Applicative and Monad both provide ways of "combining" multiple side-effectful^{1} values into a single side-effectful value.

The Applicative interface for combining just lets you combine effectful values such that the resulting effectful value combines all their effects according to some "fixed" recipe.

The Monad interface for combining lets you combine effectful values in such a way that the effects of the combined value depends on what the original effectful values do when they're actually resolved.

For example, the `State Integer`

monad/applicative is of values that depend upon (and affect) some `Integer`

state. `State Integer t`

values only have a concrete value in the presence of that state.

A function that takes two `State Integer Char`

values (call them `a`

and `b`

) and gives us back a `State Integer Char`

value and only uses the Applicative interface of `State Integer`

must produce a value whose "statefulness" is always the same, regardless of what the `Integer`

state value is and regardless of what `Char`

values the inputs yield. For example, it could thread the state through `a`

and then `b`

, combining their `Char`

values somehow. Or it could threat the state through `b`

and then `a`

. Or it could pick only `a`

or only `b`

. Or it could ignore both entirely, not taking either of their effects on the current `Integer`

state, and just `pure`

some char value. Or it could run either or both of them any fixed number of times in any fixed order, and it could incorporate any other `State Integer t`

values it knows about. But whatever it does, it *always* does that, regardless of the current `Integer`

state, or any values produced by any of the `State Integer t`

values it manages to get its hands on.

A function that took the same inputs but was able to use the monad interface for `State Integer`

can do much more than that. It can run `a`

or `b`

depending on whether the current `Integer`

state is positive or negative. It can run `a`

, then if the resulting `Char`

is an ascii digit character it can turn the digit into a number and run `b`

that many times. And so on.

So yes, a computation like:

```
do
print' "hello"
print' "world"
```

Is one that could be implemented using only the Applicative interface to whatever `print'`

returns. You are close to correct that the difference between Monad and Applicative if both had a do-notation would be that monadic do would allow `x <- ...`

, while applicative do would not. It's a bit more subtle than that though; *this* would work with Applicative too:

```
do x <- ...
y <- ...
pure $ f x y
```

What Applicative can't do is *inspect* `x`

and `y`

to decide what `f`

to call on them (or do anything with the result of `f x y`

other than just `pure`

it.

You are not quite correct that there's no difference between `Writer w`

as a monad and as an applicative, however. It's true that the monadic interface of `Writer w`

doesn't allow the *value* yielded to depend on the effects (the "log"), so it must always be possible to rewrite any `Writer w`

defined using monadic features to one that only uses applicative features and always yields the same value^{2}. But the monadic interface allows the *effects* to depend on the *values*, which the applicative interface doesn't, so you can't always faithfully reproduce the effects of a `Writer w`

using only the applicative interface.

See this (somewhat silly) example program:

```
import Control.Applicative
import Control.Monad.Writer
divM :: Writer [String] Int -> Writer [String] Int -> Writer [String] Int
divM numer denom
= do d <- denom
if d == 0
then do tell ["divide by zero"]
return 0
else do n <- numer
return $ n `div` d
divA :: Writer [String] Int -> Writer [String] Int -> Writer [String] Int
divA numer denom = divIfNotZero <$> numer <*> denom
where
divIfNotZero n d = if d == 0 then 0 else n `div` d
noisy :: Show a => a -> Writer [String] a
noisy x = tell [(show x)] >> return x
```

Then with that loaded in GHCi:

```
*Main> runWriter $ noisy 6 `divM` noisy 3
(2,["3","6"])
*Main> runWriter $ noisy 6 `divM` noisy 0
(0,["0","divide by zero"])
*Main> runWriter $ undefined `divM` noisy 0
(0,["0","divide by zero"])
*Main> runWriter $ noisy 6 `divA` noisy 3
(2,["6","3"])
*Main> runWriter $ noisy 6 `divA` noisy 0
(0,["6","0"])
*Main> runWriter $ undefined `divA` noisy 0
(0,*** Exception: Prelude.undefined
*Main> runWriter $ (tell ["undefined"] *> pure undefined) `divA` noisy 0
(0,["undefined","0"])
```

Note how with `divM`

, whether `numer`

's effects are included in `numer `divM` denom`

depends on the value of `denom`

(as does whether the effect of `tell ["divide by zero"]`

). With the best the applicative interface can do, the effects of `numer`

are always included in `numer`

divA`denom`

, even when lazy evaluation should mean that the *value* yielded by `numer`

is never inspected. And it's not possible to helpfully add "divide by 0" to the log when the denominator is zero.

^{1} I don't like to think of "combining effectful values" as the *definition* of that monads and applicatives do, but it's an *example* of what you can do with them.

^{2} When bottoms aren't involved, anyway; you should be able to see from my example why bottom can mess up the equivalence.

`(>>)`

does exist for applicatives and is called`(*>)`

so you can do`print "hello" *> print "world"`

– Lee Jun 28 at 14:40`do`

notation like that, since Applicative notation feels much purer and less cluttered. That proposal is the opposite of what I advise! – AndrewC Jun 28 at 15:33`doA`

– dfeuer Jun 28 at 21:06