synthesizer-llvm-0.8.2: src/Synthesizer/LLVM/Parameterized/Signal.hs
{-# LANGUAGE NoImplicitPrelude #-}
{-# LANGUAGE TypeFamilies #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE ScopedTypeVariables #-}
{-# LANGUAGE Rank2Types #-}
{-# LANGUAGE ForeignFunctionInterface #-}
module Synthesizer.LLVM.Parameterized.Signal (
T,
adjacentNodes02,
adjacentNodes13,
amplify,
amplifyStereo,
Sig.empty,
append,
cycle,
drop,
exponential2,
exponentialCore,
exponentialBounded2,
exponentialBoundedCore,
interpolateConstant,
iterate,
lazySize,
map,
mapSimple,
mapAccum,
Sig.mix,
Sig.mixExt,
noise,
noiseCore,
osci,
osciCore,
osciSaw,
osciSimple,
parabolaCore,
parabolaFadeIn,
parabolaFadeInInf,
parabolaFadeInMap,
parabolaFadeOut,
parabolaFadeOutInf,
parabolaFadeOutMap,
piecewiseConstant,
ramp,
rampCore,
rampInf,
rampSlope,
reparameterize,
tail,
constant,
Sig.envelope,
Sig.envelopeStereo,
simple,
zip,
zipWith,
zipWithSimple,
fromStorableVector,
fromStorableVectorLazy,
render,
renderChunky,
run,
runChunky,
runChunkyPattern,
-- for testing
noiseCoreAlt,
) where
import Synthesizer.LLVM.Parameterized.SignalPrivate
import qualified Synthesizer.LLVM.Simple.SignalPrivate as SigPriv
import qualified Synthesizer.LLVM.Simple.Signal as Sig
import qualified Synthesizer.LLVM.CausalParameterized.ProcessPrivate as CausalP
import qualified Synthesizer.LLVM.Causal.Process as Causal
import qualified Synthesizer.LLVM.Interpolation as Interpolation
import qualified Synthesizer.LLVM.ConstantPiece as Const
import qualified Synthesizer.LLVM.Parameter as Param
import Synthesizer.Causal.Class (($*), ($<), )
import qualified Synthesizer.LLVM.Frame.Stereo as Stereo
import qualified Synthesizer.LLVM.Frame as Frame
import qualified Synthesizer.LLVM.Random as Rnd
import qualified Synthesizer.LLVM.Wave as Wave
import qualified Synthesizer.LLVM.Execution as Exec
import qualified Synthesizer.LLVM.ForeignPtr as ForeignPtr
import qualified Synthesizer.LLVM.Alloc as Alloc
import qualified Synthesizer.LLVM.Storable.ChunkIterator as ChunkIt
import qualified Synthesizer.LLVM.Storable.Vector as SVU
import qualified Data.StorableVector.Lazy.Pattern as SVP
import qualified Data.StorableVector.Lazy as SVL
import qualified Data.StorableVector as SV
import qualified Data.StorableVector.Base as SVB
import qualified Data.EventList.Relative.BodyTime as EventList
import qualified Numeric.NonNegative.Chunky as Chunky
import qualified Numeric.NonNegative.Wrapper as NonNeg
import qualified LLVM.Extra.Arithmetic as A
import qualified LLVM.Extra.ScalarOrVector as SoV
import qualified LLVM.Extra.MaybeContinuation as MaybeCont
import qualified LLVM.Extra.Maybe as Maybe
import qualified LLVM.Extra.Memory as Memory
import LLVM.Extra.Class (MakeValueTuple, ValueTuple, Undefined, undefTuple, )
import LLVM.Extra.Arithmetic (advanceArrayElementPtr, )
import LLVM.Extra.Control (whileLoop, )
import qualified LLVM.ExecutionEngine as EE
import qualified LLVM.Util.Loop as Loop
import qualified LLVM.Core as LLVM
import LLVM.Core
(CodeGenFunction, ret, Value, value, valueOf,
IsSized, IsConst, IsArithmetic, IsFloating,
CodeGenModule, Function, )
import qualified Type.Data.Num.Decimal as TypeNum
import Control.Monad.HT ((<=<), )
import Control.Monad (when, )
import Control.Arrow ((^<<), )
import Control.Applicative (liftA2, liftA3, pure, (<$>), )
import Control.Functor.HT (void, )
import qualified Algebra.Transcendental as Trans
import qualified Algebra.RealField as RealField
import qualified Algebra.Algebraic as Algebraic
import qualified Algebra.Field as Field
import qualified Algebra.Additive as Additive
import Data.Functor.Compose (Compose(Compose))
import Data.Tuple.HT (mapSnd, )
import Data.Word (Word8, Word32, )
import Data.Int (Int32, )
import Foreign.Storable.Tuple ()
import Foreign.Storable (Storable, )
import Foreign.ForeignPtr (touchForeignPtr, withForeignPtr, )
import Foreign.Ptr (Ptr, nullPtr, )
import Control.Exception (bracket, )
import qualified System.Unsafe as Unsafe
import qualified Synthesizer.LLVM.Debug.Storable as DebugSt
import qualified Synthesizer.LLVM.Debug.Counter as Counter
import NumericPrelude.Numeric
import NumericPrelude.Base hiding (and, tail, iterate, map, zip, zipWith, cycle, drop, )
-- for debugChunkyMain
import qualified Control.Monad.Trans.Reader as R
reparameterize :: Param.T q p -> T p a -> T q a
reparameterize p (Cons start alloca stop next create delete) =
Cons start alloca stop next (create . Param.get p) delete
-- * timeline edit
{- |
@tail empty@ generates the empty signal.
-}
tail ::
T p a -> T p a
tail (Cons next alloca start stop createIOContext deleteIOContext) = Cons
next
alloca
(\parameter -> do
local <- alloca
(c,s0) <- start parameter
MaybeCont.resolve (next c local s0)
(return (c,s0))
(\(_a,s1) -> return (c,s1)))
stop
createIOContext
deleteIOContext
drop ::
Param.T p Int ->
T p a -> T p a
drop n (Cons next alloca start stop createIOContext deleteIOContext) =
Param.with (Param.word32 n) $ \getN valueN -> Cons
next
alloca
(\(parameter, i0) -> do
local <- alloca
(c,s0) <- start parameter
(_, _, s3) <-
whileLoop (valueOf True, valueN i0, s0)
(\(cont,i1,_s1) ->
A.and cont =<<
A.cmp LLVM.CmpGT i1 A.zero)
(\(_cont,i1,s1) -> do
(cont, s2) <-
MaybeCont.resolve (next c local s1)
(return (valueOf False, s1))
(\(_a,s) -> return (valueOf True, s))
i2 <- A.dec i1
return (cont, i2, s2))
return (c, s3))
stop
(\p -> do
(ioContext, param) <- createIOContext p
return (ioContext, (param, getN p)))
deleteIOContext
cycle ::
(Loop.Phi a, Undefined a) =>
T p a -> T p a
cycle (Cons next alloca start stop createIOContext deleteIOContext) =
Cons
(\parameter local (c0,s0) ->
MaybeCont.alternative
(fmap (mapSnd ((,) c0)) $ next c0 local s0)
(do (c1,s1) <- MaybeCont.lift $ start parameter
(b0,s2) <- next c1 local s1
return (b0,(c1,s2))))
alloca
(\parameter -> do
contextState <- start parameter
return (parameter, contextState))
(\_parameter contextState -> uncurry stop contextState)
createIOContext
deleteIOContext
-- * signal modifiers
{- |
Stretch signal in time by a certain factor.
This can be used for doing expensive computations
of filter parameters at a lower rate.
Alternatively, we could provide an adaptive @map@
that recomputes output values only if the input value changes,
or if the input value differs from the last processed one by a certain amount.
-}
interpolateConstant ::
(Memory.C a,
IsFloating b, SoV.IntegerConstant b, LLVM.CmpRet b, LLVM.CmpResult b ~ Bool,
Storable b, MakeValueTuple b, ValueTuple b ~ (Value b),
Memory.FirstClass b, IsSized (Memory.Stored b)) =>
Param.T p b -> T p a -> T p a
interpolateConstant k sig =
CausalP.toSignal
(Causal.quantizeLift (CausalP.fromSignal sig) $< constant k)
amplify ::
(A.PseudoRing al, Storable a,
MakeValueTuple a, ValueTuple a ~ al, Memory.C al) =>
Param.T p a -> T p al -> T p al
amplify =
map Frame.amplifyMono
amplifyStereo ::
(A.PseudoRing al, Storable a,
MakeValueTuple a, ValueTuple a ~ al, Memory.C al) =>
Param.T p a -> T p (Stereo.T al) -> T p (Stereo.T al)
amplifyStereo =
map Frame.amplifyStereo
mapAccum ::
(Storable pnh, MakeValueTuple pnh, ValueTuple pnh ~ pnl, Memory.C pnl,
Storable psh, MakeValueTuple psh, ValueTuple psh ~ psl, Memory.C psl,
Memory.C s) =>
(forall r. pnl -> a -> s -> CodeGenFunction r (b,s)) ->
(forall r. psl -> CodeGenFunction r s) ->
Param.T p pnh ->
Param.T p psh ->
T p a -> T p b
mapAccum next start n s xs =
CausalP.mapAccum next start n s $* xs
adjacentNodes02 ::
(Memory.C a, Undefined a) =>
T p a -> T p (Interpolation.Nodes02 a)
adjacentNodes02 =
tail
.
Sig.mapAccum
(\new old -> return (Interpolation.Nodes02 old new, new))
(return undefTuple)
adjacentNodes13 ::
(MakeValueTuple ah, Storable ah, ValueTuple ah ~ a,
Memory.C a, Undefined a) =>
Param.T p ah -> T p a -> T p (Interpolation.Nodes13 a)
adjacentNodes13 yp0 =
tail .
tail .
mapAccum
(\() new (x0, x1, x2) ->
return (Interpolation.Nodes13 x0 x1 x2 new, (x1, x2, new)))
(\y0 -> return (undefTuple, undefTuple, Param.value yp0 y0))
(pure ()) yp0
-- * signal generators
exponentialCore ::
(Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.PseudoRing al) =>
Param.T p a -> Param.T p a -> T p al
exponentialCore =
iterate A.mul
exponential2 ::
(Trans.C a, Storable a, MakeValueTuple a, ValueTuple a ~ (Value a),
Memory.FirstClass a, IsSized (Memory.Stored a),
IsArithmetic a, IsConst a) =>
Param.T p a -> Param.T p a -> T p (Value a)
exponential2 halfLife =
exponentialCore (0.5 ** recip halfLife)
exponentialBoundedCore ::
(Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.PseudoRing al, A.Real al) =>
Param.T p a -> Param.T p a -> Param.T p a ->
T p al
exponentialBoundedCore bound decay =
iterate
(\(b,k) y -> A.max b =<< A.mul k y)
(liftA2 (,) bound decay)
{- |
Exponential curve that remains at the bound value
if it would fall below otherwise.
This way you can avoid extremal values, e.g. denormalized ones.
The initial value and the bound value must be positive.
-}
exponentialBounded2 ::
(Trans.C a, Storable a, MakeValueTuple a, ValueTuple a ~ (Value a),
Memory.FirstClass a, IsSized (Memory.Stored a),
SoV.Real a, IsConst a) =>
Param.T p a -> Param.T p a -> Param.T p a ->
T p (Value a)
exponentialBounded2 bound halfLife =
exponentialBoundedCore bound (0.5 ** recip halfLife)
osciCore ::
(Storable t, MakeValueTuple t, ValueTuple t ~ tl,
Memory.C tl, A.Fraction tl) =>
Param.T p t -> Param.T p t -> T p tl
osciCore phase freq =
iterate A.incPhase freq phase
osci ::
(Storable t, MakeValueTuple t, ValueTuple t ~ tl,
Storable c, MakeValueTuple c, ValueTuple c ~ cl,
Memory.C cl,
Memory.C tl, A.Fraction tl, A.IntegerConstant tl) =>
(forall r. cl -> tl -> CodeGenFunction r y) ->
Param.T p c ->
Param.T p t -> Param.T p t -> T p y
osci wave waveParam phase freq =
map wave waveParam $
osciCore phase freq
osciSimple ::
(Storable t, MakeValueTuple t, ValueTuple t ~ tl,
Memory.C tl, A.Fraction tl, A.IntegerConstant tl) =>
(forall r. tl -> CodeGenFunction r y) ->
Param.T p t -> Param.T p t -> T p y
osciSimple wave =
osci (const wave) (return ())
osciSaw ::
(Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.PseudoRing al, A.Fraction al, A.IntegerConstant al) =>
Param.T p a -> Param.T p a -> T p al
osciSaw =
osciSimple Wave.saw
rampCore ::
(Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.Additive al, A.IntegerConstant al) =>
Param.T p a -> Param.T p a -> T p al
rampCore = iterate A.add
parabolaCore ::
(Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.Additive al, A.IntegerConstant al) =>
Param.T p a -> Param.T p a -> Param.T p a -> T p al
parabolaCore d2 d1 start =
CausalP.apply (CausalP.integrate start) $
rampCore d2 d1
rampInf, rampSlope,
parabolaFadeInInf, parabolaFadeOutInf ::
(Field.C a, Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.Additive al, A.IntegerConstant al) =>
Param.T p a -> T p al
rampSlope slope = rampCore slope Additive.zero
rampInf dur = rampSlope (recip dur)
{-
t*(2-t) = 1 - (t-1)^2
(t+d)*(2-t-d) - t*(2-t)
= d*(2-t) - d*t - d^2
= 2*d*(1-t) - d^2
= d*(2*(1-t) - d)
2*d*(1-t-d) + d^2 - (2*d*(1-t) + d^2)
= -2*d^2
-}
parabolaFadeInInf dur =
parabolaCore
(fmap (\d -> -2*d*d) $ recip dur)
(fmap (\d -> d*(2-d)) $ recip dur)
Additive.zero
{-
1-t^2
-}
parabolaFadeOutInf dur =
parabolaCore
(fmap (\d -> -2*d*d) $ recip dur)
(fmap (\d -> -d*d) $ recip dur)
one
ramp,
parabolaFadeIn, parabolaFadeOut,
parabolaFadeInMap, parabolaFadeOutMap ::
(RealField.C a, Storable a, MakeValueTuple a, ValueTuple a ~ al,
Memory.C al, A.PseudoRing al, A.IntegerConstant al) =>
Param.T p a -> T p al
ramp dur =
CausalP.apply (CausalP.take (fmap round dur)) $
rampInf dur
parabolaFadeIn dur =
CausalP.apply (CausalP.take (fmap round dur)) $
parabolaFadeInInf dur
parabolaFadeOut dur =
CausalP.apply (CausalP.take (fmap round dur)) $
parabolaFadeOutInf dur
parabolaFadeInMap dur =
-- t*(2-t)
CausalP.apply (CausalP.mapSimple (\t -> A.mul t =<< A.sub (A.fromInteger' 2) t)) $
ramp dur
parabolaFadeOutMap dur =
-- 1-t^2
CausalP.apply (CausalP.mapSimple (\t -> A.sub (A.fromInteger' 1) =<< A.mul t t)) $
ramp dur
{- |
@noise seed rate@
The @rate@ parameter is for adjusting the amplitude
such that it is uniform across different sample rates
and after frequency filters.
The @rate@ is the ratio of the current sample rate to the default sample rate,
where the variance of the samples would be one.
If you want that at sample rate 22050 the variance is 1,
then in order to get a consistent volume at sample rate 44100
you have to set @rate = 2@.
I use the variance as quantity and not the amplitude,
because the amplitude makes only sense for uniformly distributed samples.
However, frequency filters transform the probabilistic density of the samples
towards the normal distribution according to the central limit theorem.
-}
noise ::
(Algebraic.C a, IsFloating a, IsConst a,
LLVM.NumberOfElements a ~ TypeNum.D1,
Memory.C (Value a),
MakeValueTuple a, ValueTuple a ~ (Value a), Storable a) =>
Param.T p Word32 ->
Param.T p a ->
T p (Value a)
noise seed rate =
let m2 = fromInteger $ div Rnd.modulus 2
in map (\r y ->
A.mul r
=<< flip A.sub (valueOf $ m2+1)
=<< int31tofp y)
(sqrt (3 * rate) / return m2) $
noiseCore seed
{-
sitofp is a single instruction on x86
and thus we use it, since the arguments are below 2^31.
-}
int31tofp ::
(IsFloating a, LLVM.NumberOfElements a ~ TypeNum.D1) =>
Value Word32 -> CodeGenFunction r (Value a)
int31tofp =
LLVM.inttofp <=<
(LLVM.bitcast ::
Value Word32 -> CodeGenFunction r (Value Int32))
noiseCore, noiseCoreAlt ::
Param.T p Word32 ->
T p (Value Word32)
noiseCore seed =
iterate (const Rnd.nextCG)
(return ()) ((+1) . flip mod (Rnd.modulus-1) ^<< seed)
noiseCoreAlt seed =
iterate (const Rnd.nextCG32)
(return ()) ((+1) . flip mod (Rnd.modulus-1) ^<< seed)
-- * conversion from and to storable vectors
fromStorableVector ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
Param.T p (SV.Vector a) ->
T p value
fromStorableVector selectVec =
Cons
(\() () (p0,l0) -> do
cont <- MaybeCont.lift $ A.cmp LLVM.CmpGT l0 A.zero
MaybeCont.withBool cont $ do
y1 <- Memory.load p0
p1 <- advanceArrayElementPtr p0
l1 <- A.dec l0
return (y1,(p1,l1)))
(return ())
(return . (,) ())
(\() _ -> return ())
(\p ->
let (fp,ptr,l) = SVU.unsafeToPointers $ Param.get selectVec p
in return (fp, (ptr, fromIntegral l :: Word32)))
-- keep the foreign ptr alive
touchForeignPtr
{-
This function calls back into the Haskell function 'ChunkIt.next'
that returns a pointer to the data of the next chunk
and advances to the next chunk in the sequence.
-}
fromStorableVectorLazy ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
Param.T p (SVL.Vector a) ->
T p value
fromStorableVectorLazy = SigPriv.flattenChunks . storableVectorChunks
storableVectorChunks ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value,
Memory.Struct value ~ struct) =>
Param.T p (SVL.Vector a) ->
T p (Value (Ptr struct), Value Word32)
storableVectorChunks sig =
Cons
(SigPriv.storableVectorNextChunk
"Parameterized.Signal.fromStorableVectorLazy.nextChunk")
LLVM.alloca
(\s -> return (s, ()))
(\ _s _ -> return ())
(\p -> do
s <- ChunkIt.new (Param.get sig p)
return (s, s))
ChunkIt.dispose
piecewiseConstant ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
Param.T p (EventList.T NonNeg.Int a) ->
T p value
piecewiseConstant =
Const.flatten . Const.piecewiseConstant
{- |
Turns a lazy chunky size into a signal generator with unit element type.
The signal length is the only information that the generator provides.
Using 'zipWith' you can use this signal as a lazy 'take'.
-}
lazySize ::
Param.T p SVP.LazySize ->
T p ()
lazySize =
Const.flatten . Const.lazySize
foreign import ccall safe "dynamic" derefFillPtr ::
Exec.Importer (Ptr param -> Word32 -> Ptr a -> IO Word32)
moduleFill ::
(Memory.C value, Memory.Struct value ~ struct,
Memory.C parameters, Memory.Struct parameters ~ paramStruct,
Loop.Phi state, Undefined state) =>
(forall r z.
(Loop.Phi z) =>
context -> local -> state -> MaybeCont.T r z (value, state)) ->
(forall r. CodeGenFunction r local) ->
(forall r.
parameters -> CodeGenFunction r (context, state)) ->
(forall r.
context -> state -> CodeGenFunction r ()) ->
CodeGenModule
(Function (Ptr paramStruct -> Word32 -> Ptr struct -> IO Word32))
moduleFill next alloca start stop =
Exec.createLLVMFunction "fillsignalblock" $
\paramPtr size bPtr -> do
param <- Memory.load paramPtr
(c,s) <- start param
local <- alloca
(pos,se) <- MaybeCont.arrayLoop size bPtr s $ \ ptri s0 -> do
(y,s1) <- next c local s0
MaybeCont.lift $ Memory.store y ptri
return s1
Maybe.for se $ stop c
ret pos
debugMain ::
forall parameters struct paramStruct.
(Storable parameters,
LLVM.IsType struct,
LLVM.IsType paramStruct,
IsSized paramStruct) =>
CodeGenModule
(Function (Ptr paramStruct -> Word32 -> Ptr struct -> IO Word32)) ->
parameters ->
IO (Function (Word32 -> Ptr (Ptr Word8) -> IO Word32))
debugMain sigModule params = do
paramArray <-
DebugSt.withConstArray params (\arr -> do
ptr <- LLVM.alloca
LLVM.store (value arr) =<< LLVM.bitcast ptr
return ptr)
m <- LLVM.newModule
mainFunc <- LLVM.defineModule m (do
LLVM.setTarget LLVM.hostTriple
mallocBytes <- LLVM.newNamedFunction LLVM.ExternalLinkage "malloc" ::
LLVM.TFunction (Ptr Word8 -> IO (Ptr struct))
fill <- sigModule
Exec.createLLVMFunction "main" $ \ _argc _argv -> do
paramPtr <- paramArray
let chunkSize = LLVM.valueOf 100000
basePtr = LLVM.valueOf nullPtr
buffer <-
LLVM.call mallocBytes =<<
LLVM.bitcast =<<
LLVM.getElementPtr basePtr (chunkSize, ())
_done <-
LLVM.call fill paramPtr chunkSize (asTypeOf buffer basePtr)
ret (A.zero :: LLVM.Value Word32))
Counter.with Exec.counter $ R.ReaderT $ \cnt -> do
LLVM.writeBitcodeToFile ("main" ++ Counter.format 3 cnt ++ ".bc") m
return mainFunc
run ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
T p value ->
IO (Int -> p -> SV.Vector a)
run (Cons next alloca start stop createIOContext deleteIOContext) =
do -- this compiles once and is much faster than simpleFunction
fill <-
Exec.compileModule $
Compose $
(EE.getExecutionFunction derefFillPtr
<$> moduleFill next alloca start stop)
return $ \len p ->
Unsafe.performIO $
bracket (createIOContext p) (deleteIOContext . fst) $
\ (_,params) -> do
when False $ void $
debugMain (moduleFill next alloca start stop) params
SVB.createAndTrim len $ \ ptr ->
Alloc.with params $ \paramPtr ->
fmap fromIntegral $
fill (Memory.castTuplePtr paramPtr)
(fromIntegral len) (Memory.castTuplePtr ptr)
{- |
This is not really a function, see 'renderChunky'.
-}
render ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
T p value -> Int -> p -> SV.Vector a
render gen = Unsafe.performIO $ run gen
foreign import ccall safe "dynamic" derefStartPtr ::
Exec.Importer (Ptr b -> IO (Ptr a))
foreign import ccall safe "dynamic" derefStopPtr ::
Exec.Importer (Ptr a -> IO ())
foreign import ccall safe "dynamic" derefChunkPtr ::
Exec.Importer (Ptr contextStateStruct -> Word32 -> Ptr struct -> IO Word32)
moduleChunky ::
(Memory.C value, Memory.Struct value ~ struct,
Memory.C parameters, Memory.Struct parameters ~ paramStruct,
Memory.C context, Memory.C state,
Memory.Struct (context, Maybe.T state) ~ contextStateStruct) =>
(forall r z.
(Loop.Phi z) =>
context -> local -> state -> MaybeCont.T r z (value, state)) ->
(forall r. CodeGenFunction r local) ->
(forall r.
parameters -> CodeGenFunction r (context, state)) ->
(forall r.
context -> state -> CodeGenFunction r ()) ->
CodeGenModule
(Function (Ptr paramStruct -> IO (Ptr contextStateStruct)),
Function (Ptr contextStateStruct -> IO ()),
Function (Ptr contextStateStruct ->
Word32 -> Ptr struct -> IO Word32))
moduleChunky next alloca start stop = liftA3 (,,)
(Exec.createLLVMFunction "startsignal" $
\paramPtr -> do
pptr <- LLVM.malloc
flip Memory.store pptr . mapSnd Maybe.just =<< start =<< Memory.load paramPtr
ret pptr)
(Exec.createLLVMFunction "stopsignal" $
\ contextStatePtr -> do
(c,ms) <- Memory.load contextStatePtr
Maybe.for ms $ stop c
LLVM.free contextStatePtr
ret ())
(Exec.createLLVMFunction "fillsignal" $
\ contextStatePtr loopLen ptr -> do
(context, msInit) <- Memory.load contextStatePtr
local <- alloca
(pos,msExit) <-
Maybe.run msInit (return (A.zero, Maybe.nothing)) $ \sInit ->
MaybeCont.arrayLoop loopLen ptr sInit $ \ ptri s0 -> do
(y,s1) <- next context local s0
MaybeCont.lift $ Memory.store y ptri
return s1
sptr <- LLVM.getElementPtr0 contextStatePtr (TypeNum.d1, ())
Memory.store msExit sptr
ret pos)
compileChunky ::
(Memory.C value, Memory.Struct value ~ struct,
Memory.C parameters, Memory.Struct parameters ~ paramStruct,
Memory.C context, Memory.C state,
Memory.Struct (context, Maybe.T state) ~ contextStateStruct) =>
(forall r z.
(Loop.Phi z) =>
context -> local -> state -> MaybeCont.T r z (value, state)) ->
(forall r. CodeGenFunction r local) ->
(forall r.
parameters -> CodeGenFunction r (context, state)) ->
(forall r.
context -> state -> CodeGenFunction r ()) ->
IO (Ptr paramStruct -> IO (Ptr contextStateStruct),
Exec.Finalizer contextStateStruct,
Ptr contextStateStruct -> Word32 -> Ptr struct -> IO Word32)
compileChunky next alloca start stop =
Exec.compileModule $
Compose
((\(startF, stopF, nextF) ->
liftA3 (,,)
(EE.getExecutionFunction derefStartPtr startF)
(liftA2 (,) EE.getEngine $
EE.getExecutionFunction derefStopPtr stopF)
(EE.getExecutionFunction derefChunkPtr nextF))
<$> moduleChunky next alloca start stop)
debugChunkyMain ::
forall parameters struct paramStruct contextStateStruct.
(Storable parameters,
LLVM.IsType struct,
LLVM.IsType contextStateStruct,
LLVM.IsType paramStruct,
IsSized paramStruct) =>
CodeGenModule
(Function (Ptr paramStruct -> IO (Ptr contextStateStruct)),
Function (Ptr contextStateStruct -> IO ()),
Function (Ptr contextStateStruct ->
Word32 -> Ptr struct -> IO Word32)) ->
parameters ->
IO (Function (Word32 -> Ptr (Ptr Word8) -> IO Word32))
debugChunkyMain sigModule params = do
{-
This does not work, since we cannot add (Mul n D32 s) constraint
to the function argument in reifyIntegral.
nextArray <-
DebugSt.withConstArray nextParam (\arr -> do
ptr <- LLVM.alloca
LLVM.store (value arr) ptr
LLVM.bitcast ptr)
-}
paramArray <-
DebugSt.withConstArray params (\arr -> do
ptr <- LLVM.alloca
LLVM.store (value arr) =<< LLVM.bitcast ptr
return ptr)
m <- LLVM.newModule
mainFunc <- LLVM.defineModule m (do
LLVM.setTarget LLVM.hostTriple
mallocBytes <- LLVM.newNamedFunction LLVM.ExternalLinkage "malloc" ::
LLVM.TFunction (Ptr Word8 -> IO (Ptr struct))
(start, stop, fill) <- sigModule
Exec.createLLVMFunction "main" $ \ _argc _argv -> do
contextState <- LLVM.call start =<< paramArray
let chunkSize = LLVM.valueOf 100000
basePtr = LLVM.valueOf nullPtr
buffer <-
LLVM.call mallocBytes =<<
LLVM.bitcast =<<
LLVM.getElementPtr basePtr (chunkSize, ())
_done <-
LLVM.call fill contextState chunkSize (asTypeOf buffer basePtr)
_ <- LLVM.call stop contextState
ret (A.zero :: LLVM.Value Word32))
Counter.with Exec.counter $ R.ReaderT $ \cnt -> do
LLVM.writeBitcodeToFile ("main" ++ Counter.format 3 cnt ++ ".bc") m
return mainFunc
{- |
Renders a signal generator to a chunky storable vector with given pattern.
If the pattern is shorter than the generated signal
this means that the signal is shortened.
-}
runChunkyPattern ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
T p value ->
IO (SVP.LazySize -> p -> SVL.Vector a)
runChunkyPattern
(Cons next alloca start stop createIOContext deleteIOContext) = do
(startFunc, stopFunc, fill) <- compileChunky next alloca start stop
return $
\ lazysize p -> SVL.fromChunks $ Unsafe.performIO $ do
(ioContext, param) <- createIOContext p
{-
putStr "nextParam: "
DebugSt.format nextParam >>= putStrLn
-}
when False $ Counter.with DebugSt.dumpCounter $ do
DebugSt.dump "param" param
when False $ void $
debugChunkyMain (moduleChunky next alloca start stop) param
statePtr <- ForeignPtr.newParam stopFunc startFunc param
ioContextPtr <- ForeignPtr.newAux (deleteIOContext ioContext)
let go cs =
Unsafe.interleaveIO $
case cs of
[] -> return []
SVL.ChunkSize size : rest -> do
v <-
withForeignPtr statePtr $ \sptr ->
SVB.createAndTrim size $
fmap fromIntegral .
fill sptr (fromIntegral size) .
Memory.castTuplePtr
touchForeignPtr ioContextPtr
(if SV.length v > 0
then fmap (v:)
else id) $
(if SV.length v < size
then return []
else go rest)
go (Chunky.toChunks lazysize)
runChunky ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
T p value ->
IO (SVL.ChunkSize -> p -> SVL.Vector a)
runChunky sig =
flip fmap (runChunkyPattern sig) $ \f size p ->
f (Chunky.fromChunks (repeat size)) p
{- |
This looks like a function,
but it is not a function since it depends on LLVM being initialized
with LLVM.initializeNativeTarget before.
It is also problematic since you cannot control when and how often
the underlying LLVM code is compiled.
The compilation cannot be observed, thus it is referential transparent.
But this influences performance considerably
and I assume that you use this package exclusively for performance reasons.
-}
renderChunky ::
(Storable a, MakeValueTuple a, ValueTuple a ~ value, Memory.C value) =>
SVL.ChunkSize -> T p value ->
p -> SVL.Vector a
renderChunky size gen =
Unsafe.performIO (runChunky gen) size