Learning Haskell and Number Theory: The End of GCD

This is the fifth installment of my series “Learning Haskell and Number Theory”, in which I work through Gareth and Mary Jones’ text, Elementary Number Theory, and translate its ideas and algorithms into Haskell. In the last installment, I used the Haskell foldl function to convert a binary greatest common denominator into one that operates on a list. This time, I fix a glitch in that implementation, the dreaded “space leak,” and look at strict and lazy evaluation in Haskell.

The implementation of gcdmany from last time looked like this:

gcdmany :: forall a . Integral a => [ a ] -> a gcdmany = foldl gcd1 0

This is a correct implementation, but not a good one. Before we can understand why, though, we need a diversion through tail recursion. Everyone who’s done much functional programming knows the importance of tail recursion. It turns O(n) space into O(1) space. For example, this implementation of factorial:

fact 0 = 1 fact n = n * fact ( n - 1 )

uses O(n) space because it’s not tail recursive. The evaluation of fact (in a strict language; I’ll talk about Haskell’s quirks later) would look like this:

fact 6 6 * ( fact 5 ) 6 * ( 5 * ( fact 4 )) 6 * ( 5 * ( 4 * ( fact 3 ))) 6 * ( 5 * ( 4 * ( 3 * ( fact 2 )))) 6 * ( 5 * ( 4 * ( 3 * ( 2 * ( fact 1 ))))) 6 * ( 5 * ( 4 * ( 3 * ( 2 * ( 1 * ( fact 0 )))))) 6 * ( 5 * ( 4 * ( 3 * ( 2 * ( 1 * 1 ))))) 6 * ( 5 * ( 4 * ( 3 * ( 2 * 1 )))) 6 * ( 5 * ( 4 * ( 3 * 2 ))) 6 * ( 5 * ( 4 * 6 )) 6 * ( 5 * 24 ) 6 * 120 720

Each line represents the set of computations that needs to be stored in computer memory at any stage of execution. You can see that the memory needed grows with the value of n. (It doesn’t matter much for factorial, because merely storing the answer also uses space that’s O(n) in the size of the input. That’s beside the point.)

An alternative implementation is:

fact n = fact' 1 n where fact' a 0 = a fact' a n = fact' ( a * n ) ( n - 1 )

This one is made tail recursive, by following a very common technique of keeping an accumulator as an explicit parameter (in this case, a ) with an outer setup function. If you look back at the fourth installment, you’ll see that this is exactly what I did to turn the first implementation of gcdmany into the second one. I introduced an explicit accumulator parameter, and then used it to convert the routine into a tail recursive one with setup. In a strict language (like, say, the ML family of languages) that would be sufficient to turn the fact function into O(1) space.

The execution of this one (again, in a strict language) looks like this:

fact 6 fact' 1 6 fact' 6 5 fact' 30 4 fact' 120 3 fact' 360 2 fact' 720 1 fact' 720 0 720

This is much better! In our hypothetical strict language, we’ve solved the problem. In Haskell, though, it’s not quite good enough. Haskell, being a lazy language, won’t even do simple multiplication until we ask for the result. The execution, therefore, looks like this:

fact 6 fact' 1 6 fact' ( 1 * 6 ) 5 fact' ( 1 * 6 * 5 ) 4 fact' ( 1 * 6 * 5 * 4 ) 3 fact' ( 1 * 6 * 5 * 4 * 3 ) 2 fact' ( 1 * 6 * 5 * 4 * 3 * 2 ) 1 fact' ( 1 * 6 * 5 * 4 * 3 * 2 * 1 ) 0 1 * 6 * 5 * 4 * 3 * 2 * 1 6 * 5 * 4 * 3 * 2 * 1 30 * 4 * 3 * 2 * 1 120 * 3 * 2 * 1 360 * 2 * 1 720 * 1 720

And, oops! We’re back to using O(n) space again. This is the dreaded “space leak”.

Back to our gcdmany function. It, too, contains such a space leak. Instead of computing intermediate greatest common divisors as it applies arguments one by one, it actually accumulates the GCD operations for the whole list, before it starts to evaluate any of them.

We’d like to fix this. Haskell provides a way to do so: selective strict evaluation. In other words, we can tell Haskell that certain things must be evaluated strictly rather than put off for later. Doing this never changes the answer to a successful computation, but it can do two things:

Make a computation run faster, and with less memory. Make a computation fail or run forever, when it might otherwise have succeeded.

The first effect is what we want here. The second, though, is interesting as well. Consider the following code:

mylist = [ 1 , 2 , 3 , undefined ] main = print ( length mylist == 4 )

Running this program will print True . In a strict language, this program would fail because the fourth element of the list is undefined. (To elaborate more, you might design a language to avoid failing if the term is known to be undefined. But what if teh function that computes it goes into an infinite loop? In Haskell, it wouldn’t matter because we never use that value. In a strict language, it would matter quite a lot!)

In the case of gcdmany , though, I can verify that I am not doing anything that might cause the system to go into an infinite loop or fail. It is, therefore, safe, to replace it with a strict version.

The first way of doing this is standard Haskell 98. It looks like this:

gcdmany :: forall a . Integral a => [ a ] -> a gcdmany xs = gcdmany' 0 xs where gcdmany' p [] = p gcdmany' p ( x : xs ) = ( gcd1 p x ) ` seq ` gcdmany' ( gcd1 p x ) xs

The magic function seq makes this all work. If you read the description of seq in the standard library, it’s quite confusing for beginners to Haskell. What it really means is that is evaluates the first bit of code (so, as a side effect, if the first bit goes into an infinite loop or throws an exception, it’ll do that too), and then goes on with the second one as if the first one didn’t exist. However, evaluating the first one means that instead of it being work put off until later, the result is already known. That gets us back to the nice O(1) memory usage.

The second way of doing this does the same thing, but is shorter and only works in GHC with the -fallow-bang-patterns option.

gcdmany :: forall a . Integral a => [ a ] -> a gcdmany xs = gcdmany' 0 xs where gcdmany' ! p [] = p gcdmany' ! p ( x : xs ) = gcdmany' ( gcd1 p x ) xs

The ! in front of the argument p does the same thing as seq but is much nicer to read.

Both of these require that we write out gcdmany by hand, though. Before, we were able to make it a lot nicer using foldl . The third option fixes that. It’s not part of the standard Haskell 98 prelude, but it does exist in GHC.

gcdmany :: forall a . Integral a => [ a ] -> a gcdmany = foldl' gcd1 0

The foldl' function is just a strict version of foldl . It does exactly what we want. So with all those words, the solution was achieved by adding one small character. (Why, though? Because of the ability to use higher order functions to do functional abstraction!)

In general, one wants to use foldl' when folding over an operation that produces a distinct result, and foldr when folding with a data constructor or an operation that builds more complex data structures. In the first case, you avoid space leaks. In the second case, you can use lazy evaluation to only build a piece at a time of the data structure you’re operating on, and thus save even more memory through lazy evaluation.

That’s all for now. Next time, I’ll look at some cool connections between Euclid’s GCD algorithm and the Fibonacci numbers, and then move on to chapter 2.