Before I explain that final line of code, let me summarise the process for solving this type of problem. There are two key questions:
- What's the simplest possible case?
- Can I express the solution in terms of the next simplest solution?
OK, so we want to write a function that calculates the product of all the numbers in a list.
Re question 1: The simplest possible case is that there aren't any numbers. If this is the first time I've encountered the problem, it might not be obvious to me what the answer should be in this case, but let's put that aside for the moment.
Re question 2: If I have a list [n0, n1, n2,.. nk], and somehow I know the product (let's call it p) of all the numbers except the first one, then the answer is the first element times that product, or n0 * p.
The first line of code will take care of the trivial case:
productIt  = 1
That says that the function productIt for the empty list argument, , has the value 1. (I explained above why the answer has to be 1.) That takes care of the trivial case. Now we need to define productIt in the case where the list isn't empty. Let's look at that last line of code:
productIt (x:xs) = ... something?
The left-hand side uses pattern matching. The pattern (x:xs) will match a list with one or more elements. When that expression is matched, it binds x to the first element, and xs to the rest of the list. So not only are we matching the pattern, we're getting x and xs defined as a bonus. That's what makes pattern matching really powerful in Haskell.
So if the first element of the list is x, and the rest of the list (all but the first element) is xs, then what is the answer? We've already decided that it's the first element (x) times the product of all the remaining elements (xs). So...
productIt (x:xs) = x * productIt xs
Also, yjerem gave you an excellent explanation of how Haskell would evaluate it.