import Types
import Data.Param.TFVec
--- mainIO f = Sim.simulateIO (Sim.stateless f) ()
+mainIO f = Sim.simulateIO (Sim.stateless f) ()
-- This function is from Sim.hs, but we redefine it here so it can get inlined
-- by default.
--- stateless :: (i -> o) -> (i -> () -> ((), o))
--- stateless f = \i s -> (s, f i)
---
--- show_add f = do print ("Sum: " ++ (displaysigs s)); print ("Carry: " ++ (displaysig c))
--- where
--- a = [High, High, High, High]
--- b = [Low, Low, Low, High]
--- (s, c) = f (a, b)
---
--- mux2 :: Bit -> (Bit, Bit) -> Bit
--- mux2 Low (a, b) = a
--- mux2 High (a, b) = b
+stateless :: (i -> o) -> (i -> () -> ((), o))
+stateless f = \i s -> (s, f i)
+
+show_add f = do print ("Sum: " P.++ (displaysigs s)); print ("Carry: " P.++ (displaysig c))
+ where
+ a = [High, High, High, High]
+ b = [Low, Low, Low, High]
+ (s, c) = f (a, b)
+
+mux2 :: Bit -> (Bit, Bit) -> Bit
+mux2 Low (a, b) = a
+mux2 High (a, b) = b
-- Not really an adder, but this is nice minimal hardware description
--- wire :: Bit -> Bit
--- wire a = a
+wire :: Bit -> Bit
+wire a = a
-- bus :: (TypeLevel.Pos len) => BitVec len -> BitVec len
--- bus v = v
---
+bus v = v
+
-- bus_4 :: BitVec TypeLevel.D4 -> BitVec TypeLevel.D4
--- bus_4 v = v
+bus_4 v = v
{-
inv_n :: (Pos len) => BitVec len -> BitVec len
inv_n_rec v = v
-}
-- Not really an adder either, but a slightly more complex example
--- inv :: Bit -> Bit
--- inv a = let r = hwnot a in r
+inv :: Bit -> Bit
+inv a = let r = hwnot a in r
-- Not really an adder either, but a slightly more complex example
--- invinv :: Bit -> Bit
--- invinv a = hwnot (hwnot a)
+invinv :: Bit -> Bit
+invinv a = hwnot (hwnot a)
-- Not really an adder either, but a slightly more complex example
--- dup :: Bit -> (Bit, Bit)
--- dup a = (a, a)
+dup :: Bit -> (Bit, Bit)
+dup a = (a, a)
-- Not really an adder either, but a simple stateful example (D-flipflop)
--- dff :: Bit -> Bit -> (Bit, Bit)
--- dff d s = (s', q)
--- where
--- q = s
--- s' = d
---
--- type ShifterState = (Bit, Bit, Bit, Bit)
--- shifter :: Bit -> ShifterState -> (ShifterState, Bit)
--- shifter i (a, b, c, d) =
--- (s', d)
--- where
--- s' = (i, a, b, c)
---
--- {-# NOINLINE shifter_en #-}
--- shifter_en :: Bit -> Bit-> ShifterState -> (ShifterState, Bit)
--- shifter_en High i (a, b, c, d) =
--- (s', d)
--- where
--- s' = (i, a, b, c)
---
--- shifter_en Low i s@(a, b, c, d) =
--- (s, d)
+dff :: Bit -> Bit -> (Bit, Bit)
+dff d s = (s', q)
+ where
+ q = s
+ s' = d
+
+type ShifterState = (Bit, Bit, Bit, Bit)
+shifter :: Bit -> ShifterState -> (ShifterState, Bit)
+shifter i (a, b, c, d) =
+ (s', d)
+ where
+ s' = (i, a, b, c)
+
+{-# NOINLINE shifter_en #-}
+shifter_en :: Bit -> Bit-> ShifterState -> (ShifterState, Bit)
+shifter_en High i (a, b, c, d) =
+ (s', d)
+ where
+ s' = (i, a, b, c)
+
+shifter_en Low i s@(a, b, c, d) =
+ (s, d)
-- Two multiplexed shifters
--- type ShiftersState = (ShifterState, ShifterState)
--- shifters :: Bit -> Bit -> ShiftersState -> (ShiftersState, Bit)
--- shifters sel i (sa, sb) =
--- (s', out)
--- where
--- (sa', outa) = shifter_en sel i sa
--- (sb', outb) = shifter_en (hwnot sel) i sb
--- s' = (sa', sb')
--- out = if sel == High then outa else outb
+type ShiftersState = (ShifterState, ShifterState)
+shifters :: Bit -> Bit -> ShiftersState -> (ShiftersState, Bit)
+shifters sel i (sa, sb) =
+ (s', out)
+ where
+ (sa', outa) = shifter_en sel i sa
+ (sb', outb) = shifter_en (hwnot sel) i sb
+ s' = (sa', sb')
+ out = if sel == High then outa else outb
-- Combinatoric stateless no-carry adder
-- A -> B -> S
--- no_carry_adder :: (Bit, Bit) -> Bit
--- no_carry_adder (a, b) = a `hwxor` b
+no_carry_adder :: (Bit, Bit) -> Bit
+no_carry_adder (a, b) = a `hwxor` b
-- Combinatoric stateless half adder
-- A -> B -> (S, C)
--- half_adder :: (Bit, Bit) -> (Bit, Bit)
--- {-# NOINLINE half_adder #-}
--- half_adder (a, b) =
--- ( a `hwxor` b, a `hwand` b )
+half_adder :: (Bit, Bit) -> (Bit, Bit)
+{-# NOINLINE half_adder #-}
+half_adder (a, b) =
+ ( a `hwxor` b, a `hwand` b )
-- Combinatoric stateless full adder
-- (A, B, C) -> (S, C)
--- full_adder :: (Bit, Bit, Bit) -> (Bit, Bit)
--- full_adder (a, b, cin) = (s, c)
--- where
--- (s1, c1) = half_adder(a, b)
--- (s, c2) = half_adder(s1, cin)
--- c = c1 `hwor` c2
---
--- sfull_adder = stateless full_adder
+full_adder :: (Bit, Bit, Bit) -> (Bit, Bit)
+full_adder (a, b, cin) = (s, c)
+ where
+ (s1, c1) = half_adder(a, b)
+ (s, c2) = half_adder(s1, cin)
+ c = c1 `hwor` c2
+
+sfull_adder = stateless full_adder
-- Four bit adder
-- Explicit version
-- [a] -> [b] -> ([s], cout)
--- exp_adder :: ([Bit], [Bit]) -> ([Bit], Bit)
---
--- exp_adder ([a3,a2,a1,a0], [b3,b2,b1,b0]) =
--- ([s3, s2, s1, s0], c3)
--- where
--- (s0, c0) = full_adder (a0, b0, Low)
--- (s1, c1) = full_adder (a1, b1, c0)
--- (s2, c2) = full_adder (a2, b2, c1)
--- (s3, c3) = full_adder (a3, b3, c2)
+exp_adder :: ([Bit], [Bit]) -> ([Bit], Bit)
+
+exp_adder ([a3,a2,a1,a0], [b3,b2,b1,b0]) =
+ ([s3, s2, s1, s0], c3)
+ where
+ (s0, c0) = full_adder (a0, b0, Low)
+ (s1, c1) = full_adder (a1, b1, c0)
+ (s2, c2) = full_adder (a2, b2, c1)
+ (s3, c3) = full_adder (a3, b3, c2)
-- Any number of bits adder
-- Recursive version
-- [a] -> [b] -> ([s], cout)
--- rec_adder :: ([Bit], [Bit]) -> ([Bit], Bit)
---
--- rec_adder ([], []) = ([], Low)
--- rec_adder ((a:as), (b:bs)) =
--- (s : rest, cout)
--- where
--- (rest, cin) = rec_adder (as, bs)
--- (s, cout) = full_adder (a, b, cin)
---
--- foo = id
--- add, sub :: Int -> Int -> Int
--- add a b = a + b
--- sub a b = a - b
---
--- highordtest = \x ->
--- let s = foo x
--- in
--- case s of
--- (a, b) ->
--- case a of
--- High -> add
--- Low -> let
--- op' = case b of
--- High -> sub
--- Low -> \c d -> c
--- in
--- \c d -> op' d c
+rec_adder :: ([Bit], [Bit]) -> ([Bit], Bit)
+
+rec_adder ([], []) = ([], Low)
+rec_adder ((a:as), (b:bs)) =
+ (s : rest, cout)
+ where
+ (rest, cin) = rec_adder (as, bs)
+ (s, cout) = full_adder (a, b, cin)
+
+foo = id
+add, sub :: Int -> Int -> Int
+add a b = a + b
+sub a b = a - b
+
+highordtest = \x ->
+ let s = foo x
+ in
+ case s of
+ (a, b) ->
+ case a of
+ High -> add
+ Low -> let
+ op' = case b of
+ High -> sub
+ Low -> \c d -> c
+ in
+ \c d -> op' d c
functiontest :: TFVec D4 Bit -> Bit
functiontest = \v -> let r = head v in r
\c d -> op' d c
-- Four bit adder, using the continous adder below
-- [a] -> [b] -> ([s], cout)
---con_adder_4 as bs =
--- ([s3, s2, s1, s0], c)
--- where
--- ((s0, _):(s1, _):(s2, _):(s3, c):_) = con_adder (zip ((reverse as) ++ lows) ((reverse bs) ++ lows))
+con_adder_4 as bs =
+ ([s3, s2, s1, s0], c)
+ where
+ ((s0, _):(s1, _):(s2, _):(s3, c):_) = con_adder (P.zip ((P.reverse as) P.++ lows) ((P.reverse bs) P.++ lows))
-- Continuous sequential version
-- Stream a -> Stream b -> Stream (sum, cout)
---con_adder :: Stream (Bit, Bit) -> Stream (Bit, Bit)
+con_adder :: Stream (Bit, Bit) -> Stream (Bit, Bit)
-- Forward to con_adder_int, but supply an initial state
---con_adder pin =
--- con_adder_int pin Low
+con_adder pin =
+ con_adder_int pin Low
-- Stream a -> Stream b -> state -> Stream (s, c)
---con_adder_int :: Stream (Bit, Bit) -> Bit -> Stream (Bit, Bit)
---con_adder_int ((a,b):rest) cin =
--- (s, cout) : con_adder_int rest cout
--- where
--- (s, cout) = full_adder a b cin
+con_adder_int :: Stream (Bit, Bit) -> Bit -> Stream (Bit, Bit)
+con_adder_int ((a,b):rest) cin =
+ (s, cout) : con_adder_int rest cout
+ where
+ (s, cout) = full_adder (a, b, cin)
-- vim: set ts=8 sw=2 sts=2 expandtab:
projects / matthijs / master-project / cλash.git / commitdiff