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What is the 'main' difference between patterns and constructors?

Answer:

With a constructor you can add a tag to your data, in such a way that it receives a type.

Patters will be more used for matching data with a pattern, which isn't the case of a constructor. 
Patters can also be used for the destruction reasons.
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Can you please make your question more precise? I'm not sure what you're aiming at, the two are for different purposes, a constructor constructs values, and patterns are used to take values apart (broadly speaking). –  Daniel Fischer Dec 28 '12 at 12:42

2 Answers 2

As Daniel Fisher said, constructors build some value, and patterns take it apart:

data Person = P String String Int

-- constructor to build a value
makePerson firstname lastname age = P firstname lastname age 

-- pattern to take a value apart
fullName (P firstname lastname _) = firstname ++ " " + lastname 

Note that this is just an example, for this particular type the record syntax would be more appropriate.

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In some sense they're very similar to one another as they are dual. Constructors can be thought of as an algebra of the signature functor of a data type and patterns coalgebras on that same functor.

To be more explicit, let's consider []. It's signature functor is T_A X = 1 + A * X or, in Haskell

type ListF a x = Maybe (a, x)

with the obvious Functor instance. We can see that ListF-algebras with a List carrier are just its constructors

-- general definition
type Algebra f a = f a -> a

consList :: Algebra (ListF a) [a]
consList Nothing        = []
consList (Just (a, as)) = a:as

Dually, we can look at the coalgebra of ListF with List as its carrier

type Coalgebra f a = a -> f a

unconsList :: Coalgebra (ListF a) [a]
unconsList []     = Nothing
unconsList (a:as) = Just (a, as)

and further see that the safe versions of head and tail are very natural destructors on []

headMay :: [a] -> Maybe a
headMay = fmap fst . unconsList

tailMay :: [a] -> Maybe a
tailMay = fmap snd . unconsList

This fuels a personal pet peeve about head and tail not even being particularly nice functions ignoring their partiality---they're only natural on infinite lists which have signature functors T A X = A*X.

Now in Haskell the initial Algebra and final Coalgebra of a functor coincide as the fixed-point of that functor

newtype Fix f = Fix { unfix :: f (Fix f) }

Which is exactly what data types are. We can prove that [a] is isomorphic to Fix (ListF a)

fwd :: [a] -> Fix (ListF a)
fwd []     = Fix Nothing
fwd (a:as) = Fix (Just (a, fwd as))

bwd :: Fix (ListF a) -> [a]
bwd (Fix Nothing)           = []
bwd (Fix (Just (a, fixed))) = a : bwd fixed

This provides justification for using the data type itself as both constructors and patterns, but if you create other kinds of "coalgebra-like" things then you can have first-class patterns such as those provided by She or pattern combinators.

For a deeper understanding of the duality of patterns and constructors, try doing this exercise above again with a data type like

data Tree a = Leaf | Branch (Tree a) a (Tree a)

Its signature functor is T A X = 1 + X*A*X or

type TreeF a x = Maybe (x,a,x)
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