How can I compute a Cartesian product iteratively?

This question asks how to compute the Cartesian product of a given number of vectors. Since the number of vectors is known in advance and rather small, the solution is easily obtained with nested for loops.

Now suppose that you are given, in your language of choice, a vector of vectors (or list of lists, or set of sets, etc.):

``````l = [ [1,2,3], [4,5], [6,7], [8,9,10], [11,12], [13] ]
``````

If I was asked to compute its Cartesian product, that is

``````[ [1,4,6,8,11,13], [1,4,6,8,12,13], [1,4,6,9,11,13], [1,4,6,9,12,13], ... ]
``````

I would proceed with recursion. For example, in quick&dirty python,

``````def cartesianProduct(aListOfLists):
if not aListOfLists:
yield []
else:
for item in aListOfLists[0]:
for product in cartesianProduct(aListOfLists[1:]):
yield [item] + product
``````

Is there an easy way to compute it iteratively?

(Note: The answer doesn't need to be in python, and anyway I'm aware that in python itertools does the job better, as in this question.)

1) Create a list of indexes into the respective lists, initialized to 0, i.e:

``````indexes = [0,0,0,0,0,0]
``````

2) Yield the appropriate element from each list (in this case the first).

3) Increase the last index by one.

4) If the last index equals the length of the last list, reset it to zero and carry one. Repeat this until there is no carry.

5) Go back to step 2 until the indexes wrap back to [0,0,0,0,0,0]

It's similar to how counting works, except the base for each digit can be different.

Here's an implementation of the above algorithm in Python:

``````def cartesian_product(aListOfList):
indexes = [0] * len(aListOfList)
while True:
yield [l[i] for l,i in zip(aListOfList, indexes)]
j = len(indexes) - 1
while True:
indexes[j] += 1
if indexes[j] < len(aListOfList[j]): break
indexes[j] = 0
j -= 1
if j < 0: return
``````

Here is another way to implement it using modulo tricks:

``````def cartesian_product(aListOfList):
i = 0
while True:
result = []
j = i
for l in aListOfList:
result.append(l[j % len(l)])
j /= len(l)
if j > 0: return
yield result
i += 1
``````

Note that this outputs the results in a slightly different order than in your example. This can be fixed by iterating over the lists in reverse order.

• Yep. Rather easy indeed. Thanks. Commented Mar 10, 2010 at 18:29
• I think your code is actually slightly more inefficient than your algorithm.. ;P Commented Mar 10, 2010 at 18:36
• Yes... i have another version that closely matches the algorithm, but In thought it was quite confusing! Maybe I can post it anyway... Commented Mar 10, 2010 at 18:37
• @Larry: I've posted my first version too now! Maybe it could be written more neatly, but it works... Commented Mar 10, 2010 at 18:40
• =) Just saying, because when I submit my answer and saw yours, and yours is clearly more efficient! Commented Mar 10, 2010 at 18:54

Since you asked for a language-agnostic solution, here is one in bash, but can we call it iterative, recursive, what is it? It's just notation:

``````echo {1,2,3},{4,5},{6,7},{8,9,10},{11,12},13
``````

maybe interesting enough.

``````1,4,6,8,11,13 1,4,6,8,12,13 1,4,6,9,11,13 1,4,6,9,12,13 1,4,6,10,11,13 ...
``````

Iterate from 0 to `\Pi a_i_length` for all `i`.

``````for ( int i = 0; i < product; i++ ) {
// N is the number of lists
int now = i;
for ( int j = 0; j < N; j++ ) {
// This is actually the index, you can get the value easily.
current_list[j] = now % master_list[j].length;

// shifts digit (integer division)
now /= master_list[j].length;
}
}
``````

There are also some trivial ways to write this so you don't have to do the same work twice.

You just have to manage your stack manually. Basically, do what recursion does on your own. Since recursion puts data about each recursive call on a stack, you just do the same:

``````Let L[i] = elements in vector i
k = 0;
st[] = a pseudo-stack initialized with 0
N = number of vectors
while ( k > -1 )
{
if ( k == N ) // solution, print st and --k

if ( st[k] < L[k].count )
{
++st[k]
++k
}
else
{
st[k] = 0;
--k;
}
}
``````

Not tested, but the idea will work. Hopefully I didn't miss anything.

Edit: well, too late I guess. This is basically the same as counting, just another way of looking at it.

This solution is longer but i find it easier to understand, First, compute the number of combinations composing the product (multiplication of inner lists lengths) Second, loop over the number of combinations, the combination number is a unique encoding you can decode into a products element

E.G: [["Apple", "Orange"],[1,2,3], ..] -> 0 = ["Apple", 1], 1 = ["Apple", 2], 2 = ["Apple", 3], 4 = ["Orange", 1] ... And another e.g: ["Apple", 3] is equal to [0, 2]

you can look at each element in the master list as a digit determining the base of the encoding of the next digit, since the first element is ["Apple", "Orange"] and it's size is 2, the second digit is 2 if we had:

[["Apple", "Orange"],[1,2,3], ["Shrimp", "Creep", "Sleep"]] then the digits encoding would have been a list: [1, 2, 2*3]

``````from functools import reduce

def get_multiplication(digits: list):
return reduce(lambda x, y: x*y, map(len, digits)) if digits else 1

def get_accumalated_multiplication(x: list[list]):
return [get_multiplication(x[:i]) for i in range(len(x))]

def decode_to_product(encoding: int, encoding_digits: list, x: list):
product = [0] * len(encoding_digits)
current_product_encoding = encoding
for i, digit in enumerate(reversed(encoding_digits)):
bit = 0
while ((bit + 1) * digit)  <= current_product_encoding:
bit += 1
current_product_encoding -= digit * bit
product[i] = x[i][bit]
return tuple(product)

def product(x: list[list]):
encoding_digits = get_accumalated_multiplication(x)
num_products = reduce(lambda x, y: x*y, encoding_digits)

for i in range(num_products):
yield decode_to_product(i, encoding_digits, x)

``````