How to find number of items dropped based on individual probabilities?

My goal is to independently calculate the number of items an enemy would drop after it is killed. For example, say there are 50 potions each with a 50% chance of being dropped, I'd like to randomly return a number from 0 to 50, based on independent trials.

Currently, this is the code I'm using:

``````int droppedItems(int n, float probability) {
int count = 0;
for (int x = 1; x <= n; ++x) {
if (random() <= probability) {
++count;
}
}
return count;
}
``````

Where probability is a number from 0.0 to 1.0, random() returns 0.0 to 1.0, and n is the maximum number of items to be dropped. This is in C++ code, however, I'm actually using Visual Basic 6 - so there's no libraries to help with this.

This code works flawlessly. However, I'd like to optimize this so that if n happens to be 999999, it doesn't take forever (which it currently does).

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Which language are you writing this code in? The sample you posted looks likes like C family pseudocode (unless the `then` was included on accident?) –  chucksmash Sep 20 '12 at 18:01
@IamChuckB Made some clarifications. –  PhoenixX_2 Sep 20 '12 at 18:16
I updated my answer with code in python that relied on a library. I'll throw some C++ in there too, sans external libraries –  chucksmash Sep 20 '12 at 18:22
@IamChuckB As I mentioned, I'm using Visual Basic 6, and don't have access to any Python/C++ or other libraries. I'm more interested in being directed to some code that actually implements this since it's quite a small specific aspect of my project. –  PhoenixX_2 Sep 20 '12 at 19:22
I've updated my answer with my thoughts. The TL;DR version: for what you want it for, implementing a random number generator built on the binomial distribution from scratch, sans libraries, is going to be a prohibitively large PITA. I recommend using your current algo for current algorithms and for larger ones calculating say the first 100 n and then multiplying the result of that by some scaling factor. –  chucksmash Sep 20 '12 at 19:39

Use the binomial distribution. Wiki - Binomial Distribution

Ideally, use the libraries for whatever language this pseudocode will be written in. There's no sense in reinventing the wheel unless of course you are trying to learn how to invent a wheel.

Specifically, you'll want something that will let you generate random values given a binomial distribution with a probability of success in any given trial and a number of trials.

EDIT :

I went ahead and did this (in python, since that's where I live these days). It relies on the very nice numpy library (hooray, abstraction!):

``````>>>import numpy
>>>numpy.random.binomial(99999,0.5)
49853
>>>numpy.random.binomial(99999,0.5)
50077
``````

And, using `timeit.Timer` to check execution time:

``````# timing it across 10,000 iterations for 99,999 items per iteration
>>>timeit.Timer(stmt="numpy.random.binomial(99999,0.5)", setup="import numpy").timeit(10000)
0.00927[... seconds]
``````

EDIT 2 :

As it turns out, there isn't a simple way to implement a random number generator based off of the binomial distribution.

There is an algorithm you can implement without library support which will generate random variables from the binomial distribution. You can view it here as a PDF

My guess is that given what you want to use it for (having monsters drop loot in a game), implementing the algorithm is not worth your time. There's room for fudge factor here!

I would change your code like this (note: this is not a binomial distribution):

1. Use your current code for small values, say `n` up to `100`.
2. For `n` greater than one hundred, calculate the value of `count` for `100` using your current algorithm and then multiply the result by `n/100`.

Again, if you really want to figure out how to implement the BTPE algorithm yourself, you can - I think the method I give above wins in the trade off between effort to write and getting "close enough".

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Sampling 100 to avoid the hell of implementing it properly isn't such a bad idea ;). –  PhoenixX_2 Sep 20 '12 at 20:19

As @IamChuckB pointed out already, the key word is binomial distribution. When the number of Bernoulli trials (number of items in your example) is large enough, a good approximation is the Poisson distribution, which is much simpler to calculate and draw numbers from (the exact algorithm is spelled out in the linked Wikipedia article).

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