2

I've started studying Haskell a while ago and during my exams I was asked to answer what cost function would return if it was called but I couldn't understand which steps would occur. I'm sitting the exams again but I couldn't manage to understand the way I should solve this type of programs.

Any help would be appreciated!

cost = n(twice, inc, 3)
n(h,s,x) = if (x<1) then (h s x) else n(h, (h s), x-1)
inc x = x+1
twice n a = n (n a)
2
  • 5
    Simple. Take a sheet of paper, a pencil, and then just do text substitution of the arguments.
    – Cubic
    Commented Jul 21, 2014 at 17:44
  • I've tried but I don't know what I'm doing wrong. I had the same problem with prolog and by using trace mode I managed to understand it. With haskell I can't without at least an example...
    – Nanc
    Commented Jul 21, 2014 at 17:50

1 Answer 1

6

Type signatures would really go a long way here. Let's start with the simplest one, inc:

inc :: Num a => a -> a
inc x = x + 1

This is easy to derive because + 1 has type Num a => a -> a, and you can check this in GHCi with :type (+1). Next, let's look at the function twice. It's obvious that the n passed in has to be a function, since it's applied to both a and n a. Because it's applied to n a and a, both of these expressions must have the same type, and n must have only one parameter, so we can say that twice has the type

twice :: (a -> a) -> a -> a
twice n a = n (n a)

Now we can figure out n. It takes a tuple (h, s, x) as an argument and is called recursively. h has to be a function of two arguments, since it's applied to s and x, and s is unknown without more context. x has to be both a Num a => a and an Ord a => a due to its use with < 1 and -1, so we can write the signature as

n :: (Num a, Ord a) => (b -> a -> c, b, a) -> c
n (h, s, x) = if x < 1 then h s x else n (h, h s, x - 1)

Notice that I removed some unnecessary parens here. Finally, we can figure out the type of cost, which is simply n's return type:

cost :: (Num a, Ord a) => a
cost = n (twice, inc, 3)

But what would this return? For starters, it's re-write n's definition but with twice, inc, and 3 substituted in:

if 3 < 1
    then twice inc 3
    else n (twice, twice inc, 3 - 1)

Obviously 3 < 1 is false, so let's reduce n (twice, twice inc, 3 - 1):

if 2 < 1
    then twice (twice inc) 2
    else n (twice, twice (twice inc), 2 - 1)

Same story here, 2 < 1 is false, so let's continue to reduce:

if 1 < 1
    then twice (twice (twice inc)) 1
    else n (twice, twice (twice (twice inc)), 1 - 1)

Nothing new on this step, one more try:

if 0 < 1
    then twice (twice (twice (twice inc))) 0
    else n (twice, twice (twice (twice (twice inc))), 0 - 1)

Here we have 0 < 1, so we then choose the branch of twice (twice (twice (twice inc))) 2. To solve this, just plug in inc and 0 into the definition of twice:

twice (twice (twice (twice inc))) 0
           = twice (twice (twice (inc . inc))) 0
           = twice (twice (inc . inc . inc . inc)) 0
           = twice (inc . inc . inc . inc . inc . inc . inc . inc) 0
           = (inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc) 0
           = 16

And we now can't reduce this expression any more! So the entire chain of reductions is

cost = n (twice, inc, 3)
     = if 3 < 1
           then twice inc 3
           else n (twice, twice inc, 3 - 1)
     = n (twice, twice inc, 2)
     = if 2 < 1
           then twice (twice inc) 2
           else n (twice, twice (twice inc), 2 - 1)
     = n (twice, twice (twice inc), 1)
     = if 1 < 1
           then twice (twice (twice inc)) 1
           else n (twice, twice (twice (twice inc)), 1 - 1)
     = n (twice, twice (twice (twice inc)), 0)
     = if 0 < 1
           then twice (twice (twice (twice inc))) 0
           else n (twice, twice (twice (twice (twice inc))), 0 - 1)
     = twice (twice (twice (twice inc))) 0
     = inc (inc 0)
     = inc (0 + 1)
     = (inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc.inc) 0
     = 16

(To keep things readable I've used twice f = f . f instead of twice f x = f (f x), but these definitions are equivalent)

5
  • 3
    Thank you so much for the explanation. The right value is 16 though, I think it's because you forgot that second parameter is (h s). Your steps really helped me though :)
    – Nanc
    Commented Jul 21, 2014 at 18:11
  • It's else n (twice, (twice inc), 3 - 1) etc. So in the last call you have h (h 0) where h = (+8).
    – Bakuriu
    Commented Jul 21, 2014 at 18:15
  • @Nick Ah, yes, you're correct, this is what I get for not running the code before posting it. Good catch, and luckily I think this helped to demonstrate how to follow through this code by me inadvertently having an error in it. I'll update my answer.
    – bheklilr
    Commented Jul 21, 2014 at 18:17
  • One last question. We say that twice has 2 parameters. By calling twice (twice inc) 0 for example, can you explain how the first parameter of twice ( I mean twice inc) is being calculated? I cannot follow this step only.
    – Nanc
    Commented Jul 21, 2014 at 18:43
  • So another way to think of the function twice is as a function of a single argument that returns a new function (technically true of all functions in Haskell that have more than 1 arguments). So its type would be twice :: (a -> a) -> (a -> a). This is what is known as higher order functions. Since twice inc is a function, then twice (twice inc) is also a function. This is more obvious if you rewrite the definition as the equivalent twice f = \x -> f (f x). So now if you plug in inc for f and reduce that expression, then repeat for twice (twice inc), you should get the answer
    – bheklilr
    Commented Jul 21, 2014 at 18:47

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

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