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Can any one explain this to me in relation to sorting algorithms?

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what do you mean by "searches"? – Adam Bergmark May 28 '11 at 18:05
In relation to a quicksort of integers – Lunar May 28 '11 at 18:16
well, in a nutshell, it is a natural transformation. But saying it like this only complicates matters. – Alexandre C. May 28 '11 at 18:25
@Lunar: quicksort (like other sorting functions) could never be implemented as a parametrically polymorphic function. Reason: For sorting, the function has to compare values; but: since the function should work for all kind of types it is not guaranteed that the values are comparable (there are many types whose values are not comparable). – phynfo May 28 '11 at 20:20
@phynfo: A sorting function would typically just take a comparison function as one of the arguments, as in erisco's answer. In fact, the first place I ever saw a higher-order function was qsort in the C standard library. – C. A. McCann May 29 '11 at 1:53
up vote 7 down vote accepted

Let me try the simplest thing I can.

Suppose you have a pair of integers:

foo :: (Int, Int) 
foo = (2,5)

and suppose you want a function that swap the position of the integers on that pair. You could do this:

swapInt :: (Int, Int) -> (Int, Int)
swapInt (x,y) = (y,x)

But now if you need a similar function for Doubles, you'd have to implement it againt:

swapDouble :: (Double, Double) -> (Double, Double)
swapDouble (x,y) = (y,x)

You have to note a couple of things: (1) the codes of swapDouble and swapInt are identical except for their type signatures, (2) nowhere in the code you make reference to anything that would depend on what are the types of x and y. This code is valid whatever are their types. So there should be a way to write the code just once and let the compiler specialize the code automatically for each type you need. The way to do this is parametrical polymorphism. For this particular case, you can write:

swap :: (a,b) -> (b,a)
swap (x,y) = (y,x)

What this means? You're telling the compiler: there's a function swap, that takes a pair (x,y) where x is of type a and y is of type b, and return the pair (y,x). a and b can be any type, thus this function is called a polymorphic function. When you apply swap to a specific pair, the compiler will check the type of this pair and automatically instantiate a version of this function that is adequate for your tuple.

For example:

swap ('a', 1) = (1,'a')  -- in this case swap :: (Char, Int) -> (Int, Char) 
swap ( 0 , 5) = (5, 0 )  -- in this case swap :: (Int , Int) -> (Int, Int )

Let's understand the name: polymorphic is any function or data structure that works with many different types. Parametric cause the way to implement the polymorphism is to have "type parameters" in the type of the function or data structure. When you write (a,b), a and b are type parameters.

Many data structures can be implemented irrespective of the type that is contained in then: lists, arrays, maps, tuples,... all of them can have a parametrically polymorphic implementation. And functions that operate on them: sort, map, fold,... can be implemented without having to refer to specific types, but to type parameters that will be specialized automatically by the compiler.

Other kinds of polymorphism exist, and Haskell also implement ad hoc polymorphism with typeclasses, for example.

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A function which is agnostic to the argument types it works with.

linear_search f n [] = Nothing
linear_search f n (x:xs)
    | f n x     = Just x
    | otherwise = linear_search f n xs

My Haskell is rusty, so if someone could correct mistakes in the comments that would be appreciated.

The idea here is that linear_search can preform a linear search on a list of any type; this is what makes the function parametrically (meaning the function parameters) polymorphic (because they can be many types).

# preforming on integers
linear_search (==) 5 [1,2,3,4,5]
# returns Just 5

# preforming on strings
linear_search (elem) 'e' ["doctor", "apron", "horse", "sky"]
# returns Just "horse"

When talking about the type of this function, it is stated as (a -> b -> Bool) -> a -> [b] -> Maybe b. Importantly, letters indicate type variables, meaning their type can be anything -- again the property which makes functions parametrically polymorphic.

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First, there is a missing b in (a -> b -> Bool) -> a -> [b] -> Maybe b. Second, it should be Just x instead of Just n. – Rotsor May 29 '11 at 7:25

Parametric polymorphism allows a function or a data type to be written generically, so that it can handle values identically without depending on their type. Parametric polymorphism is a way to make a language more expressive, while still maintaining full static type-safety.

-- from: http://en.wikipedia.org/wiki/Polymorphism_(computer_science).

In relation to searches, I guess that depends more on the exact context - I can't help there.

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Probably the case. Simplest case is id :: a -> a which can a value of any type, and returns that same value (which of course still has the same type). Without polymorphism you would have to declare idInt :: Int -> Int idString :: String -> String etc for all types – Adam Bergmark May 28 '11 at 18:07
Agreed. Also worth noting, as it's easy to forget. "Parametrically" just means that what the function does is based on its given parameters. Apologies if that's obvious. – Adam May 28 '11 at 18:12

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