Composing two error-raising functions in Haskell

The problem I have been given says this:

In a similar way to mapMaybe, define the function: composeMaybe :: (a->Maybe b) -> (b -> Maybe c) -> (a-> Maybe c) which composes two error-raising functions.

The type Maybe a and the function mapMaybe are coded like this:

``````data Maybe a = Nothing | Just a

mapMaybe g Nothing = Nothing
mapMaybe g (Just x) = Just (g x)
``````

I tried using composition like this:

``````composeMaybe f g = f.g
``````

But it does not compile.

Could anyone point me in the right direction?

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How will you learn if others do your homework for you? – yairchu Jan 14 '10 at 14:47
I'm asking for pointers not answers – ChrisMacDee Jan 14 '10 at 15:07

First of all: if anything it should be `g.f`, not `f.g` because you want a function which takes the same argument as f and gives the same return value as g. However that doesn't work because the return type of f does not equal the argument type of g (the return type of f has a Maybe in it and the argument type of g does not).

So what you need to do is: Define a function which takes a `Maybe b` as an argument. If that argument is `Nothing`, it should return `Nothing`. If the argument is `Just b`, it should return `g b`. `composeMaybe` should return the composition of the function with f.

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Hey, thanks for helping a guy out! :P I made this from your reply: g :: Maybe b -> Maybe b g Nothing = Nothing g (Just x) = g(x) But it says = cannot construct infinite type : b = Maybe b composeMaybe :: (a->Maybe b) -> (b -> Maybe c) -> (a-> Maybe c) composeMaybe f g = g.f but it doesn't compile – ChrisMacDee Jan 14 '10 at 14:47
a) The signature of the auxilarry function should be `Maybe b -> Maybe c` because the type of g is `b -> Maybe c`. b) You must not call the auxillary function g because the second function supplied to composeMaybe is already called g. c) You should define the auxillary function within the definition of composeMaybe, so that it has access to the function g (alternatively it could accept the function g as an argument). – sepp2k Jan 14 '10 at 14:54

The tool you are looking for already exists. There are two Kleisli composition operators in Control.Monad.

``````(>=>) :: Monad m => (a -> m b) -> (b -> m c) -> a -> m c
(<=<) :: Monad m => (b -> m c) -> (a -> m b) -> a -> m c
``````

When m = Maybe, the implementation of composeMaybe becomes apparent:

``````composeMaybe = (>=>)
``````

Looking at the definition of `(>=>)`,

``````f >=> g     = \x -> f x >>= g
``````

which you can inline if you want to think about it in your own terms as

``````composeMaybe f g x = f x >>= g
``````

or which could be written in `do`-sugar as:

``````composeMaybe f g x = do
y <- f x
g y
``````

In general, I'd just stick to using `(>=>)`, which has nice theoretical reasons for existing, because it provides the cleanest way to state the monad laws.

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I'm guessing this is homework, in which case using >=> probably doesn't count as a valid solution. :-) – Martijn Jan 15 '10 at 14:41
yeah it was revision for an exam i had yesterday, we didn't cover monads but will probably do them in the advanced functional programming next year! So still will come in handy! :) – ChrisMacDee Jan 16 '10 at 18:21
Martijn, true, thats why I cracked it open to take a look at the derivation. – Edward KMETT Jan 16 '10 at 20:45

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sepp2k, you may want to check out this tutorial. What you describe is exactly the Kleisli composition function for the Maybe monad. Take a look at the Control.Monad module. – Thiago Arrais Jan 14 '10 at 19:17
``````composeMaybe :: (a -> Maybe b)
-> (b -> Maybe c)
-> (a -> Maybe c)
composeMaybe f g = \x ->
``````

Since `g` takes an argument of type `b`, but `f` produces a value of type `Maybe b`, you have to pattern match on the result of `f x` if you want to pass that result to `g`.

``````                         case f x of
Nothing -> ...
Just y  -> ...
``````
-

A very similar function already exists — the monadic bind operator, `>>=`. Its type (for the Maybe monad) is `Maybe a -> (a -> Maybe b) -> Maybe b`, and it's used like this:

``````Just 100 >>= \n -> Just (show n) -- gives Just "100"
``````

It's not exactly the same as your `composeMaybe` function, which takes a function returning a Maybe instead of a direct Maybe value for its first argument. But you can write your `composeMaybe` function very simply with this operator — it's almost as simple as the definition of the normal compose function, `(.) f g x = f (g x)`.

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Notice how close the types of `composeMaybe`'s arguments are to what the monadic bind operator wants for its latter argument:

``````ghci> :t (>>=)
(>>=) :: (Monad m) => m a -> (a -> m b) -> m b
``````

The order of `f` and `g` is backward for composition, so how about a better name?

``````thenMaybe :: (a -> Maybe b) -> (b -> Maybe c) -> (a -> Maybe c)
thenMaybe f g = (>>= g) . (>>= f) . return
``````

Given the following definitions

``````times3 x = Just \$ x * 3

saferecip x
| x == 0 = Nothing
| otherwise = Just \$ 1 / x
``````

one can, for example,

``````ghci> saferecip `thenMaybe` times3 \$ 4
Just 0.75
ghci> saferecip `thenMaybe` times3 \$ 8
Just 0.375
ghci> saferecip `thenMaybe` times3 \$ 0
Nothing
ghci> times3 `thenMaybe` saferecip \$ 0
Nothing
ghci> times3 `thenMaybe` saferecip \$ 1
Just 0.3333333333333333
``````
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