# Why do people say there is modulo bias when using a random number generator?

I have seen this question asked a lot but never seen a true concrete answer to it. So I am going to post one here which will hopefully help people understand why exactly there is "modulo bias" when using a random number generator, like `rand()` in C++.

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So `rand()` is a pseudo-random number generator which chooses a natural number between 0 and `RAND_MAX`, which is a constant defined in `cstdlib` (see this article for a general overview on `rand()`).

Now what happens if you want to generate a random number between say 0 and 2. For the sake of explanation, let's say `RAND_MAX` is 10 and I decide to generate a random number between 0 and 2 by calling `rand()%3`. However, `rand()%3` does not produce the numbers between 0 and 2 with equal probability! When `rand()` returns 0, 3, 6, or 9, `rand()%3 == 0`. When `rand()` returns 1, 4, 7, or 10, `rand()%3 == 1`. When `rand()` returns 2, 5, or 8, `rand()%3 == 2`. Now if we analyze this statistically, we very quickly see that the probability of getting a 0 is 4/11, 1 is 4/11 but 2 is 3/11. This does not generate the numbers between 0 and 2 with equal probability. Of course for small ranges this might not be the biggest issue but for a larger range this could skew the distribution, biasing the smaller numbers.

So when does `rand()%n` return a range of numbers from 0 to n-1 with equal probability? When `RAND_MAX%n == n - 1`. In this case, along with our earlier assumption `rand()` does return a number between 0 and `RAND_MAX` with equal probability, the modulo classes of n would also be equally distributed.

So how do we solve this problem? One way is to keep generating random numbers until you get a number in your desired range:

``````int x;
do {
x = rand();
} while (x >= n);
``````

Hope that helps everyone!

Works cited and further reading:

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+1 for answering a questions perfectly that I didn't even know was an issue! –  Bolster Jun 11 '12 at 17:46
Another way is to use a better random number facility, like the one in `<random>` or Boost.Random. –  R. Martinho Fernandes Jun 11 '12 at 17:46
Additionally, poor random number generators (such as `rand`) have much less random low order bits than high order ones. So `x % n` should really be replaced by `x * n / RAND_MAX` (or non-overflowing equivalent). In any case, you have the same kind of bias, due to the exact same pigeonhole argument you gave and the cure is more or less the same. –  Alexandre C. Jun 11 '12 at 19:40
"One way is to keep generating random numbers till you get a number in your desired range" - We don't need it to be in our desired range, we just need it to be below the largest number that is `== 0 (mod n)`. So we can check `while(x >= RAND_MAX - n && x >= n)` then take `x%n`. That way the expected number of `rand()` calls is 2 in the worst case (rather than millions, as in your code) –  BlueRaja - Danny Pflughoeft Jun 12 '12 at 3:17
@opert: Yes, I've come to realize my conditional above is broken. However, Nick's is broken as well - it doesn't work when `RAND_MAX == INT_MAX` (`RAND_MAX+1` will loop around and all hell will break loose). To fix his statement, we need to add after the mod.. but then mod again, in case we hit `n`. Thus, the correct conditional statement is `while(x > RAND_MAX - ((RAND_MAX%n)+1)%n)` –  BlueRaja - Danny Pflughoeft Nov 6 '12 at 22:02

Keep selecting a random is a good way to remove the bias.

Update

We could make the code fast if we search for an x in range divisible by `n`.

``````// Assumptions
// rand() in [0, RAND_MAX]
// n in (0, RAND_MAX]

int x = rand();

// Keep searching for an x in a range divisible by n
while (x >= RAND_MAX - (RAND_MAX % n)) {
x = rand();
}

x %= n;
``````

The above loop should be very fast, say 1 iteration on average.

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Yuck :-P converting to a double, then multiplying by MAX_UPPER_LIMIT/RAND_MAX is much cleaner and performs better. –  boycy Jun 13 '12 at 7:59
@boycy: you've missed the point. If the number of values that `rand()` can return is not a multiple of `n`, then whatever you do, you will inevitably get 'modulo bias', unless you discard some of those values. user1413793 explains that nicely (although the solution proposed in that answer is truly yucky). –  TonyK Jun 17 '12 at 11:31
@TonyK my apologies, I did miss the point. Didn't think hard enough, and thought the bias would only apply with methods using an explicit modulus operation. Thanks for fixing me :-) –  boycy Jun 18 '12 at 12:26
Operator precedence makes `RAND_MAX+1 - (RAND_MAX+1) % n` work correctly, but I still think it should be written as `RAND_MAX+1 - ((RAND_MAX+1) % n)` for clarity. –  opert Oct 13 '12 at 5:07
This won't work if `RAND_MAX == INT_MAX` (as it does on most systems). See my second comment to @user1413793 above. –  BlueRaja - Danny Pflughoeft Nov 6 '12 at 22:04

There are two usual complains with the use of modulo.

• one is valid for all generators. It is easier to see in an limit case. If your generator has a RAND_MAX which is 2 (that isn't compliant with the C standard) and you want only 0 or 1 as value, using modulo will generate 0 twice as often (when the generator generates 0 and 2) as it will generate 1 (when the generator generates 1). Note that this is true as soon as you don't drop values, whatever the mapping you are using from the generator values to the wanted one, one will occurs twice as often as the other.

• some kind of generator have their less significant bits less random than the other, at least for some of their parameters, but sadly those parameter have other interesting characteristic (such has being able to have RAND_MAX one less than a power of 2). The problem is well known and for a long time library implementation probably avoid the problem (for instance the sample rand() implementation in the C standard use this kind of generator, but drop the 16 less significant bits), but some like to complain about that and you may have bad luck

Using something like

``````int alea(int n){
assert (0 < n && n <= RAND_MAX);
int partSize =
n == RAND_MAX ? 1 : 1 + (RAND_MAX-n)/(n+1);
int maxUsefull = partSize * n + (partSize-1);
int draw;
do {
draw = rand();
} while (draw > maxUsefull);
return draw/partSize;
}
``````

to generate a random number between 0 and n will avoid both problems (and it avoids overflow with RAND_MAX == INT_MAX)

BTW, C++11 introduced standard ways to the the reduction and other generator than rand().

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n == RAND_MAX ? 1 : (RAND_MAX-1)/(n+1): I understand the idea here is to first divide RAND_MAX into equal page size N, then return the deviation within N, but I cannot map the code to this precisely. –  zinking Jun 15 '12 at 3:18
The naive version should be (RAND_MAX+1)/(n+1) as there is RAND_MAX+1 values to divide in n+1 buckets. If order to avoid overflow when computing RAND_MAX+1, it can be transformed in 1+(RAND_MAX-n)/(n+1). In order to avoid overflow when computing n+1, the case n==RAND_MAX is first checked. –  AProgrammer Jun 15 '12 at 6:42
+plus, doing divide is seeming costing more even compared with regenerate numbers. –  zinking Jun 15 '12 at 8:56
Taking the modulo and dividing have the same cost. Some ISA even provide just one instruction which provide always both. The cost of regenerating numbers will depend on n and RAND_MAX. If n is small in respect to RAND_MAX, it may cost a lot. And obviously you may decide the the biases isn't important for your application; I just give a way to avoid them. –  AProgrammer Jun 15 '12 at 9:10

As the accepted answer indicates, "modulo bias" has its roots in the low value of `RAND_MAX`. He uses an extremely small value of `RAND_MAX` (10) to show that if RAND_MAX were 10, then you tried to generate a number between 0 and 2 using %, the following outcomes would result:

``````rand() % 3   // if RAND_MAX were only 10, gives
output of rand()   |   rand()%3
0                  |   0
1                  |   1
2                  |   2
3                  |   0
4                  |   1
5                  |   2
6                  |   0
7                  |   1
8                  |   2
9                  |   0
``````

So there are 4 outputs of 0's (4/10 chance) and only 3 outputs of 1 and 2 (3/10 chances each).

So it's biased. The lower numbers have a better chance of coming out.

But that only shows up so obviously when `RAND_MAX` is small. Or more specifically, when the number your are modding by is large compared to `RAND_MAX`.

A much better solution than looping (which is insanely inefficient and shouldn't even be suggested) is to use a PRNG with a much larger output range. The Mersenne Twister algorithm has a maximum output of 4,294,967,295. As such doing `MersenneTwister::genrand_int32() % 10` for all intents and purposes, will be equally distributed and the modulo bias effect will all but disappear.

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Yours is more efficient and it probably is true that if RAND_MAX is significantly bigger then the number you are modding by, however yours will still be biased. Granted these are all pseudo random number generators anyways and that in and of itself is a different topic but if you assume a fully random number generator, your way still biases the lower values. –  user1413793 Apr 16 '13 at 3:09
Because the highest value is odd, `MT::genrand_int32()%2` picks 0 (50 + 2.3e-8)% of the time and 1 (50 - 2.3e-8)% of the time. Unless you're building a casino's RGN (which you probably would use a much larger range RGN for), any user is not going to notice an extra 2.3e-8% of the time. You're talking about numbers too small to matter here. –  bobobobo Apr 16 '13 at 4:08
Looping is the best solution. It is not "insanely inefficient"; requiring less than twice the iterations in worst average case. Using a high `RAND_MAX` value will decrease the modulo bias, but not eliminate it. Looping will. –  Jared Nielsen Jul 3 '13 at 16:22
If `RAND_MAX` is sufficiently bigger than the number you are modding by, the number of times you need to regenerate the random number is vanishingly small and won't affect the efficiency. I say keep the looping, as long as you're testing against the largest multiple of `n` rather than just `n` as proposed by the accepted answer. –  Mark Ransom Apr 8 at 1:08

I wrote a tool to demonstrate the bias when using a PRNG and modulo: https://gitorious.org/modulo-test/modulo-test/trees/master

You can see a demonstration of the tool in the following question: mathematics behind modulo behavor

With this tool you choose an input range (power of two) and an output range. With the correct number of iterations, it will return the probability for each output value and you will be able to see the the bias.

Regards.

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@user1413793 is correct about the problem. I'm not going to discuss that further, except to make one point: yes, for small values of `n` and large values of `RAND_MAX`, the modulo bias can be very small. But using a bias-inducing pattern means that you must consider the bias every time you calculate a random number and choose different patterns for different cases. And if you make the wrong choice, the bugs it introduces are subtle and almost impossible to unit test. Compared to just using the proper tool (such as `arc4random_uniform`), that's extra work, not less work. Doing more work and getting a worse solution is terrible engineering, especially when doing it right every time is easy on most platforms.

Unfortunately, the implementations of the solution are all incorrect or less efficient than they should be. (Each solution has various comments explaining the problems, but none of the solutions have been fixed to address them.) This is likely to confuse the casual answer-seeker, so I'm providing a known-good implementation here.

Again, the best solution is just to use `arc4random_uniform` on platforms that provide it, or a similar ranged solution for your platform (such as `Random.nextInt` on Java). It will do the right thing at no code cost to you. This is almost always the correct call to make.

If you don't have `arc4random_uniform`, then you can use the power of opensource to see exactly how it is implemented on top of a wider-range RNG (`ar4random` in this case, but a similar approach could also work on top of other RNGs).

Here is the OpenBSD implementation:

``````/*
* Calculate a uniformly distributed random number less than upper_bound
* avoiding "modulo bias".
*
* Uniformity is achieved by generating new random numbers until the one
* returned is outside the range [0, 2**32 % upper_bound).  This
* guarantees the selected random number will be inside
* [2**32 % upper_bound, 2**32) which maps back to [0, upper_bound)
* after reduction modulo upper_bound.
*/
u_int32_t
arc4random_uniform(u_int32_t upper_bound)
{
u_int32_t r, min;

if (upper_bound < 2)
return 0;

/* 2**32 % x == (2**32 - x) % x */
min = -upper_bound % upper_bound;

/*
* This could theoretically loop forever but each retry has
* p > 0.5 (worst case, usually far better) of selecting a
* number inside the range we need, so it should rarely need
* to re-roll.
*/
for (;;) {
r = arc4random();
if (r >= min)
break;
}

return r % upper_bound;
}
``````

It is worth noting the latest commit comment on this code for those who need to implement similar things:

Change arc4random_uniform() to calculate ```2**32 % upper_bound'' as ```-upper_bound % upper_bound''. Simplifies the code and makes it the same on both ILP32 and LP64 architectures, and also slightly faster on LP64 architectures by using a 32-bit remainder instead of a 64-bit remainder.

Pointed out by Jorden Verwer on tech@ ok deraadt; no objections from djm or otto

The Java implementation is also easily findable (see previous link):

``````public int nextInt(int n) {
if (n <= 0)
throw new IllegalArgumentException("n must be positive");

if ((n & -n) == n)  // i.e., n is a power of 2
return (int)((n * (long)next(31)) >> 31);

int bits, val;
do {
bits = next(31);
val = bits % n;
} while (bits - val + (n-1) < 0);
return val;
}
``````
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I just wrote a code for Von Neumann's Unbiased Coin Flip Method, that should theoretically eliminate any bias in the random number generation process. More info can be found at (http://en.wikipedia.org/wiki/Fair_coin)

``````int unbiased_random_bit() {
int x1, x2, prev;
prev = 2;
x1 = rand() % 2;
x2 = rand() % 2;

for (;; x1 = rand() % 2, x2 = rand() % 2)
{
if (x1 ^ x2)      // 01 -> 1, or 10 -> 0.
{
return x2;
}
else if (x1 & x2)
{
if (!prev)    // 0011
return 1;
else
prev = 1; // 1111 -> continue, bias unresolved
}
else
{
if (prev == 1)// 1100
return 0;
else          // 0000 -> continue, bias unresolved
prev = 0;
}
}
}
``````
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This doesn't address modulo bias. This process could be used to eliminate bias in a bit stream. However, to get from a bit stream to an even distribution from 0 to n where n is not one less than a power of two requires addressing modulo bias. Thus this solution cannot eliminate any bias in the random number generation process. –  Rick Aug 5 at 13:06

# Definition

Modulo Bias is the inherent bias in using modulo arithmetic to reduce an output set to a subset of the input set. In general, a bias exists whenever the mapping between the input and output set is not equally distributed, as in the case of using modulo arithmetic when the size of the output set is not a divisor of the size of the input set.

This bias is particularly hard to avoid in computing, where numbers are represented as strings of bits: 0s and 1s. Finding truly random sources of randomness is also extremely difficult, but is beyond the scope of this discussion. For the remainder of this answer, assume that there exists an unlimited source of truly random bits.

# Problem Example

Let's consider simulating a die roll (0 to 5) using these random bits. There are 6 possibilities, so we need enough bits to represent the number 6, which is 3 bits. Unfortunately, 3 random bits yields 8 possible outcomes:

``````000 = 0, 001 = 1, 010 = 2, 011 = 3
100 = 4, 101 = 5, 110 = 6, 111 = 7
``````

We can reduce the size of the outcome set to exactly 6 by taking the value modulo 6, however this presents the modulo bias problem: `110` yields a 0, and `111` yields a 1. This die is loaded.

# Potential Solutions

## Approach 0:

Rather than rely on random bits, in theory one could hire a small army to roll dice all day and record the results in a database, and then use each result only once. This is about as practical as it sounds, and more than likely would not yield truly random results anyway (pun intended).

## Approach 1:

Instead of using the modulus, a naive but mathematically correct solution is to discard results that yield `110` and `111` and simply try again with 3 new bits. Unfortunately, this means that there is a 25% chance on each roll that a re-roll will be required, including each of the re-rolls themselves. This is clearly impractical for all but the most trivial of uses.

## Approach 2:

Use more bits: instead of 3 bits, use 4. This yield 16 possible outcomes. Of course, re-rolling anytime the result is greater than 5 makes things worse (10/16 = 62.5%) so that alone won't help.

Notice that 2 * 6 = 12 < 16, so we can safely take any outcome less than 12 and reduce that modulo 6 to evenly distribute the outcomes. The other 4 outcomes must be discarded, and then re-rolled as in the previous approach.

Sounds good at first, but let's check the math:

``````4 discarded results / 16 possibilities = 25%
``````

In this case, 1 extra bit didn't help at all!

That result is unfortunate, but let's try again with 5 bits:

``````32 % 6 = 2 discarded results; and
2 discarded results / 32 possibilities = 6.25%
``````

A definite improvement, but not good enough in many practical cases. The good news is, adding more bits will never increase the chances of needing to discard and re-roll. This holds not just for dice, but in all cases.

As demonstrated however, adding an 1 extra bit may not change anything. In fact if we increase our roll to 6 bits, the probability remains 6.25%.

This begs 2 additional questions:

1. If we add enough bits, is there a guarantee that the probability of a discard will diminish?
2. How many bits are enough in the general case?

# General Solution

Thankfully the answer to the first question is yes. The problem with 6 is that 2^x mod 6 flips between 2 and 4 which coincidentally are a multiple of 2 from each other, so that for an even x > 1,

``````[2^x mod 6] / 2^x == [2^(x+1) mod 6] / 2^(x+1)
``````

Thus 6 is an exception rather than the rule. It is possible to find larger moduli that yield consecutive powers of 2 in the same way, but eventually this must wrap around, and the probability of a discard will be reduced.

Without offering further proof, in general using double the number of bits required will provide a smaller, usually insignificant, chance of a discard.

# Proof of Concept

Here is an example program that uses OpenSSL's libcrypo to supply random bytes. When compiling, be sure to link to the library with `-lcrypto` which most everyone should have available.

``````#include <iostream>
#include <assert.h>
#include <limits>
#include <openssl/rand.h>

volatile uint32_t dummy;

uint32_t uniformRandomUint32(uint32_t upperBound)
{
assert(RAND_status() == 1);
uint64_t discard = (std::numeric_limits<uint64_t>::max() - upperBound) % upperBound;
uint64_t randomPool = RAND_bytes((uint8_t*)(&randomPool), sizeof(randomPool));

while(randomPool > (std::numeric_limits<uint64_t>::max() - discard)) {
RAND_bytes((uint8_t*)(&randomPool), sizeof(randomPool));
}

return randomPool % upperBound;
}

int main() {

const uint32_t MODULUS = (1ul << 31)-1;
const uint32_t ROLLS = 10000000;

for(uint32_t i = 0; i < ROLLS; ++i) {
dummy = uniformRandomUint32(MODULUS);
}
std::cout << "Discard count = " << discardCount << std::endl;
}
``````

I encourage playing with the `MODULUS` and `ROLLS` values to see how many re-rolls actually happen under most conditions. A sceptical person may also wish to save the computed values to file and verify the distribution appears normal.

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