# Why does rand() repeat numbers far more often on Linux than Mac?

I was implementing a hashmap in C as part of a project I'm working on and using random inserts to test it. I noticed that `rand()` on Linux seems to repeat numbers far more often than on Mac. `RAND_MAX` is `2147483647/0x7FFFFFFF` on both platforms. I've reduced it to this test program that makes a byte array `RAND_MAX+1`-long, generates `RAND_MAX` random numbers, notes if each is a duplicate, and checks it off the list as seen.

``````#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <time.h>

int main() {
size_t size = ((size_t)RAND_MAX) + 1;
char *randoms = calloc(size, sizeof(char));
int dups = 0;
srand(time(0));
for (int i = 0; i < RAND_MAX; i++) {
int r = rand();
if (randoms[r]) {
// printf("duplicate at %d\n", r);
dups++;
}
randoms[r] = 1;
}
printf("duplicates: %d\n", dups);
}
``````

Linux consistently generates around 790 million duplicates. Mac consistently only generates one, so it loops through every random number that it can generate almost without repeating. Can anyone please explain to me how this works? I can't tell anything different from the `man` pages, can't tell which RNG each is using, and can't find anything online. Thanks!

• Since rand() returns values from 0..RAND_MAX inclusive, your array needs to be sized RAND_MAX+1 Commented Apr 24, 2020 at 15:19
• You might have noticed that RAND_MAX/e ~= 790 million. Also the limit of (1-1/n)^n as n approaches infinity is 1/e. Commented Apr 24, 2020 at 15:28
• @DavidSchwartz If I understand you correctly, that may explain why the number on Linux is consistently around 790 million. I guess the question then is: why/how does Mac not repeat that many times? Commented Apr 24, 2020 at 15:33
• There is no quality requirement for the PRNG in the runtime library. Only real requirement is repeatability with same seed. Apparently, the quality of the PRNG in your linux is better than in your Mac.
– pmg
Commented Apr 24, 2020 at 15:35
• @chux Yes, but since it's based on multiplication, the state can never be zero or the result (next state) would also be zero. Based on the source code it does check for zero as a special case if seeded with zero, but it doesn't ever produce zero as part of the sequence. Commented Apr 24, 2020 at 16:16

While at first it may sound like the macOS `rand()` is somehow better for not repeating any numbers, one should note that with this amount of numbers generated it is expected to see plenty of duplicates (in fact, around 790 million, or (231-1)/e). Likewise iterating through the numbers in sequence would also produce no duplicates, but wouldn't be considered very random. So the Linux `rand()` implementation is in this test indistinguishable from a true random source, whereas the macOS `rand()` is not.

Another thing that appears surprising at first glance is how the macOS `rand()` can manage to avoid duplicates so well. Looking at its source code, we find the implementation to be as follows:

``````/*
* Compute x = (7^5 * x) mod (2^31 - 1)
* without overflowing 31 bits:
*      (2^31 - 1) = 127773 * (7^5) + 2836
* From "Random number generators: good ones are hard to find",
* Park and Miller, Communications of the ACM, vol. 31, no. 10,
* October 1988, p. 1195.
*/
long hi, lo, x;

/* Can't be initialized with 0, so use another value. */
if (*ctx == 0)
*ctx = 123459876;
hi = *ctx / 127773;
lo = *ctx % 127773;
x = 16807 * lo - 2836 * hi;
if (x < 0)
x += 0x7fffffff;
return ((*ctx = x) % ((unsigned long) RAND_MAX + 1));
``````

This does indeed result in all numbers between 1 and `RAND_MAX`, inclusive, exactly once, before the sequence repeats again. Since the next state is based on multiplication, the state can never be zero (or all future states would also be zero). Thus the repeated number you see is the first one, and zero is the one that is never returned.

Apple has been promoting the use of better random number generators in their documentation and examples for at least as long as macOS (or OS X) has existed, so the quality of `rand()` is probably not deemed important, and they've just stuck with one of the simplest pseudorandom generators available. (As you noted, their `rand()` is even commented with a recommendation to use `arc4random()` instead.)

On a related note, the simplest pseudorandom number generator I could find that produces decent results in this (and many other) tests for randomness is xorshift*:

``````uint64_t x = *ctx;
x ^= x >> 12;
x ^= x << 25;
x ^= x >> 27;
*ctx = x;
return (x * 0x2545F4914F6CDD1DUL) >> 33;
``````

This implementation results in almost exactly 790 million duplicates in your test.

• A journal article published in the 1980's proposed a statistical test for PRNGs based on "birthday problem".
– pjs
Commented Apr 24, 2020 at 17:37
• "Apple has been promoting the use of better random number generators in their documentation" --> of course Apple could employ `arc4random()` like code behind `rand()` and get a good `rand()` result. Rather than try to steer programmers to code differently, just create better library functions. "they've just stuck" is their choice. Commented Apr 24, 2020 at 18:16
• the lack of a constant offset in mac's `rand()` makes it so bad that it isn't useful for practical usage: Why does rand() % 7 always return 0?, Rand() % 14 only generates the values 6 or 13 Commented Apr 25, 2020 at 5:47
• @PeterCordes: There is such a requirement on `rand`, that re-running it with the same seed produce the same sequence. OpenBSD's `rand` is broken and does not obey this contract. Commented Apr 25, 2020 at 5:55
• @R..GitHubSTOPHELPINGICE Do you see a C requirement that `rand()` with the same seed produce the same sequence on between different versions of the library? Such a guarantee might be useful for regression testing between library versions, yet I find no C requirement for it. Commented Apr 25, 2020 at 7:54

MacOS provides an undocumented rand() function in stdlib. If you leave it unseeded, then the first values it outputs are 16807, 282475249, 1622650073, 984943658 and 1144108930. A quick search will show that this sequence corresponds to a very basic LCG random number generator that iterates the following formula:

xn+1 = 75 · xn (mod 231 − 1)

Since the state of this RNG is described entirely by the value of a single 32-bit integer, its period is not very long. To be precise, it repeats itself every 231 − 2 iterations, outputting every value from 1 to 231 − 2.

I don't think there's a standard implementation of rand() for all versions of Linux, but there is a glibc rand() function that is often used. Instead of a single 32-bit state variable, this uses a pool of over 1000 bits, which to all intents and purposes will never produce a fully repeating sequence. Again, you can probably find out what version you have by printing the first few outputs from this RNG without seeding it first. (The glibc rand() function produces the numbers 1804289383, 846930886, 1681692777, 1714636915 and 1957747793.)

So the reason you're getting more collisions in Linux (and hardly any in MacOS) is that the Linux version of rand() is basically more random.

• an unseeded `rand()` must behave like one with `srand(1);`
– pmg
Commented Apr 24, 2020 at 16:02
• The source code for the `rand()` in macOS is available: opensource.apple.com/source/Libc/Libc-1353.11.2/stdlib/FreeBSD/… FWIW, I ran the same test against this compiled from the source and it does indeed result in only one duplicate. Apple has been promoting the use of other random number generators (such as `arc4random()` before Swift took over) in their examples and documentation, so the use of `rand()` is probably not very common in native apps on their platforms, which may explain why it's not better. Commented Apr 24, 2020 at 16:09
• Thanks for the reply, that answers my question. And a period of (2^31)-2 explains why it would start repeating right at the end like I observed. You (@r3mainer) said `rand()` was undocumented, but @Arkku has provided a link to the apparent source. Do either of you know why I can't find that file on my system, and why I see only `int rand(void) __swift_unavailable("Use arc4random instead.");` in Mac's `stdlib.h`? I suppose the code @Arkku linked to is just compiled into... what library? Commented Apr 24, 2020 at 16:27
• @TheronS It is compiled into the C library, libc, `/usr/lib/libc.dylib`. =) Commented Apr 24, 2020 at 16:28
• Which version of `rand()` a given C program uses is not determined by the "compiler" or the "operating system", but rather the implementation of the C standard library (e.g., `glibc`, `libc.dylib`, `msvcrt*.dll`). Commented Apr 24, 2020 at 17:05

`rand()` is defined by the C standard, and the C standard does not specify which algorithm to use. Obviously, Apple is using an inferior algorithm to your GNU/Linux implementation: The Linux one is indistinguishable from a true random source in your test, while the Apple implementation just shuffles the numbers around.

If you want random numbers of any quality, either use a better PRNG that gives at least some guarantees on the quality of the numbers it returns, or simply read from `/dev/urandom` or similar. The later gives you cryptographic quality numbers, but is slow. Even if it is too slow by itself, `/dev/urandom` can provide some excellent seeds to some other, faster PRNG.

• Thanks for the reply. I don't actually need a good PRNG, was just concerned that there was some undefined behavior lurking in my hashmap, then got curious when I eliminated that possibility and the platforms still behaved differently. Commented Apr 24, 2020 at 16:36
• btw here's an example of a cryptographically secure random number generator: github.com/divinity76/phpcpp/commit/… - but it's C++ instead of C and i'm letting the STL implementors do all the heavy lifting.. Commented Apr 25, 2020 at 10:17
• @hanshenrik A crypto RNG is generally overkill & too slow for a simple hash table. Commented Apr 25, 2020 at 20:32
• @PM2Ring Absolutely. A hash table hash primarily needs to be fast, not good. However, if you want to develop a hash table algorithm that's not just fast but also decent, I believe it's beneficial to know some of the tricks of cryptographic hash algorithms. It'll help you avoid most of the most glaring mistakes that riddle most fast hash algorithms. Nevertheless, I would not have advertised for a specific implementation here. Commented Apr 25, 2020 at 22:47
• @cmaster True enough. It's certainly a good idea to know a bit about things like mixing functions and the avalanche effect. Fortunately there are non-crypto hash functions with good properties that don't sacrifice too much speed (when implemented correctly), eg xxhash, murmur3, or siphash. Commented Apr 25, 2020 at 23:03

In general, the rand/srand pair has been considered sort of deprecated for a long time due to low-order bits displaying less randomness than high-order bits in the results. This may or may not have anything to do with your results, but I think this is still a good opportunity to remember that even though some rand/srand implementations are now more up to date, older implementations persist and it's better to use random(3). On my Arch Linux box, the following note is still in the man page for rand(3):

``````  The versions of rand() and srand() in the Linux C Library use the  same
random number generator as random(3) and srandom(3), so the lower-order
bits should be as random as the higher-order bits.  However,  on  older
rand()  implementations,  and  on  current implementations on different
systems, the lower-order bits are much less random than the  higher-or-
der bits.  Do not use this function in applications intended to be por-
table when good randomness is needed.  (Use random(3) instead.)
``````

Just below that, the man page actually gives very short, very simple example implementations of rand and srand that are about the simplest LC RNGs you've ever seen and having a small RAND_MAX. I don't think they match what's in the C standard library, if they ever did. Or at least I hope not.

In general, if you're going to use something from the standard library, use random if you can (the man page lists it as POSIX standard back to POSIX.1-2001, but rand is standard way back before C was even standardized). Or better yet, crack open Numerical Recipes (or look for it online) or Knuth and implement one. They're really easy and you only really need to do it once to have a general purpose RNG with the attributes you most often need and which is of known quality.

• Thanks for the context. I don't actually need high-quality randomness, and have implemented MT19937, though in Rust. Was mostly just curious about how to find out why the two platforms behaved differently. Commented Apr 24, 2020 at 16:34
• Sometimes the best questions are asked out of simple interest instead of strict need -- it seems like those are often the ones that beget a suite of good answers from a specific point of curiosity. Yours is one of them. Here's to all the curious people, the real and original hackers. Commented Apr 24, 2020 at 17:55
• It's funny that the advice was to "stop using rand()" instead of making rand() better. Nothing in the standard ever says that it has to be a specific generator.
– pipe
Commented Apr 25, 2020 at 12:44
• @pipe If making `rand()` ‘better’ would mean making it slower (which it probably would — cryptographically-secure random numbers take a lot of effort), then it's probably better to keep it fast even if marginally more predictable. Case in point: we had a production application that took ages to start up, which we traced to a RNG whose initialisation needed to wait for sufficient entropy to be generated… Turned out it didn't need to be so secure, so replacing it with a ‘worse’ RNG was a big improvement. Commented Apr 25, 2020 at 15:26