I think your two-pass algorithm is likely to be the best you can do, given the constraint you added in a comment that you don't know in advance which cards are eligible for a given draw.

You could try the cunning "select at random from a list of unknown size in a single pass" algorithm:

```
int sofar = 0;
int selected = -1;
for (i = 0; i < 52; ++i) {
if (used[i]) continue;
++sofar;
if ((rand() % sofar) == 0) selected = i;
}
if (selected == -1) panic; // there were no usable cards
else used[selected] = 1; // we have selected a card
```

Then if (as you say in a comment) different draws have different criteria, you can replace `used[i]`

with whatever the actual criteria are.

The way it works is that you select the first card. Then you replace it with the second card with probability 1/2. Replace the result with the third card with probability 1/3, etc. It's easy to prove by induction that after n steps, the probability of each of the preceding cards being the selected one, is 1/n.

This method uses lots of random numbers, so it's probably slower than your two-pass version unless getting each item is slow, or evaluating the criteria is slow. It'd normally be used e.g. for selecting a random line from a file, where you really don't want to run over the data twice. It's also sensitive to bias in the random numbers.

It's good and simple, though.

[Edit: proof

Let p(j,k) be the probability that card number j is the currently-selected card after step k.

Required to prove: for all n, p(j,n) = 1/n for all 1 <= j <= n

For n = 1, obviously p(1,1) = 1, since the first card is selected at the first step with probability 1/1 = 1.

Suppose that p(j,k) = 1/k for all 1 <= j <= k.

Then we select the (k+1)th card at step (k+1) with probability 1/(k+1), i.e p(k+1,k+1) = 1/(k+1).

We retain the existing selection with probability k/(k+1), so for any j < k+1:

```
p(j,k+1) = p(j,k) * k/(k+1)
= 1/k * k/(k+1) // by the inductive hypothesis
= 1/(k+1)
```

So p(j,k+1) = 1/(k+1) for all 1 <= k <= k+1

Hence, by induction, for all n: p(j,n) = 1/n for all 1 <= j <= n]