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When reading Chapter 4 from Real World Haskell, I solved the exercise 1, at page 97, with the following lines

asInt :: String -> Int
asInt ('-':x) = asInt x
asInt xs = foldl (\a x -> a*10 + digitToInt x) 0 xs

then I have checked some comments from the linked page, and verified that this is a solution adopted by the majority.

On the other hand, I think it would be nice to write the function not as a lambda (\a x -> a*10 + digitToInt x), which is so verbose and gives names to parameters (a and x) which really need not be given one, but as the "combination" of other functions, namely the binary functions (*), (+), and the unary function digitToInt; however I can't figure out how to combine those three in a binary function equivalent to the lambda above.

I think the ingredients to compose are (*10), the unary function that has to act on foldl's accumulator, digitToInt, the unary function that acts on the element of the list xs, and (+), that has to combine these two.

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    See pointfree.io It should come up with (.digitToInt).(+).(*10)
    – FrownyFrog
    Dec 23, 2019 at 20:23
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    Pointfree code is often a case of "just because you can doesn't mean you should". It's most useful when you have a long chain of functions with an obvious input-output pipeline. But when you start doing sections with the (.) operator to get things in the right places, remember that variable names were invented for a reason. Dec 23, 2019 at 20:38
  • @FrownyFrog, thank you for letting me know about this Pointfree.io site! However, it'd be nice if you could write your own answer where you explain how that function composition work.
    – Enlico
    Dec 23, 2019 at 21:35
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    The fact that you do not need an explanation for \a x -> a*10 + digitToInt x but you do for (.digitToInt).(+).(*10) is a massive hint about which code to use. Point-free style can be very beautiful in many cases, but in others it quickly degenerates into obfuscation, deserving the name of point-less style. Distinguishing between the two is quite important to produce quality code.
    – chi
    Dec 23, 2019 at 23:12
  • I see your point, @chi; however, I'm still eager to understand how the pointless-style function works in this case; not necessarily because I will use it, as I cannot deny it obfuscates the meaning of the function (at least in this case), but because I think there's something I can learn from it, whereas there's nothing a lambda can teach but the syntax.
    – Enlico
    Dec 23, 2019 at 23:23

2 Answers 2

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It's simpler to reduce if you convert each digit to an integer before calling foldl:

asInt xs = foldl (\a x -> a*10 + x) 0 (map digitToInt xs)
    -- == foldl ((+) . (10 *)) 0 (map digitToInt xs)

which you can further eta-convert to

asInt = foldl ((+) . (10 *)) 0 . map digitToInt

(I believe that the intermediate list that would otherwise be produced by map is not created, due to list fusion. The output of each call to digitToInt is used immediately by foldl, rather than placed into a list.)

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    Does your statement about list fusion change depending on whether foldl or foldl' is used? Dec 23, 2019 at 20:59
  • I don't think so, though my understanding of list fusion is shaky. Assuming that foldl does benefit from list fusion, I don't think it matters if the item comes from the penultimate argument to foldl or from the first element of the input list.
    – chepner
    Dec 23, 2019 at 21:03
1

(you wanted to understand how the pointless-style functions work here, so here it is.)

First.

(\a x -> a*10 + digitToInt x)
= 
(\a x -> (+) ((*10) a) (digitToInt x))
= 
(curry $ (+) . (*10) . fst <*> digitToInt . snd)
=
(curry $ uncurry (+) . ((*10) *** digitToInt))

Second.

(\a x -> a*10 + digitToInt x)
= 
(\a x -> (+) ((*10) a) (digitToInt x))
= 
(\a x -> ((+) . (*10)) a . digitToInt $ x)
= 
(\a   -> ((+) . (*10)) a . digitToInt    )
= 
(\a   -> (. digitToInt) ( ((+) . (*10)) a ) )
= 
(\a   -> (. digitToInt) . ((+) . (*10)) $ a )
= 
         (. digitToInt) .  (+) . (*10)

How does it work

First.

(curry $ (+) . (*10) . fst <*> digitToInt . snd)  a  x
= {-  curry f a b  =  f (a, b)                               -}
        ((+) . (*10) . fst <*> digitToInt . snd) (a, x)
= {-  (f <*> g) a  =  f a (g a)   ;   (f . g) a  =  f (g a)  -}
   ((+) . (*10)) (fst (a, x)) (digitToInt ( snd  (a, x)))
=
   ((+) . (*10))       a      (digitToInt            x  )
= {-  (f . g) a  =  f (g a)   ;   (`c` b) a  =  (a `c` b)    -}
    (+)   (a*10)              (digitToInt            x  )
= {-  (c) a b  =  (a `c` b)                                  -}
          (a*10)            +  digitToInt            x

and,

(curry $ uncurry (+) . ((*10) *** digitToInt))  a  x
= {-  curry f a b  =  f (a, b)                -}
        (uncurry (+) . ((*10) *** digitToInt)) (a, x)
= {-  (f *** g) a  =  (f $ fst a, g $ snd a)  -}
         uncurry (+) (  (*10) a , digitToInt       x )
= {-  uncurry f (a, b)  =  f a b              -}
                 (+) (  (*10) a) (digitToInt       x )
= {-  (`c` b) a  =  (a `c` b)                 -}
                 (+)   (a*10)    (digitToInt       x )
= {-  (c) a b  =  (a `c` b)                   -}
                       (a*10)  +  digitToInt       x

Second.

           ((. digitToInt) . (+) . (*10)) a x
= {-  (f . g) a  =  f (g a)     -}
           ((. digitToInt) . (+)) ((*10) a) x
= {-  (`c` b) a  =  (a `c` b)   -}
           ((. digitToInt) . (+)) (a*10)    x
= {-  (f . g) a  =  f (g a)     -}
            (. digitToInt) ( (+)  (a*10) )  x
= {-  (`c` b) a  =  (a `c` b)   -}
 ((+) (a*10) . digitToInt)                  x
= {-  (f . g) a  =  f (g a)     -}
  (+) (a*10) ( digitToInt                   x )
= {-  (c) a b  =  (a `c` b)     -}
      (a*10) + digitToInt                   x  

Another possibility is partially point-free,

foldl  (\a -> (a*10 +) . digitToInt)  ...

which is shorter than the full lambda yet still more readable than all the fully point-free versions.

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  • The two chunks labelled "second" are an the answer for me, so I will accept it; however I'd add some text to make the answer more readable for the future reader who could skip the comments where curry and uncurry are mentioned; furthermore, some words/links about <*> and *** would be appreciated (I've only seen * used as the multiplication symbol and by the output of :kind to display concrete types.
    – Enlico
    Dec 27, 2019 at 9:05
  • will review your edit shorty; note it's not * but <*> -- the "apply" method of the Applicative type class. will also add the hackage links to the answer later. thanks.
    – Will Ness
    Dec 27, 2019 at 9:38
  • Hi, I like the parens around the lambdas, I think they help the clarity. that's just my opinion. :) So I'd rather keep'em.
    – Will Ness
    Dec 27, 2019 at 9:40
  • the Applicative and the Arrow are general, abstract type classes, but used with functions, their <*> and *** are nothing more than the definitions which I already include in the answer, (f <*> g) a = (f a) (g a) and (f *** g) a = (f $ fst a, g $ snd a). So I just use the two operators as point-free combinators.
    – Will Ness
    Dec 27, 2019 at 9:44

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