X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=ghc%2Fcompiler%2FdeSugar%2FDsCCall.lhs;h=052a9a253f1c13d3f7d3aa3549f43877b09aa250;hb=940841711bb0c30326a5173d8107c2792919641c;hp=7752c427f0c8cbbbbcb3c3e2c9c0cd8884b5b9c3;hpb=cca2c69fc0af2b24aad230066a087a98fded0fae;p=ghc-hetmet.git diff --git a/ghc/compiler/deSugar/DsCCall.lhs b/ghc/compiler/deSugar/DsCCall.lhs index 7752c42..052a9a2 100644 --- a/ghc/compiler/deSugar/DsCCall.lhs +++ b/ghc/compiler/deSugar/DsCCall.lhs @@ -9,9 +9,7 @@ module DsCCall , mkCCall , unboxArg , boxResult - , wrapUnboxedValue - , can'tSeeDataConsPanic - + , resultWrapper ) where #include "HsVersions.h" @@ -21,26 +19,30 @@ import CoreSyn import DsMonad import DsUtils -import TcHsSyn ( maybeBoxedPrimType ) -import CoreUtils ( exprType ) +import CoreUtils ( exprType, mkCoerce ) import Id ( Id, mkWildId ) -import MkId ( mkCCallOpId ) +import MkId ( mkCCallOpId, realWorldPrimId ) import Maybes ( maybeToBool ) -import PrelInfo ( packStringForCId ) import PrimOp ( PrimOp(..), CCall(..), CCallTarget(..) ) -import DataCon ( DataCon, splitProductType_maybe ) +import DataCon ( DataCon, splitProductType_maybe, dataConSourceArity, dataConWrapId ) import CallConv import Type ( isUnLiftedType, splitAlgTyConApp_maybe, mkFunTys, - splitTyConApp_maybe, tyVarsOfType, mkForAllTys, Type + splitTyConApp_maybe, tyVarsOfType, mkForAllTys, + isNewType, repType, isUnLiftedType, mkFunTy, + Type ) -import PprType ( {- instance Outputable Type -} ) import TysPrim ( byteArrayPrimTy, realWorldStatePrimTy, - byteArrayPrimTyCon, mutableByteArrayPrimTyCon ) + byteArrayPrimTyCon, mutableByteArrayPrimTyCon, intPrimTy + ) import TysWiredIn ( unitDataConId, stringTy, unboxedPairDataCon, - mkUnboxedTupleTy, unboxedTupleCon + mkUnboxedTupleTy, unboxedTupleCon, + boolTy, trueDataCon, falseDataCon, trueDataConId, falseDataConId, + unitTy ) -import Unique ( Unique ) +import Literal ( mkMachInt ) +import CStrings ( CLabelString ) +import Unique ( Unique, Uniquable(..), ioTyConKey ) import VarSet ( varSetElems ) import Outputable \end{code} @@ -81,26 +83,22 @@ follows: \end{verbatim} \begin{code} -dsCCall :: FAST_STRING -- C routine to invoke +dsCCall :: CLabelString -- C routine to invoke -> [CoreExpr] -- Arguments (desugared) -> Bool -- True <=> might cause Haskell GC -> Bool -- True <=> really a "_casm_" - -> Type -- Type of the result (a boxed-prim IO type) + -> Type -- Type of the result: IO t -> DsM CoreExpr dsCCall lbl args may_gc is_asm result_ty - = newSysLocalDs realWorldStatePrimTy `thenDs` \ old_s -> - - mapAndUnzipDs unboxArg args `thenDs` \ (unboxed_args, arg_wrappers) -> - boxResult result_ty `thenDs` \ (final_result_ty, res_wrapper) -> + = mapAndUnzipDs unboxArg args `thenDs` \ (unboxed_args, arg_wrappers) -> + boxResult result_ty `thenDs` \ (ccall_result_ty, res_wrapper) -> getUniqueDs `thenDs` \ uniq -> let - val_args = Var old_s : unboxed_args the_ccall = CCall (StaticTarget lbl) is_asm may_gc cCallConv - the_prim_app = mkCCall uniq the_ccall val_args final_result_ty - the_body = foldr ($) (res_wrapper the_prim_app) arg_wrappers + the_prim_app = mkCCall uniq the_ccall unboxed_args ccall_result_ty in - returnDs (Lam old_s the_body) + returnDs (foldr ($) (res_wrapper the_prim_app) arg_wrappers) mkCCall :: Unique -> CCall -> [CoreExpr] -- Args @@ -130,32 +128,42 @@ unboxArg :: CoreExpr -- The supplied argument -> DsM (CoreExpr, -- To pass as the actual argument CoreExpr -> CoreExpr -- Wrapper to unbox the arg ) -unboxArg arg +-- Example: if the arg is e::Int, unboxArg will return +-- (x#::Int#, \W. case x of I# x# -> W) +-- where W is a CoreExpr that probably mentions x# - -- Primitive types - -- ADR Question: can this ever be used? None of the PrimTypes are - -- instances of the CCallable class. - -- - -- SOF response: - -- Oh yes they are, I've just added them :-) Having _ccall_ and _casm_ - -- that accept unboxed arguments is a Good Thing if you have a stub generator - -- which generates the boiler-plate box-unbox code for you, i.e., it may help - -- us nuke this very module :-) - -- +unboxArg arg + -- Unlifted types: nothing to unbox | isUnLiftedType arg_ty = returnDs (arg, \body -> body) - -- Strings - | arg_ty == stringTy - -- ToDo (ADR): - allow synonyms of Strings too? - = newSysLocalDs byteArrayPrimTy `thenDs` \ prim_arg -> + -- Newtypes + | isNewType arg_ty + = unboxArg (mkCoerce (repType arg_ty) arg_ty arg) + + -- Booleans + | arg_ty == boolTy + = newSysLocalDs intPrimTy `thenDs` \ prim_arg -> returnDs (Var prim_arg, - \body -> Case (App (Var packStringForCId) arg) - prim_arg [(DEFAULT,[],body)]) + \ body -> Case (Case arg (mkWildId arg_ty) + [(DataAlt falseDataCon,[],mkIntLit 0), + (DataAlt trueDataCon, [],mkIntLit 1)]) + prim_arg + [(DEFAULT,[],body)]) + + -- Data types with a single constructor, which has a single, primitive-typed arg + -- This deals with Int, Float etc + | is_product_type && data_con_arity == 1 + = ASSERT(isUnLiftedType data_con_arg_ty1 ) -- Typechecker ensures this + newSysLocalDs arg_ty `thenDs` \ case_bndr -> + newSysLocalDs data_con_arg_ty1 `thenDs` \ prim_arg -> + returnDs (Var prim_arg, + \ body -> Case arg case_bndr [(DataAlt data_con,[prim_arg],body)] + ) -- Byte-arrays, both mutable and otherwise; hack warning | is_product_type && - length data_con_arg_tys == 3 && + data_con_arity == 3 && maybeToBool maybe_arg3_tycon && (arg3_tycon == byteArrayPrimTyCon || arg3_tycon == mutableByteArrayPrimTyCon) @@ -166,124 +174,134 @@ unboxArg arg \ body -> Case arg case_bndr [(DataAlt data_con,vars,body)] ) - -- Data types with a single constructor, which has a single, primitive-typed arg - | maybeToBool maybe_boxed_prim_arg_ty - = newSysLocalDs arg_ty `thenDs` \ case_bndr -> - newSysLocalDs the_prim_arg_ty `thenDs` \ prim_arg -> - returnDs (Var prim_arg, - \ body -> Case arg case_bndr [(DataAlt box_data_con,[prim_arg],body)] - ) - | otherwise = getSrcLocDs `thenDs` \ l -> pprPanic "unboxArg: " (ppr l <+> ppr arg_ty) where - arg_ty = exprType arg - - maybe_boxed_prim_arg_ty = maybeBoxedPrimType arg_ty - (Just (box_data_con, the_prim_arg_ty)) = maybe_boxed_prim_arg_ty + arg_ty = exprType arg + arg_rep_ty = repType arg_ty maybe_product_type = splitProductType_maybe arg_ty is_product_type = maybeToBool maybe_product_type Just (tycon, _, data_con, data_con_arg_tys) = maybe_product_type - (data_con_arg_ty1 : data_con_arg_ty2 : data_con_arg_ty3 :_) - = data_con_arg_tys - - maybe_arg3_tycon = splitTyConApp_maybe data_con_arg_ty3 - Just (arg3_tycon,_) = maybe_arg3_tycon + data_con_arity = dataConSourceArity data_con + (data_con_arg_ty1 : _) = data_con_arg_tys -can'tSeeDataConsPanic thing ty - = pprPanic - "ERROR: Can't see the data constructor(s) for _ccall_/_casm_/foreign declaration" - (hcat [ text thing, text "; type: ", ppr ty - , text "(try compiling with -fno-prune-tydecls ..)\n"]) + (_ : _ : data_con_arg_ty3 : _) = data_con_arg_tys + maybe_arg3_tycon = splitTyConApp_maybe data_con_arg_ty3 + Just (arg3_tycon,_) = maybe_arg3_tycon \end{code} \begin{code} -boxResult :: Type -- Type of desired result - -> DsM (Type, -- Type of the result of the ccall itself - CoreExpr -> CoreExpr) -- Wrapper for the ccall - -- to box the result +boxResult :: Type -> DsM (Type, CoreExpr -> CoreExpr) + +-- Takes the result of the user-level ccall: +-- either (IO t), +-- or maybe just t for an side-effect-free call +-- Returns a wrapper for the primitive ccall itself, along with the +-- type of the result of the primitive ccall. This result type +-- will be of the form +-- State# RealWorld -> (# State# RealWorld, t' #) +-- where t' is the unwrapped form of t. If t is simply (), then +-- the result type will be +-- State# RealWorld -> (# State# RealWorld #) + boxResult result_ty - -- Data types with a single nullary constructor - | (maybeToBool maybe_product_type) && -- Data type - (null data_con_arg_tys) - = - newSysLocalDs realWorldStatePrimTy `thenDs` \ prim_state_id -> -{- - wrapUnboxedValue result_ty `thenDs` \ (state_and_prim_datacon, - state_and_prim_ty, prim_result_id, the_result) -> - mkConDs ioOkDataCon - [TyArg result_ty, VarArg (Var prim_state_id), VarArg the_result] - `thenDs` \ the_pair -> --} - let - the_pair = mkConApp unboxedPairDataCon - [Type realWorldStatePrimTy, Type result_ty, - Var prim_state_id, - Var unitDataConId] - the_alt = (DataAlt (unboxedTupleCon 1), [prim_state_id], the_pair) - scrut_ty = mkUnboxedTupleTy 1 [realWorldStatePrimTy] + = case splitAlgTyConApp_maybe result_ty of + + -- The result is IO t, so wrap the result in an IO constructor + Just (io_tycon, [io_res_ty], [io_data_con]) | getUnique io_tycon == ioTyConKey + -> mk_alt return_result + (resultWrapper io_res_ty) `thenDs` \ (ccall_res_ty, the_alt) -> + newSysLocalDs realWorldStatePrimTy `thenDs` \ state_id -> + let + wrap = \ the_call -> mkApps (Var (dataConWrapId io_data_con)) + [Type io_res_ty, Lam state_id $ + Case (App the_call (Var state_id)) + (mkWildId ccall_res_ty) + [the_alt]] + in + returnDs (realWorldStatePrimTy `mkFunTy` ccall_res_ty, wrap) + where + return_result state ans = mkConApp unboxedPairDataCon + [Type realWorldStatePrimTy, Type io_res_ty, + state, ans] + + -- It isn't, so do unsafePerformIO + -- It's not conveniently available, so we inline it + other -> mk_alt return_result + (resultWrapper result_ty) `thenDs` \ (ccall_res_ty, the_alt) -> + let + wrap = \ the_call -> Case (App the_call (Var realWorldPrimId)) + (mkWildId ccall_res_ty) + [the_alt] + in + returnDs (realWorldStatePrimTy `mkFunTy` ccall_res_ty, wrap) + where + return_result state ans = ans + where + mk_alt return_result (Nothing, wrap_result) + = -- The ccall returns () + newSysLocalDs realWorldStatePrimTy `thenDs` \ state_id -> + let + the_rhs = return_result (Var state_id) (wrap_result (panic "boxResult")) + ccall_res_ty = mkUnboxedTupleTy 1 [realWorldStatePrimTy] + the_alt = (DataAlt (unboxedTupleCon 1), [state_id], the_rhs) + in + returnDs (ccall_res_ty, the_alt) + + mk_alt return_result (Just prim_res_ty, wrap_result) + = -- The ccall returns a non-() value + newSysLocalDs realWorldStatePrimTy `thenDs` \ state_id -> + newSysLocalDs prim_res_ty `thenDs` \ result_id -> + let + the_rhs = return_result (Var state_id) (wrap_result (Var result_id)) + ccall_res_ty = mkUnboxedTupleTy 2 [realWorldStatePrimTy, prim_res_ty] + the_alt = (DataAlt unboxedPairDataCon, [state_id, result_id], the_rhs) + in + returnDs (ccall_res_ty, the_alt) + + +resultWrapper :: Type + -> (Maybe Type, -- Type of the expected result, if any + CoreExpr -> CoreExpr) -- Wrapper for the result +resultWrapper result_ty + -- Base case 1: primitive types + | isUnLiftedType result_ty + = (Just result_ty, \e -> e) + + -- Base case 1: the unit type () + | result_ty == unitTy + = (Nothing, \e -> Var unitDataConId) + + | result_ty == boolTy + = (Just intPrimTy, \e -> Case e (mkWildId intPrimTy) + [(LitAlt (mkMachInt 0),[],Var falseDataConId), + (DEFAULT ,[],Var trueDataConId )]) + + -- Data types with a single constructor, which has a single arg + | is_product_type && data_con_arity == 1 + = let + (maybe_ty, wrapper) = resultWrapper unwrapped_res_ty + (unwrapped_res_ty : _) = data_con_arg_tys in - returnDs (scrut_ty, \prim_app -> Case prim_app (mkWildId scrut_ty) [the_alt] - ) - - -- Data types with a single constructor, which has a single, primitive-typed arg - | (maybeToBool maybe_product_type) && -- Data type - not (null data_con_arg_tys) && null other_args_tys && -- Just one arg - isUnLiftedType the_prim_result_ty -- of primitive type - = - newSysLocalDs realWorldStatePrimTy `thenDs` \ prim_state_id -> - newSysLocalDs the_prim_result_ty `thenDs` \ prim_result_id -> - newSysLocalDs ccall_res_type `thenDs` \ case_bndr -> - - let - the_result = mkConApp data_con (map Type tycon_arg_tys ++ [Var prim_result_id]) - the_pair = mkConApp unboxedPairDataCon - [Type realWorldStatePrimTy, Type result_ty, - Var prim_state_id, the_result] - the_alt = (DataAlt unboxedPairDataCon, [prim_state_id, prim_result_id], the_pair) + (maybe_ty, \e -> mkApps (Var (dataConWrapId data_con)) + (map Type tycon_arg_tys ++ [wrapper e])) + + -- newtypes + | isNewType result_ty + = let + rep_ty = repType result_ty + (maybe_ty, wrapper) = resultWrapper rep_ty in - returnDs (ccall_res_type, \prim_app -> Case prim_app case_bndr [the_alt] - ) + (maybe_ty, \e -> mkCoerce result_ty rep_ty (wrapper e)) | otherwise - = pprPanic "boxResult: " (ppr result_ty) + = pprPanic "resultWrapper" (ppr result_ty) where maybe_product_type = splitProductType_maybe result_ty + is_product_type = maybeToBool maybe_product_type Just (tycon, tycon_arg_tys, data_con, data_con_arg_tys) = maybe_product_type - (the_prim_result_ty : other_args_tys) = data_con_arg_tys - - ccall_res_type = mkUnboxedTupleTy 2 [realWorldStatePrimTy, the_prim_result_ty] - --- wrap up an unboxed value. -wrapUnboxedValue :: Type -> DsM (Type, Id, CoreExpr) -wrapUnboxedValue ty - | (maybeToBool maybe_product_type) && -- Data type - not (null data_con_arg_tys) && null other_args_tys && -- Just one arg - isUnLiftedType the_prim_result_ty -- of primitive type - = - newSysLocalDs the_prim_result_ty `thenDs` \ prim_result_id -> - let - the_result = mkConApp data_con (map Type tycon_arg_tys ++ [Var prim_result_id]) - in - returnDs (ccall_res_type, prim_result_id, the_result) - - -- Data types with a single nullary constructor - | (maybeToBool maybe_product_type) && -- Data type - (null data_con_arg_tys) - = - let - scrut_ty = mkUnboxedTupleTy 1 [realWorldStatePrimTy] - in - returnDs (scrut_ty, unitDataConId, Var unitDataConId) - - | otherwise - = pprPanic "boxResult: " (ppr ty) - where - maybe_product_type = splitProductType_maybe ty - Just (tycon, tycon_arg_tys, data_con, data_con_arg_tys) = maybe_product_type - (the_prim_result_ty : other_args_tys) = data_con_arg_tys - ccall_res_type = mkUnboxedTupleTy 2 [realWorldStatePrimTy, the_prim_result_ty] + data_con_arity = dataConSourceArity data_con \end{code}