# Project Euler 3 - Haskell

I'm working my way through the Project Euler problems in Haskell. I have got a solution for Problem 3 below, I have tested it on small numbers and it works, however due to the brute force implementation by deriving all the primes numbers first it is exponentially slow for larger numbers.

``````-- Project Euler 3

module Main
where

import System.IO
import Data.List

main = do
hSetBuffering stdin LineBuffering
putStrLn "This program returns the prime factors of a given integer"
putStrLn "Please enter a number"
nums <- getPrimes
putStrLn "The prime factors are: "
print (sort nums)

getPrimes = do
userNum <- getLine
let n = read userNum :: Int
let xs = [2..n]
return \$ getFactors n (primeGen xs)

--primeGen :: (Integral a) => [a] -> [a]
primeGen [] = []
primeGen (x:xs) =
if x >= 2
then x:primeGen (filter (\n->n`mod` x/=0) xs)
else 1:[2]

--getFactors
getFactors :: (Integral a) => a -> [a] -> [a]
getFactors n xs = [ x | x <- xs, n `mod` x == 0]
``````

I have looked at the solution here and can see how it is optimised by the first guard in `factor`. What I dont understand is this:

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

Specifically the first argument of `filter`.

``````((==1) . length . primeFactors)
``````

As primeFactors is itself a function I don't understand how it is used in this context. Could somebody explain what is happening here please?

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Are you just having difficulty understanding the expression `primes = 2 : filter ((==1) . length . primeFactors) [3, 5 ..]`? – bheklilr Aug 15 '14 at 18:37
no, i understand what the expression itself does, its the first argument of filter that I don't understand ((==1) . length . primeFactors) – Dave0504 Aug 15 '14 at 19:01

## 4 Answers

If you were to open `ghci` on the command line and type

``````Prelude> :t filter
``````

You would get an output of

``````filter :: (a -> Bool) -> [a] -> [a]
``````

What this means is that `filter` takes 2 arguments.

• `(a -> Bool)` is a function that takes a single input, and returns a `Bool`.
• `[a]` is a list of any type, as longs as it is the same type from the first argument.

`filter` will loop over every element in the list of its second argument, and apply it to the function that is its first argument. If the first argument returns `True`, it is added to the resulting list.

Again, in `ghci`, if you were to type

``````Prelude> :t (((==1) . length . primeFactors))
``````

You should get

``````(((==1) . length . primeFactors)) :: a -> Bool
``````

`(==1)` is a partially applied function.

``````Prelude> :t (==)
(==) :: Eq a => a -> a -> Bool
Prelude> :t (==1)
(==1) :: (Eq a, Num a) => a -> Bool
``````

It only needs to take a single argument instead of two.

Meaning that together, it will take a single argument, and return a Boolean.

The way it works is as follows.

• `primeFactors` will take a single argument, and calculate the results, which is a `[Int]`.
• `length` will take this list, and calculate the length of the list, and return an `Int`
• `(==1)` will look to see if the values returned by `length` is equal to `1`.

If the length of the list is `1`, that means it is a prime number.

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got it. What was throwing me off is that I was expecting an argument to primeFactors within the brackets. Then after I remebered that filter cycles through [3,5..]. The recursive call returns a list of factors, to which the partial fucntion is applied, consing only lists with a length of 1 , i.e prime numbers. Hope that makes sense to everybody, I understand it now. Thanks. – Dave0504 Aug 15 '14 at 19:44
Glad I could help you understand. – Justin Wood Aug 15 '14 at 19:45
+1 nicely explained. – Daniel Kaplan Aug 15 '14 at 19:56

`(.) :: (b -> c) -> (a -> b) -> a -> c` is the composition function, so

``````f . g = \x -> f (g x)
``````

We can chain more than two functions together with this operator

``````f . g . h  ===  \x -> f (g (h x))
``````

This is what is happening in the expression `((==1) . length . primeFactors)`.

-

The expression

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

is filtering the list `[3, 5..]` using the function `(==1) . length . primeFactors`. This notation is usually called point free, not because it doesn't have `.` points, but because it doesn't have any explicit arguments (called "points" in some mathematical contexts).

The `.` is actually a function, and in particular it performs function composition. If you have two functions `f` and `g`, then `f . g = \x -> f (g x)`, that's all there is to it! The precedence of this operator lets you chain together many functions quite smoothly, so if you have `f . g . h`, this is the same as `\x -> f (g (h x))`. When you have many functions to chain together, the composition operator is very useful.

So in this case, you have the functions `(==1)`, `length`, and `primeFactors` being compose together. `(==1)` is a function through what is called operator sections, meaning that you provide an argument to one side of an operator, and it results in a function that takes one argument and applies it to the other side. Other examples and their equivalent lambda forms are

``````(+1)           =>  \x -> x + 1
(==1)          =>  \x -> x == 1
(++"world")    =>  \x -> x ++ "world"
("hello"++)    =>  \x -> "hello" ++ x
``````

If you wanted, you could re-write this expression using a lambda:

``````(==1) . length . primeFactors => (\x0 -> x0 == 1) . length . primeFactors
=> (\x1 -> (\x0 -> x0 == 1) (length (primeFactors x1)))
``````

Or a bit cleaner using the `\$` operator:

``````(\x1 -> (\x0 -> x0 == 1) \$ length \$ primeFactors x1)
``````

But this is still a lot more "wordy" than simply

``````(==1) . length . primeFactors
``````

One thing to keep in mind is the type signature for `.`:

``````(.) :: (b -> c) -> (a -> b) -> a -> c
``````

But I think it looks better with some extra parentheses:

``````(.) :: (b -> c) -> (a -> b) -> (a -> c)
``````

This makes it more clear that this function takes two other functions and returns a third one. Pay close attention the the order of the type variables in this function. The first argument to `.` is a function `(b -> c)`, and the second is a function `(a -> b)`. You can think of it as going right to left, rather than the left to right behavior that we're used to in most OOP languages (something like `myObj.someProperty.getSomeList().length()`). We can get this functionality by defining a new operator that has the reverse order of arguments. If we use the F# convention, our operator is called `|>`:

``````(|>) :: (a -> b) -> (b -> c) -> (a -> c)
(|>) = flip (.)
``````

Then we could have written this as

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

And you can think of `|>` as an arrow "feeding" the result of one function into the next.

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Thanks for the answer, I've only just seen it after accepting one of the others above. Both made it very clear and both very helpful so +1. – Dave0504 Aug 15 '14 at 19:50
@Dave0504 whichever one makes it most clear is the one to accept, I'm just glad I could help :) – bheklilr Aug 15 '14 at 20:21
in F#, `(|>) x f = f x`. it is left-associative. `flip (.)` in F# is called `( >> )`. – Will Ness Aug 16 '14 at 20:26

This simply means, keep only the odd numbers that have only one prime factor.

In other pseodo-code: `filter(x -> length(primeFactors(x)) == 1) for any x in [3,5,..]`

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