# Learning F# - printing prime numbers

Yesterday I started looking at F# during some spare time. I thought I would start with the standard problem of printing out all the prime numbers up to 100. Heres what I came up with...

``````#light
open System

let mutable divisable = false
let mutable j = 2

for i = 2 to 100 do
j <- 2
while j < i do
if i % j = 0 then divisable <- true
j <- j + 1

if divisable = false then Console.WriteLine(i)
divisable <- false
``````

The thing is I feel like I have approached this from a C/C# perspective and not embraced the true functional language aspect.

I was wondering what other people could come up with - and whether anyone has any tips/pointers/suggestions. I feel good F# content is hard to come by on the web at the moment, and the last functional language I touched was HOPE about 5 years ago in university.

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As a side note, it's very much out of the spirit of F# to use `Console.WriteLine`. I would suggest using `printfn "%i" i` instead. – Noldorin Jul 8 '09 at 11:42
printf is more typesafe and can infer some types. – Brian Jul 8 '09 at 14:17
Try rewriting it using a fold. – gradbot Jul 8 '09 at 16:07

Here is a simple implementation of the Sieve of Eratosthenes in F#:

``````let rec sieve = function
| (p::xs) -> p :: sieve [ for x in xs do if x % p > 0 then yield x ]
| []      -> []

let primes = sieve [2..50]
printfn "%A" primes  // [2; 3; 5; 7; 11; 13; 17; 19; 23; 29; 31; 37; 41; 43; 47]
``````

This implementation won't work for very large lists but it illustrates the elegance of a functional solution.

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Nice, but I think that "List.filter (fun x -> x % p > 0) xs" would be more idiomatic than the explicit list comprehension. – kvb Jul 10 '09 at 22:10
Keep in mind that that's not a real sieve. That algorithm is very slow (bad asymptotic complexity compared to the real sieve). – Jules Jul 21 '09 at 20:52
Let me explain the difference. The Sieve of Eratosthenes only marks off multiples of the current prime number (`p` in your code). So this is # of multiples of the current prime number steps. Your code however performs a divisibility test for all remaining numbers, not just the multiples. As the numbers get large there are far more non-multiples than multiples, so your algorithm does a lot of extra work compared to the real sieve. – Jules Jul 21 '09 at 20:59
The idea comes from this awesome paper: cs.hmc.edu/~oneill/papers/Sieve-JFP.pdf – Jules Jul 21 '09 at 21:00
Thanks for the info, very interesting! This code was just a port of the Haskell example found on the above link. – Ray Vernagus Jul 21 '09 at 23:56

Using a Sieve function like Eratosthenes is a good way to go. Functional languages work really well with lists, so I would start with that in mind for struture.

On another note, functional languages work well constructed out of functions (heh). For a functional language "feel" I would build a Sieve function and then call it to print out the primes. You could even split it up--one function builds the list and does all the work and one goes through and does all the printing, neatly separating functionality.

There's a couple of interesting versions here. And there are well known implementations in other similar languages. Here's one in OCAML that beats one in C.

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+1 for the Sieve article – user110714 Jul 8 '09 at 12:36

You definitely do not want to learn from this example, but I wrote an F# implementation of a NewSqueak sieve based on message passing:

``````type 'a seqMsg =
| Die

type primes() =
let counter(init) =
MailboxProcessor.Start(fun inbox ->
let rec loop n =
async { let! msg = inbox.Receive()
match msg with
| Die -> return ()
return! loop(n + 1) }
loop init)

let filter(c : MailboxProcessor<'a seqMsg>, pred) =
MailboxProcessor.Start(fun inbox ->
let rec loop() =
async {
match msg with
| Die ->
c.Post(Die)
return()
let rec filter' n =
if pred n then async { return n }
else
return! filter' m }
let! filteredItem = filter' testItem
return! loop()
}
loop()
)

let processor = MailboxProcessor.Start(fun inbox ->
let rec loop (oldFilter : MailboxProcessor<int seqMsg>) prime =
async {
match msg with
| Die ->
oldFilter.Post(Die)
return()
let newFilter = filter(oldFilter, (fun x -> x % prime <> 0))
return! loop newFilter newPrime
}
loop (counter(3)) 2)

interface System.IDisposable with
member this.Dispose() = processor.Post(Die)

static member upto max =
[ use p = new primes()
let lastPrime = ref (p.Next())
while !lastPrime <= max do
yield !lastPrime
lastPrime := p.Next() ]
``````

Does it work?

``````> let p = new primes();;

val p : primes

> p.Next();;
val it : int = 2
> p.Next();;
val it : int = 3
> p.Next();;
val it : int = 5
> p.Next();;
val it : int = 7
> p.Next();;
val it : int = 11
> p.Next();;
val it : int = 13
> p.Next();;
val it : int = 17
> primes.upto 100;;
val it : int list
= [2; 3; 5; 7; 11; 13; 17; 19; 23; 29; 31; 37; 41; 43; 47; 53; 59; 61; 67; 71;
73; 79; 83; 89; 97]
``````

Sweet! :)

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Easy bit of code there for someone who has been doing it a day :). Probably pass on your example, but thanks lol... – user110714 Jul 8 '09 at 17:49

Simple but inefficient suggestion:

• Create a function to test whether a single number is prime
• Create a list for numbers from 2 to 100
• Filter the list by the function
• Compose the result with another function to print out the results

To make this efficient you really want to test for a number being prime by checking whether or not it's divisible by any lower primes, which will require memoisation. Probably best to wait until you've got the simple version working first :)

Let me know if that's not enough of a hint and I'll come up with a full example - thought it may not be until tonight...

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I would implement that using the Sieve of Eratosthenes ( en.wikipedia.org/wiki/Sieve_of_Eratosthenes ). I can imagine that to be quite usable for a functional approach (though I don't know anything at all about F#) – balpha Jul 8 '09 at 11:25

Here is my old post at HubFS about using recursive seq's to implement prime number generator.

For case you want fast implementation, there is nice OCaml code by Markus Mottl

P.S. if you want to iterate prime number up to 10^20 you really want to port primegen by D. J. Bernstein to F#/OCaml :)

-

While solving the same problem, I have implemented Sieve of Atkins in F#. It is one of the most efficient modern algorithms.

``````// Create sieve
let initSieve topCandidate =
let result = Array.zeroCreate<bool> (topCandidate + 1)
Array.set result 2 true
Array.set result 3 true
Array.set result 5 true
result
// Remove squares of primes
let removeSquares sieve topCandidate =
let squares =
seq { 7 .. topCandidate}
|> Seq.filter (fun n -> Array.get sieve n)
|> Seq.map (fun n -> n * n)
|> Seq.takeWhile (fun n -> n <= topCandidate)
for n2 in squares do
n2
|> Seq.unfold (fun state -> Some(state, state + n2))
|> Seq.takeWhile (fun x -> x <= topCandidate)
|> Seq.iter (fun x -> Array.set sieve x false)
sieve

// Pick the primes and return as an Array
let pickPrimes sieve =
sieve
|> Array.mapi (fun i t -> if t then Some i else None)
|> Array.choose (fun t -> t)
// Flip solutions of the first equation
let doFirst sieve topCandidate =
let set1 = Set.ofList [1; 13; 17; 29; 37; 41; 49; 53]
let mutable x = 1
let mutable y = 1
let mutable go = true
let mutable x2 = 4 * x * x
while go do
let n = x2 + y*y
if n <= topCandidate then
if Set.contains (n % 60) set1 then
Array.get sieve n |> not |> Array.set sieve n

y <- y + 2
else
y <- 1
x <- x + 1
x2 <- 4 * x * x
if topCandidate < x2 + 1 then
go <- false
// Flip solutions of the second equation
let doSecond sieve topCandidate =
let set2 = Set.ofList [7; 19; 31; 43]
let mutable x = 1
let mutable y = 2
let mutable go = true
let mutable x2 = 3 * x * x
while go do
let n = x2 + y*y
if n <= topCandidate then
if Set.contains (n % 60) set2 then
Array.get sieve n |> not |> Array.set sieve n

y <- y + 2
else
y <- 2
x <- x + 2
x2 <- 3 * x * x
if topCandidate < x2 + 4 then
go <- false
// Flip solutions of the third equation
let doThird sieve topCandidate =
let set3 = Set.ofList [11; 23; 47; 59]
let mutable x = 2
let mutable y = x - 1
let mutable go = true
let mutable x2 = 3 * x * x
while go do
let n = x2 - y*y
if n <= topCandidate && 0 < y then
if Set.contains (n % 60) set3 then
Array.get sieve n |> not |> Array.set sieve n

y <- y - 2
else
x <- x + 1
y <- x - 1
x2 <- 3 * x * x
if topCandidate < x2 - y*y then
go <- false

// Sieve of Atkin
let ListAtkin (topCandidate : int) =
let sieve = initSieve topCandidate

[async { doFirst sieve topCandidate }
async { doSecond sieve topCandidate }
async { doThird sieve topCandidate }]
|> Async.Parallel
|> Async.RunSynchronously
|> ignore

removeSquares sieve topCandidate |> pickPrimes
``````

I know some don't recommend to use Parallel Async, but it did increase the speed ~20% on my 2 core (4 with hyperthreading) i5. Which is about the same increase I got using TPL.

I have tried rewriting it in functional way, getting read of loops and mutable variables, but performance degraded 3-4 times, so decided to keep this version.

-

Here are my two cents:

``````let rec primes =
seq {
yield 2
yield! (Seq.unfold (fun i -> Some(i, i + 2)) 3)
|> Seq.filter (fun p ->
primes
|> Seq.takeWhile (fun i -> i * i <= p)
|> Seq.forall (fun i -> p % i <> 0))
}
for i in primes do
printf "%d " i
``````

Or maybe this clearer version of the same thing as `isprime` is defined as a separate function:

``````let rec isprime x =
primes
|> Seq.takeWhile (fun i -> i*i <= x)
|> Seq.forall (fun i -> x%i <> 0)

and primes =
seq {
yield 2
yield! (Seq.unfold (fun i -> Some(i,i+2)) 3)
|> Seq.filter isprime
}
``````
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