Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm following Gentle introduction to Haskell tutorial and the code presented there seems to be broken. I need to understand whether it is so, or my seeing of the concept is wrong.

I am implementing parser for custom type:

data Tree a = Leaf a | Branch (Tree a) (Tree a)

printing function for convenience

showsTree              :: Show a => Tree a -> String -> String
showsTree (Leaf x)     = shows x
showsTree (Branch l r) = ('<':) . showsTree l . ('|':) . showsTree r . ('>':)

instance Show a => Show (Tree a) where 
    showsPrec _ x = showsTree x

this parser is fine but breaks when there are spaces

readsTree         :: (Read a) => String -> [(Tree a, String)]
readsTree ('<':s) =  [(Branch l r, u) | (l, '|':t) <- readsTree s,
                                        (r, '>':u) <- readsTree t ]
readsTree s       =  [(Leaf x, t)     | (x,t)      <- reads s]

this one is said to be a better solution, but it does not work without spaces

readsTree_lex    :: (Read a) => String -> [(Tree a, String)]
readsTree_lex s  = [(Branch l r, x) | ("<", t) <- lex s,
                                   (l, u)   <- readsTree_lex t,
                                   ("|", v) <- lex u,
                                   (r, w)   <- readsTree_lex v,
                                   (">", x) <- lex w ]
                ++
                [(Leaf x, t)     | (x, t)   <- reads s ]

next I pick one of parsers to use with read

instance Read a => Read (Tree a) where
    readsPrec _ s = readsTree s

then I load it in ghci using Leksah debug mode (this is unrelevant, I guess), and try to parse two strings:

    read "<1|<2|3>>"   :: Tree Int -- succeeds with readsTree
    read "<1| <2|3> >" :: Tree Int -- succeeds with readsTree_lex

when lex encounters |<2... part of the former string, it splits onto ("|<", _). That does not match ("|", v) <- lex u part of parser and fails to complete parsing.

There are two questions arising:

  1. how do I define parser that really ignores spaces, not requires them?
  2. how can I define rules for splitting encountered literals with lex

speaking of second question -- it is asked more of curiousity as defining my own lexer seems to be more correct than defining rules of existing one.

share|improve this question

2 Answers 2

up vote 4 down vote accepted

lex splits into Haskell lexemes, skipping whitespace.

This means that since Haskell permits |< as a lexeme, lex will not split it into two lexemes, since that's not how it parses in Haskell.

You can only use lex in your parser if you're using the same (or similar) syntactic rules to Haskell.

If you want to ignore all whitespace (as opposed to making any whitespace equivalent to one space), it's much simpler and more efficient to first run filter (not.isSpace).

share|improve this answer
    
that was something I was unsure of. I still don't understand why this is an example in the book. Maybe lex implementation changed for the past decade. –  sukhmel Jan 16 at 12:21
    
It does say it follows Haskell lexical rules, perhaps they were assuming you wouldn't give it "<3|<4,5>>" on the grounds that Haskell would require a space between | and < to distinguish from a potential |< operator. Thius should be made very explicit in the text, though, I agree. –  enough rep to comment Jan 16 at 12:28
1  
I found an answer to this (seemingly) inside codebase for this book. That codebase was not included with my (translated) version, which led me to not noticing that earlier. Thank you for your effort. –  sukhmel Jan 16 at 12:33
1  
using filter seems to be best solution, because either of my variants fails to remove junk from input. –  sukhmel Jan 16 at 13:16

The answer to this seems to be a small gap between text of Gentle introduction to Haskell and its code samples, plus an error in sample code.

there should also be one more lexer, but there is no working example (satisfying my need) in codebase, so I written one. Please point out any flaw in it:

lexAll :: ReadS String
lexAll s = case lex s of
            [("",_)] -> []                                  -- nothing to parse.
            [(c, r)] -> if length c == 1 then [(c, r)]      -- we will try to match
                           else [(c, r), ([head s], tail s)]-- not only as it was 
            any_else -> any_else                            -- parsed but also splitted

author sais:

Finally, the complete reader. This is not sensitive to white space as were the previous versions. When you derive the Show class for a data type the reader generated automatically is similar to this in style.

but lexAll should be used instead of lex (which seems to be said error):

readsTree' :: (Read a) => ReadS (Tree a)
readsTree' s = [(Branch l r, x) | ("<", t) <- lexAll s,
                  (l, u)   <- readsTree' t,
                                  ("|", v) <- lexAll u,
                                  (r, w)   <- readsTree' v,
                  (">", x) <- lexAll w ]
                ++
                [(Leaf x, t)    | (x, t) <- reads s]
share|improve this answer

Your Answer

 
discard

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.