Applicative functors allow static analysis at runtime. This is better explained by a simpler example.

Imagine you want to calculate a value, but want to track what dependencies that value has. Eg you may use `IO a`

to calculate the value, and have a list of `Strings`

for the dependencies:

```
data Input a = Input { dependencies :: [String], runInput :: IO a }
```

Now we can easily make this an instance of `Functor`

and `Applicative`

. The functor instance is trivial. As it doesn't introduce any new dependencies, you just need to map over the `runInput`

value:

```
instance Functor (Input) where
fmap f (Input deps runInput) = Input deps (fmap f runInput)
```

The `Applicative`

instance is more complicated. the `pure`

function will just return a value with no dependencies. The `<*>`

combiner will concat the two list of dependencies (removing duplicates), and combine the two actions:

```
instance Applicative Input where
pure = Input [] . return
(Input deps1 getF) <*> (Input deps2 runInput) = Input (nub $ deps1 ++ deps2) (getF <*> runInput)
```

With that, we can also make an `Input a`

an instance of Num if `Num a`

:

```
instance (Num a) => Num (Input a) where
(+) = liftA2 (+)
(*) = liftA2 (*)
abs = liftA abs
signum = liftA signum
fromInteger = pure . fromInteger
```

Nexts, lets make a couple of Inputs:

```
getTime :: Input UTCTime
getTime = Input { dependencies = ["Time"], runInput = getCurrentTime }
-- | Ideally this would fetch it from somewhere
stockPriceOf :: String -> Input Double
stockPriceOf stock = Input { dependencies = ["Stock ( " ++ stock ++ " )"], runInput = action } where
action = case stock of
"Apple" -> return 500
"Toyota" -> return 20
```

Finally, lets make a value that uses some inputs:

```
portfolioValue :: Input Double
portfolioValue = stockPriceOf "Apple" * 10 + stockPriceOf "Toyota" * 20
```

This is a pretty cool value. Firstly, we can find the dependencies of `portfolioValue`

as a pure value:

```
> :t dependencies portfolioValue
dependencies portfolioValue :: [String]
> dependencies portfolioValue
["Stock ( Apple )","Stock ( Toyota )"]
```

That is the static analysis that `Applicative`

allows - we know the dependencies without having to execute the action.

We can still get the value of the action though:

```
> runInput portfolioValue >>= print
5400.0
```

Now, why can't we do the same with `Monad`

? The reason is `Monad`

can express choice, in that one action can determine what the next action will be.

Imagine there was a `Monad`

interface for `Input`

, and you had the following code:

```
mostPopularStock :: Input String
mostPopularStock = Input { dependencies ["Popular Stock"], getInput = readFromWebMostPopularStock }
newPortfolio = do
stock <- mostPopularStock
stockPriceOf "Apple" * 40 + stockPriceOf stock * 10
```

Now, how can we calculate the dependencies of `newPortolio`

? It turns out we can't do it without using IO! It will depend on the most popular stock, and the only way to know is to run the IO action. Therefore it isn't possible to statically track dependencies when the type uses Monad, but completely possible with just Applicative. This is a good example of why often less power means more useful - as Applicative doesn't allow choice, dependencies can be calculated statically.

Edit: With regards to the checking if `y`

is recursive on itself, such a check is possible with applicative functors if you are willing to annotate your function names.

```
data TrackedComp a = TrackedComp { deps :: [String], recursive :: Bool, run :: a}
instance (Show a) => Show (TrackedComp a) where
show comp = "TrackedComp " ++ show (run comp)
instance Functor (TrackedComp) where
fmap f (TrackedComp deps rec1 run) = TrackedComp deps rec1 (f run)
instance Applicative TrackedComp where
pure = TrackedComp [] False
(TrackedComp deps1 rec1 getF) <*> (TrackedComp deps2 rec2 value) =
TrackedComp (combine deps1 deps2) (rec1 || rec2) (getF value)
-- | combine [1,1,1] [2,2,2] = [1,2,1,2,1,2]
combine :: [a] -> [a] -> [a]
combine x [] = x
combine [] y = y
combine (x:xs) (y:ys) = x : y : combine xs ys
instance (Num a) => Num (TrackedComp a) where
(+) = liftA2 (+)
(*) = liftA2 (*)
abs = liftA abs
signum = liftA signum
fromInteger = pure . fromInteger
newComp :: String -> TrackedComp a -> TrackedComp a
newComp name tracked = TrackedComp (name : deps tracked) isRecursive (run tracked) where
isRecursive = (name `elem` deps tracked) || recursive tracked
y :: TrackedComp [Int]
y = newComp "y" $ liftA2 (:) x z
x :: TrackedComp Int
x = newComp "x" $ 38
z :: TrackedComp [Int]
z = newComp "z" $ liftA2 (:) 3 y
> recursive x
False
> recursive y
True
> take 10 $ run y
[38,3,38,3,38,3,38,3,38,3]
```

`Applicative`

functors at runtime is optparse-applicative. Every`Parser a`

can be executed to construct something that parses commandline options into an`a`

, or it can be analyzed to extract the commandline help without actually running the parser. The source is actually pretty readable and is a nice introduction to the technique. – Lambdageek Dec 15 '13 at 6:45