- -- 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