----------------------------------------------------------------------------- -- | -- Module : ForSyDe.Shallow.MoC.Dataflow -- Copyright : (c) ForSyDe Group, KTH 2007-2008 -- License : BSD-style (see the file LICENSE) -- -- Maintainer : forsyde-dev@ict.kth.se -- Stability : experimental -- Portability : portable -- -- The dataflow library defines data types, process constructors and -- functions to model dataflow process networks, as described by Lee and -- Parks in Dataflow process networks, IEEE Proceedings, 1995 ([LeeParks95]). -- -- Each process is defined by a set of firing rules and corresponding -- actions. A process fires, if the incoming signals match a firing -- rule. Then the process consumes the matched tokens and executes the -- action corresponding to the firing rule. -- ----------------------------------------------------------------------------- module ForSyDe.Shallow.MoC.Dataflow ( -- * Data Types -- | The data type @FiringToken@ defines the data type for tokens. The -- constructor @Wild@ constructs a token wildcard, the constructor -- @Value a@ constructs a token with value @a@. -- -- A sequence (pattern) matches a signal, if the sequence is a prefix of -- the signal. The following list illustrates the firing rules: -- -- * [⊥] matches always (/NullS/ in ForSyDe) -- -- * [*] matches signal with at least one token (/[Wild]/ in ForSyDe) -- -- * [v] matches signal with v as its first value (/[Value v]/ in ForSyDe) -- -- * [*,*] matches signals with at least two tokens (/[Wild,Wild]/ in ForSyDe) -- FiringToken(Wild, Value), -- * Combinational Process Constructors -- | Combinatorial processes -- do not have an internal state. This means, that the output -- signal only depends on the input signals. -- -- To illustrate the concept of data flow processes, we create a -- process that selects tokens from two inputs according to a -- control signal. -- -- The process has the following firing rules [LeeParks95]: -- -- -- * R1 = {[*], ⊥, [T]} -- -- * R2 = {⊥, [*], [F]} -- -- -- The corresponding ForSyDe formulation of the firing rules is: -- -- @ -- selectRules = [ ([Wild], [], [Value True]), -- ([], [Wild], [Value False]) ] -- @ -- -- For the output we formulate the following set of output functions: -- -- @ -- selectOutput xs ys _ = [ [headS xs], [headS ys] ] -- @ -- -- The select process /selectDF/ is then defined by: -- -- @ -- selectDF :: Eq a => Signal a -> Signal a -- -> Signal Bool -> Signal a -- selectDF = zipWith3DF selectRules selectOutput -- @ -- -- Given the signals /s1/, /s2/ and /s3/ -- -- @ -- s1 = signal [1,2,3,4,5,6] -- s2 = signal [7,8,9,10,11,12] -- s3 = signal [True, True, False, False, True, True] -- @ -- -- the executed process gives the following results: -- -- @ -- DataflowLib> selectDF s1 s2 s3 -- {1,2,7,8,3,4} :: Signal Integer -- @ -- -- The library contains the following combinational process -- constructors: mapDF, zipWithDF, zipWith3DF, -- * Sequential Process Constructors -- | Sequential processes have -- an internal state. This means, that the output signal may -- depend internal state and on the input signal. -- -- As an example we can view a process calculating the running sum -- of the input tokens. It has only one firing rule, which is -- illustrated below. -- -- @ -- Firing Rule Next State Output -- ------------------------------------ -- (*,[*]) state + x {state} -- @ -- -- A dataflow process using these firing rules and the initial state -- 0 can be formulated in ForSyDe as -- -- @ -- rs xs = mealyDF firingRule nextState output initState xs -- where -- firingRule = [(Wild, [Wild])] -- nextState state xs = [(state + headS xs)] -- output state _ = [[state]] -- initState = 0 -- @ -- -- Execution of the process gives -- -- @ -- DataflowLib> rs (signal[1,2,3,4,5,6]) -- {0,1,3,6,10,15} :: Signal Integer -- @ -- -- Another 'running sum' process /rs2/ takes two tokens, pushes -- them into a queue of five elements and calculates the sum as -- output. -- -- @ -- rs2 = mealyDF fs ns o init -- where -- init = [0,0,0,0,0] -- fs = [(Wild, ([Wild, Wild]))] -- ns state xs = [drop 2 state ++ fromSignal (takeS 2 xs)] -- o state _ = [[(sum state)]] -- @ -- -- Execution of the process gives -- -- @ -- DataflowLib>rs2 (signal [1,2,3,4,5,6,7,8,9,10]) -- {0,3,10,20,30} :: Signal Integer -- @ scanlDF, mooreDF, mealyDF ) where import ForSyDe.Shallow.Core ------------------------------------------------------------------------ -- DATA TYPES ------------------------------------------------------------------------ data FiringToken a = Wild | Value a deriving (Eq, Show) ------------------------------------------------------------------------ -- COMBINATIONAL PROCESS CONSTRUCTORS ------------------------------------------------------------------------ -- |The process constructor @mapDF@ takes a list of firing rules, a -- list of corresponding output functions and generates a data flow -- process with one input and one output signal. mapDF :: Eq a => [[FiringToken a]] -> (Signal a -> [[b]]) -> Signal a -> Signal b mapDF _ _ NullS = NullS mapDF rs as xs = output +-+ mapDF rs as xs' where xs' = if matchedRule < 0 then NullS else consumeDF rule xs matchedRule = (matchDF rs xs) rule = rs !! matchedRule output = if matchedRule < 0 then NullS else signal ((as xs) !! matchedRule) -- |The process constructors @zipWithDF@ takes a list of firing rules, -- a list of corresponding output functions to generate a data flow -- process with two input signals and one output signal. zipWithDF :: (Eq a, Eq b) => [([FiringToken b], [FiringToken a])] -> (Signal b -> Signal a -> [[c]]) -> Signal b -> Signal a -> Signal c zipWithDF _ _ NullS NullS = NullS zipWithDF rs as xs ys = output +-+ zipWithDF rs as xs' ys' where (xs', ys') = if matchedRule < 0 then (NullS, NullS) else consume2DF rule xs ys matchedRule = (match2DF rs xs ys) rule = rs !! matchedRule output = if matchedRule < 0 then NullS else signal ((as xs ys) !! matchedRule) -- |The process constructors @zipWith3DF@ takes a list of firing -- rules, a list of corresponding output functions to generate a data -- flow process with three input signals and one output signal. zipWith3DF :: (Eq a, Eq b, Eq c) => [([FiringToken a],[FiringToken b],[FiringToken c])] -> (Signal a -> Signal b -> Signal c -> [[d]]) -> Signal a -> Signal b -> Signal c -> Signal d zipWith3DF _ _ NullS NullS NullS = NullS zipWith3DF rs as xs ys zs = output +-+ zipWith3DF rs as xs' ys' zs' where (xs', ys', zs') = if matchedRule < 0 then (NullS, NullS, NullS) else consume3DF rule xs ys zs matchedRule = (match3DF rs xs ys zs) rule = rs !! matchedRule output = if matchedRule < 0 then NullS else signal ((as xs ys zs) !! matchedRule) ------------------------------------------------------------------------ -- SEQUENTIAL PROCESS CONSTRUCTORS ------------------------------------------------------------------------ -- | The process constructor @scanlDF@ implements a finite state -- machine without output decoder in the ForSyDe methodology. It takes -- a set of firing rules and a set of corresponding next state -- functions as arguments. A firing rule is a tuple. The first value -- is a pattern for the state, the second value corresponds to an -- input pattern. When a pattern matches, the process fires, the -- corresponding next state is executed, and the tokens matching the -- pattern are consumed. scanlDF :: (Eq a, Eq b) => [(FiringToken b,[FiringToken a])] -> (b -> Signal a -> [b]) -> b -> Signal a -> Signal b scanlDF _ _ _ NullS = NullS scanlDF fs ns state xs = (unitS state) +-+ scanlDF fs ns state' xs' where xs' = if matchedRule < 0 then NullS else consumeDF rule xs matchedRule = matchStDF fs state xs rule = snd (fs !! matchedRule) state' = if matchedRule < 0 then error "No rule matches the pattern!" else (ns state xs) !! matchedRule -- | The process constructor @mooreDF@ implements a Moore finite state -- machine in the ForSyDe methodology. It takes a set of firing rules, -- a set of corresponding next state functions and a set of output -- functions as argument. A firing rule is a tuple. The first value is -- a pattern for the state, the second value corresponds to an input -- pattern. When a pattern matches, the process fires, the -- corresponding next state and output functions are executed, and the -- tokens matching the pattern are consumed. mooreDF :: (Eq a, Eq b) => [(FiringToken b,[FiringToken a])] -> (b -> Signal a -> [b]) -> (b -> [c]) -> b -> Signal a -> Signal c mooreDF _ _ _ _ NullS = NullS mooreDF fs ns o state xs = output +-+ mooreDF fs ns o state' xs' where xs' = if matchedRule < 0 then NullS else consumeDF rule xs matchedRule = matchStDF fs state xs rule = snd (fs !! matchedRule) output = signal (o state) state' = if matchedRule < 0 then error "No rule matches the pattern!" else (ns state xs) !! matchedRule -- | The process constructor @mealyDF@ implements the most general -- state machine in the ForSyDe methodology. It takes a set of firing -- rules, a set of corresponding next state functions and a set of -- output functions as argument. A firing rule is a tuple. The first -- value is a pattern for the state, the second value corresponds to -- an input pattern. When a pattern matches, the process fires, the -- corresponding next state and output functions are executed, and the -- tokens matching the pattern are consumed. mealyDF :: (Eq a, Eq b) => [(FiringToken b,[FiringToken a])] -> (b -> Signal a -> [b]) -> (b -> Signal a -> [[c]]) -> b -> Signal a -> Signal c mealyDF _ _ _ _ NullS = NullS mealyDF fs ns o state xs = output +-+ mealyDF fs ns o state' xs' where xs' = if matchedRule < 0 then NullS else consumeDF rule xs matchedRule = matchStDF fs state xs rule = snd (fs !! matchedRule) output = signal ((o state xs) !! matchedRule) state' = if matchedRule < 0 then error "No rule matches the pattern!" else (ns state xs) !! matchedRule ------------------------------------------------------------------------ -- SUPPORTING FUNCTIONS ------------------------------------------------------------------------ -- The function 'prefixDF' takes a pattern and a signal and returns -- 'True', if the pattern is a prefix from the signal. prefixDF :: Eq a => [FiringToken a] -> Signal a -> Bool prefixDF [] _ = True prefixDF _ NullS = False prefixDF (Wild:ps) (_:-xs) = prefixDF ps xs prefixDF ((Value p):ps) (x:-xs) = if p == x then prefixDF ps xs else False -- The function 'consumeDF' takes a pattern and a signal and consumes -- the pattern from the signal. The functions 'consume2DF' and -- 'consume3DF' work in the same way as 'consumeDF', but with two and -- three input signals. consumeDF :: Eq a => [FiringToken a] -> Signal a -> Signal a consumeDF _ NullS = NullS consumeDF [] xs = xs consumeDF (Wild:ts) (_:-xs) = consumeDF ts xs consumeDF (Value t:ts) (x:-xs) = if t == x then consumeDF ts xs else error "Tokens not correct" consume2DF :: (Eq a, Eq b) => ([FiringToken a], [FiringToken b]) -> Signal a -> Signal b -> (Signal a, Signal b) consume2DF (px, py) xs ys = (consumeDF px xs, consumeDF py ys) consume3DF :: (Eq a, Eq b, Eq c) => ([FiringToken a], [FiringToken b], [FiringToken c]) -> Signal a -> Signal b -> Signal c -> (Signal a,Signal b,Signal c) consume3DF (px, py, pz) xs ys zs = (consumeDF px xs, consumeDF py ys, consumeDF pz zs) -- The function 'matchDF' checks, which firing rule, starting from 0, is -- matched by the input signal. If no firing rule matches, the output is -- '-1'. The functions 'maptch2S' and 'match3DF' work in the same way -- for two and three inputs. matchDF :: (Num a, Eq b) => [[FiringToken b]] -> Signal b -> a matchDF rs xs = matchDF' 0 rs xs where matchDF' _ [] _ = -1 matchDF' n (r:rs) xs = if prefixDF r xs then n else matchDF' (n+1) rs xs match2DF :: (Num a, Eq b, Eq c) => [([FiringToken b], [FiringToken c])] -> Signal b -> Signal c -> a match2DF rs xs ys = match2DF' 0 rs xs ys where match2DF' _ [] _ _ = -1 match2DF' n ((rx, ry):rs) xs ys = if prefixDF rx xs && prefixDF ry ys then n else match2DF' (n+1) rs xs ys match3DF :: (Num a, Eq b, Eq c, Eq d) => [([FiringToken b], [FiringToken d], [FiringToken c])] -> Signal b -> Signal d -> Signal c -> a match3DF rs xs ys zs = match3DF' 0 rs xs ys zs where match3DF' _ [] _ _ _ = -1 match3DF' n ((rx, ry, rz):rs) xs ys zs = if prefixDF rx xs && prefixDF ry ys && prefixDF rz zs then n else match3DF' (n+1) rs xs ys zs -- The function 'matchStDF' works in the same way as 'matchDF', but it -- looks on patterns that include the state. matchStDF :: (Num a, Eq b, Eq c) => [(FiringToken c,[FiringToken b])] -> c -> Signal b -> a matchStDF rs state xs = matchStDF' 0 rs state xs where matchStDF' _ [] _ _ = -1 matchStDF' n (r:rs) state xs = if prefixDF (snd r) xs && matchState (fst r) state then n else matchStDF' (n+1) rs state xs matchState :: Eq a => FiringToken a -> a -> Bool matchState Wild _ = True matchState (Value v) x = x == v ------------------------------------------------------------------------ -- -- CODE FOR TESTING -- ------------------------------------------------------------------------ {- selectRules :: [([FiringToken a], [FiringToken a1], [FiringToken Bool])] selectRules = [ ([Wild], [], [Value True]), ([], [Wild], [Value False]) ] selectOutput :: Signal t1 -> Signal t1 -> t -> [[t1]] selectOutput xs ys _ = [ [headS xs], [headS ys] ] selectDF :: Eq a => Signal a -> Signal a -> Signal Bool -> Signal a selectDF = zipWith3DF selectRules selectOutput s1 :: Signal Integer s1 = signal [1,2,3,4,5,6] s2 :: Signal Integer s2 = signal [7,8,9,10,11,12] s3 :: Signal Bool s3 = signal [True, True, False, False, True, True] rs :: (Eq c, Num c) => Signal c -> Signal c rs xs = mealyDF firingRule nextState output initState xs where firingRule = [(Wild, [Wild])] nextState state xs = [(state + headS xs)] output state _ = [[state]] initState = 0 rs2 :: Signal Integer -> Signal Integer rs2 = mealyDF fs ns o init where init = [0,0,0,0,0] fs = [(Wild, ([Wild, Wild]))] ns state xs = [drop 2 state ++ fromSignal (takeS 2 xs)] o state _ = [[(sum state)]] -}