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A classic programming exercise is to write a Lisp/Scheme interpreter in Lisp/Scheme. The power of the full language can be leveraged to produce an interpreter for a subset of the language.

Is there a similar exercise for Haskell? I'd like to implement a subset of Haskell using Haskell as the engine. Of course it can be done, but are there any online resources available to look at?

Edit: Here's the backstory.

I am exploring the idea of using Haskell as a language to explore some of the concepts in a Discrete Structures course I am teaching. For this semester I have settled on Miranda, a smaller language that inspired Haskell. Miranda does about 90% of what I'd like it to do, but Haskell does about 2000%. :)

So my idea is to create a language that has exactly the features of Haskell that I'd like and disallows everything else. As the students progress, I can selectively "turn on" various features once they've mastered the basics.

Pedagogical "language levels" have been used successfully to teach Java and Scheme. By limiting what they can do, you can prevent them from shooting themselves in the foot while they are still mastering the syntax and concepts you are trying to teach. And you can offer better error messages.

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14 Answers 14

up vote 60 down vote accepted

I love your goal, but it's a big job. A couple of hints:

  • I've worked on GHC, and you don't want any part of the sources. Hugs is a much simpler, cleaner implementation but unfortunately it's in C.

  • It's a small piece of the puzzle, but Mark Jones wrote a beautiful paper called Typing Haskell in Haskell which would be a great starting point for your front end.

Good luck! Identifying language levels for Haskell, with supporting evidence from the classroom, would be of great benefit to the community and definitely a publishable result!

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I can always count on you to have a good response! –  Barry Brown Sep 18 '09 at 22:46
I wonder if the comment about GHC is still accurate. GHC is complex, but it is quite well-documented. In particular, the internal Notes are helpful in understanding low-level details, and the chapter on GHC in The Architecture of Open-Source Applications provides an excellent high-level overview. –  sjy Sep 30 at 2:08

There is a complete Haskell parser: http://hackage.haskell.org/package/haskell-src-exts

Once you've parsed it, stripping out or disallowing certain things is easy. I did this for tryhaskell.org to disallow import statements, to support top-level definitions, etc.

Just parse the module:

parseModule :: String -> ParseResult Module

Then you have an AST for a module:

Module SrcLoc ModuleName [ModulePragma] (Maybe WarningText) (Maybe [ExportSpec]) [ImportDecl] [Decl]    

The Decl type is extensive: http://hackage.haskell.org/packages/archive/haskell-src-exts/1.9.0/doc/html/Language-Haskell-Exts-Syntax.html#t%3ADecl

All you need to do is define a white-list -- of what declarations, imports, symbols, syntax is available, then walk the AST and throw a "parse error" on anything you don't want them to be aware of yet. You can use the SrcLoc value attached to every node in the AST:

data SrcLoc = SrcLoc
     { srcFilename :: String
     , srcLine :: Int
     , srcColumn :: Int

There's no need to re-implement Haskell. If you want to provide more friendly compile errors, just parse the code, filter it, send it to the compiler, and parse the compiler output. If it's a "couldn't match expected type a against inferred a -> b" then you know it's probably too few arguments to a function.

Unless you really really want to spend time implementing Haskell from scratch or messing with the internals of Hugs, or some dumb implementation, I think you should just filter what gets passed to GHC. That way, if your students want to take their code-base and take it to the next step and write some real fully fledged Haskell code, the transition is transparent.

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A pre-processor to GHC is pretty much what I had in mind. Thanks! –  Barry Brown Jul 17 '10 at 18:21

Do you want to build your interpreter from scratch? Begin with implementing an easier functional language like the lambda calculus or a lisp variant. For the latter there is a quite nice wikibook called Write yourself a Scheme in 48 hours giving a cool and pragmatic introduction into parsing and interpretation techniques.

Interpreting Haskell by hand will be much more complex since you'll have to deal with highly complex features like typeclasses, an extremely powerful type system (type-inference!) and lazy-evaluation (reduction techniques).

So you should define a quite little subset of Haskell to work with and then maybe start by extending the Scheme-example step by step.


Note that in Haskell, you have full access to the interpreters API (at least under GHC) including parsers, compilers and of course interpreters.

The package to use is hint (Language.Haskell.*). I have unfortunately neither found online tutorials on this nor tried it out by myself but it looks quite promising.

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Note that type-inference is actually a really easy, 20-30 line algorithm. it's beautiful in its simplicity. Lazy evaluation is also not so hard to encode. I'd say the difficulty lies in the insane syntax, the pattern matching, and just the large amount of stuff in the language. –  Claudiu Sep 28 '09 at 17:03
Interesting - Can you post links for the type-inference algos? –  Dario Sep 28 '09 at 17:34
Yeah, check out this free book - cs.brown.edu/~sk/Publications/Books/ProgLangs/2007-04-26 - , it's on page 273 (289 of the pdf). The alg pseudocode is on P296. –  Claudiu Sep 28 '09 at 22:44
Cool, thank you –  Dario Sep 30 '09 at 12:14
There's also an implementation of a (the?) type-inference / checking algorithm in "The Implementation of Functional Programming Languages". –  Phil Armstrong Aug 15 '11 at 9:58

create a language that has exactly the features of Haskell that I'd like and disallows everything else. As the students progress, I can selectively "turn on" various features once they've mastered the basics.

I suggest a simpler (as in less work involved) solution to this problem. Instead of creating a Haskell implementation where you can turn features off, wrap a Haskell compiler with a program that first checks that the code doesn't use any feature you disallow, and then uses the ready-made compiler to compile it.

That would be similar to HLint (and also kind of its opposite):

HLint (formerly Dr. Haskell) reads Haskell programs and suggests changes that hopefully make them easier to read. HLint also makes it easy to disable unwanted suggestions, and to add your own custom suggestions.

  • Implement your own HLint "suggestions" to not use the features you don't allow
  • Disable all the standard HLint suggestions.
  • Make your wrapper run your modified HLint as a first step
  • Treat HLint suggestions as errors. That is, if HLint "complained" then the program doesn't proceed to compilation stage
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Baskell is a teaching implementation, http://hackage.haskell.org/package/baskell

You might start by picking just, say, the type system to implement. That's about as complicated as an interpreter for Scheme, http://hackage.haskell.org/package/thih

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If you're looking for a subset of Haskell that's easy to implement, you can do away with type classes and type checking. Without type classes, you don't need type inference to evaluate Haskell code.

I wrote a self-compiling Haskell subset compiler for a Code Golf challenge. It takes Haskell subset code on input and produces C code on output. I'm sorry there isn't a more readable version available; I lifted nested definitions by hand in the process of making it self-compiling.

For a student interested in implementing an interpreter for a subset of Haskell, I would recommend starting with the following features:

  • Lazy evaluation. If the interpreter is in Haskell, you might not have to do anything for this.

  • Function definitions with pattern-matched arguments and guards. Only worry about variable, cons, nil, and _ patterns.

  • Simple expression syntax:

    • Integer literals

    • Character literals

    • [] (nil)

    • Function application (left associative)

    • Infix : (cons, right associative)

    • Parenthesis

    • Variable names

    • Function names

More concretely, write an interpreter that can run this:

-- tail :: [a] -> [a]
tail (_:xs) = xs

-- append :: [a] -> [a] -> [a]
append []     ys = ys
append (x:xs) ys = x : append xs ys

-- zipWith :: (a -> b -> c) -> [a] -> [b] -> [c]
zipWith f (a:as) (b:bs) = f a b : zipWith f as bs
zipWith _ _      _      = []

-- showList :: (a -> String) -> [a] -> String
showList _    []     = '[' : ']' : []
showList show (x:xs) = '[' : append (show x) (showItems show xs)

-- showItems :: (a -> String) -> [a] -> String
showItems show []     = ']' : []
showItems show (x:xs) = ',' : append (show x) (showItems show xs)

-- fibs :: [Int]
fibs = 0 : 1 : zipWith add fibs (tail fibs)

-- main :: String
main = showList showInt (take 40 fibs)

Type checking is a crucial feature of Haskell. However, going from nothing to a type-checking Haskell compiler is very difficult. If you start by writing an interpreter for the above, adding type checking to it should be less daunting.

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"Lazy evaluation. If the interpreter is in Haskell, you might not have to do anything for this." This may not be true. See Naylor's article in haskell.org/wikiupload/0/0a/TMR-Issue10.pdf for more info on implementing a lazy interpreter in Haskell. –  Jared Updike Mar 6 at 18:30

The EHC series of compilers is probably the best bet: it's actively developed and seems to be exactly what you want - a series of small lambda calculi compilers/interpreters culminating in Haskell '98.

But you could also look at the various languages developed in Pierce's Types and Programming Languages, or the Helium interpreter (a crippled Haskell intended for students http://en.wikipedia.org/wiki/Helium_%28Haskell%29).

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You might look at Happy (a yacc-like parser in Haskell) which has a Haskell parser.

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This might be a good idea - make a tiny version of NetLogo in Haskell. Here is the tiny interpreter.

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The links are dead. Any chance this content still exists somewhere else? I'd be curious... –  Nicolas Payette Dec 9 '12 at 5:22
hmm it was a blog post and I have no idea what keywords to use to search for it. A good lesson to include more substantial info when providing a link... –  Claudiu Dec 9 '12 at 23:22
A Google search for "netlogo haskell" turns up... this question. Anyway, no big deal. Thanks! –  Nicolas Payette Dec 10 '12 at 18:40

see if helium would make a better base to build upon than standard haskell.

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Uhc/Ehc is a series of compilers enabling/disabling various Haskell features. http://www.cs.uu.nl/wiki/Ehc/WebHome#What_is_UHC_And_EHC

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Don't you think it would be easier to take the GHC sources and strip out what you don't want, than it would be to write your own Haskell interpreter from scratch? Generally speaking, there should be a lot less effort involved in removing features as opposed to creating/adding features.

GHC is written in Haskell anyway, so technically that stays with your question of a Haskell interpreter written in Haskell.

It probably wouldn't be too hard to make the whole thing statically linked and then only distribute your customized GHCi, so that the students can't load other Haskell source modules. As to how much work it would take to prevent them from loading other Haskell object files, I have no idea. You might want to disable FFI too, if you have a bunch of cheaters in your classes :)

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This is not as easy as it sounds, as many features depend on others. But perhaps the OP just wants to not import Prelude and instead provide his own. Most of Haskell that you see are normal functions, not specific features of the runtime. (But of course, a lot are.) –  jrockway Sep 23 '09 at 7:44

I've been told that Idris has a fairly compact parser, not sure if it's really suitable for alteration, but it's written in Haskell.

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Andrej Bauer's Programming Language Zoo has a small implementation of a purely functional programming language somewhat cheekily named "minihaskell". It is about 700 lines of OCaml, so very easy to digest.

The site also contains toy versions of ML-style, Prolog-style and OO programming languages.

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