| Copyright | (C) 2013-2015, University of Twente |
|---|---|
| License | BSD2 (see the file LICENSE) |
| Maintainer | Christiaan Baaij <christiaan.baaij@gmail.com> |
| Safe Haskell | None |
| Language | Haskell2010 |
CLaSH.Prelude.Mealy
Contents
Description
- mealy :: (s -> i -> (s, o)) -> s -> Signal i -> Signal o
- mealyB :: (Bundle i, Bundle o) => (s -> i -> (s, o)) -> s -> Unbundled i -> Unbundled o
- (<^>) :: (Bundle i, Bundle o) => (s -> i -> (s, o)) -> s -> Unbundled i -> Unbundled o
- mealy' :: SClock clk -> (s -> i -> (s, o)) -> s -> Signal' clk i -> Signal' clk o
- mealyB' :: (Bundle i, Bundle o) => SClock clk -> (s -> i -> (s, o)) -> s -> Unbundled' clk i -> Unbundled' clk o
Mealy machine synchronised to the system clock
Arguments
| :: (s -> i -> (s, o)) | Transfer function in mealy machine form:
|
| -> s | Initial state |
| -> Signal i -> Signal o | Synchronous sequential function with input and output matching that of the mealy machine |
Create a synchronous function from a combinational function describing a mealy machine
mac :: Int -- Current state
-> (Int,Int) -- Input
-> (Int,Int) -- (Updated state, output)
mac s (x,y) = (s',s)
where
s' = x * y + s
topEntity :: Signal (Int, Int) -> Signal Int
topEntity = mealy mac 0
>>>simulate topEntity [(1,1),(2,2),(3,3),(4,4),...[0,1,5,14,30,...
Synchronous sequential functions can be composed just like their combinational counterpart:
dualMac :: (SignalInt,SignalInt) -> (SignalInt,SignalInt) ->SignalInt dualMac (a,b) (x,y) = s1 + s2 where s1 =mealymac 0 (bundle(a,x)) s2 =mealymac 0 (bundle(b,y))
Arguments
| :: (Bundle i, Bundle o) | |
| => (s -> i -> (s, o)) | Transfer function in mealy machine form:
|
| -> s | Initial state |
| -> Unbundled i -> Unbundled o | Synchronous sequential function with input and output matching that of the mealy machine |
A version of mealy that does automatic Bundleing
Given a function f of type:
f :: Int -> (Bool, Int) -> (Int, (Int, Bool))
When we want to make compositions of f in g using mealy, we have to
write:
g a b c = (b1,b2,i2)
where
(i1,b1) = unbundle (mealy f 0 (bundle (a,b)))
(i2,b2) = unbundle (mealy f 3 (bundle (i1,c)))
Using mealyB however we can write:
g a b c = (b1,b2,i2)
where
(i1,b1) = mealyB f 0 (a,b)
(i2,b2) = mealyB f 3 (i1,c)
Arguments
| :: (Bundle i, Bundle o) | |
| => (s -> i -> (s, o)) | Transfer function in mealy machine form:
|
| -> s | Initial state |
| -> Unbundled i -> Unbundled o | Synchronous sequential function with input and output matching that of the mealy machine |
Infix version of mealyB
Mealy machine synchronised to an arbitrary clock
Arguments
| :: SClock clk |
|
| -> (s -> i -> (s, o)) | Transfer function in mealy machine form:
|
| -> s | Initial state |
| -> Signal' clk i -> Signal' clk o | Synchronous sequential function with input and output matching that of the mealy machine |
Create a synchronous function from a combinational function describing a mealy machine
mac :: Int -- Current state
-> (Int,Int) -- Input
-> (Int,Int) -- (Updated state, output)
mac s (x,y) = (s',s)
where
s' = x * y + s
type ClkA = Clk "A" 100
clkA100 :: SClock ClkA
clkA100 = sclock
topEntity :: Signal' ClkA (Int, Int) -> Signal' ClkA Int
topEntity = mealy' clkA100 mac 0
>>>simulate topEntity [(1,1),(2,2),(3,3),(4,4),...[0,1,5,14,30,...
Synchronous sequential functions can be composed just like their combinational counterpart:
dualMac :: (Signal'clkA100 Int,Signal'clkA100 Int) -> (Signal'clkA100 Int,Signal'clkA100 Int) ->Signal'clkA100 Int dualMac (a,b) (x,y) = s1 + s2 where s1 =mealy'clkA100 mac 0 (bundle'clkA100 (a,x)) s2 =mealy'clkA100 mac 0 (bundle'clkA100 (b,y))
Arguments
| :: (Bundle i, Bundle o) | |
| => SClock clk | |
| -> (s -> i -> (s, o)) | Transfer function in mealy machine form:
|
| -> s | Initial state |
| -> Unbundled' clk i -> Unbundled' clk o | Synchronous sequential function with input and output matching that of the mealy machine |
A version of mealy' that does automatic Bundleing
Given a function f of type:
f :: Int -> (Bool,Int) -> (Int,(Int,Bool))
When we want to make compositions of f in g using mealy', we have to
write:
g clk a b c = (b1,b2,i2)
where
(i1,b1) = unbundle' clk (mealy' clk f 0 (bundle' clk (a,b)))
(i2,b2) = unbundle' clk (mealy' clk f 3 (bundle' clk (i1,c)))
Using mealyB' however we can write:
g clk a b c = (b1,b2,i2)
where
(i1,b1) = mealyB' clk f 0 (a,b)
(i2,b2) = mealyB' clk f 3 (i1,c)