This post is literate Haskell. Just put in a file like "pad.lhs" and `ghci`

will be able to run it.

```
> {-# LANGUAGE GADTs, Rank2Types #-}
> import Control.Monad
> import Control.Monad.ST
> import Data.STRef
```

Okay, so I was able to figure how to represent the `ST`

monad in pure code. First we start with our reference type. Its specific value is not really important. The most important thing is that `PT s a`

should not be isomorphic to any other type `forall s`

. (In particular, it should be isomorphic to neither `()`

nor `Void`

.)

```
> newtype PTRef s a = Ref {unref :: s a} -- This is defined liked this to make `toST'` work. It may be given a different definition.
```

The kind for `s`

is `*->*`

, but that is not really important right now. It could be polykind, for all we care.

```
> data PT s a where
> MkRef :: a -> PT s (PTRef s a)
> GetRef :: PTRef s a -> PT s a
> PutRef :: a -> PTRef s a -> PT s ()
> AndThen :: PT s a -> (a -> PT s b) -> PT s b
```

Pretty straight forward. `AndThen`

allows us to use this as a `Monad`

. You may be wondering how `return`

is implemented. Here is its monad instance (it only respects monad laws with respect to `runPF`

, to be defined later):

```
> instance Monad (PT s) where
> (>>=) = AndThen
> return a = AndThen (MkRef a) GetRef --Sorry. I like minimalism.
> instance Functor (PT s) where
> fmap = liftM
> instance Applicative (PT s) where
> pure = return
> (<*>) = ap
```

Now we can define `fib`

as a test case.

```
> fib :: Int -> PT s Integer
> fib n = do
> rold <- MkRef 0
> rnew <- MkRef 1
> replicateM_ n $ do
> old <- GetRef rold
> new <- GetRef rnew
> PutRef new rold
> PutRef (old+new) rnew
> GetRef rold
```

And it type checks. Hurray! Now, I was able to convert this to `ST`

(we now see why `s`

had to be `* -> *`

)

```
> toST :: PT (STRef s) a -> ST s a
> toST (MkRef a ) = fmap Ref $ newSTRef a
> toST (GetRef (Ref r)) = readSTRef r
> toST (PutRef a (Ref r)) = writeSTRef r a
> toST (pa `AndThen` apb) = (toST pa) >>= (toST . apb)
```

Now we can define a function to run `PT`

without referencing `ST`

at all:

```
> runPF :: (forall s. PT s a) -> a
> runPF p = runST $ toST p
```

`runPF $ fib 7`

gives `13`

, which is correct.

## My question is can we define `runPF`

without reference using `ST`

at all?

Is there a pure way to define `runPF`

? `PTRef`

's definition is completely unimportant; it's only a placeholder type anyway. It can be redefined to whatever makes it work.

If you *cannot* define `runPF`

purely, give a proof that it cannot.

Performance is not a concern (if it was, I would not have made every `return`

have its own ref).

I'm thinking that existential types may be useful.

Note: It's trivial if we assume is `a`

is dynamicable or something. I'm looking for an answer that works with all `a`

.

Note: In fact, an answer does not even necessarily have much to do with `PT`

. It just needs to be as powerful as `ST`

without using magic. (Conversion from `(forall s. PT s)`

is sort of a test of if an answer is valid or not.)

`s ~ Const Int`

in`runPF`

and keep a`Map`

with`Int`

keys and`a`

values. – David Young Nov 28 '15 at 19:28`Typeable a`

in each`PT s a`

? If so, it's a matter of adapting IOSpec, I guess. – chi Nov 28 '15 at 19:30`Typeable`

, a`Map Int Dynamic`

should suffice to represent the`STRef`

s backstore. Reads/writes will need to be implemented through partial (but pure) functions, in that case. – chi Nov 28 '15 at 19:342more comments