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Could anyone give some pointers on why the unpure computations in Haskell are modeled as monads?

I mean monad is just an interface with 4 operations, so what was the reasoning to modeling side-effects in it?

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Monads just define two operations. –  Dario Mar 21 '10 at 21:26
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but what about return and fail? (besides (>>) and (>>=)) –  bodacydo Mar 21 '10 at 22:53
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The two operations are return and (>>=). x >> y is the same as x >>= \\_ -> y (i.e. it ignores the result of the first argument). We don't talk about fail. –  Porges Mar 22 '10 at 0:30
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+1: Good question. –  gorsky Mar 22 '10 at 8:25
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@monadic: fail is in the Monad class because of a historical accident; it really belongs in MonadPlus. Take note that its default definition is unsafe. –  JB. Aug 17 '11 at 9:13
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7 Answers

up vote 170 down vote accepted

Suppose a function has side effects. If we take all the effects it produce as the input and output parameters, then the function is pure to the outside world.

So for an impure function

f' :: Int -> Int

we add the RealWorld to the consideration

f :: Int -> RealWorld -> (Int, RealWorld)
-- input some states of the whole world,
-- modify the whole world because of the a side effects,
-- then return the new world.

then f is pure again. We define a parametrized data type IO a = RealWorld -> (a, RealWorld), so we don't need to type RealWorld so many times

f :: Int -> IO Int

To the programmer, handling a RealWorld directly is too dangerous—in particular, if a programmer gets their hands on a value of type RealWorld, they might try to copy it, which is basically impossible. (Think of trying to copy the entire filesystem, for example. Where would you put it?) Therefore, our definition of IO encapsulates the states of the whole world as well.

These impure functions are useless if we can't chain them together. Consider

getLine :: IO String               = RealWorld -> (String, RealWorld)
getContents :: String -> IO String = String -> RealWorld -> (String, RealWorld)
putStrLn :: String -> IO ()        = String -> RealWorld -> ((), RealWorld)

We want to get a filename from the console, read that file, then print the content out. How would we do it if we can access the real world states?

printFile :: RealWorld -> ((), RealWorld)
printFile world0 = let (filename, world1) = getLine world0
                       (contents, world2) = (getContents filename) world1 
                   in  (putStrLn contents) world2 -- results in ((), world3)

We see a pattern here: the functions are called like this:

...
(<result-of-f>, worldY) = f worldX
(<result-of-g>, worldZ) = g <result-of-f> worldY
...

So we could define an operator ~~~ to bind them:

(~~~) :: (IO b) -> (b -> IO c) -> IO c

(~~~) ::      (RealWorld -> (b, RealWorld))
      -> (b -> RealWorld -> (c, RealWorld))
      ->       RealWorld -> (c, RealWorld)
(f ~~~ g) worldX = let (resF, worldY) = f worldX in
                        g resF worldY

then we could simply write

printFile = getLine ~~~ getContents ~~~ putStrLn

without touching the real world.


Now suppose we want to make the file content uppercase as well. Uppercasing is a pure function

upperCase :: String -> String

But to make it into the real world, it has to return an IO String. It is easy to lift such a function:

impureUpperCase :: String -> RealWorld -> (String, RealWorld)
impureUpperCase str world = (upperCase str, world)

this can be generalized:

impurify :: a -> IO a

impurify :: a -> RealWorld -> (a, RealWorld)
impurify a world = (a, world)

so that impureUpperCase = impurify . upperCase, and we can write

printUpperCaseFile = 
    getLine ~~~ getContents ~~~ (impurify . upperCase) ~~~ putStrLn

(Note: Normally we write getLine ~~~ getContents ~~~ (putStrLn . upperCase))


Now let's see what we've done:

  1. We defined an operator (~~~) :: IO b -> (b -> IO c) -> IO c which chains two impure functions together
  2. We defined a function impurify :: a -> IO a which converts a pure value to impure.

Now we make the identification (>>=) = (~~~) and return = impurity, and see? We've got a monad.


(To check whether it's really a monad there's few axioms should be satisfied:

(1) return a >>= f = f a

  impurify a               = (\world -> (a, world))
 (impurify a ~~~ f) worldX = let (resF, worldY) = (\world -> (a, world)) worldX 
                             in f resF worldY
                           = let (resF, worldY) =            (a, worldX))       
                             in f resF worldY
                           = f a worldX

(2) f >>= return = f

  (f ~~~ impurify) a worldX = let (resF, worldY) = impuify a worldX 
                              in f resF worldY
                            = let (resF, worldY) = (a, worldX)     
                              in f resF worldY
                            = f a worldX

(3) f >>= (\x -> g x >>= h) = (f >>= g) >>= h

Exercise.)

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15  
This is the best explanation I have ever read. Thank you for writing it! Ps. Can you please edit your code examples so that they weren't all on a single line? –  bodacydo Mar 21 '10 at 23:01
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+1: Hell, sooo good answer on rather complex topic. –  gorsky Mar 22 '10 at 8:24
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+1 but I want to note that this specifically covers the IO case. blog.sigfpe.com/2006/08/you-could-have-invented-monads-and.html is pretty similar, but generalizes RealWorld into... well, you'll see. –  ephemient Mar 22 '10 at 16:46
    
Whoah! I need to read this again. –  Damian Powell Apr 24 '10 at 10:14
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Note that this explanation cannot really apply to Haskell's IO, because the latter supports interaction, concurrency, and nondeterminism. See my answer to this question for some more pointers. –  Conal Aug 16 '11 at 0:23
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Could anyone give some pointers on why the unpure computations in Haskell are modeled as monads?

This question contains a widespread misunderstanding. Impurity and Monad are independent notions. Impurity is not modeled by Monad. Rather, there are a few data types, such as IO, that represent imperative computation. And for some of those types, a tiny fraction of their interface corresponds to the interface pattern called "Monad". Moreover, there is no known pure/functional/denotative explanation of IO (and there is unlikely to be one, considering the "sin bin" purpose of IO), though there is the commonly told story about World -> (a, World) being the meaning of IO a. That story cannot truthfully describe IO, because IO supports concurrency and nondeterminism. The story doesn't even work when for deterministic computations that allow mid-computation interaction with the world.

For more explanation, see this answer.

Edit: On re-reading the question, I don't think my answer is quite on track. Models of imperative computation do often turn out to be monads, just as the question said. The asker might not really assume that monadness in any way enables the modeling of imperative computation.

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@KennyTM: But RealWorld is, as the docs say, "deeply magical". It's a token that represents what the runtime system is doing, it doesn't actually mean anything about the real world. You can't even conjure up a new one to make a "thread" without doing extra trickery; the naive approach would just create a single, blocking action with a lot of ambiguity about when it will run. –  C. A. McCann Aug 16 '11 at 13:03
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Also, I would argue that monads are essentially imperative in nature. If the functor represents some structure with values embedded in it, a monad instance means you can build and flatten new layers based on those values. So whatever meaning you assign to a single layer of the functor, a monad means you can create an unbounded number of layers with a strict notion of causality going from one to the next. Specific instances may not have intrinsically imperative structure, but Monad in general really does. –  C. A. McCann Aug 16 '11 at 13:19
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By "Monad in general" I mean roughly forall m. Monad m => ..., i.e., working on an arbitrary instance. The things you can do with an arbitrary monad are almost exactly the same things you can do with IO: receive opaque primitives (as function arguments, or from libraries, respectively), construct no-ops with return, or transform a value in an irreversible manner using (>>=). The essence of programming in an arbitrary monad is generating a list of irrevocable actions: "do X, then do Y, then...". Sounds pretty imperative to me! –  C. A. McCann Aug 17 '11 at 14:17
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No, you're still missing my point here. Of course you wouldn't use that mindset for any of those specific types, because they have clear, meaningful structure. When I say "arbitrary monads" I mean "you don't get to pick which one"; the perspective here is from inside the quantifier, so thinking of m as existential might be more helpful. Furthermore, my "interpretation" is a rephrasing of the laws; the list of "do X" statements is precisely the free monoid on the unknown structure created via (>>=); and the monad laws are just monoid laws on endofunctor composition. –  C. A. McCann Aug 18 '11 at 7:04
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In short, the greatest lower bound on what all monads together describe is a blind, meaningless march into the future. IO is a pathological case precisely because it offers almost nothing more than this minimum. In specific cases, types may reveal more structure, and thus have actual meaning; but otherwise the essential properties of a monad--based on the laws--are as antithetical to clear denotation as IO is. Without exporting constructors, exhaustively enumerating primitive actions, or something similar, the situation is hopeless. –  C. A. McCann Aug 18 '11 at 7:15
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As I understand it, someone called Eugenio Moggi first noticed that a previously obscure mathematical construct called a "monad" could be used to model side effects in computer languages, and hence specify their semantics using Lambda calculus. When Haskell was being developed there were various ways in which impure computations were modelled (see Simon Peyton Jones' "hair shirt" paper for more details), but when Phil Wadler introduced monads it rapidly became obvious that this was The Answer. And the rest is history.

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Not quite. It has been known that a monad can model interpretation for a very long time (at least since "Topoi: A Categorical Analysis of Logic). On the other hand, it wasn't possible to clearly express the types for monads until strongly typed functional languages came around, and then Moggi put two and two together. –  nomen Dec 4 '12 at 2:10
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Could anyone give some pointers on why the unpure computations in Haskell are modeled as monads?

Well, because Haskell is pure. You need a mathematical concept to distinguish between unpure computations and pure ones on type-level and to model programm flows in respectively.

This means you'll have to end up with some type IO a that models an unpure computation. Then you need to know ways of combining these computations of which apply in sequence (>>=) and lift a value (return) are the most obvious and basic ones.

With these two, you've already defined a monad (without even thinking of it);)

In addition, monads provide very general and powerful abstractions, so many kinds of control flow can be conveniently generalized in monadic functions like sequence, liftM or special syntax, making unpureness not such a special case.

See monads in functional programming and uniqueness typing (the only alternative I know) for more information.

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It's actually quite a clean way to think of I/O in a functional way.

In most programming languages, you do input/output operations. In Haskell, imagine writing code not to do the operations, but to generate a list of the operations that you would like to do.

Monads are just pretty syntax for exactly that.

If you want to know why monads as opposed to something else, I guess the answer is that they're the best functional way to represent I/O that people could think of when they were making Haskell.

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AFAIK, the reason is to be able to include side effects checks in the type system. If you want to know more, listen to those SE-Radio episodes: Episode 108: Simon Peyton Jones on Functional Programming and Haskell Episode 72: Erik Meijer on LINQ

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Above there are very good detailed answers with theoretical background. But I want to give my view on IO monad. I am not experienced haskell programmer, so May be it is quite naive or even wrong. But i helped me to deal with IO monad to some extent (note, that it do not relates to other monads).

First I want to say, that example with "real world" is not too clear for me as we cannot access its (real world) previous states. May be it do not relates to monad computations at all but it is desired in the sense of referential transparency, which is generally presents in haskell code.

So we want our language (haskell) to be pure. But we need input/output operations as without them our program cannot be useful. And those operations cannot be pure by their nature. So the only way to deal with this we have to separate impure operations from the rest of code.

Here monad comes. Actually, I am not sure, that there cannot exist other construct with similar needed properties, but the point is that monad have these properties, so it can be used (and it is used successfully). The main property is that we cannot escape from it. Monad interface do not have operations to get rid of the monad around our value. Other (not IO) monads provide such operations and allow pattern matching (e.g. Maybe), but those operations are not in monad interface. Another required property is ability to chain operations.

If we think about what we need in terms of type system, we come to the fact that we need type with constructor, which can be wrapped around any vale. Constructor must be private, as we prohibit escaping from it(i.e. pattern matching). But we need function to put value into this constructor (here return comes to mind). And we need the way to chain operations. If we think about it for some time, we will come to the fact, that chaining operation must have type as >>= has. So, we come to something very similar to monad. I think, if we now analyze possible contradictory situations with this construct, we will come to monad axioms.

Note, that developed construct do not have anything in common with impurity. It only have properties, which we wished to have to be able to deal with impure operations, namely, no-escaping, chaining, and a way to get in.

Now some set of impure operations is predefined by the language within this selected monad IO. We can combine those operations to create new unpure operations. And all those operations will have to have IO in their type. Note however, that presence of IO in type of some function do not make this function impure. But as I understand, it is bad idea to write pure functions with IO in their type, as it was initially our idea to separate pure and impure functions.

Finally, I want to say, that monad do not turn impure operations into pure ones. It only allows to separate them effectively. (I repeat, that it is only my understanding)

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