# How to efficiently pick all items one at a time randomly with weights from a collection?

I've got a collection of objects that I'd like to examine one at a time until all objects have been examined. Each object is selected by a predefined weight with many likely duplicates. The end result will be an ordered list of items from the collection. What are efficient ways to get this list?

Consider, for example, the following balls with specified volumes:

``````A: 2
B: 3
C: 25
D: 100
``````

Let's add 4 A balls, 3 B balls, 1 C ball, and 2 D balls to a bag. Supposing that the probability of drawing a particular ball is proportional to its volume then the probability of drawing a particular D ball at this point is 100/242 (they have the same weight but aren't identical). Suppose that this D was drawn and continue. The odds of drawing a C at this point are 25/142, since the D ball was removed previously. Suppose that you drew the C ball here and continue. Continue drawing until all the balls have been removed so that you have a sequence like DCDBABBA.

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If you just want to produce a string like "DCDBABBA", then I think you actually don't care about which D ball is picked -- is that right? – j_random_hacker Dec 18 '12 at 21:53
I listed it that way to simplify the question. You are correct - a more accurate string would be D0CD1B0A0B1B2A1. – balor123 Dec 18 '12 at 22:06
In that case I'll update my post. – j_random_hacker Dec 18 '12 at 22:11

[EDIT: Updated to add individual ball numbers]

Suppose there are `n` balls of `k` different types. Create a `k`-element array of `(balltype, weight, count)` triples representing the initial state. As you do this, add each `weight[i] * count[i]` to `total`, which starts out at 0.

First, set up an array of ball numbers for each ball type:

1. For `i` from 1 to `k`:
• Create a `count[i]`-element array `b[i]`, assigning `j` to `b[i][j]` for 1 <= j <= `count[i]`.

Now randomly pick a ball. The following steps can be repeated `n` times to pick all balls in some random order:

1. Choose a random integer `r` between 0 and `total` - 1, inclusive.
2. Set `p` = 0.
3. For `i` from 1 to `k`:
• Add `weight[i] * count[i]` to `p`.
• If `r < p`:
• We have picked a ball of type `balltype[i]`. Output it.
• Choose a random integer `c` between 1 and `count[i]`, inclusive.
• Output `b[i][c]` as the ball number.
• Decrease `count[i]` by 1.
• Set `b[i][c] = b[i][count[i]]`. This keeps the unused ball numbers "dense".
• Set `total = total - weight[i]`.
• Stop.

To pick out all `n` balls will take O(`nk`) time. This can be sped up by roughly a factor of 2 by moving the last entry in the array of triples to position `i` whenever `count[i]` reaches 0 (i.e. when all balls of type `i` have been used up) and decreasing `n` by 1, however for the code that chooses ball numbers to continue working, either the entire array `b[n]` must also be copied to `b[i]`, or another layer of indirection must be used.

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That was my first thought as well. Thanks for the sanity check. Maybe I'll toss out the high k-values as well as an approximation (these are net weights) so that it's linear with a high constant. – balor123 Dec 18 '12 at 22:20