# Why is this F# code slower than the C# equivalent?

I'm tackling the Project Euler problems again (did the 23 first ones before when I was learning C#) and I'm quite baffled at the subpar performance of my solution to problem 5.

2520 is the smallest number that can be divided by each of the numbers from 1 to 10 without any remainder.

What is the smallest positive number that is evenly divisible by all of the numbers from 1 to 20?

Now my incredibly primitive brute-force solution of C# tugs through this problem in roughly 25 seconds.

``````var numbers = Enumerable.Range(1, 20);
int start = 1;
int result;
while (true)
{
if (numbers.All(n => start % n == 0))
{
result = start;
break;
}
start++;
}
``````

Now my F# solution uses brute forcing as well but at least it does a bit more discrimination and such so that it "should" in my mind run faster but it clocks out at ~45 secs so it's nearly twice as slow as the C# one.

``````let p5BruteForce =
let divisors = List.toSeq ([3..20] |> List.rev)
let isDivOneToTwenty n =
let dividesBy =
divisors |> Seq.takeWhile(fun x -> n % x = 0)
Seq.length dividesBy = Seq.length divisors

let findNum n =
let rec loop n =
match isDivOneToTwenty n with
| true -> n
| false -> loop (n + 2)
loop n
findNum 2520
``````

P.S - I know that my solution could be better, in this case I am simply wondering how it could be that a better brute-force solution can be so much slower than a primitive one.

• Note that the solution has to be a multiple of 2520 as well. Your increment can therefore be 2520 and you will be testing far fewer numbers. Even with a simple brute force solution it will go quickly. Also, you wouldn't need to test for divisibility of 1 to 10. Commented Nov 11, 2014 at 22:34
• Not an exact duplicate of C# / F# Performance comparison. But it explains why F# is slower than C# Commented Nov 11, 2014 at 22:51
• @L.B Really now? You are going to come here and make a rude remark about the performance? I never claimed that it was a particularly good solution. Not everyone is born with great coding talents, maybe that's why I'm trying to learn? Commented Nov 12, 2014 at 6:22

You can use `List.forall` instead of converting to a seq and then doing `Seq.length`:

``````let divisors = [3..20] |> List.rev
let isDivOneToTwenty n = divisors |> List.forall (fun d -> n % d = 0)
``````

`Seq.length` will need to traverse the entire sequence to determine the number of elements, while `forall` can return as soon as an element fails the predicate.

you can also write `findNum` as:

``````let rec findNum n = if isDivOneToTwenty n then n else findNum (n + 2)
``````
• This is it. Actually, `List.forall` makes a huge difference over `Seq.forall` in my tests. Like 100s vs 10s. Commented Nov 11, 2014 at 22:22
• @mikez - Yes `takeWhile` will break early, that count is being compared to the length of the entire divisor sequence each time, so it's traversing it between one and two times on each call.
– Lee
Commented Nov 11, 2014 at 22:38
• Yea I realized that right after I wrote my comment, so I deleted it. Commented Nov 11, 2014 at 22:50
• +1. This simple change reduced running time to about 2,5seconds on my machine. This was exactly what I was looking for. Commented Nov 12, 2014 at 6:30

Even a more direct translation such as

``````let numbers = { 1..20 }
let rec loop start =
if numbers |> Seq.forall (fun n -> start % n = 0)
then start
else loop (start + 1)
loop 1
``````

takes a minute and a half (your C# version takes 25 seconds on my machine too). The numeric sequence seems to be the culprit as changing it to an array (`[| 1..20 |]`) and using `Array.forall` drops it to 8 secs. The C# version using an array takes 20 secs (using my own array-specialized `ForAll` method instead of `Enumerable.All` takes 17 secs).

EDIT: After seeing Lee's answer, I tried `List.forall` and it's even faster than array (~5 secs).

well it's gotta be this bit

``````            divisors |> Seq.takeWhile(fun x -> n % x = 0)
Seq.length dividesBy = Seq.length divisors
``````

I think you could rewrite this as a simpler recursive function which would be more similar to your original c# implementation.