When use `Data.Traversable`

I frequently requires some code like

```
import Control.Applicative (Applicative,(<*>),pure)
import Data.Traversable (Traversable,traverse,sequenceA)
import Control.Monad.State (state,runState)
traverseF :: Traversable t => ((a,s) -> (b,s)) -> (t a, s) -> (t b, s)
traverseF f (t,s) = runState (traverse (state.curry f) t) s
```

to traverse the structure and build up a new one driven by some state. And I notice the type signature pattern and believe it could be able to generalized as

```
fmapInner :: (Applicative f,Traversable t) => (f a -> f b) -> f (t a) -> f (t b)
fmapInner f t = ???
```

But I fail to implement this with just `traverse`

, `sequenceA`

, `fmap`

, `<*>`

and `pure`

. Maybe I need stronger type class constrain? Do I absolutely need a `Monad`

here?

**UPDATE**

Specifically, I want to know if I can define `fmapInner`

for a `f`

that work for any `Traversable t`

and some laws for intuition applied (I don't know what the laws should be yet), is it imply that the `f`

thing is a `Monad`

? Since, for `Monad`

s the implementation is trivial:

```
--Monad m implies Applicative m but we still
-- have to say it unless we use mapM instead
fmapInner :: (Monad m,Traversable t) => (m a -> m b) -> m (t a) -> m (t b)
fmapInner f t = t >>= Data.Traversable.mapM (\a -> f (return a))
```

**UPDATE**

Thanks for the excellent answer. I have found that my `traverseF`

is just

```
import Data.Traversable (mapAccumL)
traverseF1 :: Traversable t => ((a, b) -> (a, c)) -> (a, t b) -> (a, t c)
traverseF1 =uncurry.mapAccumL.curry
```

without using Monad.State explicitly and have all pairs flipped. Previously I though it was `mapAccumR`

but it is actually `mapAccumL`

that works like `traverseF`

.

`fmapInner`

looks substantially different from the type of`traverseF`

to me. Perhaps you would prefer`foo :: (a -> f b) -> (t a -> f (t b))`

or some such thing, in which case it's just`traverse`

. Then`f`

can specialize to`State s`

and give you essentially the type of`traverseF`

. – Daniel Wagner Oct 11 '13 at 0:39`f a -> f b`

and then use it to convert a`f (t a)`

into`f (t b)`

, and it looks like there is no good way to do so unless I assume`f`

is a`Monad`

. – Earth Engine Oct 11 '13 at 0:55`Applicative`

instance for`((,) s)`

is (we have to put`s`

first since we don't have`flip`

defined for types)? – Cirdec Oct 11 '13 at 1:03`((,) s)`

is currently an instance of`Applicative`

, but if you want we can define a`newtype`

to instantiate it. The point is about the type signature pattern, not the specific types. – Earth Engine Oct 11 '13 at 1:12