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This is a follow on from a previously posted question:

How to generate a random number in C?

I wish to be able to generate a random number from within a particular range, such as 1 to 6 to mimic the sides of a dice.

How would I go about doing this?

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if you look at the second answer to the question you refer to you have the answer. rand() % 6. – Mats Fredriksson Mar 24 '10 at 16:58
I didn't understand how it worked, so I decided to make a separate question for clarity. – Jamie Keeling Mar 24 '10 at 17:29
Random thought: If you polled a random cross-section of programmers, you'd find a random number of them are randomly thinking of ways to randomly generate numbers. Considering the Universe is governed by precise and predictable laws, isn't it interesting that we try to generate things more randomly? Questions like this always tend to bring out the 10k+ posters. – Armstrongest Mar 24 '10 at 19:00
@Mats rand() % 6 can return a 0. Not good for a die. – new123456 Mar 5 '11 at 19:33
Can you mark stackoverflow.com/a/6852396/419 as the accepted answer instead of the answer that links to it :) Thanks. – Kev Jun 27 '12 at 13:15

10 Answers 10

up vote 98 down vote accepted

All the answers so far are mathematically wrong. Returning rand() % N does not uniformly give a number in the range [0, N) unless N divides the length of the interval into which rand() returns (i.e. is a power of 2). Furthermore, one has no idea whether the moduli of rand() are independent: it's possible that they go 0, 1, 2, ..., which is uniform but not very random. The only assumption it seems reasonable to make is that rand() puts out a Poisson distribution: any two nonoverlapping subintervals of the same size are equally likely and independent. For a finite set of values, this implies a uniform distribution and also ensures that the values of rand() are nicely scattered.

This means that the only correct way of changing the range of rand() is to divide it into boxes; for example, if RAND_MAX == 11 and you want a range of 1..6, you should assign {0,1} to 1, {2,3} to 2, and so on. These are disjoint, equally-sized intervals and thus are uniformly and independently distributed.

The suggestion to use floating-point division is mathematically plausible but suffers from rounding issues in principle. Perhaps double is high-enough precision to make it work; perhaps not. I don't know and I don't want to have to figure it out; in any case, the answer is system-dependent.

The correct way is to use integer arithmetic. That is, you want something like the following:

#include <stdlib.h> // For random(), RAND_MAX

// Assumes 0 <= max <= RAND_MAX
// Returns in the closed interval [0, max]
long random_at_most(long max) {
  unsigned long
    // max <= RAND_MAX < ULONG_MAX, so this is okay.
    num_bins = (unsigned long) max + 1,
    num_rand = (unsigned long) RAND_MAX + 1,
    bin_size = num_rand / num_bins,
    defect   = num_rand % num_bins;

  long x;
  do {
   x = random();
  // This is carefully written not to overflow
  while (num_rand - defect <= (unsigned long)x);

  // Truncated division is intentional
  return x/bin_size;

The loop is necessary to get a perfectly uniform distribution. For example, if you are given random numbers from 0 to 2 and you want only ones from 0 to 1, you just keep pulling until you don't get a 2; it's not hard to check that this gives 0 or 1 with equal probability. This method is also described in the link that nos gave in their answer, though coded differently. I'm using random() rather than rand() as it has a better distribution (as noted by the man page for rand()).

If you want to get random values outside the default range [0, RAND_MAX], then you have to do something tricky. Perhaps the most expedient is to define a function random_extended() that pulls n bits (using random_at_most()) and returns in [0, 2**n), and then apply random_at_most() with random_extended() in place of random() (and 2**n - 1 in place of RAND_MAX) to pull a random value less than 2**n, assuming you have a numerical type that can hold such a value. Finally, of course, you can get values in [min, max] using min + random_at_most(max - min), including negative values.

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tried this in xcode 4.5.1 .. am getting this error -> Undefined symbols for architecture i386: "_random_in_range", – raw3d Nov 9 '12 at 11:32
@raw3d How is the method called in your program? This is a recursive function that calls itself. – tomsmeding Dec 29 '12 at 14:41
@Adam Rosenfield,@Ryan Reich : In a related question where Adam had answered:stackoverflow.com/questions/137783/… the most upvoted answer : The usage of 'modulus' would then be incorrect, no? To generate 1..7 from 1..21,the procedure what Ryan has described should be used.Please correct me if I am wrong. – Arvind Apr 12 '13 at 17:22
A shortcut might be to use the library function arc4random_uniform() – nielsbot Oct 17 '13 at 6:36
The while loop could be made more readable. Rather than performing assignment in the conditional, you probably want a do {} while(). – theJPster Dec 31 '14 at 9:45

Following on from @Ryan Reich's answer, I thought I'd offer my cleaned up version. The first bounds check isn't required given the second bounds check, and I've made it iterative rather than recursive. It returns values in the range [min, max], where max >= min and 1+max-min < RAND_MAX.

unsigned int rand_interval(unsigned int min, unsigned int max)
    int r;
    const unsigned int range = 1 + max - min;
    const unsigned int buckets = RAND_MAX / range;
    const unsigned int limit = buckets * range;

    /* Create equal size buckets all in a row, then fire randomly towards
     * the buckets until you land in one of them. All buckets are equally
     * likely. If you land off the end of the line of buckets, try again. */
        r = rand();
    } while (r >= limit);

    return min + (r / buckets);
share|improve this answer
Note this will get stuck in an infinite loop if range >= RAND_MAX. Ask me how I know :/ – theJPster Jul 23 '13 at 13:44
How do you know!? – Ben Nov 24 '15 at 0:50
unsigned int
randr(unsigned int min, unsigned int max)
       double scaled = (double)rand()/RAND_MAX;

       return (max - min +1)*scaled + min;

See here for other options.

share|improve this answer
+1: Slightly more random than the obvious solution using %. – S.Lott Mar 24 '10 at 16:59
@S.Lott - not really. Each distributes the slightly-higher-odds cases differently, that's all. The double math gives the impression that there's more precision there, but you could just as easily use (((max-min+1)*rand())/RAND_MAX)+min and get probably the exact same distribution (assuming that RAND_MAX is small enough relative to int to not overflow). – Steve314 Mar 24 '10 at 17:05
This is slightly dangerous: it's possible for this to (very rarely) return max + 1, if either rand() == RAND_MAX, or rand() is very close to RAND_MAX and floating-point errors push the final result past max + 1. To be safe, you should check that the result is within range before returning it. – Mark Dickinson Mar 24 '10 at 17:06
@Christoph: I agree about RAND_MAX + 1.0. I'm still not sure that's good enough to prevent a max + 1 return, though: in particular, the + min at the end involves a round that could end up producing max + 1 for large values of rand(). Safer to abandon this approach altogether and use integer arithmetic. – Mark Dickinson Mar 24 '10 at 18:25
If RAND_MAX is replaced by RAND_MAX+1.0 as Christoph suggests, then I believe that this is safe provided that the + min is done using integer arithmetic: return (unsigned int)((max - min + 1) * scaled) + min. The (non-obvious) reason is that assuming IEEE 754 arithmetic and round-half-to-even, (and also that max - min + 1 is exactly representable as a double, but that'll be true on a typical machine), it's always true that x * scaled < x for any positive double x and any double scaled satisfying 0.0 <= scaled && scaled < 1.0. – Mark Dickinson Mar 24 '10 at 18:37

Wouldn't you just do:

int r = ( rand() % 6 ) + 1;

% is the modulus operator. Essentially it will just divide by 6 and return the remainder... from 0 - 5

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It will give results from 1 - 6. That's what the + 1 is for. – Armstrongest Mar 24 '10 at 17:02
Caught between page refreshes. I was updating while you were writing. ;-) – Armstrongest Mar 24 '10 at 17:08
Simon, show me a libc in use anywhere where rand() includes the low-order bits of the generator's state (if it uses an LCG). I haven't seen one so far—all of them (yes, including MSVC with RAND_MAX being just 32767) remove the low-order bits. Using modulus isn't recommended for other reasons, namely that it skews the distribution in favor of smaller numbers. – Joey Mar 24 '10 at 17:09
@Johannes: So it's safe to say slot machines don't use modulus? – Armstrongest Mar 24 '10 at 17:14
How would I exclude a 0? It seems that if I run it in a loop of 30, maybe the second or third time it runs there's a 0 roughly half way into it. Is this some sort of fluke? – Jamie Keeling Mar 24 '10 at 18:04

For those who understand the bias problem but can't stand the unpredictable run-time of rejection-based methods, this series produces a progressively less biased random integer in the [0, n-1] interval:

r = n / 2;
r = (rand() * n + r) / (RAND_MAX + 1);
r = (rand() * n + r) / (RAND_MAX + 1);
r = (rand() * n + r) / (RAND_MAX + 1);

It does so by synthesising a high-precision fixed-point random number of i * log_2(RAND_MAX + 1) bits (where i is the number of iterations) and performing a long multiplication by n.

When the number of bits is sufficiently large compared to n, the bias becomes immeasurably small.

It does not matter if RAND_MAX + 1 is less than n (as in this question), or if it is not a power of two, but care must be taken to avoid integer overflow if RAND_MAX * n is large.

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For your unique approach +1 – ryyker Jun 24 '14 at 22:45
RAND_MAX is often INT_MAX, so RAND_MAX + 1 --> UB (like INT_MIN) – chux Dec 30 '14 at 21:30
@chux that's what I mean about "care must be taken to avoid integer overflow if RAND_MAX * n is large". You need to arrange to use appropriate types for your requirements. – sh1 Dec 31 '14 at 5:42
@chux "RAND_MAX is often INT_MAX" Yes, but only on 16 bit systems! Any reasonably modern architechture will put INT_MAX at 2^32 / 2 and RAND_MAX at 2^16 / 2. Is this an incorrect assumption? – cat May 10 at 1:28
@cat Tested today 2 32-bit int compilers, I found RAND_MAX == 32767 on one and RAND_MAX == 2147483647 on another. My overall experience (decades) is that RAND_MAX == INT_MAX more often. So disagree that a reasonably modern 32-bit architecture will certainly have a RAND_MAX at 2^16 / 2. Since the C spec allows 32767 <= RAND_MAX <= INT_MAX, I code to that anyways rather than a tendency. – chux May 10 at 14:13

Here is a formula if you know the max and min values of a range, and you want to generate numbers inclusive in between the range:

r = (rand() % (max + 1 - min)) + min
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As noted in Ryan's answer, this produces a biased result. – David Wolever Jul 10 '14 at 19:04
Biased result, potential int overflow with max+1-min. – chux Dec 30 '14 at 21:28

In order to avoid the modulo bias (suggested in other answers) you can always use:


Where "MAX" is the upper bound and "MIN" is lower bound. For example, for numbers between 10 and 20:



Simple solution and better than using "rand() % N".

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Woohoo, this is a billion times better than the other answers. Worth noting you need to #include <bsd/stdlib.h> first. Also, any idea how to get this on Windows without MinGW or CygWin? – cat May 10 at 1:34

As said before modulo isn't sufficient because it skews the distribution. Heres my code which masks off bits and uses them to ensure the distribution isn't skewed.

static uint32_t randomInRange(uint32_t a,uint32_t b) {
    uint32_t v;
    uint32_t range;
    uint32_t upper;
    uint32_t lower;
    uint32_t mask;

    if(a == b) {
        return a;

    if(a > b) {
        upper = a;
        lower = b;
    } else {
        upper = b;
        lower = a; 

    range = upper - lower;

    mask = 0;
    //XXX calculate range with log and mask? nah, too lazy :).
    while(1) {
        if(mask >= range) {
        mask = (mask << 1) | 1;

    while(1) {
        v = rand() & mask;
        if(v <= range) {
            return lower + v;


The following simple code lets you look at the distribution:

int main() {

    unsigned long long int i;

    unsigned int n = 10;
    unsigned int numbers[n];

    for (i = 0; i < n; i++) {
        numbers[i] = 0;

    for (i = 0 ; i < 10000000 ; i++){
        uint32_t rand = random_in_range(0,n - 1);
        if(rand >= n){
            printf("bug: rand out of range %u\n",(unsigned int)rand);
            return 1;
        numbers[rand] += 1;

    for(i = 0; i < n; i++) {
        printf("%u: %u\n",i,numbers[i]);

share|improve this answer
Becomes quite inefficient when you reject numbers from the rand(). This will be especially inefficient when the range has a size that can be written as 2^k + 1. Then nearly half of all your attempts from a slow rand() call will be rejected by the condition. Would it may be better to calc RAND_MAX modulo range. Like: v = rand(); if (v > RAND_MAX - (RAND_MAX % range) -> reject and try again; else return v % range; I understand that modulo is a much slower operation than masking, but I still think ..... it should be tested. – oysteijo Oct 17 '13 at 13:02

Here is a slight simpler algorithm than Ryan Reich's solution:

uint32_t getRandInterval(uint32_t begin, uint32_t end) {
    uint32_t range = 1 + end - begin;
    uint32_t limit = RAND_MAX - (RAND_MAX % range); 

    uint32_t randVal;
    do {
        randVal = rand();
    } while (randVal >= limit);

    return (randVal % range) + begin;
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While Ryan is correct, the solution can be much simpler based on what is known about the source of the randomness. To re-state the problem:

  • There is a source of randomness, outputting numbers in range [0, MAX).
  • The goal is to produce uniformly distributed random numbers in range [rmin, rmax] where 0 <= rmin < rmax < MAX.

In my experience, if the number of bins (or "boxes") is significantly smaller than the range of the original numbers, and the original source is cryptographically strong - there is no need to go through all that rigamarole, and simple modulo division would suffice (like output = rnd.next() % (rmax+1), if rmin == 0), and produce random numbers that are distributed uniformly "enough", and without any loss of speed. The key factor is the randomness source (i.e., kids, don't try this at home with rand()).

Here's an example/proof of how it works in practice. I wanted to generate random numbers from 1 to 22, having a cryptographically strong source that produced random bytes (based on Intel RDRAND). The results are:

Rnd distribution test (22 boxes, numbers of entries in each box):     
 1: 409443    4.55%
 2: 408736    4.54%
 3: 408557    4.54%
 4: 409125    4.55%
 5: 408812    4.54%
 6: 409418    4.55%
 7: 408365    4.54%
 8: 407992    4.53%
 9: 409262    4.55%
10: 408112    4.53%
11: 409995    4.56%
12: 409810    4.55%
13: 409638    4.55%
14: 408905    4.54%
15: 408484    4.54%
16: 408211    4.54%
17: 409773    4.55%
18: 409597    4.55%
19: 409727    4.55%
20: 409062    4.55%
21: 409634    4.55%
22: 409342    4.55%   
total: 100.00%

This is as close to uniform as I need for my purpose (fair dice throw, generating cryptographically strong codebooks for WWII cipher machines such as http://users.telenet.be/d.rijmenants/en/kl-7sim.htm, etc). The output does not show any appreciable bias.

Here's the source of cryptographically strong (true) random number generator: Intel Digital Random Number Generator and a sample code that produces 64-bit (unsigned) random numbers.

int rdrand64_step(unsigned long long int *therand)
  unsigned long long int foo;
  int cf_error_status;

  asm("rdrand %%rax; \
        mov $1,%%edx; \
        cmovae %%rax,%%rdx; \
        mov %%edx,%1; \
        mov %%rax, %0;":"=r"(foo),"=r"(cf_error_status)::"%rax","%rdx");
        *therand = foo;
  return cf_error_status;

I compiled it on Mac OS X with clang-6.0.1 (straight), and with gcc-4.8.3 using "-Wa,q" flag (because GAS does not support these new instructions).

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Compiled with gcc randu.c -o randu -Wa,q (GCC 5.3.1 on Ubuntu 16) or clang randu.c -o randu (Clang 3.8.0) works, but dumps core at runtime with Illegal instruction (core dumped). Any ideas? – cat May 11 at 11:06
First, I don't know whether your CPU actually supports RDRAND instruction. Your OS is fairly recent, but the CPU may not be. Second (but this is less likely) - I've no idea what kind of assembler Ubuntu includes (and Ubuntu tends to be fairly backwards wrt. updating packages). Check the Intel site I referred to for ways to test whether your CPU supports RDRAND. – Mouse Jun 7 at 8:34

protected by Yu Hao Oct 17 '13 at 6:58

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