# Iterate set covered by cross-product of ranges in ruby

I figured this answer had been asked before, so I searched, but I couldn't find anything. Granted, there are a ton of Ruby Array questions, so it might be there, just buried.

In any case, I'm trying to reduce a cross-product of ranges, returning a sum of all elements of the cross-product that meet some set of conditions. To construct a trivial example, if I have an array like this:

``````[0..1,0..1,0..1]
``````

I'd like to iterate over this set:

``````[
[0,0,0],
[0,0,1],
[0,1,0],
[0,1,1],
[1,0,0],
[1,0,1],
[1,1,0],
[1,1,1]
]
``````

and return a sum based the condition "`return 1 if i[0] == 1 and i[2] == 0`" (which would give 2). In my contrived example, I could do it like this:

``````br = 0..1

br.reduce(0){|sumx, x|
sumx + br.reduce(0){|sumy, y|
sumy + br.reduce(0){|sumz, z|
sumz + (x == 1 and z == 0 ? 1 : 0)
}
}
}
``````

, but in the actual application, the set of ranges might be much larger, and nesting reduces that way would get quite ugly. Is there a better way?

-

There are two orthogonals tasks, try not to to mix them up so the code remains modular.

1. How to build a cartesian product of N arrays.

2. How to filter the product and count.

Use Array#product to get the cartesian product:

``````xs = [0..1, 0..1, 0..1].map(&:to_a)
xss = xs[0].product(*xs[1..-1]) # or xs.first.product(*xs.drop(1))
#=> [[0, 0, 0], [0, 0, 1], [0, 1, 0], ..., [1, 1, 0], [1, 1, 1]]
``````

And now do the filter and couting:

``````xss.count { |x, y, z| x == 1 && z == 0 }
#=> 2
``````

This is slightly uglier that it should, that's because we'd need the classmethod `Array::product` instead of the method `Array#product`. No problem, let's add it into our extensions module and finally write:

``````Array.product(0..1, 0..1, 0..1).count { |x, y, z| x == 1 && z == 0 }
#=> 2
``````
-
Thanks, this is exactly it. Building the Cartesian product was known to me, but thanks for the solution with fold on an array, I had forgotten blocks could split an array into arguments that way. – A. Wilson Feb 19 '11 at 16:22