TL;DR:

Use GADTs to provide implicit data contexts.

Don't use any kind of data constraint if you could do with Functor instances etc.

Map's too old to change to a GADT anyway.
Scroll to the bottom if you want to see the `User`

implementation with GADTs

Let's use a case study of a Bag where all we care about is how many times something is in it. (Like an unordered sequence. We nearly always need an Eq constraint to do anything useful with it.

I'll use the inefficient list implementation so as not to muddy the waters over the Data.Map issue.

## GADTs - the solution to the data constraint "problem"

The easy way to do what you're after is to use a GADT:

Notice below how the `Eq`

constraint not only forces you to use types with an Eq instance when making GADTBags, it provides that instance implicitly wherever the `GADTBag`

constructor appears. That's why `count`

doesn't need an `Eq`

context, whereas `countV2`

does - it doesn't use the constructor:

```
{-# LANGUAGE GADTs #-}
data GADTBag a where
GADTBag :: Eq a => [a] -> GADTBag a
unGADTBag (GADTBag xs) = xs
instance Show a => Show (GADTBag a) where
showsPrec i (GADTBag xs) = showParen (i>9) (("GADTBag " ++ show xs) ++)
count :: a -> GADTBag a -> Int -- no Eq here
count a (GADTBag xs) = length.filter (==a) $ xs -- but == here
countV2 a = length.filter (==a).unGADTBag
size :: GADTBag a -> Int
size (GADTBag xs) = length xs
```

```
ghci> count 'l' (GADTBag "Hello")
2
ghci> :t countV2
countV2 :: Eq a => a -> GADTBag a -> Int
```

Now we didn't need the Eq constraint when we found the total size of the bag, but it didn't clutter up our definition anyway. (We could have used `size = length . unGADTBag`

just as well.)

Now lets make a functor:

```
instance Functor GADTBag where
fmap f (GADTBag xs) = GADTBag (map f xs)
```

oops!

```
DataConstraints_so.lhs:49:30:
Could not deduce (Eq b) arising from a use of `GADTBag'
from the context (Eq a)
```

That's unfixable (with the standard Functor class) because I can't restrict the type of `fmap`

, but need to for the new list.

## Data Constraint version

Can we do as you asked? Well, yes, except that you have to keep repeating the Eq constraint wherever you use the constructor:

```
{-# LANGUAGE DatatypeContexts #-}
data Eq a => EqBag a = EqBag {unEqBag :: [a]}
deriving Show
count' a (EqBag xs) = length.filter (==a) $ xs
size' (EqBag xs) = length xs -- Note: doesn't use (==) at all
```

Let's go to ghci to find out some less pretty things:

```
ghci> :so DataConstraints
DataConstraints_so.lhs:1:19: Warning:
-XDatatypeContexts is deprecated: It was widely considered a misfeature,
and has been removed from the Haskell language.
[1 of 1] Compiling Main ( DataConstraints_so.lhs, interpreted )
Ok, modules loaded: Main.
ghci> :t count
count :: a -> GADTBag a -> Int
ghci> :t count'
count' :: Eq a => a -> EqBag a -> Int
ghci> :t size
size :: GADTBag a -> Int
ghci> :t size'
size' :: Eq a => EqBag a -> Int
ghci>
```

So our EqBag count' function requires an Eq constraint, which I think is perfectly reasonable, but our size' function also requires one, which is less pretty. This is because the type of the `EqBag`

constructor is `EqBag :: Eq a => [a] -> EqBag a`

, and this constraint must be added every time.

We can't make a functor here either:

```
instance Functor EqBag where
fmap f (EqBag xs) = EqBag (map f xs)
```

for exactly the same reason as with the GADTBag

## Constraintless bags

```
data ListBag a = ListBag {unListBag :: [a]}
deriving Show
count'' a = length . filter (==a) . unListBag
size'' = length . unListBag
instance Functor ListBag where
fmap f (ListBag xs) = ListBag (map f xs)
```

Now the types of count'' and show'' are exactly as we expect, and we can use standard constructor classes like Functor:

```
ghci> :t count''
count'' :: Eq a => a -> ListBag a -> Int
ghci> :t size''
size'' :: ListBag a -> Int
ghci> fmap (Data.Char.ord) (ListBag "hello")
ListBag {unListBag = [104,101,108,108,111]}
ghci>
```

# Comparison and conclusions

The GADTs version automagically propogates the Eq constraint everywhere the constructor is used. The type checker can rely on there being an Eq instance, because you can't use the constructor for a non-Eq type.

The DatatypeContexts version forces the programmer to manually propogate the Eq constraint, which is fine by me if you want it, but is deprecated because it doesn't give you anything more than the GADT one does and was seen by many as pointless and annoying.

The unconstrained version is good because it doesn't prevent you from making Functor, Monad etc instances. The constraints are written exactly when they're needed, no more or less. Data.Map uses the unconstrained version partly because unconstrained is generally seen as most flexible, but also partly because it predates GADTs by some margin, and there needs to be a compelling reason to potentially break existing code.

## What about your excellent `User`

example?

I think that's a great example of a one-purpose data type that benefits from a constraint on the type, and I'd advise you to use a GADT to implement it.

(That said, sometimes I have a one-purpose data type and end up making it unconstrainedly polymorphic just because I love to use Functor (and Applicative), and would rather use `fmap`

than `mapBag`

because I feel it's clearer.)

```
{-# LANGUAGE GADTs #-}
import Data.String
data User s where
User :: (IsString s, Show s) => s -> User s
name :: User s -> s
name (User s) = s
instance Show (User s) where -- cool, no Show context
showsPrec i (User s) = showParen (i>9) (("User " ++ show s) ++)
instance (IsString s, Show s) => IsString (User s) where
fromString = User . fromString
```

Notice since `fromString`

*does* construct a value of type `User a`

, we need the context explicitly. After all, we composed with the constructor `User :: (IsString s, Show s) => s -> User s`

. The `User`

constructor removes the need for an explicit context when we pattern match (destruct), becuase it already enforced the constraint when we used it as a constructor.

We didn't need the Show context in the Show instance because we used `(User s)`

on the left hand side in a pattern match.

`data (Show a) => User a = ..`

is not a proof that you have`Show a`

, it is a requirement that the user must fulfill. And whenever you have a polymorphic type like`User a`

, there is no way to infer that you have`Show a`

unless you write it in the constraint of the function. – user2407038 Jun 28 '14 at 11:11promisethat every`User a`

will be a`Show a`

as well, and cause`Show a`

constraint to be automatically attached to every function using`User a`

(what the OP calls "propagating") - even to such functions that make no use of the`Show`

interface. – Will Ness Jun 28 '14 at 11:42`User a`

provide an implicit Show context if you use a GADT, as in my answer. – AndrewC Jun 28 '14 at 13:50