random `double` value in the range [0,1). I thought it would just generate one and rescale that. After thinking about it I guess that this is because `std::mt19937` produces 32-bit ints and double is twice this size and thus not "random enough".

Question: How do I find out this number generically, i.e. if the random number generator and the floating point type are arbitrary types?

Edit: I just noticed that I could use `std::generate_canonical` instead, as I am only interested in random numbers of [0,1). Not sure if this makes a difference.

-
You can't find this generically. –  R. Martinho Fernandes Jul 22 '13 at 12:12
@R.MartinhoFernandes: because... –  arne Jul 22 '13 at 12:14
As an aside, think of what it would mean to "rescale" a 32-bit integer to a 64-bit double: there are approximately 2^62 distinct double values. There are 2^32 distinct int values. This means that only one out of every billion possible double values would be representable in the resulting double. This is clearly unacceptable. –  JohannesD Jul 22 '13 at 12:37
JohannesD: Thats just what I guessed above. Thanks for stating it in much clearer words! –  cschwan Jul 22 '13 at 12:43
@JohannesD But you don't want to generate all 2^62 values, or at least not with equal frequency. I'd go for generating 2^52, in order to ensure an equal distribution. –  James Kanze Jul 22 '13 at 13:24

For `template<class RealType, size_t bits, class URNG> std::generate_canonical` the standard (section 27.5.7.2) explicitly defines the number of calls to the uniform random number generator (URNG) to be
where b is the minimum of the number of bits in the mantissa of the RealType and the number of bits given to generate_canonical as template parameter. R is the range of numbers the URNG can return `(URNG::max()-URNG::min()+1)`. However, in your example this will not make any difference, since you need 2 calls to the mt19937 to fill the 53 bits of the mantissa of the double.
A reason might be that for some distributions the number uniform random numbers required to generate a single number of the distribution is not fixed and may vary from call to call. An example is the `std::poisson_distribution`, which is usually implemented as a loop which draws a uniform random number in each iteration until the product of these numbers has reached a certain threshold (see for example the implementation of the GNU C++ library (line 1523-1528)).