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New to Haskell so sorry if this is very basic

This example is taken from "Real World Haskell" -

ghci> :type fst  
fst :: (a, b) -> a

They show the type of the fst function and then follow it with this paragraph...

"The result type of fst is a. We've already mentioned that parametric polymorphism makes the real type inaccessible: fst doesn't have enough information to construct a value of type a, nor can it turn an a into a b. So the only possible valid behaviour (omitting infinite loops or crashes) it can have is to return the first element of the pair."

I feel like I am missing the fundamental point of the paragraph, and perhaps something important about Haskell. Why couldn't the fst function return type b? Why couldn't it take the tuple as a param, but simply return an Int ( or any other type that is NOT a)? I don't understand why it MUST return type a?


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up vote 24 down vote accepted

If it did any of those things, its type would change. What the quote is saying is that, given that we know fst is of type (a, b) -> a, we can make those deductions about it. If it had a different type, we would not be able to do so.

For instance, see that

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

does not type-check, and so we know a value of type (a, b) -> a cannot behave like snd.

Parametricity is basically the fact that a polymorphic function of a certain type must obey certain laws by construction — i.e., there is no well-typed expression of that type that does not obey them. So, for it to be possible to prove things about fst with it, we must first know fst's type.

Note especially the word polymorphism there: we can't do the same kind of deductions about non-polymorphic types. For instance,

myFst :: (Int, String) -> Int
myFst (a, b) = a

type-checks, but so does

myFst :: (Int, String) -> Int
myFst (a, b) = 42

and even

myFst :: (Int, String) -> Int
myFst (a, b) = length b

Parametricity relies crucially on the fact that a polymorphic function can't "look" at the types it is called with. So the only value of type a that fst knows about is the one it's given: the first element of the tuple.

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The point is that once you have that type, the implementation options are greatly limited. If you returned an Int, then your type would be (a,b) -> Int. Since a could be anything, we can't gin one up out of thin air in the implementation without resorting to undefined, and so must return the one given to us by the caller.

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You should read the Theorems for Free article.

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Before finishing chapter 2 of RWH? – ehird Dec 15 '11 at 18:52
It's a free article, hahaha – Thomas Eding Dec 16 '11 at 1:09
@ehird he wanted an in-depth explanation, so here it is. Basic hand-waving explanation have already been given by other people – nponeccop Dec 16 '11 at 9:44
Fair enough. I tried to avoid hand-waving in my answer, though, but I'm certainly not perfect :) – ehird Dec 16 '11 at 9:46

Let's try to add some more hand-waving to that already given by Real World Haskell. Lets try to convince ourselves that given that we have a function fst with type (a,b) -> a the only total function it can be is the following one:

fst (x,y) = x

First of all, we cannot return anything other then a value of type a, that is in the premise that fst has type (a,b) -> a, so we cannot have fst (x,y) = y or fst (x,y) = 1 because that does not have the correct type.

Now, as RWH says, if I give fst an (Int,Int), fst doesn't know these are Ints, furthermore, a or b are not required to belong to any type class so fst has no available values or functions associated with a or b.

So fst only knows about the a value and the b value that I give it and I can't turn b into an a (It can't make a b -> a function) so it must return the given a value.

This isn't actually just magical hand waving, one can actually deduce what possible expressions there are of a given polymorphic type. There is actually a program called djinn that does exactly that.

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thanks for the followup. Another great answer. – user772110 Dec 19 '11 at 13:47

The point here is that both a and b are type variables (that might be the same, but that's not needed). Anyway, since for a given tuple of two elements, fst returns always the first element, the returned type must be always the same as the type for the first element.

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The fundamental thing you're probably missing is this:

  • In most programming languages, if you say "this function returns any type", it means that the function can decide what type of value it actually returns.

  • In Haskell, if you say "this function returns any type", it means that the caller gets to decide what type that should be. (!)

So if I you write foo :: Int -> x, it can't just return a String, because I might not ask it for a String. I might ask for a Customer, or a ThreadId, or anything.

Obviously, there's no way that foo can know how to create a value of every possible type, even types that don't exist yet. In short, it is impossible to write foo. Everything you try will give you type errors, and won't compile.

(Caveat: There is a way to do it. foo could loop forever, or throw an exception. But it cannot return a valid value.)

There's no way for a function to be able to create values of any possible type. But it's perfectly possible for a function to move data around without caring what type it is. Therefore, if you see a function that accepts any kind of data, the only thing it can be doing with it is to move it around.

Alternatively, if the type has to belong to a specific class, then the function can use the methods of that class on it. (Could. It doesn't have to, but it can if it wants to.)

Fundamentally, this is why you can actually tell what a function does just by looking at its type signature. The type signature tells you what the function "knows" about the data it's going to be given, and hence what possible operations it might perform. This is why searching for a Haskell function by its type signature is so damned useful.

You've heard the expression "in Haskell, if it compiles, it usually works right"? Well, this is why. ;-)

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This is an excellent explanation of the ideas behind parametricity! Now we just need a similarly understandable translation of Wadler's proofs in "Theorems for Free". – dfeuer Oct 26 '15 at 14:44
@dfeuer If you find one, let me know! I keep seeing that phrase, but have no clue what it means... – MathematicalOrchid Oct 26 '15 at 15:05

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