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------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- E I N F O --
-- --
-- B o d y --
-- --
-- $Revision$
-- --
-- Copyright (C) 1992-2001 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, 59 Temple Place - Suite 330, Boston, --
-- MA 02111-1307, USA. --
-- --
-- As a special exception, if other files instantiate generics from this --
-- unit, or you link this unit with other files to produce an executable, --
-- this unit does not by itself cause the resulting executable to be --
-- covered by the GNU General Public License. This exception does not --
-- however invalidate any other reasons why the executable file might be --
-- covered by the GNU Public License. --
-- --
-- GNAT was originally developed by the GNAT team at New York University. --
-- It is now maintained by Ada Core Technologies Inc (http://www.gnat.com). --
-- --
------------------------------------------------------------------------------
pragma Style_Checks (All_Checks);
-- Turn off subprogram ordering, not used for this unit
with Atree; use Atree;
with Namet; use Namet;
with Nlists; use Nlists;
with Sinfo; use Sinfo;
with Snames; use Snames;
with Stand; use Stand;
with Output; use Output;
package body Einfo is
use Atree.Unchecked_Access;
-- This is one of the packages that is allowed direct untyped access to
-- the fields in a node, since it provides the next level abstraction
-- which incorporates appropriate checks.
----------------------------------------------
-- Usage of Fields in Defining Entity Nodes --
----------------------------------------------
-- Four of these fields are defined in Sinfo, since they in are the
-- base part of the node. The access routines for these fields and
-- the corresponding set procedures are defined in Sinfo. These fields
-- are present in all entities. Note that Homonym is also in the base
-- part of the node, but has access routines that are more properly
-- part of Einfo, which is why they are defined here.
-- Chars Name1
-- Next_Entity Node2
-- Scope Node3
-- Etype Node5
-- Remaining fields are present only in extended nodes (i.e. entities)
-- The following fields are present in all entities
-- Homonym Node4
-- First_Rep_Item Node6
-- Freeze_Node Node7
-- The usage of each field (and the entity kinds to which it applies)
-- depends on the particular field (see Einfo spec for details).
-- Associated_Node_For_Itype Node8
-- Dependent_Instances Elist8
-- Hiding_Loop_Variable Node8
-- Mechanism Uint8 (but returns Mechanism_Type)
-- Normalized_First_Bit Uint8
-- Class_Wide_Type Node9
-- Normalized_Position Uint9
-- Size_Check_Code Node9
-- Renaming_Map Uint9
-- Discriminal_Link Node10
-- Handler_Records List10
-- Normalized_Position_Max Uint10
-- Referenced_Object Node10
-- Component_Bit_Offset Uint11
-- Full_View Node11
-- Entry_Component Node11
-- Enumeration_Pos Uint11
-- Protected_Body_Subprogram Node11
-- Block_Node Node11
-- Barrier_Function Node12
-- Enumeration_Rep Uint12
-- Esize Uint12
-- Next_Inlined_Subprogram Node12
-- Corresponding_Equality Node13
-- Component_Clause Node13
-- Debug_Renaming_Link Node13
-- Elaboration_Entity Node13
-- Extra_Accessibility Node13
-- RM_Size Uint13
-- Alignment Uint14
-- First_Optional_Parameter Node14
-- Shadow_Entities List14
-- Discriminant_Number Uint15
-- DT_Position Uint15
-- DT_Entry_Count Uint15
-- Entry_Bodies_Array Node15
-- Entry_Parameters_Type Node15
-- Extra_Formal Node15
-- Lit_Indexes Node15
-- Primitive_Operations Elist15
-- Related_Instance Node15
-- Scale_Value Uint15
-- Storage_Size_Variable Node15
-- String_Literal_Low_Bound Node15
-- Shared_Var_Read_Proc Node15
-- Access_Disp_Table Node16
-- Cloned_Subtype Node16
-- DTC_Entity Node16
-- Entry_Formal Node16
-- First_Private_Entity Node16
-- Lit_Strings Node16
-- String_Literal_Length Uint16
-- Unset_Reference Node16
-- Actual_Subtype Node17
-- Digits_Value Uint17
-- Discriminal Node17
-- First_Entity Node17
-- First_Index Node17
-- First_Literal Node17
-- Master_Id Node17
-- Modulus Uint17
-- Object_Ref Node17
-- Prival Node17
-- Alias Node18
-- Corresponding_Concurrent_Type Node18
-- Corresponding_Record_Type Node18
-- Delta_Value Ureal18
-- Enclosing_Scope Node18
-- Equivalent_Type Node18
-- Private_Dependents Elist18
-- Renamed_Entity Node18
-- Renamed_Object Node18
-- Body_Entity Node19
-- Corresponding_Discriminant Node19
-- Finalization_Chain_Entity Node19
-- Parent_Subtype Node19
-- Related_Array_Object Node19
-- Spec_Entity Node19
-- Underlying_Full_View Node19
-- Component_Type Node20
-- Default_Value Node20
-- Directly_Designated_Type Node20
-- Discriminant_Checking_Func Node20
-- Discriminant_Default_Value Node20
-- Last_Entity Node20
-- Register_Exception_Call Node20
-- Scalar_Range Node20
-- Accept_Address Elist21
-- Default_Expr_Function Node21
-- Discriminant_Constraint Elist21
-- Small_Value Ureal21
-- Interface_Name Node21
-- Associated_Storage_Pool Node22
-- Component_Size Uint22
-- Corresponding_Remote_Type Node22
-- Enumeration_Rep_Expr Node22
-- Exception_Code Uint22
-- Original_Record_Component Node22
-- Private_View Node22
-- Protected_Formal Node22
-- Scope_Depth_Value Uint22
-- Shared_Var_Assign_Proc Node22
-- Associated_Final_Chain Node23
-- CR_Discriminant Node23
-- Girder_Constraint Elist23
-- Entry_Cancel_Parameter Node23
-- Extra_Constrained Node23
-- Generic_Renamings Elist23
-- Inner_Instances Elist23
-- Enum_Pos_To_Rep Node23
-- Packed_Array_Type Node23
-- Privals_Chain Elist23
-- Protected_Operation Node23
---------------------------------------------
-- Usage of Flags in Defining Entity Nodes --
---------------------------------------------
-- All flags are unique, there is no overlaying, so each flag is physically
-- present in every entity. However, for many of the flags, it only makes
-- sense for them to be set true for certain subsets of entity kinds. See
-- the spec of Einfo for further details.
-- Note: Flag1-Flag3 are absent from this list, since these flag positions
-- are used for the flags Analyzed, Comes_From_Source, and Error_Posted,
-- which are common to all nodes, including entity nodes.
-- Is_Frozen Flag4
-- Has_Discriminants Flag5
-- Is_Dispatching_Operation Flag6
-- Is_Immediately_Visible Flag7
-- In_Use Flag8
-- Is_Potentially_Use_Visible Flag9
-- Is_Public Flag10
-- Is_Inlined Flag11
-- Is_Constrained Flag12
-- Is_Generic_Type Flag13
-- Depends_On_Private Flag14
-- Is_Aliased Flag15
-- Is_Volatile Flag16
-- Is_Internal Flag17
-- Has_Delayed_Freeze Flag18
-- Is_Abstract Flag19
-- Is_Concurrent_Record_Type Flag20
-- Has_Master_Entity Flag21
-- Needs_No_Actuals Flag22
-- Has_Storage_Size_Clause Flag23
-- Is_Imported Flag24
-- Is_Limited_Record Flag25
-- Has_Completion Flag26
-- Has_Pragma_Controlled Flag27
-- Is_Statically_Allocated Flag28
-- Has_Size_Clause Flag29
-- Has_Task Flag30
-- Suppress_Access_Checks Flag31
-- Suppress_Accessibility_Checks Flag32
-- Suppress_Discriminant_Checks Flag33
-- Suppress_Division_Checks Flag34
-- Suppress_Elaboration_Checks Flag35
-- Suppress_Index_Checks Flag36
-- Suppress_Length_Checks Flag37
-- Suppress_Overflow_Checks Flag38
-- Suppress_Range_Checks Flag39
-- Suppress_Storage_Checks Flag40
-- Suppress_Tag_Checks Flag41
-- Is_Controlled Flag42
-- Has_Controlled_Component Flag43
-- Is_Pure Flag44
-- In_Private_Part Flag45
-- Has_Alignment_Clause Flag46
-- Has_Exit Flag47
-- In_Package_Body Flag48
-- Reachable Flag49
-- Delay_Subprogram_Descriptors Flag50
-- Is_Packed Flag51
-- Is_Entry_Formal Flag52
-- Is_Private_Descendant Flag53
-- Return_Present Flag54
-- Is_Tagged_Type Flag55
-- Has_Homonym Flag56
-- Is_Hidden Flag57
-- Non_Binary_Modulus Flag58
-- Is_Preelaborated Flag59
-- Is_Shared_Passive Flag60
-- Is_Remote_Types Flag61
-- Is_Remote_Call_Interface Flag62
-- Is_Character_Type Flag63
-- Is_Intrinsic_Subprogram Flag64
-- Has_Record_Rep_Clause Flag65
-- Has_Enumeration_Rep_Clause Flag66
-- Has_Small_Clause Flag67
-- Has_Component_Size_Clause Flag68
-- Is_Access_Constant Flag69
-- Is_First_Subtype Flag70
-- Has_Completion_In_Body Flag71
-- Has_Unknown_Discriminants Flag72
-- Is_Child_Unit Flag73
-- Is_CPP_Class Flag74
-- Has_Non_Standard_Rep Flag75
-- Is_Constructor Flag76
-- Is_Destructor Flag77
-- Is_Tag Flag78
-- Has_All_Calls_Remote Flag79
-- Is_Constr_Subt_For_U_Nominal Flag80
-- Is_Asynchronous Flag81
-- Has_Gigi_Rep_Item Flag82
-- Has_Machine_Radix_Clause Flag83
-- Machine_Radix_10 Flag84
-- Is_Atomic Flag85
-- Has_Atomic_Components Flag86
-- Has_Volatile_Components Flag87
-- Discard_Names Flag88
-- Is_Interrupt_Handler Flag89
-- Returns_By_Ref Flag90
-- Is_Itype Flag91
-- Size_Known_At_Compile_Time Flag92
-- Has_Subprogram_Descriptor Flag93
-- Is_Generic_Actual_Type Flag94
-- Uses_Sec_Stack Flag95
-- Warnings_Off Flag96
-- Is_Controlling_Formal Flag97
-- Has_Controlling_Result Flag98
-- Is_Exported Flag99
-- Has_Specified_Layout Flag100
-- Has_Nested_Block_With_Handler Flag101
-- Is_Called Flag102
-- Is_Completely_Hidden Flag103
-- Address_Taken Flag104
-- Suppress_Init_Proc Flag105
-- Is_Limited_Composite Flag106
-- Is_Private_Composite Flag107
-- Default_Expressions_Processed Flag108
-- Is_Non_Static_Subtype Flag109
-- Has_External_Tag_Rep_Clause Flag110
-- Is_Formal_Subprogram Flag111
-- Is_Renaming_Of_Object Flag112
-- No_Return Flag113
-- Delay_Cleanups Flag114
-- Not_Source_Assigned Flag115
-- Is_Visible_Child_Unit Flag116
-- Is_Unchecked_Union Flag117
-- Is_For_Access_Subtype Flag118
-- Has_Convention_Pragma Flag119
-- Has_Primitive_Operations Flag120
-- Has_Pragma_Pack Flag121
-- Is_Bit_Packed_Array Flag122
-- Has_Unchecked_Union Flag123
-- Is_Eliminated Flag124
-- C_Pass_By_Copy Flag125
-- Is_Instantiated Flag126
-- Is_Valued_Procedure Flag127
-- (used for Component_Alignment) Flag128
-- (used for Component_Alignment) Flag129
-- Is_Generic_Instance Flag130
-- No_Pool_Assigned Flag131
-- Is_AST_Entry Flag132
-- Is_VMS_Exception Flag133
-- Is_Optional_Parameter Flag134
-- Has_Aliased_Components Flag135
-- Is_Machine_Code_Subprogram Flag137
-- Is_Packed_Array_Type Flag138
-- Has_Biased_Representation Flag139
-- Has_Complex_Representation Flag140
-- Is_Constr_Subt_For_UN_Aliased Flag141
-- Has_Missing_Return Flag142
-- Has_Recursive_Call Flag143
-- Is_Unsigned_Type Flag144
-- Strict_Alignment Flag145
-- Elaborate_All_Desirable Flag146
-- Needs_Debug_Info Flag147
-- Suppress_Elaboration_Warnings Flag148
-- Is_Compilation_Unit Flag149
-- Has_Pragma_Elaborate_Body Flag150
-- Vax_Float Flag151
-- Entry_Accepted Flag152
-- Is_Psected Flag153
-- Has_Per_Object_Constraint Flag154
-- Has_Private_Declaration Flag155
-- Referenced Flag156
-- Has_Pragma_Inline Flag157
-- Finalize_Storage_Only Flag158
-- From_With_Type Flag159
-- Is_Package_Body_Entity Flag160
-- Has_Qualified_Name Flag161
-- Nonzero_Is_True Flag162
-- Is_True_Constant Flag163
-- Reverse_Bit_Order Flag164
-- Suppress_Style_Checks Flag165
-- Debug_Info_Off Flag166
-- Sec_Stack_Needed_For_Return Flag167
-- Materialize_Entity Flag168
-- Function_Returns_With_DSP Flag169
-- Is_Known_Valid Flag170
-- Is_Hidden_Open_Scope Flag171
-- Has_Object_Size_Clause Flag172
-- Has_Fully_Qualified_Name Flag173
-- Elaboration_Entity_Required Flag174
-- Has_Forward_Instantiation Flag175
-- Is_Discrim_SO_Function Flag176
-- Size_Depends_On_Discriminant Flag177
-- Is_Null_Init_Proc Flag178
-- Has_Pragma_Pure_Function Flag179
-- (unused) Flag180
-- (unused) Flag181
-- (unused) Flag182
-- (unused) Flag183
--------------------------------
-- Attribute Access Functions --
--------------------------------
function Accept_Address (Id : E) return L is
begin
return Elist21 (Id);
end Accept_Address;
function Access_Disp_Table (Id : E) return E is
begin
pragma Assert (Is_Tagged_Type (Id));
return Node16 (Base_Type (Underlying_Type (Base_Type (Id))));
end Access_Disp_Table;
function Actual_Subtype (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Constant
or else Ekind (Id) = E_Variable
or else Ekind (Id) = E_Generic_In_Out_Parameter
or else Ekind (Id) in E_In_Parameter .. E_In_Out_Parameter);
return Node17 (Id);
end Actual_Subtype;
function Address_Taken (Id : E) return B is
begin
return Flag104 (Id);
end Address_Taken;
function Alias (Id : E) return E is
begin
pragma Assert
(Is_Overloadable (Id) or else Ekind (Id) = E_Subprogram_Type);
return Node18 (Id);
end Alias;
function Alignment (Id : E) return U is
begin
return Uint14 (Id);
end Alignment;
function Associated_Final_Chain (Id : E) return E is
begin
pragma Assert (Is_Access_Type (Id));
return Node23 (Id);
end Associated_Final_Chain;
function Associated_Formal_Package (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Package);
return Node12 (Id);
end Associated_Formal_Package;
function Associated_Node_For_Itype (Id : E) return N is
begin
return Node8 (Id);
end Associated_Node_For_Itype;
function Associated_Storage_Pool (Id : E) return E is
begin
pragma Assert (Is_Access_Type (Id));
return Node22 (Id);
end Associated_Storage_Pool;
function Barrier_Function (Id : E) return N is
begin
pragma Assert (Is_Entry (Id));
return Node12 (Id);
end Barrier_Function;
function Block_Node (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Block);
return Node11 (Id);
end Block_Node;
function Body_Entity (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Package or else Ekind (Id) = E_Generic_Package);
return Node19 (Id);
end Body_Entity;
function C_Pass_By_Copy (Id : E) return B is
begin
pragma Assert (Is_Record_Type (Id));
return Flag125 (Implementation_Base_Type (Id));
end C_Pass_By_Copy;
function Class_Wide_Type (Id : E) return E is
begin
pragma Assert (Is_Type (Id));
return Node9 (Id);
end Class_Wide_Type;
function Cloned_Subtype (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Record_Subtype
or else Ekind (Id) = E_Class_Wide_Subtype);
return Node16 (Id);
end Cloned_Subtype;
function Component_Bit_Offset (Id : E) return U is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
return Uint11 (Id);
end Component_Bit_Offset;
function Component_Clause (Id : E) return N is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
return Node13 (Id);
end Component_Clause;
function Component_Size (Id : E) return U is
begin
pragma Assert (Is_Array_Type (Id));
return Uint22 (Implementation_Base_Type (Id));
end Component_Size;
function Component_Type (Id : E) return E is
begin
return Node20 (Implementation_Base_Type (Id));
end Component_Type;
function Corresponding_Concurrent_Type (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Record_Type);
return Node18 (Id);
end Corresponding_Concurrent_Type;
function Corresponding_Discriminant (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
return Node19 (Id);
end Corresponding_Discriminant;
function Corresponding_Equality (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Function
and then not Comes_From_Source (Id)
and then Chars (Id) = Name_Op_Ne);
return Node13 (Id);
end Corresponding_Equality;
function Corresponding_Record_Type (Id : E) return E is
begin
pragma Assert (Is_Concurrent_Type (Id));
return Node18 (Id);
end Corresponding_Record_Type;
function Corresponding_Remote_Type (Id : E) return E is
begin
return Node22 (Id);
end Corresponding_Remote_Type;
function CR_Discriminant (Id : E) return E is
begin
return Node23 (Id);
end CR_Discriminant;
function Debug_Info_Off (Id : E) return B is
begin
return Flag166 (Id);
end Debug_Info_Off;
function Debug_Renaming_Link (Id : E) return E is
begin
return Node13 (Id);
end Debug_Renaming_Link;
function Default_Expr_Function (Id : E) return E is
begin
pragma Assert (Is_Formal (Id));
return Node21 (Id);
end Default_Expr_Function;
function Default_Expressions_Processed (Id : E) return B is
begin
return Flag108 (Id);
end Default_Expressions_Processed;
function Default_Value (Id : E) return N is
begin
pragma Assert (Is_Formal (Id));
return Node20 (Id);
end Default_Value;
function Delay_Cleanups (Id : E) return B is
begin
return Flag114 (Id);
end Delay_Cleanups;
function Delay_Subprogram_Descriptors (Id : E) return B is
begin
return Flag50 (Id);
end Delay_Subprogram_Descriptors;
function Delta_Value (Id : E) return R is
begin
pragma Assert (Is_Fixed_Point_Type (Id));
return Ureal18 (Id);
end Delta_Value;
function Dependent_Instances (Id : E) return L is
begin
pragma Assert (Is_Generic_Instance (Id));
return Elist8 (Id);
end Dependent_Instances;
function Depends_On_Private (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag14 (Id);
end Depends_On_Private;
function Digits_Value (Id : E) return U is
begin
pragma Assert
(Is_Floating_Point_Type (Id)
or else Is_Decimal_Fixed_Point_Type (Id));
return Uint17 (Id);
end Digits_Value;
function Directly_Designated_Type (Id : E) return E is
begin
return Node20 (Id);
end Directly_Designated_Type;
function Discard_Names (Id : E) return B is
begin
return Flag88 (Id);
end Discard_Names;
function Discriminal (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
return Node17 (Id);
end Discriminal;
function Discriminal_Link (Id : E) return N is
begin
return Node10 (Id);
end Discriminal_Link;
function Discriminant_Checking_Func (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Component);
return Node20 (Id);
end Discriminant_Checking_Func;
function Discriminant_Constraint (Id : E) return L is
begin
pragma Assert (Is_Composite_Type (Id) and then Has_Discriminants (Id));
return Elist21 (Id);
end Discriminant_Constraint;
function Discriminant_Default_Value (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
return Node20 (Id);
end Discriminant_Default_Value;
function Discriminant_Number (Id : E) return U is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
return Uint15 (Id);
end Discriminant_Number;
function DT_Entry_Count (Id : E) return U is
begin
pragma Assert (Ekind (Id) = E_Component and then Is_Tag (Id));
return Uint15 (Id);
end DT_Entry_Count;
function DT_Position (Id : E) return U is
begin
pragma Assert
((Ekind (Id) = E_Function
or else Ekind (Id) = E_Procedure)
and then Present (DTC_Entity (Id)));
return Uint15 (Id);
end DT_Position;
function DTC_Entity (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Procedure);
return Node16 (Id);
end DTC_Entity;
function Elaborate_All_Desirable (Id : E) return B is
begin
return Flag146 (Id);
end Elaborate_All_Desirable;
function Elaboration_Entity (Id : E) return E is
begin
pragma Assert
(Is_Subprogram (Id)
or else
Ekind (Id) = E_Package
or else
Is_Generic_Unit (Id));
return Node13 (Id);
end Elaboration_Entity;
function Elaboration_Entity_Required (Id : E) return B is
begin
pragma Assert
(Is_Subprogram (Id)
or else
Ekind (Id) = E_Package
or else
Is_Generic_Unit (Id));
return Flag174 (Id);
end Elaboration_Entity_Required;
function Enclosing_Scope (Id : E) return E is
begin
return Node18 (Id);
end Enclosing_Scope;
function Entry_Accepted (Id : E) return B is
begin
pragma Assert (Is_Entry (Id));
return Flag152 (Id);
end Entry_Accepted;
function Entry_Bodies_Array (Id : E) return E is
begin
return Node15 (Id);
end Entry_Bodies_Array;
function Entry_Cancel_Parameter (Id : E) return E is
begin
return Node23 (Id);
end Entry_Cancel_Parameter;
function Entry_Component (Id : E) return E is
begin
return Node11 (Id);
end Entry_Component;
function Entry_Formal (Id : E) return E is
begin
return Node16 (Id);
end Entry_Formal;
function Entry_Index_Constant (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Entry_Index_Parameter);
return Node18 (Id);
end Entry_Index_Constant;
function Entry_Parameters_Type (Id : E) return E is
begin
return Node15 (Id);
end Entry_Parameters_Type;
function Enum_Pos_To_Rep (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Type);
return Node23 (Id);
end Enum_Pos_To_Rep;
function Enumeration_Pos (Id : E) return Uint is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
return Uint11 (Id);
end Enumeration_Pos;
function Enumeration_Rep (Id : E) return U is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
return Uint12 (Id);
end Enumeration_Rep;
function Enumeration_Rep_Expr (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
return Node22 (Id);
end Enumeration_Rep_Expr;
function Equivalent_Type (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Class_Wide_Subtype or else
Ekind (Id) = E_Access_Protected_Subprogram_Type or else
Ekind (Id) = E_Access_Subprogram_Type or else
Ekind (Id) = E_Exception_Type);
return Node18 (Id);
end Equivalent_Type;
function Esize (Id : E) return Uint is
begin
return Uint12 (Id);
end Esize;
function Exception_Code (Id : E) return Uint is
begin
pragma Assert (Ekind (Id) = E_Exception);
return Uint22 (Id);
end Exception_Code;
function Extra_Accessibility (Id : E) return E is
begin
pragma Assert (Is_Formal (Id) or else Ekind (Id) = E_Variable);
return Node13 (Id);
end Extra_Accessibility;
function Extra_Constrained (Id : E) return E is
begin
pragma Assert (Is_Formal (Id) or else Ekind (Id) = E_Variable);
return Node23 (Id);
end Extra_Constrained;
function Extra_Formal (Id : E) return E is
begin
return Node15 (Id);
end Extra_Formal;
function Finalization_Chain_Entity (Id : E) return E is
begin
return Node19 (Id);
end Finalization_Chain_Entity;
function Finalize_Storage_Only (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag158 (Base_Type (Id));
end Finalize_Storage_Only;
function First_Entity (Id : E) return E is
begin
return Node17 (Id);
end First_Entity;
function First_Index (Id : E) return N is
begin
return Node17 (Id);
end First_Index;
function First_Literal (Id : E) return E is
begin
return Node17 (Id);
end First_Literal;
function First_Optional_Parameter (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Procedure);
return Node14 (Id);
end First_Optional_Parameter;
function First_Private_Entity (Id : E) return E is
begin
return Node16 (Id);
end First_Private_Entity;
function First_Rep_Item (Id : E) return E is
begin
return Node6 (Id);
end First_Rep_Item;
function Freeze_Node (Id : E) return N is
begin
return Node7 (Id);
end Freeze_Node;
function From_With_Type (Id : E) return B is
begin
return Flag159 (Id);
end From_With_Type;
function Full_View (Id : E) return E is
begin
pragma Assert (Is_Type (Id) or else Ekind (Id) = E_Constant);
return Node11 (Id);
end Full_View;
function Function_Returns_With_DSP (Id : E) return B is
begin
pragma Assert
(Is_Subprogram (Id) or else Ekind (Id) = E_Subprogram_Type);
return Flag169 (Id);
end Function_Returns_With_DSP;
function Generic_Renamings (Id : E) return L is
begin
return Elist23 (Id);
end Generic_Renamings;
function Girder_Constraint (Id : E) return L is
begin
pragma Assert
(Is_Composite_Type (Id) and then not Is_Array_Type (Id));
return Elist23 (Id);
end Girder_Constraint;
function Handler_Records (Id : E) return S is
begin
return List10 (Id);
end Handler_Records;
function Has_Aliased_Components (Id : E) return B is
begin
return Flag135 (Implementation_Base_Type (Id));
end Has_Aliased_Components;
function Has_Alignment_Clause (Id : E) return B is
begin
return Flag46 (Id);
end Has_Alignment_Clause;
function Has_All_Calls_Remote (Id : E) return B is
begin
return Flag79 (Id);
end Has_All_Calls_Remote;
function Has_Atomic_Components (Id : E) return B is
begin
return Flag86 (Implementation_Base_Type (Id));
end Has_Atomic_Components;
function Has_Biased_Representation (Id : E) return B is
begin
return Flag139 (Id);
end Has_Biased_Representation;
function Has_Completion (Id : E) return B is
begin
return Flag26 (Id);
end Has_Completion;
function Has_Completion_In_Body (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag71 (Id);
end Has_Completion_In_Body;
function Has_Complex_Representation (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag140 (Implementation_Base_Type (Id));
end Has_Complex_Representation;
function Has_Component_Size_Clause (Id : E) return B is
begin
pragma Assert (Is_Array_Type (Id));
return Flag68 (Implementation_Base_Type (Id));
end Has_Component_Size_Clause;
function Has_Controlled_Component (Id : E) return B is
begin
return Flag43 (Base_Type (Id));
end Has_Controlled_Component;
function Has_Controlling_Result (Id : E) return B is
begin
return Flag98 (Id);
end Has_Controlling_Result;
function Has_Convention_Pragma (Id : E) return B is
begin
return Flag119 (Id);
end Has_Convention_Pragma;
function Has_Delayed_Freeze (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag18 (Id);
end Has_Delayed_Freeze;
function Has_Discriminants (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag5 (Id);
end Has_Discriminants;
function Has_Enumeration_Rep_Clause (Id : E) return B is
begin
pragma Assert (Is_Enumeration_Type (Id));
return Flag66 (Id);
end Has_Enumeration_Rep_Clause;
function Has_Exit (Id : E) return B is
begin
return Flag47 (Id);
end Has_Exit;
function Has_External_Tag_Rep_Clause (Id : E) return B is
begin
pragma Assert (Is_Tagged_Type (Id));
return Flag110 (Id);
end Has_External_Tag_Rep_Clause;
function Has_Forward_Instantiation (Id : E) return B is
begin
return Flag175 (Id);
end Has_Forward_Instantiation;
function Has_Fully_Qualified_Name (Id : E) return B is
begin
return Flag173 (Id);
end Has_Fully_Qualified_Name;
function Has_Gigi_Rep_Item (Id : E) return B is
begin
return Flag82 (Id);
end Has_Gigi_Rep_Item;
function Has_Homonym (Id : E) return B is
begin
return Flag56 (Id);
end Has_Homonym;
function Has_Machine_Radix_Clause (Id : E) return B is
begin
pragma Assert (Is_Decimal_Fixed_Point_Type (Id));
return Flag83 (Id);
end Has_Machine_Radix_Clause;
function Has_Master_Entity (Id : E) return B is
begin
return Flag21 (Id);
end Has_Master_Entity;
function Has_Missing_Return (Id : E) return B is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Generic_Function);
return Flag142 (Id);
end Has_Missing_Return;
function Has_Nested_Block_With_Handler (Id : E) return B is
begin
return Flag101 (Id);
end Has_Nested_Block_With_Handler;
function Has_Non_Standard_Rep (Id : E) return B is
begin
return Flag75 (Implementation_Base_Type (Id));
end Has_Non_Standard_Rep;
function Has_Object_Size_Clause (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag172 (Id);
end Has_Object_Size_Clause;
function Has_Per_Object_Constraint (Id : E) return B is
begin
return Flag154 (Id);
end Has_Per_Object_Constraint;
function Has_Pragma_Controlled (Id : E) return B is
begin
pragma Assert (Is_Access_Type (Id));
return Flag27 (Implementation_Base_Type (Id));
end Has_Pragma_Controlled;
function Has_Pragma_Elaborate_Body (Id : E) return B is
begin
return Flag150 (Id);
end Has_Pragma_Elaborate_Body;
function Has_Pragma_Inline (Id : E) return B is
begin
return Flag157 (Id);
end Has_Pragma_Inline;
function Has_Pragma_Pack (Id : E) return B is
begin
pragma Assert (Is_Record_Type (Id) or else Is_Array_Type (Id));
return Flag121 (Implementation_Base_Type (Id));
end Has_Pragma_Pack;
function Has_Pragma_Pure_Function (Id : E) return B is
begin
pragma Assert (Is_Subprogram (Id));
return Flag179 (Id);
end Has_Pragma_Pure_Function;
function Has_Primitive_Operations (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag120 (Base_Type (Id));
end Has_Primitive_Operations;
function Has_Private_Declaration (Id : E) return B is
begin
return Flag155 (Id);
end Has_Private_Declaration;
function Has_Qualified_Name (Id : E) return B is
begin
return Flag161 (Id);
end Has_Qualified_Name;
function Has_Record_Rep_Clause (Id : E) return B is
begin
pragma Assert (Is_Record_Type (Id));
return Flag65 (Id);
end Has_Record_Rep_Clause;
function Has_Recursive_Call (Id : E) return B is
begin
pragma Assert (Is_Subprogram (Id));
return Flag143 (Id);
end Has_Recursive_Call;
function Has_Size_Clause (Id : E) return B is
begin
return Flag29 (Id);
end Has_Size_Clause;
function Has_Small_Clause (Id : E) return B is
begin
return Flag67 (Id);
end Has_Small_Clause;
function Has_Specified_Layout (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag100 (Id);
end Has_Specified_Layout;
function Has_Storage_Size_Clause (Id : E) return B is
begin
pragma Assert (Is_Access_Type (Id) or else Is_Task_Type (Id));
return Flag23 (Implementation_Base_Type (Id));
end Has_Storage_Size_Clause;
function Has_Subprogram_Descriptor (Id : E) return B is
begin
return Flag93 (Id);
end Has_Subprogram_Descriptor;
function Has_Task (Id : E) return B is
begin
return Flag30 (Base_Type (Id));
end Has_Task;
function Has_Unchecked_Union (Id : E) return B is
begin
return Flag123 (Base_Type (Id));
end Has_Unchecked_Union;
function Has_Unknown_Discriminants (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag72 (Id);
end Has_Unknown_Discriminants;
function Has_Volatile_Components (Id : E) return B is
begin
return Flag87 (Implementation_Base_Type (Id));
end Has_Volatile_Components;
function Hiding_Loop_Variable (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Variable);
return Node8 (Id);
end Hiding_Loop_Variable;
function Homonym (Id : E) return E is
begin
return Node4 (Id);
end Homonym;
function In_Package_Body (Id : E) return B is
begin
return Flag48 (Id);
end In_Package_Body;
function In_Private_Part (Id : E) return B is
begin
return Flag45 (Id);
end In_Private_Part;
function In_Use (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag8 (Id);
end In_Use;
function Inner_Instances (Id : E) return L is
begin
return Elist23 (Id);
end Inner_Instances;
function Interface_Name (Id : E) return N is
begin
return Node21 (Id);
end Interface_Name;
function Is_Abstract (Id : E) return B is
begin
return Flag19 (Id);
end Is_Abstract;
function Is_Access_Constant (Id : E) return B is
begin
pragma Assert (Is_Access_Type (Id));
return Flag69 (Id);
end Is_Access_Constant;
function Is_Aliased (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag15 (Id);
end Is_Aliased;
function Is_AST_Entry (Id : E) return B is
begin
pragma Assert (Is_Entry (Id));
return Flag132 (Id);
end Is_AST_Entry;
function Is_Asynchronous (Id : E) return B is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Is_Type (Id));
return Flag81 (Id);
end Is_Asynchronous;
function Is_Atomic (Id : E) return B is
begin
return Flag85 (Id);
end Is_Atomic;
function Is_Bit_Packed_Array (Id : E) return B is
begin
return Flag122 (Implementation_Base_Type (Id));
end Is_Bit_Packed_Array;
function Is_Called (Id : E) return B is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Ekind (Id) = E_Function);
return Flag102 (Id);
end Is_Called;
function Is_Character_Type (Id : E) return B is
begin
return Flag63 (Id);
end Is_Character_Type;
function Is_Child_Unit (Id : E) return B is
begin
return Flag73 (Id);
end Is_Child_Unit;
function Is_Compilation_Unit (Id : E) return B is
begin
return Flag149 (Id);
end Is_Compilation_Unit;
function Is_Completely_Hidden (Id : E) return B is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
return Flag103 (Id);
end Is_Completely_Hidden;
function Is_Constr_Subt_For_U_Nominal (Id : E) return B is
begin
return Flag80 (Id);
end Is_Constr_Subt_For_U_Nominal;
function Is_Constr_Subt_For_UN_Aliased (Id : E) return B is
begin
return Flag141 (Id);
end Is_Constr_Subt_For_UN_Aliased;
function Is_Constrained (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag12 (Id);
end Is_Constrained;
function Is_Constructor (Id : E) return B is
begin
return Flag76 (Id);
end Is_Constructor;
function Is_Controlled (Id : E) return B is
begin
return Flag42 (Base_Type (Id));
end Is_Controlled;
function Is_Controlling_Formal (Id : E) return B is
begin
pragma Assert (Is_Formal (Id));
return Flag97 (Id);
end Is_Controlling_Formal;
function Is_CPP_Class (Id : E) return B is
begin
return Flag74 (Id);
end Is_CPP_Class;
function Is_Destructor (Id : E) return B is
begin
return Flag77 (Id);
end Is_Destructor;
function Is_Discrim_SO_Function (Id : E) return B is
begin
return Flag176 (Id);
end Is_Discrim_SO_Function;
function Is_Dispatching_Operation (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag6 (Id);
end Is_Dispatching_Operation;
function Is_Eliminated (Id : E) return B is
begin
return Flag124 (Id);
end Is_Eliminated;
function Is_Entry_Formal (Id : E) return B is
begin
return Flag52 (Id);
end Is_Entry_Formal;
function Is_Exported (Id : E) return B is
begin
return Flag99 (Id);
end Is_Exported;
function Is_First_Subtype (Id : E) return B is
begin
return Flag70 (Id);
end Is_First_Subtype;
function Is_For_Access_Subtype (Id : E) return B is
begin
pragma Assert
(Ekind (Id) = E_Record_Subtype
or else
Ekind (Id) = E_Private_Subtype);
return Flag118 (Id);
end Is_For_Access_Subtype;
function Is_Formal_Subprogram (Id : E) return B is
begin
return Flag111 (Id);
end Is_Formal_Subprogram;
function Is_Frozen (Id : E) return B is
begin
return Flag4 (Id);
end Is_Frozen;
function Is_Generic_Actual_Type (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag94 (Id);
end Is_Generic_Actual_Type;
function Is_Generic_Instance (Id : E) return B is
begin
return Flag130 (Id);
end Is_Generic_Instance;
function Is_Generic_Type (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag13 (Id);
end Is_Generic_Type;
function Is_Hidden (Id : E) return B is
begin
return Flag57 (Id);
end Is_Hidden;
function Is_Hidden_Open_Scope (Id : E) return B is
begin
return Flag171 (Id);
end Is_Hidden_Open_Scope;
function Is_Immediately_Visible (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag7 (Id);
end Is_Immediately_Visible;
function Is_Imported (Id : E) return B is
begin
return Flag24 (Id);
end Is_Imported;
function Is_Inlined (Id : E) return B is
begin
return Flag11 (Id);
end Is_Inlined;
function Is_Instantiated (Id : E) return B is
begin
return Flag126 (Id);
end Is_Instantiated;
function Is_Internal (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag17 (Id);
end Is_Internal;
function Is_Interrupt_Handler (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag89 (Id);
end Is_Interrupt_Handler;
function Is_Intrinsic_Subprogram (Id : E) return B is
begin
return Flag64 (Id);
end Is_Intrinsic_Subprogram;
function Is_Itype (Id : E) return B is
begin
return Flag91 (Id);
end Is_Itype;
function Is_Known_Valid (Id : E) return B is
begin
return Flag170 (Id);
end Is_Known_Valid;
function Is_Limited_Composite (Id : E) return B is
begin
return Flag106 (Id);
end Is_Limited_Composite;
function Is_Limited_Record (Id : E) return B is
begin
return Flag25 (Id);
end Is_Limited_Record;
function Is_Machine_Code_Subprogram (Id : E) return B is
begin
pragma Assert (Is_Subprogram (Id));
return Flag137 (Id);
end Is_Machine_Code_Subprogram;
function Is_Non_Static_Subtype (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag109 (Id);
end Is_Non_Static_Subtype;
function Is_Null_Init_Proc (Id : E) return B is
begin
pragma Assert (Ekind (Id) = E_Procedure);
return Flag178 (Id);
end Is_Null_Init_Proc;
function Is_Optional_Parameter (Id : E) return B is
begin
pragma Assert (Is_Formal (Id));
return Flag134 (Id);
end Is_Optional_Parameter;
function Is_Package_Body_Entity (Id : E) return B is
begin
return Flag160 (Id);
end Is_Package_Body_Entity;
function Is_Packed (Id : E) return B is
begin
return Flag51 (Implementation_Base_Type (Id));
end Is_Packed;
function Is_Packed_Array_Type (Id : E) return B is
begin
return Flag138 (Id);
end Is_Packed_Array_Type;
function Is_Potentially_Use_Visible (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag9 (Id);
end Is_Potentially_Use_Visible;
function Is_Preelaborated (Id : E) return B is
begin
return Flag59 (Id);
end Is_Preelaborated;
function Is_Private_Composite (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag107 (Id);
end Is_Private_Composite;
function Is_Private_Descendant (Id : E) return B is
begin
return Flag53 (Id);
end Is_Private_Descendant;
function Is_Psected (Id : E) return B is
begin
return Flag153 (Id);
end Is_Psected;
function Is_Public (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag10 (Id);
end Is_Public;
function Is_Pure (Id : E) return B is
begin
return Flag44 (Id);
end Is_Pure;
function Is_Remote_Call_Interface (Id : E) return B is
begin
return Flag62 (Id);
end Is_Remote_Call_Interface;
function Is_Remote_Types (Id : E) return B is
begin
return Flag61 (Id);
end Is_Remote_Types;
function Is_Renaming_Of_Object (Id : E) return B is
begin
return Flag112 (Id);
end Is_Renaming_Of_Object;
function Is_Shared_Passive (Id : E) return B is
begin
return Flag60 (Id);
end Is_Shared_Passive;
function Is_Statically_Allocated (Id : E) return B is
begin
return Flag28 (Id);
end Is_Statically_Allocated;
function Is_Tag (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag78 (Id);
end Is_Tag;
function Is_Tagged_Type (Id : E) return B is
begin
return Flag55 (Id);
end Is_Tagged_Type;
function Is_True_Constant (Id : E) return B is
begin
return Flag163 (Id);
end Is_True_Constant;
function Is_Unchecked_Union (Id : E) return B is
begin
return Flag117 (Id);
end Is_Unchecked_Union;
function Is_Unsigned_Type (Id : E) return B is
begin
pragma Assert (Is_Type (Id));
return Flag144 (Id);
end Is_Unsigned_Type;
function Is_Valued_Procedure (Id : E) return B is
begin
pragma Assert (Ekind (Id) = E_Procedure);
return Flag127 (Id);
end Is_Valued_Procedure;
function Is_Visible_Child_Unit (Id : E) return B is
begin
pragma Assert (Is_Child_Unit (Id));
return Flag116 (Id);
end Is_Visible_Child_Unit;
function Is_VMS_Exception (Id : E) return B is
begin
return Flag133 (Id);
end Is_VMS_Exception;
function Is_Volatile (Id : E) return B is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Flag16 (Id);
end Is_Volatile;
function Last_Entity (Id : E) return E is
begin
return Node20 (Id);
end Last_Entity;
function Lit_Indexes (Id : E) return E is
begin
pragma Assert (Is_Enumeration_Type (Id));
return Node15 (Id);
end Lit_Indexes;
function Lit_Strings (Id : E) return E is
begin
pragma Assert (Is_Enumeration_Type (Id));
return Node16 (Id);
end Lit_Strings;
function Machine_Radix_10 (Id : E) return B is
begin
pragma Assert (Is_Decimal_Fixed_Point_Type (Id));
return Flag84 (Id);
end Machine_Radix_10;
function Master_Id (Id : E) return E is
begin
return Node17 (Id);
end Master_Id;
function Materialize_Entity (Id : E) return B is
begin
return Flag168 (Id);
end Materialize_Entity;
function Mechanism (Id : E) return M is
begin
pragma Assert (Ekind (Id) = E_Function or else Is_Formal (Id));
return UI_To_Int (Uint8 (Id));
end Mechanism;
function Modulus (Id : E) return Uint is
begin
pragma Assert (Is_Modular_Integer_Type (Id));
return Uint17 (Base_Type (Id));
end Modulus;
function Needs_Debug_Info (Id : E) return B is
begin
return Flag147 (Id);
end Needs_Debug_Info;
function Needs_No_Actuals (Id : E) return B is
begin
pragma Assert
(Is_Overloadable (Id)
or else Ekind (Id) = E_Subprogram_Type
or else Ekind (Id) = E_Entry_Family);
return Flag22 (Id);
end Needs_No_Actuals;
function Next_Inlined_Subprogram (Id : E) return E is
begin
return Node12 (Id);
end Next_Inlined_Subprogram;
function No_Pool_Assigned (Id : E) return B is
begin
pragma Assert (Is_Access_Type (Id));
return Flag131 (Root_Type (Id));
end No_Pool_Assigned;
function No_Return (Id : E) return B is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Ekind (Id) = E_Generic_Procedure);
return Flag113 (Id);
end No_Return;
function Non_Binary_Modulus (Id : E) return B is
begin
pragma Assert (Is_Modular_Integer_Type (Id));
return Flag58 (Base_Type (Id));
end Non_Binary_Modulus;
function Nonzero_Is_True (Id : E) return B is
begin
pragma Assert (Root_Type (Id) = Standard_Boolean);
return Flag162 (Base_Type (Id));
end Nonzero_Is_True;
function Normalized_First_Bit (Id : E) return U is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
return Uint8 (Id);
end Normalized_First_Bit;
function Normalized_Position (Id : E) return U is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
return Uint9 (Id);
end Normalized_Position;
function Normalized_Position_Max (Id : E) return U is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
return Uint10 (Id);
end Normalized_Position_Max;
function Not_Source_Assigned (Id : E) return B is
begin
return Flag115 (Id);
end Not_Source_Assigned;
function Object_Ref (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Protected_Body);
return Node17 (Id);
end Object_Ref;
function Original_Record_Component (Id : E) return E is
begin
return Node22 (Id);
end Original_Record_Component;
function Packed_Array_Type (Id : E) return E is
begin
pragma Assert (Is_Array_Type (Id));
return Node23 (Id);
end Packed_Array_Type;
function Parent_Subtype (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Record_Type);
return Node19 (Id);
end Parent_Subtype;
function Primitive_Operations (Id : E) return L is
begin
pragma Assert (Is_Tagged_Type (Id));
return Elist15 (Id);
end Primitive_Operations;
function Prival (Id : E) return E is
begin
pragma Assert (Is_Protected_Private (Id));
return Node17 (Id);
end Prival;
function Privals_Chain (Id : E) return L is
begin
pragma Assert (Is_Overloadable (Id)
or else Ekind (Id) = E_Entry_Family);
return Elist23 (Id);
end Privals_Chain;
function Private_Dependents (Id : E) return L is
begin
pragma Assert (Is_Incomplete_Or_Private_Type (Id));
return Elist18 (Id);
end Private_Dependents;
function Private_View (Id : E) return N is
begin
pragma Assert (Is_Private_Type (Id));
return Node22 (Id);
end Private_View;
function Protected_Body_Subprogram (Id : E) return E is
begin
pragma Assert (Is_Subprogram (Id) or else Is_Entry (Id));
return Node11 (Id);
end Protected_Body_Subprogram;
function Protected_Formal (Id : E) return E is
begin
pragma Assert (Is_Formal (Id));
return Node22 (Id);
end Protected_Formal;
function Protected_Operation (Id : E) return N is
begin
pragma Assert (Is_Protected_Private (Id));
return Node23 (Id);
end Protected_Operation;
function Reachable (Id : E) return B is
begin
return Flag49 (Id);
end Reachable;
function Referenced (Id : E) return B is
begin
return Flag156 (Id);
end Referenced;
function Referenced_Object (Id : E) return N is
begin
pragma Assert (Is_Type (Id));
return Node10 (Id);
end Referenced_Object;
function Register_Exception_Call (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Exception);
return Node20 (Id);
end Register_Exception_Call;
function Related_Array_Object (Id : E) return E is
begin
pragma Assert (Is_Array_Type (Id));
return Node19 (Id);
end Related_Array_Object;
function Related_Instance (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Package);
return Node15 (Id);
end Related_Instance;
function Renamed_Entity (Id : E) return N is
begin
return Node18 (Id);
end Renamed_Entity;
function Renamed_Object (Id : E) return N is
begin
return Node18 (Id);
end Renamed_Object;
function Renaming_Map (Id : E) return U is
begin
return Uint9 (Id);
end Renaming_Map;
function Return_Present (Id : E) return B is
begin
return Flag54 (Id);
end Return_Present;
function Returns_By_Ref (Id : E) return B is
begin
return Flag90 (Id);
end Returns_By_Ref;
function Reverse_Bit_Order (Id : E) return B is
begin
pragma Assert (Is_Record_Type (Id));
return Flag164 (Base_Type (Id));
end Reverse_Bit_Order;
function RM_Size (Id : E) return U is
begin
pragma Assert (Is_Type (Id));
return Uint13 (Id);
end RM_Size;
function Scalar_Range (Id : E) return N is
begin
return Node20 (Id);
end Scalar_Range;
function Scale_Value (Id : E) return U is
begin
return Uint15 (Id);
end Scale_Value;
function Scope_Depth_Value (Id : E) return U is
begin
return Uint22 (Id);
end Scope_Depth_Value;
function Sec_Stack_Needed_For_Return (Id : E) return B is
begin
return Flag167 (Id);
end Sec_Stack_Needed_For_Return;
function Shadow_Entities (Id : E) return S is
begin
pragma Assert
(Ekind (Id) = E_Package or else Ekind (Id) = E_Generic_Package);
return List14 (Id);
end Shadow_Entities;
function Shared_Var_Assign_Proc (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Variable);
return Node22 (Id);
end Shared_Var_Assign_Proc;
function Shared_Var_Read_Proc (Id : E) return E is
begin
pragma Assert (Ekind (Id) = E_Variable);
return Node15 (Id);
end Shared_Var_Read_Proc;
function Size_Check_Code (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Constant or else Ekind (Id) = E_Variable);
return Node9 (Id);
end Size_Check_Code;
function Size_Depends_On_Discriminant (Id : E) return B is
begin
return Flag177 (Id);
end Size_Depends_On_Discriminant;
function Size_Known_At_Compile_Time (Id : E) return B is
begin
return Flag92 (Id);
end Size_Known_At_Compile_Time;
function Small_Value (Id : E) return R is
begin
pragma Assert (Is_Fixed_Point_Type (Id));
return Ureal21 (Id);
end Small_Value;
function Spec_Entity (Id : E) return E is
begin
pragma Assert
(Ekind (Id) = E_Package_Body or else Is_Formal (Id));
return Node19 (Id);
end Spec_Entity;
function Storage_Size_Variable (Id : E) return E is
begin
pragma Assert (Is_Access_Type (Id) or else Is_Task_Type (Id));
return Node15 (Implementation_Base_Type (Id));
end Storage_Size_Variable;
function Strict_Alignment (Id : E) return B is
begin
return Flag145 (Implementation_Base_Type (Id));
end Strict_Alignment;
function String_Literal_Length (Id : E) return U is
begin
return Uint16 (Id);
end String_Literal_Length;
function String_Literal_Low_Bound (Id : E) return N is
begin
return Node15 (Id);
end String_Literal_Low_Bound;
function Suppress_Access_Checks (Id : E) return B is
begin
return Flag31 (Id);
end Suppress_Access_Checks;
function Suppress_Accessibility_Checks (Id : E) return B is
begin
return Flag32 (Id);
end Suppress_Accessibility_Checks;
function Suppress_Discriminant_Checks (Id : E) return B is
begin
return Flag33 (Id);
end Suppress_Discriminant_Checks;
function Suppress_Division_Checks (Id : E) return B is
begin
return Flag34 (Id);
end Suppress_Division_Checks;
function Suppress_Elaboration_Checks (Id : E) return B is
begin
return Flag35 (Id);
end Suppress_Elaboration_Checks;
function Suppress_Elaboration_Warnings (Id : E) return B is
begin
return Flag148 (Id);
end Suppress_Elaboration_Warnings;
function Suppress_Index_Checks (Id : E) return B is
begin
return Flag36 (Id);
end Suppress_Index_Checks;
function Suppress_Init_Proc (Id : E) return B is
begin
return Flag105 (Base_Type (Id));
end Suppress_Init_Proc;
function Suppress_Length_Checks (Id : E) return B is
begin
return Flag37 (Id);
end Suppress_Length_Checks;
function Suppress_Overflow_Checks (Id : E) return B is
begin
return Flag38 (Id);
end Suppress_Overflow_Checks;
function Suppress_Range_Checks (Id : E) return B is
begin
return Flag39 (Id);
end Suppress_Range_Checks;
function Suppress_Storage_Checks (Id : E) return B is
begin
return Flag40 (Id);
end Suppress_Storage_Checks;
function Suppress_Style_Checks (Id : E) return B is
begin
return Flag165 (Id);
end Suppress_Style_Checks;
function Suppress_Tag_Checks (Id : E) return B is
begin
return Flag41 (Id);
end Suppress_Tag_Checks;
function Underlying_Full_View (Id : E) return E is
begin
pragma Assert (Ekind (Id) in Private_Kind);
return Node19 (Id);
end Underlying_Full_View;
function Unset_Reference (Id : E) return N is
begin
return Node16 (Id);
end Unset_Reference;
function Uses_Sec_Stack (Id : E) return B is
begin
return Flag95 (Id);
end Uses_Sec_Stack;
function Vax_Float (Id : E) return B is
begin
return Flag151 (Base_Type (Id));
end Vax_Float;
function Warnings_Off (Id : E) return B is
begin
return Flag96 (Id);
end Warnings_Off;
------------------------------
-- Classification Functions --
------------------------------
function Is_Access_Type (Id : E) return B is
begin
return Ekind (Id) in Access_Kind;
end Is_Access_Type;
function Is_Array_Type (Id : E) return B is
begin
return Ekind (Id) in Array_Kind;
end Is_Array_Type;
function Is_Class_Wide_Type (Id : E) return B is
begin
return Ekind (Id) in Class_Wide_Kind;
end Is_Class_Wide_Type;
function Is_Composite_Type (Id : E) return B is
begin
return Ekind (Id) in Composite_Kind;
end Is_Composite_Type;
function Is_Concurrent_Body (Id : E) return B is
begin
return Ekind (Id) in
Concurrent_Body_Kind;
end Is_Concurrent_Body;
function Is_Concurrent_Record_Type (Id : E) return B is
begin
return Flag20 (Id);
end Is_Concurrent_Record_Type;
function Is_Concurrent_Type (Id : E) return B is
begin
return Ekind (Id) in Concurrent_Kind;
end Is_Concurrent_Type;
function Is_Decimal_Fixed_Point_Type (Id : E) return B is
begin
return Ekind (Id) in
Decimal_Fixed_Point_Kind;
end Is_Decimal_Fixed_Point_Type;
function Is_Digits_Type (Id : E) return B is
begin
return Ekind (Id) in Digits_Kind;
end Is_Digits_Type;
function Is_Discrete_Or_Fixed_Point_Type (Id : E) return B is
begin
return Ekind (Id) in Discrete_Or_Fixed_Point_Kind;
end Is_Discrete_Or_Fixed_Point_Type;
function Is_Discrete_Type (Id : E) return B is
begin
return Ekind (Id) in Discrete_Kind;
end Is_Discrete_Type;
function Is_Elementary_Type (Id : E) return B is
begin
return Ekind (Id) in Elementary_Kind;
end Is_Elementary_Type;
function Is_Entry (Id : E) return B is
begin
return Ekind (Id) in Entry_Kind;
end Is_Entry;
function Is_Enumeration_Type (Id : E) return B is
begin
return Ekind (Id) in
Enumeration_Kind;
end Is_Enumeration_Type;
function Is_Fixed_Point_Type (Id : E) return B is
begin
return Ekind (Id) in
Fixed_Point_Kind;
end Is_Fixed_Point_Type;
function Is_Floating_Point_Type (Id : E) return B is
begin
return Ekind (Id) in Float_Kind;
end Is_Floating_Point_Type;
function Is_Formal (Id : E) return B is
begin
return Ekind (Id) in Formal_Kind;
end Is_Formal;
function Is_Generic_Unit (Id : E) return B is
begin
return Ekind (Id) in Generic_Unit_Kind;
end Is_Generic_Unit;
function Is_Incomplete_Or_Private_Type (Id : E) return B is
begin
return Ekind (Id) in
Incomplete_Or_Private_Kind;
end Is_Incomplete_Or_Private_Type;
function Is_Integer_Type (Id : E) return B is
begin
return Ekind (Id) in Integer_Kind;
end Is_Integer_Type;
function Is_Modular_Integer_Type (Id : E) return B is
begin
return Ekind (Id) in
Modular_Integer_Kind;
end Is_Modular_Integer_Type;
function Is_Named_Number (Id : E) return B is
begin
return Ekind (Id) in Named_Kind;
end Is_Named_Number;
function Is_Numeric_Type (Id : E) return B is
begin
return Ekind (Id) in Numeric_Kind;
end Is_Numeric_Type;
function Is_Object (Id : E) return B is
begin
return Ekind (Id) in Object_Kind;
end Is_Object;
function Is_Ordinary_Fixed_Point_Type (Id : E) return B is
begin
return Ekind (Id) in
Ordinary_Fixed_Point_Kind;
end Is_Ordinary_Fixed_Point_Type;
function Is_Overloadable (Id : E) return B is
begin
return Ekind (Id) in Overloadable_Kind;
end Is_Overloadable;
function Is_Private_Type (Id : E) return B is
begin
return Ekind (Id) in Private_Kind;
end Is_Private_Type;
function Is_Protected_Type (Id : E) return B is
begin
return Ekind (Id) in Protected_Kind;
end Is_Protected_Type;
function Is_Real_Type (Id : E) return B is
begin
return Ekind (Id) in Real_Kind;
end Is_Real_Type;
function Is_Record_Type (Id : E) return B is
begin
return Ekind (Id) in Record_Kind;
end Is_Record_Type;
function Is_Scalar_Type (Id : E) return B is
begin
return Ekind (Id) in Scalar_Kind;
end Is_Scalar_Type;
function Is_Signed_Integer_Type (Id : E) return B is
begin
return Ekind (Id) in
Signed_Integer_Kind;
end Is_Signed_Integer_Type;
function Is_Subprogram (Id : E) return B is
begin
return Ekind (Id) in Subprogram_Kind;
end Is_Subprogram;
function Is_Task_Type (Id : E) return B is
begin
return Ekind (Id) in Task_Kind;
end Is_Task_Type;
function Is_Type (Id : E) return B is
begin
return Ekind (Id) in Type_Kind;
end Is_Type;
------------------------------
-- Attribute Set Procedures --
------------------------------
procedure Set_Accept_Address (Id : E; V : L) is
begin
Set_Elist21 (Id, V);
end Set_Accept_Address;
procedure Set_Access_Disp_Table (Id : E; V : E) is
begin
pragma Assert (Is_Tagged_Type (Id));
Set_Node16 (Base_Type (Id), V);
end Set_Access_Disp_Table;
procedure Set_Associated_Final_Chain (Id : E; V : E) is
begin
pragma Assert (Is_Access_Type (Id));
Set_Node23 (Id, V);
end Set_Associated_Final_Chain;
procedure Set_Associated_Formal_Package (Id : E; V : E) is
begin
Set_Node12 (Id, V);
end Set_Associated_Formal_Package;
procedure Set_Associated_Node_For_Itype (Id : E; V : E) is
begin
Set_Node8 (Id, V);
end Set_Associated_Node_For_Itype;
procedure Set_Associated_Storage_Pool (Id : E; V : E) is
begin
pragma Assert (Is_Access_Type (Id));
Set_Node22 (Id, V);
end Set_Associated_Storage_Pool;
procedure Set_Actual_Subtype (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Constant
or else Ekind (Id) = E_Variable
or else Ekind (Id) = E_Generic_In_Out_Parameter
or else Ekind (Id) in E_In_Parameter .. E_In_Out_Parameter);
Set_Node17 (Id, V);
end Set_Actual_Subtype;
procedure Set_Address_Taken (Id : E; V : B := True) is
begin
Set_Flag104 (Id, V);
end Set_Address_Taken;
procedure Set_Alias (Id : E; V : E) is
begin
pragma Assert
(Is_Overloadable (Id) or else Ekind (Id) = E_Subprogram_Type);
Set_Node18 (Id, V);
end Set_Alias;
procedure Set_Alignment (Id : E; V : U) is
begin
Set_Uint14 (Id, V);
end Set_Alignment;
procedure Set_Barrier_Function (Id : E; V : N) is
begin
pragma Assert (Is_Entry (Id));
Set_Node12 (Id, V);
end Set_Barrier_Function;
procedure Set_Block_Node (Id : E; V : N) is
begin
pragma Assert (Ekind (Id) = E_Block);
Set_Node11 (Id, V);
end Set_Block_Node;
procedure Set_Body_Entity (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Package or else Ekind (Id) = E_Generic_Package);
Set_Node19 (Id, V);
end Set_Body_Entity;
procedure Set_C_Pass_By_Copy (Id : E; V : B := True) is
begin
pragma Assert (Is_Record_Type (Id) and then Id = Base_Type (Id));
Set_Flag125 (Id, V);
end Set_C_Pass_By_Copy;
procedure Set_Class_Wide_Type (Id : E; V : E) is
begin
pragma Assert (Is_Type (Id));
Set_Node9 (Id, V);
end Set_Class_Wide_Type;
procedure Set_Cloned_Subtype (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Record_Subtype
or else Ekind (Id) = E_Class_Wide_Subtype);
Set_Node16 (Id, V);
end Set_Cloned_Subtype;
procedure Set_Component_Bit_Offset (Id : E; V : U) is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
Set_Uint11 (Id, V);
end Set_Component_Bit_Offset;
procedure Set_Component_Clause (Id : E; V : N) is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
Set_Node13 (Id, V);
end Set_Component_Clause;
procedure Set_Component_Size (Id : E; V : U) is
begin
pragma Assert (Is_Array_Type (Id));
Set_Uint22 (Base_Type (Id), V);
end Set_Component_Size;
procedure Set_Component_Type (Id : E; V : E) is
begin
Set_Node20 (Id, V);
end Set_Component_Type;
procedure Set_Corresponding_Concurrent_Type (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Record_Type and then Is_Concurrent_Type (V));
Set_Node18 (Id, V);
end Set_Corresponding_Concurrent_Type;
procedure Set_Corresponding_Discriminant (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
Set_Node19 (Id, V);
end Set_Corresponding_Discriminant;
procedure Set_Corresponding_Equality (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Function
and then not Comes_From_Source (Id)
and then Chars (Id) = Name_Op_Ne);
Set_Node13 (Id, V);
end Set_Corresponding_Equality;
procedure Set_Corresponding_Record_Type (Id : E; V : E) is
begin
pragma Assert (Is_Concurrent_Type (Id));
Set_Node18 (Id, V);
end Set_Corresponding_Record_Type;
procedure Set_Corresponding_Remote_Type (Id : E; V : E) is
begin
Set_Node22 (Id, V);
end Set_Corresponding_Remote_Type;
procedure Set_CR_Discriminant (Id : E; V : E) is
begin
Set_Node23 (Id, V);
end Set_CR_Discriminant;
procedure Set_Debug_Info_Off (Id : E; V : B := True) is
begin
Set_Flag166 (Id, V);
end Set_Debug_Info_Off;
procedure Set_Debug_Renaming_Link (Id : E; V : E) is
begin
Set_Node13 (Id, V);
end Set_Debug_Renaming_Link;
procedure Set_Default_Expr_Function (Id : E; V : E) is
begin
pragma Assert (Is_Formal (Id));
Set_Node21 (Id, V);
end Set_Default_Expr_Function;
procedure Set_Default_Expressions_Processed (Id : E; V : B := True) is
begin
Set_Flag108 (Id, V);
end Set_Default_Expressions_Processed;
procedure Set_Default_Value (Id : E; V : N) is
begin
pragma Assert (Is_Formal (Id));
Set_Node20 (Id, V);
end Set_Default_Value;
procedure Set_Delay_Cleanups (Id : E; V : B := True) is
begin
pragma Assert
(Is_Subprogram (Id)
or else Is_Task_Type (Id)
or else Ekind (Id) = E_Block);
Set_Flag114 (Id, V);
end Set_Delay_Cleanups;
procedure Set_Delay_Subprogram_Descriptors (Id : E; V : B := True) is
begin
pragma Assert
(Is_Subprogram (Id)
or else Ekind (Id) = E_Package
or else Ekind (Id) = E_Package_Body);
Set_Flag50 (Id, V);
end Set_Delay_Subprogram_Descriptors;
procedure Set_Delta_Value (Id : E; V : R) is
begin
pragma Assert (Is_Fixed_Point_Type (Id));
Set_Ureal18 (Id, V);
end Set_Delta_Value;
procedure Set_Dependent_Instances (Id : E; V : L) is
begin
pragma Assert (Is_Generic_Instance (Id));
Set_Elist8 (Id, V);
end Set_Dependent_Instances;
procedure Set_Depends_On_Private (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag14 (Id, V);
end Set_Depends_On_Private;
procedure Set_Digits_Value (Id : E; V : U) is
begin
pragma Assert
(Is_Floating_Point_Type (Id)
or else Is_Decimal_Fixed_Point_Type (Id));
Set_Uint17 (Id, V);
end Set_Digits_Value;
procedure Set_Directly_Designated_Type (Id : E; V : E) is
begin
Set_Node20 (Id, V);
end Set_Directly_Designated_Type;
procedure Set_Discard_Names (Id : E; V : B := True) is
begin
Set_Flag88 (Id, V);
end Set_Discard_Names;
procedure Set_Discriminal (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
Set_Node17 (Id, V);
end Set_Discriminal;
procedure Set_Discriminal_Link (Id : E; V : E) is
begin
Set_Node10 (Id, V);
end Set_Discriminal_Link;
procedure Set_Discriminant_Checking_Func (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Component and Ekind (Scope (Id)) in Record_Kind);
Set_Node20 (Id, V);
end Set_Discriminant_Checking_Func;
procedure Set_Discriminant_Constraint (Id : E; V : L) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Elist21 (Id, V);
end Set_Discriminant_Constraint;
procedure Set_Discriminant_Default_Value (Id : E; V : N) is
begin
Set_Node20 (Id, V);
end Set_Discriminant_Default_Value;
procedure Set_Discriminant_Number (Id : E; V : U) is
begin
Set_Uint15 (Id, V);
end Set_Discriminant_Number;
procedure Set_DT_Entry_Count (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Component);
Set_Uint15 (Id, V);
end Set_DT_Entry_Count;
procedure Set_DT_Position (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Function or else Ekind (Id) = E_Procedure);
Set_Uint15 (Id, V);
end Set_DT_Position;
procedure Set_DTC_Entity (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Procedure);
Set_Node16 (Id, V);
end Set_DTC_Entity;
procedure Set_Elaborate_All_Desirable (Id : E; V : B := True) is
begin
Set_Flag146 (Id, V);
end Set_Elaborate_All_Desirable;
procedure Set_Elaboration_Entity (Id : E; V : E) is
begin
pragma Assert
(Is_Subprogram (Id)
or else
Ekind (Id) = E_Package
or else
Is_Generic_Unit (Id));
Set_Node13 (Id, V);
end Set_Elaboration_Entity;
procedure Set_Elaboration_Entity_Required (Id : E; V : B := True) is
begin
pragma Assert
(Is_Subprogram (Id)
or else
Ekind (Id) = E_Package
or else
Is_Generic_Unit (Id));
Set_Flag174 (Id, V);
end Set_Elaboration_Entity_Required;
procedure Set_Enclosing_Scope (Id : E; V : E) is
begin
Set_Node18 (Id, V);
end Set_Enclosing_Scope;
procedure Set_Entry_Accepted (Id : E; V : B := True) is
begin
pragma Assert (Is_Entry (Id));
Set_Flag152 (Id, V);
end Set_Entry_Accepted;
procedure Set_Entry_Bodies_Array (Id : E; V : E) is
begin
Set_Node15 (Id, V);
end Set_Entry_Bodies_Array;
procedure Set_Entry_Cancel_Parameter (Id : E; V : E) is
begin
Set_Node23 (Id, V);
end Set_Entry_Cancel_Parameter;
procedure Set_Entry_Component (Id : E; V : E) is
begin
Set_Node11 (Id, V);
end Set_Entry_Component;
procedure Set_Entry_Formal (Id : E; V : E) is
begin
Set_Node16 (Id, V);
end Set_Entry_Formal;
procedure Set_Entry_Index_Constant (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Entry_Index_Parameter);
Set_Node18 (Id, V);
end Set_Entry_Index_Constant;
procedure Set_Entry_Parameters_Type (Id : E; V : E) is
begin
Set_Node15 (Id, V);
end Set_Entry_Parameters_Type;
procedure Set_Enum_Pos_To_Rep (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Type);
Set_Node23 (Id, V);
end Set_Enum_Pos_To_Rep;
procedure Set_Enumeration_Pos (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
Set_Uint11 (Id, V);
end Set_Enumeration_Pos;
procedure Set_Enumeration_Rep (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
Set_Uint12 (Id, V);
end Set_Enumeration_Rep;
procedure Set_Enumeration_Rep_Expr (Id : E; V : N) is
begin
pragma Assert (Ekind (Id) = E_Enumeration_Literal);
Set_Node22 (Id, V);
end Set_Enumeration_Rep_Expr;
procedure Set_Equivalent_Type (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Class_Wide_Type or else
Ekind (Id) = E_Class_Wide_Subtype or else
Ekind (Id) = E_Access_Protected_Subprogram_Type or else
Ekind (Id) = E_Access_Subprogram_Type or else
Ekind (Id) = E_Exception_Type);
Set_Node18 (Id, V);
end Set_Equivalent_Type;
procedure Set_Esize (Id : E; V : U) is
begin
Set_Uint12 (Id, V);
end Set_Esize;
procedure Set_Exception_Code (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Exception);
Set_Uint22 (Id, V);
end Set_Exception_Code;
procedure Set_Extra_Accessibility (Id : E; V : E) is
begin
pragma Assert (Is_Formal (Id) or else Ekind (Id) = E_Variable);
Set_Node13 (Id, V);
end Set_Extra_Accessibility;
procedure Set_Extra_Constrained (Id : E; V : E) is
begin
pragma Assert (Is_Formal (Id) or else Ekind (Id) = E_Variable);
Set_Node23 (Id, V);
end Set_Extra_Constrained;
procedure Set_Extra_Formal (Id : E; V : E) is
begin
Set_Node15 (Id, V);
end Set_Extra_Formal;
procedure Set_Finalization_Chain_Entity (Id : E; V : E) is
begin
Set_Node19 (Id, V);
end Set_Finalization_Chain_Entity;
procedure Set_Finalize_Storage_Only (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag158 (Base_Type (Id), V);
end Set_Finalize_Storage_Only;
procedure Set_First_Entity (Id : E; V : E) is
begin
Set_Node17 (Id, V);
end Set_First_Entity;
procedure Set_First_Index (Id : E; V : N) is
begin
Set_Node17 (Id, V);
end Set_First_Index;
procedure Set_First_Literal (Id : E; V : E) is
begin
Set_Node17 (Id, V);
end Set_First_Literal;
procedure Set_First_Optional_Parameter (Id : E; V : E) is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Procedure);
Set_Node14 (Id, V);
end Set_First_Optional_Parameter;
procedure Set_First_Private_Entity (Id : E; V : E) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Node16 (Id, V);
end Set_First_Private_Entity;
procedure Set_First_Rep_Item (Id : E; V : N) is
begin
Set_Node6 (Id, V);
end Set_First_Rep_Item;
procedure Set_Freeze_Node (Id : E; V : N) is
begin
Set_Node7 (Id, V);
end Set_Freeze_Node;
procedure Set_From_With_Type (Id : E; V : B := True) is
begin
pragma Assert
(Is_Type (Id)
or else Ekind (Id) = E_Package);
Set_Flag159 (Id, V);
end Set_From_With_Type;
procedure Set_Full_View (Id : E; V : E) is
begin
pragma Assert (Is_Type (Id) or else Ekind (Id) = E_Constant);
Set_Node11 (Id, V);
end Set_Full_View;
procedure Set_Function_Returns_With_DSP (Id : E; V : B := True) is
begin
pragma Assert
(Is_Subprogram (Id) or else Ekind (Id) = E_Subprogram_Type);
Set_Flag169 (Id, V);
end Set_Function_Returns_With_DSP;
procedure Set_Generic_Renamings (Id : E; V : L) is
begin
Set_Elist23 (Id, V);
end Set_Generic_Renamings;
procedure Set_Girder_Constraint (Id : E; V : L) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Elist23 (Id, V);
end Set_Girder_Constraint;
procedure Set_Handler_Records (Id : E; V : S) is
begin
Set_List10 (Id, V);
end Set_Handler_Records;
procedure Set_Has_Aliased_Components (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag135 (Id, V);
end Set_Has_Aliased_Components;
procedure Set_Has_Alignment_Clause (Id : E; V : B := True) is
begin
Set_Flag46 (Id, V);
end Set_Has_Alignment_Clause;
procedure Set_Has_All_Calls_Remote (Id : E; V : B := True) is
begin
Set_Flag79 (Id, V);
end Set_Has_All_Calls_Remote;
procedure Set_Has_Atomic_Components (Id : E; V : B := True) is
begin
pragma Assert (not Is_Type (Id) or else Base_Type (Id) = Id);
Set_Flag86 (Id, V);
end Set_Has_Atomic_Components;
procedure Set_Has_Biased_Representation (Id : E; V : B := True) is
begin
pragma Assert
((V = False) or else (Is_Discrete_Type (Id) or Is_Object (Id)));
Set_Flag139 (Id, V);
end Set_Has_Biased_Representation;
procedure Set_Has_Completion (Id : E; V : B := True) is
begin
Set_Flag26 (Id, V);
end Set_Has_Completion;
procedure Set_Has_Completion_In_Body (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Incomplete_Type);
Set_Flag71 (Id, V);
end Set_Has_Completion_In_Body;
procedure Set_Has_Complex_Representation (Id : E; V : B := True) is
begin
pragma Assert (Is_Record_Type (Id));
Set_Flag140 (Implementation_Base_Type (Id), V);
end Set_Has_Complex_Representation;
procedure Set_Has_Component_Size_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Array_Type (Id));
Set_Flag68 (Implementation_Base_Type (Id), V);
end Set_Has_Component_Size_Clause;
procedure Set_Has_Controlled_Component (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag43 (Id, V);
end Set_Has_Controlled_Component;
procedure Set_Has_Controlling_Result (Id : E; V : B := True) is
begin
Set_Flag98 (Id, V);
end Set_Has_Controlling_Result;
procedure Set_Has_Convention_Pragma (Id : E; V : B := True) is
begin
Set_Flag119 (Id, V);
end Set_Has_Convention_Pragma;
procedure Set_Has_Delayed_Freeze (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag18 (Id, V);
end Set_Has_Delayed_Freeze;
procedure Set_Has_Discriminants (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag5 (Id, V);
end Set_Has_Discriminants;
procedure Set_Has_Enumeration_Rep_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Enumeration_Type (Id));
Set_Flag66 (Id, V);
end Set_Has_Enumeration_Rep_Clause;
procedure Set_Has_Exit (Id : E; V : B := True) is
begin
Set_Flag47 (Id, V);
end Set_Has_Exit;
procedure Set_Has_External_Tag_Rep_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Tagged_Type (Id));
Set_Flag110 (Id, V);
end Set_Has_External_Tag_Rep_Clause;
procedure Set_Has_Forward_Instantiation (Id : E; V : B := True) is
begin
Set_Flag175 (Id, V);
end Set_Has_Forward_Instantiation;
procedure Set_Has_Fully_Qualified_Name (Id : E; V : B := True) is
begin
Set_Flag173 (Id, V);
end Set_Has_Fully_Qualified_Name;
procedure Set_Has_Gigi_Rep_Item (Id : E; V : B := True) is
begin
Set_Flag82 (Id, V);
end Set_Has_Gigi_Rep_Item;
procedure Set_Has_Homonym (Id : E; V : B := True) is
begin
Set_Flag56 (Id, V);
end Set_Has_Homonym;
procedure Set_Has_Machine_Radix_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Decimal_Fixed_Point_Type (Id));
Set_Flag83 (Id, V);
end Set_Has_Machine_Radix_Clause;
procedure Set_Has_Master_Entity (Id : E; V : B := True) is
begin
Set_Flag21 (Id, V);
end Set_Has_Master_Entity;
procedure Set_Has_Missing_Return (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Function or else Ekind (Id) = E_Generic_Function);
Set_Flag142 (Id, V);
end Set_Has_Missing_Return;
procedure Set_Has_Nested_Block_With_Handler (Id : E; V : B := True) is
begin
Set_Flag101 (Id, V);
end Set_Has_Nested_Block_With_Handler;
procedure Set_Has_Non_Standard_Rep (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag75 (Id, V);
end Set_Has_Non_Standard_Rep;
procedure Set_Has_Object_Size_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag172 (Id, V);
end Set_Has_Object_Size_Clause;
procedure Set_Has_Per_Object_Constraint (Id : E; V : B := True) is
begin
Set_Flag154 (Id, V);
end Set_Has_Per_Object_Constraint;
procedure Set_Has_Pragma_Controlled (Id : E; V : B := True) is
begin
pragma Assert (Is_Access_Type (Id));
Set_Flag27 (Base_Type (Id), V);
end Set_Has_Pragma_Controlled;
procedure Set_Has_Pragma_Elaborate_Body (Id : E; V : B := True) is
begin
Set_Flag150 (Id, V);
end Set_Has_Pragma_Elaborate_Body;
procedure Set_Has_Pragma_Inline (Id : E; V : B := True) is
begin
Set_Flag157 (Id, V);
end Set_Has_Pragma_Inline;
procedure Set_Has_Pragma_Pack (Id : E; V : B := True) is
begin
pragma Assert (Is_Array_Type (Id) or else Is_Record_Type (Id));
Set_Flag121 (Implementation_Base_Type (Id), V);
end Set_Has_Pragma_Pack;
procedure Set_Has_Pragma_Pure_Function (Id : E; V : B := True) is
begin
pragma Assert (Is_Subprogram (Id));
Set_Flag179 (Id, V);
end Set_Has_Pragma_Pure_Function;
procedure Set_Has_Primitive_Operations (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag120 (Base_Type (Id), V);
end Set_Has_Primitive_Operations;
procedure Set_Has_Private_Declaration (Id : E; V : B := True) is
begin
Set_Flag155 (Id, V);
end Set_Has_Private_Declaration;
procedure Set_Has_Qualified_Name (Id : E; V : B := True) is
begin
Set_Flag161 (Id, V);
end Set_Has_Qualified_Name;
procedure Set_Has_Record_Rep_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Record_Type (Id));
Set_Flag65 (Id, V);
end Set_Has_Record_Rep_Clause;
procedure Set_Has_Recursive_Call (Id : E; V : B := True) is
begin
pragma Assert (Is_Subprogram (Id));
Set_Flag143 (Id, V);
end Set_Has_Recursive_Call;
procedure Set_Has_Size_Clause (Id : E; V : B := True) is
begin
Set_Flag29 (Id, V);
end Set_Has_Size_Clause;
procedure Set_Has_Small_Clause (Id : E; V : B := True) is
begin
Set_Flag67 (Id, V);
end Set_Has_Small_Clause;
procedure Set_Has_Specified_Layout (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag100 (Id, V);
end Set_Has_Specified_Layout;
procedure Set_Has_Storage_Size_Clause (Id : E; V : B := True) is
begin
pragma Assert (Is_Access_Type (Id) or else Is_Task_Type (Id));
pragma Assert (Base_Type (Id) = Id);
Set_Flag23 (Id, V);
end Set_Has_Storage_Size_Clause;
procedure Set_Has_Subprogram_Descriptor (Id : E; V : B := True) is
begin
Set_Flag93 (Id, V);
end Set_Has_Subprogram_Descriptor;
procedure Set_Has_Task (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag30 (Id, V);
end Set_Has_Task;
procedure Set_Has_Unchecked_Union (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag123 (Id, V);
end Set_Has_Unchecked_Union;
procedure Set_Has_Unknown_Discriminants (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag72 (Id, V);
end Set_Has_Unknown_Discriminants;
procedure Set_Has_Volatile_Components (Id : E; V : B := True) is
begin
pragma Assert (not Is_Type (Id) or else Base_Type (Id) = Id);
Set_Flag87 (Id, V);
end Set_Has_Volatile_Components;
procedure Set_Hiding_Loop_Variable (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Variable);
Set_Node8 (Id, V);
end Set_Hiding_Loop_Variable;
procedure Set_Homonym (Id : E; V : E) is
begin
pragma Assert (Id /= V);
Set_Node4 (Id, V);
end Set_Homonym;
procedure Set_In_Package_Body (Id : E; V : B := True) is
begin
Set_Flag48 (Id, V);
end Set_In_Package_Body;
procedure Set_In_Private_Part (Id : E; V : B := True) is
begin
Set_Flag45 (Id, V);
end Set_In_Private_Part;
procedure Set_In_Use (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag8 (Id, V);
end Set_In_Use;
procedure Set_Inner_Instances (Id : E; V : L) is
begin
Set_Elist23 (Id, V);
end Set_Inner_Instances;
procedure Set_Interface_Name (Id : E; V : N) is
begin
Set_Node21 (Id, V);
end Set_Interface_Name;
procedure Set_Is_Abstract (Id : E; V : B := True) is
begin
Set_Flag19 (Id, V);
end Set_Is_Abstract;
procedure Set_Is_Access_Constant (Id : E; V : B := True) is
begin
pragma Assert (Is_Access_Type (Id));
Set_Flag69 (Id, V);
end Set_Is_Access_Constant;
procedure Set_Is_Aliased (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag15 (Id, V);
end Set_Is_Aliased;
procedure Set_Is_AST_Entry (Id : E; V : B := True) is
begin
pragma Assert (Is_Entry (Id));
Set_Flag132 (Id, V);
end Set_Is_AST_Entry;
procedure Set_Is_Asynchronous (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Is_Type (Id));
Set_Flag81 (Id, V);
end Set_Is_Asynchronous;
procedure Set_Is_Atomic (Id : E; V : B := True) is
begin
Set_Flag85 (Id, V);
end Set_Is_Atomic;
procedure Set_Is_Bit_Packed_Array (Id : E; V : B := True) is
begin
Set_Flag122 (Implementation_Base_Type (Id), V);
end Set_Is_Bit_Packed_Array;
procedure Set_Is_Called (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Ekind (Id) = E_Function);
Set_Flag102 (Id, V);
end Set_Is_Called;
procedure Set_Is_Character_Type (Id : E; V : B := True) is
begin
Set_Flag63 (Id, V);
end Set_Is_Character_Type;
procedure Set_Is_Child_Unit (Id : E; V : B := True) is
begin
Set_Flag73 (Id, V);
end Set_Is_Child_Unit;
procedure Set_Is_Compilation_Unit (Id : E; V : B := True) is
begin
Set_Flag149 (Id, V);
end Set_Is_Compilation_Unit;
procedure Set_Is_Completely_Hidden (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Discriminant);
Set_Flag103 (Id, V);
end Set_Is_Completely_Hidden;
procedure Set_Is_Concurrent_Record_Type (Id : E; V : B := True) is
begin
Set_Flag20 (Id, V);
end Set_Is_Concurrent_Record_Type;
procedure Set_Is_Constr_Subt_For_U_Nominal (Id : E; V : B := True) is
begin
Set_Flag80 (Id, V);
end Set_Is_Constr_Subt_For_U_Nominal;
procedure Set_Is_Constr_Subt_For_UN_Aliased (Id : E; V : B := True) is
begin
Set_Flag141 (Id, V);
end Set_Is_Constr_Subt_For_UN_Aliased;
procedure Set_Is_Constrained (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag12 (Id, V);
end Set_Is_Constrained;
procedure Set_Is_Constructor (Id : E; V : B := True) is
begin
Set_Flag76 (Id, V);
end Set_Is_Constructor;
procedure Set_Is_Controlled (Id : E; V : B := True) is
begin
pragma Assert (Id = Base_Type (Id));
Set_Flag42 (Id, V);
end Set_Is_Controlled;
procedure Set_Is_Controlling_Formal (Id : E; V : B := True) is
begin
pragma Assert (Is_Formal (Id));
Set_Flag97 (Id, V);
end Set_Is_Controlling_Formal;
procedure Set_Is_CPP_Class (Id : E; V : B := True) is
begin
Set_Flag74 (Id, V);
end Set_Is_CPP_Class;
procedure Set_Is_Destructor (Id : E; V : B := True) is
begin
Set_Flag77 (Id, V);
end Set_Is_Destructor;
procedure Set_Is_Discrim_SO_Function (Id : E; V : B := True) is
begin
Set_Flag176 (Id, V);
end Set_Is_Discrim_SO_Function;
procedure Set_Is_Dispatching_Operation (Id : E; V : B := True) is
begin
pragma Assert
(V = False
or else
Is_Overloadable (Id)
or else
Ekind (Id) = E_Subprogram_Type);
Set_Flag6 (Id, V);
end Set_Is_Dispatching_Operation;
procedure Set_Is_Eliminated (Id : E; V : B := True) is
begin
Set_Flag124 (Id, V);
end Set_Is_Eliminated;
procedure Set_Is_Entry_Formal (Id : E; V : B := True) is
begin
Set_Flag52 (Id, V);
end Set_Is_Entry_Formal;
procedure Set_Is_Exported (Id : E; V : B := True) is
begin
Set_Flag99 (Id, V);
end Set_Is_Exported;
procedure Set_Is_First_Subtype (Id : E; V : B := True) is
begin
Set_Flag70 (Id, V);
end Set_Is_First_Subtype;
procedure Set_Is_For_Access_Subtype (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Record_Subtype
or else
Ekind (Id) = E_Private_Subtype);
Set_Flag118 (Id, V);
end Set_Is_For_Access_Subtype;
procedure Set_Is_Formal_Subprogram (Id : E; V : B := True) is
begin
Set_Flag111 (Id, V);
end Set_Is_Formal_Subprogram;
procedure Set_Is_Frozen (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag4 (Id, V);
end Set_Is_Frozen;
procedure Set_Is_Generic_Actual_Type (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag94 (Id, V);
end Set_Is_Generic_Actual_Type;
procedure Set_Is_Generic_Instance (Id : E; V : B := True) is
begin
Set_Flag130 (Id, V);
end Set_Is_Generic_Instance;
procedure Set_Is_Generic_Type (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag13 (Id, V);
end Set_Is_Generic_Type;
procedure Set_Is_Hidden (Id : E; V : B := True) is
begin
Set_Flag57 (Id, V);
end Set_Is_Hidden;
procedure Set_Is_Hidden_Open_Scope (Id : E; V : B := True) is
begin
Set_Flag171 (Id, V);
end Set_Is_Hidden_Open_Scope;
procedure Set_Is_Immediately_Visible (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag7 (Id, V);
end Set_Is_Immediately_Visible;
procedure Set_Is_Imported (Id : E; V : B := True) is
begin
Set_Flag24 (Id, V);
end Set_Is_Imported;
procedure Set_Is_Inlined (Id : E; V : B := True) is
begin
Set_Flag11 (Id, V);
end Set_Is_Inlined;
procedure Set_Is_Instantiated (Id : E; V : B := True) is
begin
Set_Flag126 (Id, V);
end Set_Is_Instantiated;
procedure Set_Is_Internal (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag17 (Id, V);
end Set_Is_Internal;
procedure Set_Is_Interrupt_Handler (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag89 (Id, V);
end Set_Is_Interrupt_Handler;
procedure Set_Is_Intrinsic_Subprogram (Id : E; V : B := True) is
begin
Set_Flag64 (Id, V);
end Set_Is_Intrinsic_Subprogram;
procedure Set_Is_Itype (Id : E; V : B := True) is
begin
Set_Flag91 (Id, V);
end Set_Is_Itype;
procedure Set_Is_Known_Valid (Id : E; V : B := True) is
begin
Set_Flag170 (Id, V);
end Set_Is_Known_Valid;
procedure Set_Is_Limited_Composite (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag106 (Id, V);
end Set_Is_Limited_Composite;
procedure Set_Is_Limited_Record (Id : E; V : B := True) is
begin
Set_Flag25 (Id, V);
end Set_Is_Limited_Record;
procedure Set_Is_Machine_Code_Subprogram (Id : E; V : B := True) is
begin
pragma Assert (Is_Subprogram (Id));
Set_Flag137 (Id, V);
end Set_Is_Machine_Code_Subprogram;
procedure Set_Is_Non_Static_Subtype (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag109 (Id, V);
end Set_Is_Non_Static_Subtype;
procedure Set_Is_Null_Init_Proc (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Procedure);
Set_Flag178 (Id, V);
end Set_Is_Null_Init_Proc;
procedure Set_Is_Optional_Parameter (Id : E; V : B := True) is
begin
pragma Assert (Is_Formal (Id));
Set_Flag134 (Id, V);
end Set_Is_Optional_Parameter;
procedure Set_Is_Package_Body_Entity (Id : E; V : B := True) is
begin
Set_Flag160 (Id, V);
end Set_Is_Package_Body_Entity;
procedure Set_Is_Packed (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag51 (Id, V);
end Set_Is_Packed;
procedure Set_Is_Packed_Array_Type (Id : E; V : B := True) is
begin
Set_Flag138 (Id, V);
end Set_Is_Packed_Array_Type;
procedure Set_Is_Potentially_Use_Visible (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag9 (Id, V);
end Set_Is_Potentially_Use_Visible;
procedure Set_Is_Preelaborated (Id : E; V : B := True) is
begin
Set_Flag59 (Id, V);
end Set_Is_Preelaborated;
procedure Set_Is_Private_Composite (Id : E; V : B := True) is
begin
pragma Assert (Is_Type (Id));
Set_Flag107 (Id, V);
end Set_Is_Private_Composite;
procedure Set_Is_Private_Descendant (Id : E; V : B := True) is
begin
Set_Flag53 (Id, V);
end Set_Is_Private_Descendant;
procedure Set_Is_Psected (Id : E; V : B := True) is
begin
Set_Flag153 (Id, V);
end Set_Is_Psected;
procedure Set_Is_Public (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag10 (Id, V);
end Set_Is_Public;
procedure Set_Is_Pure (Id : E; V : B := True) is
begin
Set_Flag44 (Id, V);
end Set_Is_Pure;
procedure Set_Is_Remote_Call_Interface (Id : E; V : B := True) is
begin
Set_Flag62 (Id, V);
end Set_Is_Remote_Call_Interface;
procedure Set_Is_Remote_Types (Id : E; V : B := True) is
begin
Set_Flag61 (Id, V);
end Set_Is_Remote_Types;
procedure Set_Is_Renaming_Of_Object (Id : E; V : B := True) is
begin
Set_Flag112 (Id, V);
end Set_Is_Renaming_Of_Object;
procedure Set_Is_Shared_Passive (Id : E; V : B := True) is
begin
Set_Flag60 (Id, V);
end Set_Is_Shared_Passive;
procedure Set_Is_Statically_Allocated (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Exception
or else Ekind (Id) = E_Variable
or else Ekind (Id) = E_Constant
or else Is_Type (Id)
or else Ekind (Id) = E_Void);
Set_Flag28 (Id, V);
end Set_Is_Statically_Allocated;
procedure Set_Is_Tag (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag78 (Id, V);
end Set_Is_Tag;
procedure Set_Is_Tagged_Type (Id : E; V : B := True) is
begin
Set_Flag55 (Id, V);
end Set_Is_Tagged_Type;
procedure Set_Is_True_Constant (Id : E; V : B := True) is
begin
Set_Flag163 (Id, V);
end Set_Is_True_Constant;
procedure Set_Is_Unchecked_Union (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag117 (Id, V);
end Set_Is_Unchecked_Union;
procedure Set_Is_Unsigned_Type (Id : E; V : B := True) is
begin
pragma Assert (Is_Discrete_Or_Fixed_Point_Type (Id));
Set_Flag144 (Id, V);
end Set_Is_Unsigned_Type;
procedure Set_Is_Valued_Procedure (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Procedure);
Set_Flag127 (Id, V);
end Set_Is_Valued_Procedure;
procedure Set_Is_Visible_Child_Unit (Id : E; V : B := True) is
begin
pragma Assert (Is_Child_Unit (Id));
Set_Flag116 (Id, V);
end Set_Is_Visible_Child_Unit;
procedure Set_Is_VMS_Exception (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Exception);
Set_Flag133 (Id, V);
end Set_Is_VMS_Exception;
procedure Set_Is_Volatile (Id : E; V : B := True) is
begin
pragma Assert (Nkind (Id) in N_Entity);
Set_Flag16 (Id, V);
end Set_Is_Volatile;
procedure Set_Last_Entity (Id : E; V : E) is
begin
Set_Node20 (Id, V);
end Set_Last_Entity;
procedure Set_Lit_Indexes (Id : E; V : E) is
begin
pragma Assert (Is_Enumeration_Type (Id) and then Root_Type (Id) = Id);
Set_Node15 (Id, V);
end Set_Lit_Indexes;
procedure Set_Lit_Strings (Id : E; V : E) is
begin
pragma Assert (Is_Enumeration_Type (Id) and then Root_Type (Id) = Id);
Set_Node16 (Id, V);
end Set_Lit_Strings;
procedure Set_Machine_Radix_10 (Id : E; V : B := True) is
begin
pragma Assert (Is_Decimal_Fixed_Point_Type (Id));
Set_Flag84 (Id, V);
end Set_Machine_Radix_10;
procedure Set_Master_Id (Id : E; V : E) is
begin
Set_Node17 (Id, V);
end Set_Master_Id;
procedure Set_Materialize_Entity (Id : E; V : B := True) is
begin
Set_Flag168 (Id, V);
end Set_Materialize_Entity;
procedure Set_Mechanism (Id : E; V : M) is
begin
pragma Assert (Ekind (Id) = E_Function or else Is_Formal (Id));
Set_Uint8 (Id, UI_From_Int (V));
end Set_Mechanism;
procedure Set_Modulus (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_Modular_Integer_Type);
Set_Uint17 (Id, V);
end Set_Modulus;
procedure Set_Needs_Debug_Info (Id : E; V : B := True) is
begin
Set_Flag147 (Id, V);
end Set_Needs_Debug_Info;
procedure Set_Needs_No_Actuals (Id : E; V : B := True) is
begin
pragma Assert
(Is_Overloadable (Id)
or else Ekind (Id) = E_Subprogram_Type
or else Ekind (Id) = E_Entry_Family);
Set_Flag22 (Id, V);
end Set_Needs_No_Actuals;
procedure Set_Next_Inlined_Subprogram (Id : E; V : E) is
begin
Set_Node12 (Id, V);
end Set_Next_Inlined_Subprogram;
procedure Set_No_Pool_Assigned (Id : E; V : B := True) is
begin
pragma Assert (Is_Access_Type (Id) and then Root_Type (Id) = Id);
Set_Flag131 (Id, V);
end Set_No_Pool_Assigned;
procedure Set_No_Return (Id : E; V : B := True) is
begin
pragma Assert
(Ekind (Id) = E_Procedure or else Ekind (Id) = E_Generic_Procedure);
Set_Flag113 (Id, V);
end Set_No_Return;
procedure Set_Non_Binary_Modulus (Id : E; V : B := True) is
begin
pragma Assert (Ekind (Id) = E_Modular_Integer_Type);
Set_Flag58 (Id, V);
end Set_Non_Binary_Modulus;
procedure Set_Nonzero_Is_True (Id : E; V : B := True) is
begin
pragma Assert
(Root_Type (Id) = Standard_Boolean
and then Ekind (Id) = E_Enumeration_Type);
Set_Flag162 (Id, V);
end Set_Nonzero_Is_True;
procedure Set_Normalized_First_Bit (Id : E; V : U) is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
Set_Uint8 (Id, V);
end Set_Normalized_First_Bit;
procedure Set_Normalized_Position (Id : E; V : U) is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
Set_Uint9 (Id, V);
end Set_Normalized_Position;
procedure Set_Normalized_Position_Max (Id : E; V : U) is
begin
pragma Assert
(Ekind (Id) = E_Component or else Ekind (Id) = E_Discriminant);
Set_Uint10 (Id, V);
end Set_Normalized_Position_Max;
procedure Set_Not_Source_Assigned (Id : E; V : B := True) is
begin
Set_Flag115 (Id, V);
end Set_Not_Source_Assigned;
procedure Set_Object_Ref (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Protected_Body);
Set_Node17 (Id, V);
end Set_Object_Ref;
procedure Set_Original_Record_Component (Id : E; V : E) is
begin
Set_Node22 (Id, V);
end Set_Original_Record_Component;
procedure Set_Packed_Array_Type (Id : E; V : E) is
begin
pragma Assert (Is_Array_Type (Id));
Set_Node23 (Id, V);
end Set_Packed_Array_Type;
procedure Set_Parent_Subtype (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Record_Type);
Set_Node19 (Id, V);
end Set_Parent_Subtype;
procedure Set_Primitive_Operations (Id : E; V : L) is
begin
pragma Assert (Is_Tagged_Type (Id));
Set_Elist15 (Id, V);
end Set_Primitive_Operations;
procedure Set_Prival (Id : E; V : E) is
begin
pragma Assert (Is_Protected_Private (Id));
Set_Node17 (Id, V);
end Set_Prival;
procedure Set_Privals_Chain (Id : E; V : L) is
begin
pragma Assert (Is_Overloadable (Id)
or else Ekind (Id) = E_Entry_Family);
Set_Elist23 (Id, V);
end Set_Privals_Chain;
procedure Set_Private_Dependents (Id : E; V : L) is
begin
pragma Assert (Is_Incomplete_Or_Private_Type (Id));
Set_Elist18 (Id, V);
end Set_Private_Dependents;
procedure Set_Private_View (Id : E; V : N) is
begin
pragma Assert (Is_Private_Type (Id));
Set_Node22 (Id, V);
end Set_Private_View;
procedure Set_Protected_Body_Subprogram (Id : E; V : E) is
begin
pragma Assert (Is_Subprogram (Id) or else Is_Entry (Id));
Set_Node11 (Id, V);
end Set_Protected_Body_Subprogram;
procedure Set_Protected_Formal (Id : E; V : E) is
begin
pragma Assert (Is_Formal (Id));
Set_Node22 (Id, V);
end Set_Protected_Formal;
procedure Set_Protected_Operation (Id : E; V : N) is
begin
pragma Assert (Is_Protected_Private (Id));
Set_Node23 (Id, V);
end Set_Protected_Operation;
procedure Set_Reachable (Id : E; V : B := True) is
begin
Set_Flag49 (Id, V);
end Set_Reachable;
procedure Set_Referenced (Id : E; V : B := True) is
begin
Set_Flag156 (Id, V);
end Set_Referenced;
procedure Set_Referenced_Object (Id : E; V : N) is
begin
pragma Assert (Is_Type (Id));
Set_Node10 (Id, V);
end Set_Referenced_Object;
procedure Set_Register_Exception_Call (Id : E; V : N) is
begin
pragma Assert (Ekind (Id) = E_Exception);
Set_Node20 (Id, V);
end Set_Register_Exception_Call;
procedure Set_Related_Array_Object (Id : E; V : E) is
begin
pragma Assert (Is_Array_Type (Id));
Set_Node19 (Id, V);
end Set_Related_Array_Object;
procedure Set_Related_Instance (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Package);
Set_Node15 (Id, V);
end Set_Related_Instance;
procedure Set_Renamed_Entity (Id : E; V : N) is
begin
Set_Node18 (Id, V);
end Set_Renamed_Entity;
procedure Set_Renamed_Object (Id : E; V : N) is
begin
Set_Node18 (Id, V);
end Set_Renamed_Object;
procedure Set_Renaming_Map (Id : E; V : U) is
begin
Set_Uint9 (Id, V);
end Set_Renaming_Map;
procedure Set_Return_Present (Id : E; V : B := True) is
begin
Set_Flag54 (Id, V);
end Set_Return_Present;
procedure Set_Returns_By_Ref (Id : E; V : B := True) is
begin
Set_Flag90 (Id, V);
end Set_Returns_By_Ref;
procedure Set_Reverse_Bit_Order (Id : E; V : B := True) is
begin
pragma Assert
(Is_Record_Type (Id) and then Id = Base_Type (Id));
Set_Flag164 (Id, V);
end Set_Reverse_Bit_Order;
procedure Set_RM_Size (Id : E; V : U) is
begin
pragma Assert (Is_Type (Id));
Set_Uint13 (Id, V);
end Set_RM_Size;
procedure Set_Scalar_Range (Id : E; V : N) is
begin
Set_Node20 (Id, V);
end Set_Scalar_Range;
procedure Set_Scale_Value (Id : E; V : U) is
begin
Set_Uint15 (Id, V);
end Set_Scale_Value;
procedure Set_Scope_Depth_Value (Id : E; V : U) is
begin
pragma Assert (not Is_Record_Type (Id));
Set_Uint22 (Id, V);
end Set_Scope_Depth_Value;
procedure Set_Sec_Stack_Needed_For_Return (Id : E; V : B := True) is
begin
Set_Flag167 (Id, V);
end Set_Sec_Stack_Needed_For_Return;
procedure Set_Shadow_Entities (Id : E; V : S) is
begin
pragma Assert
(Ekind (Id) = E_Package or else Ekind (Id) = E_Generic_Package);
Set_List14 (Id, V);
end Set_Shadow_Entities;
procedure Set_Shared_Var_Assign_Proc (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Variable);
Set_Node22 (Id, V);
end Set_Shared_Var_Assign_Proc;
procedure Set_Shared_Var_Read_Proc (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Variable);
Set_Node15 (Id, V);
end Set_Shared_Var_Read_Proc;
procedure Set_Size_Check_Code (Id : E; V : N) is
begin
pragma Assert (Ekind (Id) = E_Constant or else Ekind (Id) = E_Variable);
Set_Node9 (Id, V);
end Set_Size_Check_Code;
procedure Set_Size_Depends_On_Discriminant (Id : E; V : B := True) is
begin
Set_Flag177 (Id, V);
end Set_Size_Depends_On_Discriminant;
procedure Set_Size_Known_At_Compile_Time (Id : E; V : B := True) is
begin
Set_Flag92 (Id, V);
end Set_Size_Known_At_Compile_Time;
procedure Set_Small_Value (Id : E; V : R) is
begin
pragma Assert (Is_Fixed_Point_Type (Id));
Set_Ureal21 (Id, V);
end Set_Small_Value;
procedure Set_Spec_Entity (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) = E_Package_Body or else Is_Formal (Id));
Set_Node19 (Id, V);
end Set_Spec_Entity;
procedure Set_Storage_Size_Variable (Id : E; V : E) is
begin
pragma Assert (Is_Access_Type (Id) or else Is_Task_Type (Id));
pragma Assert (Base_Type (Id) = Id);
Set_Node15 (Id, V);
end Set_Storage_Size_Variable;
procedure Set_Strict_Alignment (Id : E; V : B := True) is
begin
pragma Assert (Base_Type (Id) = Id);
Set_Flag145 (Id, V);
end Set_Strict_Alignment;
procedure Set_String_Literal_Length (Id : E; V : U) is
begin
pragma Assert (Ekind (Id) = E_String_Literal_Subtype);
Set_Uint16 (Id, V);
end Set_String_Literal_Length;
procedure Set_String_Literal_Low_Bound (Id : E; V : N) is
begin
pragma Assert (Ekind (Id) = E_String_Literal_Subtype);
Set_Node15 (Id, V);
end Set_String_Literal_Low_Bound;
procedure Set_Suppress_Access_Checks (Id : E; V : B := True) is
begin
Set_Flag31 (Id, V);
end Set_Suppress_Access_Checks;
procedure Set_Suppress_Accessibility_Checks (Id : E; V : B := True) is
begin
Set_Flag32 (Id, V);
end Set_Suppress_Accessibility_Checks;
procedure Set_Suppress_Discriminant_Checks (Id : E; V : B := True) is
begin
Set_Flag33 (Id, V);
end Set_Suppress_Discriminant_Checks;
procedure Set_Suppress_Division_Checks (Id : E; V : B := True) is
begin
Set_Flag34 (Id, V);
end Set_Suppress_Division_Checks;
procedure Set_Suppress_Elaboration_Checks (Id : E; V : B := True) is
begin
Set_Flag35 (Id, V);
end Set_Suppress_Elaboration_Checks;
procedure Set_Suppress_Elaboration_Warnings (Id : E; V : B := True) is
begin
Set_Flag148 (Id, V);
end Set_Suppress_Elaboration_Warnings;
procedure Set_Suppress_Index_Checks (Id : E; V : B := True) is
begin
Set_Flag36 (Id, V);
end Set_Suppress_Index_Checks;
procedure Set_Suppress_Init_Proc (Id : E; V : B := True) is
begin
Set_Flag105 (Id, V);
end Set_Suppress_Init_Proc;
procedure Set_Suppress_Length_Checks (Id : E; V : B := True) is
begin
Set_Flag37 (Id, V);
end Set_Suppress_Length_Checks;
procedure Set_Suppress_Overflow_Checks (Id : E; V : B := True) is
begin
Set_Flag38 (Id, V);
end Set_Suppress_Overflow_Checks;
procedure Set_Suppress_Range_Checks (Id : E; V : B := True) is
begin
Set_Flag39 (Id, V);
end Set_Suppress_Range_Checks;
procedure Set_Suppress_Storage_Checks (Id : E; V : B := True) is
begin
Set_Flag40 (Id, V);
end Set_Suppress_Storage_Checks;
procedure Set_Suppress_Style_Checks (Id : E; V : B := True) is
begin
Set_Flag165 (Id, V);
end Set_Suppress_Style_Checks;
procedure Set_Suppress_Tag_Checks (Id : E; V : B := True) is
begin
Set_Flag41 (Id, V);
end Set_Suppress_Tag_Checks;
procedure Set_Underlying_Full_View (Id : E; V : E) is
begin
pragma Assert (Ekind (Id) in Private_Kind);
Set_Node19 (Id, V);
end Set_Underlying_Full_View;
procedure Set_Unset_Reference (Id : E; V : N) is
begin
Set_Node16 (Id, V);
end Set_Unset_Reference;
procedure Set_Uses_Sec_Stack (Id : E; V : B := True) is
begin
Set_Flag95 (Id, V);
end Set_Uses_Sec_Stack;
procedure Set_Vax_Float (Id : E; V : B := True) is
begin
pragma Assert (Id = Base_Type (Id));
Set_Flag151 (Id, V);
end Set_Vax_Float;
procedure Set_Warnings_Off (Id : E; V : B := True) is
begin
Set_Flag96 (Id, V);
end Set_Warnings_Off;
-----------------------------------
-- Field Initialization Routines --
-----------------------------------
procedure Init_Alignment (Id : E) is
begin
Set_Uint14 (Id, Uint_0);
end Init_Alignment;
procedure Init_Alignment (Id : E; V : Int) is
begin
Set_Uint14 (Id, UI_From_Int (V));
end Init_Alignment;
procedure Init_Component_Bit_Offset (Id : E) is
begin
Set_Uint11 (Id, No_Uint);
end Init_Component_Bit_Offset;
procedure Init_Component_Bit_Offset (Id : E; V : Int) is
begin
Set_Uint11 (Id, UI_From_Int (V));
end Init_Component_Bit_Offset;
procedure Init_Component_Size (Id : E) is
begin
Set_Uint22 (Id, Uint_0);
end Init_Component_Size;
procedure Init_Component_Size (Id : E; V : Int) is
begin
Set_Uint22 (Id, UI_From_Int (V));
end Init_Component_Size;
procedure Init_Digits_Value (Id : E) is
begin
Set_Uint17 (Id, Uint_0);
end Init_Digits_Value;
procedure Init_Digits_Value (Id : E; V : Int) is
begin
Set_Uint17 (Id, UI_From_Int (V));
end Init_Digits_Value;
procedure Init_Esize (Id : E) is
begin
Set_Uint12 (Id, Uint_0);
end Init_Esize;
procedure Init_Esize (Id : E; V : Int) is
begin
Set_Uint12 (Id, UI_From_Int (V));
end Init_Esize;
procedure Init_Normalized_First_Bit (Id : E) is
begin
Set_Uint8 (Id, No_Uint);
end Init_Normalized_First_Bit;
procedure Init_Normalized_First_Bit (Id : E; V : Int) is
begin
Set_Uint8 (Id, UI_From_Int (V));
end Init_Normalized_First_Bit;
procedure Init_Normalized_Position (Id : E) is
begin
Set_Uint9 (Id, No_Uint);
end Init_Normalized_Position;
procedure Init_Normalized_Position (Id : E; V : Int) is
begin
Set_Uint9 (Id, UI_From_Int (V));
end Init_Normalized_Position;
procedure Init_Normalized_Position_Max (Id : E) is
begin
Set_Uint10 (Id, No_Uint);
end Init_Normalized_Position_Max;
procedure Init_Normalized_Position_Max (Id : E; V : Int) is
begin
Set_Uint10 (Id, UI_From_Int (V));
end Init_Normalized_Position_Max;
procedure Init_RM_Size (Id : E) is
begin
Set_Uint13 (Id, Uint_0);
end Init_RM_Size;
procedure Init_RM_Size (Id : E; V : Int) is
begin
Set_Uint13 (Id, UI_From_Int (V));
end Init_RM_Size;
-----------------------------
-- Init_Component_Location --
-----------------------------
procedure Init_Component_Location (Id : E) is
begin
Set_Uint8 (Id, No_Uint); -- Normalized_First_Bit
Set_Uint9 (Id, No_Uint); -- Normalized_Position
Set_Uint11 (Id, No_Uint); -- Component_First_Bit
Set_Uint12 (Id, Uint_0); -- Esize
Set_Uint10 (Id, No_Uint); -- Normalized_Position_Max
end Init_Component_Location;
---------------
-- Init_Size --
---------------
procedure Init_Size (Id : E; V : Int) is
begin
Set_Uint12 (Id, UI_From_Int (V)); -- Esize
Set_Uint13 (Id, UI_From_Int (V)); -- RM_Size
end Init_Size;
---------------------
-- Init_Size_Align --
---------------------
procedure Init_Size_Align (Id : E) is
begin
Set_Uint12 (Id, Uint_0); -- Esize
Set_Uint13 (Id, Uint_0); -- RM_Size
Set_Uint14 (Id, Uint_0); -- Alignment
end Init_Size_Align;
----------------------------------------------
-- Type Representation Attribute Predicates --
----------------------------------------------
function Known_Alignment (E : Entity_Id) return B is
begin
return Uint14 (E) /= Uint_0;
end Known_Alignment;
function Known_Component_Bit_Offset (E : Entity_Id) return B is
begin
return Uint11 (E) /= No_Uint;
end Known_Component_Bit_Offset;
function Known_Component_Size (E : Entity_Id) return B is
begin
return Uint22 (Base_Type (E)) /= Uint_0;
end Known_Component_Size;
function Known_Esize (E : Entity_Id) return B is
begin
return Uint12 (E) /= Uint_0;
end Known_Esize;
function Known_Normalized_First_Bit (E : Entity_Id) return B is
begin
return Uint8 (E) /= No_Uint;
end Known_Normalized_First_Bit;
function Known_Normalized_Position (E : Entity_Id) return B is
begin
return Uint9 (E) /= No_Uint;
end Known_Normalized_Position;
function Known_Normalized_Position_Max (E : Entity_Id) return B is
begin
return Uint10 (E) /= No_Uint;
end Known_Normalized_Position_Max;
function Known_RM_Size (E : Entity_Id) return B is
begin
return Uint13 (E) /= Uint_0
or else Is_Discrete_Type (E);
end Known_RM_Size;
function Known_Static_Component_Bit_Offset (E : Entity_Id) return B is
begin
return Uint11 (E) /= No_Uint
and then Uint11 (E) >= Uint_0;
end Known_Static_Component_Bit_Offset;
function Known_Static_Component_Size (E : Entity_Id) return B is
begin
return Uint22 (Base_Type (E)) > Uint_0;
end Known_Static_Component_Size;
function Known_Static_Esize (E : Entity_Id) return B is
begin
return Uint12 (E) > Uint_0;
end Known_Static_Esize;
function Known_Static_Normalized_Position (E : Entity_Id) return B is
begin
return Uint9 (E) /= No_Uint
and then Uint9 (E) >= Uint_0;
end Known_Static_Normalized_Position;
function Known_Static_Normalized_Position_Max (E : Entity_Id) return B is
begin
return Uint10 (E) /= No_Uint
and then Uint10 (E) >= Uint_0;
end Known_Static_Normalized_Position_Max;
function Known_Static_RM_Size (E : Entity_Id) return B is
begin
return Uint13 (E) > Uint_0
or else Is_Discrete_Type (E);
end Known_Static_RM_Size;
function Unknown_Alignment (E : Entity_Id) return B is
begin
return Uint14 (E) = Uint_0;
end Unknown_Alignment;
function Unknown_Component_Bit_Offset (E : Entity_Id) return B is
begin
return Uint11 (E) = No_Uint;
end Unknown_Component_Bit_Offset;
function Unknown_Component_Size (E : Entity_Id) return B is
begin
return Uint22 (Base_Type (E)) = Uint_0;
end Unknown_Component_Size;
function Unknown_Esize (E : Entity_Id) return B is
begin
return Uint12 (E) = Uint_0;
end Unknown_Esize;
function Unknown_Normalized_First_Bit (E : Entity_Id) return B is
begin
return Uint8 (E) = No_Uint;
end Unknown_Normalized_First_Bit;
function Unknown_Normalized_Position (E : Entity_Id) return B is
begin
return Uint9 (E) = No_Uint;
end Unknown_Normalized_Position;
function Unknown_Normalized_Position_Max (E : Entity_Id) return B is
begin
return Uint10 (E) = No_Uint;
end Unknown_Normalized_Position_Max;
function Unknown_RM_Size (E : Entity_Id) return B is
begin
return Uint13 (E) = Uint_0
and then not Is_Discrete_Type (E);
end Unknown_RM_Size;
--------------------
-- Address_Clause --
--------------------
function Address_Clause (Id : E) return N is
Ritem : Node_Id;
begin
Ritem := First_Rep_Item (Id);
while Present (Ritem) loop
if Nkind (Ritem) = N_Attribute_Definition_Clause
and then Chars (Ritem) = Name_Address
then
return Ritem;
else
Ritem := Next_Rep_Item (Ritem);
end if;
end loop;
return Empty;
end Address_Clause;
----------------------
-- Alignment_Clause --
----------------------
function Alignment_Clause (Id : E) return N is
Ritem : Node_Id;
begin
Ritem := First_Rep_Item (Id);
while Present (Ritem) loop
if Nkind (Ritem) = N_Attribute_Definition_Clause
and then Chars (Ritem) = Name_Alignment
then
return Ritem;
else
Ritem := Next_Rep_Item (Ritem);
end if;
end loop;
return Empty;
end Alignment_Clause;
----------------------
-- Ancestor_Subtype --
----------------------
function Ancestor_Subtype (Id : E) return E is
begin
-- If this is first subtype, or is a base type, then there is no
-- ancestor subtype, so we return Empty to indicate this fact.
if Is_First_Subtype (Id)
or else Id = Base_Type (Id)
then
return Empty;
end if;
declare
D : constant Node_Id := Declaration_Node (Id);
begin
-- If we have a subtype declaration, get the ancestor subtype
if Nkind (D) = N_Subtype_Declaration then
if Nkind (Subtype_Indication (D)) = N_Subtype_Indication then
return Entity (Subtype_Mark (Subtype_Indication (D)));
else
return Entity (Subtype_Indication (D));
end if;
-- If not, then no subtype indication is available
else
return Empty;
end if;
end;
end Ancestor_Subtype;
-------------------
-- Append_Entity --
-------------------
procedure Append_Entity (Id : Entity_Id; V : Entity_Id) is
begin
if Last_Entity (V) = Empty then
Set_First_Entity (V, Id);
else
Set_Next_Entity (Last_Entity (V), Id);
end if;
Set_Next_Entity (Id, Empty);
Set_Scope (Id, V);
Set_Last_Entity (V, Id);
end Append_Entity;
---------------
-- Base_Type --
---------------
function Base_Type (Id : E) return E is
begin
case Ekind (Id) is
when E_Enumeration_Subtype |
E_Signed_Integer_Subtype |
E_Modular_Integer_Subtype |
E_Floating_Point_Subtype |
E_Ordinary_Fixed_Point_Subtype |
E_Decimal_Fixed_Point_Subtype |
E_Array_Subtype |
E_String_Subtype |
E_Record_Subtype |
E_Private_Subtype |
E_Record_Subtype_With_Private |
E_Limited_Private_Subtype |
E_Access_Subtype |
E_Protected_Subtype |
E_Task_Subtype |
E_String_Literal_Subtype |
E_Class_Wide_Subtype =>
return Etype (Id);
when E_Incomplete_Type =>
if Present (Etype (Id)) then
return Etype (Id);
else
return Id;
end if;
when others =>
return Id;
end case;
end Base_Type;
-------------------------
-- Component_Alignment --
-------------------------
-- Component Alignment is encoded using two flags, Flag128/129 as
-- follows. Note that both flags False = Align_Default, so that the
-- default initialization of flags to False initializes component
-- alignment to the default value as required.
-- Flag128 Flag129 Value
-- ------- ------- -----
-- False False Calign_Default
-- False True Calign_Component_Size
-- True False Calign_Component_Size_4
-- True True Calign_Storage_Unit
function Component_Alignment (Id : E) return C is
BT : Node_Id := Base_Type (Id);
begin
pragma Assert (Is_Array_Type (Id) or else Is_Record_Type (Id));
if Flag128 (BT) then
if Flag129 (BT) then
return Calign_Storage_Unit;
else
return Calign_Component_Size_4;
end if;
else
if Flag129 (BT) then
return Calign_Component_Size;
else
return Calign_Default;
end if;
end if;
end Component_Alignment;
--------------------
-- Constant_Value --
--------------------
function Constant_Value (Id : E) return N is
D : constant Node_Id := Declaration_Node (Id);
Full_D : Node_Id;
begin
-- If we have no declaration node, then return no constant value.
-- Not clear how this can happen, but it does sometimes ???
-- To investigate, remove this check and compile discrim_po.adb.
if No (D) then
return Empty;
-- Normal case where a declaration node is present
elsif Nkind (D) = N_Object_Renaming_Declaration then
return Renamed_Object (Id);
-- If this is a component declaration whose entity is constant, it
-- is a prival within a protected function. It does not have
-- a constant value.
elsif Nkind (D) = N_Component_Declaration then
return Empty;
else
if Present (Expression (D)) then
return (Expression (D));
elsif Present (Full_View (Id)) then
Full_D := Parent (Full_View (Id));
-- The full view may have been rewritten as an object renaming.
if Nkind (Full_D) = N_Object_Renaming_Declaration then
return Name (Full_D);
else
return Expression (Full_D);
end if;
else
return Empty;
end if;
end if;
end Constant_Value;
----------------------
-- Declaration_Node --
----------------------
function Declaration_Node (Id : E) return N is
P : Node_Id;
begin
if Ekind (Id) = E_Incomplete_Type
and then Present (Full_View (Id))
then
P := Parent (Full_View (Id));
else
P := Parent (Id);
end if;
loop
if Nkind (P) /= N_Selected_Component
and then Nkind (P) /= N_Expanded_Name
and then
not (Nkind (P) = N_Defining_Program_Unit_Name
and then Is_Child_Unit (Id))
then
return P;
else
P := Parent (P);
end if;
end loop;
end Declaration_Node;
---------------------
-- Designated_Type --
---------------------
function Designated_Type (Id : E) return E is
Desig_Type : E;
begin
Desig_Type := Directly_Designated_Type (Id);
if (Ekind (Desig_Type) = E_Incomplete_Type
and then Present (Full_View (Desig_Type)))
then
return Full_View (Desig_Type);
elsif Is_Class_Wide_Type (Desig_Type)
and then Ekind (Etype (Desig_Type)) = E_Incomplete_Type
and then Present (Full_View (Etype (Desig_Type)))
and then Present (Class_Wide_Type (Full_View (Etype (Desig_Type))))
then
return Class_Wide_Type (Full_View (Etype (Desig_Type)));
else
return Desig_Type;
end if;
end Designated_Type;
-----------------------------
-- Enclosing_Dynamic_Scope --
-----------------------------
function Enclosing_Dynamic_Scope (Id : E) return E is
S : Entity_Id;
begin
S := Scope (Id);
while S /= Standard_Standard
and then not Is_Dynamic_Scope (S)
loop
S := Scope (S);
end loop;
return S;
end Enclosing_Dynamic_Scope;
----------------------
-- Entry_Index_Type --
----------------------
function Entry_Index_Type (Id : E) return N is
begin
pragma Assert (Ekind (Id) = E_Entry_Family);
return Etype (Discrete_Subtype_Definition (Parent (Id)));
end Entry_Index_Type;
---------------------
-- First_Component --
---------------------
function First_Component (Id : E) return E is
Comp_Id : E;
begin
pragma Assert
(Is_Record_Type (Id) or else Is_Incomplete_Or_Private_Type (Id));
Comp_Id := First_Entity (Id);
while Present (Comp_Id) loop
exit when Ekind (Comp_Id) = E_Component;
Comp_Id := Next_Entity (Comp_Id);
end loop;
return Comp_Id;
end First_Component;
------------------------
-- First_Discriminant --
------------------------
function First_Discriminant (Id : E) return E is
Ent : Entity_Id;
begin
pragma Assert
(Has_Discriminants (Id)
or else Has_Unknown_Discriminants (Id));
Ent := First_Entity (Id);
-- The discriminants are not necessarily contiguous, because access
-- discriminants will generate itypes. They are not the first entities
-- either, because tag and controller record must be ahead of them.
if Chars (Ent) = Name_uTag then
Ent := Next_Entity (Ent);
end if;
if Chars (Ent) = Name_uController then
Ent := Next_Entity (Ent);
end if;
-- Skip all hidden girder discriminants if any.
while Present (Ent) loop
exit when Ekind (Ent) = E_Discriminant
and then not Is_Completely_Hidden (Ent);
Ent := Next_Entity (Ent);
end loop;
pragma Assert (Ekind (Ent) = E_Discriminant);
return Ent;
end First_Discriminant;
------------------
-- First_Formal --
------------------
function First_Formal (Id : E) return E is
Formal : E;
begin
pragma Assert
(Is_Overloadable (Id)
or else Ekind (Id) = E_Entry_Family
or else Ekind (Id) = E_Subprogram_Body
or else Ekind (Id) = E_Subprogram_Type);
if Ekind (Id) = E_Enumeration_Literal then
return Empty;
else
Formal := First_Entity (Id);
if Present (Formal) and then Is_Formal (Formal) then
return Formal;
else
return Empty;
end if;
end if;
end First_Formal;
-------------------------------
-- First_Girder_Discriminant --
-------------------------------
function First_Girder_Discriminant (Id : E) return E is
Ent : Entity_Id;
function Has_Completely_Hidden_Discriminant (Id : E) return Boolean;
-- Scans the Discriminants to see whether any are Completely_Hidden
-- (the mechanism for describing non-specified girder discriminants)
function Has_Completely_Hidden_Discriminant (Id : E) return Boolean is
Ent : Entity_Id := Id;
begin
pragma Assert (Ekind (Id) = E_Discriminant);
while Present (Ent) and then Ekind (Ent) = E_Discriminant loop
if Is_Completely_Hidden (Ent) then
return True;
end if;
Ent := Next_Entity (Ent);
end loop;
return False;
end Has_Completely_Hidden_Discriminant;
-- Start of processing for First_Girder_Discriminant
begin
pragma Assert
(Has_Discriminants (Id)
or else Has_Unknown_Discriminants (Id));
Ent := First_Entity (Id);
if Chars (Ent) = Name_uTag then
Ent := Next_Entity (Ent);
end if;
if Chars (Ent) = Name_uController then
Ent := Next_Entity (Ent);
end if;
if Has_Completely_Hidden_Discriminant (Ent) then
while Present (Ent) loop
exit when Is_Completely_Hidden (Ent);
Ent := Next_Entity (Ent);
end loop;
end if;
pragma Assert (Ekind (Ent) = E_Discriminant);
return Ent;
end First_Girder_Discriminant;
-------------------
-- First_Subtype --
-------------------
function First_Subtype (Id : E) return E is
B : constant Entity_Id := Base_Type (Id);
F : constant Node_Id := Freeze_Node (B);
Ent : Entity_Id;
begin
-- If the base type has no freeze node, it is a type in standard,
-- and always acts as its own first subtype unless it is one of
-- the predefined integer types. If the type is formal, it is also
-- a first subtype, and its base type has no freeze node. On the other
-- hand, a subtype of a generic formal is not its own first_subtype.
-- Its base type, if anonymous, is attached to the formal type decl.
-- from which the first subtype is obtained.
if No (F) then
if B = Base_Type (Standard_Integer) then
return Standard_Integer;
elsif B = Base_Type (Standard_Long_Integer) then
return Standard_Long_Integer;
elsif B = Base_Type (Standard_Short_Short_Integer) then
return Standard_Short_Short_Integer;
elsif B = Base_Type (Standard_Short_Integer) then
return Standard_Short_Integer;
elsif B = Base_Type (Standard_Long_Long_Integer) then
return Standard_Long_Long_Integer;
elsif Is_Generic_Type (Id) then
if Present (Parent (B)) then
return Defining_Identifier (Parent (B));
else
return Defining_Identifier (Associated_Node_For_Itype (B));
end if;
else
return B;
end if;
-- Otherwise we check the freeze node, if it has a First_Subtype_Link
-- then we use that link, otherwise (happens with some Itypes), we use
-- the base type itself.
else
Ent := First_Subtype_Link (F);
if Present (Ent) then
return Ent;
else
return B;
end if;
end if;
end First_Subtype;
------------------------
-- Has_Attach_Handler --
------------------------
function Has_Attach_Handler (Id : E) return B is
Ritem : Node_Id;
begin
pragma Assert (Is_Protected_Type (Id));
Ritem := First_Rep_Item (Id);
while Present (Ritem) loop
if Nkind (Ritem) = N_Pragma
and then Chars (Ritem) = Name_Attach_Handler
then
return True;
else
Ritem := Next_Rep_Item (Ritem);
end if;
end loop;
return False;
end Has_Attach_Handler;
-----------------
-- Has_Entries --
-----------------
function Has_Entries (Id : E) return B is
Result : Boolean := False;
Ent : Entity_Id;
begin
pragma Assert (Is_Concurrent_Type (Id));
Ent := First_Entity (Id);
while Present (Ent) loop
if Is_Entry (Ent) then
Result := True;
exit;
end if;
Ent := Next_Entity (Ent);
end loop;
return Result;
end Has_Entries;
----------------------------
-- Has_Foreign_Convention --
----------------------------
function Has_Foreign_Convention (Id : E) return B is
begin
return Convention (Id) >= Foreign_Convention'First;
end Has_Foreign_Convention;
---------------------------
-- Has_Interrupt_Handler --
---------------------------
function Has_Interrupt_Handler (Id : E) return B is
Ritem : Node_Id;
begin
pragma Assert (Is_Protected_Type (Id));
Ritem := First_Rep_Item (Id);
while Present (Ritem) loop
if Nkind (Ritem) = N_Pragma
and then Chars (Ritem) = Name_Interrupt_Handler
then
return True;
else
Ritem := Next_Rep_Item (Ritem);
end if;
end loop;
return False;
end Has_Interrupt_Handler;
--------------------------
-- Has_Private_Ancestor --
--------------------------
function Has_Private_Ancestor (Id : E) return B is
R : constant Entity_Id := Root_Type (Id);
T1 : Entity_Id := Id;
begin
loop
if Is_Private_Type (T1) then
return True;
elsif T1 = R then
return False;
else
T1 := Etype (T1);
end if;
end loop;
end Has_Private_Ancestor;
------------------------------
-- Implementation_Base_Type --
------------------------------
function Implementation_Base_Type (Id : E) return E is
Bastyp : Entity_Id;
Imptyp : Entity_Id;
begin
Bastyp := Base_Type (Id);
if Is_Incomplete_Or_Private_Type (Bastyp) then
Imptyp := Underlying_Type (Bastyp);
-- If we have an implementation type, then just return it,
-- otherwise we return the Base_Type anyway. This can only
-- happen in error situations and should avoid some error bombs.
if Present (Imptyp) then
return Imptyp;
else
return Bastyp;
end if;
else
return Bastyp;
end if;
end Implementation_Base_Type;
-----------------------
-- Is_Always_Inlined --
-----------------------
function Is_Always_Inlined (Id : E) return B is
Item : Node_Id;
begin
Item := First_Rep_Item (Id);
while Present (Item) loop
if Nkind (Item) = N_Pragma
and then Get_Pragma_Id (Chars (Item)) = Pragma_Inline_Always
then
return True;
end if;
Next_Rep_Item (Item);
end loop;
return False;
end Is_Always_Inlined;
---------------------
-- Is_Boolean_Type --
---------------------
function Is_Boolean_Type (Id : E) return B is
begin
return Root_Type (Id) = Standard_Boolean;
end Is_Boolean_Type;
---------------------
-- Is_By_Copy_Type --
---------------------
function Is_By_Copy_Type (Id : E) return B is
begin
-- If Id is a private type whose full declaration has not been seen,
-- we assume for now that it is not a By_Copy type. Clearly this
-- attribute should not be used before the type is frozen, but it is
-- needed to build the associated record of a protected type. Another
-- place where some lookahead for a full view is needed ???
return
Is_Elementary_Type (Id)
or else (Is_Private_Type (Id)
and then Present (Underlying_Type (Id))
and then Is_Elementary_Type (Underlying_Type (Id)));
end Is_By_Copy_Type;
--------------------------
-- Is_By_Reference_Type --
--------------------------
function Is_By_Reference_Type (Id : E) return B is
Btype : constant Entity_Id := Base_Type (Id);
begin
if Error_Posted (Id)
or else Error_Posted (Btype)
then
return False;
elsif Is_Private_Type (Btype) then
declare
Utyp : constant Entity_Id := Underlying_Type (Btype);
begin
if No (Utyp) then
return False;
else
return Is_By_Reference_Type (Utyp);
end if;
end;
elsif Is_Concurrent_Type (Btype) then
return True;
elsif Is_Record_Type (Btype) then
if Is_Limited_Record (Btype)
or else Is_Tagged_Type (Btype)
or else Is_Volatile (Btype)
then
return True;
else
declare
C : Entity_Id := First_Component (Btype);
begin
while Present (C) loop
if Is_By_Reference_Type (Etype (C))
or else Is_Volatile (Etype (C))
then
return True;
end if;
C := Next_Component (C);
end loop;
end;
return False;
end if;
elsif Is_Array_Type (Btype) then
return
Is_Volatile (Btype)
or else Is_By_Reference_Type (Component_Type (Btype))
or else Is_Volatile (Component_Type (Btype))
or else Has_Volatile_Components (Btype);
else
return False;
end if;
end Is_By_Reference_Type;
---------------------
-- Is_Derived_Type --
---------------------
function Is_Derived_Type (Id : E) return B is
Par : Node_Id;
begin
if Base_Type (Id) /= Root_Type (Id)
and then not Is_Generic_Type (Id)
and then not Is_Class_Wide_Type (Id)
then
if not Is_Numeric_Type (Root_Type (Id)) then
return True;
else
Par := Parent (First_Subtype (Id));
return Present (Par)
and then Nkind (Par) = N_Full_Type_Declaration
and then Nkind (Type_Definition (Par))
= N_Derived_Type_Definition;
end if;
else
return False;
end if;
end Is_Derived_Type;
----------------------
-- Is_Dynamic_Scope --
----------------------
function Is_Dynamic_Scope (Id : E) return B is
begin
return
Ekind (Id) = E_Block
or else
Ekind (Id) = E_Function
or else
Ekind (Id) = E_Procedure
or else
Ekind (Id) = E_Subprogram_Body
or else
Ekind (Id) = E_Task_Type
or else
Ekind (Id) = E_Entry
or else
Ekind (Id) = E_Entry_Family;
end Is_Dynamic_Scope;
--------------------
-- Is_Entity_Name --
--------------------
function Is_Entity_Name (N : Node_Id) return Boolean is
Kind : constant Node_Kind := Nkind (N);
begin
-- Identifiers, operator symbols, expanded names are entity names
return Kind = N_Identifier
or else Kind = N_Operator_Symbol
or else Kind = N_Expanded_Name
-- Attribute references are entity names if they refer to an entity.
-- Note that we don't do this by testing for the presence of the
-- Entity field in the N_Attribute_Reference node, since it may not
-- have been set yet.
or else (Kind = N_Attribute_Reference
and then Is_Entity_Attribute_Name (Attribute_Name (N)));
end Is_Entity_Name;
---------------------------
-- Is_Indefinite_Subtype --
---------------------------
function Is_Indefinite_Subtype (Id : Entity_Id) return B is
K : constant Entity_Kind := Ekind (Id);
begin
if Is_Constrained (Id) then
return False;
elsif K in Array_Kind
or else K in Class_Wide_Kind
or else Has_Unknown_Discriminants (Id)
then
return True;
-- Known discriminants: indefinite if there are no default values
elsif K in Record_Kind
or else Is_Incomplete_Or_Private_Type (Id)
or else Is_Concurrent_Type (Id)
then
return (Has_Discriminants (Id)
and then No (Discriminant_Default_Value (First_Discriminant (Id))));
else
return False;
end if;
end Is_Indefinite_Subtype;
---------------------
-- Is_Limited_Type --
---------------------
function Is_Limited_Type (Id : E) return B is
Btype : constant E := Base_Type (Id);
begin
if not Is_Type (Id) then
return False;
elsif Ekind (Btype) = E_Limited_Private_Type
or else Is_Limited_Composite (Btype)
then
return True;
elsif Is_Concurrent_Type (Btype) then
return True;
-- Otherwise we will look around to see if there is some other reason
-- for it to be limited, except that if an error was posted on the
-- entity, then just assume it is non-limited, because it can cause
-- trouble to recurse into a murky erroneous entity!
elsif Error_Posted (Id) then
return False;
elsif Is_Record_Type (Btype) then
if Is_Limited_Record (Root_Type (Btype)) then
return True;
elsif Is_Class_Wide_Type (Btype) then
return Is_Limited_Type (Root_Type (Btype));
else
declare
C : E := First_Component (Btype);
begin
while Present (C) loop
if Is_Limited_Type (Etype (C)) then
return True;
end if;
C := Next_Component (C);
end loop;
end;
return False;
end if;
elsif Is_Array_Type (Btype) then
return Is_Limited_Type (Component_Type (Btype));
else
return False;
end if;
end Is_Limited_Type;
----------------
-- Is_Package --
----------------
function Is_Package (Id : E) return B is
begin
return
Ekind (Id) = E_Package
or else
Ekind (Id) = E_Generic_Package;
end Is_Package;
--------------------------
-- Is_Protected_Private --
--------------------------
function Is_Protected_Private (Id : E) return B is
begin
pragma Assert (Ekind (Id) = E_Component);
return Is_Protected_Type (Scope (Id));
end Is_Protected_Private;
------------------------------
-- Is_Protected_Record_Type --
------------------------------
function Is_Protected_Record_Type (Id : E) return B is
begin
return
Is_Concurrent_Record_Type (Id)
and then Is_Protected_Type (Corresponding_Concurrent_Type (Id));
end Is_Protected_Record_Type;
---------------------------------
-- Is_Return_By_Reference_Type --
---------------------------------
function Is_Return_By_Reference_Type (Id : E) return B is
Btype : constant Entity_Id := Base_Type (Id);
begin
if Is_Private_Type (Btype) then
declare
Utyp : constant Entity_Id := Underlying_Type (Btype);
begin
if No (Utyp) then
return False;
else
return Is_Return_By_Reference_Type (Utyp);
end if;
end;
elsif Is_Concurrent_Type (Btype) then
return True;
elsif Is_Record_Type (Btype) then
if Is_Limited_Record (Btype) then
return True;
elsif Is_Class_Wide_Type (Btype) then
return Is_Return_By_Reference_Type (Root_Type (Btype));
else
declare
C : Entity_Id := First_Component (Btype);
begin
while Present (C) loop
if Is_Return_By_Reference_Type (Etype (C)) then
return True;
end if;
C := Next_Component (C);
end loop;
end;
return False;
end if;
elsif Is_Array_Type (Btype) then
return Is_Return_By_Reference_Type (Component_Type (Btype));
else
return False;
end if;
end Is_Return_By_Reference_Type;
--------------------
-- Is_String_Type --
--------------------
function Is_String_Type (Id : E) return B is
begin
return Ekind (Id) in String_Kind
or else (Is_Array_Type (Id)
and then Number_Dimensions (Id) = 1
and then Is_Character_Type (Component_Type (Id)));
end Is_String_Type;
-------------------------
-- Is_Task_Record_Type --
-------------------------
function Is_Task_Record_Type (Id : E) return B is
begin
return
Is_Concurrent_Record_Type (Id)
and then Is_Task_Type (Corresponding_Concurrent_Type (Id));
end Is_Task_Record_Type;
------------------------
-- Is_Wrapper_Package --
------------------------
function Is_Wrapper_Package (Id : E) return B is
begin
return (Ekind (Id) = E_Package
and then Present (Related_Instance (Id)));
end Is_Wrapper_Package;
--------------------
-- Next_Component --
--------------------
function Next_Component (Id : E) return E is
Comp_Id : E;
begin
Comp_Id := Next_Entity (Id);
while Present (Comp_Id) loop
exit when Ekind (Comp_Id) = E_Component;
Comp_Id := Next_Entity (Comp_Id);
end loop;
return Comp_Id;
end Next_Component;
-----------------------
-- Next_Discriminant --
-----------------------
-- This function actually implements both Next_Discriminant and
-- Next_Girder_Discriminant by making sure that the Discriminant
-- returned is of the same variety as Id.
function Next_Discriminant (Id : E) return E is
-- Derived Tagged types with private extensions look like this...
--
-- E_Discriminant d1
-- E_Discriminant d2
-- E_Component _tag
-- E_Discriminant d1
-- E_Discriminant d2
-- ...
-- so it is critical not to go past the leading discriminants.
D : E := Id;
begin
pragma Assert (Ekind (Id) = E_Discriminant);
loop
D := Next_Entity (D);
if not Present (D)
or else (Ekind (D) /= E_Discriminant
and then not Is_Itype (D))
then
return Empty;
end if;
exit when Ekind (D) = E_Discriminant
and then (Is_Completely_Hidden (D) = Is_Completely_Hidden (Id));
end loop;
return D;
end Next_Discriminant;
-----------------
-- Next_Formal --
-----------------
function Next_Formal (Id : E) return E is
P : E;
begin
-- Follow the chain of declared entities as long as the kind of
-- the entity corresponds to a formal parameter. Skip internal
-- entities that may have been created for implicit subtypes,
-- in the process of analyzing default expressions.
P := Id;
loop
P := Next_Entity (P);
if No (P) or else Is_Formal (P) then
return P;
elsif not Is_Internal (P) then
return Empty;
end if;
end loop;
end Next_Formal;
-----------------------------
-- Next_Formal_With_Extras --
-----------------------------
function Next_Formal_With_Extras (Id : E) return E is
begin
if Present (Extra_Formal (Id)) then
return Extra_Formal (Id);
else
return Next_Formal (Id);
end if;
end Next_Formal_With_Extras;
------------------------------
-- Next_Girder_Discriminant --
------------------------------
function Next_Girder_Discriminant (Id : E) return E is
begin
-- See comment in Next_Discriminant
return Next_Discriminant (Id);
end Next_Girder_Discriminant;
----------------
-- Next_Index --
----------------
function Next_Index (Id : Node_Id) return Node_Id is
begin
return Next (Id);
end Next_Index;
------------------
-- Next_Literal --
------------------
function Next_Literal (Id : E) return E is
begin
pragma Assert (Nkind (Id) in N_Entity);
return Next (Id);
end Next_Literal;
-----------------------
-- Number_Dimensions --
-----------------------
function Number_Dimensions (Id : E) return Pos is
N : Int;
T : Node_Id;
begin
if Ekind (Id) in String_Kind then
return 1;
else
N := 0;
T := First_Index (Id);
while Present (T) loop
N := N + 1;
T := Next (T);
end loop;
return N;
end if;
end Number_Dimensions;
--------------------------
-- Number_Discriminants --
--------------------------
function Number_Discriminants (Id : E) return Pos is
N : Int;
Discr : Entity_Id;
begin
N := 0;
Discr := First_Discriminant (Id);
while Present (Discr) loop
N := N + 1;
Discr := Next_Discriminant (Discr);
end loop;
return N;
end Number_Discriminants;
--------------------
-- Number_Entries --
--------------------
function Number_Entries (Id : E) return Nat is
N : Int;
Ent : Entity_Id;
begin
pragma Assert (Is_Concurrent_Type (Id));
N := 0;
Ent := First_Entity (Id);
while Present (Ent) loop
if Is_Entry (Ent) then
N := N + 1;
end if;
Ent := Next_Entity (Ent);
end loop;
return N;
end Number_Entries;
--------------------
-- Number_Formals --
--------------------
function Number_Formals (Id : E) return Pos is
N : Int;
Formal : Entity_Id;
begin
N := 0;
Formal := First_Formal (Id);
while Present (Formal) loop
N := N + 1;
Formal := Next_Formal (Formal);
end loop;
return N;
end Number_Formals;
--------------------
-- Parameter_Mode --
--------------------
function Parameter_Mode (Id : E) return Formal_Kind is
begin
return Ekind (Id);
end Parameter_Mode;
---------------
-- Root_Type --
---------------
function Root_Type (Id : E) return E is
T, Etyp : E;
begin
pragma Assert (Nkind (Id) in N_Entity);
T := Base_Type (Id);
if Ekind (T) = E_Class_Wide_Type then
return Etype (T);
-- All other cases
else
loop
Etyp := Etype (T);
if T = Etyp then
return T;
elsif Is_Private_Type (T) and then Etyp = Full_View (T) then
return T;
elsif Is_Private_Type (Etyp) and then Full_View (Etyp) = T then
return T;
end if;
T := Etyp;
end loop;
end if;
raise Program_Error;
end Root_Type;
-----------------
-- Scope_Depth --
-----------------
function Scope_Depth (Id : E) return Uint is
Scop : Entity_Id := Id;
begin
while Is_Record_Type (Scop) loop
Scop := Scope (Scop);
end loop;
return Scope_Depth_Value (Scop);
end Scope_Depth;
---------------------
-- Scope_Depth_Set --
---------------------
function Scope_Depth_Set (Id : E) return B is
begin
return not Is_Record_Type (Id)
and then Field22 (Id) /= Union_Id (Empty);
end Scope_Depth_Set;
-----------------------------
-- Set_Component_Alignment --
-----------------------------
-- Component Alignment is encoded using two flags, Flag128/129 as
-- follows. Note that both flags False = Align_Default, so that the
-- default initialization of flags to False initializes component
-- alignment to the default value as required.
-- Flag128 Flag129 Value
-- ------- ------- -----
-- False False Calign_Default
-- False True Calign_Component_Size
-- True False Calign_Component_Size_4
-- True True Calign_Storage_Unit
procedure Set_Component_Alignment (Id : E; V : C) is
begin
pragma Assert ((Is_Array_Type (Id) or else Is_Record_Type (Id))
and then Id = Base_Type (Id));
case V is
when Calign_Default =>
Set_Flag128 (Id, False);
Set_Flag129 (Id, False);
when Calign_Component_Size =>
Set_Flag128 (Id, False);
Set_Flag129 (Id, True);
when Calign_Component_Size_4 =>
Set_Flag128 (Id, True);
Set_Flag129 (Id, False);
when Calign_Storage_Unit =>
Set_Flag128 (Id, True);
Set_Flag129 (Id, True);
end case;
end Set_Component_Alignment;
-----------------
-- Size_Clause --
-----------------
function Size_Clause (Id : E) return N is
Ritem : Node_Id;
begin
Ritem := First_Rep_Item (Id);
while Present (Ritem) loop
if Nkind (Ritem) = N_Attribute_Definition_Clause
and then Chars (Ritem) = Name_Size
then
return Ritem;
else
Ritem := Next_Rep_Item (Ritem);
end if;
end loop;
return Empty;
end Size_Clause;
------------------
-- Subtype_Kind --
------------------
function Subtype_Kind (K : Entity_Kind) return Entity_Kind is
Kind : Entity_Kind;
begin
case K is
when Access_Kind =>
Kind := E_Access_Subtype;
when E_Array_Type |
E_Array_Subtype =>
Kind := E_Array_Subtype;
when E_Class_Wide_Type |
E_Class_Wide_Subtype =>
Kind := E_Class_Wide_Subtype;
when E_Decimal_Fixed_Point_Type |
E_Decimal_Fixed_Point_Subtype =>
Kind := E_Decimal_Fixed_Point_Subtype;
when E_Ordinary_Fixed_Point_Type |
E_Ordinary_Fixed_Point_Subtype =>
Kind := E_Ordinary_Fixed_Point_Subtype;
when E_Private_Type |
E_Private_Subtype =>
Kind := E_Private_Subtype;
when E_Limited_Private_Type |
E_Limited_Private_Subtype =>
Kind := E_Limited_Private_Subtype;
when E_Record_Type_With_Private |
E_Record_Subtype_With_Private =>
Kind := E_Record_Subtype_With_Private;
when E_Record_Type |
E_Record_Subtype =>
Kind := E_Record_Subtype;
when E_String_Type |
E_String_Subtype =>
Kind := E_String_Subtype;
when Enumeration_Kind =>
Kind := E_Enumeration_Subtype;
when Float_Kind =>
Kind := E_Floating_Point_Subtype;
when Signed_Integer_Kind =>
Kind := E_Signed_Integer_Subtype;
when Modular_Integer_Kind =>
Kind := E_Modular_Integer_Subtype;
when Protected_Kind =>
Kind := E_Protected_Subtype;
when Task_Kind =>
Kind := E_Task_Subtype;
when others =>
Kind := E_Void;
raise Program_Error;
end case;
return Kind;
end Subtype_Kind;
-------------------
-- Tag_Component --
-------------------
function Tag_Component (Id : E) return E is
Comp : Entity_Id;
Typ : Entity_Id := Id;
begin
pragma Assert (Is_Tagged_Type (Typ));
if Is_Class_Wide_Type (Typ) then
Typ := Root_Type (Typ);
end if;
if Is_Private_Type (Typ) then
Typ := Underlying_Type (Typ);
end if;
Comp := First_Entity (Typ);
while Present (Comp) loop
if Is_Tag (Comp) then
return Comp;
end if;
Comp := Next_Entity (Comp);
end loop;
-- No tag component found
return Empty;
end Tag_Component;
---------------------
-- Type_High_Bound --
---------------------
function Type_High_Bound (Id : E) return Node_Id is
begin
if Nkind (Scalar_Range (Id)) = N_Subtype_Indication then
return High_Bound (Range_Expression (Constraint (Scalar_Range (Id))));
else
return High_Bound (Scalar_Range (Id));
end if;
end Type_High_Bound;
--------------------
-- Type_Low_Bound --
--------------------
function Type_Low_Bound (Id : E) return Node_Id is
begin
if Nkind (Scalar_Range (Id)) = N_Subtype_Indication then
return Low_Bound (Range_Expression (Constraint (Scalar_Range (Id))));
else
return Low_Bound (Scalar_Range (Id));
end if;
end Type_Low_Bound;
---------------------
-- Underlying_Type --
---------------------
function Underlying_Type (Id : E) return E is
begin
-- For record_with_private the underlying type is always the direct
-- full view. Never try to take the full view of the parent it
-- doesn't make sense.
if Ekind (Id) = E_Record_Type_With_Private then
return Full_View (Id);
elsif Ekind (Id) in Incomplete_Or_Private_Kind then
-- If we have an incomplete or private type with a full view,
-- then we return the Underlying_Type of this full view
if Present (Full_View (Id)) then
return Underlying_Type (Full_View (Id));
-- Otherwise check for the case where we have a derived type or
-- subtype, and if so get the Underlying_Type of the parent type.
elsif Etype (Id) /= Id then
return Underlying_Type (Etype (Id));
-- Otherwise we have an incomplete or private type that has
-- no full view, which means that we have not encountered the
-- completion, so return Empty to indicate the underlying type
-- is not yet known.
else
return Empty;
end if;
-- For non-incomplete, non-private types, return the type itself
-- Also for entities that are not types at all return the entity
-- itself.
else
return Id;
end if;
end Underlying_Type;
------------------------
-- Write_Entity_Flags --
------------------------
procedure Write_Entity_Flags (Id : Entity_Id; Prefix : String) is
procedure W (Flag_Name : String; Flag : Boolean);
-- Write out given flag if it is set
procedure W (Flag_Name : String; Flag : Boolean) is
begin
if Flag then
Write_Str (Prefix);
Write_Str (Flag_Name);
Write_Str (" = True");
Write_Eol;
end if;
end W;
-- Start of processing for Write_Entity_Flags
begin
if (Is_Array_Type (Id) or else Is_Record_Type (Id))
and then Base_Type (Id) = Id
then
Write_Str (Prefix);
Write_Str ("Component_Alignment = ");
case Component_Alignment (Id) is
when Calign_Default =>
Write_Str ("Calign_Default");
when Calign_Component_Size =>
Write_Str ("Calign_Component_Size");
when Calign_Component_Size_4 =>
Write_Str ("Calign_Component_Size_4");
when Calign_Storage_Unit =>
Write_Str ("Calign_Storage_Unit");
end case;
Write_Eol;
end if;
W ("Address_Taken", Flag104 (Id));
W ("C_Pass_By_Copy", Flag125 (Id));
W ("Debug_Info_Off", Flag166 (Id));
W ("Default_Expressions_Processed", Flag108 (Id));
W ("Delay_Cleanups", Flag114 (Id));
W ("Delay_Subprogram_Descriptors", Flag50 (Id));
W ("Depends_On_Private", Flag14 (Id));
W ("Discard_Names", Flag88 (Id));
W ("Elaborate_All_Desirable", Flag146 (Id));
W ("Elaboration_Entity_Required", Flag174 (Id));
W ("Entry_Accepted", Flag152 (Id));
W ("Finalize_Storage_Only", Flag158 (Id));
W ("From_With_Type", Flag159 (Id));
W ("Function_Returns_With_DSP", Flag169 (Id));
W ("Has_Aliased_Components", Flag135 (Id));
W ("Has_Alignment_Clause", Flag46 (Id));
W ("Has_All_Calls_Remote", Flag79 (Id));
W ("Has_Atomic_Components", Flag86 (Id));
W ("Has_Biased_Representation", Flag139 (Id));
W ("Has_Completion", Flag26 (Id));
W ("Has_Completion_In_Body", Flag71 (Id));
W ("Has_Complex_Representation", Flag140 (Id));
W ("Has_Component_Size_Clause", Flag68 (Id));
W ("Has_Controlled_Component", Flag43 (Id));
W ("Has_Controlling_Result", Flag98 (Id));
W ("Has_Convention_Pragma", Flag119 (Id));
W ("Has_Delayed_Freeze", Flag18 (Id));
W ("Has_Discriminants", Flag5 (Id));
W ("Has_Enumeration_Rep_Clause", Flag66 (Id));
W ("Has_Exit", Flag47 (Id));
W ("Has_External_Tag_Rep_Clause", Flag110 (Id));
W ("Has_Forward_Instantiation", Flag175 (Id));
W ("Has_Fully_Qualified_Name", Flag173 (Id));
W ("Has_Gigi_Rep_Item", Flag82 (Id));
W ("Has_Homonym", Flag56 (Id));
W ("Has_Machine_Radix_Clause", Flag83 (Id));
W ("Has_Master_Entity", Flag21 (Id));
W ("Has_Missing_Return", Flag142 (Id));
W ("Has_Nested_Block_With_Handler", Flag101 (Id));
W ("Has_Non_Standard_Rep", Flag75 (Id));
W ("Has_Object_Size_Clause", Flag172 (Id));
W ("Has_Per_Object_Constraint", Flag154 (Id));
W ("Has_Pragma_Controlled", Flag27 (Id));
W ("Has_Pragma_Elaborate_Body", Flag150 (Id));
W ("Has_Pragma_Inline", Flag157 (Id));
W ("Has_Pragma_Pack", Flag121 (Id));
W ("Has_Pragma_Pure_Function", Flag179 (Id));
W ("Has_Primitive_Operations", Flag120 (Id));
W ("Has_Private_Declaration", Flag155 (Id));
W ("Has_Qualified_Name", Flag161 (Id));
W ("Has_Record_Rep_Clause", Flag65 (Id));
W ("Has_Recursive_Call", Flag143 (Id));
W ("Has_Size_Clause", Flag29 (Id));
W ("Has_Small_Clause", Flag67 (Id));
W ("Has_Specified_Layout", Flag100 (Id));
W ("Has_Storage_Size_Clause", Flag23 (Id));
W ("Has_Subprogram_Descriptor", Flag93 (Id));
W ("Has_Task", Flag30 (Id));
W ("Has_Unchecked_Union", Flag123 (Id));
W ("Has_Unknown_Discriminants", Flag72 (Id));
W ("Has_Volatile_Components", Flag87 (Id));
W ("In_Package_Body", Flag48 (Id));
W ("In_Private_Part", Flag45 (Id));
W ("In_Use", Flag8 (Id));
W ("Is_AST_Entry", Flag132 (Id));
W ("Is_Abstract", Flag19 (Id));
W ("Is_Access_Constant", Flag69 (Id));
W ("Is_Aliased", Flag15 (Id));
W ("Is_Asynchronous", Flag81 (Id));
W ("Is_Atomic", Flag85 (Id));
W ("Is_Bit_Packed_Array", Flag122 (Id));
W ("Is_CPP_Class", Flag74 (Id));
W ("Is_Called", Flag102 (Id));
W ("Is_Character_Type", Flag63 (Id));
W ("Is_Child_Unit", Flag73 (Id));
W ("Is_Compilation_Unit", Flag149 (Id));
W ("Is_Completely_Hidden", Flag103 (Id));
W ("Is_Concurrent_Record_Type", Flag20 (Id));
W ("Is_Constr_Subt_For_UN_Aliased", Flag141 (Id));
W ("Is_Constr_Subt_For_U_Nominal", Flag80 (Id));
W ("Is_Constrained", Flag12 (Id));
W ("Is_Constructor", Flag76 (Id));
W ("Is_Controlled", Flag42 (Id));
W ("Is_Controlling_Formal", Flag97 (Id));
W ("Is_Destructor", Flag77 (Id));
W ("Is_Discrim_SO_Function", Flag176 (Id));
W ("Is_Dispatching_Operation", Flag6 (Id));
W ("Is_Eliminated", Flag124 (Id));
W ("Is_Entry_Formal", Flag52 (Id));
W ("Is_Exported", Flag99 (Id));
W ("Is_First_Subtype", Flag70 (Id));
W ("Is_For_Access_Subtype", Flag118 (Id));
W ("Is_Formal_Subprogram", Flag111 (Id));
W ("Is_Frozen", Flag4 (Id));
W ("Is_Generic_Actual_Type", Flag94 (Id));
W ("Is_Generic_Instance", Flag130 (Id));
W ("Is_Generic_Type", Flag13 (Id));
W ("Is_Hidden", Flag57 (Id));
W ("Is_Hidden_Open_Scope", Flag171 (Id));
W ("Is_Immediately_Visible", Flag7 (Id));
W ("Is_Imported", Flag24 (Id));
W ("Is_Inlined", Flag11 (Id));
W ("Is_Instantiated", Flag126 (Id));
W ("Is_Internal", Flag17 (Id));
W ("Is_Interrupt_Handler", Flag89 (Id));
W ("Is_Intrinsic_Subprogram", Flag64 (Id));
W ("Is_Itype", Flag91 (Id));
W ("Is_Known_Valid", Flag170 (Id));
W ("Is_Limited_Composite", Flag106 (Id));
W ("Is_Limited_Record", Flag25 (Id));
W ("Is_Non_Static_Subtype", Flag109 (Id));
W ("Is_Null_Init_Proc", Flag178 (Id));
W ("Is_Optional_Parameter", Flag134 (Id));
W ("Is_Package_Body_Entity", Flag160 (Id));
W ("Is_Packed", Flag51 (Id));
W ("Is_Packed_Array_Type", Flag138 (Id));
W ("Is_Potentially_Use_Visible", Flag9 (Id));
W ("Is_Preelaborated", Flag59 (Id));
W ("Is_Private_Composite", Flag107 (Id));
W ("Is_Private_Descendant", Flag53 (Id));
W ("Is_Psected", Flag153 (Id));
W ("Is_Public", Flag10 (Id));
W ("Is_Pure", Flag44 (Id));
W ("Is_Remote_Call_Interface", Flag62 (Id));
W ("Is_Remote_Types", Flag61 (Id));
W ("Is_Renaming_Of_Object", Flag112 (Id));
W ("Is_Shared_Passive", Flag60 (Id));
W ("Is_Statically_Allocated", Flag28 (Id));
W ("Is_Tag", Flag78 (Id));
W ("Is_Tagged_Type", Flag55 (Id));
W ("Is_True_Constant", Flag163 (Id));
W ("Is_Unchecked_Union", Flag117 (Id));
W ("Is_Unsigned_Type", Flag144 (Id));
W ("Is_VMS_Exception", Flag133 (Id));
W ("Is_Valued_Procedure", Flag127 (Id));
W ("Is_Visible_Child_Unit", Flag116 (Id));
W ("Is_Volatile", Flag16 (Id));
W ("Machine_Radix_10", Flag84 (Id));
W ("Materialize_Entity", Flag168 (Id));
W ("Needs_Debug_Info", Flag147 (Id));
W ("Needs_No_Actuals", Flag22 (Id));
W ("No_Pool_Assigned", Flag131 (Id));
W ("No_Return", Flag113 (Id));
W ("Non_Binary_Modulus", Flag58 (Id));
W ("Nonzero_Is_True", Flag162 (Id));
W ("Not_Source_Assigned", Flag115 (Id));
W ("Reachable", Flag49 (Id));
W ("Referenced", Flag156 (Id));
W ("Return_Present", Flag54 (Id));
W ("Returns_By_Ref", Flag90 (Id));
W ("Reverse_Bit_Order", Flag164 (Id));
W ("Sec_Stack_Needed_For_Return", Flag167 (Id));
W ("Size_Depends_On_Discriminant", Flag177 (Id));
W ("Size_Known_At_Compile_Time", Flag92 (Id));
W ("Strict_Alignment", Flag145 (Id));
W ("Suppress_Access_Checks", Flag31 (Id));
W ("Suppress_Accessibility_Checks", Flag32 (Id));
W ("Suppress_Discriminant_Checks", Flag33 (Id));
W ("Suppress_Division_Checks", Flag34 (Id));
W ("Suppress_Elaboration_Checks", Flag35 (Id));
W ("Suppress_Elaboration_Warnings", Flag148 (Id));
W ("Suppress_Index_Checks", Flag36 (Id));
W ("Suppress_Init_Proc", Flag105 (Id));
W ("Suppress_Length_Checks", Flag37 (Id));
W ("Suppress_Overflow_Checks", Flag38 (Id));
W ("Suppress_Range_Checks", Flag39 (Id));
W ("Suppress_Storage_Checks", Flag40 (Id));
W ("Suppress_Style_Checks", Flag165 (Id));
W ("Suppress_Tag_Checks", Flag41 (Id));
W ("Uses_Sec_Stack", Flag95 (Id));
W ("Vax_Float", Flag151 (Id));
W ("Warnings_Off", Flag96 (Id));
end Write_Entity_Flags;
-----------------------
-- Write_Entity_Info --
-----------------------
procedure Write_Entity_Info (Id : Entity_Id; Prefix : String) is
procedure Write_Attribute (Which : String; Nam : E);
-- Write attribute value with given string name
procedure Write_Kind (Id : Entity_Id);
-- Write Ekind field of entity
procedure Write_Attribute (Which : String; Nam : E) is
begin
Write_Str (Prefix);
Write_Str (Which);
Write_Int (Int (Nam));
Write_Str (" ");
Write_Name (Chars (Nam));
Write_Str (" ");
end Write_Attribute;
procedure Write_Kind (Id : Entity_Id) is
K : constant String := Entity_Kind'Image (Ekind (Id));
begin
Write_Str (Prefix);
Write_Str (" Kind ");
if Is_Type (Id) and then Is_Tagged_Type (Id) then
Write_Str ("TAGGED ");
end if;
Write_Str (K (3 .. K'Length));
Write_Str (" ");
if Is_Type (Id) and then Depends_On_Private (Id) then
Write_Str ("Depends_On_Private ");
end if;
end Write_Kind;
-- Start of processing for Write_Entity_Info
begin
Write_Eol;
Write_Attribute ("Name ", Id);
Write_Int (Int (Id));
Write_Eol;
Write_Kind (Id);
Write_Eol;
Write_Attribute (" Type ", Etype (Id));
Write_Eol;
Write_Attribute (" Scope ", Scope (Id));
Write_Eol;
case Ekind (Id) is
when Discrete_Kind =>
Write_Str ("Bounds: Id = ");
if Present (Scalar_Range (Id)) then
Write_Int (Int (Type_Low_Bound (Id)));
Write_Str (" .. Id = ");
Write_Int (Int (Type_High_Bound (Id)));
else
Write_Str ("Empty");
end if;
Write_Eol;
when Array_Kind =>
declare
Index : E;
begin
Write_Attribute (" Component Type ",
Component_Type (Id));
Write_Eol;
Write_Str (Prefix);
Write_Str (" Indices ");
Index := First_Index (Id);
while Present (Index) loop
Write_Attribute (" ", Etype (Index));
Index := Next_Index (Index);
end loop;
Write_Eol;
end;
when Access_Kind =>
Write_Attribute
(" Directly Designated Type ",
Directly_Designated_Type (Id));
Write_Eol;
when Overloadable_Kind =>
if Present (Homonym (Id)) then
Write_Str (" Homonym ");
Write_Name (Chars (Homonym (Id)));
Write_Str (" ");
Write_Int (Int (Homonym (Id)));
Write_Eol;
end if;
Write_Eol;
when E_Component =>
if Ekind (Scope (Id)) in Record_Kind then
Write_Attribute (
" Original_Record_Component ",
Original_Record_Component (Id));
Write_Int (Int (Original_Record_Component (Id)));
Write_Eol;
end if;
when others => null;
end case;
end Write_Entity_Info;
-----------------------
-- Write_Field6_Name --
-----------------------
procedure Write_Field6_Name (Id : Entity_Id) is
begin
Write_Str ("First_Rep_Item");
end Write_Field6_Name;
-----------------------
-- Write_Field7_Name --
-----------------------
procedure Write_Field7_Name (Id : Entity_Id) is
begin
Write_Str ("Freeze_Node");
end Write_Field7_Name;
-----------------------
-- Write_Field8_Name --
-----------------------
procedure Write_Field8_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when E_Component |
E_Discriminant =>
Write_Str ("Normalized_First_Bit");
when Formal_Kind |
E_Function =>
Write_Str ("Mechanism");
when Type_Kind =>
Write_Str ("Associated_Node_For_Itype");
when E_Package =>
Write_Str ("Dependent_Instances");
when E_Variable =>
Write_Str ("Hiding_Loop_Variable");
when others =>
Write_Str ("Field8??");
end case;
end Write_Field8_Name;
-----------------------
-- Write_Field9_Name --
-----------------------
procedure Write_Field9_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Type_Kind =>
Write_Str ("Class_Wide_Type");
when E_Constant | E_Variable =>
Write_Str ("Size_Check_Code");
when E_Function |
E_Generic_Function |
E_Generic_Package |
E_Generic_Procedure |
E_Package |
E_Procedure =>
Write_Str ("Renaming_Map");
when E_Component |
E_Discriminant =>
Write_Str ("Normalized_Position");
when others =>
Write_Str ("Field9??");
end case;
end Write_Field9_Name;
------------------------
-- Write_Field10_Name --
------------------------
procedure Write_Field10_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Type_Kind =>
Write_Str ("Referenced_Object");
when E_In_Parameter |
E_Constant =>
Write_Str ("Discriminal_Link");
when E_Function |
E_Package |
E_Package_Body |
E_Procedure =>
Write_Str ("Handler_Records");
when E_Component |
E_Discriminant =>
Write_Str ("Normalized_Position_Max");
when others =>
Write_Str ("Field10??");
end case;
end Write_Field10_Name;
------------------------
-- Write_Field11_Name --
------------------------
procedure Write_Field11_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Formal_Kind =>
Write_Str ("Entry_Component");
when E_Component |
E_Discriminant =>
Write_Str ("Component_Bit_Offset");
when E_Constant =>
Write_Str ("Full_View");
when E_Enumeration_Literal =>
Write_Str ("Enumeration_Pos");
when E_Block =>
Write_Str ("Block_Node");
when E_Function |
E_Procedure |
E_Entry |
E_Entry_Family =>
Write_Str ("Protected_Body_Subprogram");
when Type_Kind =>
Write_Str ("Full_View");
when others =>
Write_Str ("Field11??");
end case;
end Write_Field11_Name;
------------------------
-- Write_Field12_Name --
------------------------
procedure Write_Field12_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Entry_Kind =>
Write_Str ("Barrier_Function");
when E_Enumeration_Literal =>
Write_Str ("Enumeration_Rep");
when Type_Kind |
E_Component |
E_Constant |
E_Discriminant |
E_In_Parameter |
E_In_Out_Parameter |
E_Out_Parameter |
E_Loop_Parameter |
E_Variable =>
Write_Str ("Esize");
when E_Function |
E_Procedure =>
Write_Str ("Next_Inlined_Subprogram");
when E_Package =>
Write_Str ("Associated_Formal_Package");
when others =>
Write_Str ("Field12??");
end case;
end Write_Field12_Name;
------------------------
-- Write_Field13_Name --
------------------------
procedure Write_Field13_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Type_Kind =>
Write_Str ("RM_Size");
when E_Component |
E_Discriminant =>
Write_Str ("Component_Clause");
when E_Enumeration_Literal =>
Write_Str ("Debug_Renaming_Link");
when E_Function =>
if not Comes_From_Source (Id)
and then
Chars (Id) = Name_Op_Ne
then
Write_Str ("Corresponding_Equality");
elsif Comes_From_Source (Id) then
Write_Str ("Elaboration_Entity");
else
Write_Str ("Field13??");
end if;
when Formal_Kind |
E_Variable =>
Write_Str ("Extra_Accessibility");
when E_Procedure |
E_Package |
Generic_Unit_Kind =>
Write_Str ("Elaboration_Entity");
when others =>
Write_Str ("Field13??");
end case;
end Write_Field13_Name;
-----------------------
-- Write_Field14_Name --
-----------------------
procedure Write_Field14_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Type_Kind |
Object_Kind =>
Write_Str ("Alignment");
when E_Function |
E_Procedure =>
Write_Str ("First_Optional_Parameter");
when E_Package |
E_Generic_Package =>
Write_Str ("Shadow_Entities");
when others =>
Write_Str ("Field14??");
end case;
end Write_Field14_Name;
------------------------
-- Write_Field15_Name --
------------------------
procedure Write_Field15_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Access_Kind |
Task_Kind =>
Write_Str ("Storage_Size_Variable");
when Class_Wide_Kind |
E_Record_Type |
E_Record_Subtype |
Private_Kind =>
Write_Str ("Primitive_Operations");
when E_Component =>
Write_Str ("DT_Entry_Count");
when Decimal_Fixed_Point_Kind =>
Write_Str ("Scale_Value");
when E_Discriminant =>
Write_Str ("Discriminant_Number");
when Formal_Kind =>
Write_Str ("Extra_Formal");
when E_Function |
E_Procedure =>
Write_Str ("DT_Position");
when Entry_Kind =>
Write_Str ("Entry_Parameters_Type");
when Enumeration_Kind =>
Write_Str ("Lit_Indexes");
when E_Package =>
Write_Str ("Related_Instance");
when E_Protected_Type =>
Write_Str ("Entry_Bodies_Array");
when E_String_Literal_Subtype =>
Write_Str ("String_Literal_Low_Bound");
when E_Variable =>
Write_Str ("Shared_Var_Read_Proc");
when others =>
Write_Str ("Field15??");
end case;
end Write_Field15_Name;
------------------------
-- Write_Field16_Name --
------------------------
procedure Write_Field16_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when E_Component =>
Write_Str ("Entry_Formal");
when E_Function |
E_Procedure =>
Write_Str ("DTC_Entity");
when E_Package |
E_Generic_Package |
Concurrent_Kind =>
Write_Str ("First_Private_Entity");
when E_Record_Type |
E_Record_Type_With_Private =>
Write_Str ("Access_Disp_Table");
when E_String_Literal_Subtype =>
Write_Str ("String_Literal_Length");
when Enumeration_Kind =>
Write_Str ("Lit_Strings");
when E_Variable |
E_Out_Parameter =>
Write_Str ("Unset_Reference");
when E_Record_Subtype |
E_Class_Wide_Subtype =>
Write_Str ("Cloned_Subtype");
when others =>
Write_Str ("Field16??");
end case;
end Write_Field16_Name;
------------------------
-- Write_Field17_Name --
------------------------
procedure Write_Field17_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Digits_Kind =>
Write_Str ("Digits_Value");
when E_Component =>
Write_Str ("Prival");
when E_Discriminant =>
Write_Str ("Discriminal");
when E_Block |
Class_Wide_Kind |
Concurrent_Kind |
Private_Kind |
E_Entry |
E_Entry_Family |
E_Function |
E_Generic_Function |
E_Generic_Package |
E_Generic_Procedure |
E_Loop |
E_Operator |
E_Package |
E_Package_Body |
E_Procedure |
E_Record_Type |
E_Record_Subtype |
E_Subprogram_Body |
E_Subprogram_Type =>
Write_Str ("First_Entity");
when Array_Kind =>
Write_Str ("First_Index");
when E_Protected_Body =>
Write_Str ("Object_Ref");
when Enumeration_Kind =>
Write_Str ("First_Literal");
when Access_Kind =>
Write_Str ("Master_Id");
when Modular_Integer_Kind =>
Write_Str ("Modulus");
when Formal_Kind |
E_Constant |
E_Generic_In_Out_Parameter |
E_Variable =>
Write_Str ("Actual_Subtype");
when others =>
Write_Str ("Field17??");
end case;
end Write_Field17_Name;
-----------------------
-- Write_Field18_Name --
-----------------------
procedure Write_Field18_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when E_Enumeration_Literal |
E_Function |
E_Operator |
E_Procedure =>
Write_Str ("Alias");
when E_Record_Type =>
Write_Str ("Corresponding_Concurrent_Type");
when E_Entry_Index_Parameter =>
Write_Str ("Entry_Index_Constant");
when E_Class_Wide_Subtype |
E_Access_Protected_Subprogram_Type |
E_Access_Subprogram_Type |
E_Exception_Type =>
Write_Str ("Equivalent_Type");
when Fixed_Point_Kind =>
Write_Str ("Delta_Value");
when E_Constant |
E_Variable =>
Write_Str ("Renamed_Object");
when E_Exception |
E_Package |
E_Generic_Function |
E_Generic_Procedure |
E_Generic_Package =>
Write_Str ("Renamed_Entity");
when Incomplete_Or_Private_Kind =>
Write_Str ("Private_Dependents");
when Concurrent_Kind =>
Write_Str ("Corresponding_Record_Type");
when E_Label |
E_Loop |
E_Block =>
Write_Str ("Enclosing_Scope");
when others =>
Write_Str ("Field18??");
end case;
end Write_Field18_Name;
-----------------------
-- Write_Field19_Name --
-----------------------
procedure Write_Field19_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when E_Array_Type |
E_Array_Subtype =>
Write_Str ("Related_Array_Object");
when E_Block |
Concurrent_Kind |
E_Function |
E_Procedure |
Entry_Kind =>
Write_Str ("Finalization_Chain_Entity");
when E_Discriminant =>
Write_Str ("Corresponding_Discriminant");
when E_Package |
E_Generic_Package =>
Write_Str ("Body_Entity");
when E_Package_Body |
Formal_Kind =>
Write_Str ("Spec_Entity");
when Private_Kind =>
Write_Str ("Underlying_Full_View");
when E_Record_Type =>
Write_Str ("Parent_Subtype");
when others =>
Write_Str ("Field19??");
end case;
end Write_Field19_Name;
-----------------------
-- Write_Field20_Name --
-----------------------
procedure Write_Field20_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Array_Kind =>
Write_Str ("Component_Type");
when E_In_Parameter |
E_Generic_In_Parameter =>
Write_Str ("Default_Value");
when Access_Kind =>
Write_Str ("Directly_Designated_Type");
when E_Component =>
Write_Str ("Discriminant_Checking_Func");
when E_Discriminant =>
Write_Str ("Discriminant_Default_Value");
when E_Block |
Class_Wide_Kind |
Concurrent_Kind |
Private_Kind |
E_Entry |
E_Entry_Family |
E_Function |
E_Generic_Function |
E_Generic_Package |
E_Generic_Procedure |
E_Loop |
E_Operator |
E_Package |
E_Package_Body |
E_Procedure |
E_Record_Type |
E_Record_Subtype |
E_Subprogram_Body |
E_Subprogram_Type =>
Write_Str ("Last_Entity");
when Scalar_Kind =>
Write_Str ("Scalar_Range");
when E_Exception =>
Write_Str ("Register_Exception_Call");
when others =>
Write_Str ("Field20??");
end case;
end Write_Field20_Name;
-----------------------
-- Write_Field21_Name --
-----------------------
procedure Write_Field21_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when E_Constant |
E_Exception |
E_Function |
E_Generic_Function |
E_Procedure |
E_Generic_Procedure |
E_Variable =>
Write_Str ("Interface_Name");
when Concurrent_Kind |
Incomplete_Or_Private_Kind |
Class_Wide_Kind |
E_Record_Type |
E_Record_Subtype =>
Write_Str ("Discriminant_Constraint");
when Entry_Kind =>
Write_Str ("Accept_Address");
when Fixed_Point_Kind =>
Write_Str ("Small_Value");
when E_In_Parameter =>
Write_Str ("Default_Expr_Function");
when others =>
Write_Str ("Field21??");
end case;
end Write_Field21_Name;
-----------------------
-- Write_Field22_Name --
-----------------------
procedure Write_Field22_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Access_Kind =>
Write_Str ("Associated_Storage_Pool");
when Array_Kind =>
Write_Str ("Component_Size");
when E_Component |
E_Discriminant =>
Write_Str ("Original_Record_Component");
when E_Enumeration_Literal =>
Write_Str ("Enumeration_Rep_Expr");
when E_Exception =>
Write_Str ("Exception_Code");
when Formal_Kind =>
Write_Str ("Protected_Formal");
when E_Record_Type =>
Write_Str ("Corresponding_Remote_Type");
when E_Block |
E_Entry |
E_Entry_Family |
E_Function |
E_Loop |
E_Package |
E_Package_Body |
E_Generic_Package |
E_Generic_Function |
E_Generic_Procedure |
E_Procedure |
E_Protected_Type |
E_Subprogram_Body |
E_Task_Type =>
Write_Str ("Scope_Depth_Value");
when E_Record_Type_With_Private |
E_Record_Subtype_With_Private |
E_Private_Type |
E_Private_Subtype |
E_Limited_Private_Type |
E_Limited_Private_Subtype =>
Write_Str ("Private_View");
when E_Variable =>
Write_Str ("Shared_Var_Assign_Proc");
when others =>
Write_Str ("Field22??");
end case;
end Write_Field22_Name;
------------------------
-- Write_Field23_Name --
------------------------
procedure Write_Field23_Name (Id : Entity_Id) is
begin
case Ekind (Id) is
when Access_Kind =>
Write_Str ("Associated_Final_Chain");
when Array_Kind =>
Write_Str ("Packed_Array_Type");
when E_Block =>
Write_Str ("Entry_Cancel_Parameter");
when E_Component =>
Write_Str ("Protected_Operation");
when E_Discriminant =>
Write_Str ("CR_Discriminant");
when E_Enumeration_Type =>
Write_Str ("Enum_Pos_To_Rep");
when Formal_Kind |
E_Variable =>
Write_Str ("Extra_Constrained");
when E_Generic_Function |
E_Generic_Package |
E_Generic_Procedure =>
Write_Str ("Inner_Instances");
when Concurrent_Kind |
Incomplete_Or_Private_Kind |
Class_Wide_Kind |
E_Record_Type |
E_Record_Subtype =>
Write_Str ("Girder_Constraint");
when E_Function |
E_Package |
E_Procedure =>
Write_Str ("Generic_Renamings");
-- What about Privals_Chain for protected operations ???
when Entry_Kind =>
Write_Str ("Privals_Chain");
when others =>
Write_Str ("Field23??");
end case;
end Write_Field23_Name;
-------------------------
-- Iterator Procedures --
-------------------------
procedure Proc_Next_Component (N : in out Node_Id) is
begin
N := Next_Component (N);
end Proc_Next_Component;
procedure Proc_Next_Discriminant (N : in out Node_Id) is
begin
N := Next_Discriminant (N);
end Proc_Next_Discriminant;
procedure Proc_Next_Formal (N : in out Node_Id) is
begin
N := Next_Formal (N);
end Proc_Next_Formal;
procedure Proc_Next_Formal_With_Extras (N : in out Node_Id) is
begin
N := Next_Formal_With_Extras (N);
end Proc_Next_Formal_With_Extras;
procedure Proc_Next_Girder_Discriminant (N : in out Node_Id) is
begin
N := Next_Girder_Discriminant (N);
end Proc_Next_Girder_Discriminant;
procedure Proc_Next_Index (N : in out Node_Id) is
begin
N := Next_Index (N);
end Proc_Next_Index;
procedure Proc_Next_Inlined_Subprogram (N : in out Node_Id) is
begin
N := Next_Inlined_Subprogram (N);
end Proc_Next_Inlined_Subprogram;
procedure Proc_Next_Literal (N : in out Node_Id) is
begin
N := Next_Literal (N);
end Proc_Next_Literal;
end Einfo;