{-| Copyright : (C) 2013-2016, University of Twente 2017 , Google Inc. 2019 , Myrtle Software Ltd License : BSD2 (see the file LICENSE) Maintainer : Christiaan Baaij Whereas the output of a Mealy machine depends on /current transition/, the output of a Moore machine depends on the /previous state/. Moore machines are strictly less expressive, but may impose laxer timing requirements. -} {-# LANGUAGE FlexibleContexts #-} {-# LANGUAGE Safe #-} module Clash.Prelude.Moore ( -- * Moore machine moore , mooreB , medvedev , medvedevB ) where import qualified Clash.Explicit.Moore as E import Clash.Signal import Clash.XException (NFDataX) {- $setup >>> :set -XDataKinds -XTypeApplications >>> :m -Clash.Explicit.Prelude >>> :m -Clash.Explicit.Prelude.Safe >>> import Clash.Prelude >>> :{ let macT s (x,y) = x * y + s mac = moore macT id 0 :} -} -- | Create a synchronous function from a combinational function describing -- a moore machine -- -- @ -- macT -- :: Int -- Current state -- -> (Int,Int) -- Input -- -> Int -- Updated state -- macT s (x,y) = x * y + s -- -- mac -- :: HiddenClockResetEnable dom -- => 'Signal' dom (Int, Int) -- -> 'Signal' dom Int -- mac = 'moore' mac id 0 -- @ -- -- >>> simulate @System mac [(0,0),(1,1),(2,2),(3,3),(4,4)] -- [0,0,1,5,14,30,... -- ... -- -- Synchronous sequential functions can be composed just like their -- combinational counterpart: -- -- @ -- dualMac -- :: HiddenClockResetEnable dom -- => ('Signal' dom Int, 'Signal' dom Int) -- -> ('Signal' dom Int, 'Signal' dom Int) -- -> 'Signal' dom Int -- dualMac (a,b) (x,y) = s1 + s2 -- where -- s1 = 'moore' mac id 0 ('Clash.Signal.bundle' (a,x)) -- s2 = 'moore' mac id 0 ('Clash.Signal.bundle' (b,y)) -- @ moore :: ( HiddenClockResetEnable dom , NFDataX s ) => (s -> i -> s) -- ^ Transfer function in moore machine form: @state -> input -> newstate@ -> (s -> o) -- ^ Output function in moore machine form: @state -> output@ -> s -- ^ Initial state -> (Signal dom i -> Signal dom o) -- ^ Synchronous sequential function with input and output matching that -- of the moore machine moore = hideClockResetEnable E.moore {-# INLINE moore #-} -- | Create a synchronous function from a combinational function describing -- a moore machine without any output logic medvedev :: ( HiddenClockResetEnable dom , NFDataX s ) => (s -> i -> s) -> s -> (Signal dom i -> Signal dom s) medvedev tr st = moore tr id st {-# INLINE medvedev #-} -- | A version of 'moore' that does automatic 'Bundle'ing -- -- Given a functions @t@ and @o@ of types: -- -- @ -- __t__ :: Int -> (Bool, Int) -> Int -- __o__ :: Int -> (Int, Bool) -- @ -- -- When we want to make compositions of @t@ and @o@ in @g@ using 'moore', we have to -- write: -- -- @ -- g a b c = (b1,b2,i2) -- where -- (i1,b1) = 'Clash.Signal.unbundle' ('moore' t o 0 ('Clash.Signal.bundle' (a,b))) -- (i2,b2) = 'Clash.Signal.unbundle' ('moore' t o 3 ('Clash.Signal.bundle' (c,i1))) -- @ -- -- Using 'mooreB' however we can write: -- -- @ -- g a b c = (b1,b2,i2) -- where -- (i1,b1) = 'mooreB' t o 0 (a,b) -- (i2,b2) = 'mooreB' t o 3 (c,i1) -- @ mooreB :: ( HiddenClockResetEnable dom , NFDataX s , Bundle i , Bundle o ) => (s -> i -> s) -- ^ Transfer function in moore machine form: @state -> input -> newstate@ -> (s -> o) -- ^ Output function in moore machine form: @state -> output@ -> s -- ^ Initial state -> (Unbundled dom i -> Unbundled dom o) -- ^ Synchronous sequential function with input and output matching that -- of the moore machine mooreB = hideClockResetEnable E.mooreB {-# INLINE mooreB #-} -- | A version of 'medvedev' that does automatic 'Bundle'ing medvedevB :: ( HiddenClockResetEnable dom , NFDataX s , Bundle i , Bundle s ) => (s -> i -> s) -> s -> (Unbundled dom i -> Unbundled dom s) medvedevB tr st = mooreB tr id st {-# INLINE medvedevB #-}