For the counterexample, let us first define a new data type, for which we generate traversals using `makePrisms`

:

```
data T = A T | C deriving Show
makePrisms ''T
```

`_A :: Traversal T T`

is now a valid traversal. Now, construct a new traversal using `failing`

:

```
t :: Traversal' T T
t = failing _A id
```

Notice that `(C & t .~ A C) ^.. t = [C]`

, which looks like it fails a traversal law (you don't "get what you put in"). Indeed, the second traversal law is:

```
fmap (t f) . t g ≡ getCompose . t (Compose . fmap f . g)
```

which is not satisfied, as can be seen with the following choice for `f`

and `g`

:

```
-- getConst . t f = toListOf t
f :: T -> Const [T] T
f = Const . (:[])
-- runIdentity . t g = t .~ A C
g :: T -> Identity T
g = pure . const (A C)
```

Then:

```
> getConst . runIdentity . fmap (t f) . t g $ C
[C]
```

While:

```
> getConst . runIdentity . getCompose . t (Compose . fmap f . g) $ C
[A C]
```

So there is indeed a case where `failing`

with valid traversals doesn't produce a valid traversal.