# Generating m distinct random numbers in the range [0..n-1]

I have two methods of generating m distinct random numbers in the range [0..n-1]

Method 1:

``````//C++-ish pseudocode
int result[m];
for(i = 0; i < m; ++i)
{
int r;
do
{
r = rand()%n;
}while(r is found in result array at indices from 0 to i)
result[i] = r;
}
``````

Method 2:

``````//C++-ish pseudocode
int arr[n];
for(int i = 0; i < n; ++i)
arr[i] = i;
random_shuffle(arr, arr+n);
result = first m elements in arr;
``````

The first method is more efficient when n is much larger than m, whereas the second is more efficient otherwise. But "much larger" isn't that strict a notion, is it? :)

Question: What formula of n and m should I use to determine whether method1 or method2 will be more efficient? (in terms of mathematical expectation of the running time)

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If `m` is really small, does efficiency matter all that much? Optimize for the case that's more likely to cause problems. – Mark Ransom Aug 4 '11 at 19:48
@Mark: I will dynamically get n and m. I will have to determine runtime which method to use – Armen Tsirunyan Aug 4 '11 at 19:49
Have you tested the two methods with a couple of different parameters? Just to get a rough feel of how long they take. – biziclop Aug 4 '11 at 20:00

Pure mathematics:
Let's calculate the quantity of `rand()` function calls in both cases and compare the results:

Case 1: let's see the mathematical expectation of calls on step `i = k`, when you already have k numbers chosen. The probability to get a number with one `rand()` call is equal to `p = (n-k)/n`. We need to know the mathematical expectation of such calls quantity which leads to obtaining a number we don't have yet.

The probability to get it using `1` call is `p`. Using `2` calls - `q * p`, where `q = 1 - p`. In general case, the probability to get it exactly after `n` calls is `(q^(n-1))*p`. Thus, the mathematical expectation is
`Sum[ n * q^(n-1) * p ], n = 1 --> INF`. This sum is equal to `1/p` (proved by wolfram alpha).

So, on the step `i = k` you will perform `1/p = n/(n-k)` calls of the `rand()` function.

Now let's sum it overall:

`Sum[ n/(n - k) ], k = 0 --> m - 1 = n * T` - the number of `rand` calls in method 1.
Here `T = Sum[ 1/(n - k) ], k = 0 --> m - 1`

Case 2:

Here `rand()` is called inside `random_shuffle` `n - 1` times (in most implementations).

Now, to choose the method, we have to compare these two values: `n * T ? n - 1`.
So, to choose the appropriate method, calculate `T` as described above. If `T < (n - 1)/n` it's better to use the first method. Use the second method otherwise.

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Thank you very much - very thorough and precise – Armen Tsirunyan Aug 5 '11 at 11:40

Check the Wikipedia description of the original Fisher-Yates algorithm. It advocates using essentially your method 1 for up to n/2, and your method 2 for the remainder.

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I think it is a tweaking issue. He will just have to measure it on the target system. – Nobody Aug 4 '11 at 20:00
This sounds about right, certainly from a memory efficiency perspective. Using method 2 can consume an awful lot of memory unnecessarily with smaller `m` values. – biziclop Aug 4 '11 at 20:02

Personally, I would use Method 1, and then if M > N/2, choose N-M values, and then invert the array (return the numbers that were not picked). So for example, if N is 1000 and you want 950 of them, chose 50 values using Method 1, and then return the other 950.

Edit: Though, if consistent performance is your goal, I would use a modified method 2, which doesn't do the full shuffle, but only shuffles the first M elements of your N length array.

``````int arr[n];
for(int i = 0; i < n; ++i)
arr[i] = i;

for (int i =0; i < m; ++i) {
int j = rand(n-i); // Pick random number from 0 <= r < n-i.  Pick favorite method
// j == 0 means don't swap, otherwise swap with the element j away
if (j != 0) {
std::swap(arr[i], arr[i+j]);
}
}
result = first m elements in arr;
``````
-

Here's an algorithm that will work in O(n) memory and O(n) time (where n is the number of returned results, not the size of the set you're selecting from) for any result set. It's in Python for convenience because it uses a hashtable:

``````def random_elements(num_elements, set_size):
state = {}
for i in range(num_elements):
# Swap state[i] with a random element
swap_with = random.randint(i, set_size - 1)
state[i], state[swap_with] = state.get(swap_with, swap_with), state.get(i, i)
return [state[i] for i in range(num_elements) # effectively state[:num_elements] if it were a list/array.
``````

This is just a partial fisher-yates shuffle, with the array being shuffled implemented as a sparse hashtable - any element that is not present is equal to its index. We shuffle the first `num_elements` indices, and return those values. In the case that `set_size = 1,` this is equivalent to picking a random number in the range, and in the case that `num_elements = set_size`, this is equivalent to a standard fisher-yates shuffle.

It's trivial to observe that this is O(n) time, and because each iteration of the loop initializes at most two new indices in the hashtable, it's O(n) space, too.

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Hashtable/dictionary access is not constant time O(1) but rather logarithmic time O(log(n)) so the overall complexity will be O(n log(n)). – astraujums Nov 19 '13 at 22:07
@astraujums It is constant amortized actually – ghord Feb 13 '15 at 9:11
I believe it should be `swap_with = random.randint(i, set_size-1)` since randint() uses an inclusive range? @nick-johnson – cidermole Feb 25 at 12:48
@cidermole Wow, you're right. Nice Python library gotcha there that I'd never noticed before. Fixed. – Nick Johnson Feb 25 at 17:27

``````int result[m];
for(i = 0; i < m; ++i)
{
int r;
r = rand()%(n-i);
r += (number of items in result <= r)
result[i] = r;
}
``````

Edit it should be <=. and it would actually additional logic to avoid collisions.

This is better, an example using the Modern Method from Fisher-Yates

``````//C++-ish pseudocode
int arr[n];
for(int i = 0; i < n; ++i)
arr[i] = i;

for(i = 0; i < m; ++i)
swap(arr, n-i, rand()%(n-i) );

result = last m elements in arr;
``````
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What do you mean by `(number of items in result < r)`? Should this mean that 1 is to be added if r is bigger than the number of items in result? – Nobody Aug 4 '11 at 20:06
+1 Once again, we were missing the obvious. It'd consume a lot of space though because you'd have to keep your results in a sorted list too to perform the `(number of items in result < r)` check efficiently. – biziclop Aug 4 '11 at 20:07
@Nobody I mean +1 for every item in result <= r. This is to compensate for the fact that we are getting `rand() to n-i` – Jacob Eggers Aug 4 '11 at 20:14
But this isn't exactly uniformly random, is it? – Armen Tsirunyan Aug 4 '11 at 20:16
@Jacob: I mean, even if we assume that rand() returns a uniformly distributed number, your algorithm will not generate uniformly distributes sequences – Armen Tsirunyan Aug 4 '11 at 20:23

Talking about mathematical expectation, it's pretty useless but I will post it anyway :D

Shuffle is simple O(m).

Now the other algorithm is a bit more complex. The number of steps needed to generate the next number is the expected value of the number of trials, and the probability of the trial length is a geomtric distribution. So...

``````p=1          E[X1]=1            = 1           = 1
p=1-1/n      E[x2]=1/(1-1/n)    = 1 + 1/(n-1) = 1 + 1/(n-1)
p=1-2/n      E[x3]=1/(1-1/n)    = 1 + 2/(n-2) = 1 + 1/(n-2) + 1/(n-2)
p=1-3/n      E[X4]=1/(1-2/n)    = 1 + 3/(n-3) = 1 + 1/(n-3) + 1/(n-3) + 1(n-3)
....
p=1-(m-1)/n) E[Xm]=1/(1-(m-1)/n))
``````

Note that the sum can be split up into a triangle shape, see right hand side.

Let's use the formula for the harmonic series: H_n = Sum k=0->n (1/k) = approx ln(k)

``````Sum(E[Xk]) = m + ln(n-1)-ln(n-m-1) + ln(n-2)-ln(n-m-1) + ... = m + ln(n-1) + ln(n-2) + ... - (m-1)*ln(n-m-1) ..
``````

And there is some forumla for the sum of harmonic series, if you are still interested I will look it up...

Update: actually it's quite nice formula (thanks to the brilliant Concrete Mathematics book)

``````Sum(H_k) k=0->n = n*H_n - n
``````

So the expected number of steps:

``````Sum(E[Xk]) = m + (n-1)*ln(n-1) - (n-1) - (n-m-1)*ln(n-m-1) - (n-m-1)) - (m-1)*ln(n-m-1).
``````

Note: I haven't verified it.

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This is a bit of a long shot, but it could work, depending on your system.