{-| Copyright : (C) 2013-2016, University of Twente, 2016-2017, Myrtle Software Ltd, 2017-2022, Google Inc., 2017-2024, QBayLogic B.V. License : BSD2 (see the file LICENSE) Maintainer : QBayLogic B.V. -} {-# LANGUAGE CPP #-} {-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE MagicHash #-} {-# LANGUAGE NamedFieldPuns #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE RankNTypes #-} {-# LANGUAGE TemplateHaskell #-} {-# LANGUAGE UnboxedTuples #-} {-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-} module Clash.GHC.Evaluator.Primitive ( ghcPrimStep , ghcPrimUnwind , isUndefinedPrimVal , isUndefinedXPrimVal ) where import Control.Concurrent.Supply (Supply,freshId) import Control.DeepSeq (force) import Control.Exception (ArithException(..), Exception, tryJust, evaluate) import Control.Monad.State.Strict (State, MonadState) import qualified Control.Monad.State.Strict as State import Control.Monad.Trans.Except (runExcept) import Data.Binary.IEEE754 (doubleToWord, floatToWord, wordToDouble, wordToFloat) import Data.Bits import qualified Data.ByteString.Internal as BS import Data.Char (chr,ord) import qualified Data.Either as Either import Data.Maybe (fromMaybe, mapMaybe) import qualified Data.List as List import qualified Data.Primitive.ByteArray as BA import Data.Proxy (Proxy) import Data.Reflection (reifyNat) import Data.Text (Text) import qualified Data.Text as Text import Data.Text.Extra (showt) import GHC.Exts (IsList(..)) import GHC.Float import GHC.Int import GHC.Integer (decodeDoubleInteger,encodeDoubleInteger,compareInteger,orInteger,andInteger, xorInteger,complementInteger,absInteger,signumInteger) #if MIN_VERSION_base(4,16,0) import GHC.Num.Integer (Integer (..), integerEncodeFloat#) #elif MIN_VERSION_base(4,15,0) import GHC.Num.Integer (Integer (..), integerEncodeFloat#, integerToFloat#, integerToDouble#) #else import GHC.Integer.GMP.Internals (Integer (..), BigNat (..)) #endif #if MIN_VERSION_base(4,15,0) import GHC.Num.Natural (naturalSubUnsafe) #endif import GHC.Natural import GHC.ForeignPtr import GHC.Prim import GHC.Real (Ratio (..)) import GHC.TypeLits (KnownNat) import GHC.Types (IO (..)) import GHC.Word import System.IO.Unsafe (unsafeDupablePerformIO) #if MIN_VERSION_ghc(9,4,0) import Data.Bifunctor (first) import qualified Data.Text.Array as Text import qualified Data.Text.Internal as Text #endif #if MIN_VERSION_ghc(9,0,0) import GHC.Types.Basic (Boxity (..)) import GHC.Types.Name (getSrcSpan, nameOccName, occNameString) import GHC.Builtin.Names (trueDataConKey, falseDataConKey) import qualified GHC.Core.TyCon as TyCon import GHC.Builtin.Types (tupleTyCon) #else import BasicTypes (Boxity (..)) import Name (getSrcSpan, nameOccName, occNameString) import PrelNames (trueDataConKey, falseDataConKey) import qualified TyCon import TysWiredIn (tupleTyCon) #endif import Clash.Class.BitPack (pack,unpack) import Clash.Core.DataCon (DataCon (..)) import Clash.Core.Evaluator.Types import Clash.Core.HasType (piResultTys, applyTypeToArgs) import Clash.Core.Literal (Literal (..)) import Clash.Core.Name (Name (..), NameSort (..), mkUnsafeSystemName) import Clash.Core.Pretty (showPpr) import Clash.Core.Term (IsMultiPrim (..), Pat (..), PrimInfo (..), Term (..), WorkInfo (..), mkApps, PrimUnfolding(..), collectArgs) import Clash.Core.Type (Type (..), ConstTy (..), LitTy (..), TypeView (..), mkFunTy, mkTyConApp, splitFunForallTy, tyView) import Clash.Core.TyCon (TyConMap, TyConName, tyConDataCons) import Clash.Core.TysPrim import Clash.Core.Util (mkRTree,mkVec,tyNatSize,dataConInstArgTys,primCo, mkSelectorCase,undefinedPrims, undefinedXPrims) import Clash.Core.Var (mkLocalId, mkTyVar) import qualified Clash.Data.UniqMap as UniqMap import Clash.Debug import Clash.GHC.GHC2Core (modNameM) import Clash.Unique (fromGhcUnique) import Clash.Util (MonadUnique (..), clogBase, flogBase, curLoc) import Clash.Normalize.PrimitiveReductions (typeNatMul, typeNatSub, typeNatAdd, vecLastPrim, vecInitPrim, vecHeadPrim, vecTailPrim, mkVecCons, mkVecNil) import qualified Clash.Normalize.Primitives as NP import Clash.Promoted.Nat.Unsafe (unsafeSNat) import qualified Clash.Sized.Internal.BitVector as BitVector import qualified Clash.Sized.Internal.Signed as Signed import qualified Clash.Sized.Internal.Unsigned as Unsigned import Clash.Sized.Internal.BitVector(BitVector(..), Bit(..)) import Clash.Sized.Internal.Signed (Signed (..)) import Clash.Sized.Internal.Unsigned (Unsigned (..)) import Clash.XException (isX) import {-# SOURCE #-} Clash.GHC.Evaluator isUndefinedPrimVal :: Value -> Bool isUndefinedPrimVal (PrimVal (PrimInfo{primName}) _ _) = primName `elem` undefinedPrims isUndefinedPrimVal _ = False isUndefinedXPrimVal :: Value -> Bool isUndefinedXPrimVal (PrimVal (PrimInfo{primName}) _ _) = primName `elem` undefinedXPrims isUndefinedXPrimVal _ = False -- | Evaluation of primitive operations. ghcPrimUnwind :: PrimUnwind ghcPrimUnwind tcm p tys vs v [] m | primName p `elem` [ "Clash.Sized.Internal.Index.fromInteger#" , "GHC.CString.unpackCString#" , Text.pack (show 'NP.removedArg) , "GHC.Prim.MutableByteArray#" , Text.pack (show 'NP.undefined) , Text.pack (show 'NP.undefinedX) ] -- The above primitives are actually values, and not operations. = ghcUnwind (PrimVal p tys (vs ++ [v])) m tcm | primName p == "Clash.Sized.Internal.BitVector.fromInteger#" = case (vs,v) of ([naturalLiteral -> Just n,mask], integerLiteral -> Just i) -> ghcUnwind (PrimVal p tys [Lit (NaturalLiteral n), mask, Lit (IntegerLiteral (wrapUnsigned n i))]) m tcm _ -> error ($(curLoc) ++ "Internal error" ++ show (vs,v)) | primName p == "Clash.Sized.Internal.BitVector.fromInteger##" = case (vs,v) of ([mask], integerLiteral -> Just i) -> ghcUnwind (PrimVal p tys [mask, Lit (IntegerLiteral (wrapUnsigned 1 i))]) m tcm _ -> error ($(curLoc) ++ "Internal error" ++ show (vs,v)) | primName p == "Clash.Sized.Internal.Signed.fromInteger#" = case (vs,v) of ([naturalLiteral -> Just n],integerLiteral -> Just i) -> ghcUnwind (PrimVal p tys [Lit (NaturalLiteral n), Lit (IntegerLiteral (wrapSigned n i))]) m tcm _ -> error ($(curLoc) ++ "Internal error" ++ show (vs,v)) | primName p == "Clash.Sized.Internal.Unsigned.fromInteger#" = case (vs,v) of ([naturalLiteral -> Just n],integerLiteral -> Just i) -> ghcUnwind (PrimVal p tys [Lit (NaturalLiteral n), Lit (IntegerLiteral (wrapUnsigned n i))]) m tcm _ -> error ($(curLoc) ++ "Internal error" ++ show (vs,v)) | isUndefinedPrimVal v = let tyArgs = map Right tys tmArgs = map (Left . valToTerm) (vs ++ [v]) in Just $ flip setTerm m $ TyApp (Prim NP.undefined) $ applyTypeToArgs (Prim p) tcm (primType p) (tyArgs ++ tmArgs) | isUndefinedXPrimVal v = let tyArgs = map Right tys tmArgs = map (Left . valToTerm) (vs ++ [v]) in Just $ flip setTerm m $ TyApp (Prim NP.undefinedX) $ applyTypeToArgs (Prim p) tcm (primType p) (tyArgs ++ tmArgs) | otherwise = ghcPrimStep tcm (forcePrims m) p tys (vs ++ [v]) m ghcPrimUnwind tcm p tys vs v [e] m0 -- Note [Lazy primitives] -- ~~~~~~~~~~~~~~~~~~~~~~ -- -- Primitives are usually considered undefined when one of their arguments is -- (unless they're unused). _Some_ primitives can still yield a result even -- though one of their arguments is undefined. It turns out that all primitives -- exhibiting this property happen to be "lazy" in their last argument. Thus, -- all the cases can be covered by a match on [e] and their names: | primName p `elem` [ "Clash.Sized.Vector.lazyV" , "Clash.Sized.Vector.replicate" , "Clash.Sized.Vector.replace_int" , "GHC.Classes.&&" , "GHC.Classes.||" , showt 'BitVector.xToBV , "Clash.Sized.Vector.imap_go" ] = if isUndefinedPrimVal v then let tyArgs = map Right tys tmArgs = map (Left . valToTerm) (vs ++ [v]) ++ [Left e] in Just $ flip setTerm m0 $ TyApp (Prim NP.undefined) $ applyTypeToArgs (Prim p) tcm (primType p) (tyArgs ++ tmArgs) else let (m1,i) = newLetBinding tcm m0 e in ghcPrimStep tcm (forcePrims m0) p tys (vs ++ [v,Suspend (Var i)]) m1 ghcPrimUnwind tcm p tys vs (collectValueTicks -> (v, ts)) (e:es) m | isUndefinedPrimVal v = let tyArgs = map Right tys tmArgs = map (Left . valToTerm) (vs ++ [v]) ++ map Left (e:es) in Just $ flip setTerm m $ TyApp (Prim NP.undefined) $ applyTypeToArgs (Prim p) tcm (primType p) (tyArgs ++ tmArgs) | otherwise = Just . setTerm e $ stackPush (PrimApply p tys (vs ++ [foldr TickValue v ts]) es) m newtype PrimEvalMonad a = PEM (State Supply a) deriving (Functor, Applicative, Monad, MonadState Supply) instance MonadUnique PrimEvalMonad where getUniqueM = PEM $ State.state (\s -> case freshId s of (!i,!s') -> (i,s')) runPEM :: PrimEvalMonad a -> Supply -> (a, Supply) runPEM (PEM m) = State.runState m ghcPrimStep :: PrimStep ghcPrimStep tcm isSubj pInfo tys args mach = case primName pInfo of ----------------- -- GHC.Prim.Char# ----------------- "GHC.Prim.gtChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i > j)) "GHC.Prim.geChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i >= j)) "GHC.Prim.eqChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i == j)) "GHC.Prim.neChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i /= j)) "GHC.Prim.ltChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i < j)) "GHC.Prim.leChar#" | Just (i,j) <- charLiterals args -> reduce (boolToIntLiteral (i <= j)) "GHC.Prim.ord#" | [i] <- charLiterals' args -> reduce (integerToIntLiteral (toInteger $ ord i)) ---------------- -- GHC.Prim.Int# ---------------- "GHC.Prim.+#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i+j)) "GHC.Prim.-#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i-j)) "GHC.Prim.*#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i*j)) "GHC.Prim.mulIntMayOflo#" | Just (i,j) <- intLiterals args -> let !(I# a) = fromInteger i !(I# b) = fromInteger j c :: Int# c = mulIntMayOflo# a b in reduce (integerToIntLiteral (toInteger $ I# c)) "GHC.Prim.quotInt#" | Just (i,j) <- intLiterals args -> reduce $ catchDivByZero (integerToIntLiteral (i `quot` j)) "GHC.Prim.remInt#" | Just (i,j) <- intLiterals args -> reduce $ catchDivByZero (integerToIntLiteral (i `rem` j)) "GHC.Prim.quotRemInt#" | Just (i,j) <- intLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc (q,r) = quotRem i j ret = mkApps (Data tupDc) (map Right tyArgs ++ [Left $ catchDivByZero (integerToIntLiteral q) ,Left $ catchDivByZero (integerToIntLiteral r)]) in reduce ret "GHC.Prim.andI#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i .&. j)) "GHC.Prim.orI#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i .|. j)) "GHC.Prim.xorI#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i `xor` j)) "GHC.Prim.notI#" | [i] <- intLiterals' args -> reduce (integerToIntLiteral (complement i)) "GHC.Prim.negateInt#" | [Lit (IntLiteral i)] <- args -> reduce (integerToIntLiteral (negate i)) "GHC.Prim.addIntC#" | Just (i,j) <- intLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(I# a) = fromInteger i !(I# b) = fromInteger j !(# d, c #) = addIntC# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . IntLiteral . toInteger $ I# d) , Left (Literal . IntLiteral . toInteger $ I# c)]) "GHC.Prim.subIntC#" | Just (i,j) <- intLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(I# a) = fromInteger i !(I# b) = fromInteger j !(# d, c #) = subIntC# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . IntLiteral . toInteger $ I# d) , Left (Literal . IntLiteral . toInteger $ I# c)]) "GHC.Prim.>#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i > j)) "GHC.Prim.>=#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i >= j)) "GHC.Prim.==#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i == j)) "GHC.Prim./=#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i /= j)) "GHC.Prim.<#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i < j)) "GHC.Prim.<=#" | Just (i,j) <- intLiterals args -> reduce (boolToIntLiteral (i <= j)) "GHC.Prim.chr#" | [i] <- intLiterals' args -> reduce (charToCharLiteral (chr $ fromInteger i)) "GHC.Prim.int2Word#" | [Lit (IntLiteral i)] <- args -> reduce . Literal . WordLiteral . toInteger $ (fromInteger :: Integer -> Word) i -- for overflow behavior "GHC.Prim.int2Float#" | [Lit (IntLiteral i)] <- args -> reduce . Literal . FloatLiteral . floatToWord $ fromInteger i "GHC.Prim.int2Double#" | [Lit (IntLiteral i)] <- args -> reduce . Literal . DoubleLiteral . doubleToWord $ fromInteger i "GHC.Prim.word2Float#" | [Lit (WordLiteral i)] <- args -> reduce . Literal . FloatLiteral . floatToWord $ fromInteger i "GHC.Prim.word2Double#" | [Lit (WordLiteral i)] <- args -> reduce . Literal . DoubleLiteral . doubleToWord $ fromInteger i "GHC.Prim.uncheckedIShiftL#" | [ Lit (IntLiteral i) , Lit (IntLiteral s) ] <- args -> reduce (integerToIntLiteral (i `shiftL` fromInteger s)) "GHC.Prim.uncheckedIShiftRA#" | [ Lit (IntLiteral i) , Lit (IntLiteral s) ] <- args -> reduce (integerToIntLiteral (i `shiftR` fromInteger s)) "GHC.Prim.uncheckedIShiftRL#" | Just (i,j) <- intLiterals args -> let !(I# a) = fromInteger i !(I# b) = fromInteger j c :: Int# c = uncheckedIShiftRL# a b in reduce (integerToIntLiteral (toInteger $ I# c)) ----------------- -- GHC.Prim.Word# ----------------- "GHC.Prim.plusWord#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i+j)) "GHC.Prim.subWordC#" | Just (i,j) <- wordLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(W# a) = fromInteger i !(W# b) = fromInteger j !(# d, c #) = subWordC# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . WordLiteral . toInteger $ W# d) , Left (Literal . IntLiteral . toInteger $ I# c)]) "GHC.Prim.plusWord2#" | Just (i,j) <- wordLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(W# a) = fromInteger i !(W# b) = fromInteger j !(# h', l #) = plusWord2# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . WordLiteral . toInteger $ W# h') , Left (Literal . WordLiteral . toInteger $ W# l)]) "GHC.Prim.minusWord#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i-j)) "GHC.Prim.timesWord#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i*j)) "GHC.Prim.timesWord2#" | Just (i,j) <- wordLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(W# a) = fromInteger i !(W# b) = fromInteger j !(# h', l #) = timesWord2# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . WordLiteral . toInteger $ W# h') , Left (Literal . WordLiteral . toInteger $ W# l)]) "GHC.Prim.quotWord#" | Just (i,j) <- wordLiterals args -> reduce $ catchDivByZero (integerToWordLiteral (i `quot` j)) "GHC.Prim.remWord#" | Just (i,j) <- wordLiterals args -> reduce $ catchDivByZero (integerToWordLiteral (i `rem` j)) "GHC.Prim.quotRemWord#" | Just (i,j) <- wordLiterals args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc (q,r) = quotRem i j ret = mkApps (Data tupDc) (map Right tyArgs ++ [Left $ catchDivByZero (integerToWordLiteral q) ,Left $ catchDivByZero (integerToWordLiteral r)]) in reduce ret "GHC.Prim.quotRemWord2#" | [i,j,k'] <- wordLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(W# a) = fromInteger i !(W# b) = fromInteger j !(W# c) = fromInteger k' !(# x, y #) = quotRemWord2# a b c in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left $ catchDivByZero (Literal . WordLiteral . toInteger $ W# x) , Left $ catchDivByZero (Literal . WordLiteral . toInteger $ W# y)]) "GHC.Prim.and#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i .&. j)) "GHC.Prim.or#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i .|. j)) "GHC.Prim.xor#" | Just (i,j) <- wordLiterals args -> reduce (integerToWordLiteral (i `xor` j)) "GHC.Prim.not#" | [i] <- wordLiterals' args -> reduce (integerToWordLiteral (complement i)) "GHC.Prim.uncheckedShiftL#" | [ Lit (WordLiteral w) , Lit (IntLiteral i) ] <- args -> reduce (Literal (WordLiteral (w `shiftL` fromInteger i))) "GHC.Prim.uncheckedShiftRL#" | [ Lit (WordLiteral w) , Lit (IntLiteral i) ] <- args -> reduce (Literal (WordLiteral (w `shiftR` fromInteger i))) "GHC.Prim.word2Int#" | [Lit (WordLiteral i)] <- args -> reduce . Literal . IntLiteral . toInteger $ (fromInteger :: Integer -> Int) i -- for overflow behavior "GHC.Prim.gtWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i > j)) "GHC.Prim.geWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i >= j)) "GHC.Prim.eqWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i == j)) "GHC.Prim.neWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i /= j)) "GHC.Prim.ltWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i < j)) "GHC.Prim.leWord#" | Just (i,j) <- wordLiterals args -> reduce (boolToIntLiteral (i <= j)) "GHC.Prim.popCnt8#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . popCount . (fromInteger :: Integer -> Word8) $ i "GHC.Prim.popCnt16#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . popCount . (fromInteger :: Integer -> Word16) $ i "GHC.Prim.popCnt32#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . popCount . (fromInteger :: Integer -> Word32) $ i "GHC.Prim.popCnt64#" | [i] <- word64Literals' args -> reduce . integerToWordLiteral . toInteger . popCount . (fromInteger :: Integer -> Word64) $ i "GHC.Prim.popCnt#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . popCount . (fromInteger :: Integer -> Word) $ i "GHC.Prim.clz8#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countLeadingZeros . (fromInteger :: Integer -> Word8) $ i "GHC.Prim.clz16#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countLeadingZeros . (fromInteger :: Integer -> Word16) $ i "GHC.Prim.clz32#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countLeadingZeros . (fromInteger :: Integer -> Word32) $ i "GHC.Prim.clz64#" | [i] <- word64Literals' args -> reduce . integerToWordLiteral . toInteger . countLeadingZeros . (fromInteger :: Integer -> Word64) $ i "GHC.Prim.clz#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countLeadingZeros . (fromInteger :: Integer -> Word) $ i "GHC.Prim.ctz8#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countTrailingZeros . (fromInteger :: Integer -> Word) $ i .&. (bit 8 - 1) "GHC.Prim.ctz16#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countTrailingZeros . (fromInteger :: Integer -> Word) $ i .&. (bit 16 - 1) "GHC.Prim.ctz32#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countTrailingZeros . (fromInteger :: Integer -> Word) $ i .&. (bit 32 - 1) "GHC.Prim.ctz64#" | [i] <- word64Literals' args -> reduce . integerToWordLiteral . toInteger . countTrailingZeros . (fromInteger :: Integer -> Word64) $ i .&. (bit 64 - 1) "GHC.Prim.ctz#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . countTrailingZeros . (fromInteger :: Integer -> Word) $ i "GHC.Prim.byteSwap16#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . byteSwap16 . (fromInteger :: Integer -> Word16) $ i "GHC.Prim.byteSwap32#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . byteSwap32 . (fromInteger :: Integer -> Word32) $ i "GHC.Prim.byteSwap64#" | [i] <- word64Literals' args -> reduce . integerToWordLiteral . toInteger . byteSwap64 . (fromInteger :: Integer -> Word64) $ i "GHC.Prim.byteSwap#" | [i] <- wordLiterals' args -- assume 64bits -> reduce . integerToWordLiteral . toInteger . byteSwap64 . (fromInteger :: Integer -> Word64) $ i #if MIN_VERSION_base(4,14,0) "GHC.Prim.bitReverse#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . bitReverse64 . fromInteger $ i -- assume 64bits "GHC.Prim.bitReverse8#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . bitReverse8 . fromInteger $ i "GHC.Prim.bitReverse16#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . bitReverse16 . fromInteger $ i "GHC.Prim.bitReverse32#" | [i] <- wordLiterals' args -> reduce . integerToWordLiteral . toInteger . bitReverse32 . fromInteger $ i "GHC.Prim.bitReverse64#" | [i] <- word64Literals' args -> reduce . integerToWordLiteral . toInteger . bitReverse64 . fromInteger $ i #endif ------------ -- Narrowing ------------ "GHC.Prim.narrow8Int#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow8Int# a in reduce . Literal . IntLiteral . toInteger $ I# b "GHC.Prim.narrow16Int#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow16Int# a in reduce . Literal . IntLiteral . toInteger $ I# b "GHC.Prim.narrow32Int#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow32Int# a in reduce . Literal . IntLiteral . toInteger $ I# b "GHC.Prim.narrow8Word#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow8Word# a in reduce . Literal . WordLiteral . toInteger $ W# b "GHC.Prim.narrow16Word#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow16Word# a in reduce . Literal . WordLiteral . toInteger $ W# b "GHC.Prim.narrow32Word#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow32Word# a in reduce . Literal . WordLiteral . toInteger $ W# b #if MIN_VERSION_base(4,16,0) -------- -- Int8# -------- "GHC.Prim.intToInt8#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow8Int# a in reduce . Literal . Int8Literal . toInteger $ I# b "GHC.Prim.int8ToInt#" | [i] <- int8Literals' args -> reduce . Literal $ IntLiteral i "GHC.Prim.negateInt8" | [i] <- int8Literals' args -> let !(I8# a) = fromInteger i in reduce (Literal (Int8Literal (toInteger (I8# (negateInt8# a))))) "GHC.Prim.plusInt8#" | Just r <- liftI8 plusInt8# args -> reduce r "GHC.Prim.subInt8#" | Just r <- liftI8 subInt8# args -> reduce r "GHC.Prim.timesInt8#" | Just r <- liftI8 timesInt8# args -> reduce r "GHC.Prim.quotInt8#" | Just r <- liftI8 quotInt8# args -> reduce r "GHC.Prim.remInt8#" | Just r <- liftI8 remInt8# args -> reduce r "GHC.Prim.quotRemInt8#" | [i, j] <- int8Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(I8# a) = fromInteger i !(I8# b) = fromInteger j !(# q, r #) = quotRemInt8# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Int8Literal (toInteger (I8# q)))) , Left (Literal (Int8Literal (toInteger (I8# r))))]) "GHC.Prim.uncheckedShiftLInt8#" | Just r <- liftI8I uncheckedShiftLInt8# args -> reduce r "GHC.Prim.uncheckedShiftRAInt8#" | Just r <- liftI8I uncheckedShiftRAInt8# args -> reduce r "GHC.Prim.uncheckedShiftRLInt8#" | Just r <- liftI8I uncheckedShiftRLInt8# args -> reduce r "GHC.Prim.int8ToWord8#" | [i] <- int8Literals' args -> let !(I8# a) = fromInteger i in reduce (Literal (Word8Literal (toInteger (W8# (int8ToWord8# a))))) "GHC.Prim.eqInt8#" | Just r <- liftI8RI eqInt8# args -> reduce r "GHC.Prim.geInt8#" | Just r <- liftI8RI geInt8# args -> reduce r "GHC.Prim.gtInt8#" | Just r <- liftI8RI gtInt8# args -> reduce r "GHC.Prim.leInt8#" | Just r <- liftI8RI leInt8# args -> reduce r "GHC.Prim.ltInt8#" | Just r <- liftI8RI ltInt8# args -> reduce r "GHC.Prim.neInt8#" | Just r <- liftI8RI neInt8# args -> reduce r --------- -- Int16# --------- "GHC.Prim.intToInt16#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow16Int# a in reduce . Literal . Int16Literal . toInteger $ I# b "GHC.Prim.int16ToInt#" | [i] <- int16Literals' args -> reduce . Literal $ IntLiteral i "GHC.Prim.negateInt16" | [i] <- int16Literals' args -> let !(I16# a) = fromInteger i in reduce (Literal (Int16Literal (toInteger (I16# (negateInt16# a))))) "GHC.Prim.plusInt16#" | Just r <- liftI16 plusInt16# args -> reduce r "GHC.Prim.subInt16#" | Just r <- liftI16 subInt16# args -> reduce r "GHC.Prim.timesInt16#" | Just r <- liftI16 timesInt16# args -> reduce r "GHC.Prim.quotInt16#" | Just r <- liftI16 quotInt16# args -> reduce r "GHC.Prim.remInt16#" | Just r <- liftI16 remInt16# args -> reduce r "GHC.Prim.quotRemInt16#" | [i, j] <- int16Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(I16# a) = fromInteger i !(I16# b) = fromInteger j !(# q, r #) = quotRemInt16# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Int16Literal (toInteger (I16# q)))) , Left (Literal (Int16Literal (toInteger (I16# r))))]) "GHC.Prim.uncheckedShiftLInt16#" | Just r <- liftI16I uncheckedShiftLInt16# args -> reduce r "GHC.Prim.uncheckedShiftRAInt16#" | Just r <- liftI16I uncheckedShiftRAInt16# args -> reduce r "GHC.Prim.uncheckedShiftRLInt16#" | Just r <- liftI16I uncheckedShiftRLInt16# args -> reduce r "GHC.Prim.int16ToWord16#" | [i] <- int16Literals' args -> let !(I16# a) = fromInteger i in reduce (Literal (Word16Literal (toInteger (W16# (int16ToWord16# a))))) "GHC.Prim.eqInt16#" | Just r <- liftI16RI eqInt16# args -> reduce r "GHC.Prim.geInt16#" | Just r <- liftI16RI geInt16# args -> reduce r "GHC.Prim.gtInt16#" | Just r <- liftI16RI gtInt16# args -> reduce r "GHC.Prim.leInt16#" | Just r <- liftI16RI leInt16# args -> reduce r "GHC.Prim.ltInt16#" | Just r <- liftI16RI ltInt16# args -> reduce r "GHC.Prim.neInt16#" | Just r <- liftI16RI neInt16# args -> reduce r --------- -- Int32# --------- "GHC.Prim.intToInt32#" | [i] <- intLiterals' args -> let !(I# a) = fromInteger i b = narrow32Int# a in reduce . Literal . Int32Literal . toInteger $ I# b "GHC.Prim.int32ToInt#" | [i] <- int32Literals' args -> reduce . Literal $ IntLiteral i "GHC.Prim.negateInt32" | [i] <- int32Literals' args -> let !(I32# a) = fromInteger i in reduce (Literal (Int32Literal (toInteger (I32# (negateInt32# a))))) "GHC.Prim.plusInt32#" | Just r <- liftI32 plusInt32# args -> reduce r "GHC.Prim.subInt32#" | Just r <- liftI32 subInt32# args -> reduce r "GHC.Prim.timesInt32#" | Just r <- liftI32 timesInt32# args -> reduce r "GHC.Prim.quotInt32#" | Just r <- liftI32 quotInt32# args -> reduce r "GHC.Prim.remInt32#" | Just r <- liftI32 remInt32# args -> reduce r "GHC.Prim.quotRemInt32#" | [i, j] <- int32Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(I32# a) = fromInteger i !(I32# b) = fromInteger j !(# q, r #) = quotRemInt32# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Int32Literal (toInteger (I32# q)))) , Left (Literal (Int32Literal (toInteger (I32# r))))]) "GHC.Prim.uncheckedShiftLInt32#" | Just r <- liftI32I uncheckedShiftLInt32# args -> reduce r "GHC.Prim.uncheckedShiftRAInt32#" | Just r <- liftI32I uncheckedShiftRAInt32# args -> reduce r "GHC.Prim.uncheckedShiftRLInt32#" | Just r <- liftI32I uncheckedShiftRLInt32# args -> reduce r "GHC.Prim.int32ToWord32#" | [i] <- int32Literals' args -> let !(I32# a) = fromInteger i in reduce (Literal (Word32Literal (toInteger (W32# (int32ToWord32# a))))) "GHC.Prim.eqInt32#" | Just r <- liftI32RI eqInt32# args -> reduce r "GHC.Prim.geInt32#" | Just r <- liftI32RI geInt32# args -> reduce r "GHC.Prim.gtInt32#" | Just r <- liftI32RI gtInt32# args -> reduce r "GHC.Prim.leInt32#" | Just r <- liftI32RI leInt32# args -> reduce r "GHC.Prim.ltInt32#" | Just r <- liftI32RI ltInt32# args -> reduce r "GHC.Prim.neInt32#" | Just r <- liftI32RI neInt32# args -> reduce r --------- -- Int64# --------- #if MIN_VERSION_base(4,17,0) "GHC.Prim.intToInt64#" | [i] <- intLiterals' args -> reduce (Literal (Int64Literal i)) "GHC.Prim.int64ToInt#" | [i] <- int64Literals' args -> reduce . Literal $ IntLiteral i "GHC.Prim.negateInt64" | [i] <- int64Literals' args -> let !(I64# a) = fromInteger i in reduce (Literal (Int64Literal (toInteger (I64# (negateInt64# a))))) "GHC.Prim.plusInt64#" | Just r <- liftI64 plusInt64# args -> reduce r "GHC.Prim.subInt64#" | Just r <- liftI64 subInt64# args -> reduce r "GHC.Prim.timesInt64#" | Just r <- liftI64 timesInt64# args -> reduce r "GHC.Prim.quotInt64#" | Just r <- liftI64 quotInt64# args -> reduce r "GHC.Prim.remInt64#" | Just r <- liftI64 remInt64# args -> reduce r "GHC.Prim.uncheckedIShiftL64#" | Just r <- liftI64I uncheckedIShiftL64# args -> reduce r "GHC.Prim.uncheckedIShiftRA64#" | Just r <- liftI64I uncheckedIShiftRA64# args -> reduce r "GHC.Prim.uncheckedIShiftRL64#" | Just r <- liftI64I uncheckedIShiftRL64# args -> reduce r "GHC.Prim.int64ToWord64#" | [i] <- int64Literals' args -> let !(I64# a) = fromInteger i in reduce (Literal (Word64Literal (toInteger (W64# (int64ToWord64# a))))) "GHC.Prim.eqInt64#" | Just r <- liftI64RI eqInt64# args -> reduce r "GHC.Prim.geInt64#" | Just r <- liftI64RI geInt64# args -> reduce r "GHC.Prim.gtInt64#" | Just r <- liftI64RI gtInt64# args -> reduce r "GHC.Prim.leInt64#" | Just r <- liftI64RI leInt64# args -> reduce r "GHC.Prim.ltInt64#" | Just r <- liftI64RI ltInt64# args -> reduce r "GHC.Prim.neInt64#" | Just r <- liftI64RI neInt64# args -> reduce r #endif --------- -- Word8# --------- "GHC.Prim.wordToWord8#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow8Word# a in reduce . Literal . Word8Literal . toInteger $ W# b "GHC.Prim.word8ToWord#" | [i] <- word8Literals' args -> reduce . Literal $ WordLiteral i "GHC.Prim.plusWord8#" | Just r <- liftW8 plusWord8# args -> reduce r "GHC.Prim.subWord8#" | Just r <- liftW8 subWord8# args -> reduce r "GHC.Prim.timesWord8#" | Just r <- liftW8 timesWord8# args -> reduce r "GHC.Prim.quotWord8#" | Just r <- liftW8 quotWord8# args -> reduce r "GHC.Prim.remWord8#" | Just r <- liftW8 remWord8# args -> reduce r "GHC.Prim.quotRemWord8#" | [i, j] <- word8Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(W8# a) = fromInteger i !(W8# b) = fromInteger j !(# q, r #) = quotRemWord8# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Word8Literal (toInteger (W8# q)))) , Left (Literal (Word8Literal (toInteger (W8# r))))]) "GHC.Prim.andWord8#" | Just r <- liftW8 andWord8# args -> reduce r "GHC.Prim.orWord8#" | Just r <- liftW8 orWord8# args -> reduce r "GHC.Prim.xorWord8#" | Just r <- liftW8 xorWord8# args -> reduce r "GHC.Prim.notWord8#" | [i] <- word8Literals' args -> let !(W8# a) = fromInteger i in reduce (Literal (Word8Literal (toInteger (W8# (notWord8# a))))) "GHC.Prim.uncheckedShiftLWord8#" | Just r <- liftW8I uncheckedShiftLWord8# args -> reduce r "GHC.Prim.uncheckedShiftRLWord8#" | Just r <- liftW8I uncheckedShiftRLWord8# args -> reduce r "GHC.Prim.word8ToInt8#" | [i] <- word8Literals' args -> let !(W8# a) = fromInteger i in reduce (Literal (Int8Literal (toInteger (I8# (word8ToInt8# a))))) "GHC.Prim.eqWord8#" | Just r <- liftW8RI eqWord8# args -> reduce r "GHC.Prim.geWord8#" | Just r <- liftW8RI geWord8# args -> reduce r "GHC.Prim.gtWord8#" | Just r <- liftW8RI gtWord8# args -> reduce r "GHC.Prim.leWord8#" | Just r <- liftW8RI leWord8# args -> reduce r "GHC.Prim.ltWord8#" | Just r <- liftW8RI ltWord8# args -> reduce r "GHC.Prim.neWord8#" | Just r <- liftW8RI neWord8# args -> reduce r ---------- -- Word16# ---------- "GHC.Prim.wordToWord16#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow16Word# a in reduce . Literal . Word16Literal . toInteger $ W# b "GHC.Prim.word16ToWord#" | [i] <- word16Literals' args -> reduce . Literal $ WordLiteral i "GHC.Prim.plusWord16#" | Just r <- liftW16 plusWord16# args -> reduce r "GHC.Prim.subWord16#" | Just r <- liftW16 subWord16# args -> reduce r "GHC.Prim.timesWord16#" | Just r <- liftW16 timesWord16# args -> reduce r "GHC.Prim.quotWord16#" | Just r <- liftW16 quotWord16# args -> reduce r "GHC.Prim.remWord16#" | Just r <- liftW16 remWord16# args -> reduce r "GHC.Prim.quotRemWord16#" | [i, j] <- word16Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(W16# a) = fromInteger i !(W16# b) = fromInteger j !(# q, r #) = quotRemWord16# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Word16Literal (toInteger (W16# q)))) , Left (Literal (Word16Literal (toInteger (W16# r))))]) "GHC.Prim.andWord16#" | Just r <- liftW16 andWord16# args -> reduce r "GHC.Prim.orWord16#" | Just r <- liftW16 orWord16# args -> reduce r "GHC.Prim.xorWord16#" | Just r <- liftW16 xorWord16# args -> reduce r "GHC.Prim.notWord16#" | [i] <- word16Literals' args -> let !(W16# a) = fromInteger i in reduce (Literal (Word16Literal (toInteger (W16# (notWord16# a))))) "GHC.Prim.uncheckedShiftLWord16#" | Just r <- liftW16I uncheckedShiftLWord16# args -> reduce r "GHC.Prim.uncheckedShiftRLWord16#" | Just r <- liftW16I uncheckedShiftRLWord16# args -> reduce r "GHC.Prim.word16ToInt16#" | [i] <- word16Literals' args -> let !(W16# a) = fromInteger i in reduce (Literal (Int16Literal (toInteger (I16# (word16ToInt16# a))))) "GHC.Prim.eqWord16#" | Just r <- liftW16RI eqWord16# args -> reduce r "GHC.Prim.geWord16#" | Just r <- liftW16RI geWord16# args -> reduce r "GHC.Prim.gtWord16#" | Just r <- liftW16RI gtWord16# args -> reduce r "GHC.Prim.leWord16#" | Just r <- liftW16RI leWord16# args -> reduce r "GHC.Prim.ltWord16#" | Just r <- liftW16RI ltWord16# args -> reduce r "GHC.Prim.neWord16#" | Just r <- liftW16RI neWord16# args -> reduce r ---------- -- Word32# ---------- "GHC.Prim.wordToWord32#" | [i] <- wordLiterals' args -> let !(W# a) = fromInteger i b = narrow32Word# a in reduce . Literal . Word32Literal . toInteger $ W# b "GHC.Prim.word32ToWord#" | [i] <- word32Literals' args -> reduce . Literal $ WordLiteral i "GHC.Prim.plusWord32#" | Just r <- liftW32 plusWord32# args -> reduce r "GHC.Prim.subWord32#" | Just r <- liftW32 subWord32# args -> reduce r "GHC.Prim.timesWord32#" | Just r <- liftW32 timesWord32# args -> reduce r "GHC.Prim.quotWord32#" | Just r <- liftW32 quotWord32# args -> reduce r "GHC.Prim.remWord32#" | Just r <- liftW32 remWord32# args -> reduce r "GHC.Prim.quotRemWord32#" | [i, j] <- word32Literals' args , (_,tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , (Just tupTc) <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let !(W32# a) = fromInteger i !(W32# b) = fromInteger j !(# q, r #) = quotRemWord32# a b in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (Word32Literal (toInteger (W32# q)))) , Left (Literal (Word32Literal (toInteger (W32# r))))]) "GHC.Prim.andWord32#" | Just r <- liftW32 andWord32# args -> reduce r "GHC.Prim.orWord32#" | Just r <- liftW32 orWord32# args -> reduce r "GHC.Prim.xorWord32#" | Just r <- liftW32 xorWord32# args -> reduce r "GHC.Prim.notWord32#" | [i] <- word32Literals' args -> let !(W32# a) = fromInteger i in reduce (Literal (Word32Literal (toInteger (W32# (notWord32# a))))) "GHC.Prim.uncheckedShiftLWord32#" | Just r <- liftW32I uncheckedShiftLWord32# args -> reduce r "GHC.Prim.uncheckedShiftRLWord32#" | Just r <- liftW32I uncheckedShiftRLWord32# args -> reduce r "GHC.Prim.word32ToInt32#" | [i] <- word32Literals' args -> let !(W32# a) = fromInteger i in reduce (Literal (Int32Literal (toInteger (I32# (word32ToInt32# a))))) "GHC.Prim.eqWord32#" | Just r <- liftW32RI eqWord32# args -> reduce r "GHC.Prim.geWord32#" | Just r <- liftW32RI geWord32# args -> reduce r "GHC.Prim.gtWord32#" | Just r <- liftW32RI gtWord32# args -> reduce r "GHC.Prim.leWord32#" | Just r <- liftW32RI leWord32# args -> reduce r "GHC.Prim.ltWord32#" | Just r <- liftW32RI ltWord32# args -> reduce r "GHC.Prim.neWord32#" | Just r <- liftW32RI neWord32# args -> reduce r #if MIN_VERSION_base(4,17,0) ---------- -- Word64# ---------- "GHC.Prim.wordToWord64#" | [i] <- wordLiterals' args -> reduce (Literal (Word64Literal i)) "GHC.Prim.word64ToWord#" | [i] <- word64Literals' args -> reduce . Literal $ WordLiteral i "GHC.Prim.plusWord64#" | Just r <- liftW64 plusWord64# args -> reduce r "GHC.Prim.subWord64#" | Just r <- liftW64 subWord64# args -> reduce r "GHC.Prim.timesWord64#" | Just r <- liftW64 timesWord64# args -> reduce r "GHC.Prim.quotWord64#" | Just r <- liftW64 quotWord64# args -> reduce r "GHC.Prim.remWord64#" | Just r <- liftW64 remWord64# args -> reduce r "GHC.Prim.and64#" | Just r <- liftW64 and64# args -> reduce r "GHC.Prim.or64#" | Just r <- liftW64 or64# args -> reduce r "GHC.Prim.xor64#" | Just r <- liftW64 xor64# args -> reduce r "GHC.Prim.not64#" | [i] <- word64Literals' args -> let !(W64# a) = fromInteger i in reduce (Literal (Word64Literal (toInteger (W64# (not64# a))))) "GHC.Prim.uncheckedShiftL64#" | Just r <- liftW64I uncheckedShiftL64# args -> reduce r "GHC.Prim.uncheckedShiftRL64#" | Just r <- liftW64I uncheckedShiftRL64# args -> reduce r "GHC.Prim.word64ToInt64#" | [i] <- word64Literals' args -> let !(W64# a) = fromInteger i in reduce (Literal (Int64Literal (toInteger (I64# (word64ToInt64# a))))) "GHC.Prim.eqWord64#" | Just r <- liftW64RI eqWord64# args -> reduce r "GHC.Prim.geWord64#" | Just r <- liftW64RI geWord64# args -> reduce r "GHC.Prim.gtWord64#" | Just r <- liftW64RI gtWord64# args -> reduce r "GHC.Prim.leWord64#" | Just r <- liftW64RI leWord64# args -> reduce r "GHC.Prim.ltWord64#" | Just r <- liftW64RI ltWord64# args -> reduce r "GHC.Prim.neWord64#" | Just r <- liftW64RI neWord64# args -> reduce r #endif #endif ---------- -- Double# ---------- "GHC.Prim.>##" | Just r <- liftDDI (>##) args -> reduce r "GHC.Prim.>=##" | Just r <- liftDDI (>=##) args -> reduce r "GHC.Prim.==##" | Just r <- liftDDI (==##) args -> reduce r "GHC.Prim./=##" | Just r <- liftDDI (/=##) args -> reduce r "GHC.Prim.<##" | Just r <- liftDDI (<##) args -> reduce r "GHC.Prim.<=##" | Just r <- liftDDI (<=##) args -> reduce r "GHC.Prim.+##" | Just r <- liftDDD (+##) args -> reduce r "GHC.Prim.-##" | Just r <- liftDDD (-##) args -> reduce r "GHC.Prim.*##" | Just r <- liftDDD (*##) args -> reduce r "GHC.Prim./##" | Just r <- liftDDD (/##) args -> reduce r "GHC.Prim.negateDouble#" | Just r <- liftDD negateDouble# args -> reduce r "GHC.Prim.fabsDouble#" | Just r <- liftDD fabsDouble# args -> reduce r "GHC.Prim.double2Int#" | [i] <- doubleLiterals' args -> let !(D# a) = wordToDouble i r = double2Int# a in reduce . Literal . IntLiteral . toInteger $ I# r "GHC.Prim.double2Float#" | [Lit (DoubleLiteral d)] <- args -> let !(D# a) = wordToDouble d r = double2Float# a in reduce . Literal . FloatLiteral . floatToWord $ F# r "GHC.Prim.expDouble#" | Just r <- liftDD expDouble# args -> reduce r "GHC.Prim.logDouble#" | Just r <- liftDD logDouble# args -> reduce r "GHC.Prim.sqrtDouble#" | Just r <- liftDD sqrtDouble# args -> reduce r "GHC.Prim.sinDouble#" | Just r <- liftDD sinDouble# args -> reduce r "GHC.Prim.cosDouble#" | Just r <- liftDD cosDouble# args -> reduce r "GHC.Prim.tanDouble#" | Just r <- liftDD tanDouble# args -> reduce r "GHC.Prim.asinDouble#" | Just r <- liftDD asinDouble# args -> reduce r "GHC.Prim.acosDouble#" | Just r <- liftDD acosDouble# args -> reduce r "GHC.Prim.atanDouble#" | Just r <- liftDD atanDouble# args -> reduce r "GHC.Prim.sinhDouble#" | Just r <- liftDD sinhDouble# args -> reduce r "GHC.Prim.coshDouble#" | Just r <- liftDD coshDouble# args -> reduce r "GHC.Prim.tanhDouble#" | Just r <- liftDD tanhDouble# args -> reduce r #if MIN_VERSION_ghc(8,7,0) "GHC.Prim.asinhDouble#" | Just r <- liftDD asinhDouble# args -> reduce r "GHC.Prim.acoshDouble#" | Just r <- liftDD acoshDouble# args -> reduce r "GHC.Prim.atanhDouble#" | Just r <- liftDD atanhDouble# args -> reduce r #endif "GHC.Prim.**##" | Just r <- liftDDD (**##) args -> reduce r -- decodeDouble_2Int# :: Double# -> (#Int#, Word#, Word#, Int##) "GHC.Prim.decodeDouble_2Int#" | [i] <- doubleLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(D# a) = wordToDouble i !(# p, q, r, s #) = decodeDouble_2Int# a in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . IntLiteral . toInteger $ I# p) , Left (Literal . WordLiteral . toInteger $ W# q) , Left (Literal . WordLiteral . toInteger $ W# r) , Left (Literal . IntLiteral . toInteger $ I# s)]) -- decodeDouble_Int64# :: Double# -> (# Int64#, Int# #) "GHC.Prim.decodeDouble_Int64#" | [i] <- doubleLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(D# a) = wordToDouble i !(# p, q #) = decodeDouble_Int64# a in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ #if MIN_VERSION_ghc_prim(0,9,0) [ Left (Literal . Int64Literal . toInteger $ I64# p) #else [ Left (Literal . IntLiteral . toInteger $ I64# p) #endif , Left (Literal . IntLiteral . toInteger $ I# q)]) -------- -- Float -------- "GHC.Prim.gtFloat#" | Just r <- liftFFI gtFloat# args -> reduce r "GHC.Prim.geFloat#" | Just r <- liftFFI geFloat# args -> reduce r "GHC.Prim.eqFloat#" | Just r <- liftFFI eqFloat# args -> reduce r "GHC.Prim.neFloat#" | Just r <- liftFFI neFloat# args -> reduce r "GHC.Prim.ltFloat#" | Just r <- liftFFI ltFloat# args -> reduce r "GHC.Prim.leFloat#" | Just r <- liftFFI leFloat# args -> reduce r "GHC.Prim.plusFloat#" | Just r <- liftFFF plusFloat# args -> reduce r "GHC.Prim.minusFloat#" | Just r <- liftFFF minusFloat# args -> reduce r "GHC.Prim.timesFloat#" | Just r <- liftFFF timesFloat# args -> reduce r "GHC.Prim.divideFloat#" | Just r <- liftFFF divideFloat# args -> reduce r "GHC.Prim.negateFloat#" | Just r <- liftFF negateFloat# args -> reduce r "GHC.Prim.fabsFloat#" | Just r <- liftFF fabsFloat# args -> reduce r "GHC.Prim.float2Int#" | [i] <- floatLiterals' args -> let !(F# a) = wordToFloat i r = float2Int# a in reduce . Literal . IntLiteral . toInteger $ I# r "GHC.Prim.expFloat#" | Just r <- liftFF expFloat# args -> reduce r "GHC.Prim.logFloat#" | Just r <- liftFF logFloat# args -> reduce r "GHC.Prim.sqrtFloat#" | Just r <- liftFF sqrtFloat# args -> reduce r "GHC.Prim.sinFloat#" | Just r <- liftFF sinFloat# args -> reduce r "GHC.Prim.cosFloat#" | Just r <- liftFF cosFloat# args -> reduce r "GHC.Prim.tanFloat#" | Just r <- liftFF tanFloat# args -> reduce r "GHC.Prim.asinFloat#" | Just r <- liftFF asinFloat# args -> reduce r "GHC.Prim.acosFloat#" | Just r <- liftFF acosFloat# args -> reduce r "GHC.Prim.atanFloat#" | Just r <- liftFF atanFloat# args -> reduce r "GHC.Prim.sinhFloat#" | Just r <- liftFF sinhFloat# args -> reduce r "GHC.Prim.coshFloat#" | Just r <- liftFF coshFloat# args -> reduce r "GHC.Prim.tanhFloat#" | Just r <- liftFF tanhFloat# args -> reduce r "GHC.Prim.powerFloat#" | Just r <- liftFFF powerFloat# args -> reduce r -- GHC.Float.asinh -- XXX: Very fragile -- $w$casinh is the Double specialisation of asinh -- $w$casinh1 is the Float specialisation of asinh "GHC.Float.$w$casinh" | Just r <- liftDD go args -> reduce r where go f = case asinh (D# f) of D# f' -> f' "GHC.Float.$w$casinh1" | Just r <- liftFF go args -> reduce r where go f = case asinh (F# f) of F# f' -> f' #if MIN_VERSION_ghc(8,7,0) "GHC.Prim.asinhFloat#" | Just r <- liftFF asinhFloat# args -> reduce r "GHC.Prim.acoshFloat#" | Just r <- liftFF acoshFloat# args -> reduce r "GHC.Prim.atanhFloat#" | Just r <- liftFF atanhFloat# args -> reduce r #endif "GHC.Prim.float2Double#" | [i] <- floatLiterals' args -> let !(F# a) = wordToFloat i r = float2Double# a in reduce . Literal . DoubleLiteral . doubleToWord $ D# r "GHC.Prim.newByteArray#" | [iV,PrimVal rwTy _ _] <- args , [i] <- intLiterals' [iV] -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc p = primCount mach lit = Literal (ByteArrayLiteral (fromList (List.genericReplicate i 0))) mbaTy = mkFunTy intPrimTy (last tyArgs) newE = mkApps (Data tupDc) (map Right tyArgs ++ [Left (Prim rwTy) ,Left (mkApps (Prim (PrimInfo "GHC.Prim.MutableByteArray#" mbaTy WorkNever SingleResult NoUnfolding)) [Left (Literal . IntLiteral $ toInteger p)]) ]) in Just . setTerm newE $ primInsert p lit mach "GHC.Prim.setByteArray#" | [PrimVal _mbaTy _ [baV] ,offV,lenV,cV ,PrimVal rwTy _ _ ] <- args , [ba,off,len,c] <- intLiterals' [baV,offV,lenV,cV] -> let Just (Literal (ByteArrayLiteral ba1)) = primLookup (fromInteger ba) mach !(I# off') = fromInteger off !(I# len') = fromInteger len !(I# c') = fromInteger c ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray mba <- BA.unsafeThawByteArray ba1 svoid (setByteArray# mba off' len' c') BA.unsafeFreezeByteArray (BA.MutableByteArray mba) ba3 = Literal (ByteArrayLiteral ba2) in Just . setTerm (Prim rwTy) $ primUpdate (fromInteger ba) ba3 mach "GHC.Prim.writeWordArray#" | [PrimVal _mbaTy _ [baV] ,iV,wV ,PrimVal rwTy _ _ ] <- args , [ba,i] <- intLiterals' [baV,iV] , [w] <- wordLiterals' [wV] -> let Just (Literal (ByteArrayLiteral ba1)) = primLookup (fromInteger ba) mach !(I# i') = fromInteger i !(W# w') = fromIntegral w ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray mba <- BA.unsafeThawByteArray ba1 svoid (writeWordArray# mba i' w') BA.unsafeFreezeByteArray (BA.MutableByteArray mba) ba3 = Literal (ByteArrayLiteral ba2) in Just . setTerm (Prim rwTy) $ primUpdate (fromInteger ba) ba3 mach "GHC.Prim.unsafeFreezeByteArray#" | [PrimVal _mbaTy _ [baV] ,PrimVal rwTy _ _ ] <- args , [ba] <- intLiterals' [baV] -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc Just ba' = primLookup (fromInteger ba) mach in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [Left (Prim rwTy) ,Left ba']) "GHC.Prim.sizeofByteArray#" | [Lit (ByteArrayLiteral ba)] <- args -> reduce (Literal (IntLiteral (toInteger (BA.sizeofByteArray ba)))) "GHC.Prim.indexWordArray#" | [Lit (ByteArrayLiteral (BA.ByteArray ba)),iV] <- args , [i] <- intLiterals' [iV] -> let !(I# i') = fromInteger i !w = indexWordArray# ba i' in reduce (Literal (WordLiteral (toInteger (W# w)))) "GHC.Prim.getSizeofMutBigNat#" | [PrimVal _mbaTy _ [baV] ,PrimVal rwTy _ _ ] <- args , [ba] <- intLiterals' [baV] -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc Just (Literal (ByteArrayLiteral ba')) = primLookup (fromInteger ba) mach lit = Literal (IntLiteral (toInteger (BA.sizeofByteArray ba'))) in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [Left (Prim rwTy) ,Left lit]) "GHC.Prim.resizeMutableByteArray#" | [PrimVal mbaTy _ [baV] ,iV ,PrimVal rwTy _ _ ] <- args , [ba,i] <- intLiterals' [baV,iV] -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc p = primCount mach Just (Literal (ByteArrayLiteral ba1)) = primLookup (fromInteger ba) mach !(I# i') = fromInteger i ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray mba <- BA.unsafeThawByteArray ba1 mba' <- IO (\s -> case resizeMutableByteArray# mba i' s of (# s', mba' #) -> (# s', BA.MutableByteArray mba' #)) BA.unsafeFreezeByteArray mba' ba3 = Literal (ByteArrayLiteral ba2) newE = mkApps (Data tupDc) (map Right tyArgs ++ [Left (Prim rwTy) ,Left (mkApps (Prim mbaTy) [Left (Literal . IntLiteral $ toInteger p)]) ]) in Just . setTerm newE $ primInsert p ba3 mach "GHC.Prim.shrinkMutableByteArray#" | [PrimVal _mbaTy _ [baV] ,lenV ,PrimVal rwTy _ _ ] <- args , [ba,len] <- intLiterals' [baV,lenV] -> let Just (Literal (ByteArrayLiteral ba1)) = primLookup (fromInteger ba) mach !(I# len') = fromInteger len ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray mba <- BA.unsafeThawByteArray ba1 svoid (shrinkMutableByteArray# mba len') BA.unsafeFreezeByteArray (BA.MutableByteArray mba) ba3 = Literal (ByteArrayLiteral ba2) in Just . setTerm (Prim rwTy) $ primUpdate (fromInteger ba) ba3 mach "GHC.Prim.copyByteArray#" | [Lit (ByteArrayLiteral (BA.ByteArray src_ba)) ,src_offV ,PrimVal _mbaTy _ [dst_mbaV] ,dst_offV, nV ,PrimVal rwTy _ _ ] <- args , [src_off,dst_mba,dst_off,n] <- intLiterals' [src_offV,dst_mbaV,dst_offV,nV] -> let Just (Literal (ByteArrayLiteral dst_ba)) = primLookup (fromInteger dst_mba) mach !(I# src_off') = fromInteger src_off !(I# dst_off') = fromInteger dst_off !(I# n') = fromInteger n ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray dst_mba1 <- BA.unsafeThawByteArray dst_ba svoid (copyByteArray# src_ba src_off' dst_mba1 dst_off' n') BA.unsafeFreezeByteArray (BA.MutableByteArray dst_mba1) ba3 = Literal (ByteArrayLiteral ba2) in Just . setTerm (Prim rwTy) $ primUpdate (fromInteger dst_mba) ba3 mach "GHC.Prim.readWordArray#" | [PrimVal _mbaTy _ [baV] ,offV ,PrimVal rwTy _ _ ] <- args , [ba,off] <- intLiterals' [baV,offV] -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc Just (Literal (ByteArrayLiteral ba1)) = primLookup (fromInteger ba) mach !(I# off') = fromInteger off w = unsafeDupablePerformIO $ do BA.MutableByteArray mba <- BA.unsafeThawByteArray ba1 IO (\s -> case readWordArray# mba off' s of (# s', w' #) -> (# s', W# w' #)) newE = mkApps (Data tupDc) (map Right tyArgs ++ [Left (Prim rwTy) ,Left (Literal (WordLiteral (toInteger w))) ]) in reduce newE "GHC.Prim.copyAddrToByteArray#" | [ Lit (StringLiteral addr) , PrimVal _mbaTy _ [dst_mbaV] , offV, lenV , PrimVal rwTy _ _ ] <- args , [off,len,dst_mba] <- intLiterals' [offV, lenV, dst_mbaV] -> let Just (Literal (ByteArrayLiteral dst_ba)) = primLookup (fromInteger dst_mba) mach !(I# off') = fromInteger off !(I# len') = fromInteger len !(BS.PS (ForeignPtr addr' _) _ _) = BS.packChars addr ba2 = unsafeDupablePerformIO $ do BA.MutableByteArray dst_mba1 <- BA.unsafeThawByteArray dst_ba svoid (copyAddrToByteArray# addr' dst_mba1 off' len') BA.unsafeFreezeByteArray (BA.MutableByteArray dst_mba1) ba3 = Literal (ByteArrayLiteral ba2) in Just . setTerm (Prim rwTy) $ primUpdate (fromInteger dst_mba) ba3 mach -- decodeFloat_Int# :: Float# -> (#Int#, Int##) "GHC.Prim.decodeFloat_Int#" | [i] <- floatLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(F# a) = wordToFloat i !(# p, q #) = decodeFloat_Int# a in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal . IntLiteral . toInteger $ I# p) , Left (Literal . IntLiteral . toInteger $ I# q)]) "GHC.Prim.tagToEnum#" | [ConstTy (TyCon tcN)] <- tys , [Lit (IntLiteral i)] <- args -> let dc = do { tc <- UniqMap.lookup tcN tcm ; let dcs = tyConDataCons tc ; List.find ((== (i+1)) . toInteger . dcTag) dcs } in (\e -> setTerm (Data e) mach) <$> dc "GHC.Prim.dataToTag#" | [DC dc _] <- args -> reduce (Literal (IntLiteral (toInteger (dcTag dc - 1)))) "GHC.Prim.dataToTagSmall#" | [DC dc _] <- args -> reduce (Literal (IntLiteral (toInteger (dcTag dc - 1)))) "GHC.Prim.dataToTagLarge#" | [DC dc _] <- args -> reduce (Literal (IntLiteral (toInteger (dcTag dc - 1)))) "GHC.Classes.eqInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) "GHC.Classes.neInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) "GHC.Classes.leInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) "GHC.Classes.ltInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) "GHC.Classes.geInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) "GHC.Classes.gtInt" | Just (i,j) <- intCLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) "GHC.Classes.&&" | [ lArg , rArg ] <- args , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind -- evaluation of the arguments is deferred until the evaluation of the ghcPrimUnwindWith -- to make `&&` lazy in both arguments , mach1@Machine{mStack=[],mTerm=lArgWHNF} <- whnf eval tcm True (setTerm (valToTerm lArg) $ stackClear mach) , mach2@Machine{mStack=[],mTerm=rArgWHNF} <- whnf eval tcm True (setTerm (valToTerm rArg) $ stackClear mach1) -> case [ lArgWHNF, rArgWHNF ] of [ Data lCon, Data rCon ] -> Just $ mach2 { mStack = mStack mach , mTerm = boolToBoolLiteral tcm ty (isTrueDC lCon && isTrueDC rCon) } [ Data lCon, _ ] | isTrueDC lCon -> reduce rArgWHNF | otherwise -> reduce (boolToBoolLiteral tcm ty False) [ _, Data rCon ] | isTrueDC rCon -> reduce lArgWHNF | otherwise -> reduce (boolToBoolLiteral tcm ty False) _ -> Nothing "GHC.Classes.||" | [ lArg , rArg ] <- args , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind -- evaluation of the arguments is deferred until the evaluation of the ghcPrimUnwindWith -- to make `||` lazy in both arguments , mach1@Machine{mStack=[],mTerm=lArgWHNF} <- whnf eval tcm True (setTerm (valToTerm lArg) $ stackClear mach) , mach2@Machine{mStack=[],mTerm=rArgWHNF} <- whnf eval tcm True (setTerm (valToTerm rArg) $ stackClear mach1) -> case [ lArgWHNF, rArgWHNF ] of [ Data lCon, Data rCon ] -> Just $ mach2 { mStack = mStack mach , mTerm = boolToBoolLiteral tcm ty (isTrueDC lCon || isTrueDC rCon) } [ Data lCon, _ ] | isFalseDC lCon -> reduce rArgWHNF | otherwise -> reduce (boolToBoolLiteral tcm ty True) [ _, Data rCon ] | isFalseDC rCon -> reduce lArgWHNF | otherwise -> reduce (boolToBoolLiteral tcm ty True) _ -> Nothing "GHC.Classes.divInt#" | Just (i,j) <- intLiterals args -> reduce (integerToIntLiteral (i `div` j)) -- modInt# :: Int# -> Int# -> Int# "GHC.Classes.modInt#" | [dividend, divisor] <- intLiterals' args -> if divisor == 0 then let iTy = snd (splitFunForallTy ty) in reduce (TyApp (Prim NP.undefined) iTy) else reduce (Literal (IntLiteral (dividend `mod` divisor))) "GHC.Classes.not" | [DC bCon _] <- args -> reduce (boolToBoolLiteral tcm ty (nameOcc (dcName bCon) == "GHC.Types.False")) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerLogBase#" | Just (a,b) <- integerLiterals args , Just c <- flogBase a b -> (reduce . Literal . WordLiteral . toInteger) c "GHC.Internal.Float.integerToFloat#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . FloatLiteral . floatToWord $ F# (integerToFloat# i) "GHC.Internal.Float.integerToDouble#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . DoubleLiteral . doubleToWord $ D# (integerToDouble# i) "GHC.Num.Integer.integerToFloat#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . FloatLiteral . floatToWord $ F# (integerToFloat# i) "GHC.Num.Integer.integerToDouble#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . DoubleLiteral . doubleToWord $ D# (integerToDouble# i) "GHC.Float.integerToFloat#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . FloatLiteral . floatToWord $ F# (integerToFloat# i) "GHC.Float.integerToDouble#" | [v] <- args , Just i <- integerLiteral v -> reduce . Literal . DoubleLiteral . doubleToWord $ D# (integerToDouble# i) "GHC.Num.Natural.naturalLogBase#" | Just (a,b) <- naturalLiterals args , Just c <- flogBase a b -> (reduce . Literal . WordLiteral . toInteger) c #else "GHC.Integer.Logarithms.integerLogBase#" | Just (a,b) <- integerLiterals args , Just c <- flogBase a b -> (reduce . Literal . IntLiteral . toInteger) c #endif #if !MIN_VERSION_base(4,15,0) "GHC.Integer.Type.smallInteger" | [Lit (IntLiteral i)] <- args -> reduce (Literal (IntegerLiteral i)) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerToInt#" #else "GHC.Integer.Type.integerToInt" #endif | [i] <- integerLiterals' args -> reduce (integerToIntLiteral i) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerDecodeDouble#" -- :: Double# -> (#Integer, Int##) #else "GHC.Integer.Type.decodeDoubleInteger" -- :: Double# -> (#Integer, Int##) #endif | [Lit (DoubleLiteral i)] <- args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc !(D# a) = wordToDouble i !(# b, c #) = decodeDoubleInteger a in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (integerToIntegerLiteral b) , Left (integerToIntLiteral . toInteger $ I# c)]) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerEncodeDouble#" -- :: Integer -> Int# -> Double #else "GHC.Integer.Type.encodeDoubleInteger" -- :: Integer -> Int# -> Double #endif | [iV, Lit (IntLiteral j)] <- args , [i] <- integerLiterals' [iV] -> let !(I# k') = fromInteger j r = encodeDoubleInteger i k' in reduce . Literal . DoubleLiteral . doubleToWord $ D# r #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerEncodeFloat#" | [iV, Lit (IntLiteral j)] <- args , [i] <- integerLiterals' [iV] -> let !(I# k') = fromInteger j r = integerEncodeFloat# i k' in reduce . Literal . FloatLiteral . floatToWord $ F# r #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerQuotRem#" -- :: Integer -> Integer -> (#Integer, Integer#) #else "GHC.Integer.Type.quotRemInteger" -- :: Integer -> Integer -> (#Integer, Integer#) #endif | [i, j] <- integerLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc (q,r) = quotRem i j in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left $ catchDivByZero (integerToIntegerLiteral q) , Left $ catchDivByZero (integerToIntegerLiteral r)]) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerAdd" #else "GHC.Integer.Type.plusInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (integerToIntegerLiteral (i+j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerSub" #else "GHC.Integer.Type.minusInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (integerToIntegerLiteral (i-j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerMul" #else "GHC.Integer.Type.timesInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (integerToIntegerLiteral (i*j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerNegate" #else "GHC.Integer.Type.negateInteger" #endif | [i] <- integerLiterals' args -> reduce (integerToIntegerLiteral (negate i)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerDiv" #else "GHC.Integer.Type.divInteger" #endif | Just (i,j) <- integerLiterals args -> reduce $ catchDivByZero (integerToIntegerLiteral (i `div` j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerMod" #else "GHC.Integer.Type.modInteger" #endif | Just (i,j) <- integerLiterals args -> reduce $ catchDivByZero (integerToIntegerLiteral (i `mod` j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerQuot" #else "GHC.Integer.Type.quotInteger" #endif | Just (i,j) <- integerLiterals args -> reduce $ catchDivByZero (integerToIntegerLiteral (i `quot` j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerRem" #else "GHC.Integer.Type.remInteger" #endif | Just (i,j) <- integerLiterals args -> reduce $ catchDivByZero (integerToIntegerLiteral (i `rem` j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerDivMod#" #else "GHC.Integer.Type.divModInteger" #endif | Just (i,j) <- integerLiterals args -> let (_,tyView -> TyConApp ubTupTcNm [liftedKi,_,intTy,_]) = splitFunForallTy ty (Just ubTupTc) = UniqMap.lookup ubTupTcNm tcm [ubTupDc] = tyConDataCons ubTupTc (d,m) = divMod i j in reduce $ mkApps (Data ubTupDc) [ Right liftedKi, Right liftedKi , Right intTy, Right intTy , Left $ catchDivByZero (Literal (IntegerLiteral d)) , Left $ catchDivByZero (Literal (IntegerLiteral m)) ] #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerGt" #else "GHC.Integer.Type.gtInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerGe" #else "GHC.Integer.Type.geInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerEq" #else "GHC.Integer.Type.eqInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerNe" #else "GHC.Integer.Type.neqInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerLt" #else "GHC.Integer.Type.ltInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerLe" #else "GHC.Integer.Type.leInteger" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerGt#" #else "GHC.Integer.Type.gtInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i > j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerGe#" #else "GHC.Integer.Type.geInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i >= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerEq#" #else "GHC.Integer.Type.eqInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i == j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerNe#" #else "GHC.Integer.Type.neqInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i /= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerLt#" #else "GHC.Integer.Type.ltInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i < j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerLe#" #else "GHC.Integer.Type.leInteger#" #endif | Just (i,j) <- integerLiterals args -> reduce (boolToIntLiteral (i <= j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerCompare" #else "GHC.Integer.Type.compareInteger" -- :: Integer -> Integer -> Ordering #endif | [i, j] <- integerLiterals' args -> let -- Get the required result type (viewed as an applied type constructor name) (_,tyView -> TyConApp tupTcNm []) = splitFunForallTy ty -- Find the type constructor from the name (Just tupTc) = UniqMap.lookup tupTcNm tcm -- Get the data constructors of that type -- The type is 'Ordering', so they are: 'LT', 'EQ', 'GT' [ltDc, eqDc, gtDc] = tyConDataCons tupTc -- Do the actual compile-time evaluation ordVal = compareInteger i j in reduce $ case ordVal of LT -> Data ltDc EQ -> Data eqDc GT -> Data gtDc #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerShiftR#" | [iV, Lit (WordLiteral j)] <- args #else "GHC.Integer.Type.shiftRInteger" | [iV, Lit (IntLiteral j)] <- args #endif , [i] <- integerLiterals' [iV] -> reduce (integerToIntegerLiteral (i `shiftR` fromInteger j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerShiftL#" | [iV, Lit (WordLiteral j)] <- args #else "GHC.Integer.Type.shiftLInteger" | [iV, Lit (IntLiteral j)] <- args #endif , [i] <- integerLiterals' [iV] -> reduce (integerToIntegerLiteral (i `shiftL` fromInteger j)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerFromWord#" #else "GHC.Integer.Type.wordToInteger" #endif | [Lit (WordLiteral w)] <- args -> reduce (Literal (IntegerLiteral w)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerToWord#" #else "GHC.Integer.Type.integerToWord" #endif | [i] <- integerLiterals' args -> reduce (integerToWordLiteral i) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerTestBit#" -- :: Integer -> Int# -> Int# | [Lit (IntegerLiteral i), Lit (WordLiteral j)] <- args -> reduce (boolToIntLiteral (testBit i (fromInteger j))) #else "GHC.Integer.Type.testBitInteger" -- :: Integer -> Int# -> Bool | [Lit (IntegerLiteral i), Lit (IntLiteral j)] <- args -> reduce (boolToBoolLiteral tcm ty (testBit i (fromInteger j))) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.NS" | [Lit (WordLiteral w)] <- args -> reduce (Literal (NaturalLiteral w)) "GHC.Num.Natural.NB" | [Lit (ByteArrayLiteral (BA.ByteArray ba))] <- args -> reduce (Literal (NaturalLiteral (IP ba))) | [Lit l] <- args -> error ("NB: " <> show l) "GHC.Num.Integer.IS" | [Lit (IntLiteral i)] <- args -> reduce (Literal (IntegerLiteral i)) "GHC.Num.Integer.IP" | [Lit (ByteArrayLiteral (BA.ByteArray ba))] <- args -> reduce (Literal (IntegerLiteral (IP ba))) | [Lit l] <- args -> error ("IP: " <> show l) "GHC.Num.Integer.IN" | [Lit (ByteArrayLiteral (BA.ByteArray ba))] <- args -> reduce (Literal (IntegerLiteral (IN ba))) | [Lit l] <- args -> error ("IN: " <> show l) #else "GHC.Natural.NatS#" | [Lit (WordLiteral w)] <- args -> reduce (Literal (NaturalLiteral w)) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerFromNatural" #else "GHC.Natural.naturalToInteger" #endif | [i] <- naturalLiterals' args -> reduce (Literal (IntegerLiteral (toInteger i))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerToNatural" #else "GHC.Natural.naturalFromInteger" #endif | [i] <- integerLiterals' args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange1 nTy i id) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerToNaturalClamp" | [i] <- integerLiterals' args -> if i < 0 then reduce (naturalToNaturalLiteral 0) else reduce (naturalToNaturalLiteral (fromInteger i)) "GHC.Num.Integer.integerToNaturalThrow" | [i] <- integerLiterals' args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange1 nTy i id) #endif "GHC.Num.Integer.integerToInt64#" | [i] <- integerLiterals' args -> reduce (integerToInt64Literal i) "GHC.Num.Integer.integerToWord64#" | [i] <- integerLiterals' args -> reduce (integerToWord64Literal i) #if MIN_VERSION_base(4,17,0) "GHC.Num.Integer.integerFromWord64#" | [w] <- word64Literals' args -> reduce (Literal (IntegerLiteral w)) #endif #if !MIN_VERSION_base(4,15,0) -- GHC.shiftLNatural --- XXX: Fragile worker of GHC.shiflLNatural "GHC.Natural.$wshiftLNatural" | [nV,iV] <- args , [n] <- naturalLiterals' [nV] , [i] <- fromInteger <$> intLiterals' [iV] -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange1 nTy n ((flip shiftL) i)) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalAdd" #else "GHC.Natural.plusNatural" #endif | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j (+)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalMul" #else "GHC.Natural.timesNatural" #endif | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j (*)) #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalSubUnsafe" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange nTy [i, j] (\[i', j'] -> naturalToNaturalLiteral (naturalSubUnsafe i' j'))) "GHC.Num.Natural.naturalSubThrow" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange nTy [i, j] (\[i', j'] -> case minusNaturalMaybe i' j' of Nothing -> checkNaturalRange1 nTy (-1) id Just n -> naturalToNaturalLiteral n)) #else "GHC.Natural.minusNatural" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange nTy [i, j] (\[i', j'] -> case minusNaturalMaybe i' j' of Nothing -> checkNaturalRange1 nTy (-1) id Just n -> naturalToNaturalLiteral n)) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalFromWord#" #else "GHC.Natural.wordToNatural#" #endif | [Lit (WordLiteral w)] <- args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange1 nTy w id) #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalToWord#" | [i] <- naturalLiterals' args -> reduce (integerToWordLiteral i) "GHC.Num.Natural.naturalQuot" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j quot) "GHC.Num.Natural.naturalRem" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j rem) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalQuotRem#" -- :: Natural -> Natural -> (#Natural, Natural#) | [i, j] <- naturalLiterals' args -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc (q,r) = quotRem (fromInteger i) (fromInteger j) in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left $ catchDivByZero (naturalToNaturalLiteral q) , Left $ catchDivByZero (naturalToNaturalLiteral r)]) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalGcd" #else "GHC.Natural.gcdNatural" #endif | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j gcd) #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalLcm" | Just (i,j) <- naturalLiterals args -> let nTy = snd (splitFunForallTy ty) in reduce (checkNaturalRange2 nTy i j lcm) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Natural.naturalGt#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i > j)) "GHC.Num.Natural.naturalGe#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i >= j)) "GHC.Num.Natural.naturalEq#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i == j)) "GHC.Num.Natural.naturalNe#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i /= j)) "GHC.Num.Natural.naturalLt#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i < j)) "GHC.Num.Natural.naturalLe#" | Just (i,j) <- naturalLiterals args -> reduce (boolToIntLiteral (i <= j)) "GHC.Num.Natural.naturalShiftL#" | [iV, Lit (WordLiteral j)] <- args , [i] <- naturalLiterals' [iV] -> reduce (naturalToNaturalLiteral (fromInteger (i `shiftL` fromInteger j))) "GHC.Num.Natural.naturalShiftR#" | [iV, Lit (WordLiteral j)] <- args , [i] <- naturalLiterals' [iV] -> reduce (naturalToNaturalLiteral (fromInteger (i `shiftR` fromInteger j))) "GHC.Num.Natural.naturalCompare" | [i, j] <- naturalLiterals' args -> let -- Get the required result type (viewed as an applied type constructor name) (_,tyView -> TyConApp tupTcNm []) = splitFunForallTy ty -- Find the type constructor from the name (Just tupTc) = UniqMap.lookup tupTcNm tcm -- Get the data constructors of that type -- The type is 'Ordering', so they are: 'LT', 'EQ', 'GT' [ltDc, eqDc, gtDc] = tyConDataCons tupTc -- Do the actual compile-time evaluation ordVal = compareInteger i j in reduce $ case ordVal of LT -> Data ltDc EQ -> Data eqDc GT -> Data gtDc "GHC.Num.Natural.naturalSignum" | [i] <- naturalLiterals' args -> reduce (Literal (NaturalLiteral (signum i))) "GHC.Num.Natural.$wnaturalSignum" | [i] <- naturalLiterals' args -> reduce (Literal (WordLiteral (signum i))) #endif -- GHC.Real.^ -- XXX: Very fragile -- ^_f, $wf, $wf1 are specialisations of the internal function f in the implementation of (^) in GHC.Real "GHC.Real.^_f" -- :: Integer -> Integer -> Integer | [i,j] <- integerLiterals' args -> reduce (integerToIntegerLiteral $ i ^ j) "GHC.Real.$wf" -- :: Integer -> Int# -> Integer | [iV, Lit (IntLiteral j)] <- args , [i] <- integerLiterals' [iV] -> reduce (integerToIntegerLiteral $ i ^ j) "GHC.Real.$wf1" -- :: Int# -> Int# -> Int# | [Lit (IntLiteral i), Lit (IntLiteral j)] <- args -> reduce (integerToIntLiteral $ i ^ j) -- Type level ^ -- XXX: Very fragile -- These is are specialized versions of ^_f, named by some combination of ghc and singletons. "Data.Singletons.TypeLits.Internal.$fSingI->^@#@$_f" -- ghc-8.6.5, singletons-2.5.1 | [i,j] <- naturalLiterals' args -> reduce (Literal (NaturalLiteral (i ^ j))) "Data.Singletons.TypeLits.Internal.%^_f" -- ghc-8.8.1, singletons-2.6 | [i,j] <- naturalLiterals' args -> reduce (Literal (NaturalLiteral (i ^ j))) "GHC.TypeLits.natVal" | [Lit (NaturalLiteral n), _] <- args -> reduce (integerToIntegerLiteral n) "GHC.TypeNats.natVal" | [Lit (NaturalLiteral n), _] <- args -> reduce (Literal (NaturalLiteral n)) "GHC.TypeNats.someNatVal" | [Lit (NaturalLiteral n)] <- args -> let resTy = getResultTy tcm ty tys in reduce (mkSomeNat tcm n resTy) "GHC.Internal.TypeNats.natVal" | [Lit (NaturalLiteral n), _] <- args -> reduce (Literal (NaturalLiteral n)) "GHC.Internal.TypeNats.someNatVal" | [Lit (NaturalLiteral n)] <- args -> let resTy = getResultTy tcm ty tys in reduce (mkSomeNat tcm n resTy) "GHC.Types.I#" | isSubj , [Lit (IntLiteral i)] <- args -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc in reduce (mkApps (Data intDc) [Left (Literal (IntLiteral i))]) "GHC.Int.I8#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Int8Literal i)] <- args #else , [Lit (IntLiteral i)] <- args #endif -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data intDc) [Left (Literal (Int8Literal i))]) #else in reduce (mkApps (Data intDc) [Left (Literal (IntLiteral i))]) #endif "GHC.Int.I16#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Int16Literal i)] <- args #else , [Lit (IntLiteral i)] <- args #endif -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data intDc) [Left (Literal (Int16Literal i))]) #else in reduce (mkApps (Data intDc) [Left (Literal (IntLiteral i))]) #endif "GHC.Int.I32#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Int32Literal i)] <- args #else , [Lit (IntLiteral i)] <- args #endif -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data intDc) [Left (Literal (Int32Literal i))]) #else in reduce (mkApps (Data intDc) [Left (Literal (IntLiteral i))]) #endif "GHC.Int.I64#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Int64Literal i)] <- args #else , [Lit (IntLiteral i)] <- args #endif -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data intDc) [Left (Literal (Int64Literal i))]) #else in reduce (mkApps (Data intDc) [Left (Literal (IntLiteral i))]) #endif "GHC.Word.W8#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Word8Literal c)] <- args #else , [Lit (WordLiteral c)] <- args #endif -> let (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data wordDc) [Left (Literal (Word8Literal c))]) #else in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral c))]) #endif "GHC.Word.W16#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Word16Literal c)] <- args #else , [Lit (WordLiteral c)] <- args #endif -> let (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data wordDc) [Left (Literal (Word16Literal c))]) #else in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral c))]) #endif "GHC.Word.W32#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Word32Literal c)] <- args #else , [Lit (WordLiteral c)] <- args #endif -> let (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data wordDc) [Left (Literal (Word32Literal c))]) #else in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral c))]) #endif "GHC.Word.W64#" | isSubj #if MIN_VERSION_base(4,16,0) , [Lit (Word64Literal c)] <- args #else , [Lit (WordLiteral c)] <- args #endif -> let (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc #if MIN_VERSION_base(4,16,0) in reduce (mkApps (Data wordDc) [Left (Literal (Word64Literal c))]) #else in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral c))]) #endif "GHC.Types.W#" | isSubj , [Lit (WordLiteral i)] <- args -> let (_,tyView -> TyConApp intTcNm []) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc in reduce (mkApps (Data intDc) [Left (Literal (WordLiteral i))]) "GHC.Float.$w$sfromRat''" -- XXX: Very fragile | [Lit (IntLiteral _minEx) ,Lit (IntLiteral matDigs) ,nV ,dV] <- args , [n,d] <- integerLiterals' [nV,dV] -> case fromInteger matDigs of matDigs' | matDigs' == floatDigits (undefined :: Float) -> reduce (Literal (FloatLiteral (floatToWord (fromRational (n :% d))))) | matDigs' == floatDigits (undefined :: Double) -> reduce (Literal (DoubleLiteral (doubleToWord (fromRational (n :% d))))) _ -> error $ $(curLoc) ++ "GHC.Float.$w$sfromRat'': Not a Float or Double" "GHC.Float.$w$sfromRat''1" -- XXX: Very fragile | [Lit (IntLiteral _minEx) ,Lit (IntLiteral matDigs) ,nV ,dV] <- args , [n,d] <- integerLiterals' [nV,dV] -> case fromInteger matDigs of matDigs' | matDigs' == floatDigits (undefined :: Float) -> reduce (Literal (FloatLiteral (floatToWord (fromRational (n :% d))))) | matDigs' == floatDigits (undefined :: Double) -> reduce (Literal (DoubleLiteral (doubleToWord (fromRational (n :% d))))) _ -> error $ $(curLoc) ++ "GHC.Float.$w$sfromRat'': Not a Float or Double" #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerSignum#" #else "GHC.Integer.Type.$wsignumInteger" -- XXX: Not super-fragile, but still.. #endif | [i] <- integerLiterals' args -> reduce (Literal (IntLiteral (signum i))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerSignum" #else "GHC.Integer.Type.signumInteger" #endif | [i] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (signumInteger i))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.$wintegerSignum" | [i] <- integerLiterals' args -> reduce (Literal (IntLiteral (signum i))) #endif #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerAbs" #else "GHC.Integer.Type.absInteger" #endif | [i] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (absInteger i))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerBit#" | [i] <- wordLiterals' args #else "GHC.Integer.Type.bitInteger" | [i] <- intLiterals' args #endif -> reduce (Literal (IntegerLiteral (bit (fromInteger i)))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerComplement" #else "GHC.Integer.Type.complementInteger" #endif | [i] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (complementInteger i))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerOr" #else "GHC.Integer.Type.orInteger" #endif | [i, j] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (orInteger i j))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerXor" #else "GHC.Integer.Type.xorInteger" #endif | [i, j] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (xorInteger i j))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerAnd" #else "GHC.Integer.Type.andInteger" #endif | [i, j] <- integerLiterals' args -> reduce (Literal (IntegerLiteral (andInteger i j))) #if MIN_VERSION_base(4,15,0) "GHC.Num.Integer.integerToDouble#" #else "GHC.Integer.Type.doubleFromInteger" #endif | [i] <- integerLiterals' args -> reduce (Literal (DoubleLiteral (doubleToWord (fromInteger i)))) #if MIN_VERSION_base(4,17,0) "GHC.Num.Integer.$wintegerFromInt64#" | [i] <- int64Literals' args -> reduce . Literal $ IntLiteral i #endif "GHC.Base.eqString" | [PrimVal _ _ [Lit (StringLiteral s1)] ,PrimVal _ _ [Lit (StringLiteral s2)] ] <- args -> reduce (boolToBoolLiteral tcm ty (s1 == s2)) | otherwise -> error (show args) "GHC.Base.quotInt" | [ DC intDc [Left (Literal (IntLiteral i))] , DC _ [Left (Literal (IntLiteral j))] ] <- args -> reduce (App (Data intDc) (Literal (IntLiteral (i `quot` j)))) "GHC.Base.remInt" | [ DC intDc [Left (Literal (IntLiteral i))] , DC _ [Left (Literal (IntLiteral j))] ] <- args -> reduce (App (Data intDc) (Literal (IntLiteral (i `rem` j)))) "GHC.Base.divInt" | [ DC intDc [Left (Literal (IntLiteral i))] , DC _ [Left (Literal (IntLiteral j))] ] <- args -> reduce (App (Data intDc) (Literal (IntLiteral (i `div` j)))) "GHC.Base.modInt" | [ DC intDc [Left (Literal (IntLiteral i))] , DC _ [Left (Literal (IntLiteral j))] ] <- args -> reduce (App (Data intDc) (Literal (IntLiteral (i `mod` j)))) "Clash.Class.BitPack.Internal.packDouble#" -- :: Double -> BitVector 64 | [DC _ [Left arg]] <- args , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach2@Machine{mStack=[],mTerm=Literal (DoubleLiteral i)} <- whnf eval tcm True (setTerm arg $ stackClear mach) -> let resTyInfo = extractTySizeInfo tcm ty tys in Just $ mach2 { mStack = mStack mach , mTerm = mkBitVectorLit' resTyInfo 0 (toInteger $ (pack :: Word64 -> BitVector 64) i) } "Clash.Class.BitPack.Internal.packFloat#" -- :: Float -> BitVector 32 | [DC _ [Left arg]] <- args , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach2@Machine{mStack=[],mTerm=Literal (FloatLiteral i)} <- whnf eval tcm True (setTerm arg $ stackClear mach) -> let resTyInfo = extractTySizeInfo tcm ty tys in Just $ mach2 { mStack = mStack mach , mTerm = mkBitVectorLit' resTyInfo 0 (toInteger $ (pack :: Word32 -> BitVector 32) i) } "Clash.Class.BitPack.Internal.unpackFloat#" | [i] <- bitVectorLiterals' args -> let resTy = getResultTy tcm ty tys val = unpack (toBV i :: BitVector 32) in reduce (mkFloatCLit tcm val resTy) "Clash.Class.BitPack.Internal.unpackDouble#" | [i] <- bitVectorLiterals' args -> let resTy = getResultTy tcm ty tys val = unpack (toBV i :: BitVector 64) in reduce (mkDoubleCLit tcm val resTy) "Clash.Sized.Internal.BitVector.xToBV" | isSubj , Just (nTy, kn) <- extractKnownNat tcm tys -- The second argument to `xToBV` is always going to be suspended. -- See Note [Lazy primitives] , [ _, (Suspend arg) ] <- args , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach1@Machine{mStack=[],mTerm=argWHNF} <- whnf eval tcm True (setTerm arg (stackClear mach)) , let undefBitVector = Just $ mach1 { mStack = mStack mach , mTerm = mkBitVectorLit ty nTy kn (bit (fromInteger kn)-1) 0 } -> case isX argWHNF of Left _ -> undefBitVector _ -> case collectArgs argWHNF of (Prim p,_) | primName p `elem` undefinedXPrims -> undefBitVector _ -> Just $ mach1 { mStack = mStack mach , mTerm = argWHNF } -- expIndex# -- :: KnownNat m -- => Index m -- -> SNat n -- -> Index (n^m) "Clash.Class.Exp.expIndex#" | [b] <- indexLiterals' args , [(_mTy, km), (_, e)] <- extractKnownNats tcm tys -> reduce (mkIndexLit ty (LitTy (NumTy (km^e))) (km^e) (b^e)) -- expSigned# -- :: KnownNat m -- => Signed m -- -> SNat n -- -> Signed (n*m) "Clash.Class.Exp.expSigned#" | [b] <- signedLiterals' args , [(_mTy, km), (_, e)] <- extractKnownNats tcm tys -> reduce (mkSignedLit ty (LitTy (NumTy (km*e))) (km*e) (b^e)) -- expUnsigned# -- :: KnownNat m -- => Unsigned m -- -> SNat n -- -> Unsigned m "Clash.Class.Exp.expUnsigned#" | [b] <- unsignedLiterals' args , [(_mTy, km), (_, e)] <- extractKnownNats tcm tys -> reduce (mkUnsignedLit ty (LitTy (NumTy (km*e))) (km*e) (b^e)) "Clash.Promoted.Nat.powSNat" | [Right a, Right b] <- map (runExcept . tyNatSize tcm) tys -> let c = case a of 2 -> 1 `shiftL` (fromInteger b) _ -> a ^ b (_,tyView -> TyConApp snatTcNm _) = splitFunForallTy ty (Just snatTc) = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc in reduce $ mkApps (Data snatDc) [ Right (LitTy (NumTy c)) , Left (Literal (NaturalLiteral c))] "Clash.Promoted.Nat.flogBaseSNat" | [Right a, Right b] <- map (runExcept . tyNatSize tcm) tys , Just c <- flogBase a b , let c' = toInteger c -> let (_,tyView -> TyConApp snatTcNm _) = splitFunForallTy ty (Just snatTc) = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc in reduce $ mkApps (Data snatDc) [ Right (LitTy (NumTy c')) , Left (Literal (NaturalLiteral c'))] "Clash.Promoted.Nat.clogBaseSNat" | [Right a, Right b] <- map (runExcept . tyNatSize tcm) tys , Just c <- clogBase a b , let c' = toInteger c -> let (_,tyView -> TyConApp snatTcNm _) = splitFunForallTy ty (Just snatTc) = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc in reduce $ mkApps (Data snatDc) [ Right (LitTy (NumTy c')) , Left (Literal (NaturalLiteral c'))] | otherwise -> error ("clogBaseSNat: args = " <> show args <> ", tys = " <> show tys) "Clash.Promoted.Nat.logBaseSNat" | [Right a, Right b] <- map (runExcept . tyNatSize tcm) tys , Just c <- flogBase a b , let c' = toInteger c -> let (_,tyView -> TyConApp snatTcNm _) = splitFunForallTy ty (Just snatTc) = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc in reduce $ mkApps (Data snatDc) [ Right (LitTy (NumTy c')) , Left (Literal (NaturalLiteral c'))] ------------ -- BitVector ------------ -- Constructor "Clash.Sized.Internal.BitVector.BV" | [Right _] <- map (runExcept . tyNatSize tcm) tys , Just (m,i) <- integerLiterals args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo m i) "Clash.Sized.Internal.BitVector.Bit" | Just (m,i) <- integerLiterals args -> reduce (mkBitLit ty m i) -- Initialisation "Clash.Sized.Internal.BitVector.size#" | Just (_, kn) <- extractKnownNat tcm tys -> let (_,tyView -> TyConApp intTcNm _) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral kn))]) "Clash.Sized.Internal.BitVector.maxIndex#" | Just (_, kn) <- extractKnownNat tcm tys -> let (_,tyView -> TyConApp intTcNm _) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral (kn-1)))]) -- Construction "Clash.Sized.Internal.BitVector.high" -> reduce (mkBitLit ty 0 1) "Clash.Sized.Internal.BitVector.low" -> reduce (mkBitLit ty 0 0) "Clash.Sized.Internal.BitVector.undefined#" | Just (_, kn) <- extractKnownNat tcm tys -> let resTyInfo = extractTySizeInfo tcm ty tys mask = bit (fromInteger kn) - 1 in reduce (mkBitVectorLit' resTyInfo mask 0) -- Eq "Clash.Sized.Internal.BitVector.eq##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) "Clash.Sized.Internal.BitVector.neq##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) -- Ord "Clash.Sized.Internal.BitVector.lt##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) "Clash.Sized.Internal.BitVector.ge##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) "Clash.Sized.Internal.BitVector.gt##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) "Clash.Sized.Internal.BitVector.le##" | [(0,i),(0,j)] <- bitLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) -- Enum "Clash.Sized.Internal.BitVector.toEnum##" | [i] <- intCLiterals' args -> let Bit msk val = BitVector.toEnum## (fromInteger i) in reduce (mkBitLit ty (toInteger msk) (toInteger val)) -- Bits "Clash.Sized.Internal.BitVector.and##" | [i,j] <- bitLiterals args -> let Bit msk val = BitVector.and## (toBit i) (toBit j) in reduce (mkBitLit ty (toInteger msk) (toInteger val)) "Clash.Sized.Internal.BitVector.or##" | [i,j] <- bitLiterals args -> let Bit msk val = BitVector.or## (toBit i) (toBit j) in reduce (mkBitLit ty (toInteger msk) (toInteger val)) "Clash.Sized.Internal.BitVector.xor##" | [i,j] <- bitLiterals args -> let Bit msk val = BitVector.xor## (toBit i) (toBit j) in reduce (mkBitLit ty (toInteger msk) (toInteger val)) "Clash.Sized.Internal.BitVector.complement##" | [i] <- bitLiterals args -> let Bit msk val = BitVector.complement## (toBit i) in reduce (mkBitLit ty (toInteger msk) (toInteger val)) -- Pack "Clash.Sized.Internal.BitVector.pack#" | [(msk,i)] <- bitLiterals args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo msk i) "Clash.Sized.Internal.BitVector.unpack#" | [(msk,i)] <- bitVectorLiterals' args -> reduce (mkBitLit ty msk i) -- Concatenation "Clash.Sized.Internal.BitVector.++#" -- :: KnownNat m => BitVector n -> BitVector m -> BitVector (n + m) | Just (_,m) <- extractKnownNat tcm tys , [(mski,i),(mskj,j)] <- bitVectorLiterals' args -> let val = i `shiftL` fromInteger m .|. j msk = mski `shiftL` fromInteger m .|. mskj resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo msk val) -- Reduction "Clash.Sized.Internal.BitVector.reduceAnd#" -- :: KnownNat n => BitVector n -> Bit | [i] <- bitVectorLiterals' args , Just (_, kn) <- extractKnownNat tcm tys -> let resTy = getResultTy tcm ty tys val = reifyNat kn (op (toBV i)) in reduce (mkBitLit resTy 0 val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op u _ = toInteger (BitVector.reduceAnd# u) "Clash.Sized.Internal.BitVector.reduceOr#" -- :: KnownNat n => BitVector n -> Bit | [i] <- bitVectorLiterals' args , Just (_, kn) <- extractKnownNat tcm tys -> let resTy = getResultTy tcm ty tys val = reifyNat kn (op (toBV i)) in reduce (mkBitLit resTy 0 val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op u _ = toInteger (BitVector.reduceOr# u) "Clash.Sized.Internal.BitVector.reduceXor#" -- :: KnownNat n => BitVector n -> Bit | [i] <- bitVectorLiterals' args , Just (_, kn) <- extractKnownNat tcm tys -> let resTy = getResultTy tcm ty tys val = reifyNat kn (op (toBV i)) in reduce (mkBitLit resTy 0 val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op u _ = toInteger (BitVector.reduceXor# u) -- Indexing "Clash.Sized.Internal.BitVector.index#" -- :: KnownNat n => BitVector n -> Int -> Bit | Just (_,kn,i,j) <- bitVectorLitIntLit tcm tys args -> let resTy = getResultTy tcm ty tys (msk,val) = reifyNat kn (op (toBV i) (fromInteger j)) in reduce (mkBitLit resTy msk val) where op :: KnownNat n => BitVector n -> Int -> Proxy n -> (Integer,Integer) op u i _ = (toInteger m, toInteger v) where Bit m v = (BitVector.index# u i) "Clash.Sized.Internal.BitVector.replaceBit#" -- :: :: KnownNat n => BitVector n -> Int -> Bit -> BitVector n | Just (_, n) <- extractKnownNat tcm tys , [ _ , PrimVal bvP _ [_, Lit (NaturalLiteral mskBv), Lit (IntegerLiteral bv)] , valArgs -> Just [Literal (IntLiteral i)] , PrimVal bP _ [Lit (WordLiteral mskB), Lit (IntegerLiteral b)] ] <- args , primName bvP == "Clash.Sized.Internal.BitVector.fromInteger#" , primName bP == "Clash.Sized.Internal.BitVector.fromInteger##" -> let resTyInfo = extractTySizeInfo tcm ty tys (mskVal,val) = reifyNat n (op (BV (fromInteger mskBv) (fromInteger bv)) (fromInteger i) (Bit (fromInteger mskB) (fromInteger b))) in reduce (mkBitVectorLit' resTyInfo mskVal val) where op :: KnownNat n => BitVector n -> Int -> Bit -> Proxy n -> (Integer,Integer) -- op bv i b _ = (BitVector.unsafeMask res, BitVector.unsafeToInteger res) op bv i b _ = splitBV (BitVector.replaceBit# bv i b) "Clash.Sized.Internal.BitVector.setSlice#" -- :: SNat (m+1+i) -> BitVector (m + 1 + i) -> SNat m -> SNat n -> BitVector (m + 1 - n) -> BitVector (m + 1 + i) | mTy : iTy : nTy : _ <- tys , Right m <- runExcept (tyNatSize tcm mTy) , Right iN <- runExcept (tyNatSize tcm iTy) , Right n <- runExcept (tyNatSize tcm nTy) , [i,j] <- bitVectorLiterals' args -> let BV msk val = BitVector.setSlice# (unsafeSNat (m+1+iN)) (toBV i) (unsafeSNat m) (unsafeSNat n) (toBV j) resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo (toInteger msk) (toInteger val)) "Clash.Sized.Internal.BitVector.slice#" -- :: BitVector (m + 1 + i) -> SNat m -> SNat n -> BitVector (m + 1 - n) | mTy : _ : nTy : _ <- tys , Right m <- runExcept (tyNatSize tcm mTy) , Right n <- runExcept (tyNatSize tcm nTy) , [i] <- bitVectorLiterals' args -> let BV msk val = BitVector.slice# (toBV i) (unsafeSNat m) (unsafeSNat n) resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo (toInteger msk) (toInteger val)) "Clash.Sized.Internal.BitVector.split#" -- :: forall n m. KnownNat n => BitVector (m + n) -> (BitVector m, BitVector n) | nTy : mTy : _ <- tys , Right n <- runExcept (tyNatSize tcm nTy) , Right m <- runExcept (tyNatSize tcm mTy) , [(mski,i)] <- bitVectorLiterals' args -> let ty' = piResultTys tcm ty tys (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty' (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc bvTy : _ = tyArgs valM = i `shiftR` fromInteger n mskM = mski `shiftR` fromInteger n valN = i .&. mask mskN = mski .&. mask mask = bit (fromInteger n) - 1 in reduce $ mkApps (Data tupDc) (map Right tyArgs ++ [ Left (mkBitVectorLit bvTy mTy m mskM valM) , Left (mkBitVectorLit bvTy nTy n mskN valN)]) "Clash.Sized.Internal.BitVector.msb#" -- :: forall n. KnownNat n => BitVector n -> Bit | [i] <- bitVectorLiterals' args , Just (_, kn) <- extractKnownNat tcm tys -> let resTy = getResultTy tcm ty tys (msk,val) = reifyNat kn (op (toBV i)) in reduce (mkBitLit resTy (toInteger msk) (toInteger val)) where op :: KnownNat n => BitVector n -> Proxy n -> (Word,Word) op u _ = (unsafeMask# res, BitVector.unsafeToInteger# res) where res = BitVector.msb# u "Clash.Sized.Internal.BitVector.lsb#" -- :: BitVector n -> Bit | [i] <- bitVectorLiterals' args -> let resTy = getResultTy tcm ty tys Bit msk val = BitVector.lsb# (toBV i) in reduce (mkBitLit resTy (toInteger msk) (toInteger val)) -- Eq -- eq#, neq# :: KnownNat n => BitVector n -> BitVector n -> Bool "Clash.Sized.Internal.BitVector.eq#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty True) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.eq# ty tcm args) -> reduce val "Clash.Sized.Internal.BitVector.neq#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty False) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.neq# ty tcm args) -> reduce val -- Ord -- lt#,ge#,gt#,le# :: KnownNat n => BitVector n -> BitVector n -> Bool "Clash.Sized.Internal.BitVector.lt#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty False) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.lt# ty tcm args) -> reduce val "Clash.Sized.Internal.BitVector.ge#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty True) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.ge# ty tcm args) -> reduce val "Clash.Sized.Internal.BitVector.gt#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty False) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.gt# ty tcm args) -> reduce val "Clash.Sized.Internal.BitVector.le#" | nTy : _ <- tys , Right 0 <- runExcept (tyNatSize tcm nTy) -> reduce (boolToBoolLiteral tcm ty True) | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2Bool BitVector.le# ty tcm args) -> reduce val -- Enum "Clash.Sized.Internal.BitVector.toEnum#" | let resTyInfo@(_,_,kn) = extractTySizeInfo tcm ty tys , Just val <- reifyNat kn (liftInteger2BitVector (BitVector.toEnum# . fromInteger) resTyInfo args) -> reduce val "Clash.Sized.Internal.BitVector.fromEnum#" | Just (_, kn) <- extractKnownNat tcm tys , let resTy = getResultTy tcm ty tys , Just val <- reifyNat kn (liftBitVector2CInt tcm resTy (toInteger . BitVector.fromEnum#) args) -> reduce val -- Bounded "Clash.Sized.Internal.BitVector.minBound#" | Just (nTy,len) <- extractKnownNat tcm tys -> reduce (mkBitVectorLit ty nTy len 0 0) "Clash.Sized.Internal.BitVector.maxBound#" | Just (litTy,mb) <- extractKnownNat tcm tys -> let maxB = (2 ^ mb) - 1 in reduce (mkBitVectorLit ty litTy mb 0 maxB) -- Num "Clash.Sized.Internal.BitVector.+#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.+#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.-#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.-#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.*#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.*#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.negate#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- bitVectorLiterals' args -> let (msk,val) = reifyNat kn (op (toBV i)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Proxy n -> (Integer,Integer) op u _ = splitBV (BitVector.negate# u) -- ExtendingNum "Clash.Sized.Internal.BitVector.plus#" -- :: (KnownNat n, KnownNat m) => BitVector m -> BitVector n -> BitVector (Max m n + 1) | [(0,i),(0,j)] <- bitVectorLiterals' args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkBitVectorLit resTy resSizeTy resSizeInt 0 (i+j)) "Clash.Sized.Internal.BitVector.minus#" | [(0,i),(0,j)] <- bitVectorLiterals' args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) val = reifyNat resSizeInt (runSizedF (BitVector.-#) i j) in reduce (mkBitVectorLit resTy resSizeTy resSizeInt 0 val) "Clash.Sized.Internal.BitVector.times#" | [(0,i),(0,j)] <- bitVectorLiterals' args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkBitVectorLit resTy resSizeTy resSizeInt 0 (i*j)) -- Integral "Clash.Sized.Internal.BitVector.quot#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.quot#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.BitVector.rem#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.rem#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.BitVector.toInteger#" | Just (_, kn) <- extractKnownNat tcm tys , [i] <- bitVectorLiterals' args -> let val = reifyNat kn (op (toBV i)) in reduce (integerToIntegerLiteral val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op u _ = BitVector.toInteger# u -- Bits "Clash.Sized.Internal.BitVector.and#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.and#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.or#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.or#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.xor#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftBitVector2 (BitVector.xor#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.BitVector.complement#" | [i] <- bitVectorLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> let (msk,val) = reifyNat kn (op (toBV i)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Proxy n -> (Integer,Integer) op u _ = splitBV $ BitVector.complement# u "Clash.Sized.Internal.BitVector.shiftL#" | Just (nTy,kn,i,j) <- bitVectorLitIntLit tcm tys args -> let (msk,val) = reifyNat kn (op (toBV i) (fromInteger j)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Int -> Proxy n -> (Integer,Integer) op u i _ = splitBV (BitVector.shiftL# u i) "Clash.Sized.Internal.BitVector.shiftR#" | Just (nTy,kn,i,j) <- bitVectorLitIntLit tcm tys args -> let (msk,val) = reifyNat kn (op (toBV i) (fromInteger j)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Int -> Proxy n -> (Integer,Integer) op u i _ = splitBV (BitVector.shiftR# u i) "Clash.Sized.Internal.BitVector.rotateL#" | Just (nTy,kn,i,j) <- bitVectorLitIntLit tcm tys args -> let (msk,val) = reifyNat kn (op (toBV i) (fromInteger j)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Int -> Proxy n -> (Integer,Integer) op u i _ = splitBV (BitVector.rotateL# u i) "Clash.Sized.Internal.BitVector.rotateR#" | Just (nTy,kn,i,j) <- bitVectorLitIntLit tcm tys args -> let (msk,val) = reifyNat kn (op (toBV i) (fromInteger j)) in reduce (mkBitVectorLit ty nTy kn msk val) where op :: KnownNat n => BitVector n -> Int -> Proxy n -> (Integer,Integer) op u i _ = splitBV (BitVector.rotateR# u i) -- truncateB "Clash.Sized.Internal.BitVector.truncateB#" -- forall a b . KnownNat a => BitVector (a + b) -> BitVector a | aTy : _ <- tys , Right ka <- runExcept (tyNatSize tcm aTy) , [(mski,i)] <- bitVectorLiterals' args -> let bitsKeep = (bit (fromInteger ka)) - 1 val = i .&. bitsKeep msk = mski .&. bitsKeep in reduce (mkBitVectorLit ty aTy ka msk val) -------- -- Index -------- -- BitPack "Clash.Sized.Internal.Index.pack#" | nTy : _ <- tys , Right _ <- runExcept (tyNatSize tcm nTy) , [i] <- indexLiterals' args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo 0 i) "Clash.Sized.Internal.Index.unpack#" | Just (nTy,kn) <- extractKnownNat tcm tys , [(0,i)] <- bitVectorLiterals' args -> reduce (mkIndexLit ty nTy kn i) -- Eq "Clash.Sized.Internal.Index.eq#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) "Clash.Sized.Internal.Index.neq#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) -- Ord "Clash.Sized.Internal.Index.lt#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) "Clash.Sized.Internal.Index.ge#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) "Clash.Sized.Internal.Index.gt#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) "Clash.Sized.Internal.Index.le#" | Just (i,j) <- indexLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) -- Enum "Clash.Sized.Internal.Index.toEnum#" | [i] <- intCLiterals' args , Just (nTy, mb) <- extractKnownNat tcm tys -> reduce (mkIndexLit ty nTy mb i) "Clash.Sized.Internal.Index.fromEnum#" | [i] <- indexLiterals' args -> let resTy = getResultTy tcm ty tys in reduce (mkIntCLit tcm i resTy) -- Bounded "Clash.Sized.Internal.Index.maxBound#" | Just (nTy,mb) <- extractKnownNat tcm tys -> reduce (mkIndexLit ty nTy mb (mb - 1)) -- Num "Clash.Sized.Internal.Index.+#" | Just (nTy,kn) <- extractKnownNat tcm tys , [i,j] <- indexLiterals' args -> reduce (mkIndexLit ty nTy kn (i + j)) "Clash.Sized.Internal.Index.-#" | Just (nTy,kn) <- extractKnownNat tcm tys , [i,j] <- indexLiterals' args -> reduce (mkIndexLit ty nTy kn (i - j)) "Clash.Sized.Internal.Index.*#" | Just (nTy,kn) <- extractKnownNat tcm tys , [i,j] <- indexLiterals' args -> reduce (mkIndexLit ty nTy kn (i * j)) -- ExtendingNum "Clash.Sized.Internal.Index.plus#" | mTy : nTy : _ <- tys , Right _ <- runExcept (tyNatSize tcm mTy) , Right _ <- runExcept (tyNatSize tcm nTy) , Just (i,j) <- indexLiterals args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkIndexLit' resTyInfo (i + j)) "Clash.Sized.Internal.Index.minus#" | mTy : nTy : _ <- tys , Right _ <- runExcept (tyNatSize tcm mTy) , Right _ <- runExcept (tyNatSize tcm nTy) , Just (i,j) <- indexLiterals args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkIndexLit' resTyInfo (i - j)) "Clash.Sized.Internal.Index.times#" | mTy : nTy : _ <- tys , Right _ <- runExcept (tyNatSize tcm mTy) , Right _ <- runExcept (tyNatSize tcm nTy) , Just (i,j) <- indexLiterals args -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkIndexLit' resTyInfo (i * j)) -- Integral "Clash.Sized.Internal.Index.quot#" | Just (nTy,kn) <- extractKnownNat tcm tys , Just (i,j) <- indexLiterals args -> reduce $ catchDivByZero (mkIndexLit ty nTy kn (i `quot` j)) "Clash.Sized.Internal.Index.rem#" | Just (nTy,kn) <- extractKnownNat tcm tys , Just (i,j) <- indexLiterals args -> reduce $ catchDivByZero (mkIndexLit ty nTy kn (i `rem` j)) "Clash.Sized.Internal.Index.toInteger#" | [PrimVal p _ [_, Lit (IntegerLiteral i)]] <- args , primName p == "Clash.Sized.Internal.Index.fromInteger#" -> reduce (integerToIntegerLiteral i) -- Resize "Clash.Sized.Internal.Index.resize#" | Just (mTy,m) <- extractKnownNat tcm tys , [i] <- indexLiterals' args -> reduce (mkIndexLit ty mTy m i) --------- -- Signed --------- "Clash.Sized.Internal.Signed.size#" | Just (_, kn) <- extractKnownNat tcm tys -> let (_,tyView -> TyConApp intTcNm _) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral kn))]) -- BitPack "Clash.Sized.Internal.Signed.pack#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- signedLiterals' args -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkBitVectorLit ty nTy kn 0 val) where op :: KnownNat n => Signed n -> Proxy n -> Integer op s _ = toInteger (Signed.pack# s) "Clash.Sized.Internal.Signed.unpack#" | Just (nTy, kn) <- extractKnownNat tcm tys , [(0,i)] <- bitVectorLiterals' args -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op s _ = toInteger (Signed.unpack# s) -- Eq "Clash.Sized.Internal.Signed.eq#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) "Clash.Sized.Internal.Signed.neq#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) -- Ord "Clash.Sized.Internal.Signed.lt#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) "Clash.Sized.Internal.Signed.ge#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) "Clash.Sized.Internal.Signed.gt#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) "Clash.Sized.Internal.Signed.le#" | Just (i,j) <- signedLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) -- Enum "Clash.Sized.Internal.Signed.toEnum#" | [i] <- intCLiterals' args , Just (litTy, mb) <- extractKnownNat tcm tys -> reduce (mkSignedLit ty litTy mb i) "Clash.Sized.Internal.Signed.fromEnum#" | [i] <- signedLiterals' args -> let resTy = getResultTy tcm ty tys in reduce (mkIntCLit tcm i resTy) -- Bounded "Clash.Sized.Internal.Signed.minBound#" | Just (litTy,mb) <- extractKnownNat tcm tys -> let minB = negate (2 ^ (mb - 1)) in reduce (mkSignedLit ty litTy mb minB) "Clash.Sized.Internal.Signed.maxBound#" | Just (litTy,mb) <- extractKnownNat tcm tys -> let maxB = (2 ^ (mb - 1)) - 1 in reduce (mkSignedLit ty litTy mb maxB) -- Num "Clash.Sized.Internal.Signed.+#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.+#) ty tcm tys args) -> reduce (val) "Clash.Sized.Internal.Signed.-#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.-#) ty tcm tys args) -> reduce (val) "Clash.Sized.Internal.Signed.*#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.*#) ty tcm tys args) -> reduce (val) "Clash.Sized.Internal.Signed.negate#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- signedLiterals' args -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Proxy n -> Integer op s _ = toInteger (Signed.negate# s) "Clash.Sized.Internal.Signed.abs#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- signedLiterals' args -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Proxy n -> Integer op s _ = toInteger (Signed.abs# s) -- ExtendingNum "Clash.Sized.Internal.Signed.plus#" | Just (i,j) <- signedLiterals args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkSignedLit resTy resSizeTy resSizeInt (i+j)) "Clash.Sized.Internal.Signed.minus#" | Just (i,j) <- signedLiterals args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkSignedLit resTy resSizeTy resSizeInt (i-j)) "Clash.Sized.Internal.Signed.times#" | Just (i,j) <- signedLiterals args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkSignedLit resTy resSizeTy resSizeInt (i*j)) -- Integral "Clash.Sized.Internal.Signed.quot#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.quot#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Signed.rem#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.rem#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Signed.div#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.div#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Signed.mod#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftSigned2 (Signed.mod#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Signed.toInteger#" | [PrimVal p _ [_, Lit (IntegerLiteral i)]] <- args , primName p == "Clash.Sized.Internal.Signed.fromInteger#" -> reduce (integerToIntegerLiteral i) -- Bits "Clash.Sized.Internal.Signed.and#" | [i,j] <- signedLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkSignedLit ty nTy kn (i .&. j)) "Clash.Sized.Internal.Signed.or#" | [i,j] <- signedLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkSignedLit ty nTy kn (i .|. j)) "Clash.Sized.Internal.Signed.xor#" | [i,j] <- signedLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkSignedLit ty nTy kn (i `xor` j)) "Clash.Sized.Internal.Signed.complement#" | [i] <- signedLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Proxy n -> Integer op u _ = toInteger (Signed.complement# u) "Clash.Sized.Internal.Signed.shiftL#" | Just (nTy,kn,i,j) <- signedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Int -> Proxy n -> Integer op u i _ = toInteger (Signed.shiftL# u i) "Clash.Sized.Internal.Signed.shiftR#" | Just (nTy,kn,i,j) <- signedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Int -> Proxy n -> Integer op u i _ = toInteger (Signed.shiftR# u i) "Clash.Sized.Internal.Signed.rotateL#" | Just (nTy,kn,i,j) <- signedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Int -> Proxy n -> Integer op u i _ = toInteger (Signed.rotateL# u i) "Clash.Sized.Internal.Signed.rotateR#" | Just (nTy,kn,i,j) <- signedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkSignedLit ty nTy kn val) where op :: KnownNat n => Signed n -> Int -> Proxy n -> Integer op u i _ = toInteger (Signed.rotateR# u i) -- Resize "Clash.Sized.Internal.Signed.resize#" -- forall m n. (KnownNat n, KnownNat m) => Signed n -> Signed m | mTy : nTy : _ <- tys , Right mInt <- runExcept (tyNatSize tcm mTy) , Right nInt <- runExcept (tyNatSize tcm nTy) , [i] <- signedLiterals' args -> let val | nInt <= mInt = extended | otherwise = truncated extended = i mask = 1 `shiftL` fromInteger (mInt - 1) i' = i `mod` mask truncated = if testBit i (fromInteger nInt - 1) then (i' - mask) else i' in reduce (mkSignedLit ty mTy mInt val) "Clash.Sized.Internal.Signed.truncateB#" -- KnownNat m => Signed (m + n) -> Signed m | Just (mTy, km) <- extractKnownNat tcm tys , [i] <- signedLiterals' args -> let bitsKeep = (bit (fromInteger km)) - 1 val = i .&. bitsKeep in reduce (mkSignedLit ty mTy km val) -- SaturatingNum -- No need to manually evaluate Clash.Sized.Internal.Signed.minBoundSym# -- It is just implemented in terms of other primitives. ----------- -- Unsigned ----------- "Clash.Sized.Internal.Unsigned.size#" | Just (_, kn) <- extractKnownNat tcm tys -> let (_,ty') = splitFunForallTy ty (TyConApp intTcNm _) = tyView ty' (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral kn))]) -- BitPack "Clash.Sized.Internal.Unsigned.pack#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- unsignedLiterals' args -> reduce (mkBitVectorLit ty nTy kn 0 i) "Clash.Sized.Internal.Unsigned.unpack#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- bitVectorLiterals' args -> let val = reifyNat kn (op (toBV i)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => BitVector n -> Proxy n -> Integer op u _ = toInteger (Unsigned.unpack# u) -- Eq "Clash.Sized.Internal.Unsigned.eq#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i == j)) "Clash.Sized.Internal.Unsigned.neq#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i /= j)) -- Ord "Clash.Sized.Internal.Unsigned.lt#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i < j)) "Clash.Sized.Internal.Unsigned.ge#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i >= j)) "Clash.Sized.Internal.Unsigned.gt#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i > j)) "Clash.Sized.Internal.Unsigned.le#" | Just (i,j) <- unsignedLiterals args -> reduce (boolToBoolLiteral tcm ty (i <= j)) -- Enum "Clash.Sized.Internal.Unsigned.toEnum#" | [i] <- intCLiterals' args , Just (litTy, mb) <- extractKnownNat tcm tys -> reduce (mkUnsignedLit ty litTy mb i) "Clash.Sized.Internal.Unsigned.fromEnum#" | [i] <- unsignedLiterals' args -> let resTy = getResultTy tcm ty tys in reduce (mkIntCLit tcm i resTy) -- Bounded "Clash.Sized.Internal.Unsigned.minBound#" | Just (nTy,len) <- extractKnownNat tcm tys -> reduce (mkUnsignedLit ty nTy len 0) "Clash.Sized.Internal.Unsigned.maxBound#" | Just (litTy,mb) <- extractKnownNat tcm tys -> let maxB = (2 ^ mb) - 1 in reduce (mkUnsignedLit ty litTy mb maxB) -- Num "Clash.Sized.Internal.Unsigned.+#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftUnsigned2 (Unsigned.+#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.Unsigned.-#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftUnsigned2 (Unsigned.-#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.Unsigned.*#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftUnsigned2 (Unsigned.*#) ty tcm tys args) -> reduce val "Clash.Sized.Internal.Unsigned.negate#" | Just (nTy, kn) <- extractKnownNat tcm tys , [i] <- unsignedLiterals' args -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Proxy n -> Integer op u _ = toInteger (Unsigned.negate# u) -- ExtendingNum "Clash.Sized.Internal.Unsigned.plus#" -- :: Unsigned m -> Unsigned n -> Unsigned (Max m n + 1) | Just (i,j) <- unsignedLiterals args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkUnsignedLit resTy resSizeTy resSizeInt (i+j)) "Clash.Sized.Internal.Unsigned.minus#" | [i,j] <- unsignedLiterals' args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) val = reifyNat resSizeInt (runSizedF (Unsigned.-#) i j) in reduce (mkUnsignedLit resTy resSizeTy resSizeInt val) "Clash.Sized.Internal.Unsigned.times#" | Just (i,j) <- unsignedLiterals args -> let ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' (TyConApp _ [resSizeTy]) = tyView resTy Right resSizeInt = runExcept (tyNatSize tcm resSizeTy) in reduce (mkUnsignedLit resTy resSizeTy resSizeInt (i*j)) -- Integral "Clash.Sized.Internal.Unsigned.quot#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftUnsigned2 (Unsigned.quot#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Unsigned.rem#" | Just (_, kn) <- extractKnownNat tcm tys , Just val <- reifyNat kn (liftUnsigned2 (Unsigned.rem#) ty tcm tys args) -> reduce $ catchDivByZero val "Clash.Sized.Internal.Unsigned.toInteger#" | [PrimVal p _ [_, Lit (IntegerLiteral i)]] <- args , primName p == "Clash.Sized.Internal.Unsigned.fromInteger#" -> reduce (integerToIntegerLiteral i) -- Bits "Clash.Sized.Internal.Unsigned.and#" | Just (i,j) <- unsignedLiterals args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkUnsignedLit ty nTy kn (i .&. j)) "Clash.Sized.Internal.Unsigned.or#" | Just (i,j) <- unsignedLiterals args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkUnsignedLit ty nTy kn (i .|. j)) "Clash.Sized.Internal.Unsigned.xor#" | Just (i,j) <- unsignedLiterals args , Just (nTy, kn) <- extractKnownNat tcm tys -> reduce (mkUnsignedLit ty nTy kn (i `xor` j)) "Clash.Sized.Internal.Unsigned.complement#" | [i] <- unsignedLiterals' args , Just (nTy, kn) <- extractKnownNat tcm tys -> let val = reifyNat kn (op (fromInteger i)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Proxy n -> Integer op u _ = toInteger (Unsigned.complement# u) "Clash.Sized.Internal.Unsigned.shiftL#" -- :: forall n. KnownNat n => Unsigned n -> Int -> Unsigned n | Just (nTy,kn,i,j) <- unsignedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Int -> Proxy n -> Integer op u i _ = toInteger (Unsigned.shiftL# u i) "Clash.Sized.Internal.Unsigned.shiftR#" -- :: forall n. KnownNat n => Unsigned n -> Int -> Unsigned n | Just (nTy,kn,i,j) <- unsignedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Int -> Proxy n -> Integer op u i _ = toInteger (Unsigned.shiftR# u i) "Clash.Sized.Internal.Unsigned.rotateL#" -- :: forall n. KnownNat n => Unsigned n -> Int -> Unsigned n | Just (nTy,kn,i,j) <- unsignedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Int -> Proxy n -> Integer op u i _ = toInteger (Unsigned.rotateL# u i) "Clash.Sized.Internal.Unsigned.rotateR#" -- :: forall n. KnownNat n => Unsigned n -> Int -> Unsigned n | Just (nTy,kn,i,j) <- unsignedLitIntLit tcm tys args -> let val = reifyNat kn (op (fromInteger i) (fromInteger j)) in reduce (mkUnsignedLit ty nTy kn val) where op :: KnownNat n => Unsigned n -> Int -> Proxy n -> Integer op u i _ = toInteger (Unsigned.rotateR# u i) -- Resize "Clash.Sized.Internal.Unsigned.resize#" -- forall n m . KnownNat m => Unsigned n -> Unsigned m | _ : mTy : _ <- tys , Right km <- runExcept (tyNatSize tcm mTy) , [i] <- unsignedLiterals' args -> let bitsKeep = (bit (fromInteger km)) - 1 val = i .&. bitsKeep in reduce (mkUnsignedLit ty mTy km val) -- Conversions "Clash.Sized.Internal.Unsigned.unsignedToWord" | isSubj , [a] <- unsignedLiterals' args -> let b = Unsigned.unsignedToWord (U (fromInteger a)) (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral (toInteger b)))]) "Clash.Sized.Internal.Unsigned.unsigned8toWord8" | isSubj , [a] <- unsignedLiterals' args -> let b = Unsigned.unsigned8toWord8 (U (fromInteger a)) (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral (toInteger b)))]) "Clash.Sized.Internal.Unsigned.unsigned16toWord16" | isSubj , [a] <- unsignedLiterals' args -> let b = Unsigned.unsigned16toWord16 (U (fromInteger a)) (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral (toInteger b)))]) "Clash.Sized.Internal.Unsigned.unsigned32toWord32" | isSubj , [a] <- unsignedLiterals' args -> let b = Unsigned.unsigned32toWord32 (U (fromInteger a)) (_,tyView -> TyConApp wordTcNm []) = splitFunForallTy ty (Just wordTc) = UniqMap.lookup wordTcNm tcm [wordDc] = tyConDataCons wordTc in reduce (mkApps (Data wordDc) [Left (Literal (WordLiteral (toInteger b)))]) "Clash.Annotations.BitRepresentation.Deriving.dontApplyInHDL" | isSubj , f : a : _ <- args -> reduceWHNF (mkApps (valToTerm f) [Left (valToTerm a)]) -------- -- RTree -------- "Clash.Sized.RTree.textract" | isSubj , [DC _ tArgs] <- args -> reduceWHNF (Either.lefts tArgs !! 1) "Clash.Sized.RTree.tsplit" | isSubj , dTy : aTy : _ <- tys , [DC _ tArgs] <- args , (tyArgs,tyView -> TyConApp tupTcNm _) <- splitFunForallTy ty , TyConApp treeTcNm _ <- tyView (Either.rights tyArgs !! 0) -> let (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc in reduce $ mkApps (Data tupDc) [Right (mkTyConApp treeTcNm [dTy,aTy]) ,Right (mkTyConApp treeTcNm [dTy,aTy]) ,Left (Either.lefts tArgs !! 1) ,Left (Either.lefts tArgs !! 2) ] "Clash.Sized.RTree.tdfold" | isSubj , pTy : kTy : aTy : _ <- tys , _ : p : f : g : ts : _ <- args , DC _ tArgs <- ts , Right k' <- runExcept (tyNatSize tcm kTy) -> case k' of 0 -> reduceWHNF (mkApps (valToTerm f) [Left (Either.lefts tArgs !! 1)]) _ -> let k'ty = LitTy (NumTy (k'-1)) (tyArgs,_) = splitFunForallTy ty (tyArgs',_) = splitFunForallTy (Either.rights tyArgs !! 3) TyConApp snatTcNm _ = tyView (Either.rights tyArgs' !! 0) Just snatTc = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc in reduceWHNF $ mkApps (valToTerm g) [Right k'ty ,Left (mkApps (Data snatDc) [Right k'ty ,Left (Literal (NaturalLiteral (k'-1)))]) ,Left (mkApps (Prim pInfo) [Right pTy ,Right k'ty ,Right aTy ,Left (Literal (NaturalLiteral (k'-1))) ,Left (valToTerm p) ,Left (valToTerm f) ,Left (valToTerm g) ,Left (Either.lefts tArgs !! 1) ]) ,Left (mkApps (Prim pInfo) [Right pTy ,Right k'ty ,Right aTy ,Left (Literal (NaturalLiteral (k'-1))) ,Left (valToTerm p) ,Left (valToTerm f) ,Left (valToTerm g) ,Left (Either.lefts tArgs !! 2) ]) ] "Clash.Sized.RTree.treplicate" | isSubj , let ty' = piResultTys tcm ty tys , (_,tyView -> TyConApp treeTcNm [lenTy,argTy]) <- splitFunForallTy ty' , Right len <- runExcept (tyNatSize tcm lenTy) -> let (Just treeTc) = UniqMap.lookup treeTcNm tcm [lrCon,brCon] = tyConDataCons treeTc in reduce (mkRTree lrCon brCon argTy len (replicate (2^len) (valToTerm (last args)))) --------- -- Vector --------- "Clash.Sized.Vector.length" -- :: KnownNat n => Vec n a -> Int | isSubj , [nTy, _] <- tys , Right n <-runExcept (tyNatSize tcm nTy) -> let (_, tyView -> TyConApp intTcNm _) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral (toInteger n)))]) "Clash.Sized.Vector.maxIndex" | isSubj , [nTy, _] <- tys , Right n <- runExcept (tyNatSize tcm nTy) -> let (_, tyView -> TyConApp intTcNm _) = splitFunForallTy ty (Just intTc) = UniqMap.lookup intTcNm tcm [intCon] = tyConDataCons intTc in reduce (mkApps (Data intCon) [Left (Literal (IntLiteral (toInteger (n - 1))))]) -- Indexing "Clash.Sized.Vector.index_int" -- :: KnownNat n => Vec n a -> Int | nTy : aTy : _ <- tys , _ : xs : i : _ <- args , DC intDc [Left (Literal (IntLiteral i'))] <- i -> if i' < 0 then Nothing else case xs of DC _ vArgs -> case runExcept (tyNatSize tcm nTy) of Right 0 -> Nothing Right n' -> if i' == 0 then reduceWHNF (Either.lefts vArgs !! 1) else reduceWHNF $ mkApps (Prim pInfo) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Left (Literal (NaturalLiteral (n'-1))) ,Left (Either.lefts vArgs !! 2) ,Left (mkApps (Data intDc) [Left (Literal (IntLiteral (i'-1)))]) ] _ -> Nothing _ -> Nothing "Clash.Sized.Vector.head" -- :: Vec (n+1) a -> a | isSubj , [DC _ vArgs] <- args -> reduceWHNF (Either.lefts vArgs !! 1) "Clash.Sized.Vector.last" -- :: Vec (n+1) a -> a | isSubj , [DC _ vArgs] <- args , (Right _ : Right aTy : Right nTy : _) <- vArgs , Right n <- runExcept (tyNatSize tcm nTy) -> if n == 0 then reduceWHNF (Either.lefts vArgs !! 1) else reduceWHNF (mkApps (Prim pInfo) [Right (LitTy (NumTy (n-1))) ,Right aTy ,Left (Either.lefts vArgs !! 2) ]) -- - Sub-vectors "Clash.Sized.Vector.tail" -- :: Vec (n+1) a -> Vec n a | isSubj , [DC _ vArgs] <- args -> reduceWHNF (Either.lefts vArgs !! 2) "Clash.Sized.Vector.init" -- :: Vec (n+1) a -> Vec n a | isSubj , [DC consCon vArgs] <- args , (Right _ : Right aTy : Right nTy : _) <- vArgs , Right n <- runExcept (tyNatSize tcm nTy) -> if n == 0 then reduceWHNF (Either.lefts vArgs !! 2) else reduce $ mkVecCons consCon aTy n (Either.lefts vArgs !! 1) (mkApps (Prim pInfo) [Right (LitTy (NumTy (n-1))) ,Right aTy ,Left (Either.lefts vArgs !! 2)]) "Clash.Sized.Vector.select" -- :: (CmpNat (i+s) (s*n) ~ GT) => SNat f -> SNat s -> SNat n -> Vec (f + i) a -> Vec n a | isSubj , iTy : sTy : nTy : fTy : aTy : _ <- tys , eq : f : s : n : xs : _ <- args , Right n' <- runExcept (tyNatSize tcm nTy) , Right f' <- runExcept (tyNatSize tcm fTy) , Right i' <- runExcept (tyNatSize tcm iTy) , Right s' <- runExcept (tyNatSize tcm sTy) , DC _ vArgs <- xs -> case n' of 0 -> reduce (mkVecNil nilCon aTy) _ -> case f' of 0 -> let splitAtCall = mkApps (splitAtPrim snatTcNm vecTcNm) [Right sTy ,Right (LitTy (NumTy (i'-s'))) ,Right aTy ,Left (valToTerm s) ,Left (valToTerm xs) ] fVecTy = mkTyConApp vecTcNm [sTy,aTy] iVecTy = mkTyConApp vecTcNm [LitTy (NumTy (i'-s')),aTy] -- Guaranteed no capture, so okay to use unsafe name generation fNm = mkUnsafeSystemName "fxs" 0 iNm = mkUnsafeSystemName "ixs" 1 fId = mkLocalId fVecTy fNm iId = mkLocalId iVecTy iNm tupPat = DataPat tupDc [] [fId,iId] iAlt = (tupPat, (Var iId)) in reduce $ mkVecCons consCon aTy n' (Either.lefts vArgs !! 1) $ mkApps (Prim pInfo) [Right (LitTy (NumTy (i'-s'))) ,Right sTy ,Right (LitTy (NumTy (n'-1))) ,Right (LitTy (NumTy 0)) ,Right aTy ,Left (valToTerm eq) ,Left (Literal (NaturalLiteral 0)) ,Left (valToTerm s) ,Left (Literal (NaturalLiteral (n'-1))) ,Left (Case splitAtCall iVecTy [iAlt]) ] _ -> let splitAtCall = mkApps (splitAtPrim snatTcNm vecTcNm) [Right fTy ,Right iTy ,Right aTy ,Left (valToTerm f) ,Left (valToTerm xs) ] fVecTy = mkTyConApp vecTcNm [fTy,aTy] iVecTy = mkTyConApp vecTcNm [iTy,aTy] -- Guaranteed no capture, so okay to use unsafe name generation fNm = mkUnsafeSystemName "fxs" 0 iNm = mkUnsafeSystemName "ixs" 1 fId = mkLocalId fVecTy fNm iId = mkLocalId iVecTy iNm tupPat = DataPat tupDc [] [fId,iId] iAlt = (tupPat, (Var iId)) in reduceWHNF $ mkApps (Prim pInfo) [Right iTy ,Right sTy ,Right nTy ,Right (LitTy (NumTy 0)) ,Right aTy ,Left (valToTerm eq) ,Left (Literal (NaturalLiteral 0)) ,Left (valToTerm s) ,Left (valToTerm n) ,Left (Case splitAtCall iVecTy [iAlt]) ] where (tyArgs,tyView -> TyConApp vecTcNm _) = splitFunForallTy ty Just vecTc = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc TyConApp snatTcNm _ = tyView (Either.rights tyArgs !! 1) tupTcNm = ghcTyconToTyConName (tupleTyCon Boxed 2) (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc -- - Splitting "Clash.Sized.Vector.splitAt" -- :: SNat m -> Vec (m + n) a -> (Vec m a, Vec n a) | isSubj , (DC snatDc (Right mTy:_)):_ <- args , Right m <- runExcept (tyNatSize tcm mTy) -> let _:nTy:aTy:_ = tys -- Get the tuple data-constructor ty1 = piResultTys tcm ty tys (_,tyView -> TyConApp tupTcNm tyArgs@(tyArg:_)) = splitFunForallTy ty1 (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc -- Get the vector data-constructors TyConApp vecTcNm _ = tyView tyArg Just vecTc = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc -- Recursive call to @splitAt@ splitAtRec v = mkApps (Prim pInfo) [Right (LitTy (NumTy (m-1))) ,Right nTy ,Right aTy ,Left (mkApps (Data snatDc) [ Right (LitTy (NumTy (m-1))) , Left (Literal (NaturalLiteral (m-1)))]) ,Left v ] -- Projection either the first or second field of the recursive -- call to @splitAt@ splitAtSelR v = Case (splitAtRec v) m1VecTy = mkTyConApp vecTcNm [LitTy (NumTy (m-1)),aTy] nVecTy = mkTyConApp vecTcNm [nTy,aTy] -- Guaranteed no capture, so okay to use unsafe name generation lNm = mkUnsafeSystemName "l" 0 rNm = mkUnsafeSystemName "r" 1 lId = mkLocalId m1VecTy lNm rId = mkLocalId nVecTy rNm tupPat = DataPat tupDc [] [lId,rId] lAlt = (tupPat, (Var lId)) rAlt = (tupPat, (Var rId)) in case m of -- (Nil,v) 0 -> reduce $ mkApps (Data tupDc) $ (map Right tyArgs) ++ [ Left (mkVecNil nilCon aTy) , Left (valToTerm (last args)) ] -- (x:xs) <- v m' | DC _ vArgs <- last args -- (x:fst (splitAt (m-1) xs),snd (splitAt (m-1) xs)) -> case Either.lefts vArgs of (_ : x : xs : _) -> reduce $ mkApps (Data tupDc) $ (map Right tyArgs) ++ [ Left (mkVecCons consCon aTy m' x (splitAtSelR xs m1VecTy [lAlt])) , Left (splitAtSelR xs nVecTy [rAlt]) ] _ -> -- v actually reduces to Nil and not Cons, this only happens -- when 'n' would reduce to a negative number; the complement -- of 'm'. -- -- See Clash issue: https://github.com/clash-lang/clash-compiler/issues/2831 let resTy = getResultTy tcm ty tys in reduce (TyApp (Prim NP.undefined) resTy) -- v doesn't reduce to a data-constructor _ -> Nothing "Clash.Sized.Vector.unconcat" -- :: KnownNat n => SNamt m -> Vec (n * m) a -> Vec n (Vec m a) | isSubj , kn : snat : v : _ <- args , nTy : mTy : aTy :_ <- tys , Lit (NaturalLiteral n) <- kn -> let ( Either.rights -> argTys, tyView -> TyConApp vecTcNm _) = splitFunForallTy ty Just vecTc = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc tupTcNm = ghcTyconToTyConName (tupleTyCon Boxed 2) (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc TyConApp snatTcNm _ = tyView (argTys !! 1) n1mTy = mkTyConApp typeNatMul [mkTyConApp typeNatSub [nTy,LitTy (NumTy 1)] ,mTy] splitAtCall = mkApps (splitAtPrim snatTcNm vecTcNm) [Right mTy ,Right n1mTy ,Right aTy ,Left (valToTerm snat) ,Left (valToTerm v) ] mVecTy = mkTyConApp vecTcNm [mTy,aTy] n1mVecTy = mkTyConApp vecTcNm [n1mTy,aTy] -- Guaranteed no capture, so okay to use unsafe name generation asNm = mkUnsafeSystemName "as" 0 bsNm = mkUnsafeSystemName "bs" 1 asId = mkLocalId mVecTy asNm bsId = mkLocalId n1mVecTy bsNm tupPat = DataPat tupDc [] [asId,bsId] asAlt = (tupPat, (Var asId)) bsAlt = (tupPat, (Var bsId)) in case n of 0 -> reduce (mkVecNil nilCon mVecTy) _ -> reduce $ mkVecCons consCon mVecTy n (Case splitAtCall mVecTy [asAlt]) (mkApps (Prim pInfo) [Right (LitTy (NumTy (n-1))) ,Right mTy ,Right aTy ,Left (Literal (NaturalLiteral (n-1))) ,Left (valToTerm snat) ,Left (Case splitAtCall n1mVecTy [bsAlt])]) -- Construction -- - initialisation "Clash.Sized.Vector.replicate" -- :: SNat n -> a -> Vec n a | isSubj , let ty' = piResultTys tcm ty tys , let (_,resTy) = splitFunForallTy ty' , (TyConApp vecTcNm [lenTy,argTy]) <- tyView resTy , Right len <- runExcept (tyNatSize tcm lenTy) -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc in reduce $ mkVec nilCon consCon argTy len (replicate (fromInteger len) (valToTerm (last args))) -- - Concatenation "Clash.Sized.Vector.++" -- :: Vec n a -> Vec m a -> Vec (n + m) a | isSubj , (DC dc vArgs):_ <- args , Right nTy : Right aTy : _ <- vArgs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (valToTerm (last args)) n' | (_ : _ : mTy : _) <- tys , Right m <- runExcept (tyNatSize tcm mTy) -> -- x : (xs ++ ys) reduce $ mkVecCons dc aTy (n' + m) (Either.lefts vArgs !! 1) (mkApps (Prim pInfo) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Right mTy ,Left (Either.lefts vArgs !! 2) ,Left (valToTerm (last args)) ]) _ -> Nothing "Clash.Sized.Vector.concat" -- :: Vec n (Vec m a) -> Vec (n * m) a | isSubj , (nTy : mTy : aTy : _) <- tys , (xs : _) <- args , DC dc vArgs <- xs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (mkVecNil dc aTy) _ | _ : h' : t : _ <- Either.lefts vArgs , (_,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty -> reduceWHNF $ mkApps (vecAppendPrim vecTcNm) [Right mTy ,Right aTy ,Right $ mkTyConApp typeNatMul [mkTyConApp typeNatSub [nTy,LitTy (NumTy 1)], mTy] ,Left h' ,Left $ mkApps (Prim pInfo) [ Right (LitTy (NumTy (n-1))) , Right mTy , Right aTy , Left t ] ] _ -> Nothing -- Modifying vectors "Clash.Sized.Vector.replace_int" -- :: KnownNat n => Vec n a -> Int -> a -> Vec n a | nTy : aTy : _ <- tys , _ : xs : i : a : _ <- args , DC intDc [Left (Literal (IntLiteral i'))] <- i -> if i' < 0 then Nothing else case xs of DC vecTcNm vArgs -> case runExcept (tyNatSize tcm nTy) of Right 0 -> Nothing Right n' -> if i' == 0 then reduce (mkVecCons vecTcNm aTy n' (valToTerm a) (Either.lefts vArgs !! 2)) else reduce $ mkVecCons vecTcNm aTy n' (Either.lefts vArgs !! 1) (mkApps (Prim pInfo) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Left (Literal (NaturalLiteral (n'-1))) ,Left (Either.lefts vArgs !! 2) ,Left (mkApps (Data intDc) [Left (Literal (IntLiteral (i'-1)))]) ,Left (valToTerm a) ]) _ -> Nothing _ -> Nothing -- - specialized permutations "Clash.Sized.Vector.reverse" -- :: Vec n a -> Vec n a | isSubj , nTy : aTy : _ <- tys , [DC vecDc vArgs] <- args -> case runExcept (tyNatSize tcm nTy) of Right 0 -> reduce (mkVecNil vecDc aTy) Right n | (_,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty , let (Just vecTc) = UniqMap.lookup vecTcNm tcm , let [nilCon,consCon] = tyConDataCons vecTc -> reduceWHNF $ mkApps (vecAppendPrim vecTcNm) [Right (LitTy (NumTy (n-1))) ,Right aTy ,Right (LitTy (NumTy 1)) ,Left (mkApps (Prim pInfo) [Right (LitTy (NumTy (n-1))) ,Right aTy ,Left (Either.lefts vArgs !! 2) ]) ,Left (mkVec nilCon consCon aTy 1 [Either.lefts vArgs !! 1]) ] _ -> Nothing "Clash.Sized.Vector.transpose" -- :: KnownNat n => Vec m (Vec n a) -> Vec n (Vec m a) | isSubj , nTy : mTy : aTy : _ <- tys , kn : xss : _ <- args , (_,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty , DC _ vArgs <- xss , Right n <- runExcept (tyNatSize tcm nTy) , Right m <- runExcept (tyNatSize tcm mTy) -> case m of 0 -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc in reduce $ mkVec nilCon consCon (mkTyConApp vecTcNm [mTy,aTy]) n (replicate (fromInteger n) (mkVec nilCon consCon aTy 0 [])) m' -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [_,consCon] = tyConDataCons vecTc Just (consCoTy : _) = dataConInstArgTys consCon [mTy,aTy,LitTy (NumTy (m'-1))] in reduceWHNF $ mkApps (vecZipWithPrim vecTcNm) [ Right aTy , Right (mkTyConApp vecTcNm [LitTy (NumTy (m'-1)),aTy]) , Right (mkTyConApp vecTcNm [mTy,aTy]) , Right nTy , Left (mkApps (Data consCon) [Right mTy ,Right aTy ,Right (LitTy (NumTy (m'-1))) ,Left (primCo consCoTy) ]) , Left (Either.lefts vArgs !! 1) , Left (mkApps (Prim pInfo) [ Right nTy , Right (LitTy (NumTy (m'-1))) , Right aTy , Left (valToTerm kn) , Left (Either.lefts vArgs !! 2) ]) ] "Clash.Sized.Vector.rotateLeftS" -- :: KnownNat n => Vec n a -> SNat d -> Vec n a | nTy : aTy : _ : _ <- tys , kn : xs : d : _ <- args , DC dc vArgs <- xs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (mkVecNil dc aTy) n' | DC snatDc [_,Left d'] <- d , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach2@Machine{mStack=[],mTerm=Literal (NaturalLiteral d2)} <- whnf eval tcm isSubj (setTerm d' $ stackClear mach) -> case (d2 `mod` n) of 0 -> reduce (valToTerm xs) d3 -> let (_,tyView -> TyConApp vecTcNm _) = splitFunForallTy ty (Just vecTc) = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc in reduceWHNF' mach2 $ mkApps (Prim pInfo) [Right nTy ,Right aTy ,Right (LitTy (NumTy (d3-1))) ,Left (valToTerm kn) ,Left (mkApps (vecAppendPrim vecTcNm) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Right (LitTy (NumTy 1)) ,Left (Either.lefts vArgs !! 2) ,Left (mkVec nilCon consCon aTy 1 [Either.lefts vArgs !! 1])]) ,Left (mkApps (Data snatDc) [Right (LitTy (NumTy (d3-1))) ,Left (Literal (NaturalLiteral (d3-1)))]) ] _ -> Nothing "Clash.Sized.Vector.rotateRightS" -- :: KnownNat n => Vec n a -> SNat d -> Vec n a | isSubj , nTy : aTy : _ : _ <- tys , kn : xs : d : _ <- args , DC dc _ <- xs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (mkVecNil dc aTy) n' | DC snatDc [_,Left d'] <- d , eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach2@Machine{mStack=[],mTerm=Literal (NaturalLiteral d2)} <- whnf eval tcm isSubj (setTerm d' $ stackClear mach) -> case (d2 `mod` n) of 0 -> reduce (valToTerm xs) d3 -> let (_,tyView -> TyConApp vecTcNm _) = splitFunForallTy ty in reduceWHNF' mach2 $ mkApps (Prim pInfo) [Right nTy ,Right aTy ,Right (LitTy (NumTy (d3-1))) ,Left (valToTerm kn) ,Left (mkVecCons dc aTy n (mkApps (vecLastPrim vecTcNm) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Left (valToTerm xs)]) (mkApps (vecInitPrim vecTcNm) [Right (LitTy (NumTy (n'-1))) ,Right aTy ,Left (valToTerm xs)])) ,Left (mkApps (Data snatDc) [Right (LitTy (NumTy (d3-1))) ,Left (Literal (NaturalLiteral (d3-1)))]) ] _ -> Nothing -- Element-wise operations -- - mapping "Clash.Sized.Vector.map" -- :: (a -> b) -> Vec n a -> Vec n b | isSubj , DC dc vArgs <- args !! 1 , aTy : bTy : nTy : _ <- tys , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (mkVecNil dc bTy) n' -> reduce $ mkVecCons dc bTy n' (mkApps (valToTerm (args !! 0)) [Left (Either.lefts vArgs !! 1)]) (mkApps (Prim pInfo) [Right aTy ,Right bTy ,Right (LitTy (NumTy (n' - 1))) ,Left (valToTerm (args !! 0)) ,Left (Either.lefts vArgs !! 2)]) "Clash.Sized.Vector.imap" -- :: forall n a b . KnownNat n => (Index n -> a -> b) -> Vec n a -> Vec n b | isSubj , nTy : aTy : bTy : _ <- tys , (tyArgs,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty , let (tyArgs',_) = splitFunForallTy (Either.rights tyArgs !! 1) , TyConApp indexTcNm _ <- tyView (Either.rights tyArgs' !! 0) , Right n <- runExcept (tyNatSize tcm nTy) , let iLit = mkIndexLit (Either.rights tyArgs' !! 0) nTy n 0 -> reduceWHNF $ mkApps (Prim (PrimInfo "Clash.Sized.Vector.imap_go" (vecImapGoTy vecTcNm indexTcNm) WorkNever SingleResult NoUnfolding)) [Right nTy ,Right nTy ,Right aTy ,Right bTy ,Left (valToTerm (args !! 1)) ,Left (valToTerm (args !! 2)) ,Left iLit ] "Clash.Sized.Vector.imap_go" | isSubj , nTy : mTy : aTy : bTy : _ <- tys , f : xs : (Suspend nArg) : _ <- args , DC dc vArgs <- xs , Right n' <- runExcept (tyNatSize tcm nTy) , Right m <- runExcept (tyNatSize tcm mTy) -> case m of 0 -> reduce (mkVecNil dc bTy) m' | eval <- Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind , mach1@Machine{mStack=[],mTerm=n} <- whnf eval tcm True (setTerm nArg (stackClear mach)) -> let (tyArgs,_) = splitFunForallTy ty TyConApp indexTcNm _ = tyView (Either.rights tyArgs !! 2) iLit = mkIndexLit (Either.rights tyArgs !! 2) nTy n' 1 in Just $ flip setTerm (mach1 {mStack = mStack mach}) $ mkVecCons dc bTy m' (mkApps (valToTerm f) [Left n,Left (Either.lefts vArgs !! 1)]) (mkApps (Prim pInfo) [Right nTy ,Right (LitTy (NumTy (m'-1))) ,Right aTy ,Right bTy ,Left (valToTerm f) ,Left (Either.lefts vArgs !! 2) ,Left (mkApps (Prim (PrimInfo "Clash.Sized.Internal.Index.+#" (indexAddTy indexTcNm) WorkVariable SingleResult NoUnfolding)) [Right nTy ,Left (Literal (NaturalLiteral n')) ,Left n ,Left iLit ]) ]) | otherwise -> Nothing -- :: forall n a. KnownNat n => (a -> a) -> a -> Vec n a "Clash.Sized.Vector.iterateI" | isSubj , [nTy, aTy] <- tys , [_n, f, a] <- args , Right n <- runExcept (tyNatSize tcm nTy) -> let TyConApp vecTcNm _ = tyView (getResultTy tcm ty tys) Just vecTc = UniqMap.lookup vecTcNm tcm [nilCon, consCon] = tyConDataCons vecTc in case n of 0 -> reduce (mkVecNil nilCon aTy) _ -> reduce $ mkVecCons consCon aTy n (valToTerm a) (mkApps (Prim pInfo) [ Right (LitTy (NumTy (n - 1))) , Right aTy , Left (valToTerm (Lit (NaturalLiteral (n - 1)))) , Left (valToTerm f) , Left (mkApps (valToTerm f) [Left (valToTerm a)]) ]) -- - Zipping "Clash.Sized.Vector.zipWith" -- :: (a -> b -> c) -> Vec n a -> Vec n b -> Vec n c | isSubj , aTy : bTy : cTy : nTy : _ <- tys , f : xs : ys : _ <- args , DC dc vArgs <- xs , (_,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (mkVecNil dc cTy) n' -> reduce $ mkVecCons dc cTy n' (mkApps (valToTerm f) [Left (Either.lefts vArgs !! 1) ,Left (mkApps (vecHeadPrim vecTcNm) [Right (LitTy (NumTy (n'-1))) ,Right bTy ,Left (valToTerm ys) ]) ]) (mkApps (Prim pInfo) [Right aTy ,Right bTy ,Right cTy ,Right (LitTy (NumTy (n' - 1))) ,Left (valToTerm f) ,Left (Either.lefts vArgs !! 2) ,Left (mkApps (vecTailPrim vecTcNm) [Right (LitTy (NumTy (n'-1))) ,Right bTy ,Left (valToTerm ys) ])]) -- Folding "Clash.Sized.Vector.foldr" -- :: (a -> b -> b) -> b -> Vec n a -> b | isSubj , aTy : bTy : nTy : _ <- tys , f : z : xs : _ <- args , DC _ vArgs <- xs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduce (valToTerm z) _ -> reduceWHNF $ mkApps (valToTerm f) [Left (Either.lefts vArgs !! 1) ,Left (mkApps (Prim pInfo) [Right aTy ,Right bTy ,Right (LitTy (NumTy (n-1))) ,Left (valToTerm f) ,Left (valToTerm z) ,Left (Either.lefts vArgs !! 2) ]) ] "Clash.Sized.Vector.fold" -- :: (a -> a -> a) -> Vec (n + 1) a -> a | isSubj , nTy : aTy : _ <- tys , f : vs : _ <- args , DC _ vArgs <- vs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> reduceWHNF (Either.lefts vArgs !! 1) _ -> let (tyArgs,_) = splitFunForallTy ty TyConApp vecTcNm _ = tyView (Either.rights tyArgs !! 1) tupTcNm = ghcTyconToTyConName (tupleTyCon Boxed 2) (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc n' = n+1 m = n' `div` 2 n1 = n' - m mTy = LitTy (NumTy m) m'ty = LitTy (NumTy (m-1)) n1mTy = LitTy (NumTy n1) n1m'ty = LitTy (NumTy (n1-1)) splitAtCall = mkApps (Prim (PrimInfo "Clash.Sized.Vector.fold_split" (foldSplitAtTy vecTcNm) WorkNever SingleResult NoUnfolding)) [Right mTy ,Right n1mTy ,Right aTy ,Left (Literal (NaturalLiteral m)) ,Left (valToTerm vs) ] mVecTy = mkTyConApp vecTcNm [mTy,aTy] n1mVecTy = mkTyConApp vecTcNm [n1mTy,aTy] -- Guaranteed no capture, so okay to use unsafe name generation asNm = mkUnsafeSystemName "as" 0 bsNm = mkUnsafeSystemName "bs" 1 asId = mkLocalId mVecTy asNm bsId = mkLocalId n1mVecTy bsNm tupPat = DataPat tupDc [] [asId,bsId] asAlt = (tupPat, (Var asId)) bsAlt = (tupPat, (Var bsId)) in reduceWHNF $ mkApps (valToTerm f) [Left (mkApps (Prim pInfo) [Right m'ty ,Right aTy ,Left (valToTerm f) ,Left (Case splitAtCall mVecTy [asAlt]) ]) ,Left (mkApps (Prim pInfo) [Right n1m'ty ,Right aTy ,Left (valToTerm f) ,Left (Case splitAtCall n1mVecTy [bsAlt]) ]) ] "Clash.Sized.Vector.fold_split" -- :: Natural -> Vec (m + n) a -> (Vec m a, Vec n a) | isSubj , mTy : nTy : aTy : _ <- tys , Right m <- runExcept (tyNatSize tcm mTy) -> let -- Get the tuple data-constructor ty1 = piResultTys tcm ty tys (_,tyView -> TyConApp tupTcNm tyArgs@(tyArg:_)) = splitFunForallTy ty1 (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc -- Get the vector data-constructors TyConApp vecTcNm _ = tyView tyArg Just vecTc = UniqMap.lookup vecTcNm tcm [nilCon,consCon] = tyConDataCons vecTc -- Recursive call to @splitAt@ splitAtRec v = mkApps (Prim pInfo) [Right (LitTy (NumTy (m-1))) ,Right nTy ,Right aTy ,Left (Literal (NaturalLiteral (m-1))) ,Left v ] -- Projection either the first or second field of the recursive -- call to @splitAt@ splitAtSelR v = Case (splitAtRec v) m1VecTy = mkTyConApp vecTcNm [LitTy (NumTy (m-1)),aTy] nVecTy = mkTyConApp vecTcNm [nTy,aTy] -- Guaranteed no capture, so okay to use unsafe name generation lNm = mkUnsafeSystemName "l" 0 rNm = mkUnsafeSystemName "r" 1 lId = mkLocalId m1VecTy lNm rId = mkLocalId nVecTy rNm tupPat = DataPat tupDc [] [lId,rId] lAlt = (tupPat, (Var lId)) rAlt = (tupPat, (Var rId)) in case m of -- (Nil,v) 0 -> reduce $ mkApps (Data tupDc) $ (map Right tyArgs) ++ [ Left (mkVecNil nilCon aTy) , Left (valToTerm (last args)) ] -- (x:xs) <- v m' | DC _ vArgs <- last args -- (x:fst (splitAt (m-1) xs),snd (splitAt (m-1) xs)) -> reduce $ mkApps (Data tupDc) $ (map Right tyArgs) ++ [ Left (mkVecCons consCon aTy m' (Either.lefts vArgs !! 1) (splitAtSelR (Either.lefts vArgs !! 2) m1VecTy [lAlt])) , Left (splitAtSelR (Either.lefts vArgs !! 2) nVecTy [rAlt]) ] -- v doesn't reduce to a data-constructor _ -> Nothing -- - Specialised folds "Clash.Sized.Vector.dfold" | isSubj , pTy : kTy : aTy : _ <- tys , _ : p : f : z : xs : _ <- args , DC _ vArgs <- xs , Right k' <- runExcept (tyNatSize tcm kTy) -> case k' of 0 -> reduce (valToTerm z) _ -> let (tyArgs,_) = splitFunForallTy ty (tyArgs',_) = splitFunForallTy (Either.rights tyArgs !! 2) TyConApp snatTcNm _ = tyView (Either.rights tyArgs' !! 0) Just snatTc = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc k'ty = LitTy (NumTy (k'-1)) in reduceWHNF $ mkApps (valToTerm f) [Right k'ty ,Left (mkApps (Data snatDc) [Right k'ty ,Left (Literal (NaturalLiteral (k'-1)))]) ,Left (Either.lefts vArgs !! 1) ,Left (mkApps (Prim pInfo) [Right pTy ,Right k'ty ,Right aTy ,Left (Literal (NaturalLiteral (k'-1))) ,Left (valToTerm p) ,Left (valToTerm f) ,Left (valToTerm z) ,Left (Either.lefts vArgs !! 2) ]) ] "Clash.Sized.Vector.dtfold" | isSubj , pTy : kTy : aTy : _ <- tys , _ : p : f : g : xs : _ <- args , DC _ vArgs <- xs , Right k' <- runExcept (tyNatSize tcm kTy) -> case k' of 0 -> reduceWHNF (mkApps (valToTerm f) [Left (Either.lefts vArgs !! 1)]) _ -> let (tyArgs,_) = splitFunForallTy ty TyConApp vecTcNm _ = tyView (Either.rights tyArgs !! 4) (tyArgs',_) = splitFunForallTy (Either.rights tyArgs !! 3) TyConApp snatTcNm _ = tyView (Either.rights tyArgs' !! 0) Just snatTc = UniqMap.lookup snatTcNm tcm [snatDc] = tyConDataCons snatTc tupTcNm = ghcTyconToTyConName (tupleTyCon Boxed 2) (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc k'ty = LitTy (NumTy (k'-1)) k2ty = LitTy (NumTy (2^(k'-1))) splitAtCall = mkApps (splitAtPrim snatTcNm vecTcNm) [Right k2ty ,Right k2ty ,Right aTy ,Left (mkApps (Data snatDc) [Right k2ty ,Left (Literal (NaturalLiteral (2^(k'-1))))]) ,Left (valToTerm xs) ] xsSVecTy = mkTyConApp vecTcNm [k2ty,aTy] -- Guaranteed no capture, so okay to use unsafe name generation xsLNm = mkUnsafeSystemName "xsL" 0 xsRNm = mkUnsafeSystemName "xsR" 1 xsLId = mkLocalId k2ty xsLNm xsRId = mkLocalId k2ty xsRNm tupPat = DataPat tupDc [] [xsLId,xsRId] asAlt = (tupPat, (Var xsLId)) bsAlt = (tupPat, (Var xsRId)) in reduceWHNF $ mkApps (valToTerm g) [Right k'ty ,Left (mkApps (Data snatDc) [Right k'ty ,Left (Literal (NaturalLiteral (k'-1)))]) ,Left (mkApps (Prim pInfo) [Right pTy ,Right k'ty ,Right aTy ,Left (Literal (NaturalLiteral (k'-1))) ,Left (valToTerm p) ,Left (valToTerm f) ,Left (valToTerm g) ,Left (Case splitAtCall xsSVecTy [asAlt])]) ,Left (mkApps (Prim pInfo) [Right pTy ,Right k'ty ,Right aTy ,Left (Literal (NaturalLiteral (k'-1))) ,Left (valToTerm p) ,Left (valToTerm f) ,Left (valToTerm g) ,Left (Case splitAtCall xsSVecTy [bsAlt])]) ] -- Misc "Clash.Sized.Vector.lazyV" | isSubj , nTy : aTy : _ <- tys , _ : xs : _ <- args , (_,tyView -> TyConApp vecTcNm _) <- splitFunForallTy ty , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [nilCon,_] = tyConDataCons vecTc in reduce (mkVecNil nilCon aTy) n' -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [_,consCon] = tyConDataCons vecTc in reduce $ mkVecCons consCon aTy n' (mkApps (vecHeadPrim vecTcNm) [ Right (LitTy (NumTy (n' - 1))) , Right aTy , Left (valToTerm xs) ]) (mkApps (Prim pInfo) [ Right (LitTy (NumTy (n' - 1))) , Right aTy , Left (Literal (NaturalLiteral (n'-1))) , Left (mkApps (vecTailPrim vecTcNm) [ Right (LitTy (NumTy (n'-1))) , Right aTy , Left (valToTerm xs) ]) ]) -- Traversable "Clash.Sized.Vector.traverse#" | isSubj , aTy : fTy : bTy : nTy : _ <- tys , apDict : f : xs : _ <- args , DC dc vArgs <- xs , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> let (pureF,ids') = runPEM (mkSelectorCase $(curLoc) is0 tcm (valToTerm apDict) 1 1) ids in reduceWHNF' (mach { mSupply = ids' }) $ mkApps pureF [Right (mkTyConApp (vecTcNm) [nTy,bTy]) ,Left (mkVecNil dc bTy)] _ -> let ((fmapF,apF),ids') = flip runPEM ids $ do fDict <- mkSelectorCase $(curLoc) is0 tcm (valToTerm apDict) 1 0 fmapF' <- mkSelectorCase $(curLoc) is0 tcm fDict 1 0 apF' <- mkSelectorCase $(curLoc) is0 tcm (valToTerm apDict) 1 2 return (fmapF',apF') n'ty = LitTy (NumTy (n-1)) Just (consCoTy : _) = dataConInstArgTys dc [nTy,bTy,n'ty] in reduceWHNF' (mach { mSupply = ids' }) $ mkApps apF [Right (mkTyConApp vecTcNm [n'ty,bTy]) ,Right (mkTyConApp vecTcNm [nTy,bTy]) ,Left (mkApps fmapF [Right bTy ,Right (mkFunTy (mkTyConApp vecTcNm [n'ty,bTy]) (mkTyConApp vecTcNm [nTy,bTy])) ,Left (mkApps (Data dc) [Right nTy ,Right bTy ,Right n'ty ,Left (primCo consCoTy)]) ,Left (mkApps (valToTerm f) [Left (Either.lefts vArgs !! 1)]) ]) ,Left (mkApps (Prim pInfo) [Right aTy ,Right fTy ,Right bTy ,Right n'ty ,Left (valToTerm apDict) ,Left (valToTerm f) ,Left (Either.lefts vArgs !! 2) ]) ] where (tyArgs,_) = splitFunForallTy ty TyConApp vecTcNm _ = tyView (Either.rights tyArgs !! 2) (ids, is0) = (mSupply mach, mScopeNames mach) -- BitPack "Clash.Sized.Vector.concatBitVector#" | isSubj , nTy : mTy : _ <- tys , _ : km : v : _ <- args , DC _ vArgs <- v , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> let resTyInfo = extractTySizeInfo tcm ty tys in reduce (mkBitVectorLit' resTyInfo 0 0) n' | Right m <- runExcept (tyNatSize tcm mTy) , (_,tyView -> TyConApp bvTcNm _) <- splitFunForallTy ty -> reduceWHNF $ mkApps (bvAppendPrim bvTcNm) [ Right (mkTyConApp typeNatMul [LitTy (NumTy (n'-1)),mTy]) , Right mTy , Left (Literal (NaturalLiteral ((n'-1)*m))) , Left (Either.lefts vArgs !! 1) , Left (mkApps (Prim pInfo) [ Right (LitTy (NumTy (n'-1))) , Right mTy , Left (Literal (NaturalLiteral (n'-1))) , Left (valToTerm km) , Left (Either.lefts vArgs !! 2) ]) ] _ -> Nothing "Clash.Sized.Vector.unconcatBitVector#" | isSubj , nTy : mTy : _ <- tys , _ : km : bv : _ <- args , (_,tyView -> TyConApp vecTcNm [_,bvMTy]) <- splitFunForallTy ty , TyConApp bvTcNm _ <- tyView bvMTy , Right n <- runExcept (tyNatSize tcm nTy) -> case n of 0 -> let (Just vecTc) = UniqMap.lookup vecTcNm tcm [nilCon,_] = tyConDataCons vecTc in reduce (mkVecNil nilCon (mkTyConApp bvTcNm [mTy])) n' | Right m <- runExcept (tyNatSize tcm mTy) -> let Just vecTc = UniqMap.lookup vecTcNm tcm [_,consCon] = tyConDataCons vecTc tupTcNm = ghcTyconToTyConName (tupleTyCon Boxed 2) Just tupTc = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc splitCall = mkApps (bvSplitPrim bvTcNm) [ Right (mkTyConApp typeNatMul [LitTy (NumTy (n'-1)),mTy]) , Right mTy , Left (Literal (NaturalLiteral ((n'-1)*m))) , Left (valToTerm bv) ] mBVTy = mkTyConApp bvTcNm [mTy] n1BVTy = mkTyConApp bvTcNm [mkTyConApp typeNatMul [LitTy (NumTy (n'-1)) ,mTy]] -- Guaranteed no capture, so okay to use unsafe name generation xNm = mkUnsafeSystemName "x" 0 bvNm = mkUnsafeSystemName "bv'" 1 xId = mkLocalId mBVTy xNm bvId = mkLocalId n1BVTy bvNm tupPat = DataPat tupDc [] [xId,bvId] xAlt = (tupPat, (Var xId)) bvAlt = (tupPat, (Var bvId)) in reduce $ mkVecCons consCon (mkTyConApp bvTcNm [mTy]) n' (Case splitCall mBVTy [xAlt]) (mkApps (Prim pInfo) [ Right (LitTy (NumTy (n'-1))) , Right mTy , Left (Literal (NaturalLiteral (n'-1))) , Left (valToTerm km) , Left (Case splitCall n1BVTy [bvAlt]) ]) _ -> Nothing #if MIN_VERSION_ghc(9,4,0) "Data.Text.Show.$wunpackCStringAscii#" | [Lit (StringLiteral addr)] <- args , Text.Text (Text.ByteArray ba) _off len <- Text.pack addr -> let (_,tyView -> TyConApp tupTcNm tyArgs) = splitFunForallTy ty (Just tupTc) = UniqMap.lookup tupTcNm tcm [tupDc] = tyConDataCons tupTc ret = mkApps (Data tupDc) (map Right tyArgs ++ [ Left (Literal (ByteArrayLiteral (BA.ByteArray ba))) , Left (Literal (IntLiteral 0)) , Left (Literal (IntLiteral (toInteger len)))]) in reduce ret "GHC.Magic.noinlineConstraint" | [arg] <- args -> reduce (valToTerm arg) "GHC.TypeNats.withSomeSNat" | Lit (NaturalLiteral n) : fun : _ <- args , _ : funTy : _ <- Either.rights (fst (splitFunForallTy ty)) , (tyView -> TyConApp snatTcNm _) : _ <- Either.rights (fst (splitFunForallTy funTy)) , Just snatTc <- UniqMap.lookup snatTcNm tcm , [snatDc] <- tyConDataCons snatTc -> let nTy = LitTy (NumTy n) snat = mkApps (Data snatDc) [Right nTy, Left (Literal (NaturalLiteral n))] ret = mkApps (valToTerm fun) [Right nTy, Left snat] in reduce ret "GHC.Internal.TypeNats.withSomeSNat" | Lit (NaturalLiteral n) : fun : _ <- args , _ : funTy : _ <- Either.rights (fst (splitFunForallTy ty)) , (tyView -> TyConApp snatTcNm _) : _ <- Either.rights (fst (splitFunForallTy funTy)) , Just snatTc <- UniqMap.lookup snatTcNm tcm , [snatDc] <- tyConDataCons snatTc -> let nTy = LitTy (NumTy n) snat = mkApps (Data snatDc) [Right nTy, Left (Literal (NaturalLiteral n))] ret = mkApps (valToTerm fun) [Right nTy, Left snat] in reduce ret "GHC.Magic.nospec" | [arg] <- args -> reduce (valToTerm arg) "GHC.Float.$wproperFractionDouble" | _ : Lit (DoubleLiteral d) : _ <- args , [sty@(tyView -> TyConApp signedTcNm [nTy@(LitTy (NumTy kn))])] <- tys , nameOcc signedTcNm == showt ''Signed , (_, tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , Just tupTc <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let (sn, d1) = reifyNat kn (\p -> first toInteger (op p (wordToDouble d))) ret = mkApps (Data tupDc) (map Right tyArgs ++ [ Left (mkSignedLit sty nTy kn sn) , Left (mkDoubleCLit tcm (doubleToWord d1) (last tyArgs)) ]) in reduce ret where op :: KnownNat n => Proxy n -> Double -> (Signed n, Double) op _ = properFraction "GHC.Internal.Float.$wproperFractionDouble" | _ : Lit (DoubleLiteral d) : _ <- args , [sty@(tyView -> TyConApp signedTcNm [nTy@(LitTy (NumTy kn))])] <- tys , nameOcc signedTcNm == "Clash.Sized.Internal.Signed.Signed" , (_, tyView -> TyConApp tupTcNm tyArgs) <- splitFunForallTy ty , Just tupTc <- UniqMap.lookup tupTcNm tcm , [tupDc] <- tyConDataCons tupTc -> let (sn, d1) = reifyNat kn (\p -> first toInteger (op p (wordToDouble d))) ret = mkApps (Data tupDc) (map Right tyArgs ++ [ Left (mkSignedLit sty nTy kn sn) , Left (mkDoubleCLit tcm (doubleToWord d1) (last tyArgs)) ]) in reduce ret where op :: KnownNat n => Proxy n -> Double -> (Signed n, Double) op _ = properFraction #endif _ -> Nothing where ty = primType pInfo checkNaturalRange1 nTy i f = checkNaturalRange nTy [i] (\[i'] -> naturalToNaturalLiteral (f i')) checkNaturalRange2 nTy i j f = checkNaturalRange nTy [i, j] (\[i', j'] -> naturalToNaturalLiteral (f i' j')) -- Check given integer's range. If any of them are less than zero, give up -- and return an undefined type. checkNaturalRange :: Type -- Type of GHC.Natural.Natural ^ -> [Integer] -> ([Natural] -> Term) -> Term checkNaturalRange nTy natsAsInts f = if any (<0) natsAsInts then TyApp (Prim NP.undefined) nTy else f (map fromInteger natsAsInts) reduce :: Term -> Maybe Machine reduce e = case isX e of Left msg -> trace (unlines ["Warning: Not evaluating constant expression:", show (primName pInfo), "Because doing so generates an XException:", msg]) Nothing Right e' -> Just (setTerm e' mach) reduceWHNF e = let eval = Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind mach1@Machine{mStack=[]} = whnf eval tcm isSubj (setTerm e $ stackClear mach) in Just $ mach1 { mStack = mStack mach } reduceWHNF' mach1 e = let eval = Evaluator ghcStep ghcUnwind ghcPrimStep ghcPrimUnwind mach2@Machine{mStack=[]} = whnf eval tcm isSubj (setTerm e mach1) in Just $ mach2 { mStack = mStack mach } makeUndefinedIf :: Exception e => (e -> Bool) -> Term -> Term makeUndefinedIf wantToHandle tm = case unsafeDupablePerformIO $ tryJust selectException (evaluate $ force tm) of Right b -> b Left e -> trace (msg e) (TyApp (Prim NP.undefined) resTy) where resTy = getResultTy tcm ty tys selectException e | wantToHandle e = Just e | otherwise = Nothing msg e = unlines ["Warning: caught exception: \"" ++ show e ++ "\" while trying to evaluate: " , showPpr (mkApps (Prim pInfo) (map (Left . valToTerm) args)) ] catchDivByZero = makeUndefinedIf (==DivideByZero) -- Helper functions for literals pairOf :: (Value -> Maybe a) -> [Value] -> Maybe (a, a) pairOf f [x, y] = (,) <$> f x <*> f y pairOf _ _ = Nothing listOf :: (Value -> Maybe a) -> [Value] -> [a] listOf = mapMaybe wrapUnsigned :: Integer -> Integer -> Integer wrapUnsigned n i = i `mod` sz where sz = 1 `shiftL` fromInteger n wrapSigned :: Integer -> Integer -> Integer wrapSigned n i = if n == 0 then 0 else res where mask = 1 `shiftL` fromInteger (n - 1) res = case divMod i mask of (s,i1) | even s -> i1 | otherwise -> i1 - mask doubleLiterals' :: [Value] -> [Word64] doubleLiterals' = listOf doubleLiteral doubleLiteral :: Value -> Maybe Word64 doubleLiteral v = case v of Lit (DoubleLiteral i) -> Just i _ -> Nothing floatLiterals' :: [Value] -> [Word32] floatLiterals' = listOf floatLiteral floatLiteral :: Value -> Maybe Word32 floatLiteral v = case v of Lit (FloatLiteral i) -> Just i _ -> Nothing integerLiterals :: [Value] -> Maybe (Integer, Integer) integerLiterals = pairOf integerLiteral integerLiteral :: Value -> Maybe Integer integerLiteral v = case v of Lit (IntegerLiteral i) -> Just i DC dc [Left (Literal (IntLiteral i))] | dcTag dc == 1 -> Just i DC dc [Left (Literal (ByteArrayLiteral (BA.ByteArray ba)))] | dcTag dc == 2 #if MIN_VERSION_base(4,15,0) -> Just (IP ba) #else -> Just (Jp# (BN# ba)) #endif | dcTag dc == 3 #if MIN_VERSION_base(4,15,0) -> Just (IN ba) #else -> Just (Jn# (BN# ba)) #endif _ -> Nothing naturalLiterals :: [Value] -> Maybe (Integer, Integer) naturalLiterals = pairOf naturalLiteral naturalLiteral :: Value -> Maybe Integer naturalLiteral v = case v of Lit (NaturalLiteral i) -> Just i DC dc [Left (Literal (WordLiteral i))] | dcTag dc == 1 -> Just i DC dc [Left (Literal (ByteArrayLiteral (BA.ByteArray ba)))] | dcTag dc == 2 #if MIN_VERSION_base(4,15,0) -> Just (IP ba) #else -> Just (Jp# (BN# ba)) #endif _ -> Nothing integerLiterals' :: [Value] -> [Integer] integerLiterals' = listOf integerLiteral naturalLiterals' :: [Value] -> [Integer] naturalLiterals' = listOf naturalLiteral intLiterals :: [Value] -> Maybe (Integer,Integer) intLiterals = pairOf intLiteral intLiterals' :: [Value] -> [Integer] intLiterals' = listOf intLiteral intCLiterals' :: [Value] -> [Integer] intCLiterals' = listOf intCLiteral intLiteral :: Value -> Maybe Integer intLiteral x = case x of Lit (IntLiteral i) -> Just i _ -> Nothing #if MIN_VERSION_base(4,16,0) int8Literals' :: [Value] -> [Integer] int8Literals' = listOf int8Literal int8Literal :: Value -> Maybe Integer int8Literal x = case x of Lit (Int8Literal i) -> Just i _ -> Nothing int16Literals' :: [Value] -> [Integer] int16Literals' = listOf int16Literal int16Literal :: Value -> Maybe Integer int16Literal x = case x of Lit (Int16Literal i) -> Just i _ -> Nothing int32Literals' :: [Value] -> [Integer] int32Literals' = listOf int32Literal int32Literal :: Value -> Maybe Integer int32Literal x = case x of Lit (Int32Literal i) -> Just i _ -> Nothing #if MIN_VERSION_base(4,17,0) int64Literals' :: [Value] -> [Integer] int64Literals' = listOf int64Literal int64Literal :: Value -> Maybe Integer int64Literal x = case x of Lit (Int64Literal i) -> Just i _ -> Nothing #endif #endif intCLiteral :: Value -> Maybe Integer intCLiteral v = case v of (DC _ [Left (Literal (IntLiteral i))]) -> Just i _ -> Nothing intCLiterals :: [Value] -> Maybe (Integer, Integer) intCLiterals = pairOf intCLiteral wordLiterals :: [Value] -> Maybe (Integer,Integer) wordLiterals = pairOf wordLiteral wordLiterals' :: [Value] -> [Integer] wordLiterals' = listOf wordLiteral wordLiteral :: Value -> Maybe Integer wordLiteral x = case x of Lit (WordLiteral i) -> Just i _ -> Nothing #if MIN_VERSION_base(4,16,0) word8Literals' :: [Value] -> [Integer] word8Literals' = listOf word8Literal word8Literal :: Value -> Maybe Integer word8Literal x = case x of Lit (Word8Literal i) -> Just i _ -> Nothing word16Literals' :: [Value] -> [Integer] word16Literals' = listOf word16Literal word16Literal :: Value -> Maybe Integer word16Literal x = case x of Lit (Word16Literal i) -> Just i _ -> Nothing word32Literals' :: [Value] -> [Integer] word32Literals' = listOf word32Literal word32Literal :: Value -> Maybe Integer word32Literal x = case x of Lit (Word32Literal i) -> Just i _ -> Nothing #endif word64Literals' :: [Value] -> [Integer] word64Literals' = listOf word64Literal #if MIN_VERSION_base(4,17,0) word64Literal :: Value -> Maybe Integer word64Literal x = case x of Lit (Word64Literal i) -> Just i _ -> Nothing #else -- Prior to GHC 9.4 Word64# didn't exist, 64 bit primitives took Word# instead word64Literal :: Value -> Maybe Integer word64Literal= wordLiteral #endif charLiterals :: [Value] -> Maybe (Char,Char) charLiterals = pairOf charLiteral charLiterals' :: [Value] -> [Char] charLiterals' = listOf charLiteral charLiteral :: Value -> Maybe Char charLiteral x = case x of Lit (CharLiteral c) -> Just c _ -> Nothing sizedLiterals :: Text -> [Value] -> Maybe (Integer,Integer) sizedLiterals szCon = pairOf (sizedLiteral szCon) sizedLiterals' :: Text -> [Value] -> [Integer] sizedLiterals' szCon = listOf (sizedLiteral szCon) sizedLiteral :: Text -> Value -> Maybe Integer sizedLiteral szCon val = case val of PrimVal p _ [_, Lit (IntegerLiteral i)] | primName p == szCon -> Just i _ -> Nothing bitLiterals :: [Value] -> [(Integer,Integer)] bitLiterals = map normalizeBit . mapMaybe go where normalizeBit (msk,v) = (msk .&. 1, v .&. 1) go val = case val of PrimVal p _ [Lit (WordLiteral m), Lit (IntegerLiteral i)] | primName p == "Clash.Sized.Internal.BitVector.fromInteger##" -> Just (m,i) _ -> Nothing indexLiterals, signedLiterals, unsignedLiterals :: [Value] -> Maybe (Integer,Integer) indexLiterals = sizedLiterals "Clash.Sized.Internal.Index.fromInteger#" signedLiterals = sizedLiterals "Clash.Sized.Internal.Signed.fromInteger#" unsignedLiterals = sizedLiterals "Clash.Sized.Internal.Unsigned.fromInteger#" indexLiterals', signedLiterals', unsignedLiterals' :: [Value] -> [Integer] indexLiterals' = sizedLiterals' "Clash.Sized.Internal.Index.fromInteger#" signedLiterals' = sizedLiterals' "Clash.Sized.Internal.Signed.fromInteger#" unsignedLiterals' = sizedLiterals' "Clash.Sized.Internal.Unsigned.fromInteger#" bitVectorLiterals' :: [Value] -> [(Integer,Integer)] bitVectorLiterals' = listOf bitVectorLiteral bitVectorLiteral :: Value -> Maybe (Integer, Integer) bitVectorLiteral val = case val of (PrimVal p _ [_, Lit (NaturalLiteral m), Lit (IntegerLiteral i)]) | primName p == "Clash.Sized.Internal.BitVector.fromInteger#" -> Just (m, i) _ -> Nothing toBV :: (Integer,Integer) -> BitVector n toBV (mask,val) = BV (fromInteger mask) (fromInteger val) splitBV :: BitVector n -> (Integer,Integer) splitBV (BV msk val) = (toInteger msk, toInteger val) toBit :: (Integer,Integer) -> Bit toBit (mask,val) = Bit (fromInteger mask) (fromInteger val) valArgs :: Value -> Maybe [Term] valArgs v = case v of PrimVal _ _ vs -> Just (fmap valToTerm vs) DC _ args -> Just (Either.lefts args) _ -> Nothing -- Tries to match literal arguments to a function like -- (Unsigned.shiftL# :: forall n. KnownNat n => Unsigned n -> Int -> Unsigned n) sizedLitIntLit :: Text -> TyConMap -> [Type] -> [Value] -> Maybe (Type,Integer,Integer,Integer) sizedLitIntLit szCon tcm tys args | Just (nTy,kn) <- extractKnownNat tcm tys , [_ ,PrimVal p _ [_,Lit (IntegerLiteral i)] ,valArgs -> Just [Literal (IntLiteral j)] ] <- args , primName p == szCon = Just (nTy,kn,i,j) | otherwise = Nothing signedLitIntLit, unsignedLitIntLit :: TyConMap -> [Type] -> [Value] -> Maybe (Type,Integer,Integer,Integer) signedLitIntLit = sizedLitIntLit "Clash.Sized.Internal.Signed.fromInteger#" unsignedLitIntLit = sizedLitIntLit "Clash.Sized.Internal.Unsigned.fromInteger#" bitVectorLitIntLit :: TyConMap -> [Type] -> [Value] -> Maybe (Type,Integer,(Integer,Integer),Integer) bitVectorLitIntLit tcm tys args | Just (nTy,kn) <- extractKnownNat tcm tys , [_ ,PrimVal p _ [_,Lit (NaturalLiteral m),Lit (IntegerLiteral i)] ,valArgs -> Just [Literal (IntLiteral j)] ] <- args , primName p == "Clash.Sized.Internal.BitVector.fromInteger#" = Just (nTy,kn,(m,i),j) | otherwise = Nothing mkIntCLit :: TyConMap -> Integer -> Type -> Term mkIntCLit tcm lit resTy = App (Data intDc) (Literal (IntLiteral lit)) where (_, tyView -> TyConApp intTcNm []) = splitFunForallTy resTy Just intTc = UniqMap.lookup intTcNm tcm [intDc] = tyConDataCons intTc mkFloatCLit :: TyConMap -> Word32 -> Type -> Term mkFloatCLit tcm lit resTy = App (Data floatDc) (Literal (FloatLiteral lit)) where (_, tyView -> TyConApp floatTcNm []) = splitFunForallTy resTy (Just floatTc) = UniqMap.lookup floatTcNm tcm [floatDc] = tyConDataCons floatTc mkDoubleCLit :: TyConMap -> Word64 -> Type -> Term mkDoubleCLit tcm lit resTy = App (Data doubleDc) (Literal (DoubleLiteral lit)) where (_, tyView -> TyConApp doubleTcNm []) = splitFunForallTy resTy (Just doubleTc) = UniqMap.lookup doubleTcNm tcm [doubleDc] = tyConDataCons doubleTc mkSomeNat :: TyConMap -> Integer -> Type -> Term mkSomeNat tcm lit resTy = mkApps (Data someNatDc) [ Right (LitTy (NumTy lit)) , Left (Literal (NaturalLiteral lit)) , Left proxy ] where -- Get the SomeNat data constructor TyConApp someNatTcNm [] = tyView resTy (Just someNatTc) = UniqMap.lookup someNatTcNm tcm [someNatDc] = tyConDataCons someNatTc -- Get the Proxy data constructor (_:_:Right (tyView -> TyConApp proxyTcNm [natTy,_]):_,_) = splitFunForallTy (dcType someNatDc) (Just proxyTc) = UniqMap.lookup proxyTcNm tcm [proxyDc] = tyConDataCons proxyTc -- Build the Proxy argument proxy = mkApps (Data proxyDc) [ Right natTy , Right (LitTy (NumTy lit)) ] -- From an argument list to function of type -- forall n. KnownNat n => ... -- extract (nTy,nInt) -- where nTy is the Type of n -- and nInt is its value as an Integer extractKnownNat :: TyConMap -> [Type] -> Maybe (Type, Integer) extractKnownNat tcm tys = case tys of nTy : _ | Right nInt <- runExcept (tyNatSize tcm nTy) -> Just (nTy, nInt) _ -> Nothing -- From an argument list to function of type -- forall n m o .. . (KnownNat n, KnownNat m, KnownNat o, ..) => ... -- extract [(nTy,nInt), (mTy,mInt), (oTy,oInt)] -- where nTy is the Type of n -- and nInt is its value as an Integer extractKnownNats :: TyConMap -> [Type] -> [(Type, Integer)] extractKnownNats tcm = mapMaybe (extractKnownNat tcm . pure) -- Construct a constant term of a sized type mkSizedLit :: (Type -> Term) -- ^ Type constructor? -> Type -- ^ Result type -> Type -- ^ forall n. -> Integer -- ^ KnownNat n -> Integer -- ^ Value to construct -> Term mkSizedLit conPrim ty nTy kn val = mkApps (conPrim sTy) [ Right nTy , Left (Literal (NaturalLiteral kn)) , Left (Literal (IntegerLiteral val)) ] where (_,sTy) = splitFunForallTy ty mkBitLit :: Type -- ^ Result type -> Integer -- ^ Mask -> Integer -- ^ Value -> Term mkBitLit ty msk val = mkApps (bConPrim sTy) [ Left (Literal (WordLiteral (msk .&. 1))) , Left (Literal (IntegerLiteral (val .&. 1)))] where (_,sTy) = splitFunForallTy ty mkSignedLit, mkUnsignedLit :: Type -- Result type -> Type -- forall n. -> Integer -- KnownNat n -> Integer -- Value -> Term mkSignedLit = mkSizedLit signedConPrim mkUnsignedLit = mkSizedLit unsignedConPrim mkBitVectorLit :: Type -- ^ Result type -> Type -- ^ forall n. -> Integer -- ^ KnownNat n -> Integer -- ^ mask -> Integer -- ^ Value to construct -> Term mkBitVectorLit ty nTy kn mask val = mkApps (bvConPrim sTy) [Right nTy ,Left (Literal (NaturalLiteral kn)) ,Left (Literal (NaturalLiteral mask)) ,Left (Literal (IntegerLiteral val))] where (_,sTy) = splitFunForallTy ty mkIndexLitE :: Type -- ^ Result type -> Type -- ^ forall n. -> Integer -- ^ KnownNat n -> Integer -- ^ Value to construct -> Either Term Term -- ^ Either undefined (if given value is out of bounds of given type) or term -- representing literal mkIndexLitE rTy nTy kn val | val >= 0 , val < kn = Right (mkSizedLit indexConPrim rTy nTy kn val) | otherwise = Left (TyApp (Prim NP.undefined) (mkTyConApp indexTcNm [nTy])) where TyConApp indexTcNm _ = tyView (snd (splitFunForallTy rTy)) mkIndexLit :: Type -- ^ Result type -> Type -- ^ forall n. -> Integer -- ^ KnownNat n -> Integer -- ^ Value to construct -> Term mkIndexLit rTy nTy kn val = either id id (mkIndexLitE rTy nTy kn val) mkBitVectorLit' :: (Type, Type, Integer) -- ^ (result type, forall n., KnownNat n) -> Integer -- ^ Mask -> Integer -- ^ Value -> Term mkBitVectorLit' (ty,nTy,kn) = mkBitVectorLit ty nTy kn mkIndexLit' :: (Type, Type, Integer) -- ^ (result type, forall n., KnownNat n) -> Integer -- ^ value -> Term mkIndexLit' (rTy,nTy,kn) = mkIndexLit rTy nTy kn boolToIntLiteral :: Bool -> Term boolToIntLiteral b = if b then Literal (IntLiteral 1) else Literal (IntLiteral 0) boolToBoolLiteral :: TyConMap -> Type -> Bool -> Term boolToBoolLiteral tcm ty b = let (_,tyView -> TyConApp boolTcNm []) = splitFunForallTy ty (Just boolTc) = UniqMap.lookup boolTcNm tcm [falseDc,trueDc] = tyConDataCons boolTc retDc = if b then trueDc else falseDc in Data retDc charToCharLiteral :: Char -> Term charToCharLiteral = Literal . CharLiteral integerToIntLiteral :: Integer -> Term integerToIntLiteral = Literal . IntLiteral . toInteger . (fromInteger :: Integer -> Int) -- for overflow behavior integerToWordLiteral :: Integer -> Term integerToWordLiteral = Literal . WordLiteral . toInteger . (fromInteger :: Integer -> Word) -- for overflow behavior integerToInt64Literal :: Integer -> Term integerToInt64Literal = Literal . Int64Literal . toInteger . (fromInteger :: Integer -> Int64) -- for overflow behavior integerToWord64Literal :: Integer -> Term integerToWord64Literal = Literal . Word64Literal . toInteger . (fromInteger :: Integer -> Word64) -- for overflow behavior integerToIntegerLiteral :: Integer -> Term integerToIntegerLiteral = Literal . IntegerLiteral naturalToNaturalLiteral :: Natural -> Term naturalToNaturalLiteral = Literal . NaturalLiteral . toInteger bConPrim :: Type -> Term bConPrim (tyView -> TyConApp bTcNm _) = Prim (PrimInfo "Clash.Sized.Internal.BitVector.fromInteger##" funTy WorkNever SingleResult NoUnfolding) where funTy = foldr1 mkFunTy [wordPrimTy,integerPrimTy,mkTyConApp bTcNm []] bConPrim _ = error $ $(curLoc) ++ "called with incorrect type" bvConPrim :: Type -> Term bvConPrim (tyView -> TyConApp bvTcNm _) = Prim (PrimInfo "Clash.Sized.Internal.BitVector.fromInteger#" (ForAllTy nTV funTy) WorkNever SingleResult NoUnfolding) where funTy = foldr1 mkFunTy [naturalPrimTy,naturalPrimTy,integerPrimTy,mkTyConApp bvTcNm [nVar]] nName = mkUnsafeSystemName "n" 0 nVar = VarTy nTV nTV = mkTyVar typeNatKind nName bvConPrim _ = error $ $(curLoc) ++ "called with incorrect type" indexConPrim :: Type -> Term indexConPrim (tyView -> TyConApp indexTcNm _) = Prim (PrimInfo "Clash.Sized.Internal.Index.fromInteger#" (ForAllTy nTV funTy) WorkNever SingleResult NoUnfolding) where funTy = foldr1 mkFunTy [naturalPrimTy,integerPrimTy,mkTyConApp indexTcNm [nVar]] nName = mkUnsafeSystemName "n" 0 nVar = VarTy nTV nTV = mkTyVar typeNatKind nName indexConPrim _ = error $ $(curLoc) ++ "called with incorrect type" signedConPrim :: Type -> Term signedConPrim (tyView -> TyConApp signedTcNm _) = Prim (PrimInfo "Clash.Sized.Internal.Signed.fromInteger#" (ForAllTy nTV funTy) WorkNever SingleResult NoUnfolding) where funTy = foldr1 mkFunTy [naturalPrimTy,integerPrimTy,mkTyConApp signedTcNm [nVar]] nName = mkUnsafeSystemName "n" 0 nVar = VarTy nTV nTV = mkTyVar typeNatKind nName signedConPrim _ = error $ $(curLoc) ++ "called with incorrect type" unsignedConPrim :: Type -> Term unsignedConPrim (tyView -> TyConApp unsignedTcNm _) = Prim (PrimInfo "Clash.Sized.Internal.Unsigned.fromInteger#" (ForAllTy nTV funTy) WorkNever SingleResult NoUnfolding) where funTy = foldr1 mkFunTy [naturalPrimTy,integerPrimTy,mkTyConApp unsignedTcNm [nVar]] nName = mkUnsafeSystemName "n" 0 nVar = VarTy nTV nTV = mkTyVar typeNatKind nName unsignedConPrim _ = error $ $(curLoc) ++ "called with incorrect type" -- | Lift a binary function over 'Unsigned' values to be used as literal Evaluator -- -- liftUnsigned2 :: KnownNat n => (Unsigned n -> Unsigned n -> Unsigned n) -> Type -> TyConMap -> [Type] -> [Value] -> (Proxy n -> Maybe Term) liftUnsigned2 = liftSized2 unsignedLiterals' mkUnsignedLit liftSigned2 :: KnownNat n => (Signed n -> Signed n -> Signed n) -> Type -> TyConMap -> [Type] -> [Value] -> (Proxy n -> Maybe Term) liftSigned2 = liftSized2 signedLiterals' mkSignedLit liftBitVector2 :: KnownNat n => (BitVector n -> BitVector n -> BitVector n) -> Type -> TyConMap -> [Type] -> [Value] -> (Proxy n -> Maybe Term) liftBitVector2 f ty tcm tys args _p | Just (nTy, kn) <- extractKnownNat tcm tys , [i,j] <- bitVectorLiterals' args = let BV mask val = f (toBV i) (toBV j) in Just $ mkBitVectorLit ty nTy kn (toInteger mask) (toInteger val) | otherwise = Nothing liftBitVector2Bool :: KnownNat n => (BitVector n -> BitVector n -> Bool) -> Type -> TyConMap -> [Value] -> (Proxy n -> Maybe Term) liftBitVector2Bool f ty tcm args _p | [i,j] <- bitVectorLiterals' args = let val = f (toBV i) (toBV j) in Just $ boolToBoolLiteral tcm ty val | otherwise = Nothing liftInteger2BitVector :: KnownNat n => (Integer -> BitVector n) -> (Type, Type, Integer) -> [Value] -> (Proxy n -> Maybe Term) liftInteger2BitVector f resTyInfo args _p | [i] <- intCLiterals' args = let BV msk val = f i in Just (mkBitVectorLit' resTyInfo (toInteger msk) (toInteger val)) | otherwise = Nothing liftBitVector2CInt :: KnownNat n => TyConMap -> Type -> (BitVector n -> Integer) -> [Value] -> (Proxy n -> Maybe Term) liftBitVector2CInt tcm resTy f args _p | [i] <- bitVectorLiterals' args = let val = f (toBV i) in Just $ mkIntCLit tcm val resTy | otherwise = Nothing liftSized2 :: (KnownNat n, Integral (sized n)) => ([Value] -> [Integer]) -- ^ literal argument extraction function -> (Type -> Type -> Integer -> Integer -> Term) -- ^ literal contruction function -> (sized n -> sized n -> sized n) -> Type -> TyConMap -> [Type] -> [Value] -> (Proxy n -> Maybe Term) liftSized2 extractLitArgs mkLit f ty tcm tys args p | Just (nTy, kn) <- extractKnownNat tcm tys , [i,j] <- extractLitArgs args = let val = runSizedF f i j p in Just $ mkLit ty nTy kn val | otherwise = Nothing -- | Helper to run a function over sized types on integers -- -- This only works on function of type (sized n -> sized n -> sized n) -- The resulting function must be executed with reifyNat runSizedF :: (KnownNat n, Integral (sized n)) => (sized n -> sized n -> sized n) -- ^ function to run -> Integer -- ^ first argument -> Integer -- ^ second argument -> (Proxy n -> Integer) runSizedF f i j _ = toInteger $ f (fromInteger i) (fromInteger j) extractTySizeInfo :: TyConMap -> Type -> [Type] -> (Type, Type, Integer) extractTySizeInfo tcm ty tys = (resTy,resSizeTy,resSize) where ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' TyConApp _ [resSizeTy] = tyView resTy Right resSize = runExcept (tyNatSize tcm resSizeTy) getResultTy :: TyConMap -> Type -> [Type] -> Type getResultTy tcm ty tys = resTy where ty' = piResultTys tcm ty tys (_,resTy) = splitFunForallTy ty' liftDDI :: (Double# -> Double# -> Int#) -> [Value] -> Maybe Term liftDDI f args = case doubleLiterals' args of [i,j] -> Just $ runDDI f i j _ -> Nothing liftDDD :: (Double# -> Double# -> Double#) -> [Value] -> Maybe Term liftDDD f args = case doubleLiterals' args of [i,j] -> Just $ runDDD f i j _ -> Nothing liftDD :: (Double# -> Double#) -> [Value] -> Maybe Term liftDD f args = case doubleLiterals' args of [i] -> Just $ runDD f i _ -> Nothing runDDI :: (Double# -> Double# -> Int#) -> Word64 -> Word64 -> Term runDDI f i j = let !(D# a) = wordToDouble i !(D# b) = wordToDouble j r = f a b in Literal . IntLiteral . toInteger $ I# r runDDD :: (Double# -> Double# -> Double#) -> Word64 -> Word64 -> Term runDDD f i j = let !(D# a) = wordToDouble i !(D# b) = wordToDouble j r = f a b in Literal . DoubleLiteral . doubleToWord $ D# r runDD :: (Double# -> Double#) -> Word64 -> Term runDD f i = let !(D# a) = wordToDouble i r = f a in Literal . DoubleLiteral . doubleToWord $ D# r liftFFI :: (Float# -> Float# -> Int#) -> [Value] -> Maybe Term liftFFI f args = case floatLiterals' args of [i,j] -> Just $ runFFI f i j _ -> Nothing liftFFF :: (Float# -> Float# -> Float#) -> [Value] -> Maybe Term liftFFF f args = case floatLiterals' args of [i,j] -> Just $ runFFF f i j _ -> Nothing liftFF :: (Float# -> Float#) -> [Value] -> Maybe Term liftFF f args = case floatLiterals' args of [i] -> Just $ runFF f i _ -> Nothing runFFI :: (Float# -> Float# -> Int#) -> Word32 -> Word32 -> Term runFFI f i j = let !(F# a) = wordToFloat i !(F# b) = wordToFloat j r = f a b in Literal . IntLiteral . toInteger $ I# r runFFF :: (Float# -> Float# -> Float#) -> Word32 -> Word32 -> Term runFFF f i j = let !(F# a) = wordToFloat i !(F# b) = wordToFloat j r = f a b in Literal . FloatLiteral . floatToWord $ F# r runFF :: (Float# -> Float#) -> Word32 -> Term runFF f i = let !(F# a) = wordToFloat i r = f a in Literal . FloatLiteral . floatToWord $ F# r #if MIN_VERSION_base(4,16,0) liftI8 :: (Int8# -> Int8# -> Int8#) -> [Value] -> Maybe Term liftI8 f args = case int8Literals' args of [i,j] -> let !(I8# a) = fromInteger i !(I8# b) = fromInteger j in Just (Literal (Int8Literal (toInteger (I8# (f a b))))) _ -> Nothing liftI8I :: (Int8# -> Int# -> Int8#) -> [Value] -> Maybe Term liftI8I f args = case args of [Lit (Int8Literal i),Lit (IntLiteral j)] -> let !(I8# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Int8Literal (toInteger (I8# (f a b))))) _ -> Nothing liftI8RI :: (Int8# -> Int8# -> Int#) -> [Value] -> Maybe Term liftI8RI f args = case int8Literals' args of [i,j] -> let !(I8# a) = fromInteger i !(I8# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing liftI16 :: (Int16# -> Int16# -> Int16#) -> [Value] -> Maybe Term liftI16 f args = case int16Literals' args of [i,j] -> let !(I16# a) = fromInteger i !(I16# b) = fromInteger j in Just (Literal (Int16Literal (toInteger (I16# (f a b))))) _ -> Nothing liftI16I :: (Int16# -> Int# -> Int16#) -> [Value] -> Maybe Term liftI16I f args = case args of [Lit (Int16Literal i),Lit (IntLiteral j)] -> let !(I16# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Int16Literal (toInteger (I16# (f a b))))) _ -> Nothing liftI16RI :: (Int16# -> Int16# -> Int#) -> [Value] -> Maybe Term liftI16RI f args = case int16Literals' args of [i,j] -> let !(I16# a) = fromInteger i !(I16# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing liftI32 :: (Int32# -> Int32# -> Int32#) -> [Value] -> Maybe Term liftI32 f args = case int32Literals' args of [i,j] -> let !(I32# a) = fromInteger i !(I32# b) = fromInteger j in Just (Literal (Int32Literal (toInteger (I32# (f a b))))) _ -> Nothing liftI32I :: (Int32# -> Int# -> Int32#) -> [Value] -> Maybe Term liftI32I f args = case args of [Lit (Int32Literal i),Lit (IntLiteral j)] -> let !(I32# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Int32Literal (toInteger (I32# (f a b))))) _ -> Nothing liftI32RI :: (Int32# -> Int32# -> Int#) -> [Value] -> Maybe Term liftI32RI f args = case int32Literals' args of [i,j] -> let !(I32# a) = fromInteger i !(I32# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing #if MIN_VERSION_base(4,17,0) liftI64 :: (Int64# -> Int64# -> Int64#) -> [Value] -> Maybe Term liftI64 f args = case int64Literals' args of [i,j] -> let !(I64# a) = fromInteger i !(I64# b) = fromInteger j in Just (Literal (Int64Literal (toInteger (I64# (f a b))))) _ -> Nothing liftI64I :: (Int64# -> Int# -> Int64#) -> [Value] -> Maybe Term liftI64I f args = case args of [Lit (Int64Literal i),Lit (IntLiteral j)] -> let !(I64# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Int64Literal (toInteger (I64# (f a b))))) _ -> Nothing liftI64RI :: (Int64# -> Int64# -> Int#) -> [Value] -> Maybe Term liftI64RI f args = case int64Literals' args of [i,j] -> let !(I64# a) = fromInteger i !(I64# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing #endif liftW8 :: (Word8# -> Word8# -> Word8#) -> [Value] -> Maybe Term liftW8 f args = case word8Literals' args of [i,j] -> let !(W8# a) = fromInteger i !(W8# b) = fromInteger j in Just (Literal (Word8Literal (toInteger (W8# (f a b))))) _ -> Nothing liftW8I :: (Word8# -> Int# -> Word8#) -> [Value] -> Maybe Term liftW8I f args = case args of [Lit (Word8Literal i),Lit (IntLiteral j)] -> let !(W8# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Word8Literal (toInteger (W8# (f a b))))) _ -> Nothing liftW8RI :: (Word8# -> Word8# -> Int#) -> [Value] -> Maybe Term liftW8RI f args = case word8Literals' args of [i,j] -> let !(W8# a) = fromInteger i !(W8# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing liftW16 :: (Word16# -> Word16# -> Word16#) -> [Value] -> Maybe Term liftW16 f args = case word16Literals' args of [i,j] -> let !(W16# a) = fromInteger i !(W16# b) = fromInteger j in Just (Literal (Word16Literal (toInteger (W16# (f a b))))) _ -> Nothing liftW16I :: (Word16# -> Int# -> Word16#) -> [Value] -> Maybe Term liftW16I f args = case args of [Lit (Word16Literal i),Lit (IntLiteral j)] -> let !(W16# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Word16Literal (toInteger (W16# (f a b))))) _ -> Nothing liftW16RI :: (Word16# -> Word16# -> Int#) -> [Value] -> Maybe Term liftW16RI f args = case word16Literals' args of [i,j] -> let !(W16# a) = fromInteger i !(W16# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing liftW32 :: (Word32# -> Word32# -> Word32#) -> [Value] -> Maybe Term liftW32 f args = case word32Literals' args of [i,j] -> let !(W32# a) = fromInteger i !(W32# b) = fromInteger j in Just (Literal (Word32Literal (toInteger (W32# (f a b))))) _ -> Nothing liftW32I :: (Word32# -> Int# -> Word32#) -> [Value] -> Maybe Term liftW32I f args = case args of [Lit (Word32Literal i),Lit (IntLiteral j)] -> let !(W32# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Word32Literal (toInteger (W32# (f a b))))) _ -> Nothing liftW32RI :: (Word32# -> Word32# -> Int#) -> [Value] -> Maybe Term liftW32RI f args = case word32Literals' args of [i,j] -> let !(W32# a) = fromInteger i !(W32# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing #if MIN_VERSION_base(4,17,0) liftW64 :: (Word64# -> Word64# -> Word64#) -> [Value] -> Maybe Term liftW64 f args = case word64Literals' args of [i,j] -> let !(W64# a) = fromInteger i !(W64# b) = fromInteger j in Just (Literal (Word64Literal (toInteger (W64# (f a b))))) _ -> Nothing liftW64I :: (Word64# -> Int# -> Word64#) -> [Value] -> Maybe Term liftW64I f args = case args of [Lit (Word64Literal i),Lit (IntLiteral j)] -> let !(W64# a) = fromInteger i !(I# b) = fromInteger j in Just (Literal (Word64Literal (toInteger (W64# (f a b))))) _ -> Nothing liftW64RI :: (Word64# -> Word64# -> Int#) -> [Value] -> Maybe Term liftW64RI f args = case word64Literals' args of [i,j] -> let !(W64# a) = fromInteger i !(W64# b) = fromInteger j in Just (Literal (IntLiteral (toInteger (I# (f a b))))) _ -> Nothing #endif #endif splitAtPrim :: TyConName -- ^ SNat TyCon name -> TyConName -- ^ Vec TyCon name -> Term splitAtPrim snatTcNm vecTcNm = Prim (PrimInfo "Clash.Sized.Vector.splitAt" (splitAtTy snatTcNm vecTcNm) WorkNever SingleResult NoUnfolding) splitAtTy :: TyConName -- ^ SNat TyCon name -> TyConName -- ^ Vec TyCon name -> Type splitAtTy snatNm vecNm = ForAllTy mTV ( ForAllTy nTV ( ForAllTy aTV ( mkFunTy (mkTyConApp snatNm [VarTy mTV]) (mkFunTy (mkTyConApp vecNm [mkTyConApp typeNatAdd [VarTy mTV ,VarTy nTV] ,VarTy aTV]) (mkTyConApp tupNm [mkTyConApp vecNm [VarTy mTV ,VarTy aTV] ,mkTyConApp vecNm [VarTy nTV ,VarTy aTV]]))))) where mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 0) nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 1) aTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "a" 2) tupNm = ghcTyconToTyConName (tupleTyCon Boxed 2) foldSplitAtTy :: TyConName -- ^ Vec TyCon name -> Type foldSplitAtTy vecNm = ForAllTy mTV ( ForAllTy nTV ( ForAllTy aTV ( mkFunTy naturalPrimTy (mkFunTy (mkTyConApp vecNm [mkTyConApp typeNatAdd [VarTy mTV ,VarTy nTV] ,VarTy aTV]) (mkTyConApp tupNm [mkTyConApp vecNm [VarTy mTV ,VarTy aTV] ,mkTyConApp vecNm [VarTy nTV ,VarTy aTV]]))))) where mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 0) nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 1) aTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "a" 2) tupNm = ghcTyconToTyConName (tupleTyCon Boxed 2) vecAppendPrim :: TyConName -- ^ Vec TyCon name -> Term vecAppendPrim vecNm = Prim (PrimInfo "Clash.Sized.Vector.++" (vecAppendTy vecNm) WorkNever SingleResult NoUnfolding) vecAppendTy :: TyConName -- ^ Vec TyCon name -> Type vecAppendTy vecNm = ForAllTy nTV ( ForAllTy aTV ( ForAllTy mTV ( mkFunTy (mkTyConApp vecNm [VarTy nTV ,VarTy aTV ]) (mkFunTy (mkTyConApp vecNm [VarTy mTV ,VarTy aTV ]) (mkTyConApp vecNm [mkTyConApp typeNatAdd [VarTy nTV ,VarTy mTV] ,VarTy aTV ]))))) where nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 0) aTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "a" 1) mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 2) vecZipWithPrim :: TyConName -- ^ Vec TyCon name -> Term vecZipWithPrim vecNm = Prim (PrimInfo "Clash.Sized.Vector.zipWith" (vecZipWithTy vecNm) WorkNever SingleResult NoUnfolding) vecZipWithTy :: TyConName -- ^ Vec TyCon name -> Type vecZipWithTy vecNm = ForAllTy aTV ( ForAllTy bTV ( ForAllTy cTV ( ForAllTy nTV ( mkFunTy (mkFunTy aTy (mkFunTy bTy cTy)) (mkFunTy (mkTyConApp vecNm [nTy,aTy]) (mkFunTy (mkTyConApp vecNm [nTy,bTy]) (mkTyConApp vecNm [nTy,cTy]))))))) where aTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "a" 0) bTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "b" 1) cTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "c" 2) nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 3) aTy = VarTy aTV bTy = VarTy bTV cTy = VarTy cTV nTy = VarTy nTV vecImapGoTy :: TyConName -- ^ Vec TyCon name -> TyConName -- ^ Index TyCon name -> Type vecImapGoTy vecTcNm indexTcNm = ForAllTy nTV ( ForAllTy mTV ( ForAllTy aTV ( ForAllTy bTV ( mkFunTy fTy (mkFunTy vecATy (mkFunTy indexTy vecBTy)))))) where nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 0) mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 1) aTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "a" 2) bTV = mkTyVar liftedTypeKind (mkUnsafeSystemName "b" 3) indexTy = mkTyConApp indexTcNm [nTy] nTy = VarTy nTV mTy = VarTy mTV fTy = mkFunTy indexTy (mkFunTy aTy bTy) aTy = VarTy aTV bTy = VarTy bTV vecATy = mkTyConApp vecTcNm [mTy,aTy] vecBTy = mkTyConApp vecTcNm [mTy,bTy] indexAddTy :: TyConName -- ^ Index TyCon name -> Type indexAddTy indexTcNm = ForAllTy nTV ( mkFunTy naturalPrimTy (mkFunTy indexTy (mkFunTy indexTy indexTy))) where nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 0) indexTy = mkTyConApp indexTcNm [VarTy nTV] bvAppendPrim :: TyConName -- ^ BitVector TyCon Name -> Term bvAppendPrim bvTcNm = Prim (PrimInfo "Clash.Sized.Internal.BitVector.++#" (bvAppendTy bvTcNm) WorkNever SingleResult NoUnfolding) bvAppendTy :: TyConName -- ^ BitVector TyCon Name -> Type bvAppendTy bvNm = ForAllTy mTV ( ForAllTy nTV ( mkFunTy naturalPrimTy (mkFunTy (mkTyConApp bvNm [VarTy nTV]) (mkFunTy (mkTyConApp bvNm [VarTy mTV]) (mkTyConApp bvNm [mkTyConApp typeNatAdd [VarTy nTV ,VarTy mTV]]))))) where mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 0) nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 1) bvSplitPrim :: TyConName -- ^ BitVector TyCon Name -> Term bvSplitPrim bvTcNm = Prim (PrimInfo "Clash.Sized.Internal.BitVector.split#" (bvSplitTy bvTcNm) WorkNever SingleResult NoUnfolding) bvSplitTy :: TyConName -- ^ BitVector TyCon Name -> Type bvSplitTy bvNm = ForAllTy nTV ( ForAllTy mTV ( mkFunTy naturalPrimTy (mkFunTy (mkTyConApp bvNm [mkTyConApp typeNatAdd [VarTy mTV ,VarTy nTV]]) (mkTyConApp tupNm [mkTyConApp bvNm [VarTy mTV] ,mkTyConApp bvNm [VarTy nTV]])))) where nTV = mkTyVar typeNatKind (mkUnsafeSystemName "n" 0) mTV = mkTyVar typeNatKind (mkUnsafeSystemName "m" 1) tupNm = ghcTyconToTyConName (tupleTyCon Boxed 2) ghcTyconToTyConName :: TyCon.TyCon -> TyConName ghcTyconToTyConName tc = Name User n' (fromGhcUnique (TyCon.tyConUnique tc)) (getSrcSpan n) where n' = fromMaybe "_INTERNAL_" (modNameM n) `Text.append` ('.' `Text.cons` Text.pack occName) occName = occNameString $ nameOccName n n = TyCon.tyConName tc svoid :: (State# RealWorld -> State# RealWorld) -> IO () svoid m0 = IO (\s -> case m0 s of s' -> (# s', () #)) isTrueDC,isFalseDC :: DataCon -> Bool isTrueDC dc = dcUniq dc == fromGhcUnique trueDataConKey isFalseDC dc = dcUniq dc == fromGhcUnique falseDataConKey