------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- E X P _ C H 3 -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2005, Free Software Foundation, Inc. -- -- -- -- GNAT is free software; you can redistribute it and/or modify it under -- -- terms of the GNU General Public License as published by the Free Soft- -- -- ware Foundation; either version 2, or (at your option) any later ver- -- -- sion. GNAT is distributed in the hope that it will be useful, but WITH- -- -- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY -- -- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License -- -- for more details. You should have received a copy of the GNU General -- -- Public License distributed with GNAT; see file COPYING. If not, write -- -- to the Free Software Foundation, 51 Franklin Street, Fifth Floor, -- -- Boston, MA 02110-1301, USA. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ with Atree; use Atree; with Checks; use Checks; with Einfo; use Einfo; with Errout; use Errout; with Exp_Aggr; use Exp_Aggr; with Exp_Ch4; use Exp_Ch4; with Exp_Ch7; use Exp_Ch7; with Exp_Ch9; use Exp_Ch9; with Exp_Ch11; use Exp_Ch11; with Exp_Disp; use Exp_Disp; with Exp_Dist; use Exp_Dist; with Exp_Smem; use Exp_Smem; with Exp_Strm; use Exp_Strm; with Exp_Tss; use Exp_Tss; with Exp_Util; use Exp_Util; with Freeze; use Freeze; with Hostparm; use Hostparm; with Nlists; use Nlists; with Nmake; use Nmake; with Opt; use Opt; with Restrict; use Restrict; with Rident; use Rident; with Rtsfind; use Rtsfind; with Sem; use Sem; with Sem_Attr; use Sem_Attr; with Sem_Ch3; use Sem_Ch3; with Sem_Ch8; use Sem_Ch8; with Sem_Eval; use Sem_Eval; with Sem_Mech; use Sem_Mech; with Sem_Res; use Sem_Res; with Sem_Util; use Sem_Util; with Sinfo; use Sinfo; with Stand; use Stand; with Snames; use Snames; with Tbuild; use Tbuild; with Ttypes; use Ttypes; with Validsw; use Validsw; package body Exp_Ch3 is ----------------------- -- Local Subprograms -- ----------------------- procedure Adjust_Discriminants (Rtype : Entity_Id); -- This is used when freezing a record type. It attempts to construct -- more restrictive subtypes for discriminants so that the max size of -- the record can be calculated more accurately. See the body of this -- procedure for details. procedure Build_Array_Init_Proc (A_Type : Entity_Id; Nod : Node_Id); -- Build initialization procedure for given array type. Nod is a node -- used for attachment of any actions required in its construction. -- It also supplies the source location used for the procedure. function Build_Discriminant_Formals (Rec_Id : Entity_Id; Use_Dl : Boolean) return List_Id; -- This function uses the discriminants of a type to build a list of -- formal parameters, used in the following function. If the flag Use_Dl -- is set, the list is built using the already defined discriminals -- of the type. Otherwise new identifiers are created, with the source -- names of the discriminants. procedure Build_Master_Renaming (N : Node_Id; T : Entity_Id); -- If the designated type of an access type is a task type or contains -- tasks, we make sure that a _Master variable is declared in the current -- scope, and then declare a renaming for it: -- -- atypeM : Master_Id renames _Master; -- -- where atyp is the name of the access type. This declaration is -- used when an allocator for the access type is expanded. The node N -- is the full declaration of the designated type that contains tasks. -- The renaming declaration is inserted before N, and after the Master -- declaration. procedure Build_Record_Init_Proc (N : Node_Id; Pe : Entity_Id); -- Build record initialization procedure. N is the type declaration -- node, and Pe is the corresponding entity for the record type. procedure Build_Slice_Assignment (Typ : Entity_Id); -- Build assignment procedure for one-dimensional arrays of controlled -- types. Other array and slice assignments are expanded in-line, but -- the code expansion for controlled components (when control actions -- are active) can lead to very large blocks that GCC3 handles poorly. procedure Build_Variant_Record_Equality (Typ : Entity_Id); -- Create An Equality function for the non-tagged variant record 'Typ' -- and attach it to the TSS list procedure Check_Stream_Attributes (Typ : Entity_Id); -- Check that if a limited extension has a parent with user-defined -- stream attributes, and does not itself have user-definer -- stream-attributes, then any limited component of the extension also -- has the corresponding user-defined stream attributes. procedure Expand_Tagged_Root (T : Entity_Id); -- Add a field _Tag at the beginning of the record. This field carries -- the value of the access to the Dispatch table. This procedure is only -- called on root (non CPP_Class) types, the _Tag field being inherited -- by the descendants. procedure Expand_Record_Controller (T : Entity_Id); -- T must be a record type that Has_Controlled_Component. Add a field -- _controller of type Record_Controller or Limited_Record_Controller -- in the record T. procedure Freeze_Array_Type (N : Node_Id); -- Freeze an array type. Deals with building the initialization procedure, -- creating the packed array type for a packed array and also with the -- creation of the controlling procedures for the controlled case. The -- argument N is the N_Freeze_Entity node for the type. procedure Freeze_Enumeration_Type (N : Node_Id); -- Freeze enumeration type with non-standard representation. Builds the -- array and function needed to convert between enumeration pos and -- enumeration representation values. N is the N_Freeze_Entity node -- for the type. procedure Freeze_Record_Type (N : Node_Id); -- Freeze record type. Builds all necessary discriminant checking -- and other ancillary functions, and builds dispatch tables where -- needed. The argument N is the N_Freeze_Entity node. This processing -- applies only to E_Record_Type entities, not to class wide types, -- record subtypes, or private types. procedure Freeze_Stream_Operations (N : Node_Id; Typ : Entity_Id); -- Treat user-defined stream operations as renaming_as_body if the -- subprogram they rename is not frozen when the type is frozen. function Init_Formals (Typ : Entity_Id) return List_Id; -- This function builds the list of formals for an initialization routine. -- The first formal is always _Init with the given type. For task value -- record types and types containing tasks, three additional formals are -- added: -- -- _Master : Master_Id -- _Chain : in out Activation_Chain -- _Task_Name : String -- -- The caller must append additional entries for discriminants if required. function In_Runtime (E : Entity_Id) return Boolean; -- Check if E is defined in the RTL (in a child of Ada or System). Used -- to avoid to bring in the overhead of _Input, _Output for tagged types. function Make_Eq_Case (E : Entity_Id; CL : Node_Id; Discr : Entity_Id := Empty) return List_Id; -- Building block for variant record equality. Defined to share the -- code between the tagged and non-tagged case. Given a Component_List -- node CL, it generates an 'if' followed by a 'case' statement that -- compares all components of local temporaries named X and Y (that -- are declared as formals at some upper level). E provides the Sloc to be -- used for the generated code. Discr is used as the case statement switch -- in the case of Unchecked_Union equality. function Make_Eq_If (E : Entity_Id; L : List_Id) return Node_Id; -- Building block for variant record equality. Defined to share the -- code between the tagged and non-tagged case. Given the list of -- components (or discriminants) L, it generates a return statement -- that compares all components of local temporaries named X and Y -- (that are declared as formals at some upper level). E provides the Sloc -- to be used for the generated code. procedure Make_Predefined_Primitive_Specs (Tag_Typ : Entity_Id; Predef_List : out List_Id; Renamed_Eq : out Node_Id); -- Create a list with the specs of the predefined primitive operations. -- The following entries are present for all tagged types, and provide -- the results of the corresponding attribute applied to the object. -- Dispatching is required in general, since the result of the attribute -- will vary with the actual object subtype. -- -- _alignment provides result of 'Alignment attribute -- _size provides result of 'Size attribute -- typSR provides result of 'Read attribute -- typSW provides result of 'Write attribute -- typSI provides result of 'Input attribute -- typSO provides result of 'Output attribute -- -- The following entries are additionally present for non-limited -- tagged types, and implement additional dispatching operations -- for predefined operations: -- -- _equality implements "=" operator -- _assign implements assignment operation -- typDF implements deep finalization -- typDA implements deep adust -- -- The latter two are empty procedures unless the type contains some -- controlled components that require finalization actions (the deep -- in the name refers to the fact that the action applies to components). -- -- The list is returned in Predef_List. The Parameter Renamed_Eq -- either returns the value Empty, or else the defining unit name -- for the predefined equality function in the case where the type -- has a primitive operation that is a renaming of predefined equality -- (but only if there is also an overriding user-defined equality -- function). The returned Renamed_Eq will be passed to the -- corresponding parameter of Predefined_Primitive_Bodies. function Has_New_Non_Standard_Rep (T : Entity_Id) return Boolean; -- returns True if there are representation clauses for type T that -- are not inherited. If the result is false, the init_proc and the -- discriminant_checking functions of the parent can be reused by -- a derived type. function Predef_Spec_Or_Body (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : Name_Id; Profile : List_Id; Ret_Type : Entity_Id := Empty; For_Body : Boolean := False) return Node_Id; -- This function generates the appropriate expansion for a predefined -- primitive operation specified by its name, parameter profile and -- return type (Empty means this is a procedure). If For_Body is false, -- then the returned node is a subprogram declaration. If For_Body is -- true, then the returned node is a empty subprogram body containing -- no declarations and no statements. function Predef_Stream_Attr_Spec (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : TSS_Name_Type; For_Body : Boolean := False) return Node_Id; -- Specialized version of Predef_Spec_Or_Body that apply to read, write, -- input and output attribute whose specs are constructed in Exp_Strm. function Predef_Deep_Spec (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : TSS_Name_Type; For_Body : Boolean := False) return Node_Id; -- Specialized version of Predef_Spec_Or_Body that apply to _deep_adjust -- and _deep_finalize function Predefined_Primitive_Bodies (Tag_Typ : Entity_Id; Renamed_Eq : Node_Id) return List_Id; -- Create the bodies of the predefined primitives that are described in -- Predefined_Primitive_Specs. When not empty, Renamed_Eq must denote -- the defining unit name of the type's predefined equality as returned -- by Make_Predefined_Primitive_Specs. function Predefined_Primitive_Freeze (Tag_Typ : Entity_Id) return List_Id; -- Freeze entities of all predefined primitive operations. This is needed -- because the bodies of these operations do not normally do any freezeing. function Stream_Operation_OK (Typ : Entity_Id; Operation : TSS_Name_Type) return Boolean; -- Check whether the named stream operation must be emitted for a given -- type. The rules for inheritance of stream attributes by type extensions -- are enforced by this function. Furthermore, various restrictions prevent -- the generation of these operations, as a useful optimization or for -- certification purposes. -------------------------- -- Adjust_Discriminants -- -------------------------- -- This procedure attempts to define subtypes for discriminants that -- are more restrictive than those declared. Such a replacement is -- possible if we can demonstrate that values outside the restricted -- range would cause constraint errors in any case. The advantage of -- restricting the discriminant types in this way is tha the maximum -- size of the variant record can be calculated more conservatively. -- An example of a situation in which we can perform this type of -- restriction is the following: -- subtype B is range 1 .. 10; -- type Q is array (B range <>) of Integer; -- type V (N : Natural) is record -- C : Q (1 .. N); -- end record; -- In this situation, we can restrict the upper bound of N to 10, since -- any larger value would cause a constraint error in any case. -- There are many situations in which such restriction is possible, but -- for now, we just look for cases like the above, where the component -- in question is a one dimensional array whose upper bound is one of -- the record discriminants. Also the component must not be part of -- any variant part, since then the component does not always exist. procedure Adjust_Discriminants (Rtype : Entity_Id) is Loc : constant Source_Ptr := Sloc (Rtype); Comp : Entity_Id; Ctyp : Entity_Id; Ityp : Entity_Id; Lo : Node_Id; Hi : Node_Id; P : Node_Id; Loval : Uint; Discr : Entity_Id; Dtyp : Entity_Id; Dhi : Node_Id; Dhiv : Uint; Ahi : Node_Id; Ahiv : Uint; Tnn : Entity_Id; begin Comp := First_Component (Rtype); while Present (Comp) loop -- If our parent is a variant, quit, we do not look at components -- that are in variant parts, because they may not always exist. P := Parent (Comp); -- component declaration P := Parent (P); -- component list exit when Nkind (Parent (P)) = N_Variant; -- We are looking for a one dimensional array type Ctyp := Etype (Comp); if not Is_Array_Type (Ctyp) or else Number_Dimensions (Ctyp) > 1 then goto Continue; end if; -- The lower bound must be constant, and the upper bound is a -- discriminant (which is a discriminant of the current record). Ityp := Etype (First_Index (Ctyp)); Lo := Type_Low_Bound (Ityp); Hi := Type_High_Bound (Ityp); if not Compile_Time_Known_Value (Lo) or else Nkind (Hi) /= N_Identifier or else No (Entity (Hi)) or else Ekind (Entity (Hi)) /= E_Discriminant then goto Continue; end if; -- We have an array with appropriate bounds Loval := Expr_Value (Lo); Discr := Entity (Hi); Dtyp := Etype (Discr); -- See if the discriminant has a known upper bound Dhi := Type_High_Bound (Dtyp); if not Compile_Time_Known_Value (Dhi) then goto Continue; end if; Dhiv := Expr_Value (Dhi); -- See if base type of component array has known upper bound Ahi := Type_High_Bound (Etype (First_Index (Base_Type (Ctyp)))); if not Compile_Time_Known_Value (Ahi) then goto Continue; end if; Ahiv := Expr_Value (Ahi); -- The condition for doing the restriction is that the high bound -- of the discriminant is greater than the low bound of the array, -- and is also greater than the high bound of the base type index. if Dhiv > Loval and then Dhiv > Ahiv then -- We can reset the upper bound of the discriminant type to -- whichever is larger, the low bound of the component, or -- the high bound of the base type array index. -- We build a subtype that is declared as -- subtype Tnn is discr_type range discr_type'First .. max; -- And insert this declaration into the tree. The type of the -- discriminant is then reset to this more restricted subtype. Tnn := Make_Defining_Identifier (Loc, New_Internal_Name ('T')); Insert_Action (Declaration_Node (Rtype), Make_Subtype_Declaration (Loc, Defining_Identifier => Tnn, Subtype_Indication => Make_Subtype_Indication (Loc, Subtype_Mark => New_Occurrence_Of (Dtyp, Loc), Constraint => Make_Range_Constraint (Loc, Range_Expression => Make_Range (Loc, Low_Bound => Make_Attribute_Reference (Loc, Attribute_Name => Name_First, Prefix => New_Occurrence_Of (Dtyp, Loc)), High_Bound => Make_Integer_Literal (Loc, Intval => UI_Max (Loval, Ahiv))))))); Set_Etype (Discr, Tnn); end if; <> Next_Component (Comp); end loop; end Adjust_Discriminants; --------------------------- -- Build_Array_Init_Proc -- --------------------------- procedure Build_Array_Init_Proc (A_Type : Entity_Id; Nod : Node_Id) is Loc : constant Source_Ptr := Sloc (Nod); Comp_Type : constant Entity_Id := Component_Type (A_Type); Index_List : List_Id; Proc_Id : Entity_Id; Body_Stmts : List_Id; function Init_Component return List_Id; -- Create one statement to initialize one array component, designated -- by a full set of indices. function Init_One_Dimension (N : Int) return List_Id; -- Create loop to initialize one dimension of the array. The single -- statement in the loop body initializes the inner dimensions if any, -- or else the single component. Note that this procedure is called -- recursively, with N being the dimension to be initialized. A call -- with N greater than the number of dimensions simply generates the -- component initialization, terminating the recursion. -------------------- -- Init_Component -- -------------------- function Init_Component return List_Id is Comp : Node_Id; begin Comp := Make_Indexed_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Expressions => Index_List); if Needs_Simple_Initialization (Comp_Type) then Set_Assignment_OK (Comp); return New_List ( Make_Assignment_Statement (Loc, Name => Comp, Expression => Get_Simple_Init_Val (Comp_Type, Loc, Component_Size (A_Type)))); else return Build_Initialization_Call (Loc, Comp, Comp_Type, True, A_Type); end if; end Init_Component; ------------------------ -- Init_One_Dimension -- ------------------------ function Init_One_Dimension (N : Int) return List_Id is Index : Entity_Id; begin -- If the component does not need initializing, then there is nothing -- to do here, so we return a null body. This occurs when generating -- the dummy Init_Proc needed for Initialize_Scalars processing. if not Has_Non_Null_Base_Init_Proc (Comp_Type) and then not Needs_Simple_Initialization (Comp_Type) and then not Has_Task (Comp_Type) then return New_List (Make_Null_Statement (Loc)); -- If all dimensions dealt with, we simply initialize the component elsif N > Number_Dimensions (A_Type) then return Init_Component; -- Here we generate the required loop else Index := Make_Defining_Identifier (Loc, New_External_Name ('J', N)); Append (New_Reference_To (Index, Loc), Index_List); return New_List ( Make_Implicit_Loop_Statement (Nod, Identifier => Empty, Iteration_Scheme => Make_Iteration_Scheme (Loc, Loop_Parameter_Specification => Make_Loop_Parameter_Specification (Loc, Defining_Identifier => Index, Discrete_Subtype_Definition => Make_Attribute_Reference (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Attribute_Name => Name_Range, Expressions => New_List ( Make_Integer_Literal (Loc, N))))), Statements => Init_One_Dimension (N + 1))); end if; end Init_One_Dimension; -- Start of processing for Build_Array_Init_Proc begin if Suppress_Init_Proc (A_Type) then return; end if; Index_List := New_List; -- We need an initialization procedure if any of the following is true: -- 1. The component type has an initialization procedure -- 2. The component type needs simple initialization -- 3. Tasks are present -- 4. The type is marked as a publc entity -- The reason for the public entity test is to deal properly with the -- Initialize_Scalars pragma. This pragma can be set in the client and -- not in the declaring package, this means the client will make a call -- to the initialization procedure (because one of conditions 1-3 must -- apply in this case), and we must generate a procedure (even if it is -- null) to satisfy the call in this case. -- Exception: do not build an array init_proc for a type whose root -- type is Standard.String or Standard.Wide_[Wide_]String, since there -- is no place to put the code, and in any case we handle initialization -- of such types (in the Initialize_Scalars case, that's the only time -- the issue arises) in a special manner anyway which does not need an -- init_proc. if Has_Non_Null_Base_Init_Proc (Comp_Type) or else Needs_Simple_Initialization (Comp_Type) or else Has_Task (Comp_Type) or else (not Restriction_Active (No_Initialize_Scalars) and then Is_Public (A_Type) and then Root_Type (A_Type) /= Standard_String and then Root_Type (A_Type) /= Standard_Wide_String and then Root_Type (A_Type) /= Standard_Wide_Wide_String) then Proc_Id := Make_Defining_Identifier (Loc, Make_Init_Proc_Name (A_Type)); Body_Stmts := Init_One_Dimension (1); Discard_Node ( Make_Subprogram_Body (Loc, Specification => Make_Procedure_Specification (Loc, Defining_Unit_Name => Proc_Id, Parameter_Specifications => Init_Formals (A_Type)), Declarations => New_List, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, Statements => Body_Stmts))); Set_Ekind (Proc_Id, E_Procedure); Set_Is_Public (Proc_Id, Is_Public (A_Type)); Set_Is_Internal (Proc_Id); Set_Has_Completion (Proc_Id); if not Debug_Generated_Code then Set_Debug_Info_Off (Proc_Id); end if; -- Set inlined unless controlled stuff or tasks around, in which -- case we do not want to inline, because nested stuff may cause -- difficulties in interunit inlining, and furthermore there is -- in any case no point in inlining such complex init procs. if not Has_Task (Proc_Id) and then not Controlled_Type (Proc_Id) then Set_Is_Inlined (Proc_Id); end if; -- Associate Init_Proc with type, and determine if the procedure -- is null (happens because of the Initialize_Scalars pragma case, -- where we have to generate a null procedure in case it is called -- by a client with Initialize_Scalars set). Such procedures have -- to be generated, but do not have to be called, so we mark them -- as null to suppress the call. Set_Init_Proc (A_Type, Proc_Id); if List_Length (Body_Stmts) = 1 and then Nkind (First (Body_Stmts)) = N_Null_Statement then Set_Is_Null_Init_Proc (Proc_Id); end if; end if; end Build_Array_Init_Proc; ----------------------------- -- Build_Class_Wide_Master -- ----------------------------- procedure Build_Class_Wide_Master (T : Entity_Id) is Loc : constant Source_Ptr := Sloc (T); M_Id : Entity_Id; Decl : Node_Id; P : Node_Id; Par : Node_Id; begin -- Nothing to do if there is no task hierarchy if Restriction_Active (No_Task_Hierarchy) then return; end if; -- Find declaration that created the access type: either a -- type declaration, or an object declaration with an -- access definition, in which case the type is anonymous. if Is_Itype (T) then P := Associated_Node_For_Itype (T); else P := Parent (T); end if; -- Nothing to do if we already built a master entity for this scope if not Has_Master_Entity (Scope (T)) then -- first build the master entity -- _Master : constant Master_Id := Current_Master.all; -- and insert it just before the current declaration Decl := Make_Object_Declaration (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uMaster), Constant_Present => True, Object_Definition => New_Reference_To (Standard_Integer, Loc), Expression => Make_Explicit_Dereference (Loc, New_Reference_To (RTE (RE_Current_Master), Loc))); Insert_Before (P, Decl); Analyze (Decl); Set_Has_Master_Entity (Scope (T)); -- Now mark the containing scope as a task master Par := P; while Nkind (Par) /= N_Compilation_Unit loop Par := Parent (Par); -- If we fall off the top, we are at the outer level, and the -- environment task is our effective master, so nothing to mark. if Nkind (Par) = N_Task_Body or else Nkind (Par) = N_Block_Statement or else Nkind (Par) = N_Subprogram_Body then Set_Is_Task_Master (Par, True); exit; end if; end loop; end if; -- Now define the renaming of the master_id M_Id := Make_Defining_Identifier (Loc, New_External_Name (Chars (T), 'M')); Decl := Make_Object_Renaming_Declaration (Loc, Defining_Identifier => M_Id, Subtype_Mark => New_Reference_To (Standard_Integer, Loc), Name => Make_Identifier (Loc, Name_uMaster)); Insert_Before (P, Decl); Analyze (Decl); Set_Master_Id (T, M_Id); exception when RE_Not_Available => return; end Build_Class_Wide_Master; -------------------------------- -- Build_Discr_Checking_Funcs -- -------------------------------- procedure Build_Discr_Checking_Funcs (N : Node_Id) is Rec_Id : Entity_Id; Loc : Source_Ptr; Enclosing_Func_Id : Entity_Id; Sequence : Nat := 1; Type_Def : Node_Id; V : Node_Id; function Build_Case_Statement (Case_Id : Entity_Id; Variant : Node_Id) return Node_Id; -- Build a case statement containing only two alternatives. The -- first alternative corresponds exactly to the discrete choices -- given on the variant with contains the components that we are -- generating the checks for. If the discriminant is one of these -- return False. The second alternative is an OTHERS choice that -- will return True indicating the discriminant did not match. function Build_Dcheck_Function (Case_Id : Entity_Id; Variant : Node_Id) return Entity_Id; -- Build the discriminant checking function for a given variant procedure Build_Dcheck_Functions (Variant_Part_Node : Node_Id); -- Builds the discriminant checking function for each variant of the -- given variant part of the record type. -------------------------- -- Build_Case_Statement -- -------------------------- function Build_Case_Statement (Case_Id : Entity_Id; Variant : Node_Id) return Node_Id is Alt_List : constant List_Id := New_List; Actuals_List : List_Id; Case_Node : Node_Id; Case_Alt_Node : Node_Id; Choice : Node_Id; Choice_List : List_Id; D : Entity_Id; Return_Node : Node_Id; begin Case_Node := New_Node (N_Case_Statement, Loc); -- Replace the discriminant which controls the variant, with the -- name of the formal of the checking function. Set_Expression (Case_Node, Make_Identifier (Loc, Chars (Case_Id))); Choice := First (Discrete_Choices (Variant)); if Nkind (Choice) = N_Others_Choice then Choice_List := New_Copy_List (Others_Discrete_Choices (Choice)); else Choice_List := New_Copy_List (Discrete_Choices (Variant)); end if; if not Is_Empty_List (Choice_List) then Case_Alt_Node := New_Node (N_Case_Statement_Alternative, Loc); Set_Discrete_Choices (Case_Alt_Node, Choice_List); -- In case this is a nested variant, we need to return the result -- of the discriminant checking function for the immediately -- enclosing variant. if Present (Enclosing_Func_Id) then Actuals_List := New_List; D := First_Discriminant (Rec_Id); while Present (D) loop Append (Make_Identifier (Loc, Chars (D)), Actuals_List); Next_Discriminant (D); end loop; Return_Node := Make_Return_Statement (Loc, Expression => Make_Function_Call (Loc, Name => New_Reference_To (Enclosing_Func_Id, Loc), Parameter_Associations => Actuals_List)); else Return_Node := Make_Return_Statement (Loc, Expression => New_Reference_To (Standard_False, Loc)); end if; Set_Statements (Case_Alt_Node, New_List (Return_Node)); Append (Case_Alt_Node, Alt_List); end if; Case_Alt_Node := New_Node (N_Case_Statement_Alternative, Loc); Choice_List := New_List (New_Node (N_Others_Choice, Loc)); Set_Discrete_Choices (Case_Alt_Node, Choice_List); Return_Node := Make_Return_Statement (Loc, Expression => New_Reference_To (Standard_True, Loc)); Set_Statements (Case_Alt_Node, New_List (Return_Node)); Append (Case_Alt_Node, Alt_List); Set_Alternatives (Case_Node, Alt_List); return Case_Node; end Build_Case_Statement; --------------------------- -- Build_Dcheck_Function -- --------------------------- function Build_Dcheck_Function (Case_Id : Entity_Id; Variant : Node_Id) return Entity_Id is Body_Node : Node_Id; Func_Id : Entity_Id; Parameter_List : List_Id; Spec_Node : Node_Id; begin Body_Node := New_Node (N_Subprogram_Body, Loc); Sequence := Sequence + 1; Func_Id := Make_Defining_Identifier (Loc, Chars => New_External_Name (Chars (Rec_Id), 'D', Sequence)); Spec_Node := New_Node (N_Function_Specification, Loc); Set_Defining_Unit_Name (Spec_Node, Func_Id); Parameter_List := Build_Discriminant_Formals (Rec_Id, False); Set_Parameter_Specifications (Spec_Node, Parameter_List); Set_Result_Definition (Spec_Node, New_Reference_To (Standard_Boolean, Loc)); Set_Specification (Body_Node, Spec_Node); Set_Declarations (Body_Node, New_List); Set_Handled_Statement_Sequence (Body_Node, Make_Handled_Sequence_Of_Statements (Loc, Statements => New_List ( Build_Case_Statement (Case_Id, Variant)))); Set_Ekind (Func_Id, E_Function); Set_Mechanism (Func_Id, Default_Mechanism); Set_Is_Inlined (Func_Id, True); Set_Is_Pure (Func_Id, True); Set_Is_Public (Func_Id, Is_Public (Rec_Id)); Set_Is_Internal (Func_Id, True); if not Debug_Generated_Code then Set_Debug_Info_Off (Func_Id); end if; Analyze (Body_Node); Append_Freeze_Action (Rec_Id, Body_Node); Set_Dcheck_Function (Variant, Func_Id); return Func_Id; end Build_Dcheck_Function; ---------------------------- -- Build_Dcheck_Functions -- ---------------------------- procedure Build_Dcheck_Functions (Variant_Part_Node : Node_Id) is Component_List_Node : Node_Id; Decl : Entity_Id; Discr_Name : Entity_Id; Func_Id : Entity_Id; Variant : Node_Id; Saved_Enclosing_Func_Id : Entity_Id; begin -- Build the discriminant checking function for each variant, label -- all components of that variant with the function's name. Discr_Name := Entity (Name (Variant_Part_Node)); Variant := First_Non_Pragma (Variants (Variant_Part_Node)); while Present (Variant) loop Func_Id := Build_Dcheck_Function (Discr_Name, Variant); Component_List_Node := Component_List (Variant); if not Null_Present (Component_List_Node) then Decl := First_Non_Pragma (Component_Items (Component_List_Node)); while Present (Decl) loop Set_Discriminant_Checking_Func (Defining_Identifier (Decl), Func_Id); Next_Non_Pragma (Decl); end loop; if Present (Variant_Part (Component_List_Node)) then Saved_Enclosing_Func_Id := Enclosing_Func_Id; Enclosing_Func_Id := Func_Id; Build_Dcheck_Functions (Variant_Part (Component_List_Node)); Enclosing_Func_Id := Saved_Enclosing_Func_Id; end if; end if; Next_Non_Pragma (Variant); end loop; end Build_Dcheck_Functions; -- Start of processing for Build_Discr_Checking_Funcs begin -- Only build if not done already if not Discr_Check_Funcs_Built (N) then Type_Def := Type_Definition (N); if Nkind (Type_Def) = N_Record_Definition then if No (Component_List (Type_Def)) then -- null record. return; else V := Variant_Part (Component_List (Type_Def)); end if; else pragma Assert (Nkind (Type_Def) = N_Derived_Type_Definition); if No (Component_List (Record_Extension_Part (Type_Def))) then return; else V := Variant_Part (Component_List (Record_Extension_Part (Type_Def))); end if; end if; Rec_Id := Defining_Identifier (N); if Present (V) and then not Is_Unchecked_Union (Rec_Id) then Loc := Sloc (N); Enclosing_Func_Id := Empty; Build_Dcheck_Functions (V); end if; Set_Discr_Check_Funcs_Built (N); end if; end Build_Discr_Checking_Funcs; -------------------------------- -- Build_Discriminant_Formals -- -------------------------------- function Build_Discriminant_Formals (Rec_Id : Entity_Id; Use_Dl : Boolean) return List_Id is Loc : Source_Ptr := Sloc (Rec_Id); Parameter_List : constant List_Id := New_List; D : Entity_Id; Formal : Entity_Id; Param_Spec_Node : Node_Id; begin if Has_Discriminants (Rec_Id) then D := First_Discriminant (Rec_Id); while Present (D) loop Loc := Sloc (D); if Use_Dl then Formal := Discriminal (D); else Formal := Make_Defining_Identifier (Loc, Chars (D)); end if; Param_Spec_Node := Make_Parameter_Specification (Loc, Defining_Identifier => Formal, Parameter_Type => New_Reference_To (Etype (D), Loc)); Append (Param_Spec_Node, Parameter_List); Next_Discriminant (D); end loop; end if; return Parameter_List; end Build_Discriminant_Formals; ------------------------------- -- Build_Initialization_Call -- ------------------------------- -- References to a discriminant inside the record type declaration -- can appear either in the subtype_indication to constrain a -- record or an array, or as part of a larger expression given for -- the initial value of a component. In both of these cases N appears -- in the record initialization procedure and needs to be replaced by -- the formal parameter of the initialization procedure which -- corresponds to that discriminant. -- In the example below, references to discriminants D1 and D2 in proc_1 -- are replaced by references to formals with the same name -- (discriminals) -- A similar replacement is done for calls to any record -- initialization procedure for any components that are themselves -- of a record type. -- type R (D1, D2 : Integer) is record -- X : Integer := F * D1; -- Y : Integer := F * D2; -- end record; -- procedure proc_1 (Out_2 : out R; D1 : Integer; D2 : Integer) is -- begin -- Out_2.D1 := D1; -- Out_2.D2 := D2; -- Out_2.X := F * D1; -- Out_2.Y := F * D2; -- end; function Build_Initialization_Call (Loc : Source_Ptr; Id_Ref : Node_Id; Typ : Entity_Id; In_Init_Proc : Boolean := False; Enclos_Type : Entity_Id := Empty; Discr_Map : Elist_Id := New_Elmt_List; With_Default_Init : Boolean := False) return List_Id is First_Arg : Node_Id; Args : List_Id; Decls : List_Id; Decl : Node_Id; Discr : Entity_Id; Arg : Node_Id; Proc : constant Entity_Id := Base_Init_Proc (Typ); Init_Type : constant Entity_Id := Etype (First_Formal (Proc)); Full_Init_Type : constant Entity_Id := Underlying_Type (Init_Type); Res : constant List_Id := New_List; Full_Type : Entity_Id := Typ; Controller_Typ : Entity_Id; begin -- Nothing to do if the Init_Proc is null, unless Initialize_Scalars -- is active (in which case we make the call anyway, since in the -- actual compiled client it may be non null). if Is_Null_Init_Proc (Proc) and then not Init_Or_Norm_Scalars then return Empty_List; end if; -- Go to full view if private type. In the case of successive -- private derivations, this can require more than one step. while Is_Private_Type (Full_Type) and then Present (Full_View (Full_Type)) loop Full_Type := Full_View (Full_Type); end loop; -- If Typ is derived, the procedure is the initialization procedure for -- the root type. Wrap the argument in an conversion to make it type -- honest. Actually it isn't quite type honest, because there can be -- conflicts of views in the private type case. That is why we set -- Conversion_OK in the conversion node. if (Is_Record_Type (Typ) or else Is_Array_Type (Typ) or else Is_Private_Type (Typ)) and then Init_Type /= Base_Type (Typ) then First_Arg := OK_Convert_To (Etype (Init_Type), Id_Ref); Set_Etype (First_Arg, Init_Type); else First_Arg := Id_Ref; end if; Args := New_List (Convert_Concurrent (First_Arg, Typ)); -- In the tasks case, add _Master as the value of the _Master parameter -- and _Chain as the value of the _Chain parameter. At the outer level, -- these will be variables holding the corresponding values obtained -- from GNARL. At inner levels, they will be the parameters passed down -- through the outer routines. if Has_Task (Full_Type) then if Restriction_Active (No_Task_Hierarchy) then -- See comments in System.Tasking.Initialization.Init_RTS -- for the value 3 (should be rtsfindable constant ???) Append_To (Args, Make_Integer_Literal (Loc, 3)); else Append_To (Args, Make_Identifier (Loc, Name_uMaster)); end if; Append_To (Args, Make_Identifier (Loc, Name_uChain)); -- Ada 2005 (AI-287): In case of default initialized components -- with tasks, we generate a null string actual parameter. -- This is just a workaround that must be improved later??? if With_Default_Init then Append_To (Args, Make_String_Literal (Loc, Strval => "")); else Decls := Build_Task_Image_Decls (Loc, Id_Ref, Enclos_Type); Decl := Last (Decls); Append_To (Args, New_Occurrence_Of (Defining_Identifier (Decl), Loc)); Append_List (Decls, Res); end if; else Decls := No_List; Decl := Empty; end if; -- Add discriminant values if discriminants are present if Has_Discriminants (Full_Init_Type) then Discr := First_Discriminant (Full_Init_Type); while Present (Discr) loop -- If this is a discriminated concurrent type, the init_proc -- for the corresponding record is being called. Use that -- type directly to find the discriminant value, to handle -- properly intervening renamed discriminants. declare T : Entity_Id := Full_Type; begin if Is_Protected_Type (T) then T := Corresponding_Record_Type (T); elsif Is_Private_Type (T) and then Present (Underlying_Full_View (T)) and then Is_Protected_Type (Underlying_Full_View (T)) then T := Corresponding_Record_Type (Underlying_Full_View (T)); end if; Arg := Get_Discriminant_Value ( Discr, T, Discriminant_Constraint (Full_Type)); end; if In_Init_Proc then -- Replace any possible references to the discriminant in the -- call to the record initialization procedure with references -- to the appropriate formal parameter. if Nkind (Arg) = N_Identifier and then Ekind (Entity (Arg)) = E_Discriminant then Arg := New_Reference_To (Discriminal (Entity (Arg)), Loc); -- Case of access discriminants. We replace the reference -- to the type by a reference to the actual object elsif Nkind (Arg) = N_Attribute_Reference and then Is_Access_Type (Etype (Arg)) and then Is_Entity_Name (Prefix (Arg)) and then Is_Type (Entity (Prefix (Arg))) then Arg := Make_Attribute_Reference (Loc, Prefix => New_Copy (Prefix (Id_Ref)), Attribute_Name => Name_Unrestricted_Access); -- Otherwise make a copy of the default expression. Note -- that we use the current Sloc for this, because we do not -- want the call to appear to be at the declaration point. -- Within the expression, replace discriminants with their -- discriminals. else Arg := New_Copy_Tree (Arg, Map => Discr_Map, New_Sloc => Loc); end if; else if Is_Constrained (Full_Type) then Arg := Duplicate_Subexpr_No_Checks (Arg); else -- The constraints come from the discriminant default -- exps, they must be reevaluated, so we use New_Copy_Tree -- but we ensure the proper Sloc (for any embedded calls). Arg := New_Copy_Tree (Arg, New_Sloc => Loc); end if; end if; -- Ada 2005 (AI-287) In case of default initialized components, -- we need to generate the corresponding selected component node -- to access the discriminant value. In other cases this is not -- required because we are inside the init proc and we use the -- corresponding formal. if With_Default_Init and then Nkind (Id_Ref) = N_Selected_Component then Append_To (Args, Make_Selected_Component (Loc, Prefix => New_Copy_Tree (Prefix (Id_Ref)), Selector_Name => Arg)); else Append_To (Args, Arg); end if; Next_Discriminant (Discr); end loop; end if; -- If this is a call to initialize the parent component of a derived -- tagged type, indicate that the tag should not be set in the parent. if Is_Tagged_Type (Full_Init_Type) and then not Is_CPP_Class (Full_Init_Type) and then Nkind (Id_Ref) = N_Selected_Component and then Chars (Selector_Name (Id_Ref)) = Name_uParent then Append_To (Args, New_Occurrence_Of (Standard_False, Loc)); end if; Append_To (Res, Make_Procedure_Call_Statement (Loc, Name => New_Occurrence_Of (Proc, Loc), Parameter_Associations => Args)); if Controlled_Type (Typ) and then Nkind (Id_Ref) = N_Selected_Component then if Chars (Selector_Name (Id_Ref)) /= Name_uParent then Append_List_To (Res, Make_Init_Call ( Ref => New_Copy_Tree (First_Arg), Typ => Typ, Flist_Ref => Find_Final_List (Typ, New_Copy_Tree (First_Arg)), With_Attach => Make_Integer_Literal (Loc, 1))); -- If the enclosing type is an extension with new controlled -- components, it has his own record controller. If the parent -- also had a record controller, attach it to the new one. -- Build_Init_Statements relies on the fact that in this specific -- case the last statement of the result is the attach call to -- the controller. If this is changed, it must be synchronized. elsif Present (Enclos_Type) and then Has_New_Controlled_Component (Enclos_Type) and then Has_Controlled_Component (Typ) then if Is_Return_By_Reference_Type (Typ) then Controller_Typ := RTE (RE_Limited_Record_Controller); else Controller_Typ := RTE (RE_Record_Controller); end if; Append_List_To (Res, Make_Init_Call ( Ref => Make_Selected_Component (Loc, Prefix => New_Copy_Tree (First_Arg), Selector_Name => Make_Identifier (Loc, Name_uController)), Typ => Controller_Typ, Flist_Ref => Find_Final_List (Typ, New_Copy_Tree (First_Arg)), With_Attach => Make_Integer_Literal (Loc, 1))); end if; end if; return Res; exception when RE_Not_Available => return Empty_List; end Build_Initialization_Call; --------------------------- -- Build_Master_Renaming -- --------------------------- procedure Build_Master_Renaming (N : Node_Id; T : Entity_Id) is Loc : constant Source_Ptr := Sloc (N); M_Id : Entity_Id; Decl : Node_Id; begin -- Nothing to do if there is no task hierarchy if Restriction_Active (No_Task_Hierarchy) then return; end if; M_Id := Make_Defining_Identifier (Loc, New_External_Name (Chars (T), 'M')); Decl := Make_Object_Renaming_Declaration (Loc, Defining_Identifier => M_Id, Subtype_Mark => New_Reference_To (RTE (RE_Master_Id), Loc), Name => Make_Identifier (Loc, Name_uMaster)); Insert_Before (N, Decl); Analyze (Decl); Set_Master_Id (T, M_Id); exception when RE_Not_Available => return; end Build_Master_Renaming; ---------------------------- -- Build_Record_Init_Proc -- ---------------------------- procedure Build_Record_Init_Proc (N : Node_Id; Pe : Entity_Id) is Loc : Source_Ptr := Sloc (N); Discr_Map : constant Elist_Id := New_Elmt_List; Proc_Id : Entity_Id; Rec_Type : Entity_Id; Set_Tag : Entity_Id := Empty; function Build_Assignment (Id : Entity_Id; N : Node_Id) return List_Id; -- Build a assignment statement node which assigns to record -- component its default expression if defined. The left hand side -- of the assignment is marked Assignment_OK so that initialization -- of limited private records works correctly, Return also the -- adjustment call for controlled objects procedure Build_Discriminant_Assignments (Statement_List : List_Id); -- If the record has discriminants, adds assignment statements to -- statement list to initialize the discriminant values from the -- arguments of the initialization procedure. function Build_Init_Statements (Comp_List : Node_Id) return List_Id; -- Build a list representing a sequence of statements which initialize -- components of the given component list. This may involve building -- case statements for the variant parts. function Build_Init_Call_Thru (Parameters : List_Id) return List_Id; -- Given a non-tagged type-derivation that declares discriminants, -- such as -- -- type R (R1, R2 : Integer) is record ... end record; -- -- type D (D1 : Integer) is new R (1, D1); -- -- we make the _init_proc of D be -- -- procedure _init_proc(X : D; D1 : Integer) is -- begin -- _init_proc( R(X), 1, D1); -- end _init_proc; -- -- This function builds the call statement in this _init_proc. procedure Build_Init_Procedure; -- Build the tree corresponding to the procedure specification and body -- of the initialization procedure (by calling all the preceding -- auxiliary routines), and install it as the _init TSS. procedure Build_Record_Checks (S : Node_Id; Check_List : List_Id); -- Add range checks to components of disciminated records. S is a -- subtype indication of a record component. Check_List is a list -- to which the check actions are appended. function Component_Needs_Simple_Initialization (T : Entity_Id) return Boolean; -- Determines if a component needs simple initialization, given its type -- T. This is the same as Needs_Simple_Initialization except for the -- following difference: the types Tag, Interface_Tag, and Vtable_Ptr -- which are access types which would normally require simple -- initialization to null, do not require initialization as components, -- since they are explicitly initialized by other means. procedure Constrain_Array (SI : Node_Id; Check_List : List_Id); -- Called from Build_Record_Checks. -- Apply a list of index constraints to an unconstrained array type. -- The first parameter is the entity for the resulting subtype. -- Check_List is a list to which the check actions are appended. procedure Constrain_Index (Index : Node_Id; S : Node_Id; Check_List : List_Id); -- Called from Build_Record_Checks. -- Process an index constraint in a constrained array declaration. -- The constraint can be a subtype name, or a range with or without -- an explicit subtype mark. The index is the corresponding index of the -- unconstrained array. S is the range expression. Check_List is a list -- to which the check actions are appended. function Parent_Subtype_Renaming_Discrims return Boolean; -- Returns True for base types N that rename discriminants, else False function Requires_Init_Proc (Rec_Id : Entity_Id) return Boolean; -- Determines whether a record initialization procedure needs to be -- generated for the given record type. ---------------------- -- Build_Assignment -- ---------------------- function Build_Assignment (Id : Entity_Id; N : Node_Id) return List_Id is Exp : Node_Id := N; Lhs : Node_Id; Typ : constant Entity_Id := Underlying_Type (Etype (Id)); Kind : Node_Kind := Nkind (N); Res : List_Id; begin Loc := Sloc (N); Lhs := Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Occurrence_Of (Id, Loc)); Set_Assignment_OK (Lhs); -- Case of an access attribute applied to the current instance. -- Replace the reference to the type by a reference to the actual -- object. (Note that this handles the case of the top level of -- the expression being given by such an attribute, but does not -- cover uses nested within an initial value expression. Nested -- uses are unlikely to occur in practice, but are theoretically -- possible. It is not clear how to handle them without fully -- traversing the expression. ??? if Kind = N_Attribute_Reference and then (Attribute_Name (N) = Name_Unchecked_Access or else Attribute_Name (N) = Name_Unrestricted_Access) and then Is_Entity_Name (Prefix (N)) and then Is_Type (Entity (Prefix (N))) and then Entity (Prefix (N)) = Rec_Type then Exp := Make_Attribute_Reference (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Attribute_Name => Name_Unrestricted_Access); end if; -- Ada 2005 (AI-231): Add the run-time check if required if Ada_Version >= Ada_05 and then Can_Never_Be_Null (Etype (Id)) -- Lhs then if Nkind (Exp) = N_Null then return New_List ( Make_Raise_Constraint_Error (Sloc (Exp), Reason => CE_Null_Not_Allowed)); elsif Present (Etype (Exp)) and then not Can_Never_Be_Null (Etype (Exp)) then Install_Null_Excluding_Check (Exp); end if; end if; -- Take a copy of Exp to ensure that later copies of this -- component_declaration in derived types see the original tree, -- not a node rewritten during expansion of the init_proc. Exp := New_Copy_Tree (Exp); Res := New_List ( Make_Assignment_Statement (Loc, Name => Lhs, Expression => Exp)); Set_No_Ctrl_Actions (First (Res)); -- Adjust the tag if tagged (because of possible view conversions). -- Suppress the tag adjustment when Java_VM because JVM tags are -- represented implicitly in objects. if Is_Tagged_Type (Typ) and then not Java_VM then Append_To (Res, Make_Assignment_Statement (Loc, Name => Make_Selected_Component (Loc, Prefix => New_Copy_Tree (Lhs), Selector_Name => New_Reference_To (First_Tag_Component (Typ), Loc)), Expression => Unchecked_Convert_To (RTE (RE_Tag), New_Reference_To (Node (First_Elmt (Access_Disp_Table (Typ))), Loc)))); end if; -- Adjust the component if controlled except if it is an -- aggregate that will be expanded inline if Kind = N_Qualified_Expression then Kind := Nkind (Expression (N)); end if; if Controlled_Type (Typ) and then not (Kind = N_Aggregate or else Kind = N_Extension_Aggregate) then Append_List_To (Res, Make_Adjust_Call ( Ref => New_Copy_Tree (Lhs), Typ => Etype (Id), Flist_Ref => Find_Final_List (Etype (Id), New_Copy_Tree (Lhs)), With_Attach => Make_Integer_Literal (Loc, 1))); end if; return Res; exception when RE_Not_Available => return Empty_List; end Build_Assignment; ------------------------------------ -- Build_Discriminant_Assignments -- ------------------------------------ procedure Build_Discriminant_Assignments (Statement_List : List_Id) is D : Entity_Id; Is_Tagged : constant Boolean := Is_Tagged_Type (Rec_Type); begin if Has_Discriminants (Rec_Type) and then not Is_Unchecked_Union (Rec_Type) then D := First_Discriminant (Rec_Type); while Present (D) loop -- Don't generate the assignment for discriminants in derived -- tagged types if the discriminant is a renaming of some -- ancestor discriminant. This initialization will be done -- when initializing the _parent field of the derived record. if Is_Tagged and then Present (Corresponding_Discriminant (D)) then null; else Loc := Sloc (D); Append_List_To (Statement_List, Build_Assignment (D, New_Reference_To (Discriminal (D), Loc))); end if; Next_Discriminant (D); end loop; end if; end Build_Discriminant_Assignments; -------------------------- -- Build_Init_Call_Thru -- -------------------------- function Build_Init_Call_Thru (Parameters : List_Id) return List_Id is Parent_Proc : constant Entity_Id := Base_Init_Proc (Etype (Rec_Type)); Parent_Type : constant Entity_Id := Etype (First_Formal (Parent_Proc)); Uparent_Type : constant Entity_Id := Underlying_Type (Parent_Type); First_Discr_Param : Node_Id; Parent_Discr : Entity_Id; First_Arg : Node_Id; Args : List_Id; Arg : Node_Id; Res : List_Id; begin -- First argument (_Init) is the object to be initialized. -- ??? not sure where to get a reasonable Loc for First_Arg First_Arg := OK_Convert_To (Parent_Type, New_Reference_To (Defining_Identifier (First (Parameters)), Loc)); Set_Etype (First_Arg, Parent_Type); Args := New_List (Convert_Concurrent (First_Arg, Rec_Type)); -- In the tasks case, -- add _Master as the value of the _Master parameter -- add _Chain as the value of the _Chain parameter. -- add _Task_Name as the value of the _Task_Name parameter. -- At the outer level, these will be variables holding the -- corresponding values obtained from GNARL or the expander. -- -- At inner levels, they will be the parameters passed down through -- the outer routines. First_Discr_Param := Next (First (Parameters)); if Has_Task (Rec_Type) then if Restriction_Active (No_Task_Hierarchy) then -- See comments in System.Tasking.Initialization.Init_RTS -- for the value 3. Append_To (Args, Make_Integer_Literal (Loc, 3)); else Append_To (Args, Make_Identifier (Loc, Name_uMaster)); end if; Append_To (Args, Make_Identifier (Loc, Name_uChain)); Append_To (Args, Make_Identifier (Loc, Name_uTask_Name)); First_Discr_Param := Next (Next (Next (First_Discr_Param))); end if; -- Append discriminant values if Has_Discriminants (Uparent_Type) then pragma Assert (not Is_Tagged_Type (Uparent_Type)); Parent_Discr := First_Discriminant (Uparent_Type); while Present (Parent_Discr) loop -- Get the initial value for this discriminant -- ??? needs to be cleaned up to use parent_Discr_Constr -- directly. declare Discr_Value : Elmt_Id := First_Elmt (Stored_Constraint (Rec_Type)); Discr : Entity_Id := First_Stored_Discriminant (Uparent_Type); begin while Original_Record_Component (Parent_Discr) /= Discr loop Next_Stored_Discriminant (Discr); Next_Elmt (Discr_Value); end loop; Arg := Node (Discr_Value); end; -- Append it to the list if Nkind (Arg) = N_Identifier and then Ekind (Entity (Arg)) = E_Discriminant then Append_To (Args, New_Reference_To (Discriminal (Entity (Arg)), Loc)); -- Case of access discriminants. We replace the reference -- to the type by a reference to the actual object -- ??? why is this code deleted without comment -- elsif Nkind (Arg) = N_Attribute_Reference -- and then Is_Entity_Name (Prefix (Arg)) -- and then Is_Type (Entity (Prefix (Arg))) -- then -- Append_To (Args, -- Make_Attribute_Reference (Loc, -- Prefix => New_Copy (Prefix (Id_Ref)), -- Attribute_Name => Name_Unrestricted_Access)); else Append_To (Args, New_Copy (Arg)); end if; Next_Discriminant (Parent_Discr); end loop; end if; Res := New_List ( Make_Procedure_Call_Statement (Loc, Name => New_Occurrence_Of (Parent_Proc, Loc), Parameter_Associations => Args)); return Res; end Build_Init_Call_Thru; -------------------------- -- Build_Init_Procedure -- -------------------------- procedure Build_Init_Procedure is Body_Node : Node_Id; Handled_Stmt_Node : Node_Id; Parameters : List_Id; Proc_Spec_Node : Node_Id; Body_Stmts : List_Id; Record_Extension_Node : Node_Id; Init_Tag : Node_Id; procedure Init_Secondary_Tags (Typ : Entity_Id); -- Ada 2005 (AI-251): Initialize the tags of all the secondary -- tables associated with abstract interface types ------------------------- -- Init_Secondary_Tags -- ------------------------- procedure Init_Secondary_Tags (Typ : Entity_Id) is ADT : Elmt_Id; procedure Init_Secondary_Tags_Internal (Typ : Entity_Id); -- Internal subprogram used to recursively climb to the root type ---------------------------------- -- Init_Secondary_Tags_Internal -- ---------------------------------- procedure Init_Secondary_Tags_Internal (Typ : Entity_Id) is E : Entity_Id; Aux_N : Node_Id; Iface : Entity_Id; begin -- Climb to the ancestor (if any) handling private types if Present (Full_View (Etype (Typ))) then if Full_View (Etype (Typ)) /= Typ then Init_Secondary_Tags_Internal (Full_View (Etype (Typ))); end if; elsif Etype (Typ) /= Typ then Init_Secondary_Tags_Internal (Etype (Typ)); end if; if Present (Abstract_Interfaces (Typ)) and then not Is_Empty_Elmt_List (Abstract_Interfaces (Typ)) then E := First_Entity (Typ); while Present (E) loop if Is_Tag (E) and then Chars (E) /= Name_uTag then Aux_N := Node (ADT); pragma Assert (Present (Aux_N)); Iface := Find_Interface (Typ, E); -- Initialize the pointer to the secondary DT -- associated with the interface Append_To (Body_Stmts, Make_Assignment_Statement (Loc, Name => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Reference_To (E, Loc)), Expression => New_Reference_To (Aux_N, Loc))); -- Generate: -- Set_Offset_To_Top (Init, Iface'Tag, n); Append_To (Body_Stmts, Make_Procedure_Call_Statement (Loc, Name => New_Reference_To (RTE (RE_Set_Offset_To_Top), Loc), Parameter_Associations => New_List ( Make_Attribute_Reference (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Attribute_Name => Name_Address), Unchecked_Convert_To (RTE (RE_Tag), New_Reference_To (Node (First_Elmt (Access_Disp_Table (Iface))), Loc)), Unchecked_Convert_To (RTE (RE_Storage_Offset), Make_Attribute_Reference (Loc, Prefix => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Reference_To (E, Loc)), Attribute_Name => Name_Position))))); Next_Elmt (ADT); end if; Next_Entity (E); end loop; end if; end Init_Secondary_Tags_Internal; -- Start of processing for Init_Secondary_Tags begin -- Skip the first _Tag, which is the main tag of the -- tagged type. Following tags correspond with abstract -- interfaces. ADT := Next_Elmt (First_Elmt (Access_Disp_Table (Typ))); -- Handle private types if Present (Full_View (Typ)) then Init_Secondary_Tags_Internal (Full_View (Typ)); else Init_Secondary_Tags_Internal (Typ); end if; end Init_Secondary_Tags; -- Start of processing for Build_Init_Procedure begin Body_Stmts := New_List; Body_Node := New_Node (N_Subprogram_Body, Loc); Proc_Id := Make_Defining_Identifier (Loc, Chars => Make_Init_Proc_Name (Rec_Type)); Set_Ekind (Proc_Id, E_Procedure); Proc_Spec_Node := New_Node (N_Procedure_Specification, Loc); Set_Defining_Unit_Name (Proc_Spec_Node, Proc_Id); Parameters := Init_Formals (Rec_Type); Append_List_To (Parameters, Build_Discriminant_Formals (Rec_Type, True)); -- For tagged types, we add a flag to indicate whether the routine -- is called to initialize a parent component in the init_proc of -- a type extension. If the flag is false, we do not set the tag -- because it has been set already in the extension. if Is_Tagged_Type (Rec_Type) and then not Is_CPP_Class (Rec_Type) then Set_Tag := Make_Defining_Identifier (Loc, New_Internal_Name ('P')); Append_To (Parameters, Make_Parameter_Specification (Loc, Defining_Identifier => Set_Tag, Parameter_Type => New_Occurrence_Of (Standard_Boolean, Loc), Expression => New_Occurrence_Of (Standard_True, Loc))); end if; Set_Parameter_Specifications (Proc_Spec_Node, Parameters); Set_Specification (Body_Node, Proc_Spec_Node); Set_Declarations (Body_Node, New_List); if Parent_Subtype_Renaming_Discrims then -- N is a Derived_Type_Definition that renames the parameters -- of the ancestor type. We init it by expanding our discrims -- and call the ancestor _init_proc with a type-converted object Append_List_To (Body_Stmts, Build_Init_Call_Thru (Parameters)); elsif Nkind (Type_Definition (N)) = N_Record_Definition then Build_Discriminant_Assignments (Body_Stmts); if not Null_Present (Type_Definition (N)) then Append_List_To (Body_Stmts, Build_Init_Statements ( Component_List (Type_Definition (N)))); end if; else -- N is a Derived_Type_Definition with a possible non-empty -- extension. The initialization of a type extension consists -- in the initialization of the components in the extension. Build_Discriminant_Assignments (Body_Stmts); Record_Extension_Node := Record_Extension_Part (Type_Definition (N)); if not Null_Present (Record_Extension_Node) then declare Stmts : constant List_Id := Build_Init_Statements ( Component_List (Record_Extension_Node)); begin -- The parent field must be initialized first because -- the offset of the new discriminants may depend on it Prepend_To (Body_Stmts, Remove_Head (Stmts)); Append_List_To (Body_Stmts, Stmts); end; end if; end if; -- Add here the assignment to instantiate the Tag -- The assignement corresponds to the code: -- _Init._Tag := Typ'Tag; -- Suppress the tag assignment when Java_VM because JVM tags are -- represented implicitly in objects. if Is_Tagged_Type (Rec_Type) and then not Is_CPP_Class (Rec_Type) and then not Java_VM then Init_Tag := Make_Assignment_Statement (Loc, Name => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Reference_To (First_Tag_Component (Rec_Type), Loc)), Expression => New_Reference_To (Node (First_Elmt (Access_Disp_Table (Rec_Type))), Loc)); -- The tag must be inserted before the assignments to other -- components, because the initial value of the component may -- depend ot the tag (eg. through a dispatching operation on -- an access to the current type). The tag assignment is not done -- when initializing the parent component of a type extension, -- because in that case the tag is set in the extension. -- Extensions of imported C++ classes add a final complication, -- because we cannot inhibit tag setting in the constructor for -- the parent. In that case we insert the tag initialization -- after the calls to initialize the parent. Init_Tag := Make_If_Statement (Loc, Condition => New_Occurrence_Of (Set_Tag, Loc), Then_Statements => New_List (Init_Tag)); if not Is_CPP_Class (Etype (Rec_Type)) then Prepend_To (Body_Stmts, Init_Tag); -- Ada 2005 (AI-251): Initialization of all the tags -- corresponding with abstract interfaces if Ada_Version >= Ada_05 and then not Is_Interface (Rec_Type) then Init_Secondary_Tags (Rec_Type); end if; else declare Nod : Node_Id := First (Body_Stmts); begin -- We assume the first init_proc call is for the parent while Present (Next (Nod)) and then (Nkind (Nod) /= N_Procedure_Call_Statement or else not Is_Init_Proc (Name (Nod))) loop Nod := Next (Nod); end loop; Insert_After (Nod, Init_Tag); end; end if; end if; Handled_Stmt_Node := New_Node (N_Handled_Sequence_Of_Statements, Loc); Set_Statements (Handled_Stmt_Node, Body_Stmts); Set_Exception_Handlers (Handled_Stmt_Node, No_List); Set_Handled_Statement_Sequence (Body_Node, Handled_Stmt_Node); if not Debug_Generated_Code then Set_Debug_Info_Off (Proc_Id); end if; -- Associate Init_Proc with type, and determine if the procedure -- is null (happens because of the Initialize_Scalars pragma case, -- where we have to generate a null procedure in case it is called -- by a client with Initialize_Scalars set). Such procedures have -- to be generated, but do not have to be called, so we mark them -- as null to suppress the call. Set_Init_Proc (Rec_Type, Proc_Id); if List_Length (Body_Stmts) = 1 and then Nkind (First (Body_Stmts)) = N_Null_Statement then Set_Is_Null_Init_Proc (Proc_Id); end if; end Build_Init_Procedure; --------------------------- -- Build_Init_Statements -- --------------------------- function Build_Init_Statements (Comp_List : Node_Id) return List_Id is Check_List : constant List_Id := New_List; Alt_List : List_Id; Statement_List : List_Id; Stmts : List_Id; Per_Object_Constraint_Components : Boolean; Decl : Node_Id; Variant : Node_Id; Id : Entity_Id; Typ : Entity_Id; function Has_Access_Constraint (E : Entity_Id) return Boolean; -- Components with access discriminants that depend on the current -- instance must be initialized after all other components. --------------------------- -- Has_Access_Constraint -- --------------------------- function Has_Access_Constraint (E : Entity_Id) return Boolean is Disc : Entity_Id; T : constant Entity_Id := Etype (E); begin if Has_Per_Object_Constraint (E) and then Has_Discriminants (T) then Disc := First_Discriminant (T); while Present (Disc) loop if Is_Access_Type (Etype (Disc)) then return True; end if; Next_Discriminant (Disc); end loop; return False; else return False; end if; end Has_Access_Constraint; -- Start of processing for Build_Init_Statements begin if Null_Present (Comp_List) then return New_List (Make_Null_Statement (Loc)); end if; Statement_List := New_List; -- Loop through components, skipping pragmas, in 2 steps. The first -- step deals with regular components. The second step deals with -- components have per object constraints, and no explicit initia- -- lization. Per_Object_Constraint_Components := False; -- First step : regular components Decl := First_Non_Pragma (Component_Items (Comp_List)); while Present (Decl) loop Loc := Sloc (Decl); Build_Record_Checks (Subtype_Indication (Component_Definition (Decl)), Check_List); Id := Defining_Identifier (Decl); Typ := Etype (Id); if Has_Access_Constraint (Id) and then No (Expression (Decl)) then -- Skip processing for now and ask for a second pass Per_Object_Constraint_Components := True; else -- Case of explicit initialization if Present (Expression (Decl)) then Stmts := Build_Assignment (Id, Expression (Decl)); -- Case of composite component with its own Init_Proc elsif not Is_Interface (Typ) and then Has_Non_Null_Base_Init_Proc (Typ) then Stmts := Build_Initialization_Call (Loc, Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Occurrence_Of (Id, Loc)), Typ, True, Rec_Type, Discr_Map => Discr_Map); -- Case of component needing simple initialization elsif Component_Needs_Simple_Initialization (Typ) then Stmts := Build_Assignment (Id, Get_Simple_Init_Val (Typ, Loc, Esize (Id))); -- Nothing needed for this case else Stmts := No_List; end if; if Present (Check_List) then Append_List_To (Statement_List, Check_List); end if; if Present (Stmts) then -- Add the initialization of the record controller before -- the _Parent field is attached to it when the attachment -- can occur. It does not work to simply initialize the -- controller first: it must be initialized after the parent -- if the parent holds discriminants that can be used -- to compute the offset of the controller. We assume here -- that the last statement of the initialization call is the -- attachement of the parent (see Build_Initialization_Call) if Chars (Id) = Name_uController and then Rec_Type /= Etype (Rec_Type) and then Has_Controlled_Component (Etype (Rec_Type)) and then Has_New_Controlled_Component (Rec_Type) then Insert_List_Before (Last (Statement_List), Stmts); else Append_List_To (Statement_List, Stmts); end if; end if; end if; Next_Non_Pragma (Decl); end loop; if Per_Object_Constraint_Components then -- Second pass: components with per-object constraints Decl := First_Non_Pragma (Component_Items (Comp_List)); while Present (Decl) loop Loc := Sloc (Decl); Id := Defining_Identifier (Decl); Typ := Etype (Id); if Has_Access_Constraint (Id) and then No (Expression (Decl)) then if Has_Non_Null_Base_Init_Proc (Typ) then Append_List_To (Statement_List, Build_Initialization_Call (Loc, Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => New_Occurrence_Of (Id, Loc)), Typ, True, Rec_Type, Discr_Map => Discr_Map)); elsif Component_Needs_Simple_Initialization (Typ) then Append_List_To (Statement_List, Build_Assignment (Id, Get_Simple_Init_Val (Typ, Loc, Esize (Id)))); end if; end if; Next_Non_Pragma (Decl); end loop; end if; -- Process the variant part if Present (Variant_Part (Comp_List)) then Alt_List := New_List; Variant := First_Non_Pragma (Variants (Variant_Part (Comp_List))); while Present (Variant) loop Loc := Sloc (Variant); Append_To (Alt_List, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_Copy_List (Discrete_Choices (Variant)), Statements => Build_Init_Statements (Component_List (Variant)))); Next_Non_Pragma (Variant); end loop; -- The expression of the case statement which is a reference -- to one of the discriminants is replaced by the appropriate -- formal parameter of the initialization procedure. Append_To (Statement_List, Make_Case_Statement (Loc, Expression => New_Reference_To (Discriminal ( Entity (Name (Variant_Part (Comp_List)))), Loc), Alternatives => Alt_List)); end if; -- For a task record type, add the task create call and calls -- to bind any interrupt (signal) entries. if Is_Task_Record_Type (Rec_Type) then -- In the case of the restricted run time the ATCB has already -- been preallocated. if Restricted_Profile then Append_To (Statement_List, Make_Assignment_Statement (Loc, Name => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => Make_Identifier (Loc, Name_uTask_Id)), Expression => Make_Attribute_Reference (Loc, Prefix => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => Make_Identifier (Loc, Name_uATCB)), Attribute_Name => Name_Unchecked_Access))); end if; Append_To (Statement_List, Make_Task_Create_Call (Rec_Type)); declare Task_Type : constant Entity_Id := Corresponding_Concurrent_Type (Rec_Type); Task_Decl : constant Node_Id := Parent (Task_Type); Task_Def : constant Node_Id := Task_Definition (Task_Decl); Vis_Decl : Node_Id; Ent : Entity_Id; begin if Present (Task_Def) then Vis_Decl := First (Visible_Declarations (Task_Def)); while Present (Vis_Decl) loop Loc := Sloc (Vis_Decl); if Nkind (Vis_Decl) = N_Attribute_Definition_Clause then if Get_Attribute_Id (Chars (Vis_Decl)) = Attribute_Address then Ent := Entity (Name (Vis_Decl)); if Ekind (Ent) = E_Entry then Append_To (Statement_List, Make_Procedure_Call_Statement (Loc, Name => New_Reference_To ( RTE (RE_Bind_Interrupt_To_Entry), Loc), Parameter_Associations => New_List ( Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_uInit), Selector_Name => Make_Identifier (Loc, Name_uTask_Id)), Entry_Index_Expression ( Loc, Ent, Empty, Task_Type), Expression (Vis_Decl)))); end if; end if; end if; Next (Vis_Decl); end loop; end if; end; end if; -- For a protected type, add statements generated by -- Make_Initialize_Protection. if Is_Protected_Record_Type (Rec_Type) then Append_List_To (Statement_List, Make_Initialize_Protection (Rec_Type)); end if; -- If no initializations when generated for component declarations -- corresponding to this Statement_List, append a null statement -- to the Statement_List to make it a valid Ada tree. if Is_Empty_List (Statement_List) then Append (New_Node (N_Null_Statement, Loc), Statement_List); end if; return Statement_List; exception when RE_Not_Available => return Empty_List; end Build_Init_Statements; ------------------------- -- Build_Record_Checks -- ------------------------- procedure Build_Record_Checks (S : Node_Id; Check_List : List_Id) is Subtype_Mark_Id : Entity_Id; begin if Nkind (S) = N_Subtype_Indication then Find_Type (Subtype_Mark (S)); Subtype_Mark_Id := Entity (Subtype_Mark (S)); -- Remaining processing depends on type case Ekind (Subtype_Mark_Id) is when Array_Kind => Constrain_Array (S, Check_List); when others => null; end case; end if; end Build_Record_Checks; ------------------------------------------- -- Component_Needs_Simple_Initialization -- ------------------------------------------- function Component_Needs_Simple_Initialization (T : Entity_Id) return Boolean is begin return Needs_Simple_Initialization (T) and then not Is_RTE (T, RE_Tag) and then not Is_RTE (T, RE_Vtable_Ptr) and then not Is_RTE (T, RE_Interface_Tag); -- Ada 2005 (AI-251) end Component_Needs_Simple_Initialization; --------------------- -- Constrain_Array -- --------------------- procedure Constrain_Array (SI : Node_Id; Check_List : List_Id) is C : constant Node_Id := Constraint (SI); Number_Of_Constraints : Nat := 0; Index : Node_Id; S, T : Entity_Id; begin T := Entity (Subtype_Mark (SI)); if Ekind (T) in Access_Kind then T := Designated_Type (T); end if; S := First (Constraints (C)); while Present (S) loop Number_Of_Constraints := Number_Of_Constraints + 1; Next (S); end loop; -- In either case, the index constraint must provide a discrete -- range for each index of the array type and the type of each -- discrete range must be the same as that of the corresponding -- index. (RM 3.6.1) S := First (Constraints (C)); Index := First_Index (T); Analyze (Index); -- Apply constraints to each index type for J in 1 .. Number_Of_Constraints loop Constrain_Index (Index, S, Check_List); Next (Index); Next (S); end loop; end Constrain_Array; --------------------- -- Constrain_Index -- --------------------- procedure Constrain_Index (Index : Node_Id; S : Node_Id; Check_List : List_Id) is T : constant Entity_Id := Etype (Index); begin if Nkind (S) = N_Range then Process_Range_Expr_In_Decl (S, T, Check_List); end if; end Constrain_Index; -------------------------------------- -- Parent_Subtype_Renaming_Discrims -- -------------------------------------- function Parent_Subtype_Renaming_Discrims return Boolean is De : Entity_Id; Dp : Entity_Id; begin if Base_Type (Pe) /= Pe then return False; end if; if Etype (Pe) = Pe or else not Has_Discriminants (Pe) or else Is_Constrained (Pe) or else Is_Tagged_Type (Pe) then return False; end if; -- If there are no explicit stored discriminants we have inherited -- the root type discriminants so far, so no renamings occurred. if First_Discriminant (Pe) = First_Stored_Discriminant (Pe) then return False; end if; -- Check if we have done some trivial renaming of the parent -- discriminants, i.e. someting like -- -- type DT (X1,X2: int) is new PT (X1,X2); De := First_Discriminant (Pe); Dp := First_Discriminant (Etype (Pe)); while Present (De) loop pragma Assert (Present (Dp)); if Corresponding_Discriminant (De) /= Dp then return True; end if; Next_Discriminant (De); Next_Discriminant (Dp); end loop; return Present (Dp); end Parent_Subtype_Renaming_Discrims; ------------------------ -- Requires_Init_Proc -- ------------------------ function Requires_Init_Proc (Rec_Id : Entity_Id) return Boolean is Comp_Decl : Node_Id; Id : Entity_Id; Typ : Entity_Id; begin -- Definitely do not need one if specifically suppressed if Suppress_Init_Proc (Rec_Id) then return False; end if; -- If it is a type derived from a type with unknown discriminants, -- we cannot build an initialization procedure for it. if Has_Unknown_Discriminants (Rec_Id) then return False; end if; -- Otherwise we need to generate an initialization procedure if -- Is_CPP_Class is False and at least one of the following applies: -- 1. Discriminants are present, since they need to be initialized -- with the appropriate discriminant constraint expressions. -- However, the discriminant of an unchecked union does not -- count, since the discriminant is not present. -- 2. The type is a tagged type, since the implicit Tag component -- needs to be initialized with a pointer to the dispatch table. -- 3. The type contains tasks -- 4. One or more components has an initial value -- 5. One or more components is for a type which itself requires -- an initialization procedure. -- 6. One or more components is a type that requires simple -- initialization (see Needs_Simple_Initialization), except -- that types Tag and Interface_Tag are excluded, since fields -- of these types are initialized by other means. -- 7. The type is the record type built for a task type (since at -- the very least, Create_Task must be called) -- 8. The type is the record type built for a protected type (since -- at least Initialize_Protection must be called) -- 9. The type is marked as a public entity. The reason we add this -- case (even if none of the above apply) is to properly handle -- Initialize_Scalars. If a package is compiled without an IS -- pragma, and the client is compiled with an IS pragma, then -- the client will think an initialization procedure is present -- and call it, when in fact no such procedure is required, but -- since the call is generated, there had better be a routine -- at the other end of the call, even if it does nothing!) -- Note: the reason we exclude the CPP_Class case is ??? if Is_CPP_Class (Rec_Id) then return False; elsif not Restriction_Active (No_Initialize_Scalars) and then Is_Public (Rec_Id) then return True; elsif (Has_Discriminants (Rec_Id) and then not Is_Unchecked_Union (Rec_Id)) or else Is_Tagged_Type (Rec_Id) or else Is_Concurrent_Record_Type (Rec_Id) or else Has_Task (Rec_Id) then return True; end if; Id := First_Component (Rec_Id); while Present (Id) loop Comp_Decl := Parent (Id); Typ := Etype (Id); if Present (Expression (Comp_Decl)) or else Has_Non_Null_Base_Init_Proc (Typ) or else Component_Needs_Simple_Initialization (Typ) then return True; end if; Next_Component (Id); end loop; return False; end Requires_Init_Proc; -- Start of processing for Build_Record_Init_Proc begin Rec_Type := Defining_Identifier (N); -- This may be full declaration of a private type, in which case -- the visible entity is a record, and the private entity has been -- exchanged with it in the private part of the current package. -- The initialization procedure is built for the record type, which -- is retrievable from the private entity. if Is_Incomplete_Or_Private_Type (Rec_Type) then Rec_Type := Underlying_Type (Rec_Type); end if; -- If there are discriminants, build the discriminant map to replace -- discriminants by their discriminals in complex bound expressions. -- These only arise for the corresponding records of protected types. if Is_Concurrent_Record_Type (Rec_Type) and then Has_Discriminants (Rec_Type) then declare Disc : Entity_Id; begin Disc := First_Discriminant (Rec_Type); while Present (Disc) loop Append_Elmt (Disc, Discr_Map); Append_Elmt (Discriminal (Disc), Discr_Map); Next_Discriminant (Disc); end loop; end; end if; -- Derived types that have no type extension can use the initialization -- procedure of their parent and do not need a procedure of their own. -- This is only correct if there are no representation clauses for the -- type or its parent, and if the parent has in fact been frozen so -- that its initialization procedure exists. if Is_Derived_Type (Rec_Type) and then not Is_Tagged_Type (Rec_Type) and then not Is_Unchecked_Union (Rec_Type) and then not Has_New_Non_Standard_Rep (Rec_Type) and then not Parent_Subtype_Renaming_Discrims and then Has_Non_Null_Base_Init_Proc (Etype (Rec_Type)) then Copy_TSS (Base_Init_Proc (Etype (Rec_Type)), Rec_Type); -- Otherwise if we need an initialization procedure, then build one, -- mark it as public and inlinable and as having a completion. elsif Requires_Init_Proc (Rec_Type) or else Is_Unchecked_Union (Rec_Type) then Build_Init_Procedure; Set_Is_Public (Proc_Id, Is_Public (Pe)); -- The initialization of protected records is not worth inlining. -- In addition, when compiled for another unit for inlining purposes, -- it may make reference to entities that have not been elaborated -- yet. The initialization of controlled records contains a nested -- clean-up procedure that makes it impractical to inline as well, -- and leads to undefined symbols if inlined in a different unit. -- Similar considerations apply to task types. if not Is_Concurrent_Type (Rec_Type) and then not Has_Task (Rec_Type) and then not Controlled_Type (Rec_Type) then Set_Is_Inlined (Proc_Id); end if; Set_Is_Internal (Proc_Id); Set_Has_Completion (Proc_Id); if not Debug_Generated_Code then Set_Debug_Info_Off (Proc_Id); end if; end if; end Build_Record_Init_Proc; ---------------------------- -- Build_Slice_Assignment -- ---------------------------- -- Generates the following subprogram: -- procedure Assign -- (Source, Target : Array_Type, -- Left_Lo, Left_Hi, Right_Lo, Right_Hi : Index; -- Rev : Boolean) -- is -- Li1 : Index; -- Ri1 : Index; -- begin -- if Rev then -- Li1 := Left_Hi; -- Ri1 := Right_Hi; -- else -- Li1 := Left_Lo; -- Ri1 := Right_Lo; -- end if; -- loop -- if Rev then -- exit when Li1 < Left_Lo; -- else -- exit when Li1 > Left_Hi; -- end if; -- Target (Li1) := Source (Ri1); -- if Rev then -- Li1 := Index'pred (Li1); -- Ri1 := Index'pred (Ri1); -- else -- Li1 := Index'succ (Li1); -- Ri1 := Index'succ (Ri1); -- end if; -- end loop; -- end Assign; procedure Build_Slice_Assignment (Typ : Entity_Id) is Loc : constant Source_Ptr := Sloc (Typ); Index : constant Entity_Id := Base_Type (Etype (First_Index (Typ))); -- Build formal parameters of procedure Larray : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('A')); Rarray : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('R')); Left_Lo : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('L')); Left_Hi : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('L')); Right_Lo : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('R')); Right_Hi : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('R')); Rev : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => New_Internal_Name ('D')); Proc_Name : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => Make_TSS_Name (Typ, TSS_Slice_Assign)); Lnn : constant Entity_Id := Make_Defining_Identifier (Loc, New_Internal_Name ('L')); Rnn : constant Entity_Id := Make_Defining_Identifier (Loc, New_Internal_Name ('R')); -- Subscripts for left and right sides Decls : List_Id; Loops : Node_Id; Stats : List_Id; begin -- Build declarations for indices Decls := New_List; Append_To (Decls, Make_Object_Declaration (Loc, Defining_Identifier => Lnn, Object_Definition => New_Occurrence_Of (Index, Loc))); Append_To (Decls, Make_Object_Declaration (Loc, Defining_Identifier => Rnn, Object_Definition => New_Occurrence_Of (Index, Loc))); Stats := New_List; -- Build initializations for indices declare F_Init : constant List_Id := New_List; B_Init : constant List_Id := New_List; begin Append_To (F_Init, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Lnn, Loc), Expression => New_Occurrence_Of (Left_Lo, Loc))); Append_To (F_Init, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Rnn, Loc), Expression => New_Occurrence_Of (Right_Lo, Loc))); Append_To (B_Init, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Lnn, Loc), Expression => New_Occurrence_Of (Left_Hi, Loc))); Append_To (B_Init, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Rnn, Loc), Expression => New_Occurrence_Of (Right_Hi, Loc))); Append_To (Stats, Make_If_Statement (Loc, Condition => New_Occurrence_Of (Rev, Loc), Then_Statements => B_Init, Else_Statements => F_Init)); end; -- Now construct the assignment statement Loops := Make_Loop_Statement (Loc, Statements => New_List ( Make_Assignment_Statement (Loc, Name => Make_Indexed_Component (Loc, Prefix => New_Occurrence_Of (Larray, Loc), Expressions => New_List (New_Occurrence_Of (Lnn, Loc))), Expression => Make_Indexed_Component (Loc, Prefix => New_Occurrence_Of (Rarray, Loc), Expressions => New_List (New_Occurrence_Of (Rnn, Loc))))), End_Label => Empty); -- Build exit condition declare F_Ass : constant List_Id := New_List; B_Ass : constant List_Id := New_List; begin Append_To (F_Ass, Make_Exit_Statement (Loc, Condition => Make_Op_Gt (Loc, Left_Opnd => New_Occurrence_Of (Lnn, Loc), Right_Opnd => New_Occurrence_Of (Left_Hi, Loc)))); Append_To (B_Ass, Make_Exit_Statement (Loc, Condition => Make_Op_Lt (Loc, Left_Opnd => New_Occurrence_Of (Lnn, Loc), Right_Opnd => New_Occurrence_Of (Left_Lo, Loc)))); Prepend_To (Statements (Loops), Make_If_Statement (Loc, Condition => New_Occurrence_Of (Rev, Loc), Then_Statements => B_Ass, Else_Statements => F_Ass)); end; -- Build the increment/decrement statements declare F_Ass : constant List_Id := New_List; B_Ass : constant List_Id := New_List; begin Append_To (F_Ass, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Lnn, Loc), Expression => Make_Attribute_Reference (Loc, Prefix => New_Occurrence_Of (Index, Loc), Attribute_Name => Name_Succ, Expressions => New_List ( New_Occurrence_Of (Lnn, Loc))))); Append_To (F_Ass, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Rnn, Loc), Expression => Make_Attribute_Reference (Loc, Prefix => New_Occurrence_Of (Index, Loc), Attribute_Name => Name_Succ, Expressions => New_List ( New_Occurrence_Of (Rnn, Loc))))); Append_To (B_Ass, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Lnn, Loc), Expression => Make_Attribute_Reference (Loc, Prefix => New_Occurrence_Of (Index, Loc), Attribute_Name => Name_Pred, Expressions => New_List ( New_Occurrence_Of (Lnn, Loc))))); Append_To (B_Ass, Make_Assignment_Statement (Loc, Name => New_Occurrence_Of (Rnn, Loc), Expression => Make_Attribute_Reference (Loc, Prefix => New_Occurrence_Of (Index, Loc), Attribute_Name => Name_Pred, Expressions => New_List ( New_Occurrence_Of (Rnn, Loc))))); Append_To (Statements (Loops), Make_If_Statement (Loc, Condition => New_Occurrence_Of (Rev, Loc), Then_Statements => B_Ass, Else_Statements => F_Ass)); end; Append_To (Stats, Loops); declare Spec : Node_Id; Formals : List_Id := New_List; begin Formals := New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Larray, Out_Present => True, Parameter_Type => New_Reference_To (Base_Type (Typ), Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Rarray, Parameter_Type => New_Reference_To (Base_Type (Typ), Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Left_Lo, Parameter_Type => New_Reference_To (Index, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Left_Hi, Parameter_Type => New_Reference_To (Index, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Right_Lo, Parameter_Type => New_Reference_To (Index, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Right_Hi, Parameter_Type => New_Reference_To (Index, Loc))); Append_To (Formals, Make_Parameter_Specification (Loc, Defining_Identifier => Rev, Parameter_Type => New_Reference_To (Standard_Boolean, Loc))); Spec := Make_Procedure_Specification (Loc, Defining_Unit_Name => Proc_Name, Parameter_Specifications => Formals); Discard_Node ( Make_Subprogram_Body (Loc, Specification => Spec, Declarations => Decls, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, Statements => Stats))); end; Set_TSS (Typ, Proc_Name); Set_Is_Pure (Proc_Name); end Build_Slice_Assignment; ------------------------------------ -- Build_Variant_Record_Equality -- ------------------------------------ -- Generates: -- function _Equality (X, Y : T) return Boolean is -- begin -- -- Compare discriminants -- if False or else X.D1 /= Y.D1 or else X.D2 /= Y.D2 then -- return False; -- end if; -- -- Compare components -- if False or else X.C1 /= Y.C1 or else X.C2 /= Y.C2 then -- return False; -- end if; -- -- Compare variant part -- case X.D1 is -- when V1 => -- if False or else X.C2 /= Y.C2 or else X.C3 /= Y.C3 then -- return False; -- end if; -- ... -- when Vn => -- if False or else X.Cn /= Y.Cn then -- return False; -- end if; -- end case; -- return True; -- end _Equality; procedure Build_Variant_Record_Equality (Typ : Entity_Id) is Loc : constant Source_Ptr := Sloc (Typ); F : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => Make_TSS_Name (Typ, TSS_Composite_Equality)); X : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => Name_X); Y : constant Entity_Id := Make_Defining_Identifier (Loc, Chars => Name_Y); Def : constant Node_Id := Parent (Typ); Comps : constant Node_Id := Component_List (Type_Definition (Def)); Stmts : constant List_Id := New_List; Pspecs : constant List_Id := New_List; begin -- Derived Unchecked_Union types no longer inherit the equality function -- of their parent. if Is_Derived_Type (Typ) and then not Is_Unchecked_Union (Typ) and then not Has_New_Non_Standard_Rep (Typ) then declare Parent_Eq : constant Entity_Id := TSS (Root_Type (Typ), TSS_Composite_Equality); begin if Present (Parent_Eq) then Copy_TSS (Parent_Eq, Typ); return; end if; end; end if; Discard_Node ( Make_Subprogram_Body (Loc, Specification => Make_Function_Specification (Loc, Defining_Unit_Name => F, Parameter_Specifications => Pspecs, Result_Definition => New_Reference_To (Standard_Boolean, Loc)), Declarations => New_List, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, Statements => Stmts))); Append_To (Pspecs, Make_Parameter_Specification (Loc, Defining_Identifier => X, Parameter_Type => New_Reference_To (Typ, Loc))); Append_To (Pspecs, Make_Parameter_Specification (Loc, Defining_Identifier => Y, Parameter_Type => New_Reference_To (Typ, Loc))); -- Unchecked_Unions require additional machinery to support equality. -- Two extra parameters (A and B) are added to the equality function -- parameter list in order to capture the inferred values of the -- discriminants in later calls. if Is_Unchecked_Union (Typ) then declare Discr_Type : constant Node_Id := Etype (First_Discriminant (Typ)); A : constant Node_Id := Make_Defining_Identifier (Loc, Chars => Name_A); B : constant Node_Id := Make_Defining_Identifier (Loc, Chars => Name_B); begin -- Add A and B to the parameter list Append_To (Pspecs, Make_Parameter_Specification (Loc, Defining_Identifier => A, Parameter_Type => New_Reference_To (Discr_Type, Loc))); Append_To (Pspecs, Make_Parameter_Specification (Loc, Defining_Identifier => B, Parameter_Type => New_Reference_To (Discr_Type, Loc))); -- Generate the following header code to compare the inferred -- discriminants: -- if a /= b then -- return False; -- end if; Append_To (Stmts, Make_If_Statement (Loc, Condition => Make_Op_Ne (Loc, Left_Opnd => New_Reference_To (A, Loc), Right_Opnd => New_Reference_To (B, Loc)), Then_Statements => New_List ( Make_Return_Statement (Loc, Expression => New_Occurrence_Of (Standard_False, Loc))))); -- Generate component-by-component comparison. Note that we must -- propagate one of the inferred discriminant formals to act as -- the case statement switch. Append_List_To (Stmts, Make_Eq_Case (Typ, Comps, A)); end; -- Normal case (not unchecked union) else Append_To (Stmts, Make_Eq_If (Typ, Discriminant_Specifications (Def))); Append_List_To (Stmts, Make_Eq_Case (Typ, Comps)); end if; Append_To (Stmts, Make_Return_Statement (Loc, Expression => New_Reference_To (Standard_True, Loc))); Set_TSS (Typ, F); Set_Is_Pure (F); if not Debug_Generated_Code then Set_Debug_Info_Off (F); end if; end Build_Variant_Record_Equality; ----------------------------- -- Check_Stream_Attributes -- ----------------------------- procedure Check_Stream_Attributes (Typ : Entity_Id) is Comp : Entity_Id; Par_Read : constant Boolean := Stream_Attribute_Available (Typ, TSS_Stream_Read) and then not Has_Specified_Stream_Read (Typ); Par_Write : constant Boolean := Stream_Attribute_Available (Typ, TSS_Stream_Write) and then not Has_Specified_Stream_Write (Typ); procedure Check_Attr (Nam : Name_Id; TSS_Nam : TSS_Name_Type); -- Check that Comp has a user-specified Nam stream attribute ---------------- -- Check_Attr -- ---------------- procedure Check_Attr (Nam : Name_Id; TSS_Nam : TSS_Name_Type) is begin if not Stream_Attribute_Available (Etype (Comp), TSS_Nam) then Error_Msg_Name_1 := Nam; Error_Msg_N ("|component& in limited extension must have% attribute", Comp); end if; end Check_Attr; -- Start of processing for Check_Stream_Attributes begin if Par_Read or else Par_Write then Comp := First_Component (Typ); while Present (Comp) loop if Comes_From_Source (Comp) and then Original_Record_Component (Comp) = Comp and then Is_Limited_Type (Etype (Comp)) then if Par_Read then Check_Attr (Name_Read, TSS_Stream_Read); end if; if Par_Write then Check_Attr (Name_Write, TSS_Stream_Write); end if; end if; Next_Component (Comp); end loop; end if; end Check_Stream_Attributes; ----------------------------- -- Expand_Record_Extension -- ----------------------------- -- Add a field _parent at the beginning of the record extension. This is -- used to implement inheritance. Here are some examples of expansion: -- 1. no discriminants -- type T2 is new T1 with null record; -- gives -- type T2 is new T1 with record -- _Parent : T1; -- end record; -- 2. renamed discriminants -- type T2 (B, C : Int) is new T1 (A => B) with record -- _Parent : T1 (A => B); -- D : Int; -- end; -- 3. inherited discriminants -- type T2 is new T1 with record -- discriminant A inherited -- _Parent : T1 (A); -- D : Int; -- end; procedure Expand_Record_Extension (T : Entity_Id; Def : Node_Id) is Indic : constant Node_Id := Subtype_Indication (Def); Loc : constant Source_Ptr := Sloc (Def); Rec_Ext_Part : Node_Id := Record_Extension_Part (Def); Par_Subtype : Entity_Id; Comp_List : Node_Id; Comp_Decl : Node_Id; Parent_N : Node_Id; D : Entity_Id; List_Constr : constant List_Id := New_List; begin -- Expand_Record_Extension is called directly from the semantics, so -- we must check to see whether expansion is active before proceeding if not Expander_Active then return; end if; -- This may be a derivation of an untagged private type whose full -- view is tagged, in which case the Derived_Type_Definition has no -- extension part. Build an empty one now. if No (Rec_Ext_Part) then Rec_Ext_Part := Make_Record_Definition (Loc, End_Label => Empty, Component_List => Empty, Null_Present => True); Set_Record_Extension_Part (Def, Rec_Ext_Part); Mark_Rewrite_Insertion (Rec_Ext_Part); end if; Comp_List := Component_List (Rec_Ext_Part); Parent_N := Make_Defining_Identifier (Loc, Name_uParent); -- If the derived type inherits its discriminants the type of the -- _parent field must be constrained by the inherited discriminants if Has_Discriminants (T) and then Nkind (Indic) /= N_Subtype_Indication and then not Is_Constrained (Entity (Indic)) then D := First_Discriminant (T); while Present (D) loop Append_To (List_Constr, New_Occurrence_Of (D, Loc)); Next_Discriminant (D); end loop; Par_Subtype := Process_Subtype ( Make_Subtype_Indication (Loc, Subtype_Mark => New_Reference_To (Entity (Indic), Loc), Constraint => Make_Index_Or_Discriminant_Constraint (Loc, Constraints => List_Constr)), Def); -- Otherwise the original subtype_indication is just what is needed else Par_Subtype := Process_Subtype (New_Copy_Tree (Indic), Def); end if; Set_Parent_Subtype (T, Par_Subtype); Comp_Decl := Make_Component_Declaration (Loc, Defining_Identifier => Parent_N, Component_Definition => Make_Component_Definition (Loc, Aliased_Present => False, Subtype_Indication => New_Reference_To (Par_Subtype, Loc))); if Null_Present (Rec_Ext_Part) then Set_Component_List (Rec_Ext_Part, Make_Component_List (Loc, Component_Items => New_List (Comp_Decl), Variant_Part => Empty, Null_Present => False)); Set_Null_Present (Rec_Ext_Part, False); elsif Null_Present (Comp_List) or else Is_Empty_List (Component_Items (Comp_List)) then Set_Component_Items (Comp_List, New_List (Comp_Decl)); Set_Null_Present (Comp_List, False); else Insert_Before (First (Component_Items (Comp_List)), Comp_Decl); end if; Analyze (Comp_Decl); end Expand_Record_Extension; ------------------------------------ -- Expand_N_Full_Type_Declaration -- ------------------------------------ procedure Expand_N_Full_Type_Declaration (N : Node_Id) is Def_Id : constant Entity_Id := Defining_Identifier (N); B_Id : constant Entity_Id := Base_Type (Def_Id); Par_Id : Entity_Id; FN : Node_Id; begin if Is_Access_Type (Def_Id) then -- Anonymous access types are created for the components of the -- record parameter for an entry declaration. No master is created -- for such a type. if Has_Task (Designated_Type (Def_Id)) and then Comes_From_Source (N) then Build_Master_Entity (Def_Id); Build_Master_Renaming (Parent (Def_Id), Def_Id); -- Create a class-wide master because a Master_Id must be generated -- for access-to-limited-class-wide types, whose root may be extended -- with task components. elsif Is_Class_Wide_Type (Designated_Type (Def_Id)) and then Is_Limited_Type (Designated_Type (Def_Id)) and then Tasking_Allowed -- Don't create a class-wide master for types whose convention is -- Java since these types cannot embed Ada tasks anyway. Note that -- the following test cannot catch the following case: -- -- package java.lang.Object is -- type Typ is tagged limited private; -- type Ref is access all Typ'Class; -- private -- type Typ is tagged limited ...; -- pragma Convention (Typ, Java) -- end; -- -- Because the convention appears after we have done the -- processing for type Ref. and then Convention (Designated_Type (Def_Id)) /= Convention_Java then Build_Class_Wide_Master (Def_Id); elsif Ekind (Def_Id) = E_Access_Protected_Subprogram_Type then Expand_Access_Protected_Subprogram_Type (N); end if; elsif Has_Task (Def_Id) then Expand_Previous_Access_Type (Def_Id); end if; Par_Id := Etype (B_Id); -- The parent type is private then we need to inherit -- any TSS operations from the full view. if Ekind (Par_Id) in Private_Kind and then Present (Full_View (Par_Id)) then Par_Id := Base_Type (Full_View (Par_Id)); end if; if Nkind (Type_Definition (Original_Node (N))) = N_Derived_Type_Definition and then not Is_Tagged_Type (Def_Id) and then Present (Freeze_Node (Par_Id)) and then Present (TSS_Elist (Freeze_Node (Par_Id))) then Ensure_Freeze_Node (B_Id); FN := Freeze_Node (B_Id); if No (TSS_Elist (FN)) then Set_TSS_Elist (FN, New_Elmt_List); end if; declare T_E : constant Elist_Id := TSS_Elist (FN); Elmt : Elmt_Id; begin Elmt := First_Elmt (TSS_Elist (Freeze_Node (Par_Id))); while Present (Elmt) loop if Chars (Node (Elmt)) /= Name_uInit then Append_Elmt (Node (Elmt), T_E); end if; Next_Elmt (Elmt); end loop; -- If the derived type itself is private with a full view, then -- associate the full view with the inherited TSS_Elist as well. if Ekind (B_Id) in Private_Kind and then Present (Full_View (B_Id)) then Ensure_Freeze_Node (Base_Type (Full_View (B_Id))); Set_TSS_Elist (Freeze_Node (Base_Type (Full_View (B_Id))), TSS_Elist (FN)); end if; end; end if; end Expand_N_Full_Type_Declaration; --------------------------------- -- Expand_N_Object_Declaration -- --------------------------------- -- First we do special processing for objects of a tagged type where this -- is the point at which the type is frozen. The creation of the dispatch -- table and the initialization procedure have to be deferred to this -- point, since we reference previously declared primitive subprograms. -- For all types, we call an initialization procedure if there is one procedure Expand_N_Object_Declaration (N : Node_Id) is Def_Id : constant Entity_Id := Defining_Identifier (N); Typ : constant Entity_Id := Etype (Def_Id); Loc : constant Source_Ptr := Sloc (N); Expr : constant Node_Id := Expression (N); New_Ref : Node_Id; Id_Ref : Node_Id; Expr_Q : Node_Id; begin -- Don't do anything for deferred constants. All proper actions will -- be expanded during the full declaration. if No (Expr) and Constant_Present (N) then return; end if; -- Make shared memory routines for shared passive variable if Is_Shared_Passive (Def_Id) then Make_Shared_Var_Procs (N); end if; -- If tasks being declared, make sure we have an activation chain -- defined for the tasks (has no effect if we already have one), and -- also that a Master variable is established and that the appropriate -- enclosing construct is established as a task master. if Has_Task (Typ) then Build_Activation_Chain_Entity (N); Build_Master_Entity (Def_Id); end if; -- Default initialization required, and no expression present if No (Expr) then -- Expand Initialize call for controlled objects. One may wonder why -- the Initialize Call is not done in the regular Init procedure -- attached to the record type. That's because the init procedure is -- recursively called on each component, including _Parent, thus the -- Init call for a controlled object would generate not only one -- Initialize call as it is required but one for each ancestor of -- its type. This processing is suppressed if No_Initialization set. if not Controlled_Type (Typ) or else No_Initialization (N) then null; elsif not Abort_Allowed or else not Comes_From_Source (N) then Insert_Actions_After (N, Make_Init_Call ( Ref => New_Occurrence_Of (Def_Id, Loc), Typ => Base_Type (Typ), Flist_Ref => Find_Final_List (Def_Id), With_Attach => Make_Integer_Literal (Loc, 1))); -- Abort allowed else -- We need to protect the initialize call -- begin -- Defer_Abort.all; -- Initialize (...); -- at end -- Undefer_Abort.all; -- end; -- ??? this won't protect the initialize call for controlled -- components which are part of the init proc, so this block -- should probably also contain the call to _init_proc but this -- requires some code reorganization... declare L : constant List_Id := Make_Init_Call ( Ref => New_Occurrence_Of (Def_Id, Loc), Typ => Base_Type (Typ), Flist_Ref => Find_Final_List (Def_Id), With_Attach => Make_Integer_Literal (Loc, 1)); Blk : constant Node_Id := Make_Block_Statement (Loc, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, L)); begin Prepend_To (L, Build_Runtime_Call (Loc, RE_Abort_Defer)); Set_At_End_Proc (Handled_Statement_Sequence (Blk), New_Occurrence_Of (RTE (RE_Abort_Undefer_Direct), Loc)); Insert_Actions_After (N, New_List (Blk)); Expand_At_End_Handler (Handled_Statement_Sequence (Blk), Entity (Identifier (Blk))); end; end if; -- Call type initialization procedure if there is one. We build the -- call and put it immediately after the object declaration, so that -- it will be expanded in the usual manner. Note that this will -- result in proper handling of defaulted discriminants. The call -- to the Init_Proc is suppressed if No_Initialization is set. if Has_Non_Null_Base_Init_Proc (Typ) and then not No_Initialization (N) then -- The call to the initialization procedure does NOT freeze -- the object being initialized. This is because the call is -- not a source level call. This works fine, because the only -- possible statements depending on freeze status that can -- appear after the _Init call are rep clauses which can -- safely appear after actual references to the object. Id_Ref := New_Reference_To (Def_Id, Loc); Set_Must_Not_Freeze (Id_Ref); Set_Assignment_OK (Id_Ref); Insert_Actions_After (N, Build_Initialization_Call (Loc, Id_Ref, Typ)); -- If simple initialization is required, then set an appropriate -- simple initialization expression in place. This special -- initialization is required even though No_Init_Flag is present. -- An internally generated temporary needs no initialization because -- it will be assigned subsequently. In particular, there is no -- point in applying Initialize_Scalars to such a temporary. elsif Needs_Simple_Initialization (Typ) and then not Is_Internal (Def_Id) then Set_No_Initialization (N, False); Set_Expression (N, Get_Simple_Init_Val (Typ, Loc, Esize (Def_Id))); Analyze_And_Resolve (Expression (N), Typ); end if; -- Generate attribute for Persistent_BSS if needed declare Prag : Node_Id; begin if Persistent_BSS_Mode and then Comes_From_Source (N) and then Is_Potentially_Persistent_Type (Typ) and then Is_Library_Level_Entity (Def_Id) then Prag := Make_Linker_Section_Pragma (Def_Id, Sloc (N), ".persistent.bss"); Insert_After (N, Prag); Analyze (Prag); end if; end; -- Explicit initialization present else -- Obtain actual expression from qualified expression if Nkind (Expr) = N_Qualified_Expression then Expr_Q := Expression (Expr); else Expr_Q := Expr; end if; -- When we have the appropriate type of aggregate in the -- expression (it has been determined during analysis of the -- aggregate by setting the delay flag), let's perform in -- place assignment and thus avoid creating a temporary. if Is_Delayed_Aggregate (Expr_Q) then Convert_Aggr_In_Object_Decl (N); else -- In most cases, we must check that the initial value meets -- any constraint imposed by the declared type. However, there -- is one very important exception to this rule. If the entity -- has an unconstrained nominal subtype, then it acquired its -- constraints from the expression in the first place, and not -- only does this mean that the constraint check is not needed, -- but an attempt to perform the constraint check can -- cause order of elaboration problems. if not Is_Constr_Subt_For_U_Nominal (Typ) then -- If this is an allocator for an aggregate that has been -- allocated in place, delay checks until assignments are -- made, because the discriminants are not initialized. if Nkind (Expr) = N_Allocator and then No_Initialization (Expr) then null; else Apply_Constraint_Check (Expr, Typ); end if; end if; -- If the type is controlled we attach the object to the final -- list and adjust the target after the copy. This if Controlled_Type (Typ) then declare Flist : Node_Id; F : Entity_Id; begin -- Attach the result to a dummy final list which will never -- be finalized if Delay_Finalize_Attachis set. It is -- important to attach to a dummy final list rather than -- not attaching at all in order to reset the pointers -- coming from the initial value. Equivalent code exists -- in the sec-stack case in Exp_Ch4.Expand_N_Allocator. if Delay_Finalize_Attach (N) then F := Make_Defining_Identifier (Loc, New_Internal_Name ('F')); Insert_Action (N, Make_Object_Declaration (Loc, Defining_Identifier => F, Object_Definition => New_Reference_To (RTE (RE_Finalizable_Ptr), Loc))); Flist := New_Reference_To (F, Loc); else Flist := Find_Final_List (Def_Id); end if; Insert_Actions_After (N, Make_Adjust_Call ( Ref => New_Reference_To (Def_Id, Loc), Typ => Base_Type (Typ), Flist_Ref => Flist, With_Attach => Make_Integer_Literal (Loc, 1))); end; end if; -- For tagged types, when an init value is given, the tag has to -- be re-initialized separately in order to avoid the propagation -- of a wrong tag coming from a view conversion unless the type -- is class wide (in this case the tag comes from the init -- value). Suppress the tag assignment when Java_VM because JVM -- tags are represented implicitly in objects. Ditto for types -- that are CPP_CLASS, and for initializations that are -- aggregates, because they have to have the right tag. if Is_Tagged_Type (Typ) and then not Is_Class_Wide_Type (Typ) and then not Is_CPP_Class (Typ) and then not Java_VM and then Nkind (Expr) /= N_Aggregate then -- The re-assignment of the tag has to be done even if -- the object is a constant New_Ref := Make_Selected_Component (Loc, Prefix => New_Reference_To (Def_Id, Loc), Selector_Name => New_Reference_To (First_Tag_Component (Typ), Loc)); Set_Assignment_OK (New_Ref); Insert_After (N, Make_Assignment_Statement (Loc, Name => New_Ref, Expression => Unchecked_Convert_To (RTE (RE_Tag), New_Reference_To (Node (First_Elmt (Access_Disp_Table (Base_Type (Typ)))), Loc)))); -- For discrete types, set the Is_Known_Valid flag if the -- initializing value is known to be valid. elsif Is_Discrete_Type (Typ) and then Expr_Known_Valid (Expr) then Set_Is_Known_Valid (Def_Id); elsif Is_Access_Type (Typ) then -- For access types set the Is_Known_Non_Null flag if the -- initializing value is known to be non-null. We can also set -- Can_Never_Be_Null if this is a constant. if Known_Non_Null (Expr) then Set_Is_Known_Non_Null (Def_Id); if Constant_Present (N) then Set_Can_Never_Be_Null (Def_Id); end if; end if; end if; -- If validity checking on copies, validate initial expression if Validity_Checks_On and then Validity_Check_Copies then Ensure_Valid (Expr); Set_Is_Known_Valid (Def_Id); end if; end if; -- Cases where the back end cannot handle the initialization -- directly. In such cases, we expand an assignment that will -- be appropriately handled by Expand_N_Assignment_Statement. -- The exclusion of the unconstrained case is wrong, but for -- now it is too much trouble ??? if (Is_Possibly_Unaligned_Slice (Expr) or else (Is_Possibly_Unaligned_Object (Expr) and then not Represented_As_Scalar (Etype (Expr)))) -- The exclusion of the unconstrained case is wrong, but for -- now it is too much trouble ??? and then not (Is_Array_Type (Etype (Expr)) and then not Is_Constrained (Etype (Expr))) then declare Stat : constant Node_Id := Make_Assignment_Statement (Loc, Name => New_Reference_To (Def_Id, Loc), Expression => Relocate_Node (Expr)); begin Set_Expression (N, Empty); Set_No_Initialization (N); Set_Assignment_OK (Name (Stat)); Set_No_Ctrl_Actions (Stat); Insert_After (N, Stat); Analyze (Stat); end; end if; end if; -- For array type, check for size too large -- We really need this for record types too??? if Is_Array_Type (Typ) then Apply_Array_Size_Check (N, Typ); end if; exception when RE_Not_Available => return; end Expand_N_Object_Declaration; --------------------------------- -- Expand_N_Subtype_Indication -- --------------------------------- -- Add a check on the range of the subtype. The static case is partially -- duplicated by Process_Range_Expr_In_Decl in Sem_Ch3, but we still need -- to check here for the static case in order to avoid generating -- extraneous expanded code. procedure Expand_N_Subtype_Indication (N : Node_Id) is Ran : constant Node_Id := Range_Expression (Constraint (N)); Typ : constant Entity_Id := Entity (Subtype_Mark (N)); begin if Nkind (Parent (N)) = N_Constrained_Array_Definition or else Nkind (Parent (N)) = N_Slice then Resolve (Ran, Typ); Apply_Range_Check (Ran, Typ); end if; end Expand_N_Subtype_Indication; --------------------------- -- Expand_N_Variant_Part -- --------------------------- -- If the last variant does not contain the Others choice, replace it with -- an N_Others_Choice node since Gigi always wants an Others. Note that we -- do not bother to call Analyze on the modified variant part, since it's -- only effect would be to compute the contents of the -- Others_Discrete_Choices node laboriously, and of course we already know -- the list of choices that corresponds to the others choice (it's the -- list we are replacing!) procedure Expand_N_Variant_Part (N : Node_Id) is Last_Var : constant Node_Id := Last_Non_Pragma (Variants (N)); Others_Node : Node_Id; begin if Nkind (First (Discrete_Choices (Last_Var))) /= N_Others_Choice then Others_Node := Make_Others_Choice (Sloc (Last_Var)); Set_Others_Discrete_Choices (Others_Node, Discrete_Choices (Last_Var)); Set_Discrete_Choices (Last_Var, New_List (Others_Node)); end if; end Expand_N_Variant_Part; --------------------------------- -- Expand_Previous_Access_Type -- --------------------------------- procedure Expand_Previous_Access_Type (Def_Id : Entity_Id) is T : Entity_Id := First_Entity (Current_Scope); begin -- Find all access types declared in the current scope, whose -- designated type is Def_Id. while Present (T) loop if Is_Access_Type (T) and then Designated_Type (T) = Def_Id then Build_Master_Entity (Def_Id); Build_Master_Renaming (Parent (Def_Id), T); end if; Next_Entity (T); end loop; end Expand_Previous_Access_Type; ------------------------------ -- Expand_Record_Controller -- ------------------------------ procedure Expand_Record_Controller (T : Entity_Id) is Def : Node_Id := Type_Definition (Parent (T)); Comp_List : Node_Id; Comp_Decl : Node_Id; Loc : Source_Ptr; First_Comp : Node_Id; Controller_Type : Entity_Id; Ent : Entity_Id; begin if Nkind (Def) = N_Derived_Type_Definition then Def := Record_Extension_Part (Def); end if; if Null_Present (Def) then Set_Component_List (Def, Make_Component_List (Sloc (Def), Component_Items => Empty_List, Variant_Part => Empty, Null_Present => True)); end if; Comp_List := Component_List (Def); if Null_Present (Comp_List) or else Is_Empty_List (Component_Items (Comp_List)) then Loc := Sloc (Comp_List); else Loc := Sloc (First (Component_Items (Comp_List))); end if; if Is_Return_By_Reference_Type (T) then Controller_Type := RTE (RE_Limited_Record_Controller); else Controller_Type := RTE (RE_Record_Controller); end if; Ent := Make_Defining_Identifier (Loc, Name_uController); Comp_Decl := Make_Component_Declaration (Loc, Defining_Identifier => Ent, Component_Definition => Make_Component_Definition (Loc, Aliased_Present => False, Subtype_Indication => New_Reference_To (Controller_Type, Loc))); if Null_Present (Comp_List) or else Is_Empty_List (Component_Items (Comp_List)) then Set_Component_Items (Comp_List, New_List (Comp_Decl)); Set_Null_Present (Comp_List, False); else -- The controller cannot be placed before the _Parent field since -- gigi lays out field in order and _parent must be first to -- preserve the polymorphism of tagged types. First_Comp := First (Component_Items (Comp_List)); if Chars (Defining_Identifier (First_Comp)) /= Name_uParent and then Chars (Defining_Identifier (First_Comp)) /= Name_uTag then Insert_Before (First_Comp, Comp_Decl); else Insert_After (First_Comp, Comp_Decl); end if; end if; New_Scope (T); Analyze (Comp_Decl); Set_Ekind (Ent, E_Component); Init_Component_Location (Ent); -- Move the _controller entity ahead in the list of internal entities -- of the enclosing record so that it is selected instead of a -- potentially inherited one. declare E : constant Entity_Id := Last_Entity (T); Comp : Entity_Id; begin pragma Assert (Chars (E) = Name_uController); Set_Next_Entity (E, First_Entity (T)); Set_First_Entity (T, E); Comp := Next_Entity (E); while Next_Entity (Comp) /= E loop Next_Entity (Comp); end loop; Set_Next_Entity (Comp, Empty); Set_Last_Entity (T, Comp); end; End_Scope; exception when RE_Not_Available => return; end Expand_Record_Controller; ------------------------ -- Expand_Tagged_Root -- ------------------------ procedure Expand_Tagged_Root (T : Entity_Id) is Def : constant Node_Id := Type_Definition (Parent (T)); Comp_List : Node_Id; Comp_Decl : Node_Id; Sloc_N : Source_Ptr; begin if Null_Present (Def) then Set_Component_List (Def, Make_Component_List (Sloc (Def), Component_Items => Empty_List, Variant_Part => Empty, Null_Present => True)); end if; Comp_List := Component_List (Def); if Null_Present (Comp_List) or else Is_Empty_List (Component_Items (Comp_List)) then Sloc_N := Sloc (Comp_List); else Sloc_N := Sloc (First (Component_Items (Comp_List))); end if; Comp_Decl := Make_Component_Declaration (Sloc_N, Defining_Identifier => First_Tag_Component (T), Component_Definition => Make_Component_Definition (Sloc_N, Aliased_Present => False, Subtype_Indication => New_Reference_To (RTE (RE_Tag), Sloc_N))); if Null_Present (Comp_List) or else Is_Empty_List (Component_Items (Comp_List)) then Set_Component_Items (Comp_List, New_List (Comp_Decl)); Set_Null_Present (Comp_List, False); else Insert_Before (First (Component_Items (Comp_List)), Comp_Decl); end if; -- We don't Analyze the whole expansion because the tag component has -- already been analyzed previously. Here we just insure that the tree -- is coherent with the semantic decoration Find_Type (Subtype_Indication (Component_Definition (Comp_Decl))); exception when RE_Not_Available => return; end Expand_Tagged_Root; ----------------------- -- Freeze_Array_Type -- ----------------------- procedure Freeze_Array_Type (N : Node_Id) is Typ : constant Entity_Id := Entity (N); Base : constant Entity_Id := Base_Type (Typ); begin if not Is_Bit_Packed_Array (Typ) then -- If the component contains tasks, so does the array type. This may -- not be indicated in the array type because the component may have -- been a private type at the point of definition. Same if component -- type is controlled. Set_Has_Task (Base, Has_Task (Component_Type (Typ))); Set_Has_Controlled_Component (Base, Has_Controlled_Component (Component_Type (Typ)) or else Is_Controlled (Component_Type (Typ))); if No (Init_Proc (Base)) then -- If this is an anonymous array created for a declaration with -- an initial value, its init_proc will never be called. The -- initial value itself may have been expanded into assign- -- ments, in which case the object declaration is carries the -- No_Initialization flag. if Is_Itype (Base) and then Nkind (Associated_Node_For_Itype (Base)) = N_Object_Declaration and then (Present (Expression (Associated_Node_For_Itype (Base))) or else No_Initialization (Associated_Node_For_Itype (Base))) then null; -- We do not need an init proc for string or wide [wide] string, -- since the only time these need initialization in normalize or -- initialize scalars mode, and these types are treated specially -- and do not need initialization procedures. elsif Root_Type (Base) = Standard_String or else Root_Type (Base) = Standard_Wide_String or else Root_Type (Base) = Standard_Wide_Wide_String then null; -- Otherwise we have to build an init proc for the subtype else Build_Array_Init_Proc (Base, N); end if; end if; if Typ = Base and then Has_Controlled_Component (Base) then Build_Controlling_Procs (Base); if not Is_Limited_Type (Component_Type (Typ)) and then Number_Dimensions (Typ) = 1 then Build_Slice_Assignment (Typ); end if; end if; -- For packed case, there is a default initialization, except if the -- component type is itself a packed structure with an initialization -- procedure. elsif Present (Init_Proc (Component_Type (Base))) and then No (Base_Init_Proc (Base)) then Build_Array_Init_Proc (Base, N); end if; end Freeze_Array_Type; ----------------------------- -- Freeze_Enumeration_Type -- ----------------------------- procedure Freeze_Enumeration_Type (N : Node_Id) is Typ : constant Entity_Id := Entity (N); Loc : constant Source_Ptr := Sloc (Typ); Ent : Entity_Id; Lst : List_Id; Num : Nat; Arr : Entity_Id; Fent : Entity_Id; Ityp : Entity_Id; Is_Contiguous : Boolean; Pos_Expr : Node_Id; Last_Repval : Uint; Func : Entity_Id; pragma Warnings (Off, Func); begin -- Various optimization are possible if the given representation is -- contiguous. Is_Contiguous := True; Ent := First_Literal (Typ); Last_Repval := Enumeration_Rep (Ent); Next_Literal (Ent); while Present (Ent) loop if Enumeration_Rep (Ent) - Last_Repval /= 1 then Is_Contiguous := False; exit; else Last_Repval := Enumeration_Rep (Ent); end if; Next_Literal (Ent); end loop; if Is_Contiguous then Set_Has_Contiguous_Rep (Typ); Ent := First_Literal (Typ); Num := 1; Lst := New_List (New_Reference_To (Ent, Sloc (Ent))); else -- Build list of literal references Lst := New_List; Num := 0; Ent := First_Literal (Typ); while Present (Ent) loop Append_To (Lst, New_Reference_To (Ent, Sloc (Ent))); Num := Num + 1; Next_Literal (Ent); end loop; end if; -- Now build an array declaration -- typA : array (Natural range 0 .. num - 1) of ctype := -- (v, v, v, v, v, ....) -- where ctype is the corresponding integer type. If the representation -- is contiguous, we only keep the first literal, which provides the -- offset for Pos_To_Rep computations. Arr := Make_Defining_Identifier (Loc, Chars => New_External_Name (Chars (Typ), 'A')); Append_Freeze_Action (Typ, Make_Object_Declaration (Loc, Defining_Identifier => Arr, Constant_Present => True, Object_Definition => Make_Constrained_Array_Definition (Loc, Discrete_Subtype_Definitions => New_List ( Make_Subtype_Indication (Loc, Subtype_Mark => New_Reference_To (Standard_Natural, Loc), Constraint => Make_Range_Constraint (Loc, Range_Expression => Make_Range (Loc, Low_Bound => Make_Integer_Literal (Loc, 0), High_Bound => Make_Integer_Literal (Loc, Num - 1))))), Component_Definition => Make_Component_Definition (Loc, Aliased_Present => False, Subtype_Indication => New_Reference_To (Typ, Loc))), Expression => Make_Aggregate (Loc, Expressions => Lst))); Set_Enum_Pos_To_Rep (Typ, Arr); -- Now we build the function that converts representation values to -- position values. This function has the form: -- function _Rep_To_Pos (A : etype; F : Boolean) return Integer is -- begin -- case ityp!(A) is -- when enum-lit'Enum_Rep => return posval; -- when enum-lit'Enum_Rep => return posval; -- ... -- when others => -- [raise Constraint_Error when F "invalid data"] -- return -1; -- end case; -- end; -- Note: the F parameter determines whether the others case (no valid -- representation) raises Constraint_Error or returns a unique value -- of minus one. The latter case is used, e.g. in 'Valid code. -- Note: the reason we use Enum_Rep values in the case here is to avoid -- the code generator making inappropriate assumptions about the range -- of the values in the case where the value is invalid. ityp is a -- signed or unsigned integer type of appropriate width. -- Note: if exceptions are not supported, then we suppress the raise -- and return -1 unconditionally (this is an erroneous program in any -- case and there is no obligation to raise Constraint_Error here!) We -- also do this if pragma Restrictions (No_Exceptions) is active. -- Representations are signed if Enumeration_Rep (First_Literal (Typ)) < 0 then -- The underlying type is signed. Reset the Is_Unsigned_Type -- explicitly, because it might have been inherited from -- parent type. Set_Is_Unsigned_Type (Typ, False); if Esize (Typ) <= Standard_Integer_Size then Ityp := Standard_Integer; else Ityp := Universal_Integer; end if; -- Representations are unsigned else if Esize (Typ) <= Standard_Integer_Size then Ityp := RTE (RE_Unsigned); else Ityp := RTE (RE_Long_Long_Unsigned); end if; end if; -- The body of the function is a case statement. First collect case -- alternatives, or optimize the contiguous case. Lst := New_List; -- If representation is contiguous, Pos is computed by subtracting -- the representation of the first literal. if Is_Contiguous then Ent := First_Literal (Typ); if Enumeration_Rep (Ent) = Last_Repval then -- Another special case: for a single literal, Pos is zero Pos_Expr := Make_Integer_Literal (Loc, Uint_0); else Pos_Expr := Convert_To (Standard_Integer, Make_Op_Subtract (Loc, Left_Opnd => Unchecked_Convert_To (Ityp, Make_Identifier (Loc, Name_uA)), Right_Opnd => Make_Integer_Literal (Loc, Intval => Enumeration_Rep (First_Literal (Typ))))); end if; Append_To (Lst, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_List ( Make_Range (Sloc (Enumeration_Rep_Expr (Ent)), Low_Bound => Make_Integer_Literal (Loc, Intval => Enumeration_Rep (Ent)), High_Bound => Make_Integer_Literal (Loc, Intval => Last_Repval))), Statements => New_List ( Make_Return_Statement (Loc, Expression => Pos_Expr)))); else Ent := First_Literal (Typ); while Present (Ent) loop Append_To (Lst, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_List ( Make_Integer_Literal (Sloc (Enumeration_Rep_Expr (Ent)), Intval => Enumeration_Rep (Ent))), Statements => New_List ( Make_Return_Statement (Loc, Expression => Make_Integer_Literal (Loc, Intval => Enumeration_Pos (Ent)))))); Next_Literal (Ent); end loop; end if; -- In normal mode, add the others clause with the test if not Restriction_Active (No_Exception_Handlers) then Append_To (Lst, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_List (Make_Others_Choice (Loc)), Statements => New_List ( Make_Raise_Constraint_Error (Loc, Condition => Make_Identifier (Loc, Name_uF), Reason => CE_Invalid_Data), Make_Return_Statement (Loc, Expression => Make_Integer_Literal (Loc, -1))))); -- If Restriction (No_Exceptions_Handlers) is active then we always -- return -1 (since we cannot usefully raise Constraint_Error in -- this case). See description above for further details. else Append_To (Lst, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_List (Make_Others_Choice (Loc)), Statements => New_List ( Make_Return_Statement (Loc, Expression => Make_Integer_Literal (Loc, -1))))); end if; -- Now we can build the function body Fent := Make_Defining_Identifier (Loc, Make_TSS_Name (Typ, TSS_Rep_To_Pos)); Func := Make_Subprogram_Body (Loc, Specification => Make_Function_Specification (Loc, Defining_Unit_Name => Fent, Parameter_Specifications => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uA), Parameter_Type => New_Reference_To (Typ, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uF), Parameter_Type => New_Reference_To (Standard_Boolean, Loc))), Result_Definition => New_Reference_To (Standard_Integer, Loc)), Declarations => Empty_List, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, Statements => New_List ( Make_Case_Statement (Loc, Expression => Unchecked_Convert_To (Ityp, Make_Identifier (Loc, Name_uA)), Alternatives => Lst)))); Set_TSS (Typ, Fent); Set_Is_Pure (Fent); if not Debug_Generated_Code then Set_Debug_Info_Off (Fent); end if; exception when RE_Not_Available => return; end Freeze_Enumeration_Type; ------------------------ -- Freeze_Record_Type -- ------------------------ procedure Freeze_Record_Type (N : Node_Id) is Comp : Entity_Id; Def_Id : constant Node_Id := Entity (N); Predef_List : List_Id; Type_Decl : constant Node_Id := Parent (Def_Id); Renamed_Eq : Node_Id := Empty; -- Could use some comments ??? begin -- Build discriminant checking functions if not a derived type (for -- derived types that are not tagged types, we always use the -- discriminant checking functions of the parent type). However, for -- untagged types the derivation may have taken place before the -- parent was frozen, so we copy explicitly the discriminant checking -- functions from the parent into the components of the derived type. if not Is_Derived_Type (Def_Id) or else Has_New_Non_Standard_Rep (Def_Id) or else Is_Tagged_Type (Def_Id) then Build_Discr_Checking_Funcs (Type_Decl); elsif Is_Derived_Type (Def_Id) and then not Is_Tagged_Type (Def_Id) -- If we have a derived Unchecked_Union, we do not inherit the -- discriminant checking functions from the parent type since the -- discriminants are non existent. and then not Is_Unchecked_Union (Def_Id) and then Has_Discriminants (Def_Id) then declare Old_Comp : Entity_Id; begin Old_Comp := First_Component (Base_Type (Underlying_Type (Etype (Def_Id)))); Comp := First_Component (Def_Id); while Present (Comp) loop if Ekind (Comp) = E_Component and then Chars (Comp) = Chars (Old_Comp) then Set_Discriminant_Checking_Func (Comp, Discriminant_Checking_Func (Old_Comp)); end if; Next_Component (Old_Comp); Next_Component (Comp); end loop; end; end if; if Is_Derived_Type (Def_Id) and then Is_Limited_Type (Def_Id) and then Is_Tagged_Type (Def_Id) then Check_Stream_Attributes (Def_Id); end if; -- Update task and controlled component flags, because some of the -- component types may have been private at the point of the record -- declaration. Comp := First_Component (Def_Id); while Present (Comp) loop if Has_Task (Etype (Comp)) then Set_Has_Task (Def_Id); elsif Has_Controlled_Component (Etype (Comp)) or else (Chars (Comp) /= Name_uParent and then Is_Controlled (Etype (Comp))) then Set_Has_Controlled_Component (Def_Id); end if; Next_Component (Comp); end loop; -- Creation of the Dispatch Table. Note that a Dispatch Table is -- created for regular tagged types as well as for Ada types deriving -- from a C++ Class, but not for tagged types directly corresponding to -- the C++ classes. In the later case we assume that the Vtable is -- created in the C++ side and we just use it. if Is_Tagged_Type (Def_Id) then if Is_CPP_Class (Def_Id) then Set_All_DT_Position (Def_Id); Set_Default_Constructor (Def_Id); else -- Usually inherited primitives are not delayed but the first Ada -- extension of a CPP_Class is an exception since the address of -- the inherited subprogram has to be inserted in the new Ada -- Dispatch Table and this is a freezing action (usually the -- inherited primitive address is inserted in the DT by -- Inherit_DT) -- Similarly, if this is an inherited operation whose parent is -- not frozen yet, it is not in the DT of the parent, and we -- generate an explicit freeze node for the inherited operation, -- so that it is properly inserted in the DT of the current type. declare Elmt : Elmt_Id := First_Elmt (Primitive_Operations (Def_Id)); Subp : Entity_Id; begin while Present (Elmt) loop Subp := Node (Elmt); if Present (Alias (Subp)) then if Is_CPP_Class (Etype (Def_Id)) then Set_Has_Delayed_Freeze (Subp); elsif Has_Delayed_Freeze (Alias (Subp)) and then not Is_Frozen (Alias (Subp)) then Set_Is_Frozen (Subp, False); Set_Has_Delayed_Freeze (Subp); end if; end if; Next_Elmt (Elmt); end loop; end; if Underlying_Type (Etype (Def_Id)) = Def_Id then Expand_Tagged_Root (Def_Id); end if; -- Unfreeze momentarily the type to add the predefined primitives -- operations. The reason we unfreeze is so that these predefined -- operations will indeed end up as primitive operations (which -- must be before the freeze point). Set_Is_Frozen (Def_Id, False); Make_Predefined_Primitive_Specs (Def_Id, Predef_List, Renamed_Eq); Insert_List_Before_And_Analyze (N, Predef_List); Set_Is_Frozen (Def_Id, True); Set_All_DT_Position (Def_Id); -- Add the controlled component before the freezing actions -- referenced in those actions. if Has_New_Controlled_Component (Def_Id) then Expand_Record_Controller (Def_Id); end if; -- Suppress creation of a dispatch table when Java_VM because the -- dispatching mechanism is handled internally by the JVM. if not Java_VM then -- Ada 2005 (AI-251): Build the secondary dispatch tables declare ADT : Elist_Id := Access_Disp_Table (Def_Id); procedure Add_Secondary_Tables (Typ : Entity_Id); -- Internal subprogram, recursively climb to the ancestors -------------------------- -- Add_Secondary_Tables -- -------------------------- procedure Add_Secondary_Tables (Typ : Entity_Id) is E : Entity_Id; Iface : Elmt_Id; Result : List_Id; Suffix_Index : Int; begin -- Climb to the ancestor (if any) handling private types if Present (Full_View (Etype (Typ))) then if Full_View (Etype (Typ)) /= Typ then Add_Secondary_Tables (Full_View (Etype (Typ))); end if; elsif Etype (Typ) /= Typ then Add_Secondary_Tables (Etype (Typ)); end if; if Present (Abstract_Interfaces (Typ)) and then not Is_Empty_Elmt_List (Abstract_Interfaces (Typ)) then Iface := First_Elmt (Abstract_Interfaces (Typ)); Suffix_Index := 0; E := First_Entity (Typ); while Present (E) loop if Is_Tag (E) and then Chars (E) /= Name_uTag then Make_Secondary_DT (Typ => Def_Id, Ancestor_Typ => Typ, Suffix_Index => Suffix_Index, Iface => Node (Iface), AI_Tag => E, Acc_Disp_Tables => ADT, Result => Result); Append_Freeze_Actions (Def_Id, Result); Suffix_Index := Suffix_Index + 1; Next_Elmt (Iface); end if; Next_Entity (E); end loop; end if; end Add_Secondary_Tables; -- Start of processing to build secondary dispatch tables begin -- Handle private types if Present (Full_View (Def_Id)) then Add_Secondary_Tables (Full_View (Def_Id)); else Add_Secondary_Tables (Def_Id); end if; Set_Access_Disp_Table (Def_Id, ADT); Append_Freeze_Actions (Def_Id, Make_DT (Def_Id)); end; end if; -- Make sure that the primitives Initialize, Adjust and Finalize -- are Frozen before other TSS subprograms. We don't want them -- Frozen inside. if Is_Controlled (Def_Id) then if not Is_Limited_Type (Def_Id) then Append_Freeze_Actions (Def_Id, Freeze_Entity (Find_Prim_Op (Def_Id, Name_Adjust), Sloc (Def_Id))); end if; Append_Freeze_Actions (Def_Id, Freeze_Entity (Find_Prim_Op (Def_Id, Name_Initialize), Sloc (Def_Id))); Append_Freeze_Actions (Def_Id, Freeze_Entity (Find_Prim_Op (Def_Id, Name_Finalize), Sloc (Def_Id))); end if; -- Freeze rest of primitive operations Append_Freeze_Actions (Def_Id, Predefined_Primitive_Freeze (Def_Id)); Append_Freeze_Actions (Def_Id, Init_Predefined_Interface_Primitives (Def_Id)); end if; -- In the non-tagged case, an equality function is provided only for -- variant records (that are not unchecked unions). elsif Has_Discriminants (Def_Id) and then not Is_Limited_Type (Def_Id) then declare Comps : constant Node_Id := Component_List (Type_Definition (Type_Decl)); begin if Present (Comps) and then Present (Variant_Part (Comps)) then Build_Variant_Record_Equality (Def_Id); end if; end; end if; -- Before building the record initialization procedure, if we are -- dealing with a concurrent record value type, then we must go through -- the discriminants, exchanging discriminals between the concurrent -- type and the concurrent record value type. See the section "Handling -- of Discriminants" in the Einfo spec for details. if Is_Concurrent_Record_Type (Def_Id) and then Has_Discriminants (Def_Id) then declare Ctyp : constant Entity_Id := Corresponding_Concurrent_Type (Def_Id); Conc_Discr : Entity_Id; Rec_Discr : Entity_Id; Temp : Entity_Id; begin Conc_Discr := First_Discriminant (Ctyp); Rec_Discr := First_Discriminant (Def_Id); while Present (Conc_Discr) loop Temp := Discriminal (Conc_Discr); Set_Discriminal (Conc_Discr, Discriminal (Rec_Discr)); Set_Discriminal (Rec_Discr, Temp); Set_Discriminal_Link (Discriminal (Conc_Discr), Conc_Discr); Set_Discriminal_Link (Discriminal (Rec_Discr), Rec_Discr); Next_Discriminant (Conc_Discr); Next_Discriminant (Rec_Discr); end loop; end; end if; if Has_Controlled_Component (Def_Id) then if No (Controller_Component (Def_Id)) then Expand_Record_Controller (Def_Id); end if; Build_Controlling_Procs (Def_Id); end if; Adjust_Discriminants (Def_Id); Build_Record_Init_Proc (Type_Decl, Def_Id); -- For tagged type, build bodies of primitive operations. Note that we -- do this after building the record initialization experiment, since -- the primitive operations may need the initialization routine if Is_Tagged_Type (Def_Id) then Predef_List := Predefined_Primitive_Bodies (Def_Id, Renamed_Eq); Append_Freeze_Actions (Def_Id, Predef_List); -- Populate the two auxiliary tables used for dispatching -- asynchronous, conditional and timed selects for synchronized -- types that implement a limited interface. if Ada_Version >= Ada_05 and then Is_Concurrent_Record_Type (Def_Id) and then Implements_Interface ( Typ => Def_Id, Kind => Any_Limited_Interface, Check_Parent => True) then Append_Freeze_Actions (Def_Id, Make_Select_Specific_Data_Table (Def_Id)); end if; end if; end Freeze_Record_Type; ------------------------------ -- Freeze_Stream_Operations -- ------------------------------ procedure Freeze_Stream_Operations (N : Node_Id; Typ : Entity_Id) is Names : constant array (1 .. 4) of TSS_Name_Type := (TSS_Stream_Input, TSS_Stream_Output, TSS_Stream_Read, TSS_Stream_Write); Stream_Op : Entity_Id; begin -- Primitive operations of tagged types are frozen when the dispatch -- table is constructed. if not Comes_From_Source (Typ) or else Is_Tagged_Type (Typ) then return; end if; for J in Names'Range loop Stream_Op := TSS (Typ, Names (J)); if Present (Stream_Op) and then Is_Subprogram (Stream_Op) and then Nkind (Unit_Declaration_Node (Stream_Op)) = N_Subprogram_Declaration and then not Is_Frozen (Stream_Op) then Append_Freeze_Actions (Typ, Freeze_Entity (Stream_Op, Sloc (N))); end if; end loop; end Freeze_Stream_Operations; ----------------- -- Freeze_Type -- ----------------- -- Full type declarations are expanded at the point at which the type is -- frozen. The formal N is the Freeze_Node for the type. Any statements or -- declarations generated by the freezing (e.g. the procedure generated -- for initialization) are chained in the Actions field list of the freeze -- node using Append_Freeze_Actions. function Freeze_Type (N : Node_Id) return Boolean is Def_Id : constant Entity_Id := Entity (N); RACW_Seen : Boolean := False; Result : Boolean := False; begin -- Process associated access types needing special processing if Present (Access_Types_To_Process (N)) then declare E : Elmt_Id := First_Elmt (Access_Types_To_Process (N)); begin while Present (E) loop if Is_Remote_Access_To_Class_Wide_Type (Node (E)) then RACW_Seen := True; end if; E := Next_Elmt (E); end loop; end; if RACW_Seen then -- If there are RACWs designating this type, make stubs now Remote_Types_Tagged_Full_View_Encountered (Def_Id); end if; end if; -- Freeze processing for record types if Is_Record_Type (Def_Id) then if Ekind (Def_Id) = E_Record_Type then Freeze_Record_Type (N); -- The subtype may have been declared before the type was frozen. If -- the type has controlled components it is necessary to create the -- entity for the controller explicitly because it did not exist at -- the point of the subtype declaration. Only the entity is needed, -- the back-end will obtain the layout from the type. This is only -- necessary if this is constrained subtype whose component list is -- not shared with the base type. elsif Ekind (Def_Id) = E_Record_Subtype and then Has_Discriminants (Def_Id) and then Last_Entity (Def_Id) /= Last_Entity (Base_Type (Def_Id)) and then Present (Controller_Component (Def_Id)) then declare Old_C : constant Entity_Id := Controller_Component (Def_Id); New_C : Entity_Id; begin if Scope (Old_C) = Base_Type (Def_Id) then -- The entity is the one in the parent. Create new one New_C := New_Copy (Old_C); Set_Parent (New_C, Parent (Old_C)); New_Scope (Def_Id); Enter_Name (New_C); End_Scope; end if; end; if Is_Itype (Def_Id) and then Is_Record_Type (Underlying_Type (Scope (Def_Id))) then -- The freeze node is only used to introduce the controller, -- the back-end has no use for it for a discriminated -- component. Set_Freeze_Node (Def_Id, Empty); Set_Has_Delayed_Freeze (Def_Id, False); Result := True; end if; -- Similar process if the controller of the subtype is not present -- but the parent has it. This can happen with constrained -- record components where the subtype is an itype. elsif Ekind (Def_Id) = E_Record_Subtype and then Is_Itype (Def_Id) and then No (Controller_Component (Def_Id)) and then Present (Controller_Component (Etype (Def_Id))) then declare Old_C : constant Entity_Id := Controller_Component (Etype (Def_Id)); New_C : constant Entity_Id := New_Copy (Old_C); begin Set_Next_Entity (New_C, First_Entity (Def_Id)); Set_First_Entity (Def_Id, New_C); -- The freeze node is only used to introduce the controller, -- the back-end has no use for it for a discriminated -- component. Set_Freeze_Node (Def_Id, Empty); Set_Has_Delayed_Freeze (Def_Id, False); Result := True; end; end if; -- Freeze processing for array types elsif Is_Array_Type (Def_Id) then Freeze_Array_Type (N); -- Freeze processing for access types -- For pool-specific access types, find out the pool object used for -- this type, needs actual expansion of it in some cases. Here are the -- different cases : -- 1. Rep Clause "for Def_Id'Storage_Size use 0;" -- ---> don't use any storage pool -- 2. Rep Clause : for Def_Id'Storage_Size use Expr. -- Expand: -- Def_Id__Pool : Stack_Bounded_Pool (Expr, DT'Size, DT'Alignment); -- 3. Rep Clause "for Def_Id'Storage_Pool use a_Pool_Object" -- ---> Storage Pool is the specified one -- See GNAT Pool packages in the Run-Time for more details elsif Ekind (Def_Id) = E_Access_Type or else Ekind (Def_Id) = E_General_Access_Type then declare Loc : constant Source_Ptr := Sloc (N); Desig_Type : constant Entity_Id := Designated_Type (Def_Id); Pool_Object : Entity_Id; Siz_Exp : Node_Id; Freeze_Action_Typ : Entity_Id; begin if Has_Storage_Size_Clause (Def_Id) then Siz_Exp := Expression (Parent (Storage_Size_Variable (Def_Id))); else Siz_Exp := Empty; end if; -- Case 1 -- Rep Clause "for Def_Id'Storage_Size use 0;" -- ---> don't use any storage pool if Has_Storage_Size_Clause (Def_Id) and then Compile_Time_Known_Value (Siz_Exp) and then Expr_Value (Siz_Exp) = 0 then null; -- Case 2 -- Rep Clause : for Def_Id'Storage_Size use Expr. -- ---> Expand: -- Def_Id__Pool : Stack_Bounded_Pool -- (Expr, DT'Size, DT'Alignment); elsif Has_Storage_Size_Clause (Def_Id) then declare DT_Size : Node_Id; DT_Align : Node_Id; begin -- For unconstrained composite types we give a size of zero -- so that the pool knows that it needs a special algorithm -- for variable size object allocation. if Is_Composite_Type (Desig_Type) and then not Is_Constrained (Desig_Type) then DT_Size := Make_Integer_Literal (Loc, 0); DT_Align := Make_Integer_Literal (Loc, Maximum_Alignment); else DT_Size := Make_Attribute_Reference (Loc, Prefix => New_Reference_To (Desig_Type, Loc), Attribute_Name => Name_Max_Size_In_Storage_Elements); DT_Align := Make_Attribute_Reference (Loc, Prefix => New_Reference_To (Desig_Type, Loc), Attribute_Name => Name_Alignment); end if; Pool_Object := Make_Defining_Identifier (Loc, Chars => New_External_Name (Chars (Def_Id), 'P')); -- We put the code associated with the pools in the entity -- that has the later freeze node, usually the acces type -- but it can also be the designated_type; because the pool -- code requires both those types to be frozen if Is_Frozen (Desig_Type) and then (not Present (Freeze_Node (Desig_Type)) or else Analyzed (Freeze_Node (Desig_Type))) then Freeze_Action_Typ := Def_Id; -- A Taft amendment type cannot get the freeze actions -- since the full view is not there. elsif Is_Incomplete_Or_Private_Type (Desig_Type) and then No (Full_View (Desig_Type)) then Freeze_Action_Typ := Def_Id; else Freeze_Action_Typ := Desig_Type; end if; Append_Freeze_Action (Freeze_Action_Typ, Make_Object_Declaration (Loc, Defining_Identifier => Pool_Object, Object_Definition => Make_Subtype_Indication (Loc, Subtype_Mark => New_Reference_To (RTE (RE_Stack_Bounded_Pool), Loc), Constraint => Make_Index_Or_Discriminant_Constraint (Loc, Constraints => New_List ( -- First discriminant is the Pool Size New_Reference_To ( Storage_Size_Variable (Def_Id), Loc), -- Second discriminant is the element size DT_Size, -- Third discriminant is the alignment DT_Align))))); end; Set_Associated_Storage_Pool (Def_Id, Pool_Object); -- Case 3 -- Rep Clause "for Def_Id'Storage_Pool use a_Pool_Object" -- ---> Storage Pool is the specified one elsif Present (Associated_Storage_Pool (Def_Id)) then -- Nothing to do the associated storage pool has been attached -- when analyzing the rep. clause null; end if; -- For access-to-controlled types (including class-wide types and -- Taft-amendment types which potentially have controlled -- components), expand the list controller object that will store -- the dynamically allocated objects. Do not do this -- transformation for expander-generated access types, but do it -- for types that are the full view of types derived from other -- private types. Also suppress the list controller in the case -- of a designated type with convention Java, since this is used -- when binding to Java API specs, where there's no equivalent of -- a finalization list and we don't want to pull in the -- finalization support if not needed. if not Comes_From_Source (Def_Id) and then not Has_Private_Declaration (Def_Id) then null; elsif (Controlled_Type (Desig_Type) and then Convention (Desig_Type) /= Convention_Java) or else (Is_Incomplete_Or_Private_Type (Desig_Type) and then No (Full_View (Desig_Type)) -- An exception is made for types defined in the run-time -- because Ada.Tags.Tag itself is such a type and cannot -- afford this unnecessary overhead that would generates a -- loop in the expansion scheme... and then not In_Runtime (Def_Id) -- Another exception is if Restrictions (No_Finalization) -- is active, since then we know nothing is controlled. and then not Restriction_Active (No_Finalization)) -- If the designated type is not frozen yet, its controlled -- status must be retrieved explicitly. or else (Is_Array_Type (Desig_Type) and then not Is_Frozen (Desig_Type) and then Controlled_Type (Component_Type (Desig_Type))) then Set_Associated_Final_Chain (Def_Id, Make_Defining_Identifier (Loc, New_External_Name (Chars (Def_Id), 'L'))); Append_Freeze_Action (Def_Id, Make_Object_Declaration (Loc, Defining_Identifier => Associated_Final_Chain (Def_Id), Object_Definition => New_Reference_To (RTE (RE_List_Controller), Loc))); end if; end; -- Freeze processing for enumeration types elsif Ekind (Def_Id) = E_Enumeration_Type then -- We only have something to do if we have a non-standard -- representation (i.e. at least one literal whose pos value -- is not the same as its representation) if Has_Non_Standard_Rep (Def_Id) then Freeze_Enumeration_Type (N); end if; -- Private types that are completed by a derivation from a private -- type have an internally generated full view, that needs to be -- frozen. This must be done explicitly because the two views share -- the freeze node, and the underlying full view is not visible when -- the freeze node is analyzed. elsif Is_Private_Type (Def_Id) and then Is_Derived_Type (Def_Id) and then Present (Full_View (Def_Id)) and then Is_Itype (Full_View (Def_Id)) and then Has_Private_Declaration (Full_View (Def_Id)) and then Freeze_Node (Full_View (Def_Id)) = N then Set_Entity (N, Full_View (Def_Id)); Result := Freeze_Type (N); Set_Entity (N, Def_Id); -- All other types require no expander action. There are such cases -- (e.g. task types and protected types). In such cases, the freeze -- nodes are there for use by Gigi. end if; Freeze_Stream_Operations (N, Def_Id); return Result; exception when RE_Not_Available => return False; end Freeze_Type; ------------------------- -- Get_Simple_Init_Val -- ------------------------- function Get_Simple_Init_Val (T : Entity_Id; Loc : Source_Ptr; Size : Uint := No_Uint) return Node_Id is Val : Node_Id; Result : Node_Id; Val_RE : RE_Id; Size_To_Use : Uint; -- This is the size to be used for computation of the appropriate -- initial value for the Normalize_Scalars and Initialize_Scalars case. Lo_Bound : Uint; Hi_Bound : Uint; -- These are the values computed by the procedure Check_Subtype_Bounds procedure Check_Subtype_Bounds; -- This procedure examines the subtype T, and its ancestor subtypes and -- derived types to determine the best known information about the -- bounds of the subtype. After the call Lo_Bound is set either to -- No_Uint if no information can be determined, or to a value which -- represents a known low bound, i.e. a valid value of the subtype can -- not be less than this value. Hi_Bound is similarly set to a known -- high bound (valid value cannot be greater than this). -------------------------- -- Check_Subtype_Bounds -- -------------------------- procedure Check_Subtype_Bounds is ST1 : Entity_Id; ST2 : Entity_Id; Lo : Node_Id; Hi : Node_Id; Loval : Uint; Hival : Uint; begin Lo_Bound := No_Uint; Hi_Bound := No_Uint; -- Loop to climb ancestor subtypes and derived types ST1 := T; loop if not Is_Discrete_Type (ST1) then return; end if; Lo := Type_Low_Bound (ST1); Hi := Type_High_Bound (ST1); if Compile_Time_Known_Value (Lo) then Loval := Expr_Value (Lo); if Lo_Bound = No_Uint or else Lo_Bound < Loval then Lo_Bound := Loval; end if; end if; if Compile_Time_Known_Value (Hi) then Hival := Expr_Value (Hi); if Hi_Bound = No_Uint or else Hi_Bound > Hival then Hi_Bound := Hival; end if; end if; ST2 := Ancestor_Subtype (ST1); if No (ST2) then ST2 := Etype (ST1); end if; exit when ST1 = ST2; ST1 := ST2; end loop; end Check_Subtype_Bounds; -- Start of processing for Get_Simple_Init_Val begin -- For a private type, we should always have an underlying type -- (because this was already checked in Needs_Simple_Initialization). -- What we do is to get the value for the underlying type and then do -- an Unchecked_Convert to the private type. if Is_Private_Type (T) then Val := Get_Simple_Init_Val (Underlying_Type (T), Loc, Size); -- A special case, if the underlying value is null, then qualify it -- with the underlying type, so that the null is properly typed -- Similarly, if it is an aggregate it must be qualified, because an -- unchecked conversion does not provide a context for it. if Nkind (Val) = N_Null or else Nkind (Val) = N_Aggregate then Val := Make_Qualified_Expression (Loc, Subtype_Mark => New_Occurrence_Of (Underlying_Type (T), Loc), Expression => Val); end if; Result := Unchecked_Convert_To (T, Val); -- Don't truncate result (important for Initialize/Normalize_Scalars) if Nkind (Result) = N_Unchecked_Type_Conversion and then Is_Scalar_Type (Underlying_Type (T)) then Set_No_Truncation (Result); end if; return Result; -- For scalars, we must have normalize/initialize scalars case elsif Is_Scalar_Type (T) then pragma Assert (Init_Or_Norm_Scalars); -- Compute size of object. If it is given by the caller, we can use -- it directly, otherwise we use Esize (T) as an estimate. As far as -- we know this covers all cases correctly. if Size = No_Uint or else Size <= Uint_0 then Size_To_Use := UI_Max (Uint_1, Esize (T)); else Size_To_Use := Size; end if; -- Maximum size to use is 64 bits, since we will create values -- of type Unsigned_64 and the range must fit this type. if Size_To_Use /= No_Uint and then Size_To_Use > Uint_64 then Size_To_Use := Uint_64; end if; -- Check known bounds of subtype Check_Subtype_Bounds; -- Processing for Normalize_Scalars case if Normalize_Scalars then -- If zero is invalid, it is a convenient value to use that is -- for sure an appropriate invalid value in all situations. if Lo_Bound /= No_Uint and then Lo_Bound > Uint_0 then Val := Make_Integer_Literal (Loc, 0); -- Cases where all one bits is the appropriate invalid value -- For modular types, all 1 bits is either invalid or valid. If -- it is valid, then there is nothing that can be done since there -- are no invalid values (we ruled out zero already). -- For signed integer types that have no negative values, either -- there is room for negative values, or there is not. If there -- is, then all 1 bits may be interpretecd as minus one, which is -- certainly invalid. Alternatively it is treated as the largest -- positive value, in which case the observation for modular types -- still applies. -- For float types, all 1-bits is a NaN (not a number), which is -- certainly an appropriately invalid value. elsif Is_Unsigned_Type (T) or else Is_Floating_Point_Type (T) or else Is_Enumeration_Type (T) then Val := Make_Integer_Literal (Loc, 2 ** Size_To_Use - 1); -- Resolve as Unsigned_64, because the largest number we -- can generate is out of range of universal integer. Analyze_And_Resolve (Val, RTE (RE_Unsigned_64)); -- Case of signed types else declare Signed_Size : constant Uint := UI_Min (Uint_63, Size_To_Use - 1); begin -- Normally we like to use the most negative number. The -- one exception is when this number is in the known -- subtype range and the largest positive number is not in -- the known subtype range. -- For this exceptional case, use largest positive value if Lo_Bound /= No_Uint and then Hi_Bound /= No_Uint and then Lo_Bound <= (-(2 ** Signed_Size)) and then Hi_Bound < 2 ** Signed_Size then Val := Make_Integer_Literal (Loc, 2 ** Signed_Size - 1); -- Normal case of largest negative value else Val := Make_Integer_Literal (Loc, -(2 ** Signed_Size)); end if; end; end if; -- Here for Initialize_Scalars case else -- For float types, use float values from System.Scalar_Values if Is_Floating_Point_Type (T) then if Root_Type (T) = Standard_Short_Float then Val_RE := RE_IS_Isf; elsif Root_Type (T) = Standard_Float then Val_RE := RE_IS_Ifl; elsif Root_Type (T) = Standard_Long_Float then Val_RE := RE_IS_Ilf; else pragma Assert (Root_Type (T) = Standard_Long_Long_Float); Val_RE := RE_IS_Ill; end if; -- If zero is invalid, use zero values from System.Scalar_Values elsif Lo_Bound /= No_Uint and then Lo_Bound > Uint_0 then if Size_To_Use <= 8 then Val_RE := RE_IS_Iz1; elsif Size_To_Use <= 16 then Val_RE := RE_IS_Iz2; elsif Size_To_Use <= 32 then Val_RE := RE_IS_Iz4; else Val_RE := RE_IS_Iz8; end if; -- For unsigned, use unsigned values from System.Scalar_Values elsif Is_Unsigned_Type (T) then if Size_To_Use <= 8 then Val_RE := RE_IS_Iu1; elsif Size_To_Use <= 16 then Val_RE := RE_IS_Iu2; elsif Size_To_Use <= 32 then Val_RE := RE_IS_Iu4; else Val_RE := RE_IS_Iu8; end if; -- For signed, use signed values from System.Scalar_Values else if Size_To_Use <= 8 then Val_RE := RE_IS_Is1; elsif Size_To_Use <= 16 then Val_RE := RE_IS_Is2; elsif Size_To_Use <= 32 then Val_RE := RE_IS_Is4; else Val_RE := RE_IS_Is8; end if; end if; Val := New_Occurrence_Of (RTE (Val_RE), Loc); end if; -- The final expression is obtained by doing an unchecked conversion -- of this result to the base type of the required subtype. We use -- the base type to avoid the unchecked conversion from chopping -- bits, and then we set Kill_Range_Check to preserve the "bad" -- value. Result := Unchecked_Convert_To (Base_Type (T), Val); -- Ensure result is not truncated, since we want the "bad" bits -- and also kill range check on result. if Nkind (Result) = N_Unchecked_Type_Conversion then Set_No_Truncation (Result); Set_Kill_Range_Check (Result, True); end if; return Result; -- String or Wide_[Wide]_String (must have Initialize_Scalars set) elsif Root_Type (T) = Standard_String or else Root_Type (T) = Standard_Wide_String or else Root_Type (T) = Standard_Wide_Wide_String then pragma Assert (Init_Or_Norm_Scalars); return Make_Aggregate (Loc, Component_Associations => New_List ( Make_Component_Association (Loc, Choices => New_List ( Make_Others_Choice (Loc)), Expression => Get_Simple_Init_Val (Component_Type (T), Loc, Esize (Root_Type (T)))))); -- Access type is initialized to null elsif Is_Access_Type (T) then return Make_Null (Loc); -- No other possibilities should arise, since we should only be -- calling Get_Simple_Init_Val if Needs_Simple_Initialization -- returned True, indicating one of the above cases held. else raise Program_Error; end if; exception when RE_Not_Available => return Empty; end Get_Simple_Init_Val; ------------------------------ -- Has_New_Non_Standard_Rep -- ------------------------------ function Has_New_Non_Standard_Rep (T : Entity_Id) return Boolean is begin if not Is_Derived_Type (T) then return Has_Non_Standard_Rep (T) or else Has_Non_Standard_Rep (Root_Type (T)); -- If Has_Non_Standard_Rep is not set on the derived type, the -- representation is fully inherited. elsif not Has_Non_Standard_Rep (T) then return False; else return First_Rep_Item (T) /= First_Rep_Item (Root_Type (T)); -- May need a more precise check here: the First_Rep_Item may -- be a stream attribute, which does not affect the representation -- of the type ??? end if; end Has_New_Non_Standard_Rep; ---------------- -- In_Runtime -- ---------------- function In_Runtime (E : Entity_Id) return Boolean is S1 : Entity_Id := Scope (E); begin while Scope (S1) /= Standard_Standard loop S1 := Scope (S1); end loop; return Chars (S1) = Name_System or else Chars (S1) = Name_Ada; end In_Runtime; ------------------ -- Init_Formals -- ------------------ function Init_Formals (Typ : Entity_Id) return List_Id is Loc : constant Source_Ptr := Sloc (Typ); Formals : List_Id; begin -- First parameter is always _Init : in out typ. Note that we need -- this to be in/out because in the case of the task record value, -- there are default record fields (_Priority, _Size, -Task_Info) -- that may be referenced in the generated initialization routine. Formals := New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uInit), In_Present => True, Out_Present => True, Parameter_Type => New_Reference_To (Typ, Loc))); -- For task record value, or type that contains tasks, add two more -- formals, _Master : Master_Id and _Chain : in out Activation_Chain -- We also add these parameters for the task record type case. if Has_Task (Typ) or else (Is_Record_Type (Typ) and then Is_Task_Record_Type (Typ)) then Append_To (Formals, Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uMaster), Parameter_Type => New_Reference_To (RTE (RE_Master_Id), Loc))); Append_To (Formals, Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uChain), In_Present => True, Out_Present => True, Parameter_Type => New_Reference_To (RTE (RE_Activation_Chain), Loc))); Append_To (Formals, Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_uTask_Name), In_Present => True, Parameter_Type => New_Reference_To (Standard_String, Loc))); end if; return Formals; exception when RE_Not_Available => return Empty_List; end Init_Formals; ------------------ -- Make_Eq_Case -- ------------------ -- -- case X.D1 is -- when V1 => on subcomponents -- ... -- when Vn => on subcomponents -- end case; function Make_Eq_Case (E : Entity_Id; CL : Node_Id; Discr : Entity_Id := Empty) return List_Id is Loc : constant Source_Ptr := Sloc (E); Result : constant List_Id := New_List; Variant : Node_Id; Alt_List : List_Id; begin Append_To (Result, Make_Eq_If (E, Component_Items (CL))); if No (Variant_Part (CL)) then return Result; end if; Variant := First_Non_Pragma (Variants (Variant_Part (CL))); if No (Variant) then return Result; end if; Alt_List := New_List; while Present (Variant) loop Append_To (Alt_List, Make_Case_Statement_Alternative (Loc, Discrete_Choices => New_Copy_List (Discrete_Choices (Variant)), Statements => Make_Eq_Case (E, Component_List (Variant)))); Next_Non_Pragma (Variant); end loop; -- If we have an Unchecked_Union, use one of the parameters that -- captures the discriminants. if Is_Unchecked_Union (E) then Append_To (Result, Make_Case_Statement (Loc, Expression => New_Reference_To (Discr, Loc), Alternatives => Alt_List)); else Append_To (Result, Make_Case_Statement (Loc, Expression => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_X), Selector_Name => New_Copy (Name (Variant_Part (CL)))), Alternatives => Alt_List)); end if; return Result; end Make_Eq_Case; ---------------- -- Make_Eq_If -- ---------------- -- Generates: -- if -- X.C1 /= Y.C1 -- or else -- X.C2 /= Y.C2 -- ... -- then -- return False; -- end if; -- or a null statement if the list L is empty function Make_Eq_If (E : Entity_Id; L : List_Id) return Node_Id is Loc : constant Source_Ptr := Sloc (E); C : Node_Id; Field_Name : Name_Id; Cond : Node_Id; begin if No (L) then return Make_Null_Statement (Loc); else Cond := Empty; C := First_Non_Pragma (L); while Present (C) loop Field_Name := Chars (Defining_Identifier (C)); -- The tags must not be compared they are not part of the value. -- Note also that in the following, we use Make_Identifier for -- the component names. Use of New_Reference_To to identify the -- components would be incorrect because the wrong entities for -- discriminants could be picked up in the private type case. if Field_Name /= Name_uTag then Evolve_Or_Else (Cond, Make_Op_Ne (Loc, Left_Opnd => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_X), Selector_Name => Make_Identifier (Loc, Field_Name)), Right_Opnd => Make_Selected_Component (Loc, Prefix => Make_Identifier (Loc, Name_Y), Selector_Name => Make_Identifier (Loc, Field_Name)))); end if; Next_Non_Pragma (C); end loop; if No (Cond) then return Make_Null_Statement (Loc); else return Make_Implicit_If_Statement (E, Condition => Cond, Then_Statements => New_List ( Make_Return_Statement (Loc, Expression => New_Occurrence_Of (Standard_False, Loc)))); end if; end if; end Make_Eq_If; ------------------------------------- -- Make_Predefined_Primitive_Specs -- ------------------------------------- procedure Make_Predefined_Primitive_Specs (Tag_Typ : Entity_Id; Predef_List : out List_Id; Renamed_Eq : out Node_Id) is Loc : constant Source_Ptr := Sloc (Tag_Typ); Res : constant List_Id := New_List; Prim : Elmt_Id; Eq_Needed : Boolean; Eq_Spec : Node_Id; Eq_Name : Name_Id := Name_Op_Eq; function Is_Predefined_Eq_Renaming (Prim : Node_Id) return Boolean; -- Returns true if Prim is a renaming of an unresolved predefined -- equality operation. ------------------------------- -- Is_Predefined_Eq_Renaming -- ------------------------------- function Is_Predefined_Eq_Renaming (Prim : Node_Id) return Boolean is begin return Chars (Prim) /= Name_Op_Eq and then Present (Alias (Prim)) and then Comes_From_Source (Prim) and then Is_Intrinsic_Subprogram (Alias (Prim)) and then Chars (Alias (Prim)) = Name_Op_Eq; end Is_Predefined_Eq_Renaming; -- Start of processing for Make_Predefined_Primitive_Specs begin Renamed_Eq := Empty; -- Spec of _Size Append_To (Res, Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uSize, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Long_Long_Integer)); -- Spec of _Alignment Append_To (Res, Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uAlignment, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Integer)); -- Specs for dispatching stream attributes declare Stream_Op_TSS_Names : constant array (Integer range <>) of TSS_Name_Type := (TSS_Stream_Read, TSS_Stream_Write, TSS_Stream_Input, TSS_Stream_Output); begin for Op in Stream_Op_TSS_Names'Range loop if Stream_Operation_OK (Tag_Typ, Stream_Op_TSS_Names (Op)) then Append_To (Res, Predef_Stream_Attr_Spec (Loc, Tag_Typ, Stream_Op_TSS_Names (Op))); end if; end loop; end; -- Spec of "=" if expanded if the type is not limited and if a -- user defined "=" was not already declared for the non-full -- view of a private extension if not Is_Limited_Type (Tag_Typ) then Eq_Needed := True; Prim := First_Elmt (Primitive_Operations (Tag_Typ)); while Present (Prim) loop -- If a primitive is encountered that renames the predefined -- equality operator before reaching any explicit equality -- primitive, then we still need to create a predefined -- equality function, because calls to it can occur via -- the renaming. A new name is created for the equality -- to avoid conflicting with any user-defined equality. -- (Note that this doesn't account for renamings of -- equality nested within subpackages???) if Is_Predefined_Eq_Renaming (Node (Prim)) then Eq_Name := New_External_Name (Chars (Node (Prim)), 'E'); elsif Chars (Node (Prim)) = Name_Op_Eq and then (No (Alias (Node (Prim))) or else Nkind (Unit_Declaration_Node (Node (Prim))) = N_Subprogram_Renaming_Declaration) and then Etype (First_Formal (Node (Prim))) = Etype (Next_Formal (First_Formal (Node (Prim)))) and then Base_Type (Etype (Node (Prim))) = Standard_Boolean then Eq_Needed := False; exit; -- If the parent equality is abstract, the inherited equality is -- abstract as well, and no body can be created for for it. elsif Chars (Node (Prim)) = Name_Op_Eq and then Present (Alias (Node (Prim))) and then Is_Abstract (Alias (Node (Prim))) then Eq_Needed := False; exit; end if; Next_Elmt (Prim); end loop; -- If a renaming of predefined equality was found -- but there was no user-defined equality (so Eq_Needed -- is still true), then set the name back to Name_Op_Eq. -- But in the case where a user-defined equality was -- located after such a renaming, then the predefined -- equality function is still needed, so Eq_Needed must -- be set back to True. if Eq_Name /= Name_Op_Eq then if Eq_Needed then Eq_Name := Name_Op_Eq; else Eq_Needed := True; end if; end if; if Eq_Needed then Eq_Spec := Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Eq_Name, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Y), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Boolean); Append_To (Res, Eq_Spec); if Eq_Name /= Name_Op_Eq then Renamed_Eq := Defining_Unit_Name (Specification (Eq_Spec)); Prim := First_Elmt (Primitive_Operations (Tag_Typ)); while Present (Prim) loop -- Any renamings of equality that appeared before an -- overriding equality must be updated to refer to -- the entity for the predefined equality, otherwise -- calls via the renaming would get incorrectly -- resolved to call the user-defined equality function. if Is_Predefined_Eq_Renaming (Node (Prim)) then Set_Alias (Node (Prim), Renamed_Eq); -- Exit upon encountering a user-defined equality elsif Chars (Node (Prim)) = Name_Op_Eq and then No (Alias (Node (Prim))) then exit; end if; Next_Elmt (Prim); end loop; end if; end if; -- Spec for dispatching assignment Append_To (Res, Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uAssign, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Out_Present => True, Parameter_Type => New_Reference_To (Tag_Typ, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Y), Parameter_Type => New_Reference_To (Tag_Typ, Loc))))); end if; -- Generate the declarations for the following primitive operations: -- disp_asynchronous_select -- disp_conditional_select -- disp_get_prim_op_kind -- disp_get_task_id -- disp_timed_select -- for limited interfaces and synchronized types that implement a -- limited interface. if Ada_Version >= Ada_05 and then ((Is_Interface (Tag_Typ) and then Is_Limited_Record (Tag_Typ)) or else (Is_Concurrent_Record_Type (Tag_Typ) and then Implements_Interface ( Typ => Tag_Typ, Kind => Any_Limited_Interface, Check_Parent => True))) then Append_To (Res, Make_Subprogram_Declaration (Loc, Specification => Make_Disp_Asynchronous_Select_Spec (Tag_Typ))); Append_To (Res, Make_Subprogram_Declaration (Loc, Specification => Make_Disp_Conditional_Select_Spec (Tag_Typ))); Append_To (Res, Make_Subprogram_Declaration (Loc, Specification => Make_Disp_Get_Prim_Op_Kind_Spec (Tag_Typ))); Append_To (Res, Make_Subprogram_Declaration (Loc, Specification => Make_Disp_Get_Task_Id_Spec (Tag_Typ))); Append_To (Res, Make_Subprogram_Declaration (Loc, Specification => Make_Disp_Timed_Select_Spec (Tag_Typ))); end if; -- Specs for finalization actions that may be required in case a -- future extension contain a controlled element. We generate those -- only for root tagged types where they will get dummy bodies or -- when the type has controlled components and their body must be -- generated. It is also impossible to provide those for tagged -- types defined within s-finimp since it would involve circularity -- problems if In_Finalization_Root (Tag_Typ) then null; -- We also skip these if finalization is not available elsif Restriction_Active (No_Finalization) then null; elsif Etype (Tag_Typ) = Tag_Typ or else Controlled_Type (Tag_Typ) then if not Is_Limited_Type (Tag_Typ) then Append_To (Res, Predef_Deep_Spec (Loc, Tag_Typ, TSS_Deep_Adjust)); end if; Append_To (Res, Predef_Deep_Spec (Loc, Tag_Typ, TSS_Deep_Finalize)); end if; Predef_List := Res; end Make_Predefined_Primitive_Specs; --------------------------------- -- Needs_Simple_Initialization -- --------------------------------- function Needs_Simple_Initialization (T : Entity_Id) return Boolean is begin -- Check for private type, in which case test applies to the -- underlying type of the private type. if Is_Private_Type (T) then declare RT : constant Entity_Id := Underlying_Type (T); begin if Present (RT) then return Needs_Simple_Initialization (RT); else return False; end if; end; -- Cases needing simple initialization are access types, and, if pragma -- Normalize_Scalars or Initialize_Scalars is in effect, then all scalar -- types. elsif Is_Access_Type (T) or else (Init_Or_Norm_Scalars and then (Is_Scalar_Type (T))) then return True; -- If Initialize/Normalize_Scalars is in effect, string objects also -- need initialization, unless they are created in the course of -- expanding an aggregate (since in the latter case they will be -- filled with appropriate initializing values before they are used). elsif Init_Or_Norm_Scalars and then (Root_Type (T) = Standard_String or else Root_Type (T) = Standard_Wide_String or else Root_Type (T) = Standard_Wide_Wide_String) and then (not Is_Itype (T) or else Nkind (Associated_Node_For_Itype (T)) /= N_Aggregate) then return True; else return False; end if; end Needs_Simple_Initialization; ---------------------- -- Predef_Deep_Spec -- ---------------------- function Predef_Deep_Spec (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : TSS_Name_Type; For_Body : Boolean := False) return Node_Id is Prof : List_Id; Type_B : Entity_Id; begin if Name = TSS_Deep_Finalize then Prof := New_List; Type_B := Standard_Boolean; else Prof := New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_L), In_Present => True, Out_Present => True, Parameter_Type => New_Reference_To (RTE (RE_Finalizable_Ptr), Loc))); Type_B := Standard_Short_Short_Integer; end if; Append_To (Prof, Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_V), In_Present => True, Out_Present => True, Parameter_Type => New_Reference_To (Tag_Typ, Loc))); Append_To (Prof, Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_B), Parameter_Type => New_Reference_To (Type_B, Loc))); return Predef_Spec_Or_Body (Loc, Name => Make_TSS_Name (Tag_Typ, Name), Tag_Typ => Tag_Typ, Profile => Prof, For_Body => For_Body); exception when RE_Not_Available => return Empty; end Predef_Deep_Spec; ------------------------- -- Predef_Spec_Or_Body -- ------------------------- function Predef_Spec_Or_Body (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : Name_Id; Profile : List_Id; Ret_Type : Entity_Id := Empty; For_Body : Boolean := False) return Node_Id is Id : constant Entity_Id := Make_Defining_Identifier (Loc, Name); Spec : Node_Id; begin Set_Is_Public (Id, Is_Public (Tag_Typ)); -- The internal flag is set to mark these declarations because -- they have specific properties. First they are primitives even -- if they are not defined in the type scope (the freezing point -- is not necessarily in the same scope), furthermore the -- predefined equality can be overridden by a user-defined -- equality, no body will be generated in this case. Set_Is_Internal (Id); if not Debug_Generated_Code then Set_Debug_Info_Off (Id); end if; if No (Ret_Type) then Spec := Make_Procedure_Specification (Loc, Defining_Unit_Name => Id, Parameter_Specifications => Profile); else Spec := Make_Function_Specification (Loc, Defining_Unit_Name => Id, Parameter_Specifications => Profile, Result_Definition => New_Reference_To (Ret_Type, Loc)); end if; -- If body case, return empty subprogram body. Note that this is -- ill-formed, because there is not even a null statement, and -- certainly not a return in the function case. The caller is -- expected to do surgery on the body to add the appropriate stuff. if For_Body then return Make_Subprogram_Body (Loc, Spec, Empty_List, Empty); -- For the case of Input/Output attributes applied to an abstract type, -- generate abstract specifications. These will never be called, -- but we need the slots allocated in the dispatching table so -- that typ'Class'Input and typ'Class'Output will work properly. elsif (Is_TSS (Name, TSS_Stream_Input) or else Is_TSS (Name, TSS_Stream_Output)) and then Is_Abstract (Tag_Typ) then return Make_Abstract_Subprogram_Declaration (Loc, Spec); -- Normal spec case, where we return a subprogram declaration else return Make_Subprogram_Declaration (Loc, Spec); end if; end Predef_Spec_Or_Body; ----------------------------- -- Predef_Stream_Attr_Spec -- ----------------------------- function Predef_Stream_Attr_Spec (Loc : Source_Ptr; Tag_Typ : Entity_Id; Name : TSS_Name_Type; For_Body : Boolean := False) return Node_Id is Ret_Type : Entity_Id; begin if Name = TSS_Stream_Input then Ret_Type := Tag_Typ; else Ret_Type := Empty; end if; return Predef_Spec_Or_Body (Loc, Name => Make_TSS_Name (Tag_Typ, Name), Tag_Typ => Tag_Typ, Profile => Build_Stream_Attr_Profile (Loc, Tag_Typ, Name), Ret_Type => Ret_Type, For_Body => For_Body); end Predef_Stream_Attr_Spec; --------------------------------- -- Predefined_Primitive_Bodies -- --------------------------------- function Predefined_Primitive_Bodies (Tag_Typ : Entity_Id; Renamed_Eq : Node_Id) return List_Id is Loc : constant Source_Ptr := Sloc (Tag_Typ); Res : constant List_Id := New_List; Decl : Node_Id; Prim : Elmt_Id; Eq_Needed : Boolean; Eq_Name : Name_Id; Ent : Entity_Id; begin -- See if we have a predefined "=" operator if Present (Renamed_Eq) then Eq_Needed := True; Eq_Name := Chars (Renamed_Eq); else Eq_Needed := False; Eq_Name := No_Name; Prim := First_Elmt (Primitive_Operations (Tag_Typ)); while Present (Prim) loop if Chars (Node (Prim)) = Name_Op_Eq and then Is_Internal (Node (Prim)) then Eq_Needed := True; Eq_Name := Name_Op_Eq; end if; Next_Elmt (Prim); end loop; end if; -- Body of _Alignment Decl := Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uAlignment, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Integer, For_Body => True); Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, New_List ( Make_Return_Statement (Loc, Expression => Make_Attribute_Reference (Loc, Prefix => Make_Identifier (Loc, Name_X), Attribute_Name => Name_Alignment))))); Append_To (Res, Decl); -- Body of _Size Decl := Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uSize, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Long_Long_Integer, For_Body => True); Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, New_List ( Make_Return_Statement (Loc, Expression => Make_Attribute_Reference (Loc, Prefix => Make_Identifier (Loc, Name_X), Attribute_Name => Name_Size))))); Append_To (Res, Decl); -- Bodies for Dispatching stream IO routines. We need these only for -- non-limited types (in the limited case there is no dispatching). -- We also skip them if dispatching or finalization are not available. if Stream_Operation_OK (Tag_Typ, TSS_Stream_Read) and then No (TSS (Tag_Typ, TSS_Stream_Read)) then Build_Record_Read_Procedure (Loc, Tag_Typ, Decl, Ent); Append_To (Res, Decl); end if; if Stream_Operation_OK (Tag_Typ, TSS_Stream_Write) and then No (TSS (Tag_Typ, TSS_Stream_Write)) then Build_Record_Write_Procedure (Loc, Tag_Typ, Decl, Ent); Append_To (Res, Decl); end if; -- Skip bodies of _Input and _Output for the abstract case, since -- the corresponding specs are abstract (see Predef_Spec_Or_Body) if not Is_Abstract (Tag_Typ) then if Stream_Operation_OK (Tag_Typ, TSS_Stream_Input) and then No (TSS (Tag_Typ, TSS_Stream_Input)) then Build_Record_Or_Elementary_Input_Function (Loc, Tag_Typ, Decl, Ent); Append_To (Res, Decl); end if; if Stream_Operation_OK (Tag_Typ, TSS_Stream_Output) and then No (TSS (Tag_Typ, TSS_Stream_Output)) then Build_Record_Or_Elementary_Output_Procedure (Loc, Tag_Typ, Decl, Ent); Append_To (Res, Decl); end if; end if; -- Generate the bodies for the following primitive operations: -- disp_asynchronous_select -- disp_conditional_select -- disp_get_prim_op_kind -- disp_get_task_id -- disp_timed_select -- for limited interfaces and synchronized types that implement a -- limited interface. The interface versions will have null bodies. if Ada_Version >= Ada_05 and then ((Is_Interface (Tag_Typ) and then Is_Limited_Record (Tag_Typ)) or else (Is_Concurrent_Record_Type (Tag_Typ) and then Implements_Interface ( Typ => Tag_Typ, Kind => Any_Limited_Interface, Check_Parent => True))) then Append_To (Res, Make_Disp_Asynchronous_Select_Body (Tag_Typ)); Append_To (Res, Make_Disp_Conditional_Select_Body (Tag_Typ)); Append_To (Res, Make_Disp_Get_Prim_Op_Kind_Body (Tag_Typ)); Append_To (Res, Make_Disp_Get_Task_Id_Body (Tag_Typ)); Append_To (Res, Make_Disp_Timed_Select_Body (Tag_Typ)); end if; if not Is_Limited_Type (Tag_Typ) then -- Body for equality if Eq_Needed then Decl := Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Eq_Name, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Parameter_Type => New_Reference_To (Tag_Typ, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Y), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), Ret_Type => Standard_Boolean, For_Body => True); declare Def : constant Node_Id := Parent (Tag_Typ); Stmts : constant List_Id := New_List; Variant_Case : Boolean := Has_Discriminants (Tag_Typ); Comps : Node_Id := Empty; Typ_Def : Node_Id := Type_Definition (Def); begin if Variant_Case then if Nkind (Typ_Def) = N_Derived_Type_Definition then Typ_Def := Record_Extension_Part (Typ_Def); end if; if Present (Typ_Def) then Comps := Component_List (Typ_Def); end if; Variant_Case := Present (Comps) and then Present (Variant_Part (Comps)); end if; if Variant_Case then Append_To (Stmts, Make_Eq_If (Tag_Typ, Discriminant_Specifications (Def))); Append_List_To (Stmts, Make_Eq_Case (Tag_Typ, Comps)); Append_To (Stmts, Make_Return_Statement (Loc, Expression => New_Reference_To (Standard_True, Loc))); else Append_To (Stmts, Make_Return_Statement (Loc, Expression => Expand_Record_Equality (Tag_Typ, Typ => Tag_Typ, Lhs => Make_Identifier (Loc, Name_X), Rhs => Make_Identifier (Loc, Name_Y), Bodies => Declarations (Decl)))); end if; Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, Stmts)); end; Append_To (Res, Decl); end if; -- Body for dispatching assignment Decl := Predef_Spec_Or_Body (Loc, Tag_Typ => Tag_Typ, Name => Name_uAssign, Profile => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_X), Out_Present => True, Parameter_Type => New_Reference_To (Tag_Typ, Loc)), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Y), Parameter_Type => New_Reference_To (Tag_Typ, Loc))), For_Body => True); Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, New_List ( Make_Assignment_Statement (Loc, Name => Make_Identifier (Loc, Name_X), Expression => Make_Identifier (Loc, Name_Y))))); Append_To (Res, Decl); end if; -- Generate dummy bodies for finalization actions of types that have -- no controlled components. -- Skip this processing if we are in the finalization routine in the -- runtime itself, otherwise we get hopelessly circularly confused! if In_Finalization_Root (Tag_Typ) then null; -- Skip this if finalization is not available elsif Restriction_Active (No_Finalization) then null; elsif (Etype (Tag_Typ) = Tag_Typ or else Is_Controlled (Tag_Typ)) and then not Has_Controlled_Component (Tag_Typ) then if not Is_Limited_Type (Tag_Typ) then Decl := Predef_Deep_Spec (Loc, Tag_Typ, TSS_Deep_Adjust, True); if Is_Controlled (Tag_Typ) then Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, Make_Adjust_Call ( Ref => Make_Identifier (Loc, Name_V), Typ => Tag_Typ, Flist_Ref => Make_Identifier (Loc, Name_L), With_Attach => Make_Identifier (Loc, Name_B)))); else Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, New_List ( Make_Null_Statement (Loc)))); end if; Append_To (Res, Decl); end if; Decl := Predef_Deep_Spec (Loc, Tag_Typ, TSS_Deep_Finalize, True); if Is_Controlled (Tag_Typ) then Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, Make_Final_Call ( Ref => Make_Identifier (Loc, Name_V), Typ => Tag_Typ, With_Detach => Make_Identifier (Loc, Name_B)))); else Set_Handled_Statement_Sequence (Decl, Make_Handled_Sequence_Of_Statements (Loc, New_List ( Make_Null_Statement (Loc)))); end if; Append_To (Res, Decl); end if; return Res; end Predefined_Primitive_Bodies; --------------------------------- -- Predefined_Primitive_Freeze -- --------------------------------- function Predefined_Primitive_Freeze (Tag_Typ : Entity_Id) return List_Id is Loc : constant Source_Ptr := Sloc (Tag_Typ); Res : constant List_Id := New_List; Prim : Elmt_Id; Frnodes : List_Id; begin Prim := First_Elmt (Primitive_Operations (Tag_Typ)); while Present (Prim) loop if Is_Internal (Node (Prim)) then Frnodes := Freeze_Entity (Node (Prim), Loc); if Present (Frnodes) then Append_List_To (Res, Frnodes); end if; end if; Next_Elmt (Prim); end loop; return Res; end Predefined_Primitive_Freeze; ------------------------- -- Stream_Operation_OK -- ------------------------- function Stream_Operation_OK (Typ : Entity_Id; Operation : TSS_Name_Type) return Boolean is Has_Inheritable_Stream_Attribute : Boolean := False; begin if Is_Limited_Type (Typ) and then Is_Tagged_Type (Typ) and then Is_Derived_Type (Typ) then -- Special case of a limited type extension: a default implementation -- of the stream attributes Read and Write exists if the attribute -- has been specified for an ancestor type. Has_Inheritable_Stream_Attribute := Present (Find_Inherited_TSS (Base_Type (Etype (Typ)), Operation)); end if; return not (Is_Limited_Type (Typ) and then not Has_Inheritable_Stream_Attribute) and then not Has_Unknown_Discriminants (Typ) and then RTE_Available (RE_Tag) and then RTE_Available (RE_Root_Stream_Type) and then not Restriction_Active (No_Dispatch) and then not Restriction_Active (No_Streams); end Stream_Operation_OK; end Exp_Ch3;