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I need a function that randomizes an array similar to what shuffle does, with the difference that each element has different chances.

For example, consider the following array:

$animals = array('elephant', 'dog', 'cat', 'mouse');

elephant has an higher chance of getting on the first index than dog. Dog has an higher chance than cat and so on. For example, in this particular example elephant could have a chance of 40% in getting in the 1st position, 30% of getting on the 2nd position, 20% on getting on 3rd and 10% getting on last.

So, after the shuffling, the first elements in the original array will be more likely (but not for sure) to be in the first positions and the last ones in the last positions.

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2  
An interesting question, but the mechanism for assigning probabilities for each element ending up in each position is criminally under-specified. –  Jon Mar 21 '12 at 19:33
    
What happens below 10% for example? –  Cyclone Mar 21 '12 at 19:35
    
in this case the elephant has 10% of chance of being in the last position and 90% of chance of not being in the last position. –  Diogo Pereira Mar 21 '12 at 19:46
1  
Percentage varies due to to size of array or we enter manually ? i mean where did you get 40% ? –  safarov Mar 21 '12 at 19:57

3 Answers 3

up vote 5 down vote accepted

Normal shuffle may be implemented just as

  • dropping items randomly at some range
  • picking them up from left to right

We can adjust dropping step, drop every element not into whole range, but at some sliding window. Let N would be amount of elements in array, window width would be w and we'll move it at each step by off. Then off*(N-1) + w would be total width of the range.

Here's a function, which distorts elements' positions, but not completely at random.

function weak_shuffle($a, $strength) {
    $len = count($a);
    if ($len <= 1) return $a;
    $out = array();
    $M = mt_getrandmax();
    $w = round($M / ($strength + 1)); // width of the sliding window
    $off = ($M - $w) / ($len - 1); // offset of that window for each step.
    for ($i = 0; $i < $len; $i++) {
        do {
            $idx = intval($off * $i + mt_rand(0, $w));
        } while(array_key_exists($idx, $out));
        $out[$idx] = $a[$i];
    }
    ksort($out);
    return array_values($out);
}
  • $strength = 0 ~normal shuffle.
  • $strength = 0.25 ~your desired result (40.5%, 25.5%, 22%, 12% for elephant)
  • $strength = 1 first item will never be after last one.
  • $strength >= 3 array is actually never shuffled

Playground for testing:

$animals = array( 'elephant', 'dog', 'cat', 'mouse' );
$pos = array(0,0,0,0);
for ($iter = 0; $iter < 100000; $iter++) {
    $shuffled = weak_shuffle($animals, 0.25);
    $idx = array_search('elephant', $shuffled);
    $pos[$idx]++;
}
print_r($pos);
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+1, very nice approach. It's a pity that it has a non-deterministic run time. –  Jon Mar 21 '12 at 21:18
    
@Jon First of all, mt_getrandmax returns 2^31-1, hence conflicts are almost improbable on small arrays. Secondly, resolving same key results may be performed in some deterministic order. E.g. FIFO or gather all values with same key into array and then ... shuffle it ;-) –  kirilloid Mar 21 '12 at 21:48
    
Thanks a lot @Kirilloid that is really a clever solution and serves my purpose. You can even give it a strength, really nice. –  Diogo Pereira Mar 22 '12 at 11:25

Try to use this algorithm:

$animals  = [ 'elephant', 'dog', 'cat', 'mouse' ]; // you can add more animals here
$shuffled = [];

$count = count($animals);

foreach($animals as $chance => $animal) {
    $priority = ceil(($count - $chance) * 100 / $count);
    $shuffled = array_merge($shuffled, array_fill(0, $priority, $animal));
}

shuffle($shuffled);
$animals = array_unique($shuffled);
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You have an array, let's say of n elements. The probability that the i'th element will go to the j'th position is P(i, j). If I understood well, the following formula holds:

(P(i1, j1) >= P(i2, j2)) <=> (|i1 - j1| <= |j1 - i1|)

Thus, you have a Galois connection between the distance in your array and the shuffle probability. You can use this Galois connection to implement your exact formula if you have one. If you don't have a formula, you can invent one, which will meet the criteria specified above. Good luck.

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