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I have googled the heck out of this, but haven't been able to find anything relevant (surprises me, since it would seem to be an obvious thing many would want to try).

I want to do something like this:

data Car = "ford" | "chevy"

In other words, I want the values on the right hand side to be specific values, i.e. particular strings, particular numbers, etc. rather than something general.

Is this possible? How do I do it?

Thanks.

EDIT: I am not looking for: data Car = Ford | Chevy

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closed as not constructive by Gene T, skolima, Lucifer, JoseK, AVD Sep 26 '12 at 12:31

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Can you clarify what is wrong about data Car = Ford | Chevy? –  Andres F. Sep 25 '12 at 0:05
    
I want types which correspond to a range of real-world values. I am not going to be processing Fords or Chevys, I will be processing "fords" or "chevys". One does not add One and Two together (try it, any compiler will blow up), One must add 1 and 2. I will be using my program to process real world values. Therefore I need types to map to real-world types. I do see the utility and value of having the option to go Ford and Chevy. It just isn't what I want in this particular case. –  R G Sep 25 '12 at 0:12
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Please paste some code (or pseudo-code) that illustrates how you want to use Car. The example you gave about adding One and Two together would be solved by simply using an existing type for numbers. It's likely that you might want something like type Car = String in this particular case. –  Matt S Sep 25 '12 at 0:19
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I second Matts suggestion about adding some pseudocode. Although I can't be certain what you have in mind, I think you will find that data Car = Ford | Chevy will work well. Can you give an example, where your suggested solution adds some benefit and no drawbacks? –  Boris Sep 25 '12 at 0:32
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You could derive a read instance for your car type, then use reads to decide if the input car is in fact a Car. This requires normalizing the input to match the show instance, however, but that should be trivial. –  identity Sep 25 '12 at 8:40

4 Answers 4

up vote 3 down vote accepted

What you're trying to do is not directly possible in Haskell. data Car = "ford" | "chevy" looks like it's attempting to create a subtype of String; all Car values would be Strings, but not all Strings would be Cars. More general usage of the syntax you're trying would create bizarre types that are undiscriminated unions of subtypes (for example data Strange = 1 | "one" | '1'.

Haskell's type system doesn't have sub-typing, so this is never going to work directly.

If you don't actually care that the values of the type Car are Strings, then you can just use data Car = Ford | Chevy (as proposed by Matt S).

If you do care that the values of type Car are Strings, presumably this is because you want to be able to apply functions taking String to Car values, but you don't want to be able to pass any old String as a Car.

A different way to achieve that from creating a Car type that is only the Strings you want is to create a Car type plus a function that gives you the String corresponding to any given Car. For example:

data Car = Ford | Chevy

carStr :: Car -> String
carStr Ford = "ford"
carStr Chevy = "chevy"

Then you can pass around Car values and do Car operations on them, and whenever you actually need the value as a String (such as for printing) you just invoke carStr on it.

There is however the Show class for types that can be converted to a String, and you can automatically get an instance of Show like so:

data Car = Ford | Chevy
    deriving Show

Then the show function will render the Ford constructor as the String "Ford", and Chevy as "Chevy". That isn't exactly what you originally had, because the first letter is capitalised (the data constructor names have to begin with an upper case letter, and the derived Show instance will match the constructor names). You could manually write your own Show instance instead of deriving it, like so:

data Car = Ford | Chevy

instance Show Car where
    show Ford = "ford"
    show Chevy = "chevy"

But since so many Show instances produce exactly Haskell syntax for the values they render, I tend to think it's best not to depart from this where possible. But you can get the best of both worlds, and have an auto-derived Show instance so you don't have to manually set the correspondence between data constructors and the strings they produce, plus an different function that produces the specific strings you wanted:

import Data.Char

data Car = Ford | Chevy
    deriving Show

carStr :: Car -> String
carStr = map toLower . show
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data Car = Ford | Chevy

Data constructors aren't strings. Note that the capitalization of the first letter is not optional. In haskell, data constructors must have their first letter capitalized, and identifiers for values must have non-capital first letters.

Edited:

Here's how you can both limit values of type Car to Ford and Chevy and still use them as strings:

data Car = Ford | Chevy

carToString Ford = "Ford"
carToString Chevy = "Chevy"

Then, you would create a value with something like mycar = Ford and anytime you wanted to use the values as strings you would simply use carToString mycar.

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1  
@RG He's telling you how to achieve what you want to achieve. You may not like it, but that's not Matt's problem. (More constructively: if you want a different answer, you have to say what bad property this answer has that a good answer would not have, rather than just saying "there exists a bad property that this answer has". We don't know what you want to achieve, and we can't read your mind!) –  Daniel Wagner Sep 25 '12 at 0:09
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I believe that my edit explains how to gain that type safety and still use the values as strings when necessary. –  Matt S Sep 25 '12 at 0:27
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@MattS: If you want type safety, stop trying to use strings, and use meaningful types instead. I really cannot fathom why you want to represent data as strings in the first place--it's a terrible idea, for exactly the reasons you're complaining about! –  C. A. McCann Sep 25 '12 at 0:55
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@C.A.McCann: I think you addressed that comment to the wrong person. –  hammar Sep 25 '12 at 1:06
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@RG: So I assume you don't use numeric types in your programs either? After all, "idealized types" like, say, integers aren't what the user enters at a console. Does that mean the type has to boil down to strings like "4" or "11" instead of the integers 4 or 11? –  C. A. McCann Sep 25 '12 at 13:51

It's not really clear what you are hoping to achieve. Sounds like you want a type that can be used anywhere a String can be, but at the same time, can only be a subset of the possible values that a String can be. But.. what does that really mean?

For example, should both of these functions be allowed?

reverseCar :: Car -> Car
reverseCar = reverse

idCar :: Car -> Car
idCar = map id

By inspection, you can see that reverseCar will produce an output value that is no longer really a Car. But idChar won't actually change anything at all, so the output is still really a Car. But building a compiler that can automatically check that is impossible.

So, it is not possible to have a type that can be used everywhere String can be, and at the same time prevent you apply functions that work on String but would result in a non-Car value.

Aside from the:

data Char = Ford | Chevy

Your options are use a type alias and some helper functions:

type Car = String

ford :: Car
ford = "ford"

chevy :: Car
chevy = "chevy"

This will prevent you from making typos like frod and will allow you to use a Car anywhere a String could be used. But that means that you can also apply functions like reverse which create invalid Car types.

You could go one-step more and use a newtype wrapper:

newtype Car = Car { carToString :: String }

ford :: Car
ford = Car "ford"

chevy :: Char
chevy = Car "chevy"

Then you could define a bunch of trusted functions that are safe to use an a Car and only export those functions, but not the Car data constructor. That would prevent people from applying functions like reverse directly to Car. Instead they would have to use carToString to tell the compile that they no longer want to restrict themselves to just Car safe functions.

This is likely not what you want either. But I think the more you try to explain what exactly it is that you want.. the more you will realize that what you want is inconsistent and/or impossible.

By impossible, I don't mean 'impossible in Haskell', but rather, 'you would need to solve the halting problem impossible'.

An example you gave is that Integer does not allow the literal, 3.567. That is mixing up to different issues. The Integer data type itself has no way of expressing 3.567. It looks something like:

data Integer = I Int32 | J [Digit]

That is.. it is either a small integer that can be represented by a machine int or it is a list of digits. So, the type itself explicitly prohibits the use a decimal point. Much like

data Car = Ford | Chevy

prevents you from expressing "apple".

There is also the issue of converting the numeric literal from the source code into a Integer value. When you write (3.567 :: Integer) that is essentially shorthand which gets expanded to something like:

(fromRational (3567 % 100)) :: Integer

And you get an error like:

No instance for (Fractional Integer)
      arising from the literal `3.567'

But.. that is the process of converting a literal value to a type like Integer or Double. There is no generic number type that Integer and Double are subtypes of.

We could do something similar for the Car by using quasi-quoter so that you could write:

myCar :: Car
myCar = [car| ford |]

And that would be accepted, but this would be rejected:

notMyCar :: Car
notMyCar = [car| apple |]

But now we have gone really off the deep-end and not gotten any closer to what you wanted.. though what you want is still pretty unclear.

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It seems to be very important to you to have Strings, but you want to have type safety. Strings are inherently not type safe. The abstract data type is type safe, and once you get used to it, you'll find you like it.

One benefit is that you can allow the user to use any capitalisation (16 or 32 possibilities) but internally there's only one representation, so once you've read your data in once, using the data is fast and efficient. If you use string internally, you'lll be forever doing a more complicated capitalisation string check every time your program depends on what Car is being used.

If you're only using the `Car data type internally, you don't need strings at all, so the only reason to have strings is to deal with input and output. Here's a way of having the type safety and deal with input/ouput using strings. After compilation, the abstract data type has a very small data representation so runs faster than a string.

data Car = Ford | Chevy
  deriving (Read,Show,Eq)

so now we can read, show and check for equality. This gives you the ability to do

read "Ford" -- gives Ford
show Chevy  -- gives "Chevy"
Ford == Chevy -- gives False
read "GM" -- gives an exception. oops.

But perhaps more useful to you than read and show would be

getCar :: String -> Maybe Car
getCar xs = case toLower xs of
   "ford"   -> Just Ford
    "chevy" -> Just Chevy
    _       -> Nothing

This is great, because you can easily use it for error checking without throwing an exception and crashing your whole program, and your user can use whatever capitalisation they want. For a trivial example, you could write

feedback :: Maybe Car -> String
feedback Nothing = "Please enter a valid car. Why not use one of America's favourite brands? Ford or Chevy"
feedback (Just Ford) = "Thanks for choosing Ford."
feedback (Just Chevy) = "Thanks for choosing Chevy"

You'd also need

ungetCar :: Car -> String
ungetCar Ford  = "ford"     -- or you could use "Ford"
ungetCar Chevy = "chevy"    -- or you could use "Chevy"

Whether you use "ford" or "Ford" is up to you, but seeing as I'm not using this string internally for checking just for output, I may as well use the capitalisation I would in ordinary text, "Ford", so then I could just write

ungetCar = show

Now in your code you'd be able to write

... if car == Ford then .... else .....

instead of

... if (map toLower carString) == "ford" then ... else

with the benefit of type safety being that if your function uses the Car data type, it can assume without problems that the user has entered a valid car, Ford or Chevy, and cannot crash or make errors due to strings that aren't "ford" or "chevy". This moves all your error checking code to the first time you use getCar. If you use strings, and you want your code to be robust, every function using cars should check that the car it's given is valid and throw an exception if not, and then you're wasting an awful lot or processor cycles and you're in error handling noodle soup. The data Car = Ford | Chevy has safety, speed and convenience.

Using the abstract data type allows you to program defensively whilst also checking exactly once for invalid data. For that alone, you should prefer it. It's also clear, clean and easy.

If you later add another car

data Car = Ford | Chevy | GM

you only have to updata a couple of bits of code (eg getCar).

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