Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I am currently experimenting with F#. The articles found on the internet are helpful, but as a C# programmer, I sometimes run into situations where I thought my solution would help, but it did not or just partially helped.

So my lack of knowledge of F# (and most likely, how the compiler works) is probably the reason why I am totally flabbergasted sometimes.

For example, I wrote a C# program to determine perfect numbers. It uses the known form of Euclids proof, that a perfect number can be formed from a Mersenne Prime 2p−1(2p−1) (where 2p-1 is a prime, and p is denoted as the power of).

Since the help of F# states that '**' can be used to calculate a power, but uses floating points, I tried to create a simple function with a bitshift operator (<<<) (note that I've edit this code for pointing out the need):

 let PowBitShift (y:int32) = 1 <<< y;;

However, when running a test, and looking for performance improvements, I also tried a form which I remember from using Miranda (a functional programming language also), which uses recursion and a pattern matcher to calculate the power. The main benefit is that I can use the variable y as a 64-bit Integer, which is not possible with the standard bitshift operator.

    let rec Pow (x : int64) (y : int64) = 
    match y with
        | 0L -> 1L
        | y -> x * Pow x (y - 1L);;

It turns out that this function is actually faster, but I cannot (yet) understand the reason why. Perhaps it is a less intellectual question, but I am still curious.

The seconds question then would be, that when calculating perfect numbers, you run into the fact that the int64 cannot display the big numbers crossing after finding the 9th perfectnumber (which is formed from the power of 31). I am trying to find out if you can use the BigInteger object (or bigint type) then, but here my knowledge of F# is blocking me a bit. Is it possible to create a powerfunction which accepts both arguments to be bigints?

I currently have this:

let rec PowBigInt (x : bigint) (y : bigint) = 
    match y with
        | bigint.Zero -> 1I
        | y -> x * Pow x (y - 1I);;

But it throws an error that bigint.Zero is not defined. So I am doing something wrong there as well. 0I is not accepted as a replacement, since it gives this error:

Non-primitive numeric literal constants cannot be used in pattern matches because they    
can be mapped to multiple different types through the use of a NumericLiteral module.  
Consider using replacing with a variable, and use 'when <variable> = <constant>' at the 
end of the match clause.    

But a pattern matcher cannot use a 'when' statement. Is there another solution to do this?

Thanks in advance, and please forgive my long post. I am only trying to express my 'challenges' as clear as I can.

share|improve this question
Nice first question, welcome to Stack Overflow! – Benjol Dec 5 '11 at 5:48
up vote 8 down vote accepted

I failed to understand why you need y to be an int64 or a bigint. According to this link, the biggest known Mersenne number is the one with p = 43112609, where p is indeed inside the range of int.

Having y as an integer, you can use the standard operator pown : ^T -> int -> ^T instead because:

let Pow (x : int64) y = pown x y
let PowBigInt (x: bigint) y = pown x y

Regarding your question of pattern matching bigint, the error message indicates quite clearly that you can use pattern matching via when guards:

let rec PowBigInt x y = 
    match y with
    | _ when y = 0I -> 1I
    | _ -> x * PowBigInt x (y - 1I)
share|improve this answer
Ah, that is quite clearifying, I did not yet understand that you can preceed an underscore within a pattern matcher. Regarding the need of a bigint, I am writing a program which can display the 10th (and above) perfect number, which in fact cannot be placed inside a 64bit integer (or a long as some prefer). – RvdV79 Dec 2 '11 at 15:09
You misunderstood something. 2^p-1 should be bigint, but int for p is more than enough. So the parameter y need not to be int64 or bigint. It's the same reason why pown has the second parameter as an int. – pad Dec 2 '11 at 15:15
That is indeed correct, how silly of me. However the 47th perfect number has a power of 43.112.609, and it is not yet known what the next power will be. This I have found on: My goal is writing a program which at least can do an attempt to find all 47 perfect numbers (and hopefully more, but that might be an exhaustive attempt). – RvdV79 Dec 2 '11 at 15:36
@RvdV79 - hopefully more indeed! – Stephen Swensen Dec 2 '11 at 19:37
Very interesting comments. I wish I had a wife and a blog to talk about :D. – pad Dec 2 '11 at 21:46

I think the easiest way to define PowBigInt is to use if instead of pattern matching:

let rec PowBigInt (x : bigint) (y : bigint) =  
  if y = 0I then 1I   
  else x * PowBigInt x (y - 1I) 

The problem is that bigint.Zero is a static property that returns the value, but patterns can only contain (constant) literals or F# active patterns. They can't directly contain property (or other) calls. However, you can write additional constraints in where clause if you still prefer match:

let rec PowBigInt (x : bigint) (y : bigint) =  
  match y with 
  | y when y = bigint.Zero -> 1I 
  | y -> x * PowBigInt x (y - 1I)

As a side-note, you can probably make the function more efficent using tail-recursion (the idea is that if a function makes recursive call as the last thing, then it can be compiled more efficiently):

let PowBigInt (x : bigint) (y : bigint) =   
  // Recursive helper function that stores the result calculated so far
  // in 'acc' and recursively loops until 'y = 0I'
  let rec PowBigIntHelper (y : bigint) (acc : bigint) =
    if y = 0I then acc 
    else PowBigIntHelper (y - 1I) (x * acc)
  // Start with the given value of 'y' and '1I' as the result so far
  PowBigIntHelper y 1I

Regarding the PowBitShift function - I'm not sure why it is slower, but it definitely doesn't do what you need. Using bit shifting to implement power only works when the base is 2.

share|improve this answer
Well I need to rephrase my question a bit, the code I placed is not correct, since the calculation needs a power of two, I thought that a shift to the left (the exponent part) on 1 (one as a base) would do the trick. In my code the x is filled with value one, which could be replaced by the constant value itself off course. I will have to do another test to look if it is faster or not. Thank you for your extensive answer Thomas, I will try things out. Your answer led my thought to find a smaller mistake, which I will also try to fix. – RvdV79 Dec 2 '11 at 15:27

You don't need to create the Pow function. The (**) operator has an overload for bigint -> int -> bigint. Only the second parameter should be an integer, but I don't think that's a problem for your case. Just try

bigint 10 ** 32 ;;

val it : System.Numerics.BigInteger =
  100000000000000000000000000000000 {IsEven = true;
                                     IsOne = false;
                                     IsPowerOfTwo = false;
                                     IsZero = false;
                                     Sign = 1;}
share|improve this answer
Thank you Gustavo, you are right about the second parameter. – RvdV79 Dec 2 '11 at 15:37

Another option is to inline your function so it works with all numeric types (that support the required operators: (*), (-), get_One, and get_Zero).

let rec inline PowBigInt (x:^a) (y:^a) : ^a =  
  let zero = LanguagePrimitives.GenericZero 
  let one = LanguagePrimitives.GenericOne
  if y = zero then one
  else x * PowBigInt x (y - one) 

let x = PowBigInt 10 32     //int
let y = PowBigInt 10I 32I   //bigint
let z = PowBigInt 10.0 32.0 //float

I'd probably recommend making it tail-recursive, as Tomas suggested.

share|improve this answer
Excuse me for not leaving a comment Daniel, I simply missed your reaction. Tail recursion caught my interest, but your example here helped me to understand the language F# more and more. The more I learn from all of you, the more enthusiastic I become! Anyway, thank you very much for your efforts Daniel, it is very much appreciated! – RvdV79 Dec 2 '11 at 20:39
Of course! F# is a lot of fun. There's plenty to learn. – Daniel Dec 2 '11 at 20:49

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.