# What is O value for naive random selection from finite set?

This question on getting random values from a finite set got me thinking...

It's fairly common for people to want to retrieve X unique values from a set of Y values. For example, I may want to deal a hand from a deck of cards. I want 5 cards, and I want them to all be unique.

Now, I can do this naively, by picking a random card 5 times, and try again each time I get a duplicate, until I get 5 cards. This isn't so great, however, for large numbers of values from large sets. If I wanted 999,999 values from a set of 1,000,000, for instance, this method gets very bad.

The question is: how bad? I'm looking for someone to explain an O() value. Getting the xth number will take y attempts...but how many? I know how to figure this out for any given value, but is there a straightforward way to generalize this for the whole series and get an O() value?

(The question is not: "how can I improve this?" because it's relatively easy to fix, and I'm sure it's been covered many times elsewhere.)

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I would suggest you re-tag the question as big-o instead of o-value, since that is the tag under which the majority of questions about big-O notation lie. –  Alderath Aug 18 '09 at 14:01
Thanks, done. (For some reason, I couldn't remember the correct tag.) –  Beska Aug 18 '09 at 14:17
Unfortunately, the currently accepted answer from Ambuoroko is wrong. More comments on the answer itself. –  Richard Dunlap Aug 18 '09 at 19:38
I've withdrawn "accepted answer" for the time being, until I can read and evaluate the other responses. –  Beska Aug 19 '09 at 0:04
Just to be precise, the question should ask about average performance estimation. For any O() answer and time constant Tc one can always provide test sequence that will take longer than Tc * O(). –  DK. Sep 17 '09 at 22:19

### Variables

n = the total amount of items in the set
m = the amount of unique values that are to be retrieved from the set of n items
d(i) = the expected amount of tries needed to achieve a value in step i
i = denotes one specific step. i ∈ [0, n-1]
T(m,n) = expected total amount of tries for selecting m unique items from a set of n items using the naive algorithm

### Reasoning

The first step, i=0, is trivial. No matter which value we choose, we get a unique one at the first attempt. Hence:

d(0) = 1

In the second step, i=1, we at least need 1 try (the try where we pick a valid unique value). On top of this, there is a chance that we choose the wrong value. This chance is (amount of previously picked items)/(total amount of items). In this case 1/n. In the case where we picked the wrong item, there is a 1/n chance we may pick the wrong item again. Multiplying this by 1/n, since that is the combined probability that we pick wrong both times, gives (1/n)2. To understand this, it is helpful to draw a decision tree. Having picked a non-unique item twice, there is a probability that we will do it again. This results in the addition of (1/n)3 to the total expected amounts of tries in step i=1. Each time we pick the wrong number, there is a chance we might pick the wrong number again. This results in:

d(1) = 1 + 1/n + (1/n)2 + (1/n)3 + (1/n)4 + ...

Similarly, in the general i:th step, the chance to pick the wrong item in one choice is i/n, resulting in:

d(i) = 1 + i/n + (i/n)2 + (i/n)3 + (i/n)4 + ... =
= sum( (i/n)k ), where k ∈ [0,∞]

This is a geometric sequence and hence it is easy to compute it's sum:

d(i) = (1 - i/n)-1

The overall complexity is then computed by summing the expected amount of tries in each step:

T(m,n) = sum ( d(i) ), where i ∈ [0,m-1] =
= 1 + (1 - 1/n)-1 + (1 - 2/n)-1 + (1 - 3/n)-1 + ... + (1 - (m-1)/n)-1

Extending the fractions in the series above by n, we get:

T(m,n) = n/n + n/(n-1) + n/(n-2) + n/(n-3) + ... + n/(n-m+2) + n/(n-m+1)

We can use the fact that:

n/n ≤ n/(n-1) ≤ n/(n-2) ≤ n/(n-3) ≤ ... ≤ n/(n-m+2) ≤ n/(n-m+1)

Since the series has m terms, and each term satisfies the inequality above, we get:

T(m,n) ≤ n/(n-m+1) + n/(n-m+1) + n/(n-m+1) + n/(n-m+1) + ... + n/(n-m+1) + n/(n-m+1) =
= m*n/(n-m+1)

It might be(and probably is) possible to establish a slightly stricter upper bound by using some technique to evaluate the series instead of bounding by the rough method of (amount of terms) * (biggest term)

### Conclusion

This would mean that the Big-O order is O(m*n/(n-m+1)). I see no possible way to simplify this expression from the way it is.

Looking back at the result to check if it makes sense, we see that, if n is constant, and m gets closer and closer to n, the results will quickly increase, since the denominator gets very small. This is what we'd expect, if we for example consider the example given in the question about selecting "999,999 values from a set of 1,000,000". If we instead let m be constant and n grow really, really large, the complexity will converge towards O(m) in the limit n → ∞. This is also what we'd expect, since while chosing a constant number of items from a "close to" infinitely sized set the probability of choosing a previously chosen value is basically 0. I.e. We need m tries independently of n since there are no collisions.

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Big-O isn't quite what you've computed; that describes the growth of the worst-case. In the worst case, a pessimal random-number generator is't very random and you lose. Random algorithms have to be described by average/expected case behavior, and you've done that splendidly. –  Ian Sep 5 '10 at 4:54

If you already have chosen i values then the probability that you pick a new one from a set of y values is

``````(y-i)/y.
``````

Hence the expected number of trials to get (i+1)-th element is

``````y/(y-i).
``````

Thus the expected number of trials to choose x unique element is the sum

`````` y/y + y/(y-1) + ... + y/(y-x+1)
``````

This can be expressed using harmonic numbers as

y (Hy - Hy-x).

Hx = ln(x) + gamma + O(1/x)

Hence the number of necessary trials to pick x unique elements from a set of y elements is

``````y (ln(y) - ln(y-x)) + O(y/(y-x)).
``````

If you need then you can get a more precise approximation by using a more precise approximation for Hx. In particular, when x is small it is possible to improve the result a lot.

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You are completely correct. My comment was based upon a stupid mistake by me misreading the brackets as y (ln(y) - ln(y-x) + O(y/(y-x))). I'm considering removing my previous comment in order to not incorrectly discredit your result, which is in fact correct. Should I do this? –  Alderath Aug 19 '09 at 7:29
Alderath, feel free to change or delete any comments you are not comfortable with. My last section only shows that the result does not contradict your estimates. Since the results are not strong I'm also considering to remove or replace this section. After all the OP was mainly interested in the case where x is large. –  Accipitridae Aug 19 '09 at 23:24

Your actual question is actually a lot more interesting than what I answered (and harder). I've never been any good at statistitcs (and it's been a while since I did any), but intuitively, I'd say that the run-time complexity of that algorithm would probably something like an exponential. As long as the number of elements picked is small enough compared to the size of the array the collision-rate will be so small that it will be close to linear time, but at some point the number of collisions will probably grow fast and the run-time will go down the drain.

If you want to prove this, I think you'd have to do something moderately clever with the expected number of collisions in function of the wanted number of elements. It might be possible do to by induction as well, but I think going by that route would require more cleverness than the first alternative.

EDIT: After giving it some thought, here's my attempt:

Given an array of `m` elements, and looking for `n` random and different elements. It is then easy to see that when we want to pick the `i`th element, the odds of picking an element we've already visited are `(i-1)/m`. This is then the expected number of collisions for that particular pick. For picking `n` elements, the expected number of collisions will be the sum of the number of expected collisions for each pick. We plug this into Wolfram Alpha (sum (i-1)/m, i=1 to n) and we get the answer `(n**2 - n)/2m`. The average number of picks for our naive algorithm is then `n + (n**2 - n)/2m`.

Unless my memory fails me completely (which entirely possible, actually), this gives an average-case run-time `O(n**2)`.

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He specifically stated that the question was NOT how he could improve the algorithm. The question was what the complexity of the naive solution is, in a big-O sense. Please read the whole question before you answer. –  Alderath Aug 18 '09 at 13:59
Yeah, I realized that just after I posted my answer. That question was more interesting anyways, so I killed the original reply and replaced it with something relevant. –  arnsholt Aug 18 '09 at 14:05

If you're willing to make the assumption that your random number generator will always find a unique value before cycling back to a previously seen value for a given draw, this algorithm is O(m^2), where m is the number of unique values you are drawing.

So, if you are drawing m values from a set of n values, the 1st value will require you to draw at most 1 to get a unique value. The 2nd requires at most 2 (you see the 1st value, then a unique value), the 3rd 3, ... the mth m. Hence in total you require 1 + 2 + 3 + ... + m = [m*(m+1)]/2 = (m^2 + m)/2 draws. This is O(m^2).

Without this assumption, I'm not sure how you can even guarantee the algorithm will complete. It's quite possible (especially with a pseudo-random number generator which may have a cycle), that you will keep seeing the same values over and over and never get to another unique value.

==EDIT==

For the average case:

On your first draw, you will make exactly 1 draw. On your 2nd draw, you expect to make 1 (the successful draw) + 1/n (the "partial" draw which represents your chance of drawing a repeat) On your 3rd draw, you expect to make 1 (the successful draw) + 2/n (the "partial" draw...) ... On your mth draw, you expect to make 1 + (m-1)/n draws.

Thus, you will make 1 + (1 + 1/n) + (1 + 2/n) + ... + (1 + (m-1)/n) draws altogether in the average case.

This equals the sum from i=0 to (m-1) of [1 + i/n]. Let's denote that sum(1 + i/n, i, 0, m-1).

Then:

``````sum(1 + i/n, i, 0, m-1) = sum(1, i, 0, m-1) + sum(i/n, i, 0, m-1)
= m + sum(i/n, i, 0, m-1)
= m + (1/n) * sum(i, i, 0, m-1)
= m + (1/n)*[(m-1)*m]/2
= (m^2)/(2n) - (m)/(2n) + m
``````

We drop the low order terms and the constants, and we get that this is O(m^2/n), where m is the number to be drawn and n is the size of the list.

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I'm not sure I understand the first paragraph. Why are you saying O(m^2)? I don't see the logic for it. –  Beska Aug 18 '09 at 14:29
If you take 1 + 2 + 3 + ... + m (sum up all the numbers from 1 to m), you get [m*(m+1)]/2 = (m^2 + m)/2. So when you drop out all the constants and smaller-order terms, you get O(m^2) –  Ambuoroko Aug 18 '09 at 14:32
Additionally, I don't think that the first assumption is valid. If you're excluding numbers, then it's not truly random. Random numbers could, conceivably, include a series of just 9's (just like the Dilbert cartoon.) To say that hitting a number twice before getting the correct one is not allowed avoids the problem. Just because a number has been hit twice, doesn't mean that the generator has started repeating a cycle. In particular, I'm concerned with an ideal generator, with no cycling. –  Beska Aug 18 '09 at 14:35
It's definitely true that there is no guarantee that the algorithm will complete. But in the average case, it will, which is the more interesting case. –  Beska Aug 18 '09 at 14:36
I am just about finished with a proof of the average-case behaviour. I will be editing my answer to include it once I convince myself it's correct. :) –  Ambuoroko Aug 18 '09 at 14:38

There's a beautiful O(n) algorithm for this. It goes as follows. Say you have n items, from which you want to pick m items. I assume the function rand() yields a random real number between 0 and 1. Here's the algorithm:

``````items_left=n
items_left_to_pick=m
for j=1,...,n
if rand()<=(items_left_to_pick/items_left)
Pick item j
items_left_to_pick=items_left_to_pick-1
end
items_left=items_left-1
end
``````

It can be proved that this algorithm does indeed pick each subset of m items with equal probability, though the proof is non-obvious. Unfortunately, I don't have a reference handy at the moment.

Edit The advantage of this algorithm is that it takes only O(m) memory (assuming the items are simply integers or can be generated on-the-fly) compared to doing a shuffle, which takes O(n) memory.

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Asker is not asking for a better way, but for a characterization of the time complexity of the current (bad) approach. btw, a proof of correctness of this (good) approach is in Knuth, I think. –  AakashM Aug 18 '09 at 14:02
You're right -- I was shooting from the hip there. Apologies... –  Martin B Aug 18 '09 at 15:07

The worst case for this algorithm is clearly when you're choosing the full set of N items. This is equivalent to asking: On average, how many times must I roll an N-sided die before each side has come up at least once?

Answer: N * HN, where HN is the Nth harmonic number,

a value famously approximated by `log(N)`.

This means the algorithm in question is `N log N`.

As a fun example, if you roll an ordinary 6-sided die until you see one of each number, it will take on average 6 H6 = 14.7 rolls.

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Great, this is exactly an answer you can relate to. ''NlogN'' is a quite good upper bound, when ''M'' is close to ''N'', which is of cource the interesting/worst case situation. –  Thomas Ahle Jan 30 '10 at 21:19

Before being able to answer this question in details, lets define the framework. Suppose you have a collection {a1, a2, ..., an} of n distinct objects, and want to pick m distinct objects from this set, such that the probability of a given object aj appearing in the result is equal for all objects.

If you have already picked k items, and radomly pick an item from the full set {a1, a2, ..., an}, the probability that the item has not been picked before is (n-k)/n. This means that the number of samples you have to take before you get a new object is (assuming independence of random sampling) geometric with parameter (n-k)/n. Thus the expected number of samples to obtain one extra item is n/(n-k), which is close to 1 if k is small compared to n.

Concluding, if you need m unique objects, randomly selected, this algorithm gives you

n/n + n/(n-1) + n/(n-2) + n/(n-3) + .... + n/(n-(m-1))

which, as Alderath showed, can be estimated by

m*n / (n-m+1).

You can see a little bit more from this formula: * The expected number of samples to obtain a new unique element increases as the number of already chosen objects increases (which sounds logical). * You can expect really long computation times when m is close to n, especially if n is large.

In order to obtain m unique members from the set, use a variant of David Knuth's algorithm for obtaining a random permutation. Here, I'll assume that the n objects are stored in an array.

``````for i = 1..m
k = randInt(i, n)
exchange(i, k)
end
``````

here, randInt samples an integer from {i, i+1, ... n}, and exchange flips two members of the array. You only need to shuffle m times, so the computation time is O(m), whereas the memory is O(n) (although you can adapt it to only save the entries such that a[i] <> i, which would give you O(m) on both time and memory, but with higher constants).

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Most people forget that looking up, if the number has already run, also takes a while.

The number of tries nessesary can, as descriped earlier, be evaluated from:

``````T(n,m) = n(H(n)-H(n-m)) ⪅ n(ln(n)-ln(n-m))
``````

which goes to `n*ln(n)` for interesting values of `m`

However, for each of these 'tries' you will have to do a lookup. This might be a simple `O(n)` runthrough, or something like a binary tree. This will give you a total performance of `n^2*ln(n)` or `n*ln(n)^2`.

For smaller values of `m` (`m < n/2`), you can do a very good approximation for `T(n,m)` using the `HA`-inequation, yielding the formula:

``````2*m*n/(2*n-m+1)
``````

As `m` goes to `n`, this gives a lower bound of `O(n)` tries and performance `O(n^2)` or `O(n*ln(n))`.

All the results are however far better, that I would ever have expected, which shows that the algorithm might actually be just fine in many non critical cases, where you can accept occasional longer running times (when you are unlucky).

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