# What's a good, non-recursive algorithm to calculate a Cartesian product?

### Note

This is not a REBOL-specific question. You can answer it in any language.

### Background

The REBOL language supports the creation of domain-specific languages known as "dialects" in REBOL parlance. I've created such a dialect for list comprehensions, which aren't natively supported in REBOL.

A good cartesian product algorithm is needed for list comprehensions.

### The Problem

I've used meta-programming to solve this, by dynamically creating and then executing a sequence of nested `foreach` statements. It works beautifully. However, because it's dynamic, the code is not very readable. REBOL doesn't do recursion well. It rapidly runs out of stack space and crashes. So a recursive solution is out of the question.

In sum, I want to replace my meta-programming with a readable, non-recursive, "inline" algorithm, if possible. The solution can be in any language, as long as I can reproduce it in REBOL. (I can read just about any programming language: C#, C, C++, Perl, Oz, Haskell, Erlang, whatever.)

I should stress that this algorithm needs to support an arbitrary number of sets to be "joined", since list comprehension can involve any number of sets.

-

``````#!/usr/bin/perl

use strict;
use warnings;

my @list1 = qw(1 2);
my @list2 = qw(3 4);
my @list3 = qw(5 6);

# Calculate the Cartesian Product
my @cp = cart_prod(\@list1, \@list2, \@list3);

# Print the result
foreach my \$elem (@cp) {
print join(' ', @\$elem), "\n";
}

sub cart_prod {
my @sets = @_;
my @result;
my \$result_elems = 1;

# Calculate the number of elements needed in the result
map { \$result_elems *= scalar @\$_ } @sets;
return undef if \$result_elems == 0;

# Go through each set and add the appropriate element
# to each element of the result
my \$scale_factor = \$result_elems;
foreach my \$set (@sets)
{
my \$set_elems = scalar @\$set;  # Elements in this set
\$scale_factor /= \$set_elems;
foreach my \$i (0 .. \$result_elems - 1) {
# Calculate the set element to place in this position
# of the result set.
my \$pos = \$i / \$scale_factor % \$set_elems;
push @{\$result[\$i]}, \$\$set[ \$pos ];
}
}

return @result;
}
``````

Which produces the following output:

``````1 3 5
1 3 6
1 4 5
1 4 6
2 3 5
2 3 6
2 4 5
2 4 6
``````
-
That looks great! I'm going to wait and see if I get any other responses (for curiosity's sake) before I award the answer, but I think you've got it. – Gregory Higley Oct 19 '08 at 3:51
If you're doing this in Perl, just use Set::CrossProduct – brian d foy Aug 10 '09 at 21:26

3 times Faster and less memory used (less recycles).

``````cartesian: func [
d [block! ]
/local len set i res

][
d: copy d
len: 1
res: make block! foreach d d [len: len * length? d]
len: length? d
until [
set: clear []
loop i: len [insert set d/:i/1   i: i - 1]
res: change/only res copy set
loop i: len [
unless tail? d/:i: next d/:i [break]
if i = 1 [break]
i: i - 1
]
tail? d/1
]
]
``````
-
Excellent! You are obviously twice the reboller I am. – Gregory Higley Sep 23 '09 at 18:29

For the sake of completeness, Here's Robert Gamble's answer translated into REBOL:

```REBOL []

cartesian: func [
{Given a block of sets, returns the Cartesian product of said sets.}
sets [block!] {A block containing one or more series! values}
/local
elems
result
row
][
result: copy []

elems: 1
foreach set sets [
elems: elems * (length? set)
]

for n 0 (elems - 1) 1 [
row: copy []
skip: elems
foreach set sets [
skip: skip / length? set
index: (mod to-integer (n / skip) length? set) + 1 ; REBOL is 1-based, not 0-based
append row set/(index)
]
append/only result row
]

result
]

foreach set cartesian [[1 2] [3 4] [5 6]] [
print set
]

; This returns the same thing Robert Gamble's solution did:

1 3 5
1 3 6
1 4 5
1 4 6
2 3 5
2 3 6
2 4 5
2 4 6
```
-

Here is a Java code to generate Cartesian product for arbitrary number of sets with arbitrary number of elements.

in this sample the list "ls" contains 4 sets (ls1,ls2,ls3 and ls4) as you can see "ls" can contain any number of sets with any number of elements.

``````import java.util.*;

public class CartesianProduct {

private List <List <String>> ls = new ArrayList <List <String>> ();
private List <String> ls1 = new ArrayList <String> ();
private List <String> ls2 = new ArrayList <String> ();
private List <String> ls3 = new ArrayList <String> ();
private List <String> ls4 = new ArrayList <String> ();

public List <String> generateCartesianProduct () {
List <String> set1 = null;
List <String> set2 = null;

boolean subsetAvailabe = true;
int setCount = 0;

try{
set1 = augmentSet (ls.get (setCount++), ls.get (setCount));
} catch (IndexOutOfBoundsException ex) {
if (set1 == null) {
set1 = ls.get(0);
}
return set1;
}

do {
try {
setCount++;
set1 = augmentSet(set1,ls.get(setCount));
} catch (IndexOutOfBoundsException ex) {
subsetAvailabe = false;
}
} while (subsetAvailabe);
return set1;
}

public List <String> augmentSet (List <String> set1, List <String> set2) {

List <String> augmentedSet = new ArrayList <String> (set1.size () * set2.size ());
for (String elem1 : set1) {
for(String elem2 : set2) {
augmentedSet.add (elem1 + "," + elem2);
}
}
set1 = null; set2 = null;
return augmentedSet;
}

public static void main (String [] arg) {
CartesianProduct cp = new CartesianProduct ();
List<String> cartesionProduct = cp.generateCartesianProduct ();
for (String val : cartesionProduct) {
System.out.println (val);
}
}
}
``````
-
``````use strict;

print "@\$_\n" for getCartesian(
[qw(1 2)],
[qw(3 4)],
[qw(5 6)],
);

sub getCartesian {
#
my @input = @_;
my @ret = map [\$_], @{ shift @input };

for my \$a2 (@input) {
@ret = map {
my \$v = \$_;
map [@\$v, \$_], @\$a2;
}
@ret;
}
return @ret;
}
``````

output

``````1 3 5
1 3 6
1 4 5
1 4 6
2 3 5
2 3 6
2 4 5
2 4 6
``````
-

EDIT: This solution doesn't work. Robert Gamble's is the correct solution.

I brainstormed a bit and came up with this solution:

(I know most of you won't know REBOL, but it's a fairly readable language.)

```REBOL []

sets: [[1 2 3] [4 5] [6]] ; Here's a set of sets
elems: 1
result: copy []
foreach set sets [elems: elems * (length? set)]
for n 1 elems 1 [
row: copy []
foreach set sets [
index: 1 + (mod (n - 1) length? set)
append row set/(index)
]
append/only result row
]

foreach row result [
print result
]
```

This code produces:

``````1 4 6
2 5 6
3 4 6
1 5 6
2 4 6
3 5 6
``````

(Upon first reading the numbers above, you may think there are duplicates. I did. But there aren't.)

Interestingly, this code uses almost the very same algorithm (1 + ((n - 1) % 9) that torpedoed my Digital Root question.

-
Unfortunately, this algorithm has the problem that it ONLY works on sets with different lengths. Back to the drawing board! – Gregory Higley Oct 19 '08 at 10:36