-module mTask
+implementation module mTask
/*
Pieter Koopman pieter@cs.ru.nl
imporove setp: >>*.
*/
-import iTasks
-import gdynamic, gCons, GenEq, StdMisc, StdArray
-
-// =================== examples ===================
-
-Start =
- [["//mTaskTFP16_3 \n"]
-/* ,["// --- p1 \n"]
- ,compile p1
- ,["// --- p2 \n"]
- ,compile p2
- ,["// --- p3 \n"]
- ,compile p3
- ,["// --- p4 \n"]
- ,compile p4
- ,["// --- p5 \n"]
- ,compile p5
- ,["// --- p6 \n"]
- ,compile p6
- ,["// --- p7 \n"]
- ,compile p7
- ,["// --- p8 \n"]
- ,compile p8
- ,["// --- p9 \n"]
- ,compile p9
- ,["// --- p10 \n"]
- ,compile p10
- ,["// --- p11 \n"]
- ,compile p11
- ,["// --- p12 \n"]
- ,compile p12
- ,["// --- fac \n"]
- ,compile fac
- ,["// --- blink \n"]
- ,compile blink
- ,["// --- heatingDemo \n"]
- ,compile heatingDemo
- ,["// --- hpinDemo \n"]
- ,compile pinDemo
- ,["// --- blink2 \n"]
- ,compile blink2
- ,["// --- blink3 \n"]
- ,compile blink3
- ,["// --- blinks \n"]
- ,compile blinks
- ,["// --- lcdCount \n"]
- ,compile lcdCount
-*/
- ,["// --- heating \n"]
- ,compile heating
- ]
-
-lcdHello = LCD 16 2 [] \lcd = {main = print lcd (lit "Hello world")}
-
-lcdCount =
- LCD 16 2 [] \lcd =
- task \t = (\c.
- If (pressed upButton) (
- setCursor lcd Zero Zero :.
- print lcd c :.
- t (sec 1) (c +. One)
- ) (t (msec 10) c)) In
- {main = t (sec 0) Zero}
-
-printD0 = {main = serialPrint (Not d0)}
-
-print36 = sds \x = 6 In {main = x =. x *. x :. serialPrint x}
-
-pinDemo =
- {main = a1 =. a0 =. lit 1 +. a0 :. a0 =. Not a0}
-
-fac = fun \fac = (\n. If (n <. One) One (n *. fac (n -. One)))
- In {main = fac (lit 6)}
-One = lit 1
-Zero = lit 0
-
-blink =
- task \t = (\s. setLED s :. t (If s (sec 1) (sec 3)) (Not s)) In {main = t (sec 0) (lit True)}
-blink2 =
- task \t = (\(). d13 =. Not d13 :. t (sec 1) ()) In {main = t (sec 0) ()}
-blink3 =
- task \t = (\s. d13 =. s :. t (If s (msec 100) (sec 1)) (Not s)) In {main = t (sec 0) (lit False)}
-blinks =
- task \t = (\b. d13 =. b :. t (sec 1) b) In {main = t (msec 0) true :. t (msec 100) false}
-
-setLED b = d13 =. b
-sec n = long (lit (n * 1000))
-msec n = long (lit n)
-
-qt = task \plus = (\(x,y).x +. y) In {main = plus (sec 0) (lit 3, lit 4)}
-qs = fun \plus = (\(x,y).x +. y) In {main = plus (lit 3, lit 4)}
-
-q1 =
- tasks \(switch, heat) =
- (\s1 = digitalWrite D2 s1:. heat (sec 60) s1
- ,\s2 = analogRead A3 >>*. \v.
- [Cond (v >. upper) (switch (sec 0) off)
- ,Cond (v <. lower) (switch (sec 0) on)
- ,Ever (heat (sec 1) s2)
- ])
- In {main = heat (sec 0) off}
-where
- upper = lit 876
- lower = lit 123
-
-serialReadInt = serialParseInt >>=. \i. serialRead >>*. \c. [Cond (c ==. lit '\n') i]
-
-heating =
- sds \goal = 500 In
- fun \switch = (\s. d13 =. s) In
- task \control = (\isOn.
- a0 <. goal >>*. \mustOn.
- [Cond (Not isOn &. mustOn) (switch on :. control minOnTime on)
- ,Cond (isOn &. Not mustOn) (switch off:. control minOffTime off)
- ,Ever (control (msec 100) isOn)
- ]) In
- task \change = (\().
- serialAvailable ? (serialReadInt >>=. \g.goal =. g) :.
- change (sec 1) ()) In
- {main = switch off :. control (sec 0) off :. change (sec 1) ()}
-where
- minOnTime = sec 2
- minOffTime = sec 1
-
-heating2 =
- sds \goal = 500 In
-// fun \switch = setLED In
- fun \switch = (\b. setLED b :. serialPrintln b) In
- task \control = (\isOn.
- a0 <. goal >>*. \mustOn.
- [Cond (Not isOn &. mustOn) (switch on :. control minOnTime on)
- ,Cond (isOn &. Not mustOn) (switch off:. control minOffTime off)
- ,Ever (control (msec 100) isOn)
- ]) In
- task \change = (\().
- serialAvailable ? (serialReadInt >>=. \i. serialPrintln (goal =. i)) :.
- change (sec 1) ()) In
- {main = switch off :. control (sec 0) off :. change (sec 1) ()}
-where
- minOnTime = sec 2
- minOffTime = sec 1
-
-thermoTask =
- sds \goal = 500 In
- fun \switch = (\on. d13 =. bool on :. a0 =. on) In
- task \control =
- (\isOn. a0 <. goal >>*. \mustOn.
- [Cond (mustOn &. Not isOn) (switch mustOn :. control minOnTime mustOn)
- ,Cond (Not mustOn &. isOn) (switch mustOn :. control minOffTime mustOn)
- ,Ever (control (msec 100) isOn)
- ]) In
- {main = switch off :. control (sec 0) off}
-where
- minOnTime = sec 1 // 60
- minOffTime = sec 2 //10
- off = lit False
-
-heatingDemo =
- sds \heat = False In
- sds \temp = 500 In
- LCD 16 2 [] \lcd.
- task \tempChange = (\().
- lit 0 <. temp &. Not heat ? temp =. temp -. One:.
- temp <. lit 1000 &. heat ? temp =. temp +. One :.
- setCursor lcd (lit 5) Zero :.
- print lcd (lit "temp ") :.
- print lcd temp :.
- print lcd (lit " ") :.
- tempChange (msec 789) ()) In
- fun \switch = (\s.
- heat =. s :.
- setCursor lcd Zero Zero :.
- If s
- (print lcd (lit "On "))
- (print lcd (lit "Off"))) In
- fun \measure = (\().
- analogRead A0 >>=. \a0.
- setCursor lcd Zero One :.
- print lcd a0 :.
- print lcd (lit " ") :.
- a0) In
- task \control = (\isOn.
- measure () >>=. \val.temp <. val
- >>*. \mustOn.
- [Cond (Not isOn &. mustOn) (switch on :. control minOnTime on)
- ,Cond (isOn &. Not mustOn) (switch off:. control minOffTime off)
- ,Ever (control (msec 100) isOn)
- ]
- ) In
- {main = switch off :. control (msec 10) off :. tempChange (sec 0) ()}
-where
- limit = lit 512
- minOnTime = sec 3
- minOffTime = sec 2
-true = lit True
-on = true
-false = lit False
-off = false
-
-count =
- LCD 16 2 [] \lcd.
- task \count = (\n.
- setCursor lcd Zero Zero :.
- print lcd n :.
- count (sec 1) (n +. One)) In
- {main = count (sec 0) Zero}
-
-p0 = sds \x = 6 In {main = x =. x *. lit 7}
-p1 = {main = lit 2 +. lit 4 >>=. \x. (x +. lit 1) *. x}
-p2 =
- fun \f. (\x. lit 6 *. x)
- In {main = lit 3 +. lit 4 >>=. \x. f x}
-p3 =
- fun \f. (\x. lit 6 *. x)
- In {main = lit 3 +. lit 4 >>=. f} // higher order, somewhat remarkable that this works
-p4 =
- fun \f. (\x. lit 6 *. x)
- In {main = lit 3 +. lit 4 >>=. \x. f x >>=. serialPrint}
-p5 = {main = lit 7 >>*. \x. [Cond (x <. lit 36) (x *. x),Ever (lit 42)]}
-p6 = sds \y = 1 In {main = lit 7 >>*. \x. [Cond (x <. lit 36) (y =. x *. x),Ever (y =. x)]}
-p7 = sds \y = 1 In {main = y +. lit 1 >>*. \x. [Cond (x <. lit 36) ((y =. x *. x) >>*. \z.[Cond (z ==. x) y, Ever y]),Ever (y =. x)]}
-p8 = sds \y = 1 In {main = pressed upButton >>*. \x. [Cond x (y =. y +. y),Ever (y =. lit 36)]}
-//p8 = sds \y = 1 In {main = pressed upButton >>*. \x. [Cond x ((y =. lit 42) >>*. \z.[Cond (z ==. y) y, Ever y]),Ever (y =. lit 36)]}
-//p9 = {main = If (pressed upButton) (lit 1) (lit 7)} // Overloading error [mTaskTFP16.icl,61,p9]: "isExpr" no instance available of type Stmt
-p9 = {main = pressed upButton >>=. \b.If b (lit 1) (lit 7)}
-p10 =
- sds \y = 1 In
- {main =
- (pressed upButton >>*. \x.
- [Cond x (y =. y +. y :.
- x)
- ,Ever (y =. lit 36 :.
- lit False)
- ])
- >>=. \z. z &. z}
-p11 =
- sds \y = 1 In
- {main =
- y =. lit 2 :.
- (pressed upButton >>=. \b.
- If b
- (y =. lit 3 :.
- y +. lit 1)
- (lit 42))
- >>*. \x.
- [Cond (x <. lit 36)
- ((y =. x *. x) >>*. \z.
- [Cond (z ==. x) (serialPrint y)
- ,Ever (serialPrint (lit 0))
- ])
- ,Ever (y =. x)
- ]
- }
-p12 =
- task \t = (\(). pressed upButton >>*. \b.[Cond b (serialPrintln (lit 7)),Ever (t (lit 250) ():. lit 0)]) In
- {main = t (lit 0) ()}
-
-// ----- serial definition ----- //
-
-class serial v where
- serialAvailable :: (v Bool Expr)
- serialPrint :: (v t p) -> v Int Expr | stringQuotes t & isExpr p
- serialPrintln :: (v t p) -> v Int Expr | stringQuotes t & isExpr p
- serialRead :: (v t Expr)
- serialParseInt :: (v Int Expr)
-
-instance serial Code where
- serialAvailable = embed (c "Serial.available()")
- serialPrint x = embed (c "Serial.print(" +.+ x +.+ c ")")
- serialPrintln x = embed (c "Serial.println(" +.+ x +.+ c ")")
- serialRead = embed (c "Serial.read()")
- serialParseInt = embed (c "Serial.parseInt()")
-
-instance serial Eval where
- serialAvailable = rtrn False
- serialPrint x = x >>== \a.E \r s.let str = toCode a in (size str,{s & serial = s.serial ++ [str]})
- serialPrintln x = x >>== \a.E \r s.let str = toCode a + "\n" in (size str,{s & serial = s.serial ++ [str]})
- serialRead = rtrn undef
- serialParseInt = rtrn undef
-
-class char2int v :: (v Char p) -> v Int Expr
-instance char2int Code where char2int (C f) = C \rw c.f Rd c
-
-:: SerialObject v t p =
- { available :: v Bool Expr
- , print :: (v t p) -> v Int Expr
- , println :: (v t p) -> v Int Expr
- , read :: (v Char Expr)
- }
-
-// =================== shields ===================
-
-// ----- LCD definition ----- //
-
-:: LCD =
- { cursorRow :: Int
- , cursorCol :: Int
- , sizeH :: Int
- , sizeW :: Int
- , lcdtxt :: [String]
- }
-
-:: Button = RightButton | UpButton | DownButton | LeftButton | SelectButton | NoButton
-
-rightButton = lit RightButton
-upButton = lit UpButton
-downButton = lit DownButton
-leftButton = LeftButton
-selectButton = lit SelectButton
-noButton = lit NoButton
-
-class lcd v where
- begin :: (v LCD Expr) (v Int p) (v Int q) -> v () Expr
- print :: (v LCD Expr) (v t p) -> v Int Expr | stringQuotes t // returns bytes written
- setCursor :: (v LCD Expr) (v Int p) (v Int q) -> v () Expr
- liquidCrystal0 :: [DigitalPin] ((v LCD Expr)->Main (v b q)) -> Main (v b q)
- LCD :: Int Int [DigitalPin] ((v LCD Expr)->Main (v b q)) -> Main (v b q)
- scrollLeft :: (v LCD Expr) -> v () Expr
- scrollRight :: (v LCD Expr) -> v () Expr
- pressed :: (v Button Expr) -> v Bool Expr
-
-instance lcd Code where
- begin v x y = embed (v +.+ c ".begin" +.+ codeOp2 x ", " y)
- print v x = embed (v +.+ c ".print (" +.+ stringQuotes x +.+ c ")")
- setCursor v x y = embed (v +.+ c ".setCursor" +.+ codeOp2 x ", " y)
- scrollLeft v = embed (v +.+ c ".scrollDisplayLeft()")
- scrollRight v = embed (v +.+ c ".scrollDisplayRight()")
- liquidCrystal0 [] f = liquidCrystal0 [D8, D9, D4, D5, D6, D7] f
- liquidCrystal0 pins f =
- {main =
- getCode \cd. fresh \n.
- let
- name = "lcd" + toString n
- rest = f (c name)
- in
- include "LiquidCrystal" +.+
- setCode Var +.+
- c ("LiquidCrystal " + name + "(" + argList pins + ");\n") +.+
- setCode cd +.+
- rest.main
- }
- LCD x y [] f = LCD x y [D8, D9, D4, D5, D6, D7] f
- LCD x y pins f =
- {main =
- getCode \cd. fresh \n.
- let
- name = "lcd" + toString n
- rest = f (c name)
- in
- include "LiquidCrystal" +.+
- setCode Var +.+
- c ("LiquidCrystal " + name + "(" + argList pins + ");\n") +.+
- setCode Setup +.+
- c (name + ".begin(" + toCode x + ", " + toCode y +");") +.+ nl +.+
- setCode cd +.+
- rest.main
- }
- pressed b = embed (c "pressed(" +.+ setMode SubExp +.+ b +.+ c ")")
-
-RightBound = 50
-UpBound = 190
-DownBound = 380
-LeftBound = 555
-SelectBound = 790
+import Generics.gCons
+import Generics.gdynamic
-instance lcd Eval where
- begin (E v) x y =
- x >>== \w.
- y >>== \h.
- yield () (E \r.v (Updt \lcd.{lcd & sizeH = h, sizeW = w, lcdtxt = repeatn h (toString (repeatn w ' '))}))
- print (E v) x =
- x >>== \a. let str = toCode a in
- yield (size str) (E \r.v (Updt \lcd.lcdPrintStr str lcd))
- setCursor (E v) x y =
- x >>== \w.
- y >>== \h.
- yield () (E \r.v (Updt \lcd.{lcd & cursorRow = h, cursorCol = w}))
- scrollLeft v = rtrn ()
- scrollRight v = rtrn ()
- LCD w h pins f = defEval2 lcd f where
- lcd =
- { cursorRow = 0
- , cursorCol = 0
- , sizeH = h
- , sizeW = w
- , lcdtxt = repeatn h (toString (repeatn w ' '))
- }
- liquidCrystal0 pins f = defEval2 lcd f where
- lcd =
- { cursorRow = 0
- , cursorCol = 0
- , sizeH = 0
- , sizeW = 0
- , lcdtxt = []
- }
- pressed b = rtrn False
-
-lcdPrintStr str lcd
- | lcd.cursorRow < 0 || lcd.cursorRow >= length lcd.lcdtxt ||
- lcd.cursorCol < 0 || lcd.cursorCol >= size (lcd.lcdtxt !! lcd.cursorRow)
- = lcd
- # line = lcd.lcdtxt !! lcd.cursorRow
- # endPos = size str + lcd.cursorCol
- | endPos >= lcd.sizeW
- # newLine = line % (0, lcd.cursorCol - 1) + str % (0, size str - lcd.cursorCol)
- = {lcd & lcdtxt = updateAt lcd.cursorRow newLine lcd.lcdtxt, cursorCol = lcd.sizeW - 1}
- # newLine = line % (0, lcd.cursorCol - 1) + str + line % (endPos, lcd.sizeW - 1)
- = {lcd & lcdtxt = updateAt lcd.cursorRow newLine lcd.lcdtxt, cursorCol = endPos}
-
-printAt :: (v LCD Expr) (v Int b) (v Int c) (v t e) -> v Int Stmt
- | lcd, seq v & stringQuotes t
-printAt lcd x y z = setCursor lcd x y :. print lcd z
-
-keySwitch :: (a Int b) (a c d,a c e,a c f,a c g,a c h,a c a0) -> a c Stmt | arith, boolExpr, seq a & If a h a0 b0 & If a g b0 c0 & If a f c0 d0 & If a e d0 e0 & If a d e0 f0 & type c
-keySwitch v (right, up, down, left, select, nokey)
- = v >>=. \w.
- If (w <. lit RightBound)
- right
- (If (w <. lit UpBound)
- up
- (If (w <. lit DownBound)
- down
- (If (w <.lit LeftBound)
- left
- (If (w <. lit SelectBound)
- select
- nokey
- ))))
-
-// =================== mTask ===================
-
-
-// ----- dsl definition ----- //
-
-:: DigitalPin
- = D0 | D1 | D2 | D3 | D4 | D5 |D6 | D7 | D8 | D9 | D10 | D11 | D12 | D13
-:: AnalogPin = A0 | A1 | A2 | A3 | A4 | A5
-:: PinMode = INPUT | OUTPUT | INPUT_PULLUP
-:: Pin = Digital DigitalPin | Analog AnalogPin
-instance toCode Pin where
- toCode (Digital p) = toCode p
- toCode (Analog p) = toCode p
-instance toCode Button where toCode b = toCode (consIndex{|*|} b)
-derive consIndex Button
+import iTasks
+import GenEq, StdMisc, StdArray, GenBimap
+import mTaskCode
+import mTaskSerial, mTaskLCD
-class pin p | type, == p where
- pin :: p -> Pin
instance pin DigitalPin where
pin p = Digital p
+
instance pin AnalogPin where
pin p = Analog p
-:: Upd = Upd
-:: Expr = Expr
-:: Stmt = Stmt
-:: MTask = MTask Int // String
-
-class isExpr a :: a -> Int
instance isExpr Upd where isExpr _ = 0
instance isExpr Expr where isExpr _ = 1
-class isStmt a :: a -> Int
instance isStmt Upd where isStmt _ = 10
instance isStmt Expr where isStmt _ = 11
instance isStmt Stmt where isStmt _ = 12
instance == MTask where (==) (MTask x) (MTask y) = x == y
-instance toCode MTask where toCode (MTask x) = "Task " + toCode x
-
-:: Main a = {main :: a}
unMain :: (Main x) -> x
unMain m = m.main //{main=x} = x
-class arith v where
- lit :: t -> v t Expr | toCode t
- (+.) infixl 6 :: (v t p) (v t q) -> v t Expr | type, +, zero t & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (-.) infixl 6 :: (v t p) (v t q) -> v t Expr | type, -, zero t & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (*.) infixl 7 :: (v t p) (v t q) -> v t Expr | type, *, zero, one t & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (/.) infixl 7 :: (v t p) (v t q) -> v t Expr | type, / t & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
-class boolExpr v where
- (&.) infixr 3 :: (v Bool p) (v Bool q) -> v Bool Expr | isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (|.) infixr 2 :: (v Bool p) (v Bool q) -> v Bool Expr | isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- Not :: (v Bool p) -> v Bool Expr | isExpr p //& toExpr2 p
- (==.) infix 4 :: (v a p) (v a q) -> v Bool Expr | ==, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (!=.) infix 4 :: (v a p) (v a q) -> v Bool Expr | ==, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (<.) infix 4 :: (v a p) (v a q) -> v Bool Expr | <, Ord, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (>.) infix 4 :: (v a p) (v a q) -> v Bool Expr | <, Ord, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (<=.) infix 4 :: (v a p) (v a q) -> v Bool Expr | <, Ord, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
- (>=.) infix 4 :: (v a p) (v a q) -> v Bool Expr | <, Ord, toCode a & isExpr p & isExpr q //& toExpr2 p & toExpr2 q
-// using functional dependencies
-class If v q r ~s where
- If :: (v Bool p) (v t q) (v t r) -> v t s | isExpr p & type t
-class IF v where
- IF :: (v Bool p) (v t q) (v s r) -> v () Stmt | isExpr p
- (?) infix 1 :: (v Bool p) (v t q) -> v () Stmt | isExpr p
-class var2 v where
- var2 :: t ((v t Upd)->(Main (v c s))) -> (Main (v c s)) | type, toCode t
- con2 :: t ((v t Expr) ->(Main (v c s))) -> (Main (v c s)) | type t
-class sds v where
- sds :: ((v t Upd)->In t (Main (v c s))) -> (Main (v c s)) | type, toCode t
- con :: ((v t Expr) ->In t (Main (v c s))) -> (Main (v c s)) | type t
-class seq v where
- (>>=.) infixr 0 :: (v t p) ((v t Expr) -> (v u q)) -> (v u Stmt) | type t & type u
- (:.) infixr 0 :: (v t p) (v u q) -> v u Stmt | type t & type u
-class step v where
- (>>*.) infixl 1 :: (v t p) ((v t Expr) -> [Step v u]) -> v u Stmt | type t & type u
-:: Step v t = E.p.q: Cond (v Bool q) (v t p) | E.p: Ever (v t p)
-class assign v where
- (=.) infixr 2 :: (v t Upd) (v t p) -> v t Expr | type t & isExpr p
-class fun v t where
- fun :: ((t->v s Expr)->In (t->v s p) (Main (v u q))) -> Main (v u q) | type s
-class mtask v a where
- task :: (((v delay r) a->v MTask Expr)->In (a->v u p) (Main (v t q))) -> Main (v t q) | type t & type u & isExpr r & long v delay
-class lag v where
- lag :: (v delay r) (v t p) -> v MTask Expr | type t & long v delay
-class setDelay v where
- setDelay :: (v Long p) (v MTask Expr) -> (v MTask Expr) | isExpr p
-class mtasks v a b where
- tasks :: (((v delay r1) a->v MTask Expr, (v delay r2) b->v MTask Expr)->In (a->v t p, b->v u p) (Main (v s q))) -> Main (v s q) | type s & isExpr r1 & isExpr r2 & long v delay
-class output v where
- output :: (v t p) -> v () Expr | type t & isExpr p
-class noOp v where noOp :: v t p
-
-class pinMode v where
- pinmode :: p PinMode -> v () Expr | pin p
-class digitalIO v where
- digitalRead :: p -> v Bool Expr | pin, readPinD p
- digitalWrite :: p (v Bool q) -> v Bool Expr | pin, writePinD p
-class analogIO v where
- analogRead :: AnalogPin -> v Int Expr
- analogWrite :: AnalogPin (v Int p) -> v Int Expr
-class dIO v where
- dIO :: p -> v Bool Upd | pin, readPinD p
-class aIO v where
- aIO :: AnalogPin -> v Int Upd
-class time v where
- delay :: (v Long p) -> (v Long Expr)
- millis :: (v Long Expr)
-
-class pio p t where pio :: p -> v t Upd | aIO v & dIO v
instance pio AnalogPin Int where pio p = aIO p
instance pio AnalogPin Bool where pio p = dIO p
instance pio DigitalPin Bool where pio p = dIO p
-a0 = pio A0
-a1 = pio A1
-a2 = pio A2
-a3 = pio A3
-a4 = pio A4
-a5 = pio A5
-
-d0 = pio D0
-d1 = pio D1
-d2 = pio D2
-d3 = pio D3
-d4 = pio D4
-d5 = pio D5
-d6 = pio D6
-d7 = pio D7
-d8 = pio D8
-d9 = pio D9
-d10 = pio D10
-d11 = pio D11
-d12 = pio D12
-d13 = pio D13
-
int :: (v Int p) -> (v Int p)
int x = x
bool :: (v Bool p) -> (v Bool p)
char :: (v Char p) -> (v Char p)
char x = x
-class type t | showType, dyn, toCode, ==, type2string, varName t
-class type2string t :: t -> String
instance type2string Int where type2string _ = "int"
instance type2string Long where type2string _ = "long"
instance type2string Real where type2string _ = "float"
instance type2string MTask where type2string _ = "task"
instance type2string DigitalPin where type2string _ = "int"
instance type2string AnalogPin where type2string _ = "int"
+instance type2string UserLED where type2string _ = "int"
instance type2string String where type2string _ = "Char []"
instance type2string () where type2string _ = ""
-class varName a :: a -> String
+
instance varName Int where varName _ = "vInt"
instance varName Long where varName _ = "vLong"
instance varName Bool where varName _ = "vBool"
instance varName Real where varName _ = "vFloat"
instance varName x where varName _ = ""
-class dsl t | arith, boolExpr, sds, assign, seq t
-
-argType :: (((Code a p)->Code b q)->In ((Code a p)->Code b q) (Code c s)) -> a | type a
-argType f = undef
-
-class argTypes t :: ((t->Code b Expr)->In (t->Code b2 q) (Main (Code c s))) -> t
-instance argTypes (Code a p) | showType a where argTypes f = showType
-instance argTypes (Code a p, Code b q) | showType a & showType b where argTypes f = (showType, showType)
-instance argTypes (Code a p, Code b q, Code c r) | showType a & showType b & showType c where argTypes f = (showType, showType, showType)
-
-resType :: ((t->Code b Expr)->In (t->Code b q) (Main (Code c s))) -> Code b q | showType b
-resType f = showType
-
-var2Type :: (Code t p) -> Code t p | showType t
-var2Type x = showType
-
-resType2 :: ((t->Code b Expr)->In (t->Code b q) (Main (Code c s))) -> SV b | showType2 b
-resType2 f = showType2
-
-:: SV t = SV String
-instance toCode (SV t) where toCode (SV s) = s
-
-class showType2 t :: SV t
instance showType2 () where showType2 = SV "void "
instance showType2 Int where showType2 = SV "int "
instance showType2 Char where showType2 = SV "char "
instance showType2 Bool where showType2 = SV "bool "
instance showType2 a where showType2 = SV "word /* default */"
-class showType t | showType2 /*, type*/ t :: (Code t p)
instance showType () where showType = c "void "
instance showType Int where showType = c "int "
instance showType Long where showType = c "long "
instance showType Bool where showType = c "bool "
instance showType a where showType = c "word /* default */ "
-class typeSelector t | showType2, type t :: (Code t p)
instance typeSelector Int where typeSelector = c ".i"
instance typeSelector Char where typeSelector = c ".c"
instance typeSelector Bool where typeSelector = c ".b"
instance typeSelector a where typeSelector = c ".w"
-:: In a b = In infix 0 a b
-
-read :: Int (ReadWrite a) State -> (a,State) | dyn a
-read n Rd s = (fromJust (fromDyn (s.store !! n)), s)
-read n (Wrt a) s = (a,{s&store=updateAt n (toDyn a) s.store})
-read n (Updt f) s=:{store}
+read` :: Int (ReadWrite a) State` -> (a,State`) | dyn a
+read` n Rd s = (fromJust (fromDyn (s.store !! n)), s)
+read` n (Wrt a) s = (a,{s&store=updateAt n (toDyn a) s.store})
+read` n (Updt f) s=:{store}
# obj = f (fromJust (fromDyn (store !! n)))
= (obj, {s & store = updateAt n (toDyn obj) store})
-// ----- code generation ----- //
-
-instance arith Code where
- lit a = embed (c a)
- (+.) x y = codeOp2 x " + " y
- (-.) x y = codeOp2 x " - " y
- (*.) x y = codeOp2 x " * " y
- (/.) x y = codeOp2 x " / " y
-instance boolExpr Code where
- (&.) x y = codeOp2 x " && " y
- (|.) x y = codeOp2 x " || " y
- Not x = embed (brac (c "! " +.+ brac x))
- (==.) x y = codeOp2 x " == " y
- (!=.) x y = codeOp2 x " != " y
- (<.) x y = codeOp2 x " < " y
- (<=.) x y = codeOp2 x " <= " y
- (>.) x y = codeOp2 x " > " y
- (>=.) x y = codeOp2 x " >= " y
-instance If Code Stmt Stmt Stmt where If c t e = IfStmt c t e
-instance If Code e Stmt Stmt where If c t e = IfStmt c t e
-instance If Code Stmt e Stmt where If c t e = IfStmt c t e
-instance If Code x y Expr where If c t e = IfExpr c t e
-IfExpr b t e = embed (brac (b +.+ indent +.+ nl +.+ c " ? " +.+ t +.+ nl +.+ c " : " +.+ e +.+ unindent))
-IfStmt b t e =
- getMode \mode.
- let
- v = varName t
- newMode =
- case mode of
- Return s = Return s
- Assign v = Assign v
- _ = if (v == "") NoReturn (Assign v)
- in
- setMode SubExp +.+
- c "if " +.+ brac b +.+ c " {" +.+
- indent +.+ nl +.+ setMode newMode +.+ t +.+ unindent +.+ nl +.+ c "} else {" +.+
- indent +.+ nl +.+ setMode newMode +.+ e +.+ unindent +.+ nl +.+ c "}"
-instance IF Code where
- IF b t e = IfStmt b t e
- (?) b t =
- getMode \mode.
- c "if " +.+ setMode SubExp +.+ brac b +.+ c " {" +.+
- indent +.+ nl +.+ setMode mode +.+ t +.+ c ";" +.+ unindent +.+ nl +.+ c "}"
-
-instance sds Code where
- sds f = // defCode f
- {main = fresh \n.
- let name = "sds"+toCode n
- (v In body) = f (C (var name))
- in setCode Var +.+ c (type2string v + " " + name + " = " + toCode v +
- ";\n") +.+ setCode Setup +.+ unMain body}
- con f = defCode f
-
-defCode :: ((Code t p) -> In t (Main (Code u q))) -> Main (Code u r) | type t
-defCode f =
- {main = fresh \n.
- let name = "sds"+toCode n
- (v In body) = f (C (var name))
- in setCode Var +.+ c (type2string v + " " + name + " = " + toCode v +
- ";\n") +.+ setCode Setup +.+ unMain body}
-
-var :: String (ReadWrite (Code v q)) CODE -> CODE
-var sds Rd s = unC (embed (c sds)) Rd s
-var sds (Wrt v) s = unC (embed (c ("(" + sds + " = ") +.+ v +.+ c ")")) Rd s
-
-instance assign Code where
- (=.) (C v) e = embed (setMode SubExp +.+ C \rw c.v (Wrt (toExpr e)) c)
-instance seq Code where
- (>>=.) x f =
- getMode \mode. fresh \n. let v = "b" + toCode n in
- addBinds v +.+ var2Type x +.+ c (v + ";") +.+ nl +.+
- setMode (Assign v) +.+ x +.+ nl +.+ setMode mode +.+ f (embed (c v))
- (:.) x y = getMode \mode. setMode NoReturn +.+ embed x +.+ nl +.+ setMode mode +.+ y
-instance step Code where
- (>>*.) x f =
- getMode \mode. fresh \n.
- let v = "s" + toCode n in
- c "while(true) {" +.+ indent +.+ nl +.+
- var2Type x +.+ c (v + ";") +.+ nl +.+
- setMode (Assign v) +.+ x +.+ nl +.+
- setMode mode +.+ codeSteps (f (c v)) +.+
- unindent +.+ nl +.+ c "}"
-codeSteps :: [Step Code t] -> Code u p
-codeSteps [] = C \rw c.c
-codeSteps [Cond b e:x] =
- getMode \mode. setMode SubExp +.+
- c "if (" +.+ b +.+ c ") {" +.+ indent +.+ nl +.+
- setMode mode +.+ e +.+
- optBreak mode +.+ unindent +.+ nl +.+ c "}" +.+ nl +.+ setMode mode +.+ codeSteps x
-codeSteps [Ever e:x] =
- getMode \mode. e +.+ optBreak mode
-
-optBreak :: Mode -> Code u p
-optBreak mode =
- case mode of
- Return s = C \rw c.c
- _ = nl +.+ c "break;"
-
-instance setDelay Code where
- setDelay d t = embed (c "setDelay" +.+ brac (t +.+ c ", " +.+ d))
-instance mtask Code a | taskImp2 a & types a where
- task f =
- {main = freshMTask \n.
- let (app, a) = taskImp2 n types
- (b In main) = f (\d a.app (long d) a)
- in codeMTaskBody (loopCode n (b a)) (unMain main)}
-instance mtasks Code a b | taskImp2 a & types a & taskImp2 b & types b where
- tasks f =
- {main =
- freshMTask \t1.
- freshMTask \t2.
- let (app1, a1) = taskImp2 t1 types
- (app2, a2) = taskImp2 t2 types
- ((b1, b2) In main) = f ((\d a.app1 (long d) a),(\d a.app2 (long d) a))
- in codeMTaskBody (loopCode t2 (b2 a2)) (codeMTaskBody (loopCode t1 (b1 a1)) (unMain main))}
-loopCode :: Int (Code a b) -> Code c d
-loopCode n b =
- nl +.+ c "case " +.+ c n +.+ c ": {" +.+ indent +.+ nl +.+
- setMode NoReturn +.+ b +.+ nl +.+ c "break;" +.+
- unindent +.+ nl +.+ c "} "
-
-class taskImp2 a :: Int a -> ((Code Long p) a->Code MTask Expr, a) | /*long Code delay &*/ isExpr p
-instance taskImp2 () where
- taskImp2 n () = (app, ())
- where app d a = setBinds [] +.+ embed (c "newTask(" +.+ c n +.+ c ", " +.+ d +.+ c ")")
-instance taskImp2 (Code t p) where
- taskImp2 n type1 = (app, ta)
- where
- n0 = "t0p->a[0]"
- ta = c n0 +.+ type1
- app d a =
- setBinds [n0] +.+ embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- d +.+ c ", " +.+
- a +.+ c ")")
-instance taskImp2 (Code a p, Code b q) where
- taskImp2 n (type1, type2) = (app, (ta1, ta2)) where
- n0 = "t0p->a[0]"
- n1 = "t0p->a[1]"
- ta1 = c n0 +.+ type1
- ta2 = c n1 +.+ type2
- app d (a1, a2) =
- setBinds [n0,n1] +.+ embed (c "newTask(" +.+ c n +.+ c ", " +.+ long d +.+
- c ", " +.+ a1 +.+ c ", " +.+ a2 +.+ c ")")
-instance taskImp2 (Code a p, Code b q, Code c r) where
- taskImp2 n (type1, type2, type3) = (app, (ta1, ta2, ta3))
- where
- n0 = "t0p->a[0]"
- n1 = "t0p->a[1]"
- n2 = "t0p->a[2]"
- ta1 = c n0 +.+ type1
- ta2 = c n1 +.+ type2
- ta3 = c n2 +.+ type3
- app d (a1, a2, a3) =
- setBinds [n0,n1,n2] +.+ embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- d +.+ c ", " +.+
- a1 +.+ c ", " +.+
- a2 +.+ c ", " +.+
- a3 +.+ c ", 0)")
-instance taskImp2 (Code a p, Code b q, Code c r, Code d s) where
- taskImp2 n (type1, type2, type3, type4) = (app, (ta1, ta2, ta3, ta4))
- where
- n0 = "t0p->a[0]"
- n1 = "t0p->a[1]"
- n2 = "t0p->a[2]"
- n3 = "t0p->a[3]"
- ta1 = c n0 +.+ type1
- ta2 = c n1 +.+ type2
- ta3 = c n2 +.+ type3
- ta4 = c n3 +.+ type4
- app d (a1, a2, a3, a4) =
- setBinds [n0,n1,n2,n3] +.+ embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- d +.+ c ", " +.+
- a1 +.+ c ", " +.+
- a2 +.+ c ", " +.+
- a3 +.+ c ", " +.+
- a4 +.+ c ")")
-
-class taskImp a :: Int a -> (Int a->Code MTask Expr, a)
-instance taskImp () where
- taskImp n () = (app, ())
- where app i a = embed (c "newTask(" +.+ c n +.+ c ", " +.+ c i +.+ c ")")
-instance taskImp (Code t p) where
- taskImp n type1 = (app, ta)
- where
- ta = c "t0p->a[0]" +.+ type1
- app i a =
- embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- c i +.+ c ", " +.+
- a +.+ c ")")
-instance taskImp (Code a p, Code b q) where
- taskImp n (type1, type2) = (app, (ta1, ta2)) where
- ta1 = c "t0p->a[0]" +.+ type1
- ta2 = c "t0p->a[1]" +.+ type2
- app i (a1, a2) =
- embed (c "newTask(" +.+ c n +.+ c ", " +.+ c i +.+
- c ", " +.+ a1 +.+ c ", " +.+ a2 +.+ c ")")
-instance taskImp (Code a p, Code b q, Code c r) where
- taskImp n (type1, type2, type3) = (app, (ta1, ta2, ta3))
- where
- ta1 = c "t0p->a[0]" +.+ type1
- ta2 = c "t0p->a[1]" +.+ type2
- ta3 = c "t0p->a[2]" +.+ type3
- app i (a1, a2, a3) =
- embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- c i +.+ c ", " +.+
- a1 +.+ c ", " +.+
- a2 +.+ c ", " +.+
- a3 +.+ c ")")
-instance taskImp (Code a p, Code b q, Code c r, Code d s) where
- taskImp n (type1, type2, type3, type4) = (app, (ta1, ta2, ta3, ta4))
- where
- ta1 = c "t0p->a[0]" +.+ type1
- ta2 = c "t0p->a[1]" +.+ type2
- ta3 = c "t0p->a[2]" +.+ type3
- ta4 = c "t0p->a[3]" +.+ type4
- app i (a1, a2, a3, a4) =
- embed (c "newTask(" +.+
- c n +.+ c ", " +.+
- c i +.+ c ", " +.+
- a1 +.+ c ", " +.+
- a2 +.+ c ", " +.+
- a3 +.+ c ", " +.+
- a4 +.+ c ")")
-
-tasksMain :: Int Int ((a->Code MTask Expr,b->Code MTask Expr) -> In (a->Code c d,b->Code e f) (Main (Code g h))) -> Main (Code i j) | taskImp a & types a & taskImp b & types b
-tasksMain i j f =
- { main =
- freshMTask \n. freshMTask \m.
- let
- (app1, a1) = taskImp n types
- (app2, a2) = taskImp m types
- ((b1, b2) In {main = e}) = f (app1 i, app2 j)
- in
- codeMTaskBody (loopCode n (b1 a1) +.+ setMode NoReturn +.+ loopCode m (b2 a2)) e
- }
-class types a :: a
-instance types () where types = ()
-instance types (Code a p) | typeSelector a & isExpr p
- where types = typeSelector
-instance types (Code a p, Code b q) | typeSelector a & isExpr p & typeSelector b & isExpr q
- where types = (typeSelector, typeSelector)
-instance types (Code a p, Code b q, Code c r) | typeSelector a & isExpr p & typeSelector b & isExpr q & typeSelector c & isExpr r
- where types = (typeSelector, typeSelector, typeSelector)
-instance types (Code a p, Code b q, Code c r, Code d s) | typeSelector a & isExpr p & typeSelector b & isExpr q & typeSelector c & isExpr r & typeSelector d & isExpr s
- where types = (typeSelector, typeSelector, typeSelector, typeSelector)
-
-codeMTaskBody :: (Code v w) (Code c d) -> Code e f
-codeMTaskBody loop e =
- getMode \mode.
- setMode NoReturn +.+
- setCode Loop +.+ loop +.+
- setMode mode +.+ setCode Setup +.+ embed e
-instance fun Code () where
- fun f =
- {main = getMode \mode. fresh \n.
- let fname = c ("f" + toCode n)
- (g In {main=e}) = f (\x.embed (fname +.+ c " ()"))
- in setCode Fun +.+ c "\n" +.+ resType f +.+ c " " +.+ fname +.+ c " () " +.+
- funBody (setMode (Return (toCode (resType2 f))) +.+ setBinds [] +.+ g ()) +.+ setCode Setup +.+ setMode mode +.+ e
- }
-instance fun Code (Code t p) | type, showType t & isExpr p where
- fun f =
- {main =
- getMode \mode. fresh \n.
- let fname = c ("f" + toCode n)
- aname = "a" + toCode n
- (g In {main=e}) = f (\x.embed (fname +.+ c " " +.+ brac x))
- in setCode Fun +.+ c "\n" +.+ resType f +.+ c " " +.+ fname +.+ c " " +.+
- brac (argTypes f +.+ c (" " + aname)) +.+
- funBody (setMode (Return (toCode (resType2 f))) +.+ setBinds [aname] +.+ g (embed (c aname))) +.+ setCode Setup +.+ setMode mode +.+ e
- }
-instance fun Code (Code a p, Code b q) | showType a & showType b where
- fun f =
- {main =
- getMode \mode. fresh \n.
- let fname = c ("f" + toCode n + " ")
- aname = "a" + toCode n //+ " "
- bname = "b" + toCode n //+ " "
- (atype, btype) = argTypes f
- (g In main)
- = f (\(x,y).embed (fname +.+ codeOp2 x ", " y))
- in setCode Fun +.+ nl +.+ resType f +.+ fname +.+
- codeOp2 (atype +.+ c aname) ", " (btype +.+ c bname) +.+
- funBody (setMode (Return (toCode (resType2 f))) +.+
- setBinds [aname,bname] +.+ g (embed (c aname), embed (c bname))) +.+
- setCode Setup +.+ setMode mode +.+ unMain main
- }
-instance fun Code (Code a p, Code b q, Code c r) | showType a & showType b & showType c where
- fun f =
- {main =
- getMode \mode. fresh \n.
- let fname = c ("f" + toCode n)
- aname = "a" + toCode n
- bname = "b" + toCode n
- cname = "c" + toCode n
- (atype,btype,ctype) = argTypes f
- (g In {main=e}) = f (\(x,y,z).embed (fname +.+ c " " +.+ brac (x +.+ c ", " +.+ y +.+ c ", " +.+ z)))
- in setCode Fun +.+ c "\n" +.+ resType f +.+ c " " +.+ fname +.+ c " " +.+
- brac (atype +.+ c (" " + aname + ", ") +.+ btype +.+ c (" " + bname + ", ") +.+ ctype +.+ c (" " + cname)) +.+
- funBody (setMode (Return (toCode (resType2 f))) +.+
- setBinds [aname,bname,cname] +.+ g (embed (c aname), embed (c bname), embed (c cname))) +.+ setCode Setup +.+ setMode mode +.+ e
- }
-instance output Code where
- output x = embed (c "Serial.println(" +.+ x +.+ c ")")
-instance pinMode Code where
- pinmode p m = embed (c ("pinMode(" + toCode p + ", " + consName{|*|} m + ")"))
-instance digitalIO Code where
- digitalRead p = embed (c ("digitalRead(" + toCode p + ")"))
- digitalWrite p b = embed (c ("digitalWrite(" + toCode p + ", ") +.+ b +.+ c ")")
-instance dIO Code where
- dIO p = C (ioc p) where
- ioc :: p (ReadWrite (Code t q)) CODE -> CODE | pin, readPinD p
- ioc p Rd s = f Rd s where (C f) = embed (c ("digitalRead(" + toCode p + ")"))
- ioc p (Wrt v) s = f Rd s where (C f) = embed (c ("pWrite(" + toCode p + ", ") +.+ v +.+ c ")")
-instance aIO Code where
- aIO p = C (ioc p) where
- ioc :: p (ReadWrite (Code t q)) CODE -> CODE | pin p
- ioc p Rd s = unC (embed (c ("analogRead(" + toCode p + ")"))) Rd s
- ioc p (Wrt v) s = unC (embed (c ("pWrite(" + toCode p + ", ") +.+ v +.+ c ")")) Rd s
-instance analogIO Code where
- analogRead p = embed (c ("analogRead(" + toCode p + ")"))
- analogWrite p b = embed (c ("analogWrite(" + toCode p + ", ") +.+ b +.+ c ")")
-instance noOp Code where noOp = C \rw c.c
-
-:: Code a p = C ((ReadWrite (Code a Expr)) CODE -> CODE)
-:: CODE =
- { fresh :: Int
- , freshMTask :: Int
- , funs :: [String]
- , ifuns :: Int
- , vars :: [String]
- , ivars :: Int
- , setup :: [String]
- , isetup :: Int
- , loop :: [String]
- , iloop :: Int
- , includes :: [String]
- , def :: Def
- , mode :: Mode
- , binds :: [String]
- }
-
-unC :: (Code a p) -> ((ReadWrite (Code a Expr)) CODE -> CODE)
-unC (C f) = f
-
-:: Def = Var | Fun | Setup | Loop
-:: Mode = /*MainMode |*/ NoReturn | Return String | SubExp | Assign String
-
-setMode :: Mode -> Code a p
-setMode m = C \rw c.{c & mode = m}
-
-getMode :: (Mode -> Code a p) -> Code a p
-getMode f = C \rw c.unC (f c.mode) rw c
-
-embed :: (Code a p) -> Code a p
-embed e =
- getMode \m. case m of
- NoReturn = setMode SubExp +.+ e +.+ c ";"
- Return "void" = setMode SubExp +.+ e +.+ c ";"
- Return t = c "return " +.+ setMode SubExp +.+ e +.+ c ";"
- Assign s = c (s + " = ") +.+ setMode SubExp +.+ e +.+ c ";"
- SubExp = e
- _ = abort "\n\nembed: unknown mode.\n"
-
-(+.+) infixl 5 :: (Code a p) (Code b q) -> Code c r
-(+.+) (C f) (C g) = C \rw c.g Rd (f Rd c)
-
-fresh :: (Int -> (Code a p)) -> (Code a p)
-fresh f = C \rw c.unC (f c.fresh) rw {c & fresh = c.fresh + 1}
-
-freshMTask :: (Int -> (Code a p)) -> (Code a p)
-freshMTask f = C \rw c.unC (f c.freshMTask) rw {c & freshMTask = c.freshMTask + 1}
-
-setCode :: Def -> (Code a p)
-setCode d = C \rw c.{c & def = d}
-
-getCode :: (Def -> Code a p) -> (Code a p)
-getCode f = C \rw c.unC (f c.def) rw c
-
-brac :: (Code a p) -> Code b q
-brac e = c "(" +.+ e +.+ c ")"
-
-funBody :: (Code a p) -> Code b q
-funBody e = c "{" +.+ indent +.+ nl +.+ e +.+ unindent +.+ nl +.+ c "}" +.+ nl
-
-codeOp2 :: (Code a p) String (Code b q) -> Code c r
-codeOp2 x n y = embed (brac (x +.+ c n +.+ y))
-
-include :: String -> Code a b
-include lib = C \rw c.{c & includes = [lib:c.includes]}
-
-argList :: [a] -> String | toCode a
-argList [a] = toCode a
-argList [a:x] = toCode a + "," + argList x
-argList [] = ""
-
-c :: a -> Code b p | toCode a
-c a = C \rw c.case c.def of
- Fun = {c & funs = [toCode a: c.funs]}
- Var = {c & vars = [toCode a: c.vars]}
- Setup = {c & setup = [toCode a: c.setup]}
- Loop = {c & loop = [toCode a: c.loop]}
-
-indent :: Code a p
-indent =
- C \rw c.case c.def of
- Fun = {c & ifuns = inc c.ifuns}
- Var = {c & ivars = inc c.ivars}
- Setup = {c & isetup = inc c.isetup}
- Loop = {c & iloop = inc c.iloop}
-
-unindent :: Code a p
-unindent =
- C \rw c.case c.def of
- Fun = {c & ifuns = dec c.ifuns}
- Var = {c & ivars = dec c.ivars}
- Setup = {c & isetup = dec c.isetup}
- Loop = {c & iloop = dec c.iloop}
-where
- dec n | n > 1
- = n - 1
- = 0
-
-nl :: Code a p
-nl =
- C \rw c.case c.def of
- Fun = {c & funs = [str c.ifuns: c.funs]}
- Var = {c & vars = [str c.ivars: c.vars]}
- Setup = {c & setup = [str c.isetup: c.setup]}
- Loop = {c & loop = [str c.iloop: c.loop]}
-where
- str n = toString ['\n':repeatn (tabSize * n) ' ']
-
-setBinds :: [String] -> Code a p
-setBinds list = C \rw c.{c & binds = list}
-
-addBinds :: String -> Code a p
-addBinds name = C \rw c.{c & binds = [name:c.binds]}
-
-getBinds :: ([String] -> Code a p) -> (Code a p)
-getBinds f = C \rw c.unC (f c.binds) rw c
-
-// ----- driver ----- //
-
-compile :: (Main (Code a p)) -> [String]
-compile {main=(C f)} =
- ["/*\n"
- ," Generated code for Arduino\n"
- ," Pieter Koopman, pieter@cs.ru.nl\n"
- ,"*/\n"
- ,"\n"
- ,"#define MAX_ARGS 4\n"
- ,"#define MAX_TASKS 20\n"
- ,"#define MAX_TASK_NO MAX_TASKS - 1\n"
- ,"#define NEXT_TASK(n) ((n) == MAX_TASK_NO ? 0 : (n) + 1)\n"
- ,"\n"
- ,"typedef union Arg {\n"
- ," int i;\n"
- ," bool b;\n"
- ," char c;\n"
-// ," float f;\n" // requires 4 bytes
- ," word w;\n"
- ,"} ARG;\n"
- ,"\n"
- ,"typedef struct Task {\n"
- ," byte id;\n"
- ," long wait;\n"
- ," ARG a[MAX_ARGS];\n"
- ,"} TASK;\n"
- ,"\n"
- ] ++
- foldr (\lib c.["#include <":lib:".h>\n":c]) [] (mkset c.includes) ++
- ["\n// --- variables ---\n"
- ,"TASK tasks[MAX_TASKS];\n"
- ,"byte t0 = 0, tc = 0, tn = 0;\n"
- ,"long delta;\n"
- ,"\n"
- ,"int vInt;\n"
- ,"bool vBool;\n"
- ,"char vChar;\n"
- ,"float vFloat;\n"
- ,"unsigned long time = 0;\n"
- :reverse c.vars
- ] ++
- ["\n// --- functions ---\n"
- ,"byte newTask(byte id, long wait, word a0 = 0, word a1 = 0, word a2 = 0, word a3 = 0) {\n"
- ," TASK *tnp = &tasks[tn];\n"
- ," tnp->id = id;\n"
- ," tnp->wait = wait;\n"
- ," tnp->a[0].w = a0;\n"
- ," tnp->a[1].w = a1;\n"
- ," tnp->a[2].w = a2;\n"
- ," tnp->a[3].w = a3;\n"
- ," byte r = tn;\n"
- ," tn = NEXT_TASK(tn);\n"
- ," return r;\n"
- ,"}\n"
- ,"\n"
- ,"byte setDelay(byte t, long d) {\n"
- ," tasks[t].wait = d;\n"
- ," return t;\n"
- ,"}\n"
- ,"boolean pressed(int b) {\n"
- ," pinMode(A0, INPUT);\n"
- ," int a0 = analogRead(A0);\n"
- ," switch (b) {\n"
- ," case 0: return a0 < ",toString RightBound,"; // right\n"
- ," case 1: return ",toString RightBound," < a0 && a0 < ",toString UpBound,"; // up\n"
- ," case 2: return ",toString UpBound," < a0 && a0 < ",toString DownBound,";// down\n"
- ," case 3: return ",toString DownBound," < a0 && a0 < ",toString LeftBound,";//left\n"
- ," case 4: return ",toString LeftBound," < a0 && a0 < ",toString SelectBound,";//select\n"
- ," default: return ",toString SelectBound," < a0; //no button\n"
- ," }\n"
- ,"}\n"
- ,"boolean pWrite (int pin, boolean b) {\n"
- ," pinMode(pin, OUTPUT);\n"
- ," digitalWrite(pin, b);\n"
- ," return b;\n"
- ,"}\n"
- ,"int pWrite (int pin, int i) {\n"
- ," pinMode(pin, OUTPUT);\n"
- ," analogWrite(pin, i);\n"
- ," return i;\n"
- ,"}\n"
- :reverse c.funs
- ] ++
- ["\n// --- setup --- \n"
- ,"void setup () {\n"
- ," Serial.begin(9600);\n"
- ," "
- :reverse c.setup
- ] ++
- ["\n}\n"
- ,"\n// --- loop --- \n"
- ,"void loop () {\n"
- ," if (t0 != tn) {\n"
- ," if (t0 == tc) {\n"
- ," unsigned long time2 = millis();\n"
- ," delta = time2 - time;\n"
- ," time = time2;\n"
- ," tc = tn;\n"
- ," };\n"
- ," TASK* t0p = &tasks[t0];\n"
- ," t0p->wait -= delta;\n"
- ," if (t0p->wait > 0L) {\n"
- ," newTask(t0p->id, t0p->wait, t0p->a[0].w, t0p->a[1].w, t0p->a[2].w, t0p->a[3].w);\n"
- ," } else {\n"
- ," switch (t0p->id) {"
- :reverse c.loop
- ] ++
- ["\n"
- ," default:\n"
- ," Serial.println(\"stopped\");\n"
- ," t0 = tn; // no known task: force termination of tasks\n"
- ," return;\n"
- ," };\n"
- ," }\n"
- ," t0 = NEXT_TASK(t0);\n"
- ," }\n"
- ,"}\n"
- ]
-where c = f Rd newCode
-
-mkset :: [a] -> [a] | Eq a
-mkset [a:x] = [a:mkset (filter ((<>) a) x)]
-mkset [] = []
-
-newCode :: CODE
-newCode =
- { fresh = 0
- , freshMTask = 0
- , funs = []
- , ifuns = 0
- , vars = []
- , ivars = 0
- , setup = []
- , isetup = 1
- , loop = []
- , iloop = 4
- , includes = []
- , def = Setup
- , mode = NoReturn
- , binds = []
- }
-
-// ----- simulation ----- //
-
-eval :: (Main (Eval t p)) -> [String] | toString t
-eval {main=(E f)} = [toString (fst (f Rd state0))]
-
-:: State =
- { tasks :: [(Int, State->State)]
- , store :: [Dyn]
- , dpins :: [(DigitalPin, Bool)]
- , apins :: [(AnalogPin, Int)]
- , serial:: [String]
- , millis:: Int
- }
-
-state0 :: State
-state0 = {store = [], tasks = [], serial = [], millis = 0, dpins = [] , apins = []}
-
-//:: TaskSim :== (Int, State->State)
-:: Eval t p = E ((ReadWrite t) State -> (t, State))
-toS2S :: (Eval t p) -> (State->State)
-toS2S (E f) = \state.snd (f Rd state)
-
-unEval :: (Eval t p) -> ((ReadWrite t) State -> (t, State))
-unEval (E f) = f
-
-:: ReadWrite t = Rd | Wrt t | Updt (t->t)
-
-(>>==) infixl 1 :: (Eval a p) (a -> Eval b q) -> Eval b r
-//(>>== ) (E f) g = E \r s. let (a, s2) = f Rd s; (E h) = g a in h Rd s2
-(>>==) (E f) g = E\r s.let (a,t) = f Rd s in unEval (g a) Rd t
-
-rtrn :: t -> Eval t p
-rtrn a = E \r s -> (a, s)
-
-yield :: t (Eval s p) -> Eval t Expr
-//yield a (E f) = E (\r s.(\(_,t).(a,t)) (f r s))
-yield a (E f) = E \r s.(a,snd (f Rd s))
-
-instance arith Eval where
- lit a = rtrn a
- (+.) x y = x >>== \a. y >>== \b. rtrn (a + b)
- (-.) x y = x >>== \a. y >>== \b. rtrn (a - b)
- (*.) x y = x >>== \a. y >>== \b. rtrn (a * b)
- (/.) x y = x >>== \a. y >>== \b. rtrn (a / b)
-instance boolExpr Eval where
- (&.) x y = x >>== \a. if a y (rtrn False) // lazy AND
- (|.) x y = x >>== \a. if a (rtrn True) (y >>== rtrn)
- Not x = x >>== \a. rtrn (not a)
- (==.) x y = x >>== \a. y >>== \b. rtrn (a == b)
- (!=.) x y = x >>== \a. y >>== \b. rtrn (a <> b)
- (<.) x y = x >>== \a. y >>== \b. rtrn (a < b)
- (>.) x y = x >>== \a. y >>== \b. rtrn (a > b)
- (<=.) x y = x >>== \a. y >>== \b. rtrn (a <= b)
- (>=.) x y = x >>== \a. y >>== \b. rtrn (a >= b)
-instance If Eval p q Expr where
- If c t e = c >>== \b.if b (toExpr t) (toExpr e)
-instance IF Eval where
- IF c t e = c >>== \b.if b (yield () t) (yield () e)
- (?) c t = c >>== \b.if b (yield () t) (rtrn ())
-instance var2 Eval where
- var2 v f = defEval2 v f
- con2 v f = defEval2 v f
-
-defEval2 :: t ((Eval t p)->Main (Eval u q)) -> (Main (Eval u q)) | dyn t
-defEval2 v f =
- {main = E (\r s.(length s.store
- , {s & store = s.store ++ [toDyn v]}))
- >>== \n.unMain (f (E (read n)))}
-instance sds Eval where
- sds f = defEval f
- con f = defEval f
-
-defEval :: ((Eval t p)->In t (Main (Eval u q))) -> (Main (Eval u q)) | dyn t
-defEval f =
- {main = E \r s.let (v In g) = f (E (read (length s.store))) in
- unEval (unMain g) r {s & store = s.store ++ [toDyn v]}}
-instance fun Eval x | arg x where
- fun f = e where (g In e) = f (\a.toExpr (g a))
-instance mtask Eval x | arg x where
- task f = e where
- (t In e) = f (\d a.long d >>== \(L i).E\r s.(MTask (length s.tasks),{s&tasks=[(i,toS2S (t a)):s.tasks]}))
-instance mtasks Eval x y | arg x & arg y where
- tasks f = e where
- ((t,u) In e) =
- f ((\d a.long d >>== \(L i).E\r s.(MTask (length s.tasks),{s&tasks=[(i,toS2S (t a)):s.tasks]}))
- ,(\d b.long d >>== \(L j).E\r s.(MTask (length s.tasks),{s&tasks=[(j,toS2S (u b)):s.tasks]}))
- )
-instance setDelay Eval where
- setDelay d t = d >>== \(L x). t >>== \(MTask n).E \r s.(MTask n,{s & tasks = updateAt n (x,snd (s.tasks !! n)) s.tasks})
-class toExpr v where toExpr :: (v t p) -> v t Expr
-instance toExpr Eval where toExpr (E f) = E f
-instance toExpr Code where toExpr (C f) = C f
-instance seq Eval where
- (>>=.) x f = x >>== f o rtrn
- (:.) x y = x >>== \_. y
-instance assign Eval where
- (=.) (E v) e = e >>== \a. E \r s.v (Wrt a) s
-instance output Eval where
- output x = x >>== \a.E \r s.((),{s & serial = s.serial ++ [toCode a]})
-instance pinMode Eval where
- pinmode p m = rtrn ()
-instance digitalIO Eval where
- digitalRead p = E \rw s=:{dpins, apins}.(readPinD p dpins apins, s)
- digitalWrite p b = b >>== \a. E \rw s.(a, writePinD p a s)
-instance analogIO Eval where
- analogRead p = E \rw s=:{apins}. (readPinA p apins, s)
- analogWrite p b = b >>== \a. E \rw s.(a, writePinA p a s)
-instance noOp Eval where noOp = E \r s.(undef,s)
-
-class arg x :: x -> Int
-instance arg () where arg _ = 0
-instance arg (Eval t p) | type t where arg _ = 1
-instance arg (Eval t p, Eval u q) | type t & type u where arg _ = 2
-instance arg (Eval t p, Eval u q, Eval v r) | type t & type u & type v where arg _ = 3
-instance arg (Eval t p, Eval u q, Eval v r, Eval w s) | type t & type u & type v where arg _ = 4
-
-instance + String where (+) x y = x +++ y
-
-readPinA :: AnalogPin [(AnalogPin, Int)] -> Int
-readPinA p lista
- = case [b \\ (q, b) <- lista | p == q] of
- [] = 0
- [a:x] = a
-
-writePinA :: AnalogPin Int State -> State
-writePinA p x s
- = {s & apins = [(p, x):[(q, y) \\ (q, y) <- s.apins | p <> q]]}
-
-class readPinD p :: p [(DigitalPin,Bool)] [(AnalogPin,Int)] -> Bool
-instance readPinD DigitalPin where
- readPinD p listd lista
- = case [b \\ (q,b) <- listd | p == q] of
- [] = False
- [a:x] = a
-instance readPinD AnalogPin where
- readPinD p listd lista
- = case [b \\ (q,b) <- lista | p == q] of
- [] = False
- [a:x] = a <> 0
-class writePinD p :: p Bool State -> State
-instance writePinD DigitalPin where
- writePinD p b s=:{dpins} = {s & dpins = [(p, b):[(q, c) \\ (q, c) <- dpins | p <> q]]}
-instance writePinD AnalogPin where
- writePinD p b s=:{apins} = {s & apins = [(p, if b 1 0):[(q, c) \\ (q, c) <- apins | p <> q]]}
-
-
-// ----- Interactive Simulation ----- //
-
-derive class iTask DigitalPin, AnalogPin, Dyn, StateInterface, DisplayVar, Pin
-
-simulate :: (Main (Eval a p)) -> Task ()
-simulate {main=(E f)} = setup state0 where
- setup s =
- updateInformation "State" [] (toView s)
- >>* [ OnAction ActionFinish (always shutDown)
- , OnAction (Action "setup" []) (hasValue
- (\si.simloop (snd (f Rd (mergeView s si)))))
- ]
- simloop s =
- updateInformation "State" [] (toView s)
- >>* [ OnAction ActionFinish (always shutDown)
- , OnAction (Action "clear serial" []) (always (simloop {s & serial = []}))
- , OnAction ActionNew (always (setup state0))
- : if (isEmpty s.tasks)
- []
- [OnAction (Action "loop" []) (hasValue
- \si.simloop (step (mergeView s si)))
- ]
- ]
-
-toView :: State -> StateInterface
-toView s =
- { serialOut = Display s.serial
- , analogPins = s.apins
- , digitalPins = s.dpins
- , var2iables = map toDisplayVar s.store
- , timer = s.millis
- , taskCount = Display (length s.tasks)
- }
-
-mergeView :: State StateInterface -> State
-mergeView s si =
- { s
- & store = [fromDisplayVar new old \\ new <- si.var2iables & old <- s.store]
- , dpins = si.digitalPins
- , apins = si.analogPins
-// , serial = si.serialOut
- , millis = si.timer
- }
-
-:: StateInterface =
- { serialOut :: Display [String]
- , analogPins :: [(AnalogPin, Int)]
- , digitalPins :: [(DigitalPin, Bool)]
- , var2iables :: [DisplayVar]
- , timer :: Int
- , taskCount :: Display Int
- }
-
-toDisplayVar :: Dyn -> DisplayVar
-toDisplayVar (Dyn [v])
- # i = toInt v
- | toString i == v
- = INT i
- = Variable v
-toDisplayVar (Dyn ["L",v]) = LONG (toInt v)
-toDisplayVar (Dyn ["Servo",pinKind,pin,pos]) = Servo (fromJust (fromDyn (Dyn [pinKind,pin]))) (toInt pos)
-toDisplayVar (Dyn ["LCD",_,_,_,_,_,l1,_,l2,_]) = LCD16x2 l1 l2
-toDisplayVar (Dyn l) = DisplayVar l
-
-fromDisplayVar :: DisplayVar Dyn -> Dyn
-fromDisplayVar (Variable v) dyn = Dyn [v]
-fromDisplayVar (INT v) dyn = Dyn [toString v]
-fromDisplayVar (LONG v) dyn = Dyn ["L",toString v]
-fromDisplayVar (Servo pin pos) dyn = Dyn (["Servo":let (Dyn p) = toDyn pin in p] ++ [toString pos])
-fromDisplayVar (LCD16x2 l1 l2) (Dyn list) = Dyn (updateAt 6 l1 (updateAt 8 l2 list))
-fromDisplayVar (DisplayVar l) dyn = Dyn l
-
-:: DisplayVar
- = Variable String
- | INT Int
- | LONG Int
- | Servo Pin Int
- | LCD16x2 String String
- | DisplayVar [String]
-
-
-step :: State -> State
-step s =
- foldr appTask {s & millis = s.millis + delta, tasks = []}
- [(w - delta, f) \\ (w, f) <- s.tasks]
-where delta = foldl1 min (map fst s.tasks) // smallest wait
-
-appTask t=:(w,f) s | w <= 0
- = f s
- = {s & tasks = [t:s.tasks]}
-
-foldl1 op [a:x] = foldl op a x
-foldr1 op l :== foldr l
- where
- foldr [a] = a
- foldr [a:x] = op a (foldr x)
-
-class stringQuotes t | type t :: (Code t p) -> Code t p
-instance stringQuotes String where stringQuotes x = c "\"" +.+ x +.+ c "\""
-instance stringQuotes t where stringQuotes x = x
-
-
-derive toGenDynamic (), MTask, DigitalPin, AnalogPin, Pin, [], Long, LCD //, Servo
-derive fromGenDynamic (), MTask, DigitalPin, AnalogPin, Pin, [], Long, LCD //, Servo
-instance toCode () where toCode _ = ""
-instance == () where (==) _ _ = True
-
// ----- long ----- //
:: Long = L Int // 32 bit on Arduino
-instance toCode Long where toCode (L i) = toCode i + "L"
instance + Long where (+) (L x) (L y) = L (x + y)
instance - Long where (-) (L x) (L y) = L (x + y)
instance * Long where (*) (L x) (L y) = L (x + y)
// ----- tools ----- //
-class toCode a :: a -> String
-instance toCode Bool where toCode b = if b "true" "false"
-instance toCode Int where toCode a = toString a
-instance toCode Real where toCode a = toString a
-instance toCode Char where
- toCode '\0' = "'\\0'"
- toCode '\n' = "'\\n'"
- toCode '\\' = "\\"
- toCode a = "'" + toString a + "'"
-instance toCode String where toCode s = s
-instance toCode DigitalPin where toCode x = s%(1, size s - 1) where s = consName{|*|} x
-instance toCode AnalogPin where toCode x = consName{|*|} x
-derive consName DigitalPin, AnalogPin, PinMode
-
instance == DigitalPin where (==) x y = x === y
instance == AnalogPin where (==) x y = x === y
+instance == UserLED where (==) x y = x === y
-derive consIndex DigitalPin, AnalogPin
+//derive class gCons UserLED, Long, Pin, Button, UserLED, AnalogPin, DigitalPin, PinMode
+//derive class iTask UserLED, Long, Pin, Button, UserLED, AnalogPin, DigitalPin, PinMode
tab =: toString (repeatn tabSize ' ')
tabSize :== 2