Is there a built-in function with signature :: (Monad m) => m a -> a
?
Hoogle tells that there is no such function.
Can you explain why?
A monad only supplies two functions:
return :: Monad m => a -> m a
(>>=) :: Monad m => m a -> (a -> m b) -> m b
Both of these return something of type m a
, so there is no way to combine these in any way to get a function of type Monad m => m a -> a
. To do that, you'll need more than these two functions, so you need to know more about m
than that it's a monad.
For example, the Identity
monad has runIdentity :: Identity a -> a
, and several monads have similar functions, but there is no way to provide it generically. In fact, the inability to "escape" from the monad is essential for monads like IO
.
There is probably a better answer than this, but one way to see why you cannot have a type (Monad m) => m a -> a
is to consider a null monad:
data Null a = Null
instance Monad Null where
return a = Null
ma >>= f = Null
Now (Monad m) => m a -> a
means Null a -> a
, ie getting something out of nothing. You can't do that.
fromJust
from existence. It returns contents of a Just
and raises an exception in case of Nothing
. Your Null
monad could simply always raise an exception on calling such imaginary monad unwrapping function.
fromJust
is terrible and would be better not existing.
Commented
Dec 19, 2011 at 21:51
fromJust
is bad... but mainly because you used "other other hand".
Commented
Dec 19, 2011 at 23:54
Monad
class would have to be implemented as raising an exception for many classes is evidence enough that it should not be part of the class. If we actually had some examples of "monad that we can extract from" that we wanted to cope, then we could create a subclass of Monad to tackle them and put the operation there.
Commented
Dec 20, 2011 at 0:26
fromMaybe (error "UI definition file missing")
rather than fromJust
.
Commented
Dec 20, 2011 at 14:45
This doesn't exist because Monad
is a pattern for composition, not a pattern for decomposition. You can always put more pieces together with the interface it defines. It doesn't say a thing about taking anything apart.
Asking why you can't take something out is like asking why Java's Iterator
interface doesn't contain a method for adding elements to what it's iterating over. It's just not what the Iterator
interface is for.
And your arguments about specific types having a kind of extract function follows in the exact same way. Some particular implementation of Iterator
might have an add
function. But since it's not what Iterator
s are for, the presence that method on some particular instance is irrelevant.
And the presence of fromJust
is just as irrelevant. It's not part of the behavior Monad
is intended to describe. Others have given lots of examples of types where there is no value for extract
to work on. But those types still support the intended semantics of Monad
. This is important. It means that Monad
is a more general interface than you are giving it credit for.
Suppose there was such a function:
extract :: Monad m => m a -> a
Now you could write a "function" like this:
appendLine :: String -> String
appendLine str = str ++ extract getLine
Unless the extract
function was guaranteed never to terminate, this would violate referential transparency, because the result of appendLine "foo"
would (a) depend on something other than "foo"
, (b) evaluate to different values when evaluated in different contexts.
Or in simpler words, if there was an actually useful extract
operation Haskell would not be purely functional.
extract
would also make the program no longer purely functional, by virtue of violating referential transparency.
Is there a build-in function with signature
:: (Monad m) => m a -> a
?
If Hoogle says there isn't...then there probably isn't, assuming your definition of "built in" is "in the base libraries".
Hoogle tells that there is no such function. Can you explain why?
That's easy, because Hoogle didn't find any function in the base libraries that matches that type signature!
More seriously, I suppose you were asking for the monadic explanation. The issues are safety and meaning. (See also my previous thoughts on magicMonadUnwrap :: Monad m => m a -> a
)
Suppose I tell you I have a value which has the type [Int]
. Since we know that []
is a monad, this is similar to telling you I have a value which has the type Monad m => m Int
. So let's suppose you want to get the Int
out of that [Int]
. Well, which Int
do you want? The first one? The last one? What if the value I told you about is actually an empty list? In that case, there isn't even an Int
to give you! So for lists, it is unsafe to try and extract a single value willy-nilly like that. Even when it is safe (a non-empty list), you need a list-specific function (for example, head
) to clarify what you mean by desiring f :: [Int] -> Int
. Hopefully you can intuit from here that the meaning of Monad m => m a -> a
is simply not well defined. It could hold multiple meanings for the same monad, or it could mean absolutely nothing at all for some monads, and sometimes, it's just simply not safe.
Monad m => m a -> a
lacks meaning in any way that wouldn't also apply to >>=
or return
or fail
. You could always say that the "meaning" of the operation isn't well-defined in advance of knowing the full implementation that m
provides for its inclusion in the Monad type class. For your list example, a function with type Monad m => m a -> a
could very well mean any of the things you suggest -- and any of them might be valid. You could always use newtype
to tweak the behavior for your application, but denying even the chance to do it seems too severe.
Any
type etc. etc. For example, Haskell could define a value Placeholder
that has any possible type, and then you could create a really gross baked-in implementation of a Haskell runtime that essentially does a try / catch at runtime and if a monadic extraction operation would fail, it return Placeholder
instead, and the compiler can be made aware of this. It's totally gross and has many downsides, but the point is that it's absolutely possible.
Monad m => m a -> Either a
but you'd also need to be able to query the argument to see if you can get an a
and you can't do that because the Monad
typeclass doesn't have a query function. If your function was of type (Monad m, Nullable m) => m a -> Either a
then you could implement that. Or (Monad m, Nullable m, Monoid a) => m a -> a
- these cover some of the implementation choices you gave - but you see those have different types because they allow more things.
Because it may make no sense (actually, does make no sense in many instances).
For example, I might define a Parser Monad like this:
data Parser a = Parser (String ->[(a, String)])
Now there is absolutely no sensible default way to get a String
out of a Parser String
. Actually, there is no way at all to get a String out of this with just the Monad.
There is a useful extract
function and some other functions related to this at http://hackage.haskell.org/package/comonad-5.0.4/docs/Control-Comonad.html
It's only defined for some functors/monads and it doesn't necessarily give you the whole answer but rather gives an answer. Thus there will be possible subclasses of comonad that give you intermediate stages of picking the answer where you could control it. Probably related to the possible subclasses of Traversable. I don't know if such things are defined anywhere.
Why hoogle doesn't list this function at all appears to be because the comonad package isn't indexed otherwise I think the Monad constraint would be warned and extract
would be in the results for those Monads with a Comonad
instance. Perhaps this is because the hoogle parser is incomplete and fails on some lines of code.
My alternative answers:
monad >>= \a -> return $ your code uses a here
as an alternative code structure and as long as you can convert the monad to "IO ()" in a way that prints your outputs you're done. This doesn't look like extraction but maths isn't the same as the real world.Well, technicaly there is unsafePerformIO for the IO monad.
But, as the name itself suggests, this function is evil and you should only use it if you really know what you are doing (and if you have to ask wether you know or not then you don't)
unsafeHead
for the List monad...(oh wait, it's just called head
...but it is similarly, though not quite as drastically, unsafe.)
Commented
Dec 21, 2011 at 5:23
unsafePerformIO
is often safer; it may launch rockets to destroy the moon, but at least it doesn't cause your program to crash.
Monad m => m a -> a
. In order to use either you have to know the type of m
: IO a -> a
or [] a -> a
a
into functions expecting anm a
:(=<<) :: Monad m => (a -> m b) -> (m a -> m b)
. Invert your expectations, and you will be fine. =)liftM :: Monad m => (a -> b) -> (m a -> m b)
allows a "regular" function to accept a monadic value as input, but in exchange it must output a monadic value rather than a "regular" value.liftM
makes a regular functionf :: a -> b
work "inside the monad" without knowing it, such thatliftM f
outputsm b
values givenm a
values. the regular functionf
still outputs the sameb
values as it is defined to. can't do anything else.