My favorite example is the "purely applicative Either". We'll start by analyzing the base Monad instance for Either

```
instance Monad (Either e) where
return = Right
Left e >>= _ = Left e
Right a >>= f = f a
```

This instance embeds a very natural short-circuiting notion: we proceed from left to right and once a single computation "fails" into the `Left`

then all the rest do as well. There's also the natural `Applicative`

instance that any `Monad`

has

```
instance Applicative (Either e) where
pure = return
(<*>) = ap
```

where `ap`

is nothing more than left-to-right sequencing before a `return`

:

```
ap :: Monad m => m (a -> b) -> m a -> m b
ap mf ma = do
f <- mf
a <- ma
return (f a)
```

Now the trouble with this `Either`

instance comes to light when you'd like to collect error messages which occur anywhere in a computation and somehow produce a summary of errors. This flies in the face of short-circuiting. It also flies in the face of the type of `(>>=)`

```
(>>=) :: m a -> (a -> m b) -> m b
```

If we think of `m a`

as "the past" and `m b`

as "the future" then `(>>=)`

produces the future from the past so long as it can run the "stepper" `(a -> m b)`

. This "stepper" demands that the value of `a`

really exists in the future... and this is impossible for `Either`

. Therefore `(>>=)`

*demands* short-circuiting.

So instead we'll implement an `Applicative`

instance which cannot have a corresponding `Monad`

.

```
instance Monoid e => Applicative (Either e) where
pure = Right
```

Now the implementation of `(<*>)`

is the special part worth considering carefully. It performs some amount of "short-circuiting" in its first *3* cases, but does something interesting in the fourth.

```
Right f <*> Right a = Right (f a) -- neutral
Left e <*> Right _ = Left e -- short-circuit
Right _ <*> Left e = Left e -- short-circuit
Left e1 <*> Left e2 = Left (e1 <> e2) -- combine!
```

Notice again that if we think of the left argument as "the past" and the right argument as "the future" then `(<*>)`

is special compared to `(>>=)`

as it's allowed to "open up" the future and the past in parallel instead of necessarily needing results from "the past" in order to compute "the future".

This means, directly, that we can use our purely `Applicative`

`Either`

to collect errors, ignoring `Right`

s if any `Left`

s exist in the chain

```
> Right (+1) <*> Left [1] <*> Left [2]
> Left [1,2]
```

So let's flip this intuition on its head. What can we not do with a purely applicative `Either`

? Well, since its operation depends upon examining the future prior to running the past, we must be able to determine the structure of the future without depending upon values in the past. In other words, we cannot write

```
ifA :: Applicative f => f Bool -> f a -> f a -> f a
```

which satisfies the following equations

```
ifA (pure True) t e == t
ifA (pure False) t e == e
```

while we can write `ifM`

```
ifM :: Monad m => m Bool -> m a -> m a -> m a
ifM mbool th el = do
bool <- mbool
if bool then th else el
```

such that

```
ifM (return True) t e == t
ifM (return False) t e == e
```

This impossibility arises because `ifA`

embodies exactly the idea of the result computation depending upon the values embedded in the argument computations.

`Just 1`

describes a "computation", whose "result" is 1.`Nothing`

describes a computation which produces no results.