Good day, ladies and gentlemen!
I'm constantly writing parsers and codecs. Implementing both parsers and printers seems to be massive code duplication. I wonder whether it is possible to invert a stateful computation, given it is isomorphic by nature.
It is possible to invert pure function composition (Control.Lens.Iso did that by defining a composition operator over isomorphisms). As it can be observed,
Iso bc cb . Iso ab ba = Iso (bc . ab) (ba . cb) -- from Lenses talk invert (f . g) = (invert g) . (invert f) -- pseudo-code
In other words, to invert a function composition one should compose inverted functions in the opposite order. So, given all primitive isomorphic pairs are defined, one can compose them to get more complicated pairs with no code duplication. Here is an example of pure bidirectional computation (Control.Lens is used, the explanatory video can help you to get the general idea of Lenses, Folds and Traversals):
import Control.Lens tick :: Num a => Iso' a a tick = iso (+1) (subtract 1) -- define an isomorphic pair double :: Num a => Iso' a a double = iso (+2) (subtract 2) -- and another one threeTick :: Num a => Iso' a a -- These are composed via simple function composition! threeTick = double . tick main :: IO () main = do print $ (4 :: Int)^.tick -- => 5 print $ (4 :: Int)^.from tick -- => 3 print $ (4 :: Int)^.threeTick -- => 7, Composable print $ (4 :: Int)^.from threeTick -- => 1, YEAH
As you can see, I didn't need to supply the inverted version of
threeTick; it is obtained by backward composition automatically!
Now, let's consider a simple parser.
data FOO = FOO Int Int deriving Show parseFoo :: Parser FOO parseFoo = FOO <$> decimal <* char ' ' <*> decimal parseFoo' :: Parser FOO parseFoo' = do first <- decimal void $ char ' ' second <- decimal return $ FOO first second printFoo :: FOO -> BS.ByteString printFoo (FOO a b) = BS.pack(show a) <> BS.pack(" ") <> BS.pack(show b) main :: IO () main = do print $ parseOnly parseFoo "10 11" -- => Right (FOO 10 11) print $ parseOnly parseFoo' "10 11" -- => Right (FOO 10 11) print . printFoo $ FOO 10 11 -- => "10 11" print . parseOnly parseFoo . printFoo $ FOO 10 11 -- id
You can see that both versions of
parseFoo are fairly declarative (thanks to parser combinators). Note the similarity between
printFoo. Can I define isomorphisms over primitive parsers (
char) and then just derive the printer (
printFoo :: FOO -> String) automatically? Ideally, parser combinators will work as well.
I tried to redefine a monadic
>>= operator in order to provide inverted semantics, but I've failed to do so. I feel that one could define inverted Kleisli composition operator (monadic function composition) similarly to composition inversion, but can one use it with ordinary monads?
f :: a -> m b, inverse f :: b -> m a g :: b -> m c, inverse g :: c -> m b inverse (f >=> g) = (inverse f) <=< (inverse g)
inverse f is of type
b -> m a and not
m b -> a? The answer is: monadic side effect is an attribute of an arrow, not that of a data type
b. The state monad dualization is further discussed in the great Expert to Expert video.
If the solution does exist, could you please supply a working example of
printFoo derivation? By the way, here is an interesting paper that could help us find the solution.