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I cant figure out why I get two different results but I'm sure it has to do with IO, which I am beginning to hate!

For example:

  ghci> x <- readFile "foo.txt"
  ghci> let y = read x :: [Int]
  ghci> :t y
  y :: [Int]

Now when I create that file and do the same thing it comes out as IO [Int] ?

foo.txt is a txt file containing only this: 12345

Someone that can explain this to me? As I'm about to snap it!

Thanks for any insight!

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2  
probably you should write the whole program and add that here too ,,, –  Satvik Sep 30 '12 at 18:59

4 Answers 4

up vote 6 down vote accepted

Read about ghci. To quote

The syntax of a statement accepted at the GHCi prompt is exactly the same as the syntax of a statement in a Haskell do expression. However, there's no monad overloading here: statements typed at the prompt must be in the IO monad.

Basically you are inside the IO Monad when you are writing anything in ghci.

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GHCi does a little bit of magic to make it easier to quickly test stuff at the command prompt. If this were part of a program, then IO [Int] would indeed be the correct type. GHCi is letting you treat it as just Int to save you a bit of typing.

So that's the "why".

Now, if you have a specific question like "how do I do X given that the type signature is this?"...

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Main idea

Be clear on the distinction in Haskell between an IO operation that produces a value, and the value itself.

Recommended Reading

A good reference to IO in Haskell that doesn't expect you to want to know the theoretical basis for monads is sigfpe's The IO Monad for People who Simply Don't Care.

Note it's the monad-theoretical bit that he's assuming you don't care about. He's assuming you do care about doing IO. It's not very long, and I think it's very much worth a read for you, because it makes explicit some 'rules' that you're not aware of so are causing you irritation.

Your code

Anyway, in your code

x <- readFile "foo.txt"

the readFile "foo.txt" bit has type IO String, which means it's an operation that produces a String. When you do x <- readFile "foo.txt", you use x to refer to the String it produces. Notice the distinction between the output, x and the operation that produced it, readFile "foo.txt".

Next let's look at y. You define let y = read x :: [Int], so y is a list of Ints, as you specified. However, y isn't the same as the whole chunk that defines it.

example = do
  x <- readFile "foo.txt"
  let y = read x :: [Int]
  return y

Here example :: IO [Int], whereas y itself has type [Int].

The cause of your frustration

If you come from an imperative language, this is frustrating at first - you're used to being able to use functions that produce values wherever you'd use values, but you're used to those functions also being allowed to execute arbitrary IO operations.

In Haskell, you can do whatever you like with 'pure' functions (that don't use IO) but not IO operations. Haskell programmers see a whole world of difference between an IO operation that returns a value, which can only be reused in other IO operations, and a pure function which can be used anywhere.

This means that you can end up trapped in the awkward IO monad all the time, and all your functions are full of IO datatypes. This is inconvenient and you write messy code.

How to avoid IO mess

First solve the problem you have in its entirety without using external (file or user) data:

  • Write sample data that you normally read from a file or user as values in your source code.
  • Write your functions with any data you need in the definition as parameters to the function. This is the only way you can get data when you're writing pure code. Write pure code first.
  • Test your functions on the specimen data. (If you like, you can reload in ghci every time you write a new function, making sure it does what you expect.)
  • Once your program is complete without the IO, you can introduce it as a wrapper around the pure code at the end.

This means that in your program, I don't think you should be writing any readFile or other IO code until you're nearly finished.

It's a completely different workflow - in an imperative language you'd write code to read your data, then do stuff, then write your data. In Haskell it's better to write the code that does stuff first, then the code to read and write the data at the end, once you know the functionality is right.

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You can't actually do exactly the same thing in a Haskell source file, so I suspect what you did actually looks like this:

readFoo = do
    x <- readFile "foo.txt"
    let y = read x :: [Int]
    return y

And are surprised that the type of readFoo comes out as IO [Int], even though it's returning y which is of type [Int].

If this is the case, the source of your confusion is that return in Haskell isn't a return statement from imperative languages.

return in Haskell is a function. A perfectly ordinary function. Like any other function it takes a value of some type as input and gives you a value of some other type as output. Specialised to the case of IO (return can be used with any monad, but we'll keep it simple here), it has this type:

a -> IO a

So it takes a value of any type and gives you a value in the same type wrapped up in the IO monad. So if y has type [Int], then return y has type IO [Int], and that's what you get as the result of readFoo.

There's no way to get the [Int] "out" of the IO [Int]. This is deliberate. The whole point of IO is that any value which is dependent on anything "outside" the program can only appear in an IO x type. So a function which internally reads "foo.txt" and returns a list of the integers in it must be impossible to write in Haskell, or the whole house of cards falls down. If we saw a function with a type like readFoo :: [Int], as you were trying to write, then we know that readFoo can only be one particular list of integers; it can't be a list that depends on the contents of a file on disk.

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