TMTOWTDI. Here are several solutions in order of complexity.

(Short primer on complexity follows):`O(n)`

or "big o" means **worst** case scenario where `n`

means the number of elements in the array, and `o(n)`

or "little o" means **best** case scenario. Long discrete math story short, you **only really have to worry about the worst case scenario**, and make sure it's not `n ^ 2`

or `n!`

. It's more a measure of change in computing time as `n`

increases than it is overall computing time. Wikipedia has a good article about computational aka time complexity.

If experience has taught me anything, it's that spending too much time optimizing your programs' little-o is a distinct waste of time better spent doing something - anything - better.

### Solution 0: `O(n) / o(1)`

complexity:

This solution has a best case scenario of 1 comparison - 1 iteration thru the loop, but **only provided the matching value is in position 0 of the array**. The worst case scenario is it's not in the array, and thus has to iterate over every element of the array.

```
foreach ($my_array as $sub_array) {
if (@$sub_array['id'] === 152) {
return true;
}
}
return false;
```

### Solution 1: `O(n) / o(n)`

complexity:

This solution must loop thru the entire array no matter where the matching value is, so it's always going to be `n`

iterations thru the array.

```
return 0 < count(
array_filter(
$my_array,
function ($a) {
return array_key_exists('id', $a) && $a['id'] == 152;
}
)
);
```

### Solution 2: `O(n log n) / o(n log n)`

complexity:

A hash insertion is where the `log n`

comes from; `n`

hash insertions = `n * log n`

. There's a hash lookup at the end which is another `log n`

but it's not included because that's just how discrete math works.

```
$existence_hash = [];
foreach ($my_array as $sub_array) {
$existence_hash[$sub_array['id']] = true;
}
return @$existence_hash['152'];
```