# Does FreeT keep the equational reasoning benefits of Free?

In this blog post , the author explains the equational reasoning benefits of purifying code with the Free monad. Does the Free monad transformer FreeT retain these benefits, even if its wrapped over IO?

-

Yes. `FreeT` does not depend on any specific properties of the base monad, other than the fact that it is a monad. Every equation that you can deduce for `Free f` has an equivalent proof for `FreeT f m`.

To demonstrate that, let's repeat the exercise in my blog post, but this time using `FreeT`:

``````data TeletypeF x
= PutStrLn String x
| GetLine (String -> x)
| ExitSuccess
deriving (Functor)

type Teletype = FreeT TeletypeF

exitSuccess :: (Monad m) => Teletype m r
exitSuccess = liftF ExitSuccess
``````

``````return :: (Functor f, Monad m) => r -> FreeT f m r
return r = FreeT (return (Pure r))

(>>=) :: (Functor f, Monad m) => FreeT f m a -> (a -> FreeT f m b) -> FreeT f m b
m >>= f = FreeT \$ do
x <- runFreeT m
case x of
Free w -> return (Free (fmap (>>= f) w))
Pure r -> runFreeT (f r)

wrap :: (Functor f, Monad m) => f (FreeT f m r) -> FreeT f m r
wrap f = FreeT (return (Free f))

liftF :: (Functor f, Monad m) => f r -> FreeT f m r
liftF fr = wrap (fmap return fr)
``````

We can use equational reasoning to deduce what `exitSuccess` reduces to:

``````exitSuccess

-- Definition of 'exitSuccess'
= liftF ExitSuccess

-- Definition of 'liftF'
= wrap (fmap return ExitSuccess)

-- fmap f ExitSuccess = ExitSuccess
= wrap ExitSuccess

-- Definition of 'wrap'
= FreeT (return (Free ExitSuccess))
``````

Now we can reprove that `exitSuccess >> m` = `exitSuccess`:

``````exitSuccess >> m

-- m1 >> m2 = m1 >>= \_ -> m2
= exitSuccess >>= \_ -> m

-- exitSuccess = FreeT (return (Free ExitSuccess))
= FreeT (return (Free ExitSuccess)) >>= \_ -> m

= FreeT \$ do
x <- runFreeT \$ FreeT (return (Free ExitSuccess))
case x of
Free w -> return (Free (fmap (>>= (\_ -> m)) w))
Pure r -> runFreeT ((\_ -> m) r)

-- runFreeT (FreeT x) = x
= FreeT \$ do
x <- return (Free ExitSuccess)
case x of
Free w -> return (Free (fmap (>>= (\_ -> m)) w))
Pure r -> runFreeT ((\_ -> m) r)

-- do { y <- return x; m } = do { let y = x; m }
= FreeT \$ do
let x = Free ExitSuccess
case x of
Free w -> return (Free (fmap (>>= (\_ -> m)) w))
Pure r -> runFreeT ((\_ -> m) r)

-- Substitute in 'x'
= FreeT \$ do
case Free ExitSuccess of
Free w -> return (Free (fmap (>>= (\_ -> m)) w))
Pure r -> runFreeT ((\_ -> m) r)

-- First branch of case statement matches 'w' to 'ExitSuccess'
= FreeT \$ do
return (Free (fmap (>>= (\_ -> m)) ExitSuccess))

-- fmap f ExitSuccess = ExitSuccess
= FreeT \$ do
return (Free ExitSuccess)

-- do { m; } desugars to 'm'
= FreeT (return (Free ExitSuccess))

-- exitSuccess = FreeT (return (Free ExitSuccess))
= exitSuccess
``````

The `do` block in the proof belonged to the base monad, yet we never needed to use any specific source code or properties of the base monad in order to manipulate it equationally. The only property we needed to know was that it was a monad (any monad!) and obeyed the monad laws.

Using only the monad laws, we were still able to deduce that `exitSuccess >> m = exitSuccess`. That's the reason why the monad laws matter, because they allow us to reason about code over a polymorphic base monad, knowing only that it is a monad.

More generally, this is the reason that people say that type classes should always have associated laws (like the monad laws, or the functor laws, or the category laws), because these allow you to reason about code that uses that type class without consulting the specific instances of that type class. Without these kinds of laws, the type class interface wouldn't truly be a loosely coupled interface since you wouldn't be able to equationally reason about it without consulting the original instance source code.

Also, if you want an extra dose of category theory, we can easily prove that every property that holds for `Free` must also hold for `FreeT` if the base monad is polymorphic. All we have to do is prove that:

``````(forall m. (Monad m) => FreeT f m r) ~ Free f r
``````

The `~` symbol means "is isomorphic to", which means that we must prove that there are two functions, `fw`, and `bw`:

``````fw :: (forall m . (Monad m) => FreeT f m r) -> Free f r

bw :: Free f r -> (forall m . (Monad m) => FreeT f m r)
``````

... such that:

``````fw . bw = id

bw . fw = id
``````

It's an interesting proof, and I leave it as an exercise!

-