# Haskell, understanding a solution for euler #3

I've recently taken to learning me a haskell and have been having a pretty good time. I've been working through some Project Euler problems to get a grip of the syntax and have been reviewing the solutions posted here http://www.haskell.org/haskellwiki/Euler_problems/1_to_10 as a learning tool. Though I have found myself unable to wrap my head around the solution posted for problem #3:

``````-- Find the largest prime factor of 317584931803.

primes = 2 : filter ((==1) . length . primeFactors) [3,5..]

primeFactors n = factor n primes
where
factor n (p:ps)
| p*p > n        = [n]
| n `mod` p == 0 = p : factor (n `div` p) (p:ps)
| otherwise      = factor n ps

problem_3 = last (primeFactors 317584931803)
``````

I can't figure out for the life of me how it works. `primes` and `primeFactors` seem to be calling each other to build their own lists and trying to follow it pickles my brain. Any one know a good blog post about this solution or want to write an explanation about it here?

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Have you seen the recursive definition of the fibonacci numbers? `fibs = 1 : 1 : zipWith (+) fibs (tail fibs)`? Do you understand that? That's a good place to start with recursively defined data. –  rampion Feb 7 '12 at 18:58

This is indeed puzzling at first sight. But it's no magic if you don't think "imperatively". Haskell definitions are just that: the tell you what something is, not what lower level operations the computer is supposed to execute.

Hence, the list of primes is the list that contains 2 and all odd natural numbers greater 2 that have only a single prime factor (namely itself).

The list of prime factors for some integer n, on the other hand, is the list of prime numbers that divide n.

Make sure you understand those definitions, before reading on.

As abstract Haskell may be, it is still a programming language, so we need to give some advice from time to time how to compute something. Specifically, in the example above, we do not test all prime numbers to find prime factors of `n`, because it is enough to test `2..k` where `k*k <= n`. This also makes sure that we only use that part of prime which is already computed.

At the start, `primes` looks like this:

``````2 : filter ((==1) . length . primeFactors) [3,5..]
``````

If we demand the next element after 2, we force evaluation of the expression right of the colon. This, in turn, causes filter to evaluate the predicate for 3. Then it goes:

``````primeFactors 3
factor 3 (2 : ...)
2*2 > 3
[3]
[3]
``````

Hence, `primeFactors 3` is `[3]` and we didn't need to look beyond 2 in primes. (This is the key point why this works!) Clearly, the length of `[3]` is 1 and

``````2 : filter ((==1) . length . primeFactors) [3,5..]
``````

evaluates to

``````2 : 3 : filter ((==1) . length . primeFactors) [5, 7..]
``````

You may now want to reduce `primeFactors 5` for yourself.

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Wow, great. Haskell is too much fun. I'm just starting to fully understand what it means to be lazy. –  greggreg Feb 8 '12 at 0:10
@greg - Watch out! Lazyness is highly addictive. :) –  Ingo Feb 8 '12 at 1:30

It's laziness in action :) The list of primes starts nonempty,

``````primes = 2 : don't_know_yet_let's_see
``````

and `primeFactors` calculates the prime factors of a number using the list of primes. But to find the prime factors of any number 'n', we only need to know the primes up to `sqrt(n)`. So the tail of `primes`,

``````filter ((== 1) . length . primeFactors) [3, 5 .. ]
``````

can use what's already known of `primes`. To check `3`, we

``````factor 3 (2:don't_kow_yet_let's_see)
| 2*2 > 3 = [3]
| don't_care_above_was_true
``````

And if we start with any `n`, say `n = 35` to keep it short,

``````factor 35 (2:??)
| 2*2 > 35  -- False, next clause
| 35 `mod` 2 == 0 -- False, next clause
| otherwise = factor 35 ??
``````

Now we need to find out what `??` is. We saw above that the `filter`ing lets 3 pass, so it's `3:???`, hence

``````factor 35 (3:???)
| -- first two guards are False
| otherwise = factor 35 ???
``````

Now what's `???`? Well, `filter ((== 1) . length . primeFactors) [5, 7 .. ]`, so let's see whether `5` passes the filter

``````factor 5 (2:3:???)  -- note, we already know the first two elements of primes
| 2*2 > 5 -- False
| 5 `mod` 2 == 0 -- False
| otherwise = factor 5 (3:???)
| 3*3 > 5 = [5]
``````

So `5` passes and we know the first three elements of `primes`. In the factorisation of 35, we continue

``````factor 35 (5:????)
| 5*5 > 35 -- False
| 35 `mod` 5 == 0 = 5 : factor (35 `div` 5) (5:????)
factor 7 (5:????)
| 5*5 > 7 = [7]
``````

So, when factorising a number, the list of primes is built up as far as needed, each new prime will be determined when it's demanded, and at that time, all the primes needed to determine the next prime have already been found.

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Awesome answer. Helped me out a ton. I really appreciate your time and I think I'm finally coming to grips with the laziness. –  greggreg Feb 8 '12 at 0:11