module LLVM.Extra.Iterator where
import qualified LLVM.Extra.MaybeContinuation as MaybeCont
import qualified LLVM.Extra.Maybe as Maybe
import qualified LLVM.Extra.ArithmeticPrivate as A
import qualified LLVM.Extra.Class as Class
import qualified LLVM.Extra.Control as C
import qualified LLVM.Core as LLVM
import LLVM.Util.Loop (Phi, )
import LLVM.Core
(CodeGenFunction, Value, value, valueOf,
CmpRet, CmpResult, IsInteger, IsType, IsConst, )
import Foreign.Ptr (Ptr, )
import qualified Control.Monad.Trans.State as MS
import qualified Control.Applicative as App
import qualified Control.Functor.HT as FuncHT
import Control.Monad (void, (<=<), )
import Control.Applicative (Applicative, liftA2, (<$>), (<$), )
import Data.Tuple.HT (mapFst, mapSnd, )
import Prelude2010 hiding (iterate, takeWhile, take, mapM)
import Prelude ()
data T r a =
forall s. (Phi s, Class.Undefined s) =>
Cons s (forall z. (Phi z) => s -> MaybeCont.T r z (a,s))
mapM_ :: (a -> CodeGenFunction r ()) -> T r a -> CodeGenFunction r ()
mapM_ f (Cons s next) =
void $
C.loopWithExit s
(\s0 ->
MaybeCont.resolve (next s0)
(return (valueOf False, s0))
(\(a,s1) -> (valueOf True, s1) <$ f a))
return
mapState_ ::
(Phi t) =>
(a -> t -> CodeGenFunction r t) ->
T r a -> t -> CodeGenFunction r t
mapState_ f (Cons s next) t =
snd <$>
C.loopWithExit (s,t)
(\(s0,t0) ->
MaybeCont.resolve (next s0)
(return (valueOf False, (s0,t0)))
(\(a,s1) -> (\t1 -> (valueOf True, (s1,t1))) <$> f a t0))
return
mapStateM_ ::
(Phi t) =>
(a -> MS.StateT t (CodeGenFunction r) ()) ->
T r a -> MS.StateT t (CodeGenFunction r) ()
mapStateM_ f xs =
MS.StateT $ \t ->
(,) () <$> mapState_ (\a t0 -> snd <$> MS.runStateT (f a) t0) xs t
mapWhileState_ ::
(Phi t) =>
(a -> t -> CodeGenFunction r (Value Bool, t)) ->
T r a -> t -> CodeGenFunction r t
mapWhileState_ f (Cons s next) t =
snd <$>
C.loopWithExit (s,t)
(\(s0,t0) ->
MaybeCont.resolve (next s0)
(return (valueOf False, (s0,t0)))
(\(a,s1) -> (\(b,t1) -> (b, (s1,t1))) <$> f a t0))
return
empty :: T r a
empty = Cons () (\() -> MaybeCont.nothing)
singleton :: a -> T r a
singleton a =
Cons
(valueOf True)
(\running -> MaybeCont.guard running >> return (a, valueOf False))
cons :: (Phi a, Class.Undefined a) => a -> T r a -> T r a
cons a0 (Cons s next) =
Cons Maybe.nothing
(fmap (mapSnd Maybe.just) .
MaybeCont.fromMaybe .
(\ms -> Maybe.run ms
(return $ Maybe.just (a0,s))
(MaybeCont.toMaybe . next)))
instance Functor (T r) where
fmap f (Cons s next) = Cons s (\s0 -> mapFst f <$> next s0)
instance Applicative (T r) where
pure a = Cons () (\() -> return (a,()))
Cons fs fnext <*> Cons as anext =
Cons (fs,as)
(\(fs0,as0) -> do
(f,fs1) <- fnext fs0
(a,as1) <- anext as0
return (f a, (fs1,as1)))
mapM :: (a -> CodeGenFunction r b) -> T r a -> T r b
mapM f (Cons s next) = Cons s (MaybeCont.lift . FuncHT.mapFst f <=< next)
mapMaybe ::
(Phi b, Class.Undefined b) =>
(a -> CodeGenFunction r (Maybe.T b)) -> T r a -> T r b
mapMaybe f = catMaybes . mapM f
catMaybes :: (Phi a, Class.Undefined a) => T r (Maybe.T a) -> T r a
catMaybes (Cons s next) =
Cons s
(\s0 ->
MaybeCont.fromMaybe $
fmap (\(ma,s2) -> fmap (flip (,) s2) ma) $
C.loopWithExit s0
(\s1 ->
MaybeCont.resolve (next s1)
(return (valueOf False, (Maybe.nothing, s1)))
(\(ma,s2) ->
Maybe.run ma
(return (valueOf True, (Maybe.nothing, s2)))
(\a -> return (valueOf False, (Maybe.just a, s2)))))
(return . snd))
takeWhileJust :: T r (Maybe.T a) -> T r a
takeWhileJust (Cons s next) =
Cons s (FuncHT.mapFst MaybeCont.fromPlainMaybe <=< next)
takeWhile :: (a -> CodeGenFunction r (Value Bool)) -> T r a -> T r a
takeWhile p = takeWhileJust . mapM (\a -> flip Maybe.fromBool a <$> p a)
iterate ::
(Phi a, Class.Undefined a) => (a -> CodeGenFunction r a) -> a -> T r a
iterate f a = Cons a (\a0 -> MaybeCont.lift $ fmap ((,) a0) $ f a0)
cartesianAux ::
(Phi a, Phi b, Class.Undefined a, Class.Undefined b) =>
T r a -> T r b -> T r (Maybe.T (a,b))
cartesianAux (Cons sa nextA) (Cons sb nextB) =
Cons (Maybe.nothing,sa,sb)
(\(ma0,sa0,sb0) -> do
(a1,sa1) <-
MaybeCont.alternative
(MaybeCont.fromMaybe $ return $ fmap (flip (,) sa0) ma0)
(nextA sa0)
MaybeCont.lift $
MaybeCont.resolve (nextB sb0)
(return (Maybe.nothing,(Maybe.nothing,sa1,sb)))
(\(b1,sb1) ->
return (Maybe.just (a1,b1), (Maybe.just a1, sa1, sb1))))
cartesian ::
(Phi a, Phi b, Class.Undefined a, Class.Undefined b) =>
T r a -> T r b -> T r (a,b)
cartesian as bs = catMaybes $ cartesianAux as bs
countDown ::
(Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> T r (Value i)
countDown len =
takeWhile (A.cmp LLVM.CmpLT (value LLVM.zero)) $ iterate A.dec len
take ::
(Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> T r a -> T r a
take len xs = liftA2 const xs (countDown len)
arrayPtrs :: (IsType a) => Value (Ptr a) -> T r (Value (Ptr a))
arrayPtrs = iterate A.advanceArrayElementPtr
fixedLengthLoop ::
(Phi s,
Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> s ->
(s -> CodeGenFunction r s) ->
CodeGenFunction r s
fixedLengthLoop len start loopBody =
mapState_ (const loopBody) (countDown len) start
arrayLoop ::
(Phi a, IsType b,
Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> Value (Ptr b) -> a ->
(Value (Ptr b) -> a -> CodeGenFunction r a) ->
CodeGenFunction r a
arrayLoop len ptr start loopBody =
mapState_ loopBody (take len $ arrayPtrs ptr) start
arrayLoopWithExit ::
(Phi s, IsType a,
Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> Value (Ptr a) -> s ->
(Value (Ptr a) -> s -> CodeGenFunction r (Value Bool, s)) ->
CodeGenFunction r (Value i, s)
arrayLoopWithExit len ptr0 start loopBody = do
(i, end) <-
mapWhileState_
(\(i,ptr) (_i,s) -> mapSnd ((,) i) <$> loopBody ptr s)
(liftA2 (,) (countDown len) (arrayPtrs ptr0))
(len,start)
pos <- A.sub len i
return (pos, end)
arrayLoop2 ::
(Phi s, IsType a, IsType b,
Num i, IsConst i, IsInteger i, CmpRet i, CmpResult i ~ Bool) =>
Value i -> Value (Ptr a) -> Value (Ptr b) -> s ->
(Value (Ptr a) -> Value (Ptr b) -> s -> CodeGenFunction r s) ->
CodeGenFunction r s
arrayLoop2 len ptrA ptrB start loopBody =
mapState_ (uncurry loopBody)
(take len $ liftA2 (,) (arrayPtrs ptrA) (arrayPtrs ptrB)) start