127

As the title suggests, I am trying to figure out a way of generating random numbers using the new C++11 <random> library. I have tried it with this code:

std::default_random_engine generator;
std::uniform_real_distribution<double> uniform_distance(1, 10.001);

The problem with the code I have is that every time I compile and run it, it always generates the same numbers. So my question is what other functions in the random library can accomplish this while being truly random?

For my particular use case, I was trying to get a value within the range [1, 10]

180

Stephan T. Lavavej (stl) from Microsoft did a talk at Going Native about how to use the new C++11 random functions and why not to use rand(). In it, he included a slide that basically solves your question. I've copied the code from that slide below.

You can see his full talk here: http://channel9.msdn.com/Events/GoingNative/2013/rand-Considered-Harmful

#include <random>
#include <iostream>

int main() {
    std::random_device rd;
    std::mt19937 mt(rd());
    std::uniform_real_distribution<double> dist(1.0, 10.0);

    for (int i=0; i<16; ++i)
        std::cout << dist(mt) << "\n";
}

We use random_device once to seed the random number generator named mt. random_device() is slower than mt19937, but it does not need to be seeded because it requests random data from your operating system (which will source from various locations, like RdRand for example).


Looking at this question / answer, it appears that uniform_real_distribution returns a number in the range [a, b), where you want [a, b]. To do that, our uniform_real_distibution should actually look like:

std::uniform_real_distribution<double> dist(1, std::nextafter(10, DBL_MAX));
  • 2
    Since the question is asking for the most general way to generate random numbers you might wanna just use default_random_engine, according to c++ primer it is the one that the implementation has deemed most useful – aaronman Oct 29 '13 at 18:56
  • 1
    @aaronman: I'm going by STL's talk, where he explicitly doesn't like that default_random_engine exists. – Bill Lynch Oct 29 '13 at 18:57
  • 4
    @chris we all know the difference between a vector and a map, not everyone knows the difference between mt19937 and ranlux24, if someone managed to become a programmer without knowing what a vector and a dictionary are maybe they should have a std::default_container, hopefully there are no people considering themselves programmers that don't know the differences, a lot of scripting languages have a default map type structure, which could be implemented in a whole variety of ways that the user may not know – aaronman Oct 29 '13 at 21:04
  • 20
    The nextafter call is overkill for most applications. The chances of a random double landing exactly on the endpoint are so minuscule that there's no practical difference between including and excluding it. – Mark Ransom Jun 27 '14 at 17:00
  • 3
    @chris Unrelated (but you opened the door), your std::vector analogy doesn't work here because std::vector is actually a good default due to CPU caching. It even outperforms std::list for insertion in the middle. That's true even if you do understand all the containers and could make an informed decision based on algorithmic complexity. – void.pointer Oct 23 '14 at 22:53
21

My 'random' library provide a high convenient wrapper around C++11 random classes. You can do almost all things with a simple 'get' method.

Examples:

  1. Random number in a range

    auto val = Random::get(-10, 10); // Integer
    auto val = Random::get(10.f, -10.f); // Float point
    
  2. Random boolean

    auto val = Random::get<bool>( ) // 50% to generate true
    auto val = Random::get<bool>( 0.7 ) // 70% to generate true
    
  3. Random value from a std::initilizer_list

    auto val = Random::get( { 1, 3, 5, 7, 9 } ); // val = 1 or 3 or...
    
  4. Random iterator from iterator range or all container

    auto it = Random::get( vec.begin(), vec.end() ); // it = random iterator
    auto it = Random::get( vec ); // return random iterator
    

And even more things ! Check out the github page:

https://github.com/effolkronium/random

  • Why does your random boolean generator have a 0.5% chance to generate true? I think you meant 50%? Very nice library, glad to see you are still maintaining it – smac89 Nov 6 '17 at 19:42
  • 1
    Yep, you're right. Glad to see that someone likes my library =) – Ilya Polishchuk Nov 7 '17 at 18:57
1

Here's something that I just wrote along those lines::

#include <random>
#include <chrono>
#include <thread>

using namespace std;

//==============================================================
// RANDOM BACKOFF TIME
//==============================================================
class backoff_time_t {
  public:
    random_device                      rd;
    mt19937                            mt;
    uniform_real_distribution<double>  dist;

    backoff_time_t() : rd{}, mt{rd()}, dist{0.5, 1.5} {}

    double rand() {
      return dist(mt);
    }
};

thread_local backoff_time_t backoff_time;


int main(int argc, char** argv) {
   double x1 = backoff_time.rand();
   double x2 = backoff_time.rand();
   double x3 = backoff_time.rand();
   double x4 = backoff_time.rand();
   return 0;
}

~

0

Here is some resource you can read about pseudo-random number generator.

https://en.wikipedia.org/wiki/Pseudorandom_number_generator

Basically, random numbers in computer need a seed (this number can be the current system time).

Replace

std::default_random_engine generator;

By

std::default_random_engine generator(<some seed number>);
-2

You've got two common situations. The first is that you want random numbers and aren't too fussed about the quality or execution speed. In that case, use the following macro

#define uniform() (rand()/(RAND_MAX + 1.0))

that gives you p in the range 0 to 1 - epsilon (unless RAND_MAX is bigger than the precision of a double, but worry about that when you come to it).

int x = (int) (uniform() * N);

Now gives a random integer on 0 to N -1.

If you need other distributions, you have to transform p. Or sometimes it's easier to call uniform() several times.

If you want repeatable behaviour, seed with a constant, otherwise seed with a call to time().

Now if you are bothered about quality or run time performance, rewrite uniform(). But otherwise don't touch the code. Always keep uniform() on 0 to 1 minus epsilon. Now you can wrap the C++ random number library to create a better uniform(), but that's a sort of medium-level option. If you are bothered about the characteristics of the RNG, then it's also worth investing a bit of time to understand how the underlying methods work, then provide one. So you've got complete control of the code, and you can guarantee that with the same seed, the sequence will always be exactly the same, regardless of platform or which version of C++ you are linking to.

  • 3
    Except that isn't uniform (0 to N-1). The reason is easy, let's suppose N=100 and RAND_MAX = 32758. There is not a way to uniformely map 32758 elements (RAND_MAX) to 100 inputs. The unique way is set a bound on 32000 and re-execute rand() if gets out of bounds – amchacon Nov 13 '16 at 11:03
  • 1
    If N is 100 then your RNG must be extremely good to be able to detect the deviation from a flat distribution. – Malcolm McLean Mar 13 '17 at 0:43

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