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I need a function which would generate a random integer in given range (including border values). I don't unreasonable quality/randomness requirements, I have four requirements:

  • I need it to be fast. My project needs to generate millions (or sometimes even tens of millions) of random numbers and my current generator function has proven to be a bottleneck.
  • I need it to be reasonably uniform (use of rand() is perfectly fine).
  • the min-max ranges can be anything from <0, 1> to <-32727, 32727>.
  • it has to be seedable.

I currently have following C++ code:

output = min + (rand() * (int)(max - min) / RAND_MAX)

The problem is, that it is not really uniform - max is returned only when rand() = RAND_MAX (for Visual C++ it is 1/32727). This is major issue for small ranges like <-1, 1>, where the last value is almost never returned.

So I grabbed pen and paper and came up with following formula (which builds on the (int)(n + 0.5) integer rounding trick):

enter image description here

But it still doesn't give me uniform distribution. Repeated runs with 10000 samples give me ratio of 37:50:13 for values values -1, 0. 1.

Could you please suggest better formula? (or even whole pseudo-random number generator function)

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1  
See: stackoverflow.com/questions/2254498/… –  Jerry Coffin Feb 15 '11 at 20:01
3  
@Bill MaGriff: yes. It has the same problem. A simplified version is: how can you divide 10 pieces of candy among 3 children evenly (without breaking any of the candies)? The answer is, you can't -- you have to give three to each child, and just not give the tenth one to anybody. –  Jerry Coffin Feb 15 '11 at 20:04
3  
Have you looked at Boost.Random? –  Fred Nurk Feb 15 '11 at 20:09
2  
Check the Andrew Koenig article "A simple problem that is almost never solved correctly": drdobbs.com/blog/archives/2010/11/a_simple_proble.html –  Gene Bushuyev Feb 15 '11 at 20:34
1  
@Gene Bushuyev: Both Andrew and I have been harping on this subject for quite a while now. See: groups.google.com/group/comp.lang.c++/browse_frm/thread/…, and: groups.google.com/group/comp.os.ms-windows.programmer.tools.mfc/… –  Jerry Coffin Feb 15 '11 at 20:59

10 Answers 10

up vote 19 down vote accepted

Have you tried:

output = min + (rand() % (int)(max - min + 1))

This is still slightly biased towards lower numbers but much less so than your original version. It's also possible to extend it so that it removes the bias.

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2  
Thanks, this seems to be good enough for me from quick tests - its distribution for the -1, 0, 1 is nearly 33:33:33. –  Matěj Zábský Feb 15 '11 at 20:23
    
It returns max value always. Am I missing here something? :| –  rohan-patel Sep 6 '13 at 2:18
2  
rand() should be considered harmful in C++ there are much better ways of getting something that is uniformly distributed and actually random. –  Mgetz Sep 12 '13 at 19:14
    
Does it really return a correct number within range 100% of the time? I've found some other stackoverflow answer here that is using recursion to do it "the right way": stackoverflow.com/a/6852396/623622 –  Czarek Tomczak Jan 25 at 11:07

If your compiler supports C++0x and using it is an option for you, then the new standard <random> header is likely to meet your needs. It has a high quality uniform_int_distribution which will accept minimum and maximum bounds (inclusive as you need), and you can choose among various random number generators to plug into that distribution.

Here is code that generates a million random ints uniformly distributed in [-57, 365]. I've used the new std <chrono> facilities to time it as you mentioned performance is a major concern for you.

#include <iostream>
#include <random>
#include <chrono>

int main()
{
    typedef std::chrono::high_resolution_clock Clock;
    typedef std::chrono::duration<double> sec;
    Clock::time_point t0 = Clock::now();
    const int N = 10000000;
    typedef std::minstd_rand G;
    G g;
    typedef std::uniform_int_distribution<> D;
    D d(-57, 365);
    int c = 0;
    for (int i = 0; i < N; ++i) 
        c += d(g);
    Clock::time_point t1 = Clock::now();
    std::cout << N/sec(t1-t0).count() << " random numbers per second.\n";
    return c;
}

For me (2.8 GHz Intel Core i5) this prints out:

2.10268e+07 random numbers per second.

You can seed the generator by passing in an int to its constructor:

    G g(seed);

If you later find that int doesn't cover the range you need for your distribution, this can be remedied by changing the uniform_int_distribution like so (e.g. to long long):

    typedef std::uniform_int_distribution<long long> D;

If you later find that the minstd_rand isn't a high enough quality generator, that can also easily be swapped out. E.g.:

    typedef std::mt19937 G;  // Now using mersenne_twister_engine

Having separate control over the random number generator, and the random distribution can be quite liberating.

I've also computed (not shown) the first 4 "moments" of this distribution (using minstd_rand) and compared them to the theoretical values in an attempt to quantify the quality of the distribution:

min = -57
max = 365
mean = 154.131
x_mean = 154
var = 14931.9
x_var = 14910.7
skew = -0.00197375
x_skew = 0
kurtosis = -1.20129
x_kurtosis = -1.20001

(The x_ prefix refers to "expected")

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wow this is really nice –  pyCthon Oct 27 '11 at 0:18

Let's split the problem into two parts:

  • Generate a random number n in the range 0 through (max-min).
  • Add min to that number

The first part is obviously the hardest. Let's assume that the return value of rand() is perfectly uniform. Using modulo will add bias to the first (RAND_MAX + 1) % (max-min+1) numbers. So if we could magically change RAND_MAX to RAND_MAX - (RAND_MAX + 1) % (max-min+1), there would no longer be any bias.

It turns out that we can use this intuition if we are willing to allow pseudo-nondeterminism into the running time of our algorithm. Whenever rand() returns a number which is too large, we simply ask for another random number until we get one which is small enough.

The running time is now geometrically distributed, with expected value 1/p where p is the probability of getting a small enough number on the first try. Since RAND_MAX - (RAND_MAX + 1) % (max-min+1) is always less than (RAND_MAX + 1) / 2, we know that p > 1/2, so the expected number of iterations will always be less than two for any range. It should be possible to generate tens of millions of random numbers in less than a second on a standard CPU with this technique.

EDIT:

Although the above is technically correct, DSimon's answer is probably more useful in practice. You shouldn't implement this stuff yourself. I have seen a lot of implementations of rejection sampling and it is often very difficult to see if it's correct or not.

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For completeness: This is Rejection Sampling. –  etarion Feb 15 '11 at 21:22
    
Of course, this is the correct answer. –  Joe Blow Feb 19 '11 at 6:05

How about the Mersenne Twister? The boost implementation is rather easy to use and is well tested in many real-world applications. I've used it myself in several academic projects such as artificial intelligence and evolutionary algorithms.

Here's their example where they make a simple function to roll a six-sided die:

#include <boost/random/mersenne_twister.hpp>
#include <boost/random/uniform_int.hpp>
#include <boost/random/variate_generator.hpp>

boost::mt19937 gen;

int roll_die() {
    boost::uniform_int<> dist(1, 6);
    boost::variate_generator<boost::mt19937&, boost::uniform_int<> > die(gen, dist);
    return die();
}

Oh, and here's some more pimping of this generator just in case you aren't convinced you should use it over the vastly inferior rand():

The Mersenne Twister is a "random number" generator invented by Makoto Matsumoto and Takuji Nishimura; their website includes numerous implementations of the algorithm.

Essentially, the Mersenne Twister is a very large linear-feedback shift register. The algorithm operates on a 19,937 bit seed, stored in an 624-element array of 32-bit unsigned integers. The value 2^19937-1 is a Mersenne prime; the technique for manipulating the seed is based on an older "twisting" algorithm -- hence the name "Mersenne Twister".

An appealing aspect of the Mersenne Twister is its use of binary operations -- as opposed to time-consuming multiplication -- for generating numbers. The algorithm also has a very long period, and good granularity. It is both fast and effective for non-cryptographic applications.

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The Mersenne twister is a good generator, but the problem he's dealing with remains, regardless of the underlying generator itself. –  Jerry Coffin Feb 15 '11 at 20:21
    
I don't want to use Boost just for the random generator, because (since my project is a library) it means introducing another dependency to the project. I will probably be forced to use it anyways in the future, so then I can switch to this generator. –  Matěj Zábský Feb 15 '11 at 20:26
1  
@Jerry Coffin Which problem? I offered it because it satisfied all of his requirements: it's fast, it's uniform (using the boost::uniform_int distribution), you can transform the min max ranges into anything you like, and it's seedable. –  Aphex Feb 15 '11 at 20:29
    
@mzabsky I probably wouldn't let that stop me, when I had to ship my projects to my professors for submission, I just included the relevant boost header files I was using; you shouldn't have to package the entire 40mb boost library with your code. Of course in your case this might not be feasible for other reasons such as copyright... –  Aphex Feb 15 '11 at 20:32
    
@Aphex My project is not really a scientific simulator or something that needs really uniform distribution. I used the old generator for 1.5 years without any issue, I only noticed the biased distribution when I first needed it to generate numbers from very small range (3 in this case). The speed is still argument to consider the boost solution though. I will look into its license to see whether I can just add the few needed files to my project - I like the "Checkout -> F5 -> ready to use" as it is now. –  Matěj Zábský Feb 15 '11 at 20:44
int RandU(int nMin, int nMax)
{
    return nMin + (int)((double)rand() / (RAND_MAX+1) * (nMax-nMin+1));
}

This is a mapping of 32768 integers to (nMax-nMin+1) integers. The mapping will be quite good if (nMax-nMin+1) is small (as in your requirement). Note however that if (nMax-nMin+1) is large, the mapping won't work (For example - you can't map 32768 values to 30000 values with equal probability). If such ranges are needed - you should use a 32-bit or 64-bit random source, instead of the 15-bit rand(), or ignore rand() results which are out-of-range.

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Despite its unpopularity, this is also what I use for my non-scientific projects. Easy to understand (you don't need a math degree) and performs adequately (never had to profile any code using it). :) In case of large ranges, I guess we could string two rand() values together and get a 30-bit value to work with (assuming RAND_MAX = 0x7fff, i.e. 15 random bits) –  efotinis May 21 '11 at 20:48

I recommend the Boost.Random library, it's super detailed and well-documented, lets you explicitly specify what distribution you want, and in non-cryptographic scenarios can actually outperform a typical C library rand implementation.

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Here is an unbiased version that generates numbers in [low, high]:

int r;
do {
  r = rand();
} while (r < ((unsigned int)(RAND_MAX) + 1) % (high + 1 - low));
return r % (high + 1 - low) + low;

If your range is reasonably small, there is no reason to cache the right-hand side of the comparison in the do loop.

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IMO, none of the solutions presented there is really much improvement. His loop-based solution works, but likely to be quite inefficient, especially for a small range like the OP discusses. His uniform deviate solution doesn't actually produce uniform deviates at all. At most it kind of camouflages the lack of uniformity. –  Jerry Coffin Feb 15 '11 at 20:15
    
@Jerry: Please check the new version. –  Jeremiah Willcock Feb 15 '11 at 20:21
    
I'm a bit uncertain about that working correctly. It might, but correctness doesn't seem obvious, at least to me. –  Jerry Coffin Feb 15 '11 at 21:03
    
@Jerry: Here's my reasoning: Assume the range is [0, h) for simplicity. Calling rand() has RAND_MAX + 1 possible return values; taking rand() % h collapses (RAND_MAX + 1) / h of them to each of the h output values, except that (RAND_MAX + 1) / h + 1 of them are mapped to the values that are less than (RAND_MAX + 1) % h (because of the last partial cycle through the h outputs). We therefore remove (RAND_MAX + 1) % h possible outputs to get an unbiased distribution. –  Jeremiah Willcock Feb 16 '11 at 0:11
    
As far as I can tell, this is correct. –  Jørgen Fogh Mar 3 '11 at 14:26

The simplest (and hence best) C++ (using the 2011 standard) answer is

#include <random>

std::random_device rd;     // only used once to initialise engine
std::mt19937 rng(rd);      // random-number engine used
std::uniform_int_distribution<int> uni(min,max); // guaranteed unbiased

auto random_integer = uni(rng);

No need to re-invent the wheel. No need to worry about bias. No need to worry about using time as random seed.

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The following expression should be unbiased if I am not mistaken:

std::floor( ( max - min + 1.0 ) * rand() ) + min;

I am assuming here that rand() gives you a random value in the range between 0.0 and 1.0 NOT including 1.0 and that max and min are integers with the condition that min < max.

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std::floor returns double, and we need an integer value here. I would just cast to int instead of using std::floor. –  musiphil Sep 30 '13 at 18:27

The formula for this is very simple, so try this expression,

 int num = (int) rand() * (max - min) + min;  
 //Where rand() returns a random number between 0.0 and 1.0
share|improve this answer
    
Whole problem was using C/C++'s rand which returns integer in a range specified by the runtime. As demonstrated in this thread, mapping random integers from [0, RAND_MAX] to [MIN, MAX] isn't entirely straightforward, if you want to avoid destroying their statistical properties or performance. If you have doubles in range [0, 1], the mapping is easy. –  Matěj Zábský Aug 6 at 11:10

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