### Proofs

In this blog post, Tekmo makes the point that we can prove that `ExitSuccess`

exits because (I presume) it's like the `Const`

functor for that constructor (it doesn't carry the `x`

so `fmap`

behaves like `const`

).

With the operational package, Tekmo's `TeletypeF`

might be translated something like this:

```
data TeletypeI a where
PutStrLn :: String -> TeletypeI ()
GetLine :: TeletypeI String
ExitSuccess :: TeletypeI ()
```

I've read that operational is isomorphic to a free monad, but can we prove here that `ExitSuccess`

exits? It seems to me that it suffers from exactly the same problem as `exitSuccess :: IO ()`

does, and in particular if we were to write an interpreter for it, we'd need to write it like as if it didn't exit:

```
eval (ExitSuccess :>>= _) = exitSuccess
```

Compare to the free monad version which doesn't involve any pattern wildcard:

```
run (Free ExitSuccess) = exitSuccess
```

### Laziness

In the Operational Monad Tutorial apfelmus mentions a drawback:

The state monad represented as s -> (a,s) can cope with some infinite programs like

`evalState (sequence . repeat . state $ \s -> (s,s+1)) 0`

whereas the list of instructions approach has no hope of ever handling that, since only the very last Return instruction can return values.

Is this true for free monads as well?

`Free (Coyoneda f)`

,`Coyoneda f`

is isomorphic to`f`

, so`Free (Coyoneda f)`

is isomorphic to`Free f`

.`Coyoneda Const a ~= Identity a`

, which is not isomorphic to`Const a`

.`Coyoneda (Const m) a`

is isomorphic to`Const m a`

which is isomorphic to`m`

.`data Foo a = Foo`

functor then`Coyoneda Foo a = exists b. (b -> a, Foo)`

which doesn't give you an extra element, since you don't have a`b`

to call the function with.3more comments