# Cartesian product of several vectors

similar questions have been asked before but I cant find an exact match to my question.

I have 4 vectors each of which hold between 200-500 4 digit integers. The exact number of elements in each vector varies but I could fix it to a specific value. I need to find all possible combinations of the elements in these 4 vectors.

eg:

v1[10, 30] v2[11, 45] v3[63, 56] v4[82, 98]

so I'd get something like this:

[10, 11, 63, 82]; [30, 11, 63, 82]; [10, 45, 63, 82]; [10, 45, 56, 82] etc..

Is there a common name for this algorithm so I can find some references to it online? Otherwise any tips on implementing this in C++ would be helpful. Performance isn't much of an issue as I only need to run the algorithm once. Is there anything built into the STL?

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Beware that there will be between 200^4 and 500^4 combinations. 500^4 is 62.5 billion and 200^4 is over 1 billion. –  Peter Alexander Mar 8 '10 at 22:37
Wait, if you just had 2 with v1={1,1,2} and v2={1,2}, do you want {1,2} to appear in the output twice? Also, do you consider {1,2} and {2,1} to be the same? –  Peter Alexander Mar 8 '10 at 22:39
The common name for this operation is the "Cartesian product". –  Jim Lewis Mar 8 '10 at 22:40
Good questions Poita. There are no duplicate entries within any one vector although there could be duplicate entries across vectors. I don't consider {1,2} and {2,1} to be the same but removing such occurrences would be advantageous. –  Stephen Spillage Mar 9 '10 at 14:06
Just out of curiosity, what do you need this for? –  Nordlöw Oct 29 '11 at 16:24

Not much of an algorithm...

``````for(vector<int>::const_iterator i1 = v1.begin(); i1 != v1.end(); ++i1)
for(vector<int>::const_iterator i2 = v2.begin(); i2 != v2.end(); ++i2)
for(vector<int>::const_iterator i3 = v3.begin(); i3 != v3.end(); ++i3)
for(vector<int>::const_iterator i4 = v4.begin(); i4 != v4.end(); ++i4)
cout << "[" << *i1 << "," << *i2 << "," << *i3 << "," << *i4 << "]" << endl;
``````
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+1 This is the logical way to do it. There might be a prettier way to represent but the process would be the same. –  Kirk Broadhurst Mar 8 '10 at 22:32
It's times like these you wish you had a meta-for loop that could loop through the for loops. –  Peter Alexander Mar 9 '10 at 0:02
+1 Thanks, this is working of course. I agree with Poita about the meta loop comment. –  Stephen Spillage Mar 9 '10 at 16:59