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So. I want to represent a type of the following form :

(Card, Suit)

to represent cards in a card game where Card instances would be in the set:

{2, 3, 4, 5, 6, 7, 8, 9, J, Q, K, 1}

and Suit would have instances in the set:

{S, D, H, C}

I'd handle that with two Data declarations if that wasn't for the numbers:

data Suit = S | D | H | C deri...

but obviously adding numbers to those null arity types will fail.

So my question is, how to simulate the kind of enum you find in C?

I guess I'm misundestanding a basic point of the type system and help will be appreciated!

EDIT: I'll add some context: I want to represent the data contained in this Euler problem, as you can check, the data is represented in the form of 1S for an ace of spade, 2D for a 2 of diamond, etc...

What I'd really like is to be able to perform a read operation directly on the string to obtain the corresponding object.

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C also can’t do that. – Konrad Rudolph Apr 25 '12 at 10:02
The ability to parse strings like "1S" or "2D" to cards is actually orthogonal to enum representation. – Matvey Aksenov Apr 25 '12 at 12:16
@MatveyAksenov Well, I do understand that. What I was looking for was the most idiomatic way to do it within the type system. Anyway, I guess I asked the wrong questions. – m09 Apr 25 '12 at 12:39

3 Answers 3

up vote 12 down vote accepted

I actually happen to have an implementation handy from when I was developing a poker bot. It's not particularly sophisticated, but it does work.

First, the relevant types. Ranks and suits are enumerations, while cards are the obvious compound type (with a custom Show instance)

import Text.ParserCombinators.Parsec

data Suit = Clubs | Diamonds | Hearts | Spades deriving (Eq,Ord,Enum,Show)

data Rank = Two | Three | Four | Five | Six | Seven | Eight | Nine | Ten
          | Jack | Queen | King | Ace deriving (Eq,Ord,Enum,Show)  

data Card = Card { rank :: Rank
                 , suit :: Suit } deriving (Eq,Ord,Bounded)

instance Show Card where
    show (Card rank suit) = show rank ++ " of " ++ show suit

Then we have the parsing code, which uses Parsec. You could develop this to be much more sophisticated, to return better error messages, etc.

Note that, as Matvey said in the comments, the problem of parsing strings into their representations in the program is (or rather should be) orthogonal to how the enums are represented. Here I've cheated and broken the orthogonality: if you wanted to re-order the ranks (e.g. to have Ace rank below Two) then you would break the parsing code, because the parser depends on the internal representation of Two being 0, Three being 1 etc..

A better approach would be to spell out all of the ranks in parseRank explicitly (which is what I do in the original code). I wrote it like this to (a) save some space, (b) illustrate how it's possible in principle to parse a number into a rank, and (c) give you an example of bad practice explicitly spelled out, so you can avoid it in the future.

parseSuit :: Parser Suit
parseSuit = do s <- oneOf "SDCH"
               return $ case s of
                'S' -> Spades
                'D' -> Diamonds
                'H' -> Hearts
                'C' -> Clubs

parseRank :: Parser Rank
parseRank = do r <- oneOf "23456789TJQKA"
               return $ case r of
                'T' -> Ten
                'J' -> Jack
                'Q' -> Queen
                'K' -> King
                'A' -> Ace
                 n  -> toEnum (read [n] - 2)

parseCard :: Parser Card
parseCard = do r <- parseRank
               s <- parseSuit
               return $ Card { rank = r, suit = s }

readCard :: String -> Either ParseError Card
readCard str = parse parseCard "" str

And here it is in action:

*Cards> readCard "2C"
Right Two of Clubs
*Cards> readCard "JH"
Right Jack of Hearts
*Cards> readCard "AS"
Right Ace of Spades


@yatima2975 mentioned in the comments that you might be able to have some fun playing with OverloadedStrings. I haven't been able to get it to do much that's useful, but it seems promising. First you need to enable the language option by putting {-# LANGUAGE OverloadedStrings #-} at the top of your file, and include the line import GHC.Exts ( IsString(..) ) to import the relevant typeclass. Then you can make a Card into a string literal:

instance IsString Card where
    fromString str = case readCard str of Right c -> c

This allows you to pattern-match on the string representation of your card, rather than having to write out the types explicitly:

isAce :: Card -> Bool
isAce "AH" = True
isAce "AC" = True
isAce "AD" = True
isAce "AS" = True
isAce _    = False

You can also use the string literals as input to functions:

printAces = do
    let cards = ["2H", "JH", "AH"]
    mapM_ (\x -> putStrLn $ show x ++ ": " ++ show (isAce x)) cards

And here it is in action:

*Cards> printAces
Two of Hearts: False
Jack of Hearts: False
Ace of Hearts: True
share|improve this answer
Thanks for this answer. Quick question: wouldn't it be nicer to make your Card type an instance of Read? I didn't use parsec yet so I do not know if it's common to ignore Read and parse it aside. – m09 Apr 25 '12 at 12:56
You could add a derived instance of Read, although you'd only gain the ability to parse strings like "Card { rank = Two, suit = Clubs }" which wouldn't be that useful. You could specify a Read instance yourself, which essentially comes down to writing a parser for your type. I don't think there's a way to get away with writing any fewer lines than I did here. – Chris Taylor Apr 25 '12 at 13:24
What are the options of now using OverloadedStringLiterals? That would get you pretty close to a DSL! – yatima2975 Apr 25 '12 at 15:07
@yatima2975 I edited to include some information about string literals. Maybe you can flesh it out if you have more experience with that language extension? – Chris Taylor Apr 26 '12 at 10:41
huh, this extension seems to be what I was looking for, in the end. Thanks @yatima2975 for bringing that up :) – m09 Apr 27 '12 at 15:01
data Card = Two | Three | Four | Five | Six
          | Seven | Eight | Nine | Ten
          | Jack | Queen | King | Ace
    deriving Enum

Implementing the Enum typeclass means you can use fromEnum and toEnum to convert between Card and Int.

However, if it's important to you that fromEnum Two is 2, you will have to implement the Enum instance for Card by hand. (The autoderived instance starts at 0, just like C, but there's no way of overriding that without doing it all yourself.)

n.b. You might not need Enum --- if all you want is to use operators like < and == with your Cards, then you need to use deriving Ord.


You cannot use read to turn a String of the form "2S" or "QH" into a (Card, Suit) because read will expect the string to look like "(a,b)" (e.g. "(2,S)" in the form you initially asked for, or "(Two,S)" in the form I suggested above).

You will have to write a function to parse the string yourself. You could use a parser (e.g. Parsec or Attoparsec), but in this case it should be simple enough to write by hand.


{-# LANGUAGE TupleSections #-}

parseSuit :: String -> Maybe Suit
parseSuit "S" = Just S
parseSuit _   = Nothing

parseCard :: String -> Maybe (Card, Suit)
parseCard ('2' : s) = fmap (Two,) (parseSuit s)
parseCard _         = Nothing
share|improve this answer
@Mod This answer actually already addresses your edit. – Konrad Rudolph Apr 25 '12 at 12:19
@Mog See my edit. – dave4420 Apr 25 '12 at 12:27

I’d just prefix the numbers with a letter, or better yet, a word. I’d also not use too many one-letter abbreviations – H, K etc. are downright unreadable.

data Suit = Club | Spade | Heart | Diamond
data Card = Card1 | Card2 | … | Jack | Queen | King | Ace

… But I even prefer dave’s suggestion of using the number words (One, Two) for values instead.

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