{-# LANGUAGE CPP #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE TemplateHaskell #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE ViewPatterns #-}
{-# OPTIONS_GHC -fno-warn-orphans #-}
module Clash.GHC.GHC2Core
( GHC2CoreState
, tyConMap
, coreToTerm
, coreToId
, coreToName
, modNameM
, qualfiedNameString
, makeAllTyCons
, emptyGHC2CoreState
)
where
import Control.Lens ((^.), (%~), (&), (%=))
import Control.Monad.Trans.Class (lift)
import Control.Monad.Trans.Reader (ReaderT)
import qualified Control.Monad.Trans.Reader as Reader
import Control.Monad.State (State)
import qualified Control.Monad.State.Lazy as State
import qualified Data.ByteString.Char8 as Char8
import Data.Hashable (Hashable (..))
import Data.HashMap.Lazy (HashMap)
import qualified Data.HashMap.Lazy as HashMap
import qualified Data.HashMap.Strict as HSM
import Data.Maybe (catMaybes,fromMaybe,listToMaybe)
import Data.Text (isInfixOf,pack)
import qualified Data.Traversable as T
import Unbound.Generics.LocallyNameless
(bind, embed, rebind, rec, runFreshM, unbind, unembed)
import qualified Unbound.Generics.LocallyNameless as Unbound
import CoAxiom (CoAxiom (co_ax_branches), CoAxBranch (cab_lhs,cab_rhs),
fromBranches)
import Coercion (coercionType,coercionKind)
import CoreFVs (exprSomeFreeVars)
import CoreSyn
(AltCon (..), Bind (..), CoreExpr, Expr (..), Unfolding (..), collectArgs,
rhssOfAlts, unfoldingTemplate)
import DataCon (DataCon, dataConExTyVars,
dataConName, dataConRepArgTys,
dataConTag, dataConTyCon,
dataConUnivTyVars, dataConWorkId)
import DynFlags (unsafeGlobalDynFlags)
import FamInstEnv (FamInst (..), FamInstEnvs,
familyInstances)
import FastString (unpackFS)
import Id (isDataConId_maybe)
import IdInfo (IdDetails (..), unfoldingInfo)
import Literal (Literal (..))
import Module (moduleName, moduleNameString)
import Name (Name, nameModule_maybe,
nameOccName, nameUnique, getSrcSpan)
import PrelNames (tYPETyConKey)
import OccName (occNameString)
import Outputable (showPpr)
import Pair (Pair (..))
import SrcLoc (isGoodSrcSpan)
import TyCon (AlgTyConRhs (..), TyCon,
algTyConRhs, isAlgTyCon, isFamilyTyCon,
isFunTyCon, isNewTyCon,
isPrimTyCon, isTupleTyCon,
isClosedSynFamilyTyConWithAxiom_maybe,
expandSynTyCon_maybe,
tyConArity,
tyConDataCons, tyConKind,
tyConName, tyConUnique)
import Type (mkTvSubstPrs, substTy, coreView)
#if MIN_VERSION_ghc(8,2,0)
import TyCoRep (Coercion (..), TyLit (..), Type (..))
#else
import TyCoRep (Coercion (..), TyBinder (..), TyLit (..), Type (..))
#endif
import Unique (Uniquable (..), Unique, getKey, hasKey)
import Var (Id, TyVar, Var, idDetails,
isTyVar, varName, varType,
varUnique, idInfo)
#if MIN_VERSION_ghc(8,2,0)
import Var (TyVarBndr (..))
#endif
import VarSet (isEmptyVarSet)
import qualified Clash.Core.DataCon as C
import qualified Clash.Core.Literal as C
import qualified Clash.Core.Name as C
import qualified Clash.Core.Term as C
import qualified Clash.Core.TyCon as C
import qualified Clash.Core.Type as C
import qualified Clash.Core.Var as C
import Clash.Driver.Types
import Clash.Primitives.Types
import Clash.Util
instance Hashable Name where
hashWithSalt s = hashWithSalt s . getKey . nameUnique
data GHC2CoreState
= GHC2CoreState
{ _tyConMap :: HashMap C.TyConOccName TyCon
, _nameMap :: HashMap Name String
}
makeLenses ''GHC2CoreState
emptyGHC2CoreState :: GHC2CoreState
emptyGHC2CoreState = GHC2CoreState HSM.empty HSM.empty
makeAllTyCons
:: GHC2CoreState
-> FamInstEnvs
-> HashMap C.TyConOccName C.TyCon
makeAllTyCons hm fiEnvs = go hm hm
where
go old new
| HSM.null (new ^. tyConMap) = HSM.empty
| otherwise = tcm `HSM.union` tcm'
where
(tcm,old') = State.runState (T.mapM (makeTyCon fiEnvs) (new ^. tyConMap)) old
tcm' = go old' (old' & tyConMap %~ (`HSM.difference` (old ^. tyConMap)))
makeTyCon :: FamInstEnvs
-> TyCon
-> State GHC2CoreState C.TyCon
makeTyCon fiEnvs tc = tycon
where
tycon
| isFamilyTyCon tc = mkFunTyCon
| isTupleTyCon tc = mkTupleTyCon
| isAlgTyCon tc = mkAlgTyCon
| isPrimTyCon tc = mkPrimTyCon
| tc `hasKey` tYPETyConKey = mkSuperKindTyCon
| otherwise = mkVoidTyCon
where
tcArity = tyConArity tc
mkAlgTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tcKind <- coreToType (tyConKind tc)
tcRhsM <- makeAlgTyConRhs $ algTyConRhs tc
case tcRhsM of
Just tcRhs ->
return
C.AlgTyCon
{ C.tyConName = tcName
, C.tyConKind = tcKind
, C.tyConArity = tcArity
, C.algTcRhs = tcRhs
}
Nothing -> return (C.PrimTyCon tcName tcKind tcArity)
mkFunTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tcKind <- coreToType (tyConKind tc)
substs <- case isClosedSynFamilyTyConWithAxiom_maybe tc of
Nothing -> let instances = familyInstances fiEnvs tc
in mapM famInstToSubst instances
Just cx -> let bx = fromBranches (co_ax_branches cx)
in mapM (\b -> (,) <$> mapM coreToType (cab_lhs b)
<*> coreToType (cab_rhs b))
bx
return
C.FunTyCon
{ C.tyConName = tcName
, C.tyConKind = tcKind
, C.tyConArity = tcArity
, C.tyConSubst = substs
}
mkTupleTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tcKind <- coreToType (tyConKind tc)
tcDc <- fmap (C.DataTyCon . (:[])) . coreToDataCon . head . tyConDataCons $ tc
return
C.AlgTyCon
{ C.tyConName = tcName
, C.tyConKind = tcKind
, C.tyConArity = tcArity
, C.algTcRhs = tcDc
}
mkPrimTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tcKind <- coreToType (tyConKind tc)
return
C.PrimTyCon
{ C.tyConName = tcName
, C.tyConKind = tcKind
, C.tyConArity = tcArity
}
mkSuperKindTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
return C.SuperKindTyCon
{ C.tyConName = tcName
}
mkVoidTyCon = do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tcKind <- coreToType (tyConKind tc)
return (C.PrimTyCon tcName tcKind tcArity)
famInstToSubst :: FamInst -> State GHC2CoreState ([C.Type],C.Type)
famInstToSubst fi = do
tys <- mapM coreToType (fi_tys fi)
ty <- coreToType (fi_rhs fi)
return (tys,ty)
makeAlgTyConRhs :: AlgTyConRhs
-> State GHC2CoreState (Maybe C.AlgTyConRhs)
makeAlgTyConRhs algTcRhs = case algTcRhs of
DataTyCon dcs _ -> Just <$> C.DataTyCon <$> mapM coreToDataCon dcs
#if MIN_VERSION_ghc(8,2,0)
SumTyCon dcs -> Just <$> C.DataTyCon <$> mapM coreToDataCon dcs
#endif
NewTyCon dc _ (rhsTvs,rhsEtad) _ -> Just <$> (C.NewTyCon <$> coreToDataCon dc
<*> ((,) <$> mapM coreToVar rhsTvs
<*> coreToType rhsEtad
)
)
AbstractTyCon {} -> return Nothing
TupleTyCon {} -> error "Cannot handle tuple tycons"
coreToTerm :: PrimMap a
-> [Var]
-> SrcSpan
-> CoreExpr
-> State GHC2CoreState C.Term
coreToTerm primMap unlocs srcsp coreExpr = Reader.runReaderT (term coreExpr) srcsp
where
term :: CoreExpr -> ReaderT SrcSpan (State GHC2CoreState) C.Term
term e
| (Var x,args) <- collectArgs e
, let nm = State.evalState (qualfiedNameString (varName x)) emptyGHC2CoreState
= go nm args
| otherwise
= term' e
where
go "Clash.Signal.Internal.mapSignal#" args
| length args == 5
= term (App (args!!3) (args!!4))
go "Clash.Signal.Internal.signal#" args
| length args == 3
= term (args!!2)
go "Clash.Signal.Internal.appSignal#" args
| length args == 5
= term (App (args!!3) (args!!4))
go "Clash.Signal.Internal.joinSignal#" args
| length args == 3
= term (args!!2)
go "Clash.Signal.Bundle.vecBundle#" args
| length args == 4
= term (args!!3)
go "GHC.Base.$" args
| length args == 5
= term (App (args!!3) (args!!4))
go "GHC.Stack.Types.PushCallStack" args = term (last args)
go "GHC.Stack.Types.FreezeCallStack" args = term (last args)
go "GHC.Stack.withFrozenCallStack" args
| length args == 3
= term (App (args!!2) (args!!1))
go _ _ = term' e
term' (Var x) = do
srcsp' <- Reader.ask
lift (var srcsp' x)
term' (Lit l) = return $ C.Literal (coreToLiteral l)
term' (App eFun (Type tyArg)) = C.TyApp <$> term eFun <*> lift (coreToType tyArg)
term' (App eFun eArg) = C.App <$> term eFun <*> term eArg
term' (Lam x e) | isTyVar x = C.TyLam <$> (bind <$> lift (coreToTyVar x) <*> addUsefull (getSrcSpan x) (term e))
| otherwise = C.Lam <$> (bind <$> lift (coreToId x) <*> addUsefull (getSrcSpan x) (term e))
term' (Let (NonRec x e1) e2) = do
x' <- lift (coreToId x)
e1' <- addUsefull (getSrcSpan x) (term e1)
e2' <- term e2
return $ C.Letrec $ bind (rec [(x', embed e1')]) e2'
term' (Let (Rec xes) e) = do
xes' <- mapM (\(x,b) -> (,) <$> lift (coreToId x)
<*> addUsefull (getSrcSpan x)
(embed <$> term b))
xes
e' <- term e
return $ C.Letrec $ bind (rec xes') e'
term' (Case _ _ ty []) = C.Prim (pack "EmptyCase") <$> lift (coreToType ty)
term' (Case e b ty alts) = do
let usesBndr = any ( not . isEmptyVarSet . exprSomeFreeVars (`elem` [b]))
$ rhssOfAlts alts
b' <- lift (coreToId b)
e' <- addUsefull (getSrcSpan b) (term e)
ty' <- lift (coreToType ty)
let caseTerm v = C.Case v ty' <$> mapM (addUsefull (getSrcSpan b) . alt) alts
if usesBndr
then do
ct <- caseTerm (C.Var (unembed $ C.varType b') (C.varName b'))
return $ C.Letrec $ bind (rec [(b',embed e')]) ct
else caseTerm e'
term' (Cast e co) = do
let (Pair ty1 ty2) = coercionKind co
hasPrimCoM <- lift (hasPrimCo co)
ty1_I <- lift (isIntegerTy ty1)
ty2_I <- lift (isIntegerTy ty2)
case hasPrimCoM of
Just _ | ty1_I || ty2_I
-> C.Cast <$> term e <*> lift (coreToType ty1) <*> lift (coreToType ty2)
_ -> term e
term' (Tick _ e) = term e
term' (Type t) = C.Prim (pack "_TY_") <$> lift (coreToType t)
term' (Coercion co) = C.Prim (pack "_CO_") <$> lift (coreToType (coercionType co))
var srcsp' x = do
xVar <- coreToVar x
xPrim <- coreToPrimVar x
let xNameS = pack $ C.name2String xPrim
xType <- coreToType (varType x)
case isDataConId_maybe x of
Just dc -> case HashMap.lookup xNameS primMap of
Just _ -> return $ C.Prim xNameS xType
Nothing -> if isDataConWrapId x && not (isNewTyCon (dataConTyCon dc))
then let xInfo = idInfo x
unfolding = unfoldingInfo xInfo
in case unfolding of
CoreUnfolding {} -> Reader.runReaderT (term (unfoldingTemplate unfolding)) srcsp'
NoUnfolding -> error ("No unfolding for DC wrapper: " ++ showPpr unsafeGlobalDynFlags x)
_ -> error ("Unexpected unfolding for DC wrapper: " ++ showPpr unsafeGlobalDynFlags x)
else C.Data <$> coreToDataCon dc
Nothing -> case HashMap.lookup xNameS primMap of
Just (Primitive f _)
| f == pack "Clash.Signal.Internal.mapSignal#" -> return (mapSignalTerm xType)
| f == pack "Clash.Signal.Internal.signal#" -> return (signalTerm xType)
| f == pack "Clash.Signal.Internal.appSignal#" -> return (appSignalTerm xType)
| f == pack "Clash.Signal.Internal.traverse#" -> return (traverseTerm xType)
| f == pack "Clash.Signal.Internal.joinSignal#" -> return (joinTerm xType)
| f == pack "Clash.Signal.Bundle.vecBundle#" -> return (vecUnwrapTerm xType)
| f == pack "GHC.Base.$" -> return (dollarTerm xType)
| f == pack "GHC.Stack.withFrozenCallStack" -> return (withFrozenCallStackTerm xType)
| f == pack "GHC.Magic.lazy" -> return (idTerm xType)
| f == pack "GHC.Magic.runRW#" -> return (runRWTerm xType)
| otherwise -> return (C.Prim xNameS xType)
Just (BlackBox {}) ->
return (C.Prim xNameS xType)
Nothing
| x `elem` unlocs -> return (C.Prim xNameS xType)
| pack "$cshow" `isInfixOf` xNameS -> return (C.Prim xNameS xType)
| otherwise -> return (C.Var xType xVar)
alt (DEFAULT , _ , e) = bind C.DefaultPat <$> term e
alt (LitAlt l , _ , e) = bind (C.LitPat . embed $ coreToLiteral l) <$> term e
alt (DataAlt dc, xs, e) = case span isTyVar xs of
(tyvs,tmvs) -> bind <$> (C.DataPat . embed <$>
lift (coreToDataCon dc) <*>
(rebind <$>
lift (mapM coreToTyVar tyvs) <*>
lift (mapM coreToId tmvs))) <*>
term e
coreToLiteral :: Literal
-> C.Literal
coreToLiteral l = case l of
MachStr fs -> C.StringLiteral (Char8.unpack fs)
MachChar c -> C.CharLiteral c
MachInt i -> C.IntLiteral i
MachInt64 i -> C.IntLiteral i
MachWord i -> C.WordLiteral i
MachWord64 i -> C.WordLiteral i
LitInteger i _ -> C.IntegerLiteral i
MachFloat r -> C.FloatLiteral r
MachDouble r -> C.DoubleLiteral r
MachNullAddr -> C.StringLiteral []
MachLabel fs _ _ -> C.StringLiteral (unpackFS fs)
addUsefull :: SrcSpan -> ReaderT SrcSpan (State GHC2CoreState) a
-> ReaderT SrcSpan (State GHC2CoreState) a
addUsefull x = Reader.local (\r -> if isGoodSrcSpan x then x else r)
isIntegerTy :: Type -> State GHC2CoreState Bool
isIntegerTy (TyConApp tc []) = do
tcNm <- qualfiedNameString (tyConName tc)
return (tcNm == "GHC.Integer.Type.Integer")
isIntegerTy _ = return False
hasPrimCo :: Coercion -> State GHC2CoreState (Maybe Type)
hasPrimCo (TyConAppCo _ _ coers) = do
tcs <- catMaybes <$> mapM hasPrimCo coers
return (listToMaybe tcs)
hasPrimCo (AppCo co1 co2) = do
tc1M <- hasPrimCo co1
case tc1M of
Just _ -> return tc1M
_ -> hasPrimCo co2
hasPrimCo (ForAllCo _ _ co) = hasPrimCo co
hasPrimCo co@(AxiomInstCo _ _ coers) = do
let (Pair ty1 _) = coercionKind co
ty1PM <- isPrimTc ty1
if ty1PM
then return (Just ty1)
else do
tcs <- catMaybes <$> mapM hasPrimCo coers
return (listToMaybe tcs)
where
isPrimTc (TyConApp tc _) = do
tcNm <- qualfiedNameString (tyConName tc)
return (tcNm `elem` ["Clash.Sized.Internal.BitVector.Bit"
,"Clash.Sized.Internal.BitVector.BitVector"
,"Clash.Sized.Internal.Index.Index"
,"Clash.Sized.Internal.Signed.Signed"
,"Clash.Sized.Internal.Unsigned.Unsigned"
])
isPrimTc _ = return False
hasPrimCo (SymCo co) = hasPrimCo co
hasPrimCo (TransCo co1 co2) = do
tc1M <- hasPrimCo co1
case tc1M of
Just _ -> return tc1M
_ -> hasPrimCo co2
hasPrimCo (AxiomRuleCo _ coers) = do
tcs <- catMaybes <$> mapM hasPrimCo coers
return (listToMaybe tcs)
hasPrimCo (NthCo _ co) = hasPrimCo co
hasPrimCo (LRCo _ co) = hasPrimCo co
hasPrimCo (InstCo co _) = hasPrimCo co
hasPrimCo (SubCo co) = hasPrimCo co
hasPrimCo _ = return Nothing
coreToDataCon :: DataCon
-> State GHC2CoreState C.DataCon
coreToDataCon dc = do
repTys <- mapM coreToType (dataConRepArgTys dc)
dcTy <- coreToType (varType $ dataConWorkId dc)
mkDc dcTy repTys
where
mkDc dcTy repTys = do
nm <- coreToName dataConName getUnique qualfiedNameString dc
uTvs <- mapM coreToVar (dataConUnivTyVars dc)
eTvs <- mapM coreToVar (dataConExTyVars dc)
return $ C.MkData
{ C.dcName = nm
, C.dcTag = dataConTag dc
, C.dcType = dcTy
, C.dcArgTys = repTys
, C.dcUnivTyVars = uTvs
, C.dcExtTyVars = eTvs
}
coreToType :: Type
-> State GHC2CoreState C.Type
coreToType ty = coreToType' $ fromMaybe ty (coreView ty)
coreToType' :: Type
-> State GHC2CoreState C.Type
coreToType' (TyVarTy tv) = C.VarTy <$> coreToType (varType tv) <*> (coreToVar tv)
coreToType' (TyConApp tc args)
| isFunTyCon tc = foldl C.AppTy (C.ConstTy C.Arrow) <$> mapM coreToType args
| otherwise = case expandSynTyCon_maybe tc args of
Just (substs,synTy,remArgs) -> do
let substs' = mkTvSubstPrs substs
synTy' = substTy substs' synTy
foldl C.AppTy <$> coreToType synTy' <*> mapM coreToType remArgs
_ -> do
tcName <- coreToName tyConName tyConUnique qualfiedNameString tc
tyConMap %= (HSM.insert (C.nameOcc tcName) tc)
C.mkTyConApp <$> (pure tcName) <*> mapM coreToType args
#if MIN_VERSION_ghc(8,2,0)
coreToType' (ForAllTy (TvBndr tv _) ty) = C.ForAllTy <$> (bind <$> coreToTyVar tv <*> coreToType ty)
coreToType' (FunTy ty1 ty2) = C.mkFunTy <$> coreToType ty1 <*> coreToType ty2
#else
coreToType' (ForAllTy (Named tv _) ty) = C.ForAllTy <$> (bind <$> coreToTyVar tv <*> coreToType ty)
coreToType' (ForAllTy (Anon ty1) ty2) = C.mkFunTy <$> coreToType ty1 <*> coreToType ty2
#endif
coreToType' (LitTy tyLit) = return $ C.LitTy (coreToTyLit tyLit)
coreToType' (AppTy ty1 ty2) = C.AppTy <$> coreToType ty1 <*> coreToType' ty2
coreToType' t@(CastTy _ _) = error ("Cannot handle CastTy " ++ showPpr unsafeGlobalDynFlags t)
coreToType' t@(CoercionTy _) = error ("Cannot handle CoercionTy " ++ showPpr unsafeGlobalDynFlags t)
coreToTyLit :: TyLit
-> C.LitTy
coreToTyLit (NumTyLit i) = C.NumTy (fromInteger i)
coreToTyLit (StrTyLit s) = C.SymTy (unpackFS s)
coreToTyVar :: TyVar
-> State GHC2CoreState C.TyVar
coreToTyVar tv =
C.TyVar <$> (coreToVar tv) <*> (embed <$> coreToType (varType tv))
coreToId :: Id
-> State GHC2CoreState C.Id
coreToId i =
C.Id <$> (coreToVar i) <*> (embed <$> coreToType (varType i))
coreToVar :: Var
-> State GHC2CoreState (C.Name a)
coreToVar = coreToName varName varUnique qualfiedNameStringM
coreToPrimVar :: Var
-> State GHC2CoreState (C.Name C.Term)
coreToPrimVar = coreToName varName varUnique qualfiedNameString
coreToName :: (b -> Name)
-> (b -> Unique)
-> (Name -> State GHC2CoreState String)
-> b
-> State GHC2CoreState (C.Name a)
coreToName toName toUnique toString v = do
ns <- toString (toName v)
let nm = Unbound.makeName ns (toInteger . getKey . toUnique $ v)
loc = getSrcSpan (toName v)
return (C.Name C.User nm loc)
qualfiedNameString :: Name
-> State GHC2CoreState String
qualfiedNameString n = makeCached n nameMap
$ return (fromMaybe "_INTERNAL_" (modNameM n) ++ ('.':occName))
where
occName = occNameString $ nameOccName n
qualfiedNameStringM :: Name
-> State GHC2CoreState String
qualfiedNameStringM n = makeCached n nameMap
$ return (maybe occName (\modName -> modName ++ ('.':occName)) (modNameM n))
where
occName = occNameString $ nameOccName n
modNameM :: Name
-> Maybe String
modNameM n = do
module_ <- nameModule_maybe n
let moduleNm = moduleName module_
return (moduleNameString moduleNm)
mapSignalTerm :: C.Type
-> C.Term
mapSignalTerm (C.ForAllTy tvATy) =
C.TyLam (bind aTV (
C.TyLam (bind bTV (
C.TyLam (bind clkTV (
C.Lam (bind fId (
C.Lam (bind xId (
C.App (C.Var fTy fName) (C.Var aTy xName)))))))))))
where
(aTV,bTV,clkTV,funTy) = runFreshM $ do
{ (aTV',C.ForAllTy tvBTy) <- unbind tvATy
; (bTV',C.ForAllTy tvClkTy) <- unbind tvBTy
; (clkTV',funTy') <- unbind tvClkTy
; return (aTV',bTV',clkTV',funTy')
}
(C.FunTy _ funTy'') = C.tyView funTy
(C.FunTy aTy bTy) = C.tyView funTy''
fName = C.string2SystemName "f"
xName = C.string2SystemName "x"
fTy = C.mkFunTy aTy bTy
fId = C.Id fName (embed fTy)
xId = C.Id xName (embed aTy)
mapSignalTerm ty = error $ $(curLoc) ++ show ty
signalTerm :: C.Type
-> C.Term
signalTerm (C.ForAllTy tvATy) =
C.TyLam (bind aTV (
C.TyLam (bind clkTV (
C.Lam (bind xId (
C.Var aTy xName))))))
where
(aTV,clkTV,funTy) = runFreshM $ do
{ (aTV', C.ForAllTy tvClkTy) <- unbind tvATy
; (clkTV', funTy') <- unbind tvClkTy
; return (aTV',clkTV',funTy')
}
(C.FunTy _ aTy) = C.tyView funTy
xName = C.string2SystemName "x"
xId = C.Id xName (embed aTy)
signalTerm ty = error $ $(curLoc) ++ show ty
appSignalTerm :: C.Type
-> C.Term
appSignalTerm (C.ForAllTy tvClkTy) =
C.TyLam (bind clkTV (
C.TyLam (bind aTV (
C.TyLam (bind bTV (
C.Lam (bind fId (
C.Lam (bind xId (
C.App (C.Var fTy fName) (C.Var aTy xName)))))))))))
where
(clkTV,aTV,bTV,funTy) = runFreshM $ do
{ (clkTV',C.ForAllTy tvATy) <- unbind tvClkTy
; (aTV',C.ForAllTy tvBTy) <- unbind tvATy
; (bTV',funTy') <- unbind tvBTy
; return (clkTV',aTV',bTV',funTy')
}
(C.FunTy _ funTy'') = C.tyView funTy
(C.FunTy aTy bTy) = C.tyView funTy''
fName = C.string2SystemName "f"
xName = C.string2SystemName "x"
fTy = C.mkFunTy aTy bTy
fId = C.Id fName (embed fTy)
xId = C.Id xName (embed aTy)
appSignalTerm ty = error $ $(curLoc) ++ show ty
vecUnwrapTerm :: C.Type
-> C.Term
vecUnwrapTerm (C.ForAllTy tvTTy) =
C.TyLam (bind tTV (
C.TyLam (bind nTV (
C.TyLam (bind aTV (
C.Lam (bind vsId (
C.Var vsTy vsName))))))))
where
(tTV,nTV,aTV,funTy) = runFreshM $ do
{ (tTV',C.ForAllTy tvNTy) <- unbind tvTTy
; (nTV',C.ForAllTy tvATy) <- unbind tvNTy
; (aTV',funTy') <- unbind tvATy
; return (tTV',nTV',aTV',funTy')
}
(C.FunTy _ vsTy) = C.tyView funTy
vsName = C.string2SystemName "vs"
vsId = C.Id vsName (embed vsTy)
vecUnwrapTerm ty = error $ $(curLoc) ++ show ty
traverseTerm :: C.Type
-> C.Term
traverseTerm (C.ForAllTy tvFTy) =
C.TyLam (bind fTV (
C.TyLam (bind aTV (
C.TyLam (bind bTV (
C.TyLam (bind clkTV (
C.Lam (bind dictId (
C.Lam (bind gId (
C.Lam (bind xId (
C.App (C.Var gTy gName) (C.Var xTy xName)))))))))))))))
where
(fTV,aTV,bTV,clkTV,funTy) = runFreshM $ do
{ (fTV',C.ForAllTy tvATy) <- unbind tvFTy
; (aTV',C.ForAllTy tvBTy) <- unbind tvATy
; (bTV',C.ForAllTy tvClkTy) <- unbind tvBTy
; (clkTV',funTy') <- unbind tvClkTy
; return (fTV',aTV',bTV',clkTV',funTy')
}
(C.FunTy dictTy funTy1) = C.tyView funTy
(C.FunTy gTy funTy2) = C.tyView funTy1
(C.FunTy xTy _) = C.tyView funTy2
dictName = C.string2SystemName "dict"
gName = C.string2SystemName "g"
xName = C.string2SystemName "x"
dictId = C.Id dictName (embed dictTy)
gId = C.Id gName (embed gTy)
xId = C.Id xName (embed xTy)
traverseTerm ty = error $ $(curLoc) ++ show ty
dollarTerm :: C.Type
-> C.Term
dollarTerm (C.ForAllTy tvRTy) =
C.TyLam (bind rTV (
C.TyLam (bind aTV (
C.TyLam (bind bTV (
C.Lam (bind fId (
C.Lam (bind xId (
C.App (C.Var fTy fName) (C.Var aTy xName)))))))))))
where
(rTV,aTV,bTV,funTy) = runFreshM $ do
{ (rTV',C.ForAllTy tvATy) <- unbind tvRTy
; (aTV',C.ForAllTy tvBTy) <- unbind tvATy
; (bTV',funTy') <- unbind tvBTy
; return (rTV',aTV',bTV',funTy')
}
(C.FunTy fTy funTy'') = C.tyView funTy
(C.FunTy aTy _) = C.tyView funTy''
fName = C.string2SystemName "f"
xName = C.string2SystemName "x"
fId = C.Id fName (embed fTy)
xId = C.Id xName (embed aTy)
dollarTerm ty = error $ $(curLoc) ++ show ty
joinTerm :: C.Type
-> C.Term
joinTerm ty@(C.ForAllTy _) = signalTerm ty
joinTerm ty = error $ $(curLoc) ++ show ty
withFrozenCallStackTerm
:: C.Type
-> C.Term
withFrozenCallStackTerm (C.ForAllTy tvATy) =
C.TyLam (bind aTV (
C.Lam (bind callStackId (
C.Lam (bind fId (
C.App (C.Var fTy fName) (C.Var callStackTy callStackName)))))))
where
(aTV,funTy) = runFreshM (unbind tvATy)
(C.FunTy callStackTy fTy) = C.tyView funTy
callStackName = C.string2SystemName "callStack"
fName = C.string2SystemName "f"
callStackId = C.Id callStackName (embed callStackTy)
fId = C.Id fName (embed fTy)
withFrozenCallStackTerm ty = error $ $(curLoc) ++ show ty
idTerm
:: C.Type
-> C.Term
idTerm (C.ForAllTy tvATy) =
C.TyLam (bind aTV (
C.Lam (bind xId (
C.Var xTy xName))))
where
(aTV,funTy) = runFreshM (unbind tvATy)
(C.FunTy xTy _) = C.tyView funTy
xName = C.string2SystemName "x"
xId = C.Id xName (embed xTy)
idTerm ty = error $ $(curLoc) ++ show ty
runRWTerm
:: C.Type
-> C.Term
runRWTerm (C.ForAllTy tvRTy) =
C.TyLam (bind rTV (
C.TyLam (bind oTV (
C.Lam (bind fId (
(C.App (C.Var fTy fName) (C.Prim rwNm rwTy))))))))
where
(rTV,oTV,funTy) = runFreshM $ do
{ (rTV',C.ForAllTy tvOTy) <- unbind tvRTy
; (oTV',funTy') <- unbind tvOTy
; return (rTV',oTV',funTy')
}
(C.FunTy fTy _) = C.tyView funTy
(C.FunTy rwTy _) = C.tyView fTy
fName = C.string2SystemName "f"
fId = C.Id fName (embed fTy)
rwNm = pack "Clash.GHC.GHC2Core.realWorld#"
runRWTerm ty = error $ $(curLoc) ++ show ty
isDataConWrapId :: Id -> Bool
isDataConWrapId v = case idDetails v of
DataConWrapId {} -> True
_ -> False