I need to find every possible combination of N sets of X length with no duplicates and in a particular order, e.g.

```
input: [["A"], ["B"], ["C"]]
output: [["A","B","C"],["A","B"],["A","C"],["B","C"],["A"],["B"],["C"]]
```

Rules:

- The number or size of partitions is not fixed.
- Only one member from each partition in each combination.
- Combinations with more members are higher precedence.
- Members earlier on in the input are higher precedence than members later on.

Another example with larger sets:

```
input: [["A","B"],["C","D","E"],["F"]]
output: [["A","C","F"],["A","D","F"],["A","E","F"],["B","C","F"],["B","D","F"],["B","E","F"],["A","C"],["A","D"],["A","E"],["B","C"],["B","D"],["B","E"],["A","F"],["B","F"],["C","F"],["D","F"],["E","F"],["A"],["B"],["C"],["D"],["E"],["F"]]
```

I've managed to get the output I want by combining the output of a power set function with a cartesian product function, but the resulting code isn't very concise or pretty. I was wondering if this could be better done with recursion?

Here's what I have already:

```
$test = json_decode('[["A"]]');
$test1 = json_decode('[["A"], ["B"], ["C"]]');
$test2 = json_decode('[["A", "B"], ["C", "D", "E"], ["F"]]');
/**
* Returns a power set of the input array.
*/
function power_set($in, $minLength = 1) {
$count = count($in);
$members = pow(2,$count);
$return = array();
for ($i = 0; $i < $members; $i++) {
$b = sprintf("%0".$count."b",$i);
$out = array();
for ($j = 0; $j < $count; $j++) {
if ($b[$j] == '1') {
$out[] = $in[$j];
}
}
if (count($out) >= $minLength) {
$return[] = $out;
}
}
return $return;
}
/**
* Returns the cartesian product of the input arrays.
*/
function array_cartesian() {
$_ = func_get_args();
if(count($_) == 0) {
return array(array());
}
$a = array_shift($_);
$c = call_user_func_array(__FUNCTION__, $_);
$r = array();
foreach($a as $v) {
foreach($c as $p) {
$r[] = array_merge(array($v), $p);
}
}
return $r;
}
/**
* Used with usort() to sort arrays by length, desc.
* If two arrays are the same length, then a sum of
* their keys is taken, with lower values coming first.
*/
function arraySizeDesc($a, $b) {
if(count($a) === count($b)) {
if(array_sum($a) === array_sum($b)) {
return 0;
}
return (array_sum($a) > array_sum($b)) ? 1 : -1;
}
return (count($a) < count($b)) ? 1 : -1;
}
/**
* Calculates a powerset of the input array and then uses
* this to generate cartesian products of each combination
* until all possible combinations are aquired.
*/
function combinations($in) {
$out = array();
$powerSet = power_set(array_keys($in));
usort($powerSet, 'arraySizeDesc');
foreach($powerSet as $combination) {
if(count($combination) < 2) {
foreach($in[$combination[0]] as $value) {
$out[] = array($value);
}
} else {
$sets = array();
foreach($combination as $setId) {
$sets[] = $in[$setId];
}
$out = array_merge($out, call_user_func_array('array_cartesian', $sets));
}
}
return $out;
}
echo "input: ".json_encode($test2);
echo "<br />output: ".json_encode(combinations($test2));
```

I realise the size of the output could grow very rapidly, but the input should only usually contain 1-5 sets of 1-50 members, so it doesn't need to deal with massive sets.