-module VectType ( vectTyCon, vectType, vectTypeEnv,
- PAInstance, painstInstance, buildPADict )
+{-# OPTIONS -fno-warn-missing-signatures #-}
+
+module VectType (
+ vectTyCon,
+ vectAndLiftType,
+ vectType,
+ vectTypeEnv,
+ buildPADict,
+ fromVect
+)
where
-
-#include "HsVersions.h"
-
-import VectMonad
import VectUtils
-
-import HscTypes ( TypeEnv, extendTypeEnvList, typeEnvTyCons )
+import Vectorise.Env
+import Vectorise.Convert
+import Vectorise.Vect
+import Vectorise.Monad
+import Vectorise.Builtins
+import Vectorise.Type.Type
+import Vectorise.Type.TyConDecl
+import Vectorise.Type.Classify
+import Vectorise.Type.PADict
+import Vectorise.Type.PData
+import Vectorise.Type.PRepr
+import Vectorise.Type.Repr
+import Vectorise.Utils.Closure
+import Vectorise.Utils.Hoisting
+
+import HscTypes
import CoreSyn
import CoreUtils
+import CoreUnfold
import DataCon
import TyCon
import Type
-import TypeRep
-import Coercion
-import FamInstEnv ( FamInst, mkLocalFamInst )
-import InstEnv ( Instance, mkLocalInstance, instanceDFunId )
+import FamInstEnv
import OccName
+import Id
import MkId
-import BasicTypes ( StrictnessMark(..), OverlapFlag(..), boolToRecFlag )
-import Var ( Var )
-import Id ( mkWildId )
-import Name ( Name, getOccName )
+import Var
import NameEnv
-import TysWiredIn ( intTy, intDataCon )
-import TysPrim ( intPrimTy )
import Unique
import UniqFM
-import UniqSet
-import Digraph ( SCC(..), stronglyConnComp )
-
+import Util
import Outputable
-
-import Control.Monad ( liftM, liftM2, zipWithM, zipWithM_ )
-import Data.List ( inits, tails )
-
--- ----------------------------------------------------------------------------
--- Types
-
-vectTyCon :: TyCon -> VM TyCon
-vectTyCon tc
- | isFunTyCon tc = builtin closureTyCon
- | isBoxedTupleTyCon tc = return tc
- | isUnLiftedTyCon tc = return tc
- | otherwise = do
- r <- lookupTyCon tc
- case r of
- Just tc' -> return tc'
-
- -- FIXME: just for now
- Nothing -> pprTrace "ccTyCon:" (ppr tc) $ return tc
-
-vectType :: Type -> VM Type
-vectType ty | Just ty' <- coreView ty = vectType ty'
-vectType (TyVarTy tv) = return $ TyVarTy tv
-vectType (AppTy ty1 ty2) = liftM2 AppTy (vectType ty1) (vectType ty2)
-vectType (TyConApp tc tys) = liftM2 TyConApp (vectTyCon tc) (mapM vectType tys)
-vectType (FunTy ty1 ty2) = liftM2 TyConApp (builtin closureTyCon)
- (mapM vectType [ty1,ty2])
-vectType ty@(ForAllTy _ _)
- = do
- mdicts <- mapM paDictArgType tyvars
- mono_ty' <- vectType mono_ty
- return $ tyvars `mkForAllTys` ([dict | Just dict <- mdicts] `mkFunTys` mono_ty')
- where
- (tyvars, mono_ty) = splitForAllTys ty
-
-vectType ty = pprPanic "vectType:" (ppr ty)
-
--- ----------------------------------------------------------------------------
--- Type definitions
-
-type TyConGroup = ([TyCon], UniqSet TyCon)
-
-data PAInstance = PAInstance {
- painstInstance :: Instance
- , painstVectTyCon :: TyCon
- , painstArrTyCon :: TyCon
- }
-
-vectTypeEnv :: TypeEnv -> VM (TypeEnv, [FamInst], [PAInstance])
+import FastString
+import MonadUtils
+import Control.Monad
+import Data.List
+
+debug = False
+dtrace s x = if debug then pprTrace "VectType" s x else x
+
+
+-- | Vectorise a type environment.
+-- The type environment contains all the type things defined in a module.
+vectTypeEnv
+ :: TypeEnv
+ -> VM ( TypeEnv -- Vectorised type environment.
+ , [FamInst] -- New type family instances.
+ , [(Var, CoreExpr)]) -- New top level bindings.
+
vectTypeEnv env
- = do
+ = dtrace (ppr env)
+ $ do
cs <- readGEnv $ mk_map . global_tycons
+
+ -- Split the list of TyCons into the ones we have to vectorise vs the
+ -- ones we can pass through unchanged. We also pass through algebraic
+ -- types that use non Haskell98 features, as we don't handle those.
let (conv_tcs, keep_tcs) = classifyTyCons cs groups
keep_dcs = concatMap tyConDataCons keep_tcs
+
zipWithM_ defTyCon keep_tcs keep_tcs
zipWithM_ defDataCon keep_dcs keep_dcs
+
new_tcs <- vectTyConDecls conv_tcs
let orig_tcs = keep_tcs ++ conv_tcs
- vect_tcs = keep_tcs ++ new_tcs
- parr_tcs <- zipWithM buildPArrayTyCon orig_tcs vect_tcs
- pa_insts <- zipWithM buildPAInstance vect_tcs parr_tcs
-
- let all_new_tcs = new_tcs ++ parr_tcs
+ -- We don't need to make new representation types for dictionary
+ -- constructors. The constructors are always fully applied, and we don't
+ -- need to lift them to arrays as a dictionary of a particular type
+ -- always has the same value.
+ let vect_tcs = filter (not . isClassTyCon)
+ $ keep_tcs ++ new_tcs
+
+ (_, binds, inst_tcs) <- fixV $ \ ~(dfuns', _, _) ->
+ do
+ defTyConPAs (zipLazy vect_tcs dfuns')
+ reprs <- mapM tyConRepr vect_tcs
+ repr_tcs <- zipWith3M buildPReprTyCon orig_tcs vect_tcs reprs
+ pdata_tcs <- zipWith3M buildPDataTyCon orig_tcs vect_tcs reprs
+
+ dfuns <- sequence
+ $ zipWith5 buildTyConBindings
+ orig_tcs
+ vect_tcs
+ repr_tcs
+ pdata_tcs
+ reprs
+
+ binds <- takeHoisted
+ return (dfuns, binds, repr_tcs ++ pdata_tcs)
+
+ let all_new_tcs = new_tcs ++ inst_tcs
let new_env = extendTypeEnvList env
(map ATyCon all_new_tcs
++ [ADataCon dc | tc <- all_new_tcs
, dc <- tyConDataCons tc])
- return (new_env, map mkLocalFamInst parr_tcs, pa_insts)
+ return (new_env, map mkLocalFamInst inst_tcs, binds)
where
tycons = typeEnvTyCons env
groups = tyConGroups tycons
mk_map env = listToUFM_Directly [(u, getUnique n /= u) | (u,n) <- nameEnvUniqueElts env]
- keep_tc tc = let dcs = tyConDataCons tc
- in
- defTyCon tc tc >> zipWithM_ defDataCon dcs dcs
-vectTyConDecls :: [TyCon] -> VM [TyCon]
-vectTyConDecls tcs = fixV $ \tcs' ->
- do
- mapM_ (uncurry defTyCon) (lazy_zip tcs tcs')
- mapM vectTyConDecl tcs
- where
- lazy_zip [] _ = []
- lazy_zip (x:xs) ~(y:ys) = (x,y) : lazy_zip xs ys
-
-vectTyConDecl :: TyCon -> VM TyCon
-vectTyConDecl tc
- = do
- name' <- cloneName mkVectTyConOcc name
- rhs' <- vectAlgTyConRhs (algTyConRhs tc)
-
- return $ mkAlgTyCon name'
- kind
- tyvars
- [] -- no stupid theta
- rhs'
- [] -- no selector ids
- NoParentTyCon -- FIXME
- rec_flag -- FIXME: is this ok?
- False -- FIXME: no generics
- False -- not GADT syntax
- where
- name = tyConName tc
- kind = tyConKind tc
- tyvars = tyConTyVars tc
- rec_flag = boolToRecFlag (isRecursiveTyCon tc)
-
-vectAlgTyConRhs :: AlgTyConRhs -> VM AlgTyConRhs
-vectAlgTyConRhs (DataTyCon { data_cons = data_cons
- , is_enum = is_enum
- })
- = do
- data_cons' <- mapM vectDataCon data_cons
- zipWithM_ defDataCon data_cons data_cons'
- return $ DataTyCon { data_cons = data_cons'
- , is_enum = is_enum
- }
-
-vectDataCon :: DataCon -> VM DataCon
-vectDataCon dc
- | not . null $ dataConExTyVars dc = pprPanic "vectDataCon: existentials" (ppr dc)
- | not . null $ dataConEqSpec dc = pprPanic "vectDataCon: eq spec" (ppr dc)
- | otherwise
- = do
- name' <- cloneName mkVectDataConOcc name
- tycon' <- vectTyCon tycon
- arg_tys <- mapM vectType rep_arg_tys
- wrk_name <- cloneName mkDataConWorkerOcc name'
-
- let ids = mkDataConIds (panic "vectDataCon: wrapper id")
- wrk_name
- data_con
- data_con = mkDataCon name'
- False -- not infix
- (map (const NotMarkedStrict) arg_tys)
- [] -- no labelled fields
- univ_tvs
- [] -- no existential tvs for now
- [] -- no eq spec for now
- [] -- no theta
- arg_tys
- tycon'
- [] -- no stupid theta
- ids
- return data_con
- where
- name = dataConName dc
- univ_tvs = dataConUnivTyVars dc
- rep_arg_tys = dataConRepArgTys dc
- tycon = dataConTyCon dc
-
-buildPArrayTyCon :: TyCon -> TyCon -> VM TyCon
-buildPArrayTyCon orig_tc vect_tc = fixV $ \repr_tc ->
- do
- name' <- cloneName mkPArrayTyConOcc orig_name
- parent <- buildPArrayParentInfo orig_name vect_tc repr_tc
- rhs <- buildPArrayTyConRhs orig_name vect_tc repr_tc
-
- return $ mkAlgTyCon name'
- kind
- tyvars
- [] -- no stupid theta
- rhs
- [] -- no selector ids
- parent
- rec_flag -- FIXME: is this ok?
- False -- FIXME: no generics
- False -- not GADT syntax
- where
- orig_name = tyConName orig_tc
- name = tyConName vect_tc
- kind = tyConKind vect_tc
- tyvars = tyConTyVars vect_tc
- rec_flag = boolToRecFlag (isRecursiveTyCon vect_tc)
-
-
-buildPArrayParentInfo :: Name -> TyCon -> TyCon -> VM TyConParent
-buildPArrayParentInfo orig_name vect_tc repr_tc
- = do
- parray_tc <- builtin parrayTyCon
- co_name <- cloneName mkInstTyCoOcc (tyConName repr_tc)
-
- let inst_tys = [mkTyConApp vect_tc (map mkTyVarTy tyvars)]
-
- return . FamilyTyCon parray_tc inst_tys
- $ mkFamInstCoercion co_name
- tyvars
- parray_tc
- inst_tys
- repr_tc
- where
- tyvars = tyConTyVars vect_tc
-
-buildPArrayTyConRhs :: Name -> TyCon -> TyCon -> VM AlgTyConRhs
-buildPArrayTyConRhs orig_name vect_tc repr_tc
- = do
- data_con <- buildPArrayDataCon orig_name vect_tc repr_tc
- return $ DataTyCon { data_cons = [data_con], is_enum = False }
-
-buildPArrayDataCon :: Name -> TyCon -> TyCon -> VM DataCon
-buildPArrayDataCon orig_name vect_tc repr_tc
- = do
- dc_name <- cloneName mkPArrayDataConOcc orig_name
- shape_ty <- mkPArrayType intTy -- FIXME: we want to unbox this!
- repr_tys <- mapM mkPArrayType types
- wrk_name <- cloneName mkDataConWorkerOcc dc_name
- wrp_name <- cloneName mkDataConWrapperOcc dc_name
-
- let ids = mkDataConIds wrp_name wrk_name data_con
- data_con = mkDataCon dc_name
- False
- (MarkedStrict : map (const NotMarkedStrict) repr_tys)
- []
- (tyConTyVars vect_tc)
- []
- []
- []
- (shape_ty : repr_tys)
- repr_tc
- []
- ids
-
- return data_con
- where
- types = [ty | dc <- tyConDataCons vect_tc
- , ty <- dataConRepArgTys dc]
-
-buildPAInstance :: TyCon -> TyCon -> VM PAInstance
-buildPAInstance vect_tc arr_tc
- = do
- pa <- builtin paClass
- let inst_ty = mkForAllTys tvs
- . (mkFunTys $ mkPredTys [ClassP pa [ty] | ty <- arg_tys])
- $ mkPredTy (ClassP pa [mkTyConApp vect_tc arg_tys])
-
- dfun <- newExportedVar (mkPADFunOcc $ getOccName vect_tc) inst_ty
-
- return $ PAInstance {
- painstInstance = mkLocalInstance dfun NoOverlap
- , painstVectTyCon = vect_tc
- , painstArrTyCon = arr_tc
- }
- where
- tvs = tyConTyVars arr_tc
- arg_tys = mkTyVarTys tvs
-
-buildPADict :: PAInstance -> VM [(Var, CoreExpr)]
-buildPADict (PAInstance {
- painstInstance = inst
- , painstVectTyCon = vect_tc
- , painstArrTyCon = arr_tc })
- = localV . abstractOverTyVars (tyConTyVars arr_tc) $ \abstract ->
- do
- meth_binds <- mapM mk_method paMethods
- let meth_exprs = map (Var . fst) meth_binds
-
- pa_dc <- builtin paDictDataCon
- let dict = mkConApp pa_dc (Type (mkTyConApp vect_tc arg_tys) : meth_exprs)
- body = Let (Rec meth_binds) dict
- return [(instanceDFunId inst, abstract body)]
- where
- tvs = tyConTyVars arr_tc
- arg_tys = mkTyVarTys tvs
-
- mk_method (name, build)
- = localV
- $ do
- body <- build vect_tc arr_tc
- var <- newLocalVar name (exprType body)
- return (var, mkInlineMe body)
-
-paMethods = [(FSLIT("lengthPA"), buildLengthPA),
- (FSLIT("replicatePA"), buildReplicatePA)]
-
-buildLengthPA :: TyCon -> TyCon -> VM CoreExpr
-buildLengthPA vect_tc arr_tc
- = do
- parr_ty <- mkPArrayType (mkTyConApp vect_tc arg_tys)
- arg <- newLocalVar FSLIT("xs") parr_ty
- let scrut = unwrapFamInstScrut arr_tc arg_tys (Var arg)
- scrut_ty = exprType scrut
- shape <- newLocalVar FSLIT("sel") shape_ty
- body <- lengthPA (Var shape)
- wilds <- mapM newDummyVar repr_tys
- return . Lam arg
- $ Case scrut (mkWildId scrut_ty) intPrimTy
- [(DataAlt repr_dc, shape : wilds, body)]
- where
- arg_tys = mkTyVarTys $ tyConTyVars arr_tc
- [repr_dc] = tyConDataCons arr_tc
- shape_ty : repr_tys = dataConRepArgTys repr_dc
-
--- data T = C0 t1 ... tm
--- ...
--- Ck u1 ... un
---
--- data [:T:] = A ![:Int:] [:t1:] ... [:un:]
---
--- replicatePA :: Int# -> T -> [:T:]
--- replicatePA n# t
--- = let c = case t of
--- C0 _ ... _ -> 0
--- ...
--- Ck _ ... _ -> k
---
--- xs1 = case t of
--- C0 x1 _ ... _ -> replicatePA @t1 n# x1
--- _ -> emptyPA @t1
---
--- ...
---
--- ysn = case t of
--- Ck _ ... _ yn -> replicatePA @un n# yn
--- _ -> emptyPA @un
--- in
--- A (replicatePA @Int n# c) xs1 ... ysn
---
---
-
-buildReplicatePA :: TyCon -> TyCon -> VM CoreExpr
-buildReplicatePA vect_tc arr_tc
- = do
- len_var <- newLocalVar FSLIT("n") intPrimTy
- val_var <- newLocalVar FSLIT("x") val_ty
-
- let len = Var len_var
- val = Var val_var
-
- shape <- replicatePA len (ctr_num val)
- reprs <- liftM concat $ mapM (mk_comp_arrs len val) vect_dcs
-
- return . mkLams [len_var, val_var]
- . wrapFamInstBody arr_tc arg_tys
- $ mkConApp arr_dc (map Type arg_tys ++ (shape : reprs))
- where
- arg_tys = mkTyVarTys (tyConTyVars arr_tc)
- val_ty = mkTyConApp vect_tc arg_tys
- wild = mkWildId val_ty
- vect_dcs = tyConDataCons vect_tc
- [arr_dc] = tyConDataCons arr_tc
+buildTyConBindings :: TyCon -> TyCon -> TyCon -> TyCon -> SumRepr -> VM Var
+buildTyConBindings orig_tc vect_tc prepr_tc pdata_tc repr
+ = do vectDataConWorkers orig_tc vect_tc pdata_tc
+ buildPADict vect_tc prepr_tc pdata_tc repr
- ctr_num val = Case val wild intTy (zipWith ctr_num_alt vect_dcs [0..])
- ctr_num_alt dc i = (DataAlt dc, map mkWildId (dataConRepArgTys dc),
- mkConApp intDataCon [mkIntLitInt i])
+vectDataConWorkers :: TyCon -> TyCon -> TyCon -> VM ()
+vectDataConWorkers orig_tc vect_tc arr_tc
+ = do bs <- sequence
+ . zipWith3 def_worker (tyConDataCons orig_tc) rep_tys
+ $ zipWith4 mk_data_con (tyConDataCons vect_tc)
+ rep_tys
+ (inits rep_tys)
+ (tail $ tails rep_tys)
+ mapM_ (uncurry hoistBinding) bs
+ where
+ tyvars = tyConTyVars vect_tc
+ var_tys = mkTyVarTys tyvars
+ ty_args = map Type var_tys
+ res_ty = mkTyConApp vect_tc var_tys
- mk_comp_arrs len val dc = let tys = dataConRepArgTys dc
- wilds = map mkWildId tys
- in
- sequence (zipWith3 (mk_comp_arr len val dc)
- tys (inits wilds) (tails wilds))
+ cons = tyConDataCons vect_tc
+ arity = length cons
+ [arr_dc] = tyConDataCons arr_tc
- mk_comp_arr len val dc ty pre (_:post)
- = do
- var <- newLocalVar FSLIT("x") ty
- rep <- replicatePA len (Var var)
- empty <- emptyPA ty
- arr_ty <- mkPArrayType ty
-
- return $ Case val wild arr_ty
- [(DEFAULT, [], empty), (DataAlt dc, pre ++ (var : post), rep)]
-
--- | Split the given tycons into two sets depending on whether they have to be
--- converted (first list) or not (second list). The first argument contains
--- information about the conversion status of external tycons:
---
--- * tycons which have converted versions are mapped to True
--- * tycons which are not changed by vectorisation are mapped to False
--- * tycons which can't be converted are not elements of the map
---
-classifyTyCons :: UniqFM Bool -> [TyConGroup] -> ([TyCon], [TyCon])
-classifyTyCons = classify [] []
- where
- classify conv keep cs [] = (conv, keep)
- classify conv keep cs ((tcs, ds) : rs)
- | can_convert && must_convert
- = classify (tcs ++ conv) keep (cs `addListToUFM` [(tc,True) | tc <- tcs]) rs
- | can_convert
- = classify conv (tcs ++ keep) (cs `addListToUFM` [(tc,False) | tc <- tcs]) rs
- | otherwise
- = classify conv keep cs rs
- where
- refs = ds `delListFromUniqSet` tcs
+ rep_tys = map dataConRepArgTys $ tyConDataCons vect_tc
- can_convert = isNullUFM (refs `minusUFM` cs) && all convertable tcs
- must_convert = foldUFM (||) False (intersectUFM_C const cs refs)
- convertable tc = isDataTyCon tc && all isVanillaDataCon (tyConDataCons tc)
-
--- | Compute mutually recursive groups of tycons in topological order
---
-tyConGroups :: [TyCon] -> [TyConGroup]
-tyConGroups tcs = map mk_grp (stronglyConnComp edges)
- where
- edges = [((tc, ds), tc, uniqSetToList ds) | tc <- tcs
- , let ds = tyConsOfTyCon tc]
+ mk_data_con con tys pre post
+ = liftM2 (,) (vect_data_con con)
+ (lift_data_con tys pre post (mkDataConTag con))
- mk_grp (AcyclicSCC (tc, ds)) = ([tc], ds)
- mk_grp (CyclicSCC els) = (tcs, unionManyUniqSets dss)
- where
- (tcs, dss) = unzip els
+ sel_replicate len tag
+ | arity > 1 = do
+ rep <- builtin (selReplicate arity)
+ return [rep `mkApps` [len, tag]]
-tyConsOfTyCon :: TyCon -> UniqSet TyCon
-tyConsOfTyCon
- = tyConsOfTypes . concatMap dataConRepArgTys . tyConDataCons
+ | otherwise = return []
-tyConsOfType :: Type -> UniqSet TyCon
-tyConsOfType ty
- | Just ty' <- coreView ty = tyConsOfType ty'
-tyConsOfType (TyVarTy v) = emptyUniqSet
-tyConsOfType (TyConApp tc tys) = extend (tyConsOfTypes tys)
- where
- extend | isUnLiftedTyCon tc
- || isTupleTyCon tc = id
+ vect_data_con con = return $ mkConApp con ty_args
+ lift_data_con tys pre_tys post_tys tag
+ = do
+ len <- builtin liftingContext
+ args <- mapM (newLocalVar (fsLit "xs"))
+ =<< mapM mkPDataType tys
+
+ sel <- sel_replicate (Var len) tag
- | otherwise = (`addOneToUniqSet` tc)
+ pre <- mapM emptyPD (concat pre_tys)
+ post <- mapM emptyPD (concat post_tys)
-tyConsOfType (AppTy a b) = tyConsOfType a `unionUniqSets` tyConsOfType b
-tyConsOfType (FunTy a b) = (tyConsOfType a `unionUniqSets` tyConsOfType b)
- `addOneToUniqSet` funTyCon
-tyConsOfType (ForAllTy _ ty) = tyConsOfType ty
-tyConsOfType other = pprPanic "ClosureConv.tyConsOfType" $ ppr other
+ return . mkLams (len : args)
+ . wrapFamInstBody arr_tc var_tys
+ . mkConApp arr_dc
+ $ ty_args ++ sel ++ pre ++ map Var args ++ post
-tyConsOfTypes :: [Type] -> UniqSet TyCon
-tyConsOfTypes = unionManyUniqSets . map tyConsOfType
+ def_worker data_con arg_tys mk_body
+ = do
+ arity <- polyArity tyvars
+ body <- closedV
+ . inBind orig_worker
+ . polyAbstract tyvars $ \args ->
+ liftM (mkLams (tyvars ++ args) . vectorised)
+ $ buildClosures tyvars [] arg_tys res_ty mk_body
+
+ raw_worker <- cloneId mkVectOcc orig_worker (exprType body)
+ let vect_worker = raw_worker `setIdUnfolding`
+ mkInlineRule body (Just arity)
+ defGlobalVar orig_worker vect_worker
+ return (vect_worker, body)
+ where
+ orig_worker = dataConWorkId data_con
projects / ghc-hetmet.git / blobdiff