# Haskell Confusing Type Classes / Polymorphism

So basically I've past learning this part way back a month ago, and I can do more complicated stuff but I still don't understand when I need "Ord" or "Eq" etc in my type definitions. When I look it up online its just so confusing to me for some reason.

E.g.

``````my_min :: Ord a => a -> a -> a
my_min n1 n2 = if n1<n2 then n1 else n2
``````

Why does this need Ord? Can you give an example of when you need Eq as well (a very simple one)? I need a very clear, basic explanation of when you need to put these, what to look out for to do that, and how to avoid using these at all if possible.

Usually I just need something like "[Int] -> Int -> [Int]" so i know ok this function takes an integer list and an integer, and returns an integer list. But when it includes Eq or Ord I have no idea.

What about this Eq type in this example I found in my lecture notes about finding two lists is identical, how does it apply?

``````identical :: Eq a =>[a]->[a]->Bool
identical [] [] = True
identical [] _ = False
identical _ [] = False
identical (h1:t1) (h2:t2) =
if h1==h2
then (identical t1 t2)
else False
``````

Thank you.

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`Ord` implies that the thing can be ordered, which means that you can say `a` is smaller (or greater) than `b`. Using only `Eq` is like saying: I know that these two items are not the same, but I cannot say which one is greater or smaller. For example if you take a traffic light as a data type:

``````data TLight = Red | Yellow | Green deriving (Show, Eq)

instance Eq TLight where
Green == Green = True
Yellow == Yellow = True
Red == Red = True
_ == _ = False
``````

Now we can say: `Red` is unequal to `Yellow` but we cannot say what is greater. This is the reason why you could not use `TLight` in your `my_min`. You cannot say which one is greater.

To your second question: "Is there any case where you have to use `Eq` and `Ord`?":

`Ord` implies `Eq`. This means that if a type can be ordered, you can also check it for equality.

You said you have mostly dealt with `[Int] -> Int -> [Int]` and you then knew it takes a list of integer and an integer and returns an integer. Now if you want to generalise your function you have to ask yourself: Do the possible types I want to use in my function need any special functionality? like if they have to be able to be ordered or equated.

Lets do a few examples: Say we want to write a function which takes a list of type `a` and an element of type `a` and returns the lisy with the element consed onto it. How would it's type signature look like? Lets start with simply this:

``````consfunc :: [a] -> a -> [a]
``````

Do we need any more functionality? No! Our type `a` can be anything because we do not need it to be able to be ordered simple because that is mot what our function should do.

Now what if we want to take a list and an element and check if the element is in the list already? The beginning type signature is:

``````elemfunc :: [a] -> a -> Bool
``````

Now does our element have to be able to do something special? Yes it does, we have to be able to check if it is equal to any element in the list, which says that our type `a` has to be equatable, so our type signature looks like this:

``````elemfunc :: (Eq a) => [a] -> a -> Bool
``````

Now what if we want to take a list and a element and insert it if it is smaller than the first element? Can you guess how the type signature would look like?

Lets begin with the standard again and ask ourselves: Do we need more than just knowing that the element and the list have to be of the same type: Yes, becuase our condition needs to perform a test that requires our type to be ordered, we have to include `Ord` in our type signature:

``````conditionalconsfunc :: (Ord a) => [a] -> a -> [a]
``````

## Edit:

Well you want to see if two lists are identical, so there are two things you have to look out for:

Your lists have to contain the same type and the things inside the list have to be equatable, hence the `Eq`.

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ok i got the Ord part, still slightly unsure about the Eq part after I checked my notes, I updated my question to include the example - how does what you say about Eq types apply to that example function of compairing to see if 2 lists are the same? –  darkphoton Aug 9 '14 at 16:31
amazing explanantion, thank you very much! upvoted and accepted –  darkphoton Aug 9 '14 at 17:04

If you are working with fixed types like `Int`, you never need class constraints. These only arise when working with polymorphic code.

You need `Eq` if you ever use the `==` or `/=` functions, or if you call any other functions that do. (I.e., if you call a function that has `Eq` in its type, then your type needs to have `Eq` as well.)

You need `Ord` if you ever use `<`, `>`, `compare` or similar functions. (Again, or if you call something that does.)

Note that you do not need `Eq` if you only do pattern matching. Thus, the following are different:

``````factorial 1 = 1
factorial n = n * factorial (n-1)
-- Only needs Num.

factorial n = if n == 1 then 1 else  n * factorial (n-1)
-- Needs Num and Eq.

factorial n = if n < 2 then 1 else n * factorial (n-1)
-- Needs Num, Eq and Ord. (But Ord implies Eq automatically.)
``````
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Actually the first function requires `Eq` as well. This is because numbers are handled as a special case, and pattern matching is converted to equality tests. Still, the point you make is correct, pattern matching against a constructor does not require `Eq`. –  chi Aug 9 '14 at 17:25
I know how it was misleading with what I said but I never said I only use Ints, I just gave the form of the type definition I usually do, e.g. "Int -> Int -> Int" or "String -> [String] -> String" and no Eqs and Ord was my point, and so I was asking how do you know when to use Ord and Eq. BUt your answer answers that as well so thanks! –  darkphoton Aug 10 '14 at 13:53

`(<)` and `(==)` are functions, but they are different from normal ones. Not because of their name, but how they are defined: `(<)` is part of the `Ord` type class, and `(==)` is part of the `Eq` type class.

Whenever you use `(<)`, the compiler needs to be told which `(<)` you mean: you need to hint which instance of `Ord` you're referring to. In case of `'a' < 'b'`, the compiler can figure it out for itself that you mean the `Ord Char` instance. Something very similar holds for `Ord Int`.

But since you're using `(<)` with arguments of type `a` in `my_min`, the compiler doesn't have enough information to figure it out by themselves. That's why you put this `Ord a =>` in the type; you'll tell the compiler whenever you actually use `my_min` (or pass the buck again, and use it in a function that also has `Ord a =>` in its type), often by context.

For instance, if you use `my_min` on two `Int`s, the compiler knows that `a` must be `Int` in that case, so you mean `Ord Int =>`, which means the compiler has found the instance. Note that you can't actually write `Ord Int =>` in a type; even if it were allowed, it wouldn't mean much to the compiler.

The same goes for the `identical` example: you need to use `(==)` with arguments of type `a`, and you'll tell the compiler later how to find the instance that gives a definition for `(==)`.

Can you give an example of when you need `Eq` as well (a very simple one)?

The definition of `Ord` starts with `instance Eq a => Ord a where`. `Eq` is a superclass of `Ord`. You could write `(Eq a, Ord a) =>`, but it has no added value over `Ord a =>`, because the compiler knows about this superclass relationship.

Since `x == y = x <= y && y <= x`, you can always give an `Eq` instance if you already have an `Ord` instance. As ThreeFx wrote, `Ord` implies `Eq`. You find this kind of relationship very often with type classes, and superclasses are often included precisely because they're implied anyway.

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