{-# LANGUAGE MultiParamTypeClasses #-} {-# LANGUAGE FlexibleInstances #-} {-# LANGUAGE CPP #-} -- | A module that abstracts out monoidal actions. module Raaz.Core.MonoidalAction ( -- * Monoidal action -- $basics$ LAction (..), Distributive, SemiR (..), (<++>), semiRSpace, semiRMonoid -- ** Monoidal action on functors , LActionF(..), DistributiveF, TwistRF(..), twistFunctorValue, twistMonoidValue -- * Fields -- $fields$ , FieldA, FieldM, Field, computeField, runFieldM, liftToFieldM ) where import Control.Arrow import Control.Applicative import Data.Monoid ------------------ Actions and Monoidal actions ----------------------- -- $basics$ -- -- Consider any instance @l@ of a length unit as a monoid under -- addition. Length units acts on pointers by displacing them. It -- turns out that this action is crucial in abstracting out many -- pointer manipulations in our library. In particular, Applicative -- parsers, memory allocators and data serialisers can be abstractly -- captured using this action. -- -- We start with setting up some terminology. Our setting here is a -- space of points (captured by the type @space@) on which a monoid -- (captured by the type @m@) acts. The space which we are most -- interested in is the space of `CryptoPtr` and the monoid that act -- on it can be any instance of `LengthUnit` as described above. -- -- In this module, we consider /left/ actions of monoids, although -- right actions can be analogously defined as well. For applications -- we have in mind, namely for parsers etc, it is sufficient to -- restrict our attention to left actions. The left action will be -- written in multiplicative notation with the operator `<.>` being the -- multiplication. -- | A monoid @m@ acting on the left of a space. Think of a left -- action as a multiplication with the monoid. It should satisfy the -- law: -- -- > 1 <.> p = p -- identity -- > a <> b <.> p = a <.> b <.> p -- successive displacements -- class Monoid m => LAction m space where (<.>) :: m -> space -> space infixr 5 <.> -- | An alternate symbol for <> more useful in the additive context. (<++>) :: Monoid m => m -> m -> m (<++>) = (<>) infixr 5 <++> -- | Uniform action of a monoid on a functor. The laws that should -- be satisfied are: -- -- > 1 <<.>> fx = fx -- > (a <> b) <<.>> fx = a . (b <<.>> fx) -- > m <<.>> fmap f u = fmap f (m <<.>> u) -- acts uniformly class (Monoid m, Functor f) => LActionF m f where (<<.>>) :: m -> f a -> f a infixr 5 <<.>> ---------------------- The semi-direct products ------------------------ -- | A left-monoid action on a monoidal-space, i.e. the space on which -- the monoid acts is itself a monoid, is /distributive/ if it -- satisfies the law: -- -- > a <.> p <> q = (a <.> p) <> (a <.> q). -- -- The above law implies that every element @m@ is a monoid -- homomorphism. class (LAction m space, Monoid space) => Distributive m space -- | The semidirect product Space ⋊ Monoid. For monoids acting on -- monoidal spaces distributively the semi-direct product is itself a -- monoid. It turns out that data serialisers can essentially seen as -- a semidirect product. data SemiR space m = SemiR space !m #if MIN_VERSION_base(4,11,0) instance Distributive m space => Semigroup (SemiR space m) where (<>) (SemiR x a) (SemiR y b) = SemiR (x `mappend` (a <.> y)) (a `mappend` b) #endif instance Distributive m space => Monoid (SemiR space m) where mempty = SemiR mempty mempty {-# INLINE mempty #-} mappend (SemiR x a) (SemiR y b) = SemiR (x <++> a <.> y) (a <> b) {-# INLINE mappend #-} mconcat = foldr mappend mempty {-# INLINE mconcat #-} -- | From the an element of semi-direct product Space ⋊ Monoid return -- the point. semiRSpace :: SemiR space m -> space {-# INLINE semiRSpace #-} semiRSpace (SemiR space _) = space -- | From the an element of semi-direct product Space ⋊ Monoid return -- the monoid element. semiRMonoid :: SemiR space m -> m {-# INLINE semiRMonoid #-} semiRMonoid (SemiR _ m) = m --------------------------- Twisted functors ---------------------------- -- | The generalisation of distributivity to applicative -- functors. This generalisation is what allows us to capture -- applicative functors like parsers. For an applicative functor, and -- a monoid acting uniformly on it, we say that the action is -- distributive if the following laws are satisfied: -- -- > m <<.>> (pure a) = pure a -- pure values are stoic -- > m <<.>> (a <*> b) = (m <<.>> a) <*> (m <<.>> b) -- dist class (Applicative f, LActionF m f) => DistributiveF m f -- | The twisted functor is essentially a generalisation of -- semi-direct product to applicative functors. data TwistRF f m a = TwistRF (f a) !m -- | Get the underlying functor value. twistFunctorValue :: TwistRF f m a -> f a twistFunctorValue (TwistRF fa _) = fa {-# INLINE twistFunctorValue #-} -- | Get the underlying monoid value. twistMonoidValue :: TwistRF f m a -> m twistMonoidValue (TwistRF _ m) = m {-# INLINE twistMonoidValue #-} instance Functor f => Functor (TwistRF f m) where fmap f (TwistRF x m) = TwistRF (fmap f x) m -- Proof of functor laws. -- -- fmap id (TwistRF (x, m)) = TwistRF (fmap id x, m) -- = TwistRF (x, m) -- -- fmap (f . g) (TwistRF fx m) = TwistRF (fmap (f . g) x, m) -- = TwistRF (fmap f . fmap g $ x, m) -- = TwistRF (fmap f (fmap g x), m) -- = fmap f $ TwistRF (fmap g x, m) -- = (fmap f . fmap g) (TwistRF fx) m) -- instance DistributiveF m f => Applicative (TwistRF f m) where pure a = TwistRF (pure a) mempty {-# INLINE pure #-} (TwistRF f mf) <*> (TwistRF val mval) = TwistRF res mres where res = f <*> mf <<.>> val mres = mf <> mval -- Consider an expression @u = u1 <*> u2 <*> ... <ur>@ where -- ui = TwistRF fi mi -- -- u = TwistRF f m where m = m1 <> m2 <> .. <> mr -- f = f1 <*> m1 f2 <*> (m1 m2) f3 ... <*> (m1 m2 .. mr-1) fr. -- -- We will separately verify the functor part and the monoid -- part of the ofNow we can verify the laws of applicative -- -- ------------------------- A generic field ----------------------------------- -- $fields$ -- -- The main goal behind looking at monoidal actions are to captures -- concrete objects of interest to us like parsers, serialisers and -- memory allocators. These are essentially functions with domain -- `CryptoPtr`. For example, a parser is a function that takes a -- `CryptoPtr`, reads @n@ bytes say and produces a result a. To -- sequence the next parse we need to essentially keep track of this -- @n@. If we abstract this out to the general setting we need to -- consider functions whose domain is the space of points. We use the -- physicist's terminology and call them fields. The action of the -- monoid on a space of points naturally extends to fields on them -- -- @F^g = λ x -> F (x^g) @ -- -- For our applications, we need to define generalised fields -- associated with arrows. This is because we often have to deal with -- functions that have side effects (i.e. `Kleisli` arrows). However, -- for conceptual understanding, it is sufficient to stick to ordinary -- functions. In fact, the informal proofs that we have scattered in -- the source all have been written only for the arrow @->@. -- | A field on the space is a function from the points in the space -- to some value. Here we define it for a general arrow. type FieldA arrow = WrappedArrow arrow -- | A field where the underlying arrow is the (->). This is normally -- what we call a field. type Field = FieldA (->) -- | Compute the value of a field at a given point in the space. computeField :: Field space b -> space -> b computeField = unwrapArrow {-# INLINE computeField #-} -- | A monadic arrow field. type FieldM monad = FieldA (Kleisli monad) -- | Lift a monadic action to FieldM. liftToFieldM :: (a -> m b) -> FieldM m a b liftToFieldM = WrapArrow . Kleisli {-# INLINE liftToFieldM #-} -- | Runs a monadic field at a given point in the space. runFieldM :: FieldM monad space b -> space -> monad b runFieldM = runKleisli . unwrapArrow {-# INLINE runFieldM #-} -- | The action on the space translates to the action on field. instance (Arrow arrow, LAction m space) => LActionF m (WrappedArrow arrow space) where m <<.>> field = WrapArrow $ unwrapArrow field <<^ (m<.>) {-# INLINE (<<.>>) #-} instance (Arrow arrow, LAction m space) => DistributiveF m (WrappedArrow arrow space)