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As a learning exercise I am trying to implment a parser for the graphviz dot language (The DOT language) using the functional parser library fparsec (FParsec). The language describes graphs.

Looking at the language definition I was compelled to write down the following definition:

let rec pstmt_list = opt(pstmt .>> opt(pchar ';') >>. opt pstmt_list)

Where pstmt and pchar ';' are parsers, .>> and >>. combine an occurence of the left parser with an occurence of the right parser, and opt parsers an optional occurrence of its argument parser as an option value. However this definition does not work complaining "... the resulting type would be infinite ...".

This example is probably most easily understood by taking a look at the DOT language linked above.

I am aware of the following seemingly linked questions:

But my F# knowledge may not be sufficient to translate them yet, if they apply here at all.

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2 Answers 2

up vote 4 down vote accepted

FParsec provides special combinators for parsing sequences. Normally you should prefer these combinators to reimplementing them with a recursive function. You can find an overview of the available combinators for parsing sequences here: http://www.quanttec.com/fparsec/reference/parser-overview.html#parsing-sequences

In this example pstmt_list is a sequence of statements separated and optionally ended by semicolons, so you could easily define the parser as

let pstmt_list = sepEndBy pstmt (pstring ";")
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The problem is that your pstmt_list parser produces some values of some type, but when you use it in the definition, you wrap the values of this type with additional option type (using the opt combinator).

The F# compiler thinks that the type of the values returned by the parser e.g. 'a should be the same as the wrapped type option 'a (which is, of course, not possible).

Anyway, I don't think that this is quite what you need to do - the .>> combinator creates a parser that returns the result of the second argument, which means that you'll be ignoring all the results of pstmt parsed so far.

I think you probably need something like this:

let rec pstmt_list : Parser<int list, unit> = 
  parse.Delay(fun () ->
    opt(pstmt .>> pchar ';') .>>. opt pstmt_list
    |>> (function Some(prev), Some(rest) -> prev::rest
                | Some(prev), _ -> [prev]
                | _, Some(rest) -> rest
                | _ -> [] ))

The additional use of Delay is to avoid declaring a value that refers directly to itself.

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The .>> combinator actually returns the result of the left parser (i.e. the result of the first argument parser). The point points to the parser whose result is returned. –  Stephan Tolksdorf Jun 21 '11 at 19:36
    
@Stephan - You're right (of course :-)). When I wrote that, I was actually thinking about the >>. operator (used later in the parser). –  Tomas Petricek Jun 21 '11 at 23:33
    
Thanks very much your answer, I think the other answer is proper one of this question, but I'm personally more interested in understanding your one and making it work. I replaced Parser<int list, unit> with Parser<int list, unit> to make it compile, but I get a stack overflow exception. Could you explain how the Delay works and suggest why the recursion doesn't terminate? –  silasdavis Jun 22 '11 at 17:46

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