Stylistically this is very nice. In the real world, I would expect a 60% chance of this notation instead of the one you gave:

```
C x c >>= f = C (value $ f x) (c + 1)
```

But that is so minor it is hardly worth mentioning.

On a more serious note, not stylistic but semantic: this is not a monad. In fact, it violates all three of the monad laws.

```
(1) return x >>= f = f x
(2) m >>= return = m
(3) m >>= (f >=> g) = (m >>= f) >>= g
```

(Where `(>=>)`

is defined as `f >=> g = \x -> f x >>= g`

. If `(>>=)`

is considered an "application" operator, then `(>=>)`

is the corresponding composition operator. I like to state the third law using this operator because it brings out the third law's meaning: associativity.)

With these computations:

(1):

```
return 0 >>= return
= C 0 0 >>= return
= C (value $ return 0) 1
= C 0 1
Not equal to return 0 = C 0 0
```

(2):

```
C 0 0 >>= return
= C (value $ return 0) 1
= C 0 1
Not equal to C 0 0
```

(3)

```
C 0 0 >>= (return >=> return)
= C (value $ (return >=> return) 0) 1
= C (value $ return 0 >>= return) 1
= C (value $ C 0 1) 1
= C 0 1
Is not equal to:
(C 0 0 >>= return) >>= return
= C (value $ return 0) 1 >>= return
= C 0 1 >>= return
= C (value $ return 0) 2
= C 0 2
```

This isn't just an error in your implementation -- there is no monad that "counts the number of binds". It *must* violate laws (1) and (2). The fact that yours violates law (3) is an implementation error, however.

The trouble is that `f`

in the definition of `(>>=)`

might return an action that has more than one bind, and you are ignoring that. You need to *add* the number of binds from the left and right arguments:

```
C x c >>= f = C y (c+c'+1)
where
C y c' = f x
```

This will correctly count the number of binds, and will satisfy the third law, which is the associativity law. It won't satisfy the other two. However, if you drop the `+1`

from this definition, then you *do* get a real monad, which is equivalent to the `Writer`

monad over the `+`

monoid. This basically adds together the results of all subcomputations. You could use this to count the number of *somethings*, just not binds -- bind is too special to count. But, for example:

```
tick :: C ()
tick = C () 1
```

Then `C`

will count the number of `tick`

s that occurred in the computation.

In fact, you can replace `Int`

with any type and `(+)`

with any *associative* operator and get a monad. This is what a `Writer`

monad is in general. If the operator is not associative, then this will fail the third law (can you see why?).