Maybe monad construction
Question
I'm currently struggling with a new element of Haskell: Monads. Therefore I was introduced to this by an example of creating a (>>=) operator that executes a function on a Maybe type (taking its actual integer value as argument to it) only if it's not equal to Nothing , and otherwise return Nothing :
(>>=) :: Maybe a -> (a -> Maybe b) -> Maybe b
Nothing >>= _ = Nothing
(Just x) >>= f = f x
However, I'm not quite sure how this works with the following usage of it:
eval (Val n) = Just n
eval (Div x y) = eval x >>= (\n ->
eval y >>= (\m ->
safediv n m))
It seems to me that the (>>=) operator simply takes one Maybe value and a function that returns one, however in this example usage code it seems like it's taking 2 times a Maybe value and once a function. I was told however that it evaluates x , puts the result in n , then evaluates y , puts the result in y , and then executes the safediv function on both. Although I don't see how the (>>=) operator plays its role here; How does this work?
3 answers
solution1
6 ACCPTED 2014-10-07 16:17:14
You can read it like this:
eval (Div x y) = eval x >>= (\n ->
eval y >>= (\m ->
safediv n m))
when you want do eval (Div xy) then
- first
eval x: -
- if was
Just n(using the first >>= )
- if was
-
- then take the
nand have a look ateval y(using the first >>= )
- then take the
-
-
- if the last is
Just m(second >>= )
- if the last is
-
-
-
- then take the
mand do a (second >>= )
- then take the
-
-
-
-
savediv nmto return it's result - you still have thenfrom your closure!.
-
-
in ever other caes return Nothing
So here the (>>=) just helps you to deconstruct.
Maybe it's easier to read and understand in the do form:
eval (Val n) = Just n
eval (Div x y) = do
n <- eval x
m <- eval y
safediv n m
which is just syntactic sugar around (>>=)
let's chase the cases:
1.eval x = Nothing and eval y = Nothing :
eval x >>= (...) = Nothing >>= (...) = Nothing
eval x = Nothing and eval y = Just n :
which is just the same:
eval x >>= (...) = Nothing >>= (...) = Nothing
eval x = Just n and eval y = Nothing :
eval x >>= (\n -> eval y >>= (...))
= Just n >>= (\n -> eval y >>= (...))
= Just n >>= (\n -> Nothing)
= Nothing
eval x = Just n and eval y = Just m :
eval x >>= (\n -> Just m >>= (...))
= Just n >>= (\n -> Just m >>= (...))
= Just n >>= (\n -> Just m >>= (\m -> safediv n m))
= (first >>= for Just) = Just m >>= (\n -> safediv n m)
= (second >>= for Just) = safediv n m
solution2
1 2014-10-07 16:36:44
Let's do element chasing to illustrate how it works. If we have
eval (Div (Val 5) (Div (Val 0) (Val 1)))
Then we can break this down into
eval (Div (Val 5) (Div (Val 0) (Val 1)))
= eval (Val 5) >>=
(\n ->
eval (Div (Val 0) (Val 1)) >>=
(\m ->
safediv n m
)
)
-- eval (Val 5) = Just 5
= Just 5 >>=
(\n ->
eval (Div (Val 0) (Val 1)) >>=
(\m ->
safediv n m
)
)
-- Just x >>= f = f x
= (\n ->
eval (Div (Val 0) (Val 1)) >>=
(\m ->
safediv n m
)
) 5
-- Substitute n = 5, since the 5 is the argument to the `\n ->` lamba
= eval (Div (Val 0) (Val 1)) >>=
(\m ->
safediv 5 m
)
Now we need to take a detour to compute eval (Div (Val 0) (Val 1)) ...
eval (Div (Val 0) (Val 1))
= eval (Val 0) >>=
(\n ->
eval (Val 1) >>=
(\m ->
safediv n m
)
)
-- eval (Val 0) = Just 0
-- eval (Val 1) = Just 1
eval (Div (Val 0) (Val 1))
= Just 0 >>=
(\n ->
Just 1 >>=
(\m ->
safediv n m
)
)
-- Just x >>= f = f x
eval (Div (Val 0) (Val 1))
= (\n ->
(\m ->
safediv n m
) 1
) 0
= (\n -> safediv n 1) 0
= safediv 0 1
= Just 0
And now back to our original call to eval , substituting Just 0 in:
eval (Div (Val 5) (Div (Val 0) (Val 1)))
= Just 0 >>= (\m -> safediv 5 m)
-- Just x >>= f = f x
eval (Div (Val 5) (Div (Val 0) (Val 1)))
= safediv 5 0
-- safediv x 0 = Nothing
eval (Div (Val 5) (Div (Val 0) (Val 1)))
= Nothing
solution3
0 2014-10-07 17:26:56
you have
eval (Val n) = Just n
from this we conclude that eval produces a Maybe value. The second equation, let's rewrite it as
eval (Div x y) =
eval x >>= (\n ->
eval y >>= (\m ->
safediv n m ) )
ie
eval (Div x y) =
eval x >>= g
where
g n = eval y >>= h
where
h m = safediv n m
See? There is only one function involved in each >>= application. At the top, it's g . But g defines – and uses – h , so h 's body has access both to its argument m and the g 's argument, n .
If eval x produced Nothing , then eval x >>= g is just Nothing , immediately, according to the >>= definition for the Maybe types ( Nothing >>= _ = Nothing ), and no eval y will be attempted.
But if it was (Just ...) then its value is just fed to the bound function ( Just x >>= f = fx ).
So if both eval s produce Just ... values, safediv nm is called inside the scope where both arguments n and m are accessible. It's probably defined as
safediv :: Num a => a -> a -> Maybe a
safediv n m | m == 0 = Nothing
| otherwise = Just (div n m) -- or something
and so h :: m -> Maybe m and g :: n -> Maybe n and the types fit,
-- assuming a missing type of "expressions", `Exp a`,
eval :: Num a => Exp a -> Maybe a
-- Num a is assumed throughout, below
eval (Div x y) = -- Maybe a
-- Maybe a >>= a -> Maybe a
eval x >>= g
where
-- a -> Maybe a
-- Maybe a >>= a -> Maybe a
g n = eval y >>= h
where
-- a -> Maybe a
h m = safediv n m -- Maybe a
-- safediv :: a -> a -> Maybe a
as per the type of bind for the Maybe monad,
(>>=) :: Maybe a ->
->
Maybe b
The technical post webpages of this site follow the CC BY-SA 4.0 protocol. If you need to reprint, please indicate the site URL or the original address.Any question please contact:yoyou2525@163.com.