I've been thinking about this idea for some time, which I'd call **mutable lenses**. So far, I haven't made it into a package, let me know, if you'd benefit from it.

First let's recall the generalized van Laarhoven Lenses (after some imports we'll need later):

```
{-# LANGUAGE RankNTypes #-}
import qualified Data.ByteString as BS
import Data.Functor.Constant
import Data.Functor.Identity
import Data.Traversable (Traversable)
import qualified Data.Traversable as T
import Control.Monad
import Control.Monad.STM
import Control.Concurrent.STM.TVar
type Lens s t a b = forall f . (Functor f) => (a -> f b) -> (s -> f t)
type Lens' s a = Lens s s a a
```

we can create such a lens from a "getter" and a "setter" as

```
mkLens :: (s -> a) -> (s -> b -> t) -> Lens s t a b
mkLens g s f x = fmap (s x) (f (g x))
```

and get a "getter"/"setter" from a lens back as

```
get :: Lens s t a b -> (s -> a)
get l = getConstant . l Constant
set :: Lens s t a b -> (s -> b -> t)
set l x v = runIdentity $ l (const $ Identity v) x
```

as an example, the following lens accesses the first element of a pair:

```
_1 :: Lens' (a, b) a
_1 = mkLens fst (\(x, y) x' -> (x', y))
-- or directly: _1 f (a,c) = (\b -> (b,c)) `fmap` f a
```

Now how a **mutable lens** should work? Getting some container's content involves a monadic action. And setting a value doesn't change the container, it remains the same, just as a mutable piece of memory does. So the result of a mutable lens will have to be monadic, and instead of the return type container `t`

we'll have just `()`

. Moreover, the `Functor`

constraint isn't enough, since we need to interleave it with monadic computations. Therefore, we'll need `Traversable`

:

```
type MutableLensM m s a b
= forall f . (Traversable f) => (a -> f b) -> (s -> m (f ()))
type MutableLensM' m s a
= MutableLensM m s a a
```

(`Traversable`

is to monadic computations what `Functor`

is to pure computations).

Again, we create helper functions

```
mkLensM :: (Monad m) => (s -> m a) -> (s -> b -> m ())
-> MutableLensM m s a b
mkLensM g s f x = g x >>= T.mapM (s x) . f
mget :: (Monad m) => MutableLensM m s a b -> s -> m a
mget l s = liftM getConstant $ l Constant s
mset :: (Monad m) => MutableLensM m s a b -> s -> b -> m ()
mset l s v = liftM runIdentity $ l (const $ Identity v) s
```

As an example, let's create a mutable lens from a `TVar`

within `STM`

:

```
alterTVar :: MutableLensM' STM (TVar a) a
alterTVar = mkLensM readTVar writeTVar
```

These lenses are one-sidedly directly composable with `Lens`

, for example

```
alterTVar . _1 :: MutableLensM' STM (TVar (a, b)) a
```

**Notes:**

Mutable lenses could be made more powerful if we allow that the modifying function to include effects:

```
type MutableLensM2 m s a b
= (Traversable f) => (a -> m (f b)) -> (s -> m (f ()))
type MutableLensM2' m s a
= MutableLensM2 m s a a
mkLensM2 :: (Monad m) => (s -> m a) -> (s -> b -> m ())
-> MutableLensM2 m s a b
mkLensM2 g s f x = g x >>= f >>= T.mapM (s x)
```

However, it has two major drawbacks:

- It isn't composable with pure
`Lens`

.
- Since the inner action is arbitrary, it allows you to shoot yourself in the foot by mutating this (or other) lens during the mutating operation itself.

There are other possibilities for monadic lenses. For example, we can create a monadic copy-on-write lens that preserves the original container (just as `Lens`

does), but where the operation involves some monadic action:

```
type LensCOW m s t a b
= forall f . (Traversable f) => (a -> f b) -> (s -> m (f t))
```

I've made jLens - a Java library for mutable lenses, but the API is of course far from being as nice as Haskell lenses.