+
module Vectorise( vectorise )
where
-#include "HsVersions.h"
-
import VectMonad
import VectUtils
import VectType
import VectCore
-import DynFlags
-import HscTypes
+import HscTypes hiding ( MonadThings(..) )
-import CoreLint ( showPass, endPass )
+import Module ( PackageId )
import CoreSyn
import CoreUtils
+import CoreUnfold ( mkInlineRule )
+import MkCore ( mkWildCase )
import CoreFVs
-import SimplMonad ( SimplCount, zeroSimplCount )
-import Rules ( RuleBase )
+import CoreMonad ( CoreM, getHscEnv )
import DataCon
import TyCon
import Type
import FamInstEnv ( extendFamInstEnvList )
-import InstEnv ( extendInstEnvList )
import Var
import VarEnv
import VarSet
-import Name ( Name, mkSysTvName, getName )
-import NameEnv
import Id
-import MkId ( unwrapFamInstScrut )
import OccName
-import Module ( Module )
+import BasicTypes ( isLoopBreaker )
-import DsMonad hiding (mapAndUnzipM)
-import DsUtils ( mkCoreTup, mkCoreTupTy )
-
-import Literal ( Literal )
-import PrelNames
+import Literal ( Literal, mkMachInt )
import TysWiredIn
import TysPrim ( intPrimTy )
-import BasicTypes ( Boxity(..) )
import Outputable
import FastString
-import Control.Monad ( liftM, liftM2, zipWithM, mapAndUnzipM )
-
-vectorise :: HscEnv -> UniqSupply -> RuleBase -> ModGuts
- -> IO (SimplCount, ModGuts)
-vectorise hsc_env _ _ guts
- = do
- showPass dflags "Vectorisation"
+import Util ( zipLazy )
+import Control.Monad
+import Data.List ( sortBy, unzip4 )
+
+vectorise :: PackageId -> ModGuts -> CoreM ModGuts
+vectorise backend guts = do
+ hsc_env <- getHscEnv
+ liftIO $ vectoriseIO backend hsc_env guts
+
+-- | Vectorise a single monad, given its HscEnv (code gen environment).
+vectoriseIO :: PackageId -> HscEnv -> ModGuts -> IO ModGuts
+vectoriseIO backend hsc_env guts
+ = do -- Get information about currently loaded external packages.
eps <- hscEPS hsc_env
+
+ -- Combine vectorisation info from the current module, and external ones.
let info = hptVectInfo hsc_env `plusVectInfo` eps_vect_info eps
- Just (info', guts') <- initV hsc_env guts info (vectModule guts)
- endPass dflags "Vectorisation" Opt_D_dump_vect (mg_binds guts')
- return (zeroSimplCount dflags, guts' { mg_vect_info = info' })
- where
- dflags = hsc_dflags hsc_env
+ -- Run the main VM computation.
+ Just (info', guts') <- initV backend hsc_env guts info (vectModule guts)
+ return (guts' { mg_vect_info = info' })
+
+
+-- | Vectorise a single module, in the VM monad.
vectModule :: ModGuts -> VM ModGuts
vectModule guts
- = do
+ = do -- Vectorise the type environment.
+ -- This may add new TyCons and DataCons.
+ -- TODO: What new binds do we get back here?
(types', fam_insts, tc_binds) <- vectTypeEnv (mg_types guts)
-
+
+ -- TODO: What is this?
let fam_inst_env' = extendFamInstEnvList (mg_fam_inst_env guts) fam_insts
updGEnv (setFamInstEnv fam_inst_env')
-
+
-- dicts <- mapM buildPADict pa_insts
-- workers <- mapM vectDataConWorkers pa_insts
+
+ -- Vectorise all the top level bindings.
binds' <- mapM vectTopBind (mg_binds guts)
+
return $ guts { mg_types = types'
, mg_binds = Rec tc_binds : binds'
, mg_fam_inst_env = fam_inst_env'
, mg_fam_insts = mg_fam_insts guts ++ fam_insts
}
+
+-- | Try to vectorise a top-level binding.
+-- If it doesn't vectorise then return it unharmed.
+--
+-- For example, for the binding
+--
+-- @
+-- foo :: Int -> Int
+-- foo = \x -> x + x
+-- @
+--
+-- we get
+-- @
+-- foo :: Int -> Int
+-- foo = \x -> vfoo $: x
+--
+-- v_foo :: Closure void vfoo lfoo
+-- v_foo = closure vfoo lfoo void
+--
+-- vfoo :: Void -> Int -> Int
+-- vfoo = ...
+--
+-- lfoo :: PData Void -> PData Int -> PData Int
+-- lfoo = ...
+-- @
+--
+-- @vfoo@ is the "vectorised", or scalar, version that does the same as the original
+-- function foo, but takes an explicit environment.
+--
+-- @lfoo@ is the "lifted" version that works on arrays.
+--
+-- @v_foo@ combines both of these into a `Closure` that also contains the
+-- environment.
+--
+-- The original binding @foo@ is rewritten to call the vectorised version
+-- present in the closure.
+--
vectTopBind :: CoreBind -> VM CoreBind
vectTopBind b@(NonRec var expr)
- = do
- var' <- vectTopBinder var
- expr' <- vectTopRhs var expr
- hs <- takeHoisted
- return . Rec $ (var, expr) : (var', expr') : hs
+ = do
+ (inline, expr') <- vectTopRhs var expr
+ var' <- vectTopBinder var inline expr'
+
+ -- Vectorising the body may create other top-level bindings.
+ hs <- takeHoisted
+
+ -- To get the same functionality as the original body we project
+ -- out its vectorised version from the closure.
+ cexpr <- tryConvert var var' expr
+
+ return . Rec $ (var, cexpr) : (var', expr') : hs
`orElseV`
return b
vectTopBind b@(Rec bs)
- = do
- vars' <- mapM vectTopBinder vars
- exprs' <- zipWithM vectTopRhs vars exprs
+ = do
+ (vars', _, exprs')
+ <- fixV $ \ ~(_, inlines, rhss) ->
+ do vars' <- sequence [vectTopBinder var inline rhs
+ | (var, ~(inline, rhs)) <- zipLazy vars (zip inlines rhss)]
+ (inlines', exprs')
+ <- mapAndUnzipM (uncurry vectTopRhs) bs
+
+ return (vars', inlines', exprs')
+
hs <- takeHoisted
- return . Rec $ bs ++ zip vars' exprs' ++ hs
+ cexprs <- sequence $ zipWith3 tryConvert vars vars' exprs
+ return . Rec $ zip vars cexprs ++ zip vars' exprs' ++ hs
`orElseV`
return b
where
(vars, exprs) = unzip bs
-vectTopBinder :: Var -> VM Var
-vectTopBinder var
- = do
+
+-- | Make the vectorised version of this top level binder, and add the mapping
+-- between it and the original to the state. For some binder @foo@ the vectorised
+-- version is @$v_foo@
+--
+-- NOTE: vectTopBinder *MUST* be lazy in inline and expr because of how it is
+-- used inside of fixV in vectTopBind
+vectTopBinder
+ :: Var -- ^ Name of the binding.
+ -> Inline -- ^ Whether it should be inlined, used to annotate it.
+ -> CoreExpr -- ^ RHS of the binding, used to set the `Unfolding` of the returned `Var`.
+ -> VM Var -- ^ Name of the vectorised binding.
+
+vectTopBinder var inline expr
+ = do
+ -- Vectorise the type attached to the var.
vty <- vectType (idType var)
- var' <- cloneId mkVectOcc var vty
+ var' <- liftM (`setIdUnfolding` unfolding) $ cloneId mkVectOcc var vty
defGlobalVar var var'
return var'
-
-vectTopRhs :: Var -> CoreExpr -> VM CoreExpr
+ where
+ unfolding = case inline of
+ Inline arity -> mkInlineRule expr (Just arity)
+ DontInline -> noUnfolding
+
+
+-- | Vectorise the RHS of a top-level binding, in an empty local environment.
+vectTopRhs
+ :: Var -- ^ Name of the binding.
+ -> CoreExpr -- ^ Body of the binding.
+ -> VM (Inline, CoreExpr)
+
vectTopRhs var expr
- = do
- closedV . liftM vectorised
- . inBind var
- $ vectPolyExpr (freeVars expr)
+ = dtrace (vcat [text "vectTopRhs", ppr expr])
+ $ closedV
+ $ do (inline, vexpr) <- inBind var
+ $ vectPolyExpr (isLoopBreaker $ idOccInfo var)
+ (freeVars expr)
+ return (inline, vectorised vexpr)
+
+
+-- | Project out the vectorised version of a binding from some closure,
+-- or return the original body if that doesn't work.
+tryConvert
+ :: Var -- ^ Name of the original binding (eg @foo@)
+ -> Var -- ^ Name of vectorised version of binding (eg @$vfoo@)
+ -> CoreExpr -- ^ The original body of the binding.
+ -> VM CoreExpr
+
+tryConvert var vect_var rhs
+ = fromVect (idType var) (Var vect_var) `orElseV` return rhs
-- ----------------------------------------------------------------------------
-- Bindings
+-- | Vectorise a binder variable, along with its attached type.
vectBndr :: Var -> VM VVar
vectBndr v
= do
- vty <- vectType (idType v)
- lty <- mkPArrayType vty
+ (vty, lty) <- vectAndLiftType (idType v)
let vv = v `Id.setIdType` vty
lv = v `Id.setIdType` lty
updLEnv (mapTo vv lv)
where
mapTo vv lv env = env { local_vars = extendVarEnv (local_vars env) v (vv, lv) }
+
+-- | Vectorise a binder variable, along with its attached type,
+-- but give the result a new name.
+vectBndrNew :: Var -> FastString -> VM VVar
+vectBndrNew v fs
+ = do
+ vty <- vectType (idType v)
+ vv <- newLocalVVar fs vty
+ updLEnv (upd vv)
+ return vv
+ where
+ upd vv env = env { local_vars = extendVarEnv (local_vars env) v vv }
+
+
+-- | Vectorise a binder then run a computation with that binder in scope.
vectBndrIn :: Var -> VM a -> VM (VVar, a)
vectBndrIn v p
= localV
x <- p
return (vv, x)
-vectBndrIn' :: Var -> (VVar -> VM a) -> VM (VVar, a)
-vectBndrIn' v p
+
+-- | Vectorise a binder, give it a new name, then run a computation with that binder in scope.
+vectBndrNewIn :: Var -> FastString -> VM a -> VM (VVar, a)
+vectBndrNewIn v fs p
= localV
$ do
- vv <- vectBndr v
- x <- p vv
+ vv <- vectBndrNew v fs
+ x <- p
return (vv, x)
+-- | Vectorise some binders, then run a computation with them in scope.
vectBndrsIn :: [Var] -> VM a -> VM ([VVar], a)
vectBndrsIn vs p
= localV
x <- p
return (vvs, x)
+
-- ----------------------------------------------------------------------------
-- Expressions
+-- | Vectorise a variable, producing the vectorised and lifted versions.
vectVar :: Var -> VM VExpr
vectVar v
- = do
+ = do
+ -- lookup the variable from the environment.
r <- lookupVar v
+
case r of
Local (vv,lv) -> return (Var vv, Var lv)
Global vv -> do
let vexpr = Var vv
- lexpr <- liftPA vexpr
+ lexpr <- liftPD vexpr
return (vexpr, lexpr)
+-- | Like `vectVar` but also add type applications to the variables.
vectPolyVar :: Var -> [Type] -> VM VExpr
vectPolyVar v tys
= do
- vtys <- mapM vectType tys
- r <- lookupVar v
+ vtys <- mapM vectType tys
+ r <- lookupVar v
case r of
- Local (vv, lv) -> liftM2 (,) (polyApply (Var vv) vtys)
- (polyApply (Var lv) vtys)
- Global poly -> do
- vexpr <- polyApply (Var poly) vtys
- lexpr <- liftPA vexpr
- return (vexpr, lexpr)
+ Local (vv, lv)
+ -> liftM2 (,) (polyApply (Var vv) vtys)
+ (polyApply (Var lv) vtys)
+ Global poly
+ -> do vexpr <- polyApply (Var poly) vtys
+ lexpr <- liftPD vexpr
+ return (vexpr, lexpr)
+
+
+-- | Lifted literals are created by replicating them.
vectLiteral :: Literal -> VM VExpr
vectLiteral lit
= do
- lexpr <- liftPA (Lit lit)
+ lexpr <- liftPD (Lit lit)
return (Lit lit, lexpr)
-vectPolyExpr :: CoreExprWithFVs -> VM VExpr
-vectPolyExpr expr
- = polyAbstract tvs $ \abstract ->
- do
- mono' <- vectExpr mono
- return $ mapVect abstract mono'
+
+-- | Vectorise a polymorphic expression
+vectPolyExpr
+ :: Bool -- ^ When vectorising the RHS of a binding, whether that
+ -- binding is a loop breaker.
+ -> CoreExprWithFVs
+ -> VM (Inline, VExpr)
+
+vectPolyExpr loop_breaker (_, AnnNote note expr)
+ = do (inline, expr') <- vectPolyExpr loop_breaker expr
+ return (inline, vNote note expr')
+
+vectPolyExpr loop_breaker expr
+ = do
+ arity <- polyArity tvs
+ polyAbstract tvs $ \args ->
+ do
+ (inline, mono') <- vectFnExpr False loop_breaker mono
+ return (addInlineArity inline arity,
+ mapVect (mkLams $ tvs ++ args) mono')
where
- (tvs, mono) = collectAnnTypeBinders expr
-
+ (tvs, mono) = collectAnnTypeBinders expr
+
+
+-- | Vectorise a core expression.
vectExpr :: CoreExprWithFVs -> VM VExpr
vectExpr (_, AnnType ty)
= liftM vType (vectType ty)
-vectExpr (_, AnnVar v) = vectVar v
+vectExpr (_, AnnVar v)
+ = vectVar v
-vectExpr (_, AnnLit lit) = vectLiteral lit
+vectExpr (_, AnnLit lit)
+ = vectLiteral lit
vectExpr (_, AnnNote note expr)
= liftM (vNote note) (vectExpr expr)
where
(fn, tys) = collectAnnTypeArgs e
+vectExpr (_, AnnApp (_, AnnVar v) (_, AnnLit lit))
+ | Just con <- isDataConId_maybe v
+ , is_special_con con
+ = do
+ let vexpr = App (Var v) (Lit lit)
+ lexpr <- liftPD vexpr
+ return (vexpr, lexpr)
+ where
+ is_special_con con = con `elem` [intDataCon, floatDataCon, doubleDataCon]
+
+
+-- TODO: Avoid using closure application for dictionaries.
+-- vectExpr (_, AnnApp fn arg)
+-- | if is application of dictionary
+-- just use regular app instead of closure app.
+
+-- for lifted version.
+-- do liftPD (sub a dNumber)
+-- lift the result of the selection, not sub and dNumber seprately.
+
vectExpr (_, AnnApp fn arg)
= do
arg_ty' <- vectType arg_ty
res_ty' <- vectType res_ty
fn' <- vectExpr fn
arg' <- vectExpr arg
+
mkClosureApp arg_ty' res_ty' fn' arg'
where
(arg_ty, res_ty) = splitFunTy . exprType $ deAnnotate fn
vectExpr (_, AnnCase scrut bndr ty alts)
- | isAlgType scrut_ty
- = vectAlgCase scrut bndr ty alts
+ | Just (tycon, ty_args) <- splitTyConApp_maybe scrut_ty
+ , isAlgTyCon tycon
+ = vectAlgCase tycon ty_args scrut bndr ty alts
where
scrut_ty = exprType (deAnnotate scrut)
-vectExpr (_, AnnCase expr bndr ty alts)
- = panic "vectExpr: case"
-
vectExpr (_, AnnLet (AnnNonRec bndr rhs) body)
= do
- vrhs <- localV . inBind bndr $ vectPolyExpr rhs
+ vrhs <- localV . inBind bndr . liftM snd $ vectPolyExpr False rhs
(vbndr, vbody) <- vectBndrIn bndr (vectExpr body)
return $ vLet (vNonRec vbndr vrhs) vbody
(vbndrs, (vrhss, vbody)) <- vectBndrsIn bndrs
$ liftM2 (,)
(zipWithM vect_rhs bndrs rhss)
- (vectPolyExpr body)
+ (vectExpr body)
return $ vLet (vRec vbndrs vrhss) vbody
where
(bndrs, rhss) = unzip bs
vect_rhs bndr rhs = localV
. inBind bndr
- $ vectExpr rhs
+ . liftM snd
+ $ vectPolyExpr (isLoopBreaker $ idOccInfo bndr) rhs
+
+vectExpr e@(_, AnnLam bndr _)
+ | isId bndr = liftM snd $ vectFnExpr True False e
+{-
+onlyIfV (isEmptyVarSet fvs) (vectScalarLam bs $ deAnnotate body)
+ `orElseV` vectLam True fvs bs body
+ where
+ (bs,body) = collectAnnValBinders e
+-}
+
+vectExpr e = cantVectorise "Can't vectorise expression" (ppr $ deAnnotate e)
+
-vectExpr e@(fvs, AnnLam bndr _)
- | not (isId bndr) = pprPanic "vectExpr" (ppr $ deAnnotate e)
- | otherwise = vectLam fvs bs body
+-- | Vectorise an expression with an outer lambda abstraction.
+vectFnExpr
+ :: Bool -- ^ When the RHS of a binding, whether that binding should be inlined.
+ -> Bool -- ^ Whether the binding is a loop breaker.
+ -> CoreExprWithFVs -- ^ Expression to vectorise. Must have an outer `AnnLam`.
+ -> VM (Inline, VExpr)
+
+vectFnExpr inline loop_breaker e@(fvs, AnnLam bndr _)
+ | isId bndr = onlyIfV (isEmptyVarSet fvs)
+ (mark DontInline . vectScalarLam bs $ deAnnotate body)
+ `orElseV` mark inlineMe (vectLam inline loop_breaker fvs bs body)
where
(bs,body) = collectAnnValBinders e
+vectFnExpr _ _ e = mark DontInline $ vectExpr e
+
+mark :: Inline -> VM a -> VM (Inline, a)
+mark b p = do { x <- p; return (b,x) }
+
-vectLam :: VarSet -> [Var] -> CoreExprWithFVs -> VM VExpr
-vectLam fvs bs body
+-- | Vectorise a function where are the args have scalar type, that is Int, Float or Double.
+vectScalarLam
+ :: [Var] -- ^ Bound variables of function.
+ -> CoreExpr -- ^ Function body.
+ -> VM VExpr
+vectScalarLam args body
+ = do
+ scalars <- globalScalars
+ onlyIfV (all is_scalar_ty arg_tys
+ && is_scalar_ty res_ty
+ && is_scalar (extendVarSetList scalars args) body
+ && uses scalars body)
+ $ do
+ fn_var <- hoistExpr (fsLit "fn") (mkLams args body) DontInline
+ zipf <- zipScalars arg_tys res_ty
+ clo <- scalarClosure arg_tys res_ty (Var fn_var)
+ (zipf `App` Var fn_var)
+ clo_var <- hoistExpr (fsLit "clo") clo DontInline
+ lclo <- liftPD (Var clo_var)
+ return (Var clo_var, lclo)
+ where
+ arg_tys = map idType args
+ res_ty = exprType body
+
+ is_scalar_ty ty
+ | Just (tycon, []) <- splitTyConApp_maybe ty
+ = tycon == intTyCon
+ || tycon == floatTyCon
+ || tycon == doubleTyCon
+
+ | otherwise = False
+
+ is_scalar vs (Var v) = v `elemVarSet` vs
+ is_scalar _ e@(Lit _) = is_scalar_ty $ exprType e
+ is_scalar vs (App e1 e2) = is_scalar vs e1 && is_scalar vs e2
+ is_scalar _ _ = False
+
+ -- A scalar function has to actually compute something. Without the check,
+ -- we would treat (\(x :: Int) -> x) as a scalar function and lift it to
+ -- (map (\x -> x)) which is very bad. Normal lifting transforms it to
+ -- (\n# x -> x) which is what we want.
+ uses funs (Var v) = v `elemVarSet` funs
+ uses funs (App e1 e2) = uses funs e1 || uses funs e2
+ uses _ _ = False
+
+
+vectLam
+ :: Bool -- ^ When the RHS of a binding, whether that binding should be inlined.
+ -> Bool -- ^ Whether the binding is a loop breaker.
+ -> VarSet -- ^ The free variables in the body.
+ -> [Var] --
+ -> CoreExprWithFVs
+ -> VM VExpr
+
+vectLam inline loop_breaker fvs bs body
= do
tyvars <- localTyVars
(vs, vvs) <- readLEnv $ \env ->
res_ty <- vectType (exprType $ deAnnotate body)
buildClosures tyvars vvs arg_tys res_ty
- . hoistPolyVExpr tyvars
+ . hoistPolyVExpr tyvars (maybe_inline (length vs + length bs))
$ do
lc <- builtin liftingContext
(vbndrs, vbody) <- vectBndrsIn (vs ++ bs)
(vectExpr body)
- return $ vLams lc vbndrs vbody
-
+ vbody' <- break_loop lc res_ty vbody
+ return $ vLams lc vbndrs vbody'
+ where
+ maybe_inline n | inline = Inline n
+ | otherwise = DontInline
+
+ break_loop lc ty (ve, le)
+ | loop_breaker
+ = do
+ empty <- emptyPD ty
+ lty <- mkPDataType ty
+ return (ve, mkWildCase (Var lc) intPrimTy lty
+ [(DEFAULT, [], le),
+ (LitAlt (mkMachInt 0), [], empty)])
+
+ | otherwise = return (ve, le)
+
+
vectTyAppExpr :: CoreExprWithFVs -> [Type] -> VM VExpr
vectTyAppExpr (_, AnnVar v) tys = vectPolyVar v tys
-vectTyAppExpr e tys = pprPanic "vectTyAppExpr" (ppr $ deAnnotate e)
-
-type CoreAltWithFVs = AnnAlt Id VarSet
+vectTyAppExpr e tys = cantVectorise "Can't vectorise expression"
+ (ppr $ deAnnotate e `mkTyApps` tys)
-- We convert
--
--
-- to
--
--- V: let v = e in case v of _ { ... }
--- L: let v = e in case v `cast` ... of _ { ... }
+-- V: let v' = e in case v' of _ { ... }
+-- L: let v' = e in case v' `cast` ... of _ { ... }
--
-- When lifting, we have to do it this way because v must have the type
--- [:V(T):] but the scrutinee must be cast to the representation type.
---
+-- [:V(T):] but the scrutinee must be cast to the representation type. We also
+-- have to handle the case where v is a wild var correctly.
+--
-- FIXME: this is too lazy
-vectAlgCase scrut bndr ty [(DEFAULT, [], body)]
+vectAlgCase :: TyCon -> [Type] -> CoreExprWithFVs -> Var -> Type
+ -> [(AltCon, [Var], CoreExprWithFVs)]
+ -> VM VExpr
+vectAlgCase _tycon _ty_args scrut bndr ty [(DEFAULT, [], body)]
= do
- vscrut <- vectExpr scrut
- vty <- vectType ty
- lty <- mkPArrayType vty
+ vscrut <- vectExpr scrut
+ (vty, lty) <- vectAndLiftType ty
(vbndr, vbody) <- vectBndrIn bndr (vectExpr body)
return $ vCaseDEFAULT vscrut vbndr vty lty vbody
-vectAlgCase scrut bndr ty [(DataAlt dc, bndrs, body)]
+vectAlgCase _tycon _ty_args scrut bndr ty [(DataAlt _, [], body)]
= do
- vty <- vectType ty
- lty <- mkPArrayType vty
- vexpr <- vectExpr scrut
- (vbndr, (vbndrs, vbody)) <- vectBndrIn bndr
- . vectBndrsIn bndrs
- $ vectExpr body
+ vscrut <- vectExpr scrut
+ (vty, lty) <- vectAndLiftType ty
+ (vbndr, vbody) <- vectBndrIn bndr (vectExpr body)
+ return $ vCaseDEFAULT vscrut vbndr vty lty vbody
- (vscrut, arr_tc, arg_tys) <- mkVScrut (vVar vbndr)
+vectAlgCase _tycon _ty_args scrut bndr ty [(DataAlt dc, bndrs, body)]
+ = do
+ (vty, lty) <- vectAndLiftType ty
+ vexpr <- vectExpr scrut
+ (vbndr, (vbndrs, (vect_body, lift_body)))
+ <- vect_scrut_bndr
+ . vectBndrsIn bndrs
+ $ vectExpr body
+ let (vect_bndrs, lift_bndrs) = unzip vbndrs
+ (vscrut, lscrut, pdata_tc, _arg_tys) <- mkVScrut (vVar vbndr)
vect_dc <- maybeV (lookupDataCon dc)
- let [arr_dc] = tyConDataCons arr_tc
- let shape_tys = take (dataConRepArity arr_dc - length bndrs)
- (dataConRepArgTys arr_dc)
- shape_bndrs <- mapM (newLocalVar FSLIT("s")) shape_tys
+ let [pdata_dc] = tyConDataCons pdata_tc
+
+ let vcase = mk_wild_case vscrut vty vect_dc vect_bndrs vect_body
+ lcase = mk_wild_case lscrut lty pdata_dc lift_bndrs lift_body
+
+ return $ vLet (vNonRec vbndr vexpr) (vcase, lcase)
+ where
+ vect_scrut_bndr | isDeadBinder bndr = vectBndrNewIn bndr (fsLit "scrut")
+ | otherwise = vectBndrIn bndr
+
+ mk_wild_case expr ty dc bndrs body
+ = mkWildCase expr (exprType expr) ty [(DataAlt dc, bndrs, body)]
+
+vectAlgCase tycon _ty_args scrut bndr ty alts
+ = do
+ vect_tc <- maybeV (lookupTyCon tycon)
+ (vty, lty) <- vectAndLiftType ty
+
+ let arity = length (tyConDataCons vect_tc)
+ sel_ty <- builtin (selTy arity)
+ sel_bndr <- newLocalVar (fsLit "sel") sel_ty
+ let sel = Var sel_bndr
+
+ (vbndr, valts) <- vect_scrut_bndr
+ $ mapM (proc_alt arity sel vty lty) alts'
+ let (vect_dcs, vect_bndrss, lift_bndrss, vbodies) = unzip4 valts
+
+ vexpr <- vectExpr scrut
+ (vect_scrut, lift_scrut, pdata_tc, _arg_tys) <- mkVScrut (vVar vbndr)
+ let [pdata_dc] = tyConDataCons pdata_tc
+
+ let (vect_bodies, lift_bodies) = unzip vbodies
+
+ vdummy <- newDummyVar (exprType vect_scrut)
+ ldummy <- newDummyVar (exprType lift_scrut)
+ let vect_case = Case vect_scrut vdummy vty
+ (zipWith3 mk_vect_alt vect_dcs vect_bndrss vect_bodies)
+
+ lc <- builtin liftingContext
+ lbody <- combinePD vty (Var lc) sel lift_bodies
+ let lift_case = Case lift_scrut ldummy lty
+ [(DataAlt pdata_dc, sel_bndr : concat lift_bndrss,
+ lbody)]
+
return . vLet (vNonRec vbndr vexpr)
- $ vCaseProd vscrut vty lty vect_dc arr_dc shape_bndrs vbndrs vbody
+ $ (vect_case, lift_case)
+ where
+ vect_scrut_bndr | isDeadBinder bndr = vectBndrNewIn bndr (fsLit "scrut")
+ | otherwise = vectBndrIn bndr
+
+ alts' = sortBy (\(alt1, _, _) (alt2, _, _) -> cmp alt1 alt2) alts
+
+ cmp (DataAlt dc1) (DataAlt dc2) = dataConTag dc1 `compare` dataConTag dc2
+ cmp DEFAULT DEFAULT = EQ
+ cmp DEFAULT _ = LT
+ cmp _ DEFAULT = GT
+ cmp _ _ = panic "vectAlgCase/cmp"
+
+ proc_alt arity sel _ lty (DataAlt dc, bndrs, body)
+ = do
+ vect_dc <- maybeV (lookupDataCon dc)
+ let ntag = dataConTagZ vect_dc
+ tag = mkDataConTag vect_dc
+ fvs = freeVarsOf body `delVarSetList` bndrs
+
+ sel_tags <- liftM (`App` sel) (builtin (selTags arity))
+ lc <- builtin liftingContext
+ elems <- builtin (selElements arity ntag)
+
+ (vbndrs, vbody)
+ <- vectBndrsIn bndrs
+ . localV
+ $ do
+ binds <- mapM (pack_var (Var lc) sel_tags tag)
+ . filter isLocalId
+ $ varSetElems fvs
+ (ve, le) <- vectExpr body
+ return (ve, Case (elems `App` sel) lc lty
+ [(DEFAULT, [], (mkLets (concat binds) le))])
+ -- empty <- emptyPD vty
+ -- return (ve, Case (elems `App` sel) lc lty
+ -- [(DEFAULT, [], Let (NonRec flags_var flags_expr)
+ -- $ mkLets (concat binds) le),
+ -- (LitAlt (mkMachInt 0), [], empty)])
+ let (vect_bndrs, lift_bndrs) = unzip vbndrs
+ return (vect_dc, vect_bndrs, lift_bndrs, vbody)
+
+ proc_alt _ _ _ _ _ = panic "vectAlgCase/proc_alt"
+
+ mk_vect_alt vect_dc bndrs body = (DataAlt vect_dc, bndrs, body)
+
+ pack_var len tags t v
+ = do
+ r <- lookupVar v
+ case r of
+ Local (vv, lv) ->
+ do
+ lv' <- cloneVar lv
+ expr <- packByTagPD (idType vv) (Var lv) len tags t
+ updLEnv (\env -> env { local_vars = extendVarEnv
+ (local_vars env) v (vv, lv') })
+ return [(NonRec lv' expr)]
+
+ _ -> return []
+