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I am trying to implement a foreach morphism so as to test my "skills" in morphism definition and pattern-matching... Obviously I miss both points completely.

Could you correct me ? I want the morphism foreach to takes a list of 'a' and a morphism 'f' as arguments and to return the list of all the results 'r' of f applied to all 'a' elements.

foreach :: [a] → f → [r]
foreach [] f = []
foreach x:[] f = (f x):[]
foreach []:x f = []:(f x)
foreach (x:xs) f = (f x) : (foreach (xs f))

When compiled, I have src\Main.hs:23:0: Parse error in pattern

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By the way: This already exists, is called map and defined in half the lines. –  delnan Jan 19 '11 at 15:42
@delnan: with arguments this way, this is called for (and defined in terms of map probably). –  Alexandre C. Jan 19 '11 at 15:51
@Alexandre: Ah yes, overlooked argument order... definition would be flip map. –  delnan Jan 19 '11 at 15:52
The third and fourth lines are unnecessary. The third is taken care of by the second and fifth lines, while the fourth simply doesn't make sense. –  Dan Burton Jan 19 '11 at 16:05
@Dan thx for the noticing these incoherences. –  Stephane Rolland Jan 19 '11 at 16:18

3 Answers 3

up vote 12 down vote accepted

The problem is syntactic, in this line:

foreach x:[] f = (f x):[]

Constructor application in patterns usually need to be parenthesized. This would work:

foreach (x:[]) f = (f x):[]

Incidentally... function application is highest precedence, so on the other hand you don't need parentheses on the right-hand side:

foreach (x:[]) f = f x:[]

The above holds for any infix constructor, but as a final note, for lists in particular there is a special syntax:

foreach [x] f = [f x]

There are other issues with your code as it stands, but that's the immediate error. A quick overview of the other problems:

foreach :: [a] → f → [r]

Type variables are implicitly universally quantified, so this means any type f. You need a more specific type, namely a -> r.

foreach x:[] f = (f x):[]

This is unnecessary--the recursive case will work correctly here, applying f to x and calling itself on the tail, giving the empty list case.

foreach []:x f = []:(f x)

I don't think this means what you think it means--this is pattern matching the head of a list against the empty list [], implying that the function is working on a list of lists.

foreach (x:xs) f = (f x) : (foreach (xs f))

The parentheses here are either unnecessary or incorrect. Again, function application has higher precedence than operators like :. Additionally, (xs f) means applying xs to f, as if it were a function. To apply foreach to two arguments, simply foreach xs f will suffice.

For comparison, here's the source code for the (identical except for argument order) standard library function map:

map :: (a -> b) -> [a] -> [b]
map _ []     = []
map f (x:xs) = f x : map f xs
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thx for all precisions, namely function application with higher precedence. –  Stephane Rolland Jan 19 '11 at 15:57
and great example with the implementation of map –  Stephane Rolland Jan 19 '11 at 16:32

The type signature you give, is (at least in the Haskell compiler's opinion) bogus. It's a function which takes a list of items of any a and a value of any type f, and produces a list of values of any type r. It's like saying "I have a bunch of elephants and a screwdriver. Turn each elephant into a mango".

It seems your goal is to implement the map function:

map :: (a -> b) -> [a] -> [b]

Of course, it's perfectly valid to flip the arguments:

foreach :: [a] -> (a -> b) -> [b]

Your implementation is pretty close, but there are a few issues.

The biggest thing is to bear in mind that you're working with lists, not arrays. The : operator, also known as "cons", takes an item and prepends it to a list (e.g. 1 : [2,3,4]). You can't use it to arbitrarily concatenate items and lists, as you do in []:(f x). There is the ++ operator which concatenates two lists (e.g. [f x] ++ xs, which is the same as (f x) : xs), but you shouldn't need it to implement foreach.

Lastly, (foreach (xs f)) doesn't do what you may think it does. It is not like foreach(xs,f) in a C-style language, it is like foreach(xs(f)). (xs f), by itself, is like using xs as a function and applying f as the argument. Instead, you want (foreach xs f).

I will stop here, to avoid giving away too much. One little tidbit though: function application has higher precedence than any operator, so instead of (f x) : (foreach xs f), you can say f x : foreach xs f.

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nice to know it already exist as map. I have used it in tutorial but i forgot it ;-), I'll use it now. I have also notice the existence of the keyword forall as a Leksah auto-completion proposition, but I couldn't find its syntax. –  Stephane Rolland Jan 19 '11 at 16:00
@Stephane Rolland: forall a b. (a -> b) -> [a] -> [b]. You'll need to an enable a Haskell language extension to use this syntax. See Existentially quantified types. –  Joey Adams Jan 19 '11 at 17:35

You've forgot to put () in foreach []:x f = []:(f x) and incorrectly specified the function type, the following should now compile:

foreach :: [a] -> (a -> r) -> [r]
foreach [] f = []
foreach (x:[]) f = (f x):[]
foreach (x:xs) f = (f x) : (foreach xs f)

and run:

*Main> foreach [1..20] (+1)
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(a -> r) here means that the second argument to foreach is the function which converts type a to type r. If you would for example specified function type as foreach :: [a] -> (a -> a) -> [a], you'd be unable to evaluate foreach [1..20] show, because show produces a String, and your function takes value of one type and returns the value of the same type. –  Yasir Arsanukaev Jan 19 '11 at 15:50
thank you yasir ;-) –  Stephane Rolland Jan 19 '11 at 15:58
:-O You're welcome @Stephane Questions tagged "haskell" are far more active than "scheme", "racket" or "erlang" are. I think I need to hang out here a bit. –  Yasir Arsanukaev Jan 19 '11 at 16:04
The third line is not necessary by the way ((x:xs) matches (x:[]), binds xs to [] and then terminates on the next recursion) instead. –  delnan Jan 19 '11 at 16:08
@delnan: Indeed, I just focused my attention on syntax and function type definition which prevented the source from compiling. –  Yasir Arsanukaev Jan 19 '11 at 16:11

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