The clue to your answer is in the HaskellWiki about MonadPlus you linked to:

Which rules? Martin & Gibbons choose Monoid, Left Zero, and Left Distribution. This makes `[]`

a MonadPlus, but not `Maybe`

or `IO`

.

So according to your favoured choice, `Maybe`

isn't a MonadPlus (although there's an instance, it doesn't satisfy left distribution). Let's prove it satisfies Alternative.

`Maybe`

is an Alternative

**Right distributivity (of **`<*>`

): `(f <|> g) <*> a = (f <*> a) <|> (g <*> a)`

Case 1: `f=Nothing`

:

```
(Nothing <|> g) <*> a = (g) <*> a -- left identity <|>
= Nothing <|> (g <*> a) -- left identity <|>
= (Nothing <*> a) <|> (g <*> a) -- left failure <*>
```

Case 2: `a=Nothing`

:

```
(f <|> g) <*> Nothing = Nothing -- right failure <*>
= Nothing <|> Nothing -- left identity <|>
= (f <*> Nothing) <|> (g <*> Nothing) -- right failure <*>
```

Case 3: `f=Just h, a = Just x`

```
(Just h <|> g) <*> Just x = Just h <*> Just x -- left bias <|>
= Just (h x) -- success <*>
= Just (h x) <|> (g <*> Just x) -- left bias <|>
= (Just h <*> Just x) <|> (g <*> Just x) -- success <*>
```

**Right absorption (for **`<*>`

): `empty <*> a = empty`

That's easy, because

```
Nothing <*> a = Nothing -- left failure <*>
```

**Left distributivity (of **`fmap`

): `f <$> (a <|> b) = (f <$> a) <|> (f <$> b)`

Case 1: `a = Nothing`

```
f <$> (Nothing <|> b) = f <$> b -- left identity <|>
= Nothing <|> (f <$> b) -- left identity <|>
= (f <$> Nothing) <|> (f <$> b) -- failure <$>
```

Case 2: `a = Just x`

```
f <$> (Just x <|> b) = f <$> Just x -- left bias <|>
= Just (f x) -- success <$>
= Just (f x) <|> (f <$> b) -- left bias <|>
= (f <$> Just x) <|> (f <$> b) -- success <$>
```

**Left absorption (for **`fmap`

): `f <$> empty = empty`

Another easy one:

```
f <$> Nothing = Nothing -- failure <$>
```

`Maybe`

isn't a MonadPlus

Let's prove the assertion that `Maybe`

isn't a MonadPlus: We need to show that `mplus a b >>= k = mplus (a >>= k) (b >>= k)`

doesn't always hold. The trick is, as ever, to use some binding to sneak very different values out:

```
a = Just False
b = Just True
k True = Just "Made it!"
k False = Nothing
```

Now

```
mplus (Just False) (Just True) >>= k = Just False >>= k
= k False
= Nothing
```

here I've used bind `(>>=)`

to snatch failure (`Nothing`

) from the jaws of victory because `Just False`

looked like success.

```
mplus (Just False >>= k) (Just True >>= k) = mplus (k False) (k True)
= mplus Nothing (Just "Made it!")
= Just "Made it!"
```

Here the failure (`k False`

) was calculated early, so got ignored and we `"Made it!"`

.

So, `mplus a b >>= k = Nothing`

but `mplus (a >>= k) (b >>= k) = Just "Made it!"`

.

You can look at this as me using `>>=`

to break the left-bias of `mplus`

for `Maybe`

.

## Validity of my proofs:

Just in case you felt I hadn't done enough tedious deriving, I'll prove the identities I used:

Firstly

```
Nothing <|> c = c -- left identity <|>
Just d <|> c = Just d -- left bias <|>
```

which come from the instance declaration

```
instance Alternative Maybe where
empty = Nothing
Nothing <|> r = r
l <|> _ = l
```

Secondly

```
f <$> Nothing = Nothing -- failure <$>
f <$> Just x = Just (f x) -- success <$>
```

which just come from `(<$>) = fmap`

and

```
instance Functor Maybe where
fmap _ Nothing = Nothing
fmap f (Just a) = Just (f a)
```

Thirdly, the other three take a bit more work:

```
Nothing <*> c = Nothing -- left failure <*>
c <*> Nothing = Nothing -- right failure <*>
Just f <*> Just x = Just (f x) -- success <*>
```

Which comes from the definitions

```
instance Applicative Maybe where
pure = return
(<*>) = ap
ap :: (Monad m) => m (a -> b) -> m a -> m b
ap = liftM2 id
liftM2 :: (Monad m) => (a1 -> a2 -> r) -> m a1 -> m a2 -> m r
liftM2 f m1 m2 = do { x1 <- m1; x2 <- m2; return (f x1 x2) }
instance Monad Maybe where
(Just x) >>= k = k x
Nothing >>= _ = Nothing
return = Just
```

so

```
mf <*> mx = ap mf mx
= liftM2 id mf mx
= do { f <- mf; x <- mx; return (id f x) }
= do { f <- mf; x <- mx; return (f x) }
= do { f <- mf; x <- mx; Just (f x) }
= mf >>= \f ->
mx >>= \x ->
Just (f x)
```

so if `mf`

or `mx`

are Nothing, the result is also `Nothing`

, whereas if `mf = Just f`

and `mx = Just x`

, the result is `Just (f x)`

`Alternative`

is "a monoid on applicative functors." That's clear in the original context, but you're right, I probably should have been more explicit. – Antal S-Z Oct 30 '12 at 8:22