# Creating nested loops of arbitrary depth in ruby

I want to write a ruby program that steps over space in an arbitrary number of dimensions.

In 3 dimensions what I'm doing looks like this:

``````x_range = (-1..1)
y_range = (-1..1)
z_range = (-1..1)

step_size = 0.01

x_range.step(step_size) do |x|
y_range.step(step_size) do |y|
z_range.step(step_size) do |z|

# do something with the point x,y,z

end
end
end
``````

I want to do the same for `n` dimensions

Recursion could solve this kind of problem easily and perfectly. Code below fits any number of dimensions, and also various length of ranges.

``````def traversal(ranges, step_size, conjunction = [], &blk)
ranges[0].step(step_size) do |x|
conjunction.push(x)
if ranges.size > 1
traversal(ranges[1..-1], step_size, conjunction, &blk)
else
blk.call(conjunction) if block_given?
conjunction.pop
end
end
conjunction.pop
end
``````

Run: (dimension = 4, length = 3, 3, 4, 2)

``````x = (1..3)
y = (4..6)
z = (7..10)
w = (100..101)
test_data = [x, y, z, w]
step_size = 1

traversal(test_data, step_size) do |x|
puts "Point: #{x.join('-')}"
end
``````

Output: (72 points in total, which is 3 * 3 * 4 * 2)

``````Point: 1-4-7-100
Point: 1-4-7-101
Point: 1-4-8-100
Point: 1-4-8-101
Point: 1-4-9-100
Point: 1-4-9-101
Point: 1-4-10-100
Point: 1-4-10-101
Point: 1-5-7-100
Point: 1-5-7-101
Point: 1-5-8-100
Point: 1-5-8-101
Point: 1-5-9-100
Point: 1-5-9-101
Point: 1-5-10-100
Point: 1-5-10-101
Point: 1-6-7-100
Point: 1-6-7-101
Point: 1-6-8-100
Point: 1-6-8-101
Point: 1-6-9-100
Point: 1-6-9-101
Point: 1-6-10-100
Point: 1-6-10-101
Point: 2-4-7-100
Point: 2-4-7-101
Point: 2-4-8-100
Point: 2-4-8-101
Point: 2-4-9-100
Point: 2-4-9-101
Point: 2-4-10-100
Point: 2-4-10-101
Point: 2-5-7-100
Point: 2-5-7-101
Point: 2-5-8-100
Point: 2-5-8-101
Point: 2-5-9-100
Point: 2-5-9-101
Point: 2-5-10-100
Point: 2-5-10-101
Point: 2-6-7-100
Point: 2-6-7-101
Point: 2-6-8-100
Point: 2-6-8-101
Point: 2-6-9-100
Point: 2-6-9-101
Point: 2-6-10-100
Point: 2-6-10-101
Point: 3-4-7-100
Point: 3-4-7-101
Point: 3-4-8-100
Point: 3-4-8-101
Point: 3-4-9-100
Point: 3-4-9-101
Point: 3-4-10-100
Point: 3-4-10-101
Point: 3-5-7-100
Point: 3-5-7-101
Point: 3-5-8-100
Point: 3-5-8-101
Point: 3-5-9-100
Point: 3-5-9-101
Point: 3-5-10-100
Point: 3-5-10-101
Point: 3-6-7-100
Point: 3-6-7-101
Point: 3-6-8-100
Point: 3-6-8-101
Point: 3-6-9-100
Point: 3-6-9-101
Point: 3-6-10-100
Point: 3-6-10-101
``````

This is the first thing that comes to mind for me:

``````def enumerate(nDimens, bottom, top, step_size)
bottom = (bottom / step_size).to_i
top    = (top    / step_size).to_i

range = (bottom..top).to_a.map{ |x| x * step_size }
return range.repeated_permutation(nDimens)
end

stepper = enumerate(4, -1, 1, 0.1)

loop do
puts "#{stepper.next()}"
end
``````

This produces:

``````[-1.0, -1.0, -1.0, -1.0]
[-1.0, -1.0, -1.0, -0.9]
[-1.0, -1.0, -1.0, -0.8]
# Lots more...
[1.0, 1.0, 1.0, 0.8]
[1.0, 1.0, 1.0, 0.9]
[1.0, 1.0, 1.0, 1.0]
``````

This assumes all dimensions have the same range, but it'd be easy to adjust if for some reason that doesn't hold.

If ranges are not too big you can do something like this:

``````n = 5 # 5 dimentions
x = (-1..1).to_a
x.product(*[x]*(n-1)).each {|i| p i}
``````

Result:

``````[-1, -1, -1, -1, -1]
[-1, -1, -1, -1, 0]
[-1, -1, -1, -1, 1]
[-1, -1, -1, 0, -1]
[-1, -1, -1, 0, 0]
[-1, -1, -1, 0, 1]
[-1, -1, -1, 1, -1]
[-1, -1, -1, 1, 0]
[-1, -1, -1, 1, 1]
[-1, -1, 0, -1, -1]
[-1, -1, 0, -1, 0]
# skipped
``````

This is what you could do... here is an example iterator.

``````#next(l[dim] array of lower ranges ,h[dim] = upper ranges, step[dim], dim = dimensions -1, curr[dim] = current state in dim dimensions )
def nextx(l ,h, step, dim, curr)
x = dim
update= false
while (update==false)
if curr[x] == h[x]
if x > 0
x = x-1
else
exit
end

else
curr[x]= curr[x]+step[x]
while (x < dim)
x = x+1
curr[x] = l[x]
end
update = true
end
end
return curr
end

l = [0,0,0]
h = [3,3,3]
step = [1,1,1]
currx = [0,0,2]

i = 0
while i < 70
currx = nextx(l, h, step, 2, currx)
puts currx.inspect
i=i+1
end
``````

This is typically encountered in algorithms that explore a search space. The `do` loops are creating a product space from the one dimensional ranges.

First pack as many ranges are needed into an array e.g.

``````search_space_1Ds = [x_range.step(step_size).to_a, y_range.step(step_size).to_a, z_range.step(step_size).to_a]
``````

then the following will work with an arbitrary number of dimensions.

``````search_space = search_spaces_1Ds.shift.product(*search_space_1Ds)
search_space.map do |vec|
# calculate something with vec
end
``````

This implementation is not only concise, it makes it very clear what your algorithm is doing; enumerating through a search space that is created as the product space of the one dimensional search spaces.

• `product` is an undefined method for a Range – steenslag Dec 6 '18 at 23:37
• Thanks, steenslag, I have corrected accordingly – Obromios Dec 7 '18 at 0:08