# Finding cartesian product with PHP associative arrays

Say that I have an array like the following:

``````Array
(
[arm] => Array
(
[0] => A
[1] => B
[2] => C
)
[gender] => Array
(
[0] => Female
[1] => Male
)
[location] => Array
(
[0] => Vancouver
[1] => Calgary
)
)
``````

How can I find the cartesian product while preserving the keys of the outer associative array and using them in the inner ones? The result of the algorithm should be this:

``````Array
(
[0] => Array
(
[arm] => A
[gender] => Female
[location] => Vancouver
)

[1] => Array
(
[arm] => A
[gender] => Female
[location] => Calgary
)

[2] => Array
(
[arm] => A
[gender] => Male
[location] => Vancouver
)

...etc.
``````

I've looked up quite a number of cartesian product algorithms but I'm getting stuck on the specifics of how to preserve the associative keys. The current algorithm I am using gives numerical indices only:

``````    \$result = array();
foreach (\$map as \$a) {
if (empty(\$result)) {
\$result = \$a;
continue;
}
\$res = array();
foreach (\$result as \$r) {
foreach (\$a as \$v) {
\$res[] = array_merge((array)\$r, (array)\$v);
}
}
\$result = \$res;
}

print_r(\$result);
``````

Any help would be appreciated.

• Commented Aug 11, 2013 at 9:51
• This seems like a transpose action instead of cartesian product. Commented Aug 9, 2016 at 5:30
• Have a look at cartesianProduct from nSPL Commented Feb 27, 2019 at 20:36

## Rationale

Assume that we have an input array `\$input` with `N` sub-arrays, as in your example. Each sub-array has `Cn` items, where `n` is its index inside `\$input`, and its key is `Kn`. I will refer to the `i`th item of the `n`th sub-array as `Vn,i`.

The algorithm below can be proved to work (barring bugs) by induction:

1. For N = 1, the cartesian product is simply `array(0 => array(K1 => V1,1), 1 => array(K1 => V1,2), ... )` -- C1 items in total. This can be done with a simple `foreach`.

2. Assume that `\$result` already holds the cartesian product of the first N-1 sub-arrays. The cartesian product of `\$result` and the Nth sub-array can be produced this way:

3. In each item (array) inside `\$product`, add the value `KN => VN,1`. Remember the resulting item (with the added value); I 'll refer to it as `\$item`.

4a) For each array inside `\$product`:

4b) For each value in the set `VN,2 ... VN,CN`, add to `\$product` a copy of `\$item`, but change the value with the key `KN` to `VN,m` (for all `2 <= m <= CN`).

The two iterations 4a (over `\$product`) and 4b (over the Nth input sub-array) ends up with `\$result` having `CN` items for every item it had before the iterations, so in the end `\$result` indeed contains the cartesian product of the first N sub arrays.

Therefore the algorithm will work for any N.

## Code

``````function cartesian(\$input) {
\$result = array();

while (list(\$key, \$values) = each(\$input)) {
// If a sub-array is empty, it doesn't affect the cartesian product
if (empty(\$values)) {
continue;
}

// Seeding the product array with the values from the first sub-array
if (empty(\$result)) {
foreach(\$values as \$value) {
\$result[] = array(\$key => \$value);
}
}
else {
// Second and subsequent input sub-arrays work like this:
//   1. In each existing array inside \$product, add an item with
//      key == \$key and value == first item in input sub-array
//   2. Then, for each remaining item in current input sub-array,
//      add a copy of each existing array inside \$product with
//      key == \$key and value == first item of input sub-array

// Store all items to be added to \$product here; adding them
// inside the foreach will result in an infinite loop
\$append = array();

foreach(\$result as &\$product) {
// Do step 1 above. array_shift is not the most efficient, but
// it allows us to iterate over the rest of the items with a
// simple foreach, making the code short and easy to read.
\$product[\$key] = array_shift(\$values);

// \$product is by reference (that's why the key we added above
// will appear in the end result), so make a copy of it here
\$copy = \$product;

// Do step 2 above.
foreach(\$values as \$item) {
\$copy[\$key] = \$item;
\$append[] = \$copy;
}

// Undo the side effecst of array_shift
array_unshift(\$values, \$product[\$key]);
}

// Out of the foreach, we can add to \$results now
\$result = array_merge(\$result, \$append);
}
}

return \$result;
}
``````

## Usage

``````\$input = array(
'arm' => array('A', 'B', 'C'),
'gender' => array('Female', 'Male'),
'location' => array('Vancouver', 'Calgary'),
);

print_r(cartesian(\$input));
``````
• Is there a reason you did `while (list(\$key, \$values) = each(\$input)) {` instead of `foreach (\$input as \$key => \$values) {` Commented Feb 10, 2015 at 17:35
• @FunBeans: No reason. Actually I am myself surprised that I chose to write it like that, even though it was several years ago.
– Jon
Commented Feb 11, 2015 at 20:12

Here is optimized version of @Jon's cartesian function:

``````function cartesian(\$input) {
\$result = array(array());

foreach (\$input as \$key => \$values) {
\$append = array();

foreach(\$result as \$product) {
foreach(\$values as \$item) {
\$product[\$key] = \$item;
\$append[] = \$product;
}
}

\$result = \$append;
}

return \$result;
}
``````

See more examples of this algorithm in different languages: https://rosettacode.org/wiki/Cartesian_product_of_two_or_more_lists

• FYI, this technique returns a product in the 'order' I would expect - the accepted answer does not. Commented Oct 24, 2015 at 17:40
• @Matthew, thanks for noticing this, I guess that's due to the fact that "array_merge" is used in the accepted solution. Commented Oct 25, 2015 at 18:12

Why not use a recursive generator ... memory issues: close to none
(and it´s beautiful)

``````function cartesian(\$a)
{
if (\$a)
{
if(\$u=array_pop(\$a))
foreach(cartesian(\$a)as\$p)
foreach(\$u as\$v)
yield \$p+[count(\$p)=>\$v];
}
else
yield[];
}
``````

note: this does not preserve keys; but it´s a start.

This should do:

``````function acartesian(array \$a)
{
if (\$a) {
\$k = array_key_last(\$a);
if (\$u = array_pop(\$a)) {
foreach (acartesian(\$a) as \$p) {
foreach (\$u as \$v) {
yield \$p + [\$k => \$v];
}
}
}
} else {
yield[];
}
}
``````
• What is the c() function ? Commented Dec 21, 2016 at 22:38
• @PolDellaiera Oops I renamed the functions themselves after golfing; but forgot to modify the recursion calls. Fixed. Commented Dec 22, 2016 at 12:26
• How about tha callstack? Whats the maximum depth of nested calls? Commented Apr 29, 2017 at 18:13
• I asked because in your case the callstack is equal with the number of level0 items in the input array and this can become a problem with long arrays. Commented May 2, 2017 at 9:26
• Hi Titus, your solution has been ported and enhanced in a dedicated library: github.com/bpolaszek/cartesian-product (adds a count() method to count the number of combinations without ever iterating). Big thanks to you!
– Ben
Commented Apr 18, 2018 at 15:27

In PHP 7 @Serg's answer can be shortened to:

``````function cartesian(array \$input)
{
\$result = [[]];
foreach (\$input as \$key => \$values) {
\$append = [];
foreach (\$values as \$value) {
foreach (\$result as \$data) {
\$append[] = \$data + [\$key => \$value];
}
}
\$result = \$append;
}

return \$result;
}
``````

Here's what I could come up with:

``````function inject(\$elem, \$array) {
return array_map(function (\$n) use (\$elem) { return array_merge((array)\$elem, (array)\$n); }, \$array);
}

function zip(\$array1, \$array2) {
return array_reduce(\$array1, function (\$v, \$n) use (\$array2) { return array_merge(\$v, inject(\$n, \$array2));  }, array());
}

function cartesian_product(\$array) {
\$keys = array_keys(\$array);
\$prod = array_shift(\$array);
\$prod = array_reduce(\$array, 'zip', \$prod);
return array_map(function (\$n) use (\$keys) { return array_combine(\$keys, \$n); }, \$prod);
}
``````

(Using pseudo array/list/dictionary notation below since PHP is simply too verbose for such things.)

The `inject` function transforms `a, [b]` into `[(a,b)]`, i.e. it injects a single value into each value of an array, returning an array of arrays. It doesn't matter whether `a` or `b` already is an array, it'll always return a two dimensional array.

``````inject('a', ['foo', 'bar'])
=>  [('a', 'foo'), ('b', 'bar')]
``````

The `zip` function applies the `inject` function to each element in an array.

``````zip(['a', 'b'], ['foo', 'bar'])
=>  [('a', 'foo'), ('a', 'bar'), ('b', 'foo'), ('b', 'bar')]
``````

Note that this actually produces a cartesian product, so `zip` is a slight misnomer. Simply applying this function to all elements in a data set in succession gives you the cartesian product for an array of any length.

``````zip(zip(['a', 'b'], ['foo', 'bar']), ['42', '76'])
=>  [('a', 'foo', '42'), ('a', 'foo', '76'), ('a', 'bar', '42'), …]
``````

This does not contain the keys, but since the elements are all in order within the result set, you can simply re-inject the keys into the result.

``````array_combine(['key1', 'key2', 'key3'], ['a', 'foo', '42'])
=>  [ key1 : 'a', key2 : 'foo', key3 : '42' ]
``````

Applying this to all elements in the product gives the desired result.

You can collapse the above three functions into a single long statement if you wish (which would also clear up the misnomers).

An "unrolled" version without anonymous functions for PHP <= 5.2 would look like this:

``````function inject(\$elem, \$array) {
\$elem = (array)\$elem;
foreach (\$array as &\$a) {
\$a = array_merge(\$elem, (array)\$a);
}
return \$array;
}

function zip(\$array1, \$array2) {
\$prod = array();
foreach (\$array1 as \$a) {
\$prod = array_merge(\$prod, inject(\$a, \$array2));
}
return \$prod;
}

function cartesian_product(\$array) {
\$keys = array_keys(\$array);
\$prod = array_shift(\$array);
\$prod = array_reduce(\$array, 'zip', \$prod);

foreach (\$prod as &\$a) {
\$a = array_combine(\$keys, \$a);
}
return \$prod;
}
``````

Another solution:

``````function getAllVariations(\$input) {
\$result = array();
\$cnt = array_product(array_map('count', \$input));
\$step = 1;
foreach (\$input as \$key=>\$array) {
for (\$i=0; \$i<\$cnt; \$i++) {
foreach (\$array as \$value) {
for (\$k=0; \$k<\$step; \$k++) {
\$result[\$i+\$k][\$key] = \$value;
}
\$i += \$step;
}
\$i--;
}
\$step = \$step * count(\$array);
}
return \$result;
}
``````

Usage:

``````\$input = array(
'arm' => array('A', 'B', 'C'),
'gender' => array('Female', 'Male'),
'location' => array('Vancouver', 'Calgary'),
'name' => array('Rio', 'Mark')
);

echo "<pre>";
var_dump(getAllVariations(\$input));
``````

If memory consumption is important or you don't need all the combinations in the end you could use an iterator to generate one combination at a time. If you need all the combinations you can use `iterator_to_array`.

``````function cartezianIterator(\$inputArray)
{
\$maximumPosition = array_map('count', \$inputArray);

while (false !== (\$item = buildItemAtPosition(\$inputArray, \$position))) {

yield \$item;

\$position = incrementPosition(\$position, \$maximumPosition);
}
}

function buildItemAtPosition(\$inputArray, \$positions)
{
if (\$positions[0] >= count(\$inputArray[0])) {
return false;
}

\$item = [];
foreach (\$inputArray as \$rowIndex => \$row) {
\$position = \$positions[\$rowIndex];

\$item[] = \$row[\$position];
}

return \$item;
}

function incrementPosition(\$position, \$maximumPosition)
{
\$digitToIncrement = count(\$position) - 1;

do {
\$position[\$digitToIncrement]++;

if (\$position[\$digitToIncrement] < \$maximumPosition[\$digitToIncrement] || 0 === \$digitToIncrement) {
//no overflow
break;
}

//overflow, reset to zero and increment parent digit
\$position[\$digitToIncrement] = 0;

\$digitToIncrement--;
} while (\$digitToIncrement >= 0);

return \$position;
}
``````

Then, to get one solution at a time you could use a `foreach` or `next`, like this:

``````\$iterator = cartezianIterator(\$inputArray);

//of course, you need to do something with the result...
\$combination = next(\$iterator);
\$combination = next(\$iterator);
\$combination = next(\$iterator);
\$combination = next(\$iterator);
\$combination = next(\$iterator);
\$combination = next(\$iterator);
``````

This solution is very very fast if you need only a few combinations. Also, the memory consumption is very low (it uses a flat `array` to store some `integers`).

Note: recursive functions are not used.

I quickly adjusted your code a bit , my attempt is crude i think but see if this works as you want:

``````\$result = array();
\$nm = '';
foreach (\$map as \$name => \$a) {
if (empty(\$result)) {
\$result = \$a;
\$nm = \$name;
continue;
}

\$res = array();
foreach (\$result as \$r) {
foreach (\$a as \$v) {
\$myr = \$r;
\$myv = \$v;
if(!is_array(\$r)) \$myr = array(\$nm => \$r);
if(!is_array(\$v)) \$myv = array(\$name => \$v);

\$res[] = array_merge(\$myr, \$myv);
}
}
\$result = \$res;
}
echo "<pre>";
print_r(\$result);
``````

Why not use a database to do this?

It's easy in MySQL..

``````table arm
id integer primary key
label char

table gender
id integer primary key
gender enum('male','female')

table location
id integer primary key
city varchar(255)
``````

Then do a query

``````\$query = mysql_query("
SELECT a.label, g.gender, l.city
FROM arm a
CROSS JOIN gender g
CROSS JOIN location l
ORDER BY a.id
") or die("Could not execute query");

while(\$row = mysql_fetch_array(\$query) )
{
....
}
``````

• Thanks for your solution but I can not do this particular problem in a database. I will definitely use your query as a reference if I do later on, however. Commented Jun 11, 2011 at 18:47

One algorithm is to expand at each step the previous results with the current step items:

``````function cartezian1(\$inputArray)
{
\$results = [];

foreach (\$inputArray as \$group) {
\$results = expandItems(\$results, \$group);
}

return \$results;
}

function expandItems(\$sourceItems, \$tails)
{
\$result = [];

if (empty(\$sourceItems)) {
foreach (\$tails as \$tail) {
\$result[] = [\$tail];
}
return \$result;
}

foreach (\$sourceItems as \$sourceItem) {
foreach (\$tails as \$tail) {
\$result[] = array_merge(\$sourceItem, [\$tail]);
}
}

return \$result;
}
``````

This solution uses memory to store the all combinations then returns them all at once. So, it's fast but it needs a lot of memory. Also, recursive functions are not used.