------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- S E M _ P R A G -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2004, 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. -- -- -- -- GNAT was originally developed by the GNAT team at New York University. -- -- Extensive contributions were provided by Ada Core Technologies Inc. -- -- -- ------------------------------------------------------------------------------ -- This unit contains the semantic processing for all pragmas, both language -- and implementation defined. For most pragmas, the parser only does the -- most basic job of checking the syntax, so Sem_Prag also contains the code -- to complete the syntax checks. Certain pragmas are handled partially or -- completely by the parser (see Par.Prag for further details). with Atree; use Atree; with Casing; use Casing; with Csets; use Csets; with Debug; use Debug; with Einfo; use Einfo; with Elists; use Elists; with Errout; use Errout; with Expander; use Expander; with Exp_Dist; use Exp_Dist; with Fname; use Fname; with Hostparm; use Hostparm; with Lib; use Lib; with Lib.Writ; use Lib.Writ; with Lib.Xref; use Lib.Xref; with Namet; use Namet; with Nlists; use Nlists; with Nmake; use Nmake; with Opt; use Opt; with Output; use Output; with Restrict; use Restrict; with Rident; use Rident; with Rtsfind; use Rtsfind; with Sem; use Sem; with Sem_Ch3; use Sem_Ch3; with Sem_Ch8; use Sem_Ch8; with Sem_Ch13; use Sem_Ch13; with Sem_Disp; use Sem_Disp; with Sem_Elim; use Sem_Elim; with Sem_Eval; use Sem_Eval; with Sem_Intr; use Sem_Intr; with Sem_Mech; use Sem_Mech; with Sem_Res; use Sem_Res; with Sem_Type; use Sem_Type; with Sem_Util; use Sem_Util; with Sem_VFpt; use Sem_VFpt; with Stand; use Stand; with Sinfo; use Sinfo; with Sinfo.CN; use Sinfo.CN; with Sinput; use Sinput; with Snames; use Snames; with Stringt; use Stringt; with Stylesw; use Stylesw; with Targparm; use Targparm; with Tbuild; use Tbuild; with Ttypes; with Uintp; use Uintp; with Urealp; use Urealp; with Validsw; use Validsw; with GNAT.Spelling_Checker; use GNAT.Spelling_Checker; package body Sem_Prag is ---------------------------------------------- -- Common Handling of Import-Export Pragmas -- ---------------------------------------------- -- In the following section, a number of Import_xxx and Export_xxx -- pragmas are defined by GNAT. These are compatible with the DEC -- pragmas of the same name, and all have the following common -- form and processing: -- pragma Export_xxx -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, other optional parameters ]); -- pragma Import_xxx -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, other optional parameters ]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- The internal LOCAL_NAME designates the entity that is imported or -- exported, and must refer to an entity in the current declarative -- part (as required by the rules for LOCAL_NAME). -- The external linker name is designated by the External parameter -- if given, or the Internal parameter if not (if there is no External -- parameter, the External parameter is a copy of the Internal name). -- If the External parameter is given as a string, then this string -- is treated as an external name (exactly as though it had been given -- as an External_Name parameter for a normal Import pragma). -- If the External parameter is given as an identifier (or there is no -- External parameter, so that the Internal identifier is used), then -- the external name is the characters of the identifier, translated -- to all upper case letters for OpenVMS versions of GNAT, and to all -- lower case letters for all other versions -- Note: the external name specified or implied by any of these special -- Import_xxx or Export_xxx pragmas override an external or link name -- specified in a previous Import or Export pragma. -- Note: these and all other DEC-compatible GNAT pragmas allow full -- use of named notation, following the standard rules for subprogram -- calls, i.e. parameters can be given in any order if named notation -- is used, and positional and named notation can be mixed, subject to -- the rule that all positional parameters must appear first. -- Note: All these pragmas are implemented exactly following the DEC -- design and implementation and are intended to be fully compatible -- with the use of these pragmas in the DEC Ada compiler. ------------------------------------- -- Local Subprograms and Variables -- ------------------------------------- function Adjust_External_Name_Case (N : Node_Id) return Node_Id; -- This routine is used for possible casing adjustment of an explicit -- external name supplied as a string literal (the node N), according -- to the casing requirement of Opt.External_Name_Casing. If this is -- set to As_Is, then the string literal is returned unchanged, but if -- it is set to Uppercase or Lowercase, then a new string literal with -- appropriate casing is constructed. function Get_Base_Subprogram (Def_Id : Entity_Id) return Entity_Id; -- If Def_Id refers to a renamed subprogram, then the base subprogram -- (the original one, following the renaming chain) is returned. -- Otherwise the entity is returned unchanged. Should be in Einfo??? procedure Set_Unit_Name (N : Node_Id; With_Item : Node_Id); -- Place semantic information on the argument of an Elaborate or -- Elaborate_All pragma. Entity name for unit and its parents is -- taken from item in previous with_clause that mentions the unit. ------------------------------- -- Adjust_External_Name_Case -- ------------------------------- function Adjust_External_Name_Case (N : Node_Id) return Node_Id is CC : Char_Code; begin -- Adjust case of literal if required if Opt.External_Name_Exp_Casing = As_Is then return N; else -- Copy existing string Start_String; -- Set proper casing for J in 1 .. String_Length (Strval (N)) loop CC := Get_String_Char (Strval (N), J); if Opt.External_Name_Exp_Casing = Uppercase and then CC >= Get_Char_Code ('a') and then CC <= Get_Char_Code ('z') then Store_String_Char (CC - 32); elsif Opt.External_Name_Exp_Casing = Lowercase and then CC >= Get_Char_Code ('A') and then CC <= Get_Char_Code ('Z') then Store_String_Char (CC + 32); else Store_String_Char (CC); end if; end loop; return Make_String_Literal (Sloc (N), Strval => End_String); end if; end Adjust_External_Name_Case; -------------------- -- Analyze_Pragma -- -------------------- procedure Analyze_Pragma (N : Node_Id) is Loc : constant Source_Ptr := Sloc (N); Prag_Id : Pragma_Id; Pragma_Exit : exception; -- This exception is used to exit pragma processing completely. It -- is used when an error is detected, and in other situations where -- it is known that no further processing is required. Arg_Count : Nat; -- Number of pragma argument associations Arg1 : Node_Id; Arg2 : Node_Id; Arg3 : Node_Id; Arg4 : Node_Id; -- First four pragma arguments (pragma argument association nodes, -- or Empty if the corresponding argument does not exist). procedure Check_Ada_83_Warning; -- Issues a warning message for the current pragma if operating in Ada -- 83 mode (used for language pragmas that are not a standard part of -- Ada 83). This procedure does not raise Error_Pragma. Also notes use -- of 95 pragma. procedure Check_Arg_Count (Required : Nat); -- Check argument count for pragma is equal to given parameter. -- If not, then issue an error message and raise Pragma_Exit. -- Note: all routines whose name is Check_Arg_Is_xxx take an -- argument Arg which can either be a pragma argument association, -- in which case the check is applied to the expression of the -- association or an expression directly. procedure Check_Arg_Is_Identifier (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is an -- identifier. If not give error and raise Pragma_Exit. procedure Check_Arg_Is_Integer_Literal (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is an -- integer literal. If not give error and raise Pragma_Exit. procedure Check_Arg_Is_Library_Level_Local_Name (Arg : Node_Id); -- Check the specified argument Arg to make sure that it has the -- proper syntactic form for a local name and meets the semantic -- requirements for a local name. The local name is analyzed as -- part of the processing for this call. In addition, the local -- name is required to represent an entity at the library level. procedure Check_Arg_Is_Local_Name (Arg : Node_Id); -- Check the specified argument Arg to make sure that it has the -- proper syntactic form for a local name and meets the semantic -- requirements for a local name. The local name is analyzed as -- part of the processing for this call. procedure Check_Arg_Is_Locking_Policy (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a valid -- locking policy name. If not give error and raise Pragma_Exit. procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2 : Name_Id); procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3 : Name_Id); -- Check the specified argument Arg to make sure that it is an -- identifier whose name matches either N1 or N2 (or N3 if present). -- If not then give error and raise Pragma_Exit. procedure Check_Arg_Is_Queuing_Policy (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a valid -- queuing policy name. If not give error and raise Pragma_Exit. procedure Check_Arg_Is_Static_Expression (Arg : Node_Id; Typ : Entity_Id); -- Check the specified argument Arg to make sure that it is a static -- expression of the given type (i.e. it will be analyzed and resolved -- using this type, which can be any valid argument to Resolve, e.g. -- Any_Integer is OK). If not, given error and raise Pragma_Exit. procedure Check_Arg_Is_String_Literal (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a -- string literal. If not give error and raise Pragma_Exit procedure Check_Arg_Is_Task_Dispatching_Policy (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a valid -- valid task dispatching policy name. If not give error and raise -- Pragma_Exit. procedure Check_At_Least_N_Arguments (N : Nat); -- Check there are at least N arguments present procedure Check_At_Most_N_Arguments (N : Nat); -- Check there are no more than N arguments present procedure Check_First_Subtype (Arg : Node_Id); -- Checks that Arg, whose expression is an entity name referencing -- a subtype, does not reference a type that is not a first subtype. procedure Check_In_Main_Program; -- Common checks for pragmas that appear within a main program -- (Priority, Main_Storage, Time_Slice). procedure Check_Interrupt_Or_Attach_Handler; -- Common processing for first argument of pragma Interrupt_Handler -- or pragma Attach_Handler. procedure Check_Is_In_Decl_Part_Or_Package_Spec; -- Check that pragma appears in a declarative part, or in a package -- specification, i.e. that it does not occur in a statement sequence -- in a body. procedure Check_No_Identifier (Arg : Node_Id); -- Checks that the given argument does not have an identifier. If -- an identifier is present, then an error message is issued, and -- Pragma_Exit is raised. procedure Check_No_Identifiers; -- Checks that none of the arguments to the pragma has an identifier. -- If any argument has an identifier, then an error message is issued, -- and Pragma_Exit is raised. procedure Check_Optional_Identifier (Arg : Node_Id; Id : Name_Id); -- Checks if the given argument has an identifier, and if so, requires -- it to match the given identifier name. If there is a non-matching -- identifier, then an error message is given and Error_Pragmas raised. procedure Check_Optional_Identifier (Arg : Node_Id; Id : String); -- Checks if the given argument has an identifier, and if so, requires -- it to match the given identifier name. If there is a non-matching -- identifier, then an error message is given and Error_Pragmas raised. -- In this version of the procedure, the identifier name is given as -- a string with lower case letters. procedure Check_Static_Constraint (Constr : Node_Id); -- Constr is a constraint from an N_Subtype_Indication node from a -- component constraint in an Unchecked_Union type. This routine checks -- that the constraint is static as required by the restrictions for -- Unchecked_Union. procedure Check_Valid_Configuration_Pragma; -- Legality checks for placement of a configuration pragma procedure Check_Valid_Library_Unit_Pragma; -- Legality checks for library unit pragmas. A special case arises for -- pragmas in generic instances that come from copies of the original -- library unit pragmas in the generic templates. In the case of other -- than library level instantiations these can appear in contexts which -- would normally be invalid (they only apply to the original template -- and to library level instantiations), and they are simply ignored, -- which is implemented by rewriting them as null statements. procedure Error_Pragma (Msg : String); pragma No_Return (Error_Pragma); -- Outputs error message for current pragma. The message contains an % -- that will be replaced with the pragma name, and the flag is placed -- on the pragma itself. Pragma_Exit is then raised. procedure Error_Pragma_Arg (Msg : String; Arg : Node_Id); pragma No_Return (Error_Pragma_Arg); -- Outputs error message for current pragma. The message may contain -- a % that will be replaced with the pragma name. The parameter Arg -- may either be a pragma argument association, in which case the flag -- is placed on the expression of this association, or an expression, -- in which case the flag is placed directly on the expression. The -- message is placed using Error_Msg_N, so the message may also contain -- an & insertion character which will reference the given Arg value. -- After placing the message, Pragma_Exit is raised. procedure Error_Pragma_Arg (Msg1, Msg2 : String; Arg : Node_Id); pragma No_Return (Error_Pragma_Arg); -- Similar to above form of Error_Pragma_Arg except that two messages -- are provided, the second is a continuation comment starting with \. procedure Error_Pragma_Arg_Ident (Msg : String; Arg : Node_Id); pragma No_Return (Error_Pragma_Arg_Ident); -- Outputs error message for current pragma. The message may contain -- a % that will be replaced with the pragma name. The parameter Arg -- must be a pragma argument association with a non-empty identifier -- (i.e. its Chars field must be set), and the error message is placed -- on the identifier. The message is placed using Error_Msg_N so -- the message may also contain an & insertion character which will -- reference the identifier. After placing the message, Pragma_Exit -- is raised. function Find_Lib_Unit_Name return Entity_Id; -- Used for a library unit pragma to find the entity to which the -- library unit pragma applies, returns the entity found. procedure Find_Program_Unit_Name (Id : Node_Id); -- If the pragma is a compilation unit pragma, the id must denote the -- compilation unit in the same compilation, and the pragma must appear -- in the list of preceding or trailing pragmas. If it is a program -- unit pragma that is not a compilation unit pragma, then the -- identifier must be visible. type Name_List is array (Natural range <>) of Name_Id; type Args_List is array (Natural range <>) of Node_Id; procedure Gather_Associations (Names : Name_List; Args : out Args_List); -- This procedure is used to gather the arguments for a pragma that -- permits arbitrary ordering of parameters using the normal rules -- for named and positional parameters. The Names argument is a list -- of Name_Id values that corresponds to the allowed pragma argument -- association identifiers in order. The result returned in Args is -- a list of corresponding expressions that are the pragma arguments. -- Note that this is a list of expressions, not of pragma argument -- associations (Gather_Associations has completely checked all the -- optional identifiers when it returns). An entry in Args is Empty -- on return if the corresponding argument is not present. function Get_Pragma_Arg (Arg : Node_Id) return Node_Id; -- All the routines that check pragma arguments take either a pragma -- argument association (in which case the expression of the argument -- association is checked), or the expression directly. The function -- Get_Pragma_Arg is a utility used to deal with these two cases. If -- Arg is a pragma argument association node, then its expression is -- returned, otherwise Arg is returned unchanged. procedure GNAT_Pragma; -- Called for all GNAT defined pragmas to note the use of the feature, -- and also check the relevant restriction (No_Implementation_Pragmas). function Is_Before_First_Decl (Pragma_Node : Node_Id; Decls : List_Id) return Boolean; -- Return True if Pragma_Node is before the first declarative item in -- Decls where Decls is the list of declarative items. function Is_Configuration_Pragma return Boolean; -- Deterermines if the placement of the current pragma is appropriate -- for a configuration pragma (precedes the current compilation unit) procedure Pragma_Misplaced; -- Issue fatal error message for misplaced pragma procedure Process_Atomic_Shared_Volatile; -- Common processing for pragmas Atomic, Shared, Volatile. Note that -- Shared is an obsolete Ada 83 pragma, treated as being identical -- in effect to pragma Atomic. procedure Process_Convention (C : out Convention_Id; E : out Entity_Id); -- Common procesing for Convention, Interface, Import and Export. -- Checks first two arguments of pragma, and sets the appropriate -- convention value in the specified entity or entities. On return -- C is the convention, E is the referenced entity. procedure Process_Extended_Import_Export_Exception_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Form : Node_Id; Arg_Code : Node_Id); -- Common processing for the pragmas Import/Export_Exception. -- The three arguments correspond to the three named parameters of -- the pragma. An argument is empty if the corresponding parameter -- is not present in the pragma. procedure Process_Extended_Import_Export_Object_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Size : Node_Id); -- Common processing for the pragmass Import/Export_Object. -- The three arguments correspond to the three named parameters -- of the pragmas. An argument is empty if the corresponding -- parameter is not present in the pragma. procedure Process_Extended_Import_Export_Internal_Arg (Arg_Internal : Node_Id := Empty); -- Common processing for all extended Import and Export pragmas. The -- argument is the pragma parameter for the Internal argument. If -- Arg_Internal is empty or inappropriate, an error message is posted. -- Otherwise, on normal return, the Entity_Field of Arg_Internal is -- set to identify the referenced entity. procedure Process_Extended_Import_Export_Subprogram_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Parameter_Types : Node_Id; Arg_Result_Type : Node_Id := Empty; Arg_Mechanism : Node_Id; Arg_Result_Mechanism : Node_Id := Empty; Arg_First_Optional_Parameter : Node_Id := Empty); -- Common processing for all extended Import and Export pragmas -- applying to subprograms. The caller omits any arguments that do -- bnot apply to the pragma in question (for example, Arg_Result_Type -- can be non-Empty only in the Import_Function and Export_Function -- cases). The argument names correspond to the allowed pragma -- association identifiers. procedure Process_Generic_List; -- Common processing for Share_Generic and Inline_Generic procedure Process_Import_Or_Interface; -- Common processing for Import of Interface procedure Process_Inline (Active : Boolean); -- Common processing for Inline and Inline_Always. The parameter -- indicates if the inline pragma is active, i.e. if it should -- actually cause inlining to occur. procedure Process_Interface_Name (Subprogram_Def : Entity_Id; Ext_Arg : Node_Id; Link_Arg : Node_Id); -- Given the last two arguments of pragma Import, pragma Export, or -- pragma Interface_Name, performs validity checks and sets the -- Interface_Name field of the given subprogram entity to the -- appropriate external or link name, depending on the arguments -- given. Ext_Arg is always present, but Link_Arg may be missing. -- Note that Ext_Arg may represent the Link_Name if Link_Arg is -- missing, and appropriate named notation is used for Ext_Arg. -- If neither Ext_Arg nor Link_Arg is present, the interface name -- is set to the default from the subprogram name. procedure Process_Interrupt_Or_Attach_Handler; -- Common processing for Interrupt and Attach_Handler pragmas procedure Process_Restrictions_Or_Restriction_Warnings; -- Common processing for Restrictions and Restriction_Warnings pragmas procedure Process_Suppress_Unsuppress (Suppress_Case : Boolean); -- Common processing for Suppress and Unsuppress. The boolean parameter -- Suppress_Case is True for the Suppress case, and False for the -- Unsuppress case. procedure Set_Exported (E : Entity_Id; Arg : Node_Id); -- This procedure sets the Is_Exported flag for the given entity, -- checking that the entity was not previously imported. Arg is -- the argument that specified the entity. A check is also made -- for exporting inappropriate entities. procedure Set_Extended_Import_Export_External_Name (Internal_Ent : Entity_Id; Arg_External : Node_Id); -- Common processing for all extended import export pragmas. The first -- argument, Internal_Ent, is the internal entity, which has already -- been checked for validity by the caller. Arg_External is from the -- Import or Export pragma, and may be null if no External parameter -- was present. If Arg_External is present and is a non-null string -- (a null string is treated as the default), then the Interface_Name -- field of Internal_Ent is set appropriately. procedure Set_Imported (E : Entity_Id); -- This procedure sets the Is_Imported flag for the given entity, -- checking that it is not previously exported or imported. procedure Set_Mechanism_Value (Ent : Entity_Id; Mech_Name : Node_Id); -- Mech is a parameter passing mechanism (see Import_Function syntax -- for MECHANISM_NAME). This routine checks that the mechanism argument -- has the right form, and if not issues an error message. If the -- argument has the right form then the Mechanism field of Ent is -- set appropriately. -------------------------- -- Check_Ada_83_Warning -- -------------------------- procedure Check_Ada_83_Warning is begin if Ada_83 and then Comes_From_Source (N) then Error_Msg_N ("(Ada 83) pragma& is non-standard?", N); end if; end Check_Ada_83_Warning; --------------------- -- Check_Arg_Count -- --------------------- procedure Check_Arg_Count (Required : Nat) is begin if Arg_Count /= Required then Error_Pragma ("wrong number of arguments for pragma%"); end if; end Check_Arg_Count; ----------------------------- -- Check_Arg_Is_Identifier -- ----------------------------- procedure Check_Arg_Is_Identifier (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin if Nkind (Argx) /= N_Identifier then Error_Pragma_Arg ("argument for pragma% must be identifier", Argx); end if; end Check_Arg_Is_Identifier; ---------------------------------- -- Check_Arg_Is_Integer_Literal -- ---------------------------------- procedure Check_Arg_Is_Integer_Literal (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin if Nkind (Argx) /= N_Integer_Literal then Error_Pragma_Arg ("argument for pragma% must be integer literal", Argx); end if; end Check_Arg_Is_Integer_Literal; ------------------------------------------- -- Check_Arg_Is_Library_Level_Local_Name -- ------------------------------------------- -- LOCAL_NAME ::= -- DIRECT_NAME -- | DIRECT_NAME'ATTRIBUTE_DESIGNATOR -- | library_unit_NAME procedure Check_Arg_Is_Library_Level_Local_Name (Arg : Node_Id) is begin Check_Arg_Is_Local_Name (Arg); if not Is_Library_Level_Entity (Entity (Expression (Arg))) and then Comes_From_Source (N) then Error_Pragma_Arg ("argument for pragma% must be library level entity", Arg); end if; end Check_Arg_Is_Library_Level_Local_Name; ----------------------------- -- Check_Arg_Is_Local_Name -- ----------------------------- -- LOCAL_NAME ::= -- DIRECT_NAME -- | DIRECT_NAME'ATTRIBUTE_DESIGNATOR -- | library_unit_NAME procedure Check_Arg_Is_Local_Name (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Analyze (Argx); if Nkind (Argx) not in N_Direct_Name and then (Nkind (Argx) /= N_Attribute_Reference or else Present (Expressions (Argx)) or else Nkind (Prefix (Argx)) /= N_Identifier) and then (not Is_Entity_Name (Argx) or else not Is_Compilation_Unit (Entity (Argx))) then Error_Pragma_Arg ("argument for pragma% must be local name", Argx); end if; if Is_Entity_Name (Argx) and then Scope (Entity (Argx)) /= Current_Scope then Error_Pragma_Arg ("pragma% argument must be in same declarative part", Arg); end if; end Check_Arg_Is_Local_Name; --------------------------------- -- Check_Arg_Is_Locking_Policy -- --------------------------------- procedure Check_Arg_Is_Locking_Policy (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Is_Locking_Policy_Name (Chars (Argx)) then Error_Pragma_Arg ("& is not a valid locking policy name", Argx); end if; end Check_Arg_Is_Locking_Policy; ------------------------- -- Check_Arg_Is_One_Of -- ------------------------- procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2 : Name_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if Chars (Argx) /= N1 and then Chars (Argx) /= N2 then Error_Msg_Name_2 := N1; Error_Msg_Name_3 := N2; Error_Pragma_Arg ("argument for pragma% must be% or%", Argx); end if; end Check_Arg_Is_One_Of; procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3 : Name_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if Chars (Argx) /= N1 and then Chars (Argx) /= N2 and then Chars (Argx) /= N3 then Error_Pragma_Arg ("invalid argument for pragma%", Argx); end if; end Check_Arg_Is_One_Of; --------------------------------- -- Check_Arg_Is_Queuing_Policy -- --------------------------------- procedure Check_Arg_Is_Queuing_Policy (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Is_Queuing_Policy_Name (Chars (Argx)) then Error_Pragma_Arg ("& is not a valid queuing policy name", Argx); end if; end Check_Arg_Is_Queuing_Policy; ------------------------------------ -- Check_Arg_Is_Static_Expression -- ------------------------------------ procedure Check_Arg_Is_Static_Expression (Arg : Node_Id; Typ : Entity_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Analyze_And_Resolve (Argx, Typ); if Is_OK_Static_Expression (Argx) then return; elsif Etype (Argx) = Any_Type then raise Pragma_Exit; -- An interesting special case, if we have a string literal and -- we are in Ada 83 mode, then we allow it even though it will -- not be flagged as static. This allows the use of Ada 95 -- pragmas like Import in Ada 83 mode. They will of course be -- flagged with warnings as usual, but will not cause errors. elsif Ada_83 and then Nkind (Argx) = N_String_Literal then return; -- Static expression that raises Constraint_Error. This has -- already been flagged, so just exit from pragma processing. elsif Is_Static_Expression (Argx) then raise Pragma_Exit; -- Finally, we have a real error else Error_Msg_Name_1 := Chars (N); Flag_Non_Static_Expr ("argument for pragma% must be a static expression!", Argx); raise Pragma_Exit; end if; end Check_Arg_Is_Static_Expression; --------------------------------- -- Check_Arg_Is_String_Literal -- --------------------------------- procedure Check_Arg_Is_String_Literal (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin if Nkind (Argx) /= N_String_Literal then Error_Pragma_Arg ("argument for pragma% must be string literal", Argx); end if; end Check_Arg_Is_String_Literal; ------------------------------------------ -- Check_Arg_Is_Task_Dispatching_Policy -- ------------------------------------------ procedure Check_Arg_Is_Task_Dispatching_Policy (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Is_Task_Dispatching_Policy_Name (Chars (Argx)) then Error_Pragma_Arg ("& is not a valid task dispatching policy name", Argx); end if; end Check_Arg_Is_Task_Dispatching_Policy; -------------------------------- -- Check_At_Least_N_Arguments -- -------------------------------- procedure Check_At_Least_N_Arguments (N : Nat) is begin if Arg_Count < N then Error_Pragma ("too few arguments for pragma%"); end if; end Check_At_Least_N_Arguments; ------------------------------- -- Check_At_Most_N_Arguments -- ------------------------------- procedure Check_At_Most_N_Arguments (N : Nat) is Arg : Node_Id; begin if Arg_Count > N then Arg := Arg1; for J in 1 .. N loop Next (Arg); Error_Pragma_Arg ("too many arguments for pragma%", Arg); end loop; end if; end Check_At_Most_N_Arguments; ------------------------- -- Check_First_Subtype -- ------------------------- procedure Check_First_Subtype (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin if not Is_First_Subtype (Entity (Argx)) then Error_Pragma_Arg ("pragma% cannot apply to subtype", Argx); end if; end Check_First_Subtype; --------------------------- -- Check_In_Main_Program -- --------------------------- procedure Check_In_Main_Program is P : constant Node_Id := Parent (N); begin -- Must be at in subprogram body if Nkind (P) /= N_Subprogram_Body then Error_Pragma ("% pragma allowed only in subprogram"); -- Otherwise warn if obviously not main program elsif Present (Parameter_Specifications (Specification (P))) or else not Is_Compilation_Unit (Defining_Entity (P)) then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("?pragma% is only effective in main program", N); end if; end Check_In_Main_Program; --------------------------------------- -- Check_Interrupt_Or_Attach_Handler -- --------------------------------------- procedure Check_Interrupt_Or_Attach_Handler is Arg1_X : constant Node_Id := Expression (Arg1); begin Analyze (Arg1_X); if not Is_Entity_Name (Arg1_X) then Error_Pragma_Arg ("argument of pragma% must be entity name", Arg1); elsif Prag_Id = Pragma_Interrupt_Handler then Check_Restriction (No_Dynamic_Interrupts, N); end if; declare Handler_Proc : Entity_Id := Empty; Proc_Scope : Entity_Id; Found : Boolean := False; begin if not Is_Overloaded (Arg1_X) then Handler_Proc := Entity (Arg1_X); else declare It : Interp; Index : Interp_Index; begin Get_First_Interp (Arg1_X, Index, It); while Present (It.Nam) loop Handler_Proc := It.Nam; if Ekind (Handler_Proc) = E_Procedure and then No (First_Formal (Handler_Proc)) then if not Found then Found := True; Set_Entity (Arg1_X, Handler_Proc); Set_Is_Overloaded (Arg1_X, False); else Error_Pragma_Arg ("ambiguous handler name for pragma% ", Arg1); end if; end if; Get_Next_Interp (Index, It); end loop; if not Found then Error_Pragma_Arg ("argument of pragma% must be parameterless procedure", Arg1); else Handler_Proc := Entity (Arg1_X); end if; end; end if; Proc_Scope := Scope (Handler_Proc); -- On AAMP only, a pragma Interrupt_Handler is supported for -- nonprotected parameterless procedures. if AAMP_On_Target and then Prag_Id = Pragma_Interrupt_Handler then if Ekind (Handler_Proc) /= E_Procedure then Error_Pragma_Arg ("argument of pragma% must be a procedure", Arg1); end if; elsif Ekind (Handler_Proc) /= E_Procedure or else Ekind (Proc_Scope) /= E_Protected_Type then Error_Pragma_Arg ("argument of pragma% must be protected procedure", Arg1); end if; if (not AAMP_On_Target or else Prag_Id = Pragma_Attach_Handler) and then Ekind (Proc_Scope) = E_Protected_Type then if Parent (N) /= Protected_Definition (Parent (Proc_Scope)) then Error_Pragma ("pragma% must be in protected definition"); end if; end if; if not Is_Library_Level_Entity (Proc_Scope) or else (AAMP_On_Target and then not Is_Library_Level_Entity (Handler_Proc)) then Error_Pragma_Arg ("pragma% requires library-level entity", Arg1); end if; if Present (First_Formal (Handler_Proc)) then Error_Pragma_Arg ("argument of pragma% must be parameterless procedure", Arg1); end if; end; end Check_Interrupt_Or_Attach_Handler; ------------------------------------------- -- Check_Is_In_Decl_Part_Or_Package_Spec -- ------------------------------------------- procedure Check_Is_In_Decl_Part_Or_Package_Spec is P : Node_Id; begin P := Parent (N); loop if No (P) then exit; elsif Nkind (P) = N_Handled_Sequence_Of_Statements then exit; elsif Nkind (P) = N_Package_Specification then return; elsif Nkind (P) = N_Block_Statement then return; -- Note: the following tests seem a little peculiar, because -- they test for bodies, but if we were in the statement part -- of the body, we would already have hit the handled statement -- sequence, so the only way we get here is by being in the -- declarative part of the body. elsif Nkind (P) = N_Subprogram_Body or else Nkind (P) = N_Package_Body or else Nkind (P) = N_Task_Body or else Nkind (P) = N_Entry_Body then return; end if; P := Parent (P); end loop; Error_Pragma ("pragma% is not in declarative part or package spec"); end Check_Is_In_Decl_Part_Or_Package_Spec; ------------------------- -- Check_No_Identifier -- ------------------------- procedure Check_No_Identifier (Arg : Node_Id) is begin if Chars (Arg) /= No_Name then Error_Pragma_Arg_Ident ("pragma% does not permit identifier& here", Arg); end if; end Check_No_Identifier; -------------------------- -- Check_No_Identifiers -- -------------------------- procedure Check_No_Identifiers is Arg_Node : Node_Id; begin if Arg_Count > 0 then Arg_Node := Arg1; while Present (Arg_Node) loop Check_No_Identifier (Arg_Node); Next (Arg_Node); end loop; end if; end Check_No_Identifiers; ------------------------------- -- Check_Optional_Identifier -- ------------------------------- procedure Check_Optional_Identifier (Arg : Node_Id; Id : Name_Id) is begin if Present (Arg) and then Chars (Arg) /= No_Name then if Chars (Arg) /= Id then Error_Msg_Name_1 := Chars (N); Error_Msg_Name_2 := Id; Error_Msg_N ("pragma% argument expects identifier%", Arg); raise Pragma_Exit; end if; end if; end Check_Optional_Identifier; procedure Check_Optional_Identifier (Arg : Node_Id; Id : String) is begin Name_Buffer (1 .. Id'Length) := Id; Name_Len := Id'Length; Check_Optional_Identifier (Arg, Name_Find); end Check_Optional_Identifier; ----------------------------- -- Check_Static_Constraint -- ----------------------------- -- Note: for convenience in writing this procedure, in addition to -- the officially (i.e. by spec) allowed argument which is always -- a constraint, it also allows ranges and discriminant associations. -- Above is not clear ??? procedure Check_Static_Constraint (Constr : Node_Id) is -------------------- -- Require_Static -- -------------------- procedure Require_Static (E : Node_Id); -- Require given expression to be static expression procedure Require_Static (E : Node_Id) is begin if not Is_OK_Static_Expression (E) then Flag_Non_Static_Expr ("non-static constraint not allowed in Unchecked_Union!", E); raise Pragma_Exit; end if; end Require_Static; -- Start of processing for Check_Static_Constraint begin case Nkind (Constr) is when N_Discriminant_Association => Require_Static (Expression (Constr)); when N_Range => Require_Static (Low_Bound (Constr)); Require_Static (High_Bound (Constr)); when N_Attribute_Reference => Require_Static (Type_Low_Bound (Etype (Prefix (Constr)))); Require_Static (Type_High_Bound (Etype (Prefix (Constr)))); when N_Range_Constraint => Check_Static_Constraint (Range_Expression (Constr)); when N_Index_Or_Discriminant_Constraint => declare IDC : Entity_Id := First (Constraints (Constr)); begin while Present (IDC) loop Check_Static_Constraint (IDC); Next (IDC); end loop; end; when others => null; end case; end Check_Static_Constraint; -------------------------------------- -- Check_Valid_Configuration_Pragma -- -------------------------------------- -- A configuration pragma must appear in the context clause of -- a compilation unit, at the start of the list (i.e. only other -- pragmas may precede it). procedure Check_Valid_Configuration_Pragma is begin if not Is_Configuration_Pragma then Error_Pragma ("incorrect placement for configuration pragma%"); end if; end Check_Valid_Configuration_Pragma; ------------------------------------- -- Check_Valid_Library_Unit_Pragma -- ------------------------------------- procedure Check_Valid_Library_Unit_Pragma is Plist : List_Id; Parent_Node : Node_Id; Unit_Name : Entity_Id; Unit_Kind : Node_Kind; Unit_Node : Node_Id; Sindex : Source_File_Index; begin if not Is_List_Member (N) then Pragma_Misplaced; else Plist := List_Containing (N); Parent_Node := Parent (Plist); if Parent_Node = Empty then Pragma_Misplaced; -- Case of pragma appearing after a compilation unit. In this -- case it must have an argument with the corresponding name -- and must be part of the following pragmas of its parent. elsif Nkind (Parent_Node) = N_Compilation_Unit_Aux then if Plist /= Pragmas_After (Parent_Node) then Pragma_Misplaced; elsif Arg_Count = 0 then Error_Pragma ("argument required if outside compilation unit"); else Check_No_Identifiers; Check_Arg_Count (1); Unit_Node := Unit (Parent (Parent_Node)); Unit_Kind := Nkind (Unit_Node); Analyze (Expression (Arg1)); if Unit_Kind = N_Generic_Subprogram_Declaration or else Unit_Kind = N_Subprogram_Declaration then Unit_Name := Defining_Entity (Unit_Node); elsif Unit_Kind = N_Function_Instantiation or else Unit_Kind = N_Package_Instantiation or else Unit_Kind = N_Procedure_Instantiation then Unit_Name := Defining_Entity (Unit_Node); else Unit_Name := Cunit_Entity (Current_Sem_Unit); end if; if Chars (Unit_Name) /= Chars (Entity (Expression (Arg1))) then Error_Pragma_Arg ("pragma% argument is not current unit name", Arg1); end if; if Ekind (Unit_Name) = E_Package and then Present (Renamed_Entity (Unit_Name)) then Error_Pragma ("pragma% not allowed for renamed package"); end if; end if; -- Pragma appears other than after a compilation unit else -- Here we check for the generic instantiation case and also -- for the case of processing a generic formal package. We -- detect these cases by noting that the Sloc on the node -- does not belong to the current compilation unit. Sindex := Source_Index (Current_Sem_Unit); if Loc not in Source_First (Sindex) .. Source_Last (Sindex) then Rewrite (N, Make_Null_Statement (Loc)); return; -- If before first declaration, the pragma applies to the -- enclosing unit, and the name if present must be this name. elsif Is_Before_First_Decl (N, Plist) then Unit_Node := Unit_Declaration_Node (Current_Scope); Unit_Kind := Nkind (Unit_Node); if Nkind (Parent (Unit_Node)) /= N_Compilation_Unit then Pragma_Misplaced; elsif Unit_Kind = N_Subprogram_Body and then not Acts_As_Spec (Unit_Node) then Pragma_Misplaced; elsif Nkind (Parent_Node) = N_Package_Body then Pragma_Misplaced; elsif Nkind (Parent_Node) = N_Package_Specification and then Plist = Private_Declarations (Parent_Node) then Pragma_Misplaced; elsif (Nkind (Parent_Node) = N_Generic_Package_Declaration or else Nkind (Parent_Node) = N_Generic_Subprogram_Declaration) and then Plist = Generic_Formal_Declarations (Parent_Node) then Pragma_Misplaced; elsif Arg_Count > 0 then Analyze (Expression (Arg1)); if Entity (Expression (Arg1)) /= Current_Scope then Error_Pragma_Arg ("name in pragma% must be enclosing unit", Arg1); end if; -- It is legal to have no argument in this context else return; end if; -- Error if not before first declaration. This is because a -- library unit pragma argument must be the name of a library -- unit (RM 10.1.5(7)), but the only names permitted in this -- context are (RM 10.1.5(6)) names of subprogram declarations, -- generic subprogram declarations or generic instantiations. else Error_Pragma ("pragma% misplaced, must be before first declaration"); end if; end if; end if; end Check_Valid_Library_Unit_Pragma; ------------------ -- Error_Pragma -- ------------------ procedure Error_Pragma (Msg : String) is begin Error_Msg_Name_1 := Chars (N); Error_Msg_N (Msg, N); raise Pragma_Exit; end Error_Pragma; ---------------------- -- Error_Pragma_Arg -- ---------------------- procedure Error_Pragma_Arg (Msg : String; Arg : Node_Id) is begin Error_Msg_Name_1 := Chars (N); Error_Msg_N (Msg, Get_Pragma_Arg (Arg)); raise Pragma_Exit; end Error_Pragma_Arg; procedure Error_Pragma_Arg (Msg1, Msg2 : String; Arg : Node_Id) is begin Error_Msg_Name_1 := Chars (N); Error_Msg_N (Msg1, Get_Pragma_Arg (Arg)); Error_Pragma_Arg (Msg2, Arg); end Error_Pragma_Arg; ---------------------------- -- Error_Pragma_Arg_Ident -- ---------------------------- procedure Error_Pragma_Arg_Ident (Msg : String; Arg : Node_Id) is begin Error_Msg_Name_1 := Chars (N); Error_Msg_N (Msg, Arg); raise Pragma_Exit; end Error_Pragma_Arg_Ident; ------------------------ -- Find_Lib_Unit_Name -- ------------------------ function Find_Lib_Unit_Name return Entity_Id is begin -- Return inner compilation unit entity, for case of nested -- categorization pragmas. This happens in generic unit. if Nkind (Parent (N)) = N_Package_Specification and then Defining_Entity (Parent (N)) /= Current_Scope then return Defining_Entity (Parent (N)); else return Current_Scope; end if; end Find_Lib_Unit_Name; ---------------------------- -- Find_Program_Unit_Name -- ---------------------------- procedure Find_Program_Unit_Name (Id : Node_Id) is Unit_Name : Entity_Id; Unit_Kind : Node_Kind; P : constant Node_Id := Parent (N); begin if Nkind (P) = N_Compilation_Unit then Unit_Kind := Nkind (Unit (P)); if Unit_Kind = N_Subprogram_Declaration or else Unit_Kind = N_Package_Declaration or else Unit_Kind in N_Generic_Declaration then Unit_Name := Defining_Entity (Unit (P)); if Chars (Id) = Chars (Unit_Name) then Set_Entity (Id, Unit_Name); Set_Etype (Id, Etype (Unit_Name)); else Set_Etype (Id, Any_Type); Error_Pragma ("cannot find program unit referenced by pragma%"); end if; else Set_Etype (Id, Any_Type); Error_Pragma ("pragma% inapplicable to this unit"); end if; else Analyze (Id); end if; end Find_Program_Unit_Name; ------------------------- -- Gather_Associations -- ------------------------- procedure Gather_Associations (Names : Name_List; Args : out Args_List) is Arg : Node_Id; begin -- Initialize all parameters to Empty for J in Args'Range loop Args (J) := Empty; end loop; -- That's all we have to do if there are no argument associations if No (Pragma_Argument_Associations (N)) then return; end if; -- Otherwise first deal with any positional parameters present Arg := First (Pragma_Argument_Associations (N)); for Index in Args'Range loop exit when No (Arg) or else Chars (Arg) /= No_Name; Args (Index) := Expression (Arg); Next (Arg); end loop; -- Positional parameters all processed, if any left, then we -- have too many positional parameters. if Present (Arg) and then Chars (Arg) = No_Name then Error_Pragma_Arg ("too many positional associations for pragma%", Arg); end if; -- Process named parameters if any are present while Present (Arg) loop if Chars (Arg) = No_Name then Error_Pragma_Arg ("positional association cannot follow named association", Arg); else for Index in Names'Range loop if Names (Index) = Chars (Arg) then if Present (Args (Index)) then Error_Pragma_Arg ("duplicate argument association for pragma%", Arg); else Args (Index) := Expression (Arg); exit; end if; end if; if Index = Names'Last then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("pragma% does not allow & argument", Arg); -- Check for possible misspelling for Index1 in Names'Range loop if Is_Bad_Spelling_Of (Get_Name_String (Chars (Arg)), Get_Name_String (Names (Index1))) then Error_Msg_Name_1 := Names (Index1); Error_Msg_N ("\possible misspelling of%", Arg); exit; end if; end loop; raise Pragma_Exit; end if; end loop; end if; Next (Arg); end loop; end Gather_Associations; -------------------- -- Get_Pragma_Arg -- -------------------- function Get_Pragma_Arg (Arg : Node_Id) return Node_Id is begin if Nkind (Arg) = N_Pragma_Argument_Association then return Expression (Arg); else return Arg; end if; end Get_Pragma_Arg; ----------------- -- GNAT_Pragma -- ----------------- procedure GNAT_Pragma is begin Check_Restriction (No_Implementation_Pragmas, N); end GNAT_Pragma; -------------------------- -- Is_Before_First_Decl -- -------------------------- function Is_Before_First_Decl (Pragma_Node : Node_Id; Decls : List_Id) return Boolean is Item : Node_Id := First (Decls); begin -- Only other pragmas can come before this pragma loop if No (Item) or else Nkind (Item) /= N_Pragma then return False; elsif Item = Pragma_Node then return True; end if; Next (Item); end loop; end Is_Before_First_Decl; ----------------------------- -- Is_Configuration_Pragma -- ----------------------------- -- A configuration pragma must appear in the context clause of -- a compilation unit, at the start of the list (i.e. only other -- pragmas may precede it). function Is_Configuration_Pragma return Boolean is Lis : constant List_Id := List_Containing (N); Par : constant Node_Id := Parent (N); Prg : Node_Id; begin -- If no parent, then we are in the configuration pragma file, -- so the placement is definitely appropriate. if No (Par) then return True; -- Otherwise we must be in the context clause of a compilation unit -- and the only thing allowed before us in the context list is more -- configuration pragmas. elsif Nkind (Par) = N_Compilation_Unit and then Context_Items (Par) = Lis then Prg := First (Lis); loop if Prg = N then return True; elsif Nkind (Prg) /= N_Pragma then return False; end if; Next (Prg); end loop; else return False; end if; end Is_Configuration_Pragma; ---------------------- -- Pragma_Misplaced -- ---------------------- procedure Pragma_Misplaced is begin Error_Pragma ("incorrect placement of pragma%"); end Pragma_Misplaced; ------------------------------------ -- Process Atomic_Shared_Volatile -- ------------------------------------ procedure Process_Atomic_Shared_Volatile is E_Id : Node_Id; E : Entity_Id; D : Node_Id; K : Node_Kind; Utyp : Entity_Id; begin Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); D := Declaration_Node (E); K := Nkind (D); if Is_Type (E) then if Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N) then return; else Check_First_Subtype (Arg1); end if; if Prag_Id /= Pragma_Volatile then Set_Is_Atomic (E); Set_Is_Atomic (Underlying_Type (E)); end if; -- Attribute belongs on the base type. If the -- view of the type is currently private, it also -- belongs on the underlying type. Set_Is_Volatile (Base_Type (E)); Set_Is_Volatile (Underlying_Type (E)); Set_Treat_As_Volatile (E); Set_Treat_As_Volatile (Underlying_Type (E)); elsif K = N_Object_Declaration or else (K = N_Component_Declaration and then Original_Record_Component (E) = E) then if Rep_Item_Too_Late (E, N) then return; end if; if Prag_Id /= Pragma_Volatile then Set_Is_Atomic (E); -- If the object declaration has an explicit -- initialization, a temporary may have to be -- created to hold the expression, to insure -- that access to the object remain atomic. if Nkind (Parent (E)) = N_Object_Declaration and then Present (Expression (Parent (E))) then Set_Has_Delayed_Freeze (E); end if; -- An interesting improvement here. If an object of type X -- is declared atomic, and the type X is not atomic, that's -- a pity, since it may not have appropraite alignment etc. -- We can rescue this in the special case where the object -- and type are in the same unit by just setting the type -- as atomic, so that the back end will process it as atomic. Utyp := Underlying_Type (Etype (E)); if Present (Utyp) and then Sloc (E) > No_Location and then Sloc (Utyp) > No_Location and then Get_Source_File_Index (Sloc (E)) = Get_Source_File_Index (Sloc (Underlying_Type (Etype (E)))) then Set_Is_Atomic (Underlying_Type (Etype (E))); end if; end if; Set_Is_Volatile (E); Set_Treat_As_Volatile (E); else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; end Process_Atomic_Shared_Volatile; ------------------------ -- Process_Convention -- ------------------------ procedure Process_Convention (C : out Convention_Id; E : out Entity_Id) is Id : Node_Id; E1 : Entity_Id; Comp_Unit : Unit_Number_Type; Cname : Name_Id; procedure Set_Convention_From_Pragma (E : Entity_Id); -- Set convention in entity E, and also flag that the entity has a -- convention pragma. If entity is for a private or incomplete type, -- also set convention and flag on underlying type. This procedure -- also deals with the special case of C_Pass_By_Copy convention. -------------------------------- -- Set_Convention_From_Pragma -- -------------------------------- procedure Set_Convention_From_Pragma (E : Entity_Id) is begin Set_Convention (E, C); Set_Has_Convention_Pragma (E); if Is_Incomplete_Or_Private_Type (E) then Set_Convention (Underlying_Type (E), C); Set_Has_Convention_Pragma (Underlying_Type (E), True); end if; -- A class-wide type should inherit the convention of -- the specific root type (although this isn't specified -- clearly by the RM). if Is_Type (E) and then Present (Class_Wide_Type (E)) then Set_Convention (Class_Wide_Type (E), C); end if; -- If the entity is a record type, then check for special case -- of C_Pass_By_Copy, which is treated the same as C except that -- the special record flag is set. This convention is also only -- permitted on record types (see AI95-00131). if Cname = Name_C_Pass_By_Copy then if Is_Record_Type (E) then Set_C_Pass_By_Copy (Base_Type (E)); elsif Is_Incomplete_Or_Private_Type (E) and then Is_Record_Type (Underlying_Type (E)) then Set_C_Pass_By_Copy (Base_Type (Underlying_Type (E))); else Error_Pragma_Arg ("C_Pass_By_Copy convention allowed only for record type", Arg2); end if; end if; -- If the entity is a derived boolean type, check for the -- special case of convention C, C++, or Fortran, where we -- consider any nonzero value to represent true. if Is_Discrete_Type (E) and then Root_Type (Etype (E)) = Standard_Boolean and then (C = Convention_C or else C = Convention_CPP or else C = Convention_Fortran) then Set_Nonzero_Is_True (Base_Type (E)); end if; end Set_Convention_From_Pragma; -- Start of processing for Process_Convention begin Check_At_Least_N_Arguments (2); Check_Arg_Is_Identifier (Arg1); Check_Optional_Identifier (Arg1, Name_Convention); Cname := Chars (Expression (Arg1)); -- C_Pass_By_Copy is treated as a synonym for convention C -- (this is tested again below to set the critical flag) if Cname = Name_C_Pass_By_Copy then C := Convention_C; -- Otherwise we must have something in the standard convention list elsif Is_Convention_Name (Cname) then C := Get_Convention_Id (Chars (Expression (Arg1))); -- In DEC VMS, it seems that there is an undocumented feature -- that any unrecognized convention is treated as the default, -- which for us is convention C. It does not seem so terrible -- to do this unconditionally, silently in the VMS case, and -- with a warning in the non-VMS case. else if Warn_On_Export_Import and not OpenVMS_On_Target then Error_Msg_N ("?unrecognized convention name, C assumed", Expression (Arg1)); end if; C := Convention_C; end if; Check_Arg_Is_Local_Name (Arg2); Check_Optional_Identifier (Arg2, Name_Entity); Id := Expression (Arg2); Analyze (Id); if not Is_Entity_Name (Id) then Error_Pragma_Arg ("entity name required", Arg2); end if; E := Entity (Id); -- Go to renamed subprogram if present, since convention applies -- to the actual renamed entity, not to the renaming entity. if Is_Subprogram (E) and then Present (Alias (E)) and then Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Renaming_Declaration then E := Alias (E); end if; -- Check that we not applying this to a specless body if Is_Subprogram (E) and then Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Body then Error_Pragma ("pragma% requires separate spec and must come before body"); end if; -- Check that we are not applying this to a named constant if Ekind (E) = E_Named_Integer or else Ekind (E) = E_Named_Real then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("cannot apply pragma% to named constant!", Get_Pragma_Arg (Arg2)); Error_Pragma_Arg ("\supply appropriate type for&!", Arg2); end if; if Etype (E) = Any_Type or else Rep_Item_Too_Early (E, N) then raise Pragma_Exit; else E := Underlying_Type (E); end if; if Rep_Item_Too_Late (E, N) then raise Pragma_Exit; end if; if Has_Convention_Pragma (E) then Error_Pragma_Arg ("at most one Convention/Export/Import pragma is allowed", Arg2); elsif Convention (E) = Convention_Protected or else Ekind (Scope (E)) = E_Protected_Type then Error_Pragma_Arg ("a protected operation cannot be given a different convention", Arg2); end if; -- For Intrinsic, a subprogram is required if C = Convention_Intrinsic and then not Is_Subprogram (E) and then not Is_Generic_Subprogram (E) then Error_Pragma_Arg ("second argument of pragma% must be a subprogram", Arg2); end if; -- For Stdcall, a subprogram, variable or subprogram type is required if C = Convention_Stdcall and then not Is_Subprogram (E) and then not Is_Generic_Subprogram (E) and then Ekind (E) /= E_Variable and then not (Is_Access_Type (E) and then Ekind (Designated_Type (E)) = E_Subprogram_Type) then Error_Pragma_Arg ("second argument of pragma% must be subprogram (type)", Arg2); end if; if not Is_Subprogram (E) and then not Is_Generic_Subprogram (E) then Set_Convention_From_Pragma (E); if Is_Type (E) then Check_First_Subtype (Arg2); Set_Convention_From_Pragma (Base_Type (E)); -- For subprograms, we must set the convention on the -- internally generated directly designated type as well. if Ekind (E) = E_Access_Subprogram_Type then Set_Convention_From_Pragma (Directly_Designated_Type (E)); end if; end if; -- For the subprogram case, set proper convention for all homonyms -- in same compilation unit. -- Is the test of compilation unit really necessary ??? -- What about subprogram renamings here??? else Comp_Unit := Get_Source_Unit (E); Set_Convention_From_Pragma (E); -- Treat a pragma Import as an implicit body, for GPS use. if Prag_Id = Pragma_Import then Generate_Reference (E, Id, 'b'); end if; E1 := E; loop E1 := Homonym (E1); exit when No (E1) or else Scope (E1) /= Current_Scope; -- Note: below we are missing a check for Rep_Item_Too_Late. -- That is deliberate, we cannot chain the rep item on more -- than one Rep_Item chain, to be fixed later ??? if Comp_Unit = Get_Source_Unit (E1) then Set_Convention_From_Pragma (E1); if Prag_Id = Pragma_Import then Generate_Reference (E, Id, 'b'); end if; end if; end loop; end if; end Process_Convention; ----------------------------------------------------- -- Process_Extended_Import_Export_Exception_Pragma -- ----------------------------------------------------- procedure Process_Extended_Import_Export_Exception_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Form : Node_Id; Arg_Code : Node_Id) is Def_Id : Entity_Id; Code_Val : Uint; begin GNAT_Pragma; if not OpenVMS_On_Target then Error_Pragma ("?pragma% ignored (applies only to Open'V'M'S)"); end if; Process_Extended_Import_Export_Internal_Arg (Arg_Internal); Def_Id := Entity (Arg_Internal); if Ekind (Def_Id) /= E_Exception then Error_Pragma_Arg ("pragma% must refer to declared exception", Arg_Internal); end if; Set_Extended_Import_Export_External_Name (Def_Id, Arg_External); if Present (Arg_Form) then Check_Arg_Is_One_Of (Arg_Form, Name_Ada, Name_VMS); end if; if Present (Arg_Form) and then Chars (Arg_Form) = Name_Ada then null; else Set_Is_VMS_Exception (Def_Id); Set_Exception_Code (Def_Id, No_Uint); end if; if Present (Arg_Code) then if not Is_VMS_Exception (Def_Id) then Error_Pragma_Arg ("Code option for pragma% not allowed for Ada case", Arg_Code); end if; Check_Arg_Is_Static_Expression (Arg_Code, Any_Integer); Code_Val := Expr_Value (Arg_Code); if not UI_Is_In_Int_Range (Code_Val) then Error_Pragma_Arg ("Code option for pragma% must be in 32-bit range", Arg_Code); else Set_Exception_Code (Def_Id, Code_Val); end if; end if; end Process_Extended_Import_Export_Exception_Pragma; ------------------------------------------------- -- Process_Extended_Import_Export_Internal_Arg -- ------------------------------------------------- procedure Process_Extended_Import_Export_Internal_Arg (Arg_Internal : Node_Id := Empty) is begin GNAT_Pragma; if No (Arg_Internal) then Error_Pragma ("Internal parameter required for pragma%"); end if; if Nkind (Arg_Internal) = N_Identifier then null; elsif Nkind (Arg_Internal) = N_Operator_Symbol and then (Prag_Id = Pragma_Import_Function or else Prag_Id = Pragma_Export_Function) then null; else Error_Pragma_Arg ("wrong form for Internal parameter for pragma%", Arg_Internal); end if; Check_Arg_Is_Local_Name (Arg_Internal); end Process_Extended_Import_Export_Internal_Arg; -------------------------------------------------- -- Process_Extended_Import_Export_Object_Pragma -- -------------------------------------------------- procedure Process_Extended_Import_Export_Object_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Size : Node_Id) is Def_Id : Entity_Id; begin Process_Extended_Import_Export_Internal_Arg (Arg_Internal); Def_Id := Entity (Arg_Internal); if Ekind (Def_Id) /= E_Constant and then Ekind (Def_Id) /= E_Variable then Error_Pragma_Arg ("pragma% must designate an object", Arg_Internal); end if; if Is_Psected (Def_Id) then Error_Pragma_Arg ("previous Psect_Object applies, pragma % not permitted", Arg_Internal); end if; if Rep_Item_Too_Late (Def_Id, N) then raise Pragma_Exit; end if; Set_Extended_Import_Export_External_Name (Def_Id, Arg_External); if Present (Arg_Size) and then Nkind (Arg_Size) /= N_Identifier and then Nkind (Arg_Size) /= N_String_Literal then Error_Pragma_Arg ("pragma% Size argument must be identifier or string literal", Arg_Size); end if; -- Export_Object case if Prag_Id = Pragma_Export_Object then if not Is_Library_Level_Entity (Def_Id) then Error_Pragma_Arg ("argument for pragma% must be library level entity", Arg_Internal); end if; if Ekind (Current_Scope) = E_Generic_Package then Error_Pragma ("pragma& cannot appear in a generic unit"); end if; if not Size_Known_At_Compile_Time (Etype (Def_Id)) then Error_Pragma_Arg ("exported object must have compile time known size", Arg_Internal); end if; if Warn_On_Export_Import and then Is_Exported (Def_Id) then Error_Msg_N ("?duplicate Export_Object pragma", N); else Set_Exported (Def_Id, Arg_Internal); end if; -- Import_Object case else if Is_Concurrent_Type (Etype (Def_Id)) then Error_Pragma_Arg ("cannot use pragma% for task/protected object", Arg_Internal); end if; if Ekind (Def_Id) = E_Constant then Error_Pragma_Arg ("cannot import a constant", Arg_Internal); end if; if Warn_On_Export_Import and then Has_Discriminants (Etype (Def_Id)) then Error_Msg_N ("imported value must be initialized?", Arg_Internal); end if; if Warn_On_Export_Import and then Is_Access_Type (Etype (Def_Id)) then Error_Pragma_Arg ("cannot import object of an access type?", Arg_Internal); end if; if Warn_On_Export_Import and then Is_Imported (Def_Id) then Error_Msg_N ("?duplicate Import_Object pragma", N); -- Check for explicit initialization present. Note that an -- initialization that generated by the code generator, e.g. -- for an access type, does not count here. elsif Present (Expression (Parent (Def_Id))) and then Comes_From_Source (Original_Node (Expression (Parent (Def_Id)))) then Error_Msg_Sloc := Sloc (Def_Id); Error_Pragma_Arg ("no initialization allowed for declaration of& #", "\imported entities cannot be initialized ('R'M' 'B.1(24))", Arg1); else Set_Imported (Def_Id); Note_Possible_Modification (Arg_Internal); end if; end if; end Process_Extended_Import_Export_Object_Pragma; ------------------------------------------------------ -- Process_Extended_Import_Export_Subprogram_Pragma -- ------------------------------------------------------ procedure Process_Extended_Import_Export_Subprogram_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Parameter_Types : Node_Id; Arg_Result_Type : Node_Id := Empty; Arg_Mechanism : Node_Id; Arg_Result_Mechanism : Node_Id := Empty; Arg_First_Optional_Parameter : Node_Id := Empty) is Ent : Entity_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; Formal : Entity_Id; Ambiguous : Boolean; Match : Boolean; Dval : Node_Id; function Same_Base_Type (Ptype : Node_Id; Formal : Entity_Id) return Boolean; -- Determines if Ptype references the type of Formal. Note that -- only the base types need to match according to the spec. Ptype -- here is the argument from the pragma, which is either a type -- name, or an access attribute. -------------------- -- Same_Base_Type -- -------------------- function Same_Base_Type (Ptype : Node_Id; Formal : Entity_Id) return Boolean is Ftyp : constant Entity_Id := Base_Type (Etype (Formal)); Pref : Node_Id; begin -- Case where pragma argument is typ'Access if Nkind (Ptype) = N_Attribute_Reference and then Attribute_Name (Ptype) = Name_Access then Pref := Prefix (Ptype); Find_Type (Pref); if not Is_Entity_Name (Pref) or else Entity (Pref) = Any_Type then raise Pragma_Exit; end if; -- We have a match if the corresponding argument is of an -- anonymous access type, and its designicated type matches -- the type of the prefix of the access attribute return Ekind (Ftyp) = E_Anonymous_Access_Type and then Base_Type (Entity (Pref)) = Base_Type (Etype (Designated_Type (Ftyp))); -- Case where pragma argument is a type name else Find_Type (Ptype); if not Is_Entity_Name (Ptype) or else Entity (Ptype) = Any_Type then raise Pragma_Exit; end if; -- We have a match if the corresponding argument is of -- the type given in the pragma (comparing base types) return Base_Type (Entity (Ptype)) = Ftyp; end if; end Same_Base_Type; -- Start of processing for -- Process_Extended_Import_Export_Subprogram_Pragma begin Process_Extended_Import_Export_Internal_Arg (Arg_Internal); Hom_Id := Entity (Arg_Internal); Ent := Empty; Ambiguous := False; -- Loop through homonyms (overloadings) of Hom_Id while Present (Hom_Id) loop Def_Id := Get_Base_Subprogram (Hom_Id); -- We need a subprogram in the current scope if not Is_Subprogram (Def_Id) or else Scope (Def_Id) /= Current_Scope then null; else Match := True; -- Pragma cannot apply to subprogram body if Is_Subprogram (Def_Id) and then Nkind (Parent (Declaration_Node (Def_Id))) = N_Subprogram_Body then Error_Pragma ("pragma% requires separate spec" & " and must come before body"); end if; -- Test result type if given, note that the result type -- parameter can only be present for the function cases. if Present (Arg_Result_Type) and then not Same_Base_Type (Arg_Result_Type, Def_Id) then Match := False; elsif Etype (Def_Id) /= Standard_Void_Type and then (Chars (N) = Name_Export_Procedure or else Chars (N) = Name_Import_Procedure) then Match := False; -- Test parameter types if given. Note that this parameter -- has not been analyzed (and must not be, since it is -- semantic nonsense), so we get it as the parser left it. elsif Present (Arg_Parameter_Types) then Check_Matching_Types : declare Formal : Entity_Id; Ptype : Node_Id; begin Formal := First_Formal (Def_Id); if Nkind (Arg_Parameter_Types) = N_Null then if Present (Formal) then Match := False; end if; -- A list of one type, e.g. (List) is parsed as -- a parenthesized expression. elsif Nkind (Arg_Parameter_Types) /= N_Aggregate and then Paren_Count (Arg_Parameter_Types) = 1 then if No (Formal) or else Present (Next_Formal (Formal)) then Match := False; else Match := Same_Base_Type (Arg_Parameter_Types, Formal); end if; -- A list of more than one type is parsed as a aggregate elsif Nkind (Arg_Parameter_Types) = N_Aggregate and then Paren_Count (Arg_Parameter_Types) = 0 then Ptype := First (Expressions (Arg_Parameter_Types)); while Present (Ptype) or else Present (Formal) loop if No (Ptype) or else No (Formal) or else not Same_Base_Type (Ptype, Formal) then Match := False; exit; else Next_Formal (Formal); Next (Ptype); end if; end loop; -- Anything else is of the wrong form else Error_Pragma_Arg ("wrong form for Parameter_Types parameter", Arg_Parameter_Types); end if; end Check_Matching_Types; end if; -- Match is now False if the entry we found did not match -- either a supplied Parameter_Types or Result_Types argument if Match then if No (Ent) then Ent := Def_Id; -- Ambiguous case, the flag Ambiguous shows if we already -- detected this and output the initial messages. else if not Ambiguous then Ambiguous := True; Error_Msg_Name_1 := Chars (N); Error_Msg_N ("pragma% does not uniquely identify subprogram!", N); Error_Msg_Sloc := Sloc (Ent); Error_Msg_N ("matching subprogram #!", N); Ent := Empty; end if; Error_Msg_Sloc := Sloc (Def_Id); Error_Msg_N ("matching subprogram #!", N); end if; end if; end if; Hom_Id := Homonym (Hom_Id); end loop; -- See if we found an entry if No (Ent) then if not Ambiguous then if Is_Generic_Subprogram (Entity (Arg_Internal)) then Error_Pragma ("pragma% cannot be given for generic subprogram"); else Error_Pragma ("pragma% does not identify local subprogram"); end if; end if; return; end if; -- Import pragmas must be be for imported entities if Prag_Id = Pragma_Import_Function or else Prag_Id = Pragma_Import_Procedure or else Prag_Id = Pragma_Import_Valued_Procedure then if not Is_Imported (Ent) then Error_Pragma ("pragma Import or Interface must precede pragma%"); end if; -- Here we have the Export case which can set the entity as exported -- But does not do so if the specified external name is null, -- since that is taken as a signal in DEC Ada 83 (with which -- we want to be compatible) to request no external name. elsif Nkind (Arg_External) = N_String_Literal and then String_Length (Strval (Arg_External)) = 0 then null; -- In all other cases, set entit as exported else Set_Exported (Ent, Arg_Internal); end if; -- Special processing for Valued_Procedure cases if Prag_Id = Pragma_Import_Valued_Procedure or else Prag_Id = Pragma_Export_Valued_Procedure then Formal := First_Formal (Ent); if No (Formal) then Error_Pragma ("at least one parameter required for pragma%"); elsif Ekind (Formal) /= E_Out_Parameter then Error_Pragma ("first parameter must have mode out for pragma%"); else Set_Is_Valued_Procedure (Ent); end if; end if; Set_Extended_Import_Export_External_Name (Ent, Arg_External); -- Process Result_Mechanism argument if present. We have already -- checked that this is only allowed for the function case. if Present (Arg_Result_Mechanism) then Set_Mechanism_Value (Ent, Arg_Result_Mechanism); end if; -- Process Mechanism parameter if present. Note that this parameter -- is not analyzed, and must not be analyzed since it is semantic -- nonsense, so we get it in exactly as the parser left it. if Present (Arg_Mechanism) then declare Formal : Entity_Id; Massoc : Node_Id; Mname : Node_Id; Choice : Node_Id; begin -- A single mechanism association without a formal parameter -- name is parsed as a parenthesized expression. All other -- cases are parsed as aggregates, so we rewrite the single -- parameter case as an aggregate for consistency. if Nkind (Arg_Mechanism) /= N_Aggregate and then Paren_Count (Arg_Mechanism) = 1 then Rewrite (Arg_Mechanism, Make_Aggregate (Sloc (Arg_Mechanism), Expressions => New_List ( Relocate_Node (Arg_Mechanism)))); end if; -- Case of only mechanism name given, applies to all formals if Nkind (Arg_Mechanism) /= N_Aggregate then Formal := First_Formal (Ent); while Present (Formal) loop Set_Mechanism_Value (Formal, Arg_Mechanism); Next_Formal (Formal); end loop; -- Case of list of mechanism associations given else if Null_Record_Present (Arg_Mechanism) then Error_Pragma_Arg ("inappropriate form for Mechanism parameter", Arg_Mechanism); end if; -- Deal with positional ones first Formal := First_Formal (Ent); if Present (Expressions (Arg_Mechanism)) then Mname := First (Expressions (Arg_Mechanism)); while Present (Mname) loop if No (Formal) then Error_Pragma_Arg ("too many mechanism associations", Mname); end if; Set_Mechanism_Value (Formal, Mname); Next_Formal (Formal); Next (Mname); end loop; end if; -- Deal with named entries if Present (Component_Associations (Arg_Mechanism)) then Massoc := First (Component_Associations (Arg_Mechanism)); while Present (Massoc) loop Choice := First (Choices (Massoc)); if Nkind (Choice) /= N_Identifier or else Present (Next (Choice)) then Error_Pragma_Arg ("incorrect form for mechanism association", Massoc); end if; Formal := First_Formal (Ent); loop if No (Formal) then Error_Pragma_Arg ("parameter name & not present", Choice); end if; if Chars (Choice) = Chars (Formal) then Set_Mechanism_Value (Formal, Expression (Massoc)); exit; end if; Next_Formal (Formal); end loop; Next (Massoc); end loop; end if; end if; end; end if; -- Process First_Optional_Parameter argument if present. We have -- already checked that this is only allowed for the Import case. if Present (Arg_First_Optional_Parameter) then if Nkind (Arg_First_Optional_Parameter) /= N_Identifier then Error_Pragma_Arg ("first optional parameter must be formal parameter name", Arg_First_Optional_Parameter); end if; Formal := First_Formal (Ent); loop if No (Formal) then Error_Pragma_Arg ("specified formal parameter& not found", Arg_First_Optional_Parameter); end if; exit when Chars (Formal) = Chars (Arg_First_Optional_Parameter); Next_Formal (Formal); end loop; Set_First_Optional_Parameter (Ent, Formal); -- Check specified and all remaining formals have right form while Present (Formal) loop if Ekind (Formal) /= E_In_Parameter then Error_Msg_NE ("optional formal& is not of mode in!", Arg_First_Optional_Parameter, Formal); else Dval := Default_Value (Formal); if not Present (Dval) then Error_Msg_NE ("optional formal& does not have default value!", Arg_First_Optional_Parameter, Formal); elsif Compile_Time_Known_Value_Or_Aggr (Dval) then null; else Error_Msg_FE ("default value for optional formal& is non-static!", Arg_First_Optional_Parameter, Formal); end if; end if; Set_Is_Optional_Parameter (Formal); Next_Formal (Formal); end loop; end if; end Process_Extended_Import_Export_Subprogram_Pragma; -------------------------- -- Process_Generic_List -- -------------------------- procedure Process_Generic_List is Arg : Node_Id; Exp : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Least_N_Arguments (1); Arg := Arg1; while Present (Arg) loop Exp := Expression (Arg); Analyze (Exp); if not Is_Entity_Name (Exp) or else (not Is_Generic_Instance (Entity (Exp)) and then not Is_Generic_Unit (Entity (Exp))) then Error_Pragma_Arg ("pragma% argument must be name of generic unit/instance", Arg); end if; Next (Arg); end loop; end Process_Generic_List; --------------------------------- -- Process_Import_Or_Interface -- --------------------------------- procedure Process_Import_Or_Interface is C : Convention_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; begin Process_Convention (C, Def_Id); Kill_Size_Check_Code (Def_Id); Note_Possible_Modification (Expression (Arg2)); if Ekind (Def_Id) = E_Variable or else Ekind (Def_Id) = E_Constant then -- User initialization is not allowed for imported object, but -- the object declaration may contain a default initialization, -- that will be discarded. Note that an explicit initialization -- only counts if it comes from source, otherwise it is simply -- the code generator making an implicit initialization explicit. if Present (Expression (Parent (Def_Id))) and then Comes_From_Source (Expression (Parent (Def_Id))) then Error_Msg_Sloc := Sloc (Def_Id); Error_Pragma_Arg ("no initialization allowed for declaration of& #", "\imported entities cannot be initialized ('R'M' 'B.1(24))", Arg2); else Set_Imported (Def_Id); Set_Is_Public (Def_Id); Process_Interface_Name (Def_Id, Arg3, Arg4); -- It is not possible to import a constant of an unconstrained -- array type (e.g. string) because there is no simple way to -- write a meaningful subtype for it. if Is_Array_Type (Etype (Def_Id)) and then not Is_Constrained (Etype (Def_Id)) then Error_Msg_NE ("imported constant& must have a constrained subtype", N, Def_Id); end if; end if; elsif Is_Subprogram (Def_Id) or else Is_Generic_Subprogram (Def_Id) then -- If the name is overloaded, pragma applies to all of the -- denoted entities in the same declarative part. Hom_Id := Def_Id; while Present (Hom_Id) loop Def_Id := Get_Base_Subprogram (Hom_Id); -- Ignore inherited subprograms because the pragma will -- apply to the parent operation, which is the one called. if Is_Overloadable (Def_Id) and then Present (Alias (Def_Id)) then null; -- If it is not a subprogram, it must be in an outer -- scope and pragma does not apply. elsif not Is_Subprogram (Def_Id) and then not Is_Generic_Subprogram (Def_Id) then null; -- Verify that the homonym is in the same declarative -- part (not just the same scope). elsif Parent (Unit_Declaration_Node (Def_Id)) /= Parent (N) and then Nkind (Parent (N)) /= N_Compilation_Unit_Aux then exit; else Set_Imported (Def_Id); -- If Import intrinsic, set intrinsic flag -- and verify that it is known as such. if C = Convention_Intrinsic then Set_Is_Intrinsic_Subprogram (Def_Id); Check_Intrinsic_Subprogram (Def_Id, Expression (Arg2)); end if; -- All interfaced procedures need an external -- symbol created for them since they are -- always referenced from another object file. Set_Is_Public (Def_Id); -- Verify that the subprogram does not have a completion -- through a renaming declaration. For other completions -- the pragma appears as a too late representation. declare Decl : constant Node_Id := Unit_Declaration_Node (Def_Id); begin if Present (Decl) and then Nkind (Decl) = N_Subprogram_Declaration and then Present (Corresponding_Body (Decl)) and then Nkind (Unit_Declaration_Node (Corresponding_Body (Decl))) = N_Subprogram_Renaming_Declaration then Error_Msg_Sloc := Sloc (Def_Id); Error_Msg_NE ("cannot import&#," & " already completed by a renaming", N, Def_Id); end if; end; Set_Has_Completion (Def_Id); Process_Interface_Name (Def_Id, Arg3, Arg4); end if; if Is_Compilation_Unit (Hom_Id) then -- Its possible homonyms are not affected by the pragma. -- Such homonyms might be present in the context of other -- units being compiled. exit; else Hom_Id := Homonym (Hom_Id); end if; end loop; -- When the convention is Java, we also allow Import to be given -- for packages, exceptions, and record components. elsif C = Convention_Java and then (Ekind (Def_Id) = E_Package or else Ekind (Def_Id) = E_Exception or else Nkind (Parent (Def_Id)) = N_Component_Declaration) then Set_Imported (Def_Id); Set_Is_Public (Def_Id); Process_Interface_Name (Def_Id, Arg3, Arg4); else Error_Pragma_Arg ("second argument of pragma% must be object or subprogram", Arg2); end if; -- If this pragma applies to a compilation unit, then the unit, -- which is a subprogram, does not require (or allow) a body. -- We also do not need to elaborate imported procedures. if Nkind (Parent (N)) = N_Compilation_Unit_Aux then declare Cunit : constant Node_Id := Parent (Parent (N)); begin Set_Body_Required (Cunit, False); end; end if; end Process_Import_Or_Interface; -------------------- -- Process_Inline -- -------------------- procedure Process_Inline (Active : Boolean) is Assoc : Node_Id; Decl : Node_Id; Subp_Id : Node_Id; Subp : Entity_Id; Applies : Boolean; Effective : Boolean := False; procedure Make_Inline (Subp : Entity_Id); -- Subp is the defining unit name of the subprogram -- declaration. Set the flag, as well as the flag in the -- corresponding body, if there is one present. procedure Set_Inline_Flags (Subp : Entity_Id); -- Sets Is_Inlined and Has_Pragma_Inline flags for Subp function Back_End_Cannot_Inline (Subp : Entity_Id) return Boolean; -- Do not set the inline flag if body is available and contains -- exception handlers, to prevent undefined symbols at link time. ---------------------------- -- Back_End_Cannot_Inline -- ---------------------------- function Back_End_Cannot_Inline (Subp : Entity_Id) return Boolean is Decl : constant Node_Id := Unit_Declaration_Node (Subp); begin if Nkind (Decl) = N_Subprogram_Body then return Present (Exception_Handlers (Handled_Statement_Sequence (Decl))); elsif Nkind (Decl) = N_Subprogram_Declaration and then Present (Corresponding_Body (Decl)) then -- If the subprogram is a renaming as body, the body is -- just a call to the renamed subprogram, and inlining is -- trivially possible. if Nkind (Unit_Declaration_Node (Corresponding_Body (Decl))) = N_Subprogram_Renaming_Declaration then return False; else return Present (Exception_Handlers (Handled_Statement_Sequence (Unit_Declaration_Node (Corresponding_Body (Decl))))); end if; else -- If body is not available, assume the best, the check is -- performed again when compiling enclosing package bodies. return False; end if; end Back_End_Cannot_Inline; ----------------- -- Make_Inline -- ----------------- procedure Make_Inline (Subp : Entity_Id) is Kind : constant Entity_Kind := Ekind (Subp); Inner_Subp : Entity_Id := Subp; begin if Etype (Subp) = Any_Type then return; elsif Back_End_Cannot_Inline (Subp) then Applies := True; -- Do not treat as an error. return; -- Here we have a candidate for inlining, but we must exclude -- derived operations. Otherwise we will end up trying to -- inline a phantom declaration, and the result would be to -- drag in a body which has no direct inlining associated with -- it. That would not only be inefficient but would also result -- in the backend doing cross-unit inlining in cases where it -- was definitely inappropriate to do so. -- However, a simple Comes_From_Source test is insufficient, -- since we do want to allow inlining of generic instances, -- which also do not come from source. Predefined operators do -- not come from source but are not inlineable either. elsif not Comes_From_Source (Subp) and then not Is_Generic_Instance (Subp) and then Scope (Subp) /= Standard_Standard then Applies := True; return; -- The referenced entity must either be the enclosing entity, -- or an entity declared within the current open scope. elsif Present (Scope (Subp)) and then Scope (Subp) /= Current_Scope and then Subp /= Current_Scope then Error_Pragma_Arg ("argument of% must be entity in current scope", Assoc); return; end if; -- Processing for procedure, operator or function. -- If subprogram is aliased (as for an instance) indicate -- that the renamed entity is inlined. if Is_Subprogram (Subp) then while Present (Alias (Inner_Subp)) loop Inner_Subp := Alias (Inner_Subp); end loop; Set_Inline_Flags (Inner_Subp); Decl := Parent (Parent (Inner_Subp)); if Nkind (Decl) = N_Subprogram_Declaration and then Present (Corresponding_Body (Decl)) then Set_Inline_Flags (Corresponding_Body (Decl)); end if; Applies := True; -- For a generic subprogram set flag as well, for use at -- the point of instantiation, to determine whether the -- body should be generated. elsif Is_Generic_Subprogram (Subp) then Set_Inline_Flags (Subp); Applies := True; -- Literals are by definition inlined elsif Kind = E_Enumeration_Literal then null; -- Anything else is an error else Error_Pragma_Arg ("expect subprogram name for pragma%", Assoc); end if; end Make_Inline; ---------------------- -- Set_Inline_Flags -- ---------------------- procedure Set_Inline_Flags (Subp : Entity_Id) is begin if Active then Set_Is_Inlined (Subp, True); end if; if not Has_Pragma_Inline (Subp) then Set_Has_Pragma_Inline (Subp); Set_Next_Rep_Item (N, First_Rep_Item (Subp)); Set_First_Rep_Item (Subp, N); Effective := True; end if; end Set_Inline_Flags; -- Start of processing for Process_Inline begin Check_No_Identifiers; Check_At_Least_N_Arguments (1); if Active then Inline_Processing_Required := True; end if; Assoc := Arg1; while Present (Assoc) loop Subp_Id := Expression (Assoc); Analyze (Subp_Id); Applies := False; if Is_Entity_Name (Subp_Id) then Subp := Entity (Subp_Id); if Subp = Any_Id then Applies := True; else Make_Inline (Subp); while Present (Homonym (Subp)) and then Scope (Homonym (Subp)) = Current_Scope loop Make_Inline (Homonym (Subp)); Subp := Homonym (Subp); end loop; end if; end if; if not Applies then Error_Pragma_Arg ("inappropriate argument for pragma%", Assoc); elsif not Effective and then Warn_On_Redundant_Constructs then Error_Msg_NE ("pragma inline on& is redundant?", N, Entity (Subp_Id)); end if; Next (Assoc); end loop; end Process_Inline; ---------------------------- -- Process_Interface_Name -- ---------------------------- procedure Process_Interface_Name (Subprogram_Def : Entity_Id; Ext_Arg : Node_Id; Link_Arg : Node_Id) is Ext_Nam : Node_Id; Link_Nam : Node_Id; String_Val : String_Id; procedure Check_Form_Of_Interface_Name (SN : Node_Id); -- SN is a string literal node for an interface name. This routine -- performs some minimal checks that the name is reasonable. In -- particular that no spaces or other obviously incorrect characters -- appear. This is only a warning, since any characters are allowed. procedure Check_Form_Of_Interface_Name (SN : Node_Id) is S : constant String_Id := Strval (Expr_Value_S (SN)); SL : constant Nat := String_Length (S); C : Char_Code; begin if SL = 0 then Error_Msg_N ("interface name cannot be null string", SN); end if; for J in 1 .. SL loop C := Get_String_Char (S, J); if Warn_On_Export_Import and then (not In_Character_Range (C) or else Get_Character (C) = ' ' or else Get_Character (C) = ',') then Error_Msg_N ("?interface name contains illegal character", SN); end if; end loop; end Check_Form_Of_Interface_Name; -- Start of processing for Process_Interface_Name begin if No (Link_Arg) then if No (Ext_Arg) then return; elsif Chars (Ext_Arg) = Name_Link_Name then Ext_Nam := Empty; Link_Nam := Expression (Ext_Arg); else Check_Optional_Identifier (Ext_Arg, Name_External_Name); Ext_Nam := Expression (Ext_Arg); Link_Nam := Empty; end if; else Check_Optional_Identifier (Ext_Arg, Name_External_Name); Check_Optional_Identifier (Link_Arg, Name_Link_Name); Ext_Nam := Expression (Ext_Arg); Link_Nam := Expression (Link_Arg); end if; -- Check expressions for external name and link name are static if Present (Ext_Nam) then Check_Arg_Is_Static_Expression (Ext_Nam, Standard_String); Check_Form_Of_Interface_Name (Ext_Nam); -- Verify that the external name is not the name of a local -- entity, which would hide the imported one and lead to -- run-time surprises. The problem can only arise for entities -- declared in a package body (otherwise the external name is -- fully qualified and won't conflict). declare Nam : Name_Id; E : Entity_Id; Par : Node_Id; begin if Prag_Id = Pragma_Import then String_To_Name_Buffer (Strval (Expr_Value_S (Ext_Nam))); Nam := Name_Find; E := Entity_Id (Get_Name_Table_Info (Nam)); if Nam /= Chars (Subprogram_Def) and then Present (E) and then not Is_Overloadable (E) and then Is_Immediately_Visible (E) and then not Is_Imported (E) and then Ekind (Scope (E)) = E_Package then Par := Parent (E); while Present (Par) loop if Nkind (Par) = N_Package_Body then Error_Msg_Sloc := Sloc (E); Error_Msg_NE ("imported entity is hidden by & declared#", Ext_Arg, E); exit; end if; Par := Parent (Par); end loop; end if; end if; end; end if; if Present (Link_Nam) then Check_Arg_Is_Static_Expression (Link_Nam, Standard_String); Check_Form_Of_Interface_Name (Link_Nam); end if; -- If there is no link name, just set the external name if No (Link_Nam) then Set_Encoded_Interface_Name (Get_Base_Subprogram (Subprogram_Def), Adjust_External_Name_Case (Expr_Value_S (Ext_Nam))); -- For the Link_Name case, the given literal is preceded by an -- asterisk, which indicates to GCC that the given name should -- be taken literally, and in particular that no prepending of -- underlines should occur, even in systems where this is the -- normal default. else Start_String; Store_String_Char (Get_Char_Code ('*')); String_Val := Strval (Expr_Value_S (Link_Nam)); for J in 1 .. String_Length (String_Val) loop Store_String_Char (Get_String_Char (String_Val, J)); end loop; Link_Nam := Make_String_Literal (Sloc (Link_Nam), End_String); Set_Encoded_Interface_Name (Get_Base_Subprogram (Subprogram_Def), Link_Nam); end if; end Process_Interface_Name; ----------------------------------------- -- Process_Interrupt_Or_Attach_Handler -- ----------------------------------------- procedure Process_Interrupt_Or_Attach_Handler is Arg1_X : constant Node_Id := Expression (Arg1); Handler_Proc : constant Entity_Id := Entity (Arg1_X); Proc_Scope : constant Entity_Id := Scope (Handler_Proc); begin Set_Is_Interrupt_Handler (Handler_Proc); -- If the pragma is not associated with a handler procedure -- within a protected type, then it must be for a nonprotected -- procedure for the AAMP target, in which case we don't -- associate a representation item with the procedure's scope. if Ekind (Proc_Scope) = E_Protected_Type then if Prag_Id = Pragma_Interrupt_Handler or else Prag_Id = Pragma_Attach_Handler then Record_Rep_Item (Proc_Scope, N); end if; end if; end Process_Interrupt_Or_Attach_Handler; -------------------------------------------------- -- Process_Restrictions_Or_Restriction_Warnings -- -------------------------------------------------- procedure Process_Restrictions_Or_Restriction_Warnings is Arg : Node_Id; R_Id : Restriction_Id; Id : Name_Id; Expr : Node_Id; Val : Uint; procedure Set_Warning (R : All_Restrictions); -- If this is a Restriction_Warnings pragma, set warning flag procedure Set_Warning (R : All_Restrictions) is begin if Prag_Id = Pragma_Restriction_Warnings then Restriction_Warnings (R) := True; end if; end Set_Warning; -- Start of processing for Process_Restrictions_Or_Restriction_Warnings begin Check_Ada_83_Warning; Check_At_Least_N_Arguments (1); Check_Valid_Configuration_Pragma; Arg := Arg1; while Present (Arg) loop Id := Chars (Arg); Expr := Expression (Arg); -- Case of no restriction identifier if Id = No_Name then if Nkind (Expr) /= N_Identifier then Error_Pragma_Arg ("invalid form for restriction", Arg); else -- No_Requeue is a synonym for No_Requeue_Statements if Chars (Expr) = Name_No_Requeue then Check_Restriction (No_Implementation_Restrictions, Arg); Set_Restriction (No_Requeue_Statements, N); Set_Warning (No_Requeue_Statements); -- No_Task_Attributes is a synonym for -- No_Task_Attributes_Package elsif Chars (Expr) = Name_No_Task_Attributes then Check_Restriction (No_Implementation_Restrictions, Arg); Set_Restriction (No_Task_Attributes_Package, N); Set_Warning (No_Task_Attributes_Package); -- Normal processing for all other cases else R_Id := Get_Restriction_Id (Chars (Expr)); if R_Id not in All_Boolean_Restrictions then Error_Pragma_Arg ("invalid restriction identifier", Arg); -- Restriction is active else if Implementation_Restriction (R_Id) then Check_Restriction (No_Implementation_Restrictions, Arg); end if; Set_Restriction (R_Id, N); Set_Warning (R_Id); -- A very special case that must be processed here: -- pragma Restrictions (No_Exceptions) turns off -- all run-time checking. This is a bit dubious in -- terms of the formal language definition, but it -- is what is intended by RM H.4(12). if R_Id = No_Exceptions then Scope_Suppress := (others => True); end if; end if; end if; end if; -- Case of restriction identifier present else R_Id := Get_Restriction_Id (Id); Analyze_And_Resolve (Expr, Any_Integer); if R_Id not in All_Parameter_Restrictions then Error_Pragma_Arg ("invalid restriction parameter identifier", Arg); elsif not Is_OK_Static_Expression (Expr) then Flag_Non_Static_Expr ("value must be static expression!", Expr); raise Pragma_Exit; elsif not Is_Integer_Type (Etype (Expr)) or else Expr_Value (Expr) < 0 then Error_Pragma_Arg ("value must be non-negative integer", Arg); -- Restriction pragma is active else Val := Expr_Value (Expr); if not UI_Is_In_Int_Range (Val) then Error_Pragma_Arg ("pragma ignored, value too large?", Arg); else Set_Restriction (R_Id, N, Integer (UI_To_Int (Val))); Set_Warning (R_Id); end if; end if; end if; Next (Arg); end loop; end Process_Restrictions_Or_Restriction_Warnings; --------------------------------- -- Process_Suppress_Unsuppress -- --------------------------------- -- Note: this procedure makes entries in the check suppress data -- structures managed by Sem. See spec of package Sem for full -- details on how we handle recording of check suppression. procedure Process_Suppress_Unsuppress (Suppress_Case : Boolean) is C : Check_Id; E_Id : Node_Id; E : Entity_Id; In_Package_Spec : constant Boolean := (Ekind (Current_Scope) = E_Package or else Ekind (Current_Scope) = E_Generic_Package) and then not In_Package_Body (Current_Scope); procedure Suppress_Unsuppress_Echeck (E : Entity_Id; C : Check_Id); -- Used to suppress a single check on the given entity -------------------------------- -- Suppress_Unsuppress_Echeck -- -------------------------------- procedure Suppress_Unsuppress_Echeck (E : Entity_Id; C : Check_Id) is ESR : constant Entity_Check_Suppress_Record := (Entity => E, Check => C, Suppress => Suppress_Case); begin Set_Checks_May_Be_Suppressed (E); if In_Package_Spec then Global_Entity_Suppress.Append (ESR); else Local_Entity_Suppress.Append (ESR); end if; -- If this is a first subtype, and the base type is distinct, -- then also set the suppress flags on the base type. if Is_First_Subtype (E) and then Etype (E) /= E then Suppress_Unsuppress_Echeck (Etype (E), C); end if; end Suppress_Unsuppress_Echeck; -- Start of processing for Process_Suppress_Unsuppress begin -- Suppress/Unsuppress can appear as a configuration pragma, -- or in a declarative part or a package spec (RM 11.5(5)) if not Is_Configuration_Pragma then Check_Is_In_Decl_Part_Or_Package_Spec; end if; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); Check_No_Identifier (Arg1); Check_Arg_Is_Identifier (Arg1); if not Is_Check_Name (Chars (Expression (Arg1))) then Error_Pragma_Arg ("argument of pragma% is not valid check name", Arg1); else C := Get_Check_Id (Chars (Expression (Arg1))); end if; if Arg_Count = 1 then -- Make an entry in the local scope suppress table. This is the -- table that directly shows the current value of the scope -- suppress check for any check id value. if C = All_Checks then Scope_Suppress := (others => Suppress_Case); else Scope_Suppress (C) := Suppress_Case; end if; -- Also make an entry in the Local_Entity_Suppress table. See -- extended description in the package spec of Sem for details. Local_Entity_Suppress.Append ((Entity => Empty, Check => C, Suppress => Suppress_Case)); -- Case of two arguments present, where the check is -- suppressed for a specified entity (given as the second -- argument of the pragma) else Check_Optional_Identifier (Arg2, Name_On); E_Id := Expression (Arg2); Analyze (E_Id); if not Is_Entity_Name (E_Id) then Error_Pragma_Arg ("second argument of pragma% must be entity name", Arg2); end if; E := Entity (E_Id); if E = Any_Id then return; end if; -- Enforce RM 11.5(7) which requires that for a pragma that -- appears within a package spec, the named entity must be -- within the package spec. We allow the package name itself -- to be mentioned since that makes sense, although it is not -- strictly allowed by 11.5(7). if In_Package_Spec and then E /= Current_Scope and then Scope (E) /= Current_Scope then Error_Pragma_Arg ("entity in pragma% is not in package spec ('R'M 11.5(7))", Arg2); end if; -- Loop through homonyms. As noted below, in the case of a package -- spec, only homonyms within the package spec are considered. loop Suppress_Unsuppress_Echeck (E, C); if Is_Generic_Instance (E) and then Is_Subprogram (E) and then Present (Alias (E)) then Suppress_Unsuppress_Echeck (Alias (E), C); end if; -- Move to next homonym E := Homonym (E); exit when No (E); -- If we are within a package specification, the -- pragma only applies to homonyms in the same scope. exit when In_Package_Spec and then Scope (E) /= Current_Scope; end loop; end if; end Process_Suppress_Unsuppress; ------------------ -- Set_Exported -- ------------------ procedure Set_Exported (E : Entity_Id; Arg : Node_Id) is begin if Is_Imported (E) then Error_Pragma_Arg ("cannot export entity& that was previously imported", Arg); elsif Present (Address_Clause (E)) then Error_Pragma_Arg ("cannot export entity& that has an address clause", Arg); end if; Set_Is_Exported (E); -- Generate a reference for entity explicitly, because the -- identifier may be overloaded and name resolution will not -- generate one. Generate_Reference (E, Arg); -- Deal with exporting non-library level entity if not Is_Library_Level_Entity (E) then -- Not allowed at all for subprograms if Is_Subprogram (E) then Error_Pragma_Arg ("local subprogram& cannot be exported", Arg); -- Otherwise set public and statically allocated else Set_Is_Public (E); Set_Is_Statically_Allocated (E); if Warn_On_Export_Import then Error_Msg_NE ("?& has been made static as a result of Export", Arg, E); Error_Msg_N ("\this usage is non-standard and non-portable", Arg); end if; end if; end if; if Warn_On_Export_Import and then Is_Type (E) then Error_Msg_NE ("exporting a type has no effect?", Arg, E); end if; if Warn_On_Export_Import and Inside_A_Generic then Error_Msg_NE ("all instances of& will have the same external name?", Arg, E); end if; end Set_Exported; ---------------------------------------------- -- Set_Extended_Import_Export_External_Name -- ---------------------------------------------- procedure Set_Extended_Import_Export_External_Name (Internal_Ent : Entity_Id; Arg_External : Node_Id) is Old_Name : constant Node_Id := Interface_Name (Internal_Ent); New_Name : Node_Id; begin if No (Arg_External) then return; elsif Nkind (Arg_External) = N_String_Literal then if String_Length (Strval (Arg_External)) = 0 then return; else New_Name := Adjust_External_Name_Case (Arg_External); end if; elsif Nkind (Arg_External) = N_Identifier then New_Name := Get_Default_External_Name (Arg_External); else Error_Pragma_Arg ("incorrect form for External parameter for pragma%", Arg_External); end if; -- If we already have an external name set (by a prior normal -- Import or Export pragma), then the external names must match if Present (Interface_Name (Internal_Ent)) then declare S1 : constant String_Id := Strval (Old_Name); S2 : constant String_Id := Strval (New_Name); procedure Mismatch; -- Called if names do not match procedure Mismatch is begin Error_Msg_Sloc := Sloc (Old_Name); Error_Pragma_Arg ("external name does not match that given #", Arg_External); end Mismatch; begin if String_Length (S1) /= String_Length (S2) then Mismatch; else for J in 1 .. String_Length (S1) loop if Get_String_Char (S1, J) /= Get_String_Char (S2, J) then Mismatch; end if; end loop; end if; end; -- Otherwise set the given name else Set_Encoded_Interface_Name (Internal_Ent, New_Name); end if; end Set_Extended_Import_Export_External_Name; ------------------ -- Set_Imported -- ------------------ procedure Set_Imported (E : Entity_Id) is begin Error_Msg_Sloc := Sloc (E); if Is_Exported (E) or else Is_Imported (E) then Error_Msg_NE ("import of& declared# not allowed", N, E); if Is_Exported (E) then Error_Msg_N ("\entity was previously exported", N); else Error_Msg_N ("\entity was previously imported", N); end if; Error_Pragma ("\(pragma% applies to all previous entities)"); else Set_Is_Imported (E); -- If the entity is an object that is not at the library -- level, then it is statically allocated. We do not worry -- about objects with address clauses in this context since -- they are not really imported in the linker sense. if Is_Object (E) and then not Is_Library_Level_Entity (E) and then No (Address_Clause (E)) then Set_Is_Statically_Allocated (E); end if; end if; end Set_Imported; ------------------------- -- Set_Mechanism_Value -- ------------------------- -- Note: the mechanism name has not been analyzed (and cannot indeed -- be analyzed, since it is semantic nonsense), so we get it in the -- exact form created by the parser. procedure Set_Mechanism_Value (Ent : Entity_Id; Mech_Name : Node_Id) is Class : Node_Id; Param : Node_Id; procedure Bad_Class; -- Signal bad descriptor class name procedure Bad_Mechanism; -- Signal bad mechanism name procedure Bad_Class is begin Error_Pragma_Arg ("unrecognized descriptor class name", Class); end Bad_Class; procedure Bad_Mechanism is begin Error_Pragma_Arg ("unrecognized mechanism name", Mech_Name); end Bad_Mechanism; -- Start of processing for Set_Mechanism_Value begin if Mechanism (Ent) /= Default_Mechanism then Error_Msg_NE ("mechanism for & has already been set", Mech_Name, Ent); end if; -- MECHANISM_NAME ::= value | reference | descriptor if Nkind (Mech_Name) = N_Identifier then if Chars (Mech_Name) = Name_Value then Set_Mechanism (Ent, By_Copy); return; elsif Chars (Mech_Name) = Name_Reference then Set_Mechanism (Ent, By_Reference); return; elsif Chars (Mech_Name) = Name_Descriptor then Check_VMS (Mech_Name); Set_Mechanism (Ent, By_Descriptor); return; elsif Chars (Mech_Name) = Name_Copy then Error_Pragma_Arg ("bad mechanism name, Value assumed", Mech_Name); else Bad_Mechanism; end if; -- MECHANISM_NAME ::= descriptor (CLASS_NAME) -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca -- Note: this form is parsed as an indexed component elsif Nkind (Mech_Name) = N_Indexed_Component then Class := First (Expressions (Mech_Name)); if Nkind (Prefix (Mech_Name)) /= N_Identifier or else Chars (Prefix (Mech_Name)) /= Name_Descriptor or else Present (Next (Class)) then Bad_Mechanism; end if; -- MECHANISM_NAME ::= descriptor (Class => CLASS_NAME) -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca -- Note: this form is parsed as a function call elsif Nkind (Mech_Name) = N_Function_Call then Param := First (Parameter_Associations (Mech_Name)); if Nkind (Name (Mech_Name)) /= N_Identifier or else Chars (Name (Mech_Name)) /= Name_Descriptor or else Present (Next (Param)) or else No (Selector_Name (Param)) or else Chars (Selector_Name (Param)) /= Name_Class then Bad_Mechanism; else Class := Explicit_Actual_Parameter (Param); end if; else Bad_Mechanism; end if; -- Fall through here with Class set to descriptor class name Check_VMS (Mech_Name); if Nkind (Class) /= N_Identifier then Bad_Class; elsif Chars (Class) = Name_UBS then Set_Mechanism (Ent, By_Descriptor_UBS); elsif Chars (Class) = Name_UBSB then Set_Mechanism (Ent, By_Descriptor_UBSB); elsif Chars (Class) = Name_UBA then Set_Mechanism (Ent, By_Descriptor_UBA); elsif Chars (Class) = Name_S then Set_Mechanism (Ent, By_Descriptor_S); elsif Chars (Class) = Name_SB then Set_Mechanism (Ent, By_Descriptor_SB); elsif Chars (Class) = Name_A then Set_Mechanism (Ent, By_Descriptor_A); elsif Chars (Class) = Name_NCA then Set_Mechanism (Ent, By_Descriptor_NCA); else Bad_Class; end if; end Set_Mechanism_Value; -- Start of processing for Analyze_Pragma begin if not Is_Pragma_Name (Chars (N)) then if Warn_On_Unrecognized_Pragma then Error_Pragma ("unrecognized pragma%!?"); else raise Pragma_Exit; end if; else Prag_Id := Get_Pragma_Id (Chars (N)); end if; -- Preset arguments Arg1 := Empty; Arg2 := Empty; Arg3 := Empty; Arg4 := Empty; if Present (Pragma_Argument_Associations (N)) then Arg1 := First (Pragma_Argument_Associations (N)); if Present (Arg1) then Arg2 := Next (Arg1); if Present (Arg2) then Arg3 := Next (Arg2); if Present (Arg3) then Arg4 := Next (Arg3); end if; end if; end if; end if; -- Count number of arguments declare Arg_Node : Node_Id; begin Arg_Count := 0; Arg_Node := Arg1; while Present (Arg_Node) loop Arg_Count := Arg_Count + 1; Next (Arg_Node); end loop; end; -- An enumeration type defines the pragmas that are supported by the -- implementation. Get_Pragma_Id (in package Prag) transorms a name -- into the corresponding enumeration value for the following case. case Prag_Id is ----------------- -- Abort_Defer -- ----------------- -- pragma Abort_Defer; when Pragma_Abort_Defer => GNAT_Pragma; Check_Arg_Count (0); -- The only required semantic processing is to check the -- placement. This pragma must appear at the start of the -- statement sequence of a handled sequence of statements. if Nkind (Parent (N)) /= N_Handled_Sequence_Of_Statements or else N /= First (Statements (Parent (N))) then Pragma_Misplaced; end if; ------------ -- Ada_83 -- ------------ -- pragma Ada_83; -- Note: this pragma also has some specific processing in Par.Prag -- because we want to set the Ada 83 mode switch during parsing. when Pragma_Ada_83 => GNAT_Pragma; Ada_83 := True; Ada_95 := False; Check_Arg_Count (0); ------------ -- Ada_95 -- ------------ -- pragma Ada_95; -- Note: this pragma also has some specific processing in Par.Prag -- because we want to set the Ada 83 mode switch during parsing. when Pragma_Ada_95 => GNAT_Pragma; Ada_83 := False; Ada_95 := True; Check_Arg_Count (0); ---------------------- -- All_Calls_Remote -- ---------------------- -- pragma All_Calls_Remote [(library_package_NAME)]; when Pragma_All_Calls_Remote => All_Calls_Remote : declare Lib_Entity : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Lib_Entity := Find_Lib_Unit_Name; -- This pragma should only apply to a RCI unit (RM E.2.3(23)). if Present (Lib_Entity) and then not Debug_Flag_U then if not Is_Remote_Call_Interface (Lib_Entity) then Error_Pragma ("pragma% only apply to rci unit"); -- Set flag for entity of the library unit else Set_Has_All_Calls_Remote (Lib_Entity); end if; end if; end All_Calls_Remote; -------------- -- Annotate -- -------------- -- pragma Annotate (IDENTIFIER {, ARG}); -- ARG ::= NAME | EXPRESSION when Pragma_Annotate => Annotate : begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_Arg_Is_Identifier (Arg1); declare Arg : Node_Id := Arg2; Exp : Node_Id; begin while Present (Arg) loop Exp := Expression (Arg); Analyze (Exp); if Is_Entity_Name (Exp) then null; elsif Nkind (Exp) = N_String_Literal then Resolve (Exp, Standard_String); elsif Is_Overloaded (Exp) then Error_Pragma_Arg ("ambiguous argument for pragma%", Exp); else Resolve (Exp); end if; Next (Arg); end loop; end; end Annotate; ------------ -- Assert -- ------------ -- pragma Assert (Boolean_EXPRESSION [, static_string_EXPRESSION]); when Pragma_Assert => GNAT_Pragma; Check_No_Identifiers; if Arg_Count > 1 then Check_Arg_Count (2); Check_Arg_Is_Static_Expression (Arg2, Standard_String); end if; -- If expansion is active and assertions are inactive, then -- we rewrite the Assertion as: -- if False and then condition then -- null; -- end if; -- The reason we do this rewriting during semantic analysis -- rather than as part of normal expansion is that we cannot -- analyze and expand the code for the boolean expression -- directly, or it may cause insertion of actions that would -- escape the attempt to suppress the assertion code. if Expander_Active and not Assertions_Enabled then Rewrite (N, Make_If_Statement (Loc, Condition => Make_And_Then (Loc, Left_Opnd => New_Occurrence_Of (Standard_False, Loc), Right_Opnd => Get_Pragma_Arg (Arg1)), Then_Statements => New_List ( Make_Null_Statement (Loc)))); Analyze (N); -- Otherwise (if assertions are enabled, or if we are not -- operating with expansion active), then we just analyze -- and resolve the expression. else Analyze_And_Resolve (Expression (Arg1), Any_Boolean); end if; --------------- -- AST_Entry -- --------------- -- pragma AST_Entry (entry_IDENTIFIER); when Pragma_AST_Entry => AST_Entry : declare Ent : Node_Id; begin GNAT_Pragma; Check_VMS (N); Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Local_Name (Arg1); Ent := Entity (Expression (Arg1)); -- Note: the implementation of the AST_Entry pragma could handle -- the entry family case fine, but for now we are consistent with -- the DEC rules, and do not allow the pragma, which of course -- has the effect of also forbidding the attribute. if Ekind (Ent) /= E_Entry then Error_Pragma_Arg ("pragma% argument must be simple entry name", Arg1); elsif Is_AST_Entry (Ent) then Error_Pragma_Arg ("duplicate % pragma for entry", Arg1); elsif Has_Homonym (Ent) then Error_Pragma_Arg ("pragma% argument cannot specify overloaded entry", Arg1); else declare FF : constant Entity_Id := First_Formal (Ent); begin if Present (FF) then if Present (Next_Formal (FF)) then Error_Pragma_Arg ("entry for pragma% can have only one argument", Arg1); elsif Parameter_Mode (FF) /= E_In_Parameter then Error_Pragma_Arg ("entry parameter for pragma% must have mode IN", Arg1); end if; end if; end; Set_Is_AST_Entry (Ent); end if; end AST_Entry; ------------------ -- Asynchronous -- ------------------ -- pragma Asynchronous (LOCAL_NAME); when Pragma_Asynchronous => Asynchronous : declare Nm : Entity_Id; C_Ent : Entity_Id; L : List_Id; S : Node_Id; N : Node_Id; Formal : Entity_Id; procedure Process_Async_Pragma; -- Common processing for procedure and access-to-procedure case -------------------------- -- Process_Async_Pragma -- -------------------------- procedure Process_Async_Pragma is begin if not Present (L) then Set_Is_Asynchronous (Nm); return; end if; -- The formals should be of mode IN (RM E.4.1(6)) S := First (L); while Present (S) loop Formal := Defining_Identifier (S); if Nkind (Formal) = N_Defining_Identifier and then Ekind (Formal) /= E_In_Parameter then Error_Pragma_Arg ("pragma% procedure can only have IN parameter", Arg1); end if; Next (S); end loop; Set_Is_Asynchronous (Nm); end Process_Async_Pragma; -- Start of processing for pragma Asynchronous begin Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); if Debug_Flag_U then return; end if; C_Ent := Cunit_Entity (Current_Sem_Unit); Analyze (Expression (Arg1)); Nm := Entity (Expression (Arg1)); if not Is_Remote_Call_Interface (C_Ent) and then not Is_Remote_Types (C_Ent) then -- This pragma should only appear in an RCI or Remote Types -- unit (RM E.4.1(4)) Error_Pragma ("pragma% not in Remote_Call_Interface or " & "Remote_Types unit"); end if; if Ekind (Nm) = E_Procedure and then Nkind (Parent (Nm)) = N_Procedure_Specification then if not Is_Remote_Call_Interface (Nm) then Error_Pragma_Arg ("pragma% cannot be applied on non-remote procedure", Arg1); end if; L := Parameter_Specifications (Parent (Nm)); Process_Async_Pragma; return; elsif Ekind (Nm) = E_Function then Error_Pragma_Arg ("pragma% cannot be applied to function", Arg1); elsif Ekind (Nm) = E_Record_Type and then Present (Corresponding_Remote_Type (Nm)) then N := Declaration_Node (Corresponding_Remote_Type (Nm)); if Nkind (N) = N_Full_Type_Declaration and then Nkind (Type_Definition (N)) = N_Access_Procedure_Definition then L := Parameter_Specifications (Type_Definition (N)); Process_Async_Pragma; else Error_Pragma_Arg ("pragma% cannot reference access-to-function type", Arg1); end if; -- Only other possibility is Access-to-class-wide type elsif Is_Access_Type (Nm) and then Is_Class_Wide_Type (Designated_Type (Nm)) then Check_First_Subtype (Arg1); Set_Is_Asynchronous (Nm); if Expander_Active then RACW_Type_Is_Asynchronous (Nm); end if; else Error_Pragma_Arg ("inappropriate argument for pragma%", Arg1); end if; end Asynchronous; ------------ -- Atomic -- ------------ -- pragma Atomic (LOCAL_NAME); when Pragma_Atomic => Process_Atomic_Shared_Volatile; ----------------------- -- Atomic_Components -- ----------------------- -- pragma Atomic_Components (array_LOCAL_NAME); -- This processing is shared by Volatile_Components when Pragma_Atomic_Components | Pragma_Volatile_Components => Atomic_Components : declare E_Id : Node_Id; E : Entity_Id; D : Node_Id; K : Node_Kind; begin Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); if Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N) then return; end if; D := Declaration_Node (E); K := Nkind (D); if (K = N_Full_Type_Declaration and then Is_Array_Type (E)) or else ((Ekind (E) = E_Constant or else Ekind (E) = E_Variable) and then Nkind (D) = N_Object_Declaration and then Nkind (Object_Definition (D)) = N_Constrained_Array_Definition) then -- The flag is set on the object, or on the base type if Nkind (D) /= N_Object_Declaration then E := Base_Type (E); end if; Set_Has_Volatile_Components (E); if Prag_Id = Pragma_Atomic_Components then Set_Has_Atomic_Components (E); if Is_Packed (E) then Set_Is_Packed (E, False); Error_Pragma_Arg ("?Pack canceled, cannot pack atomic components", Arg1); end if; end if; else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; end Atomic_Components; -------------------- -- Attach_Handler -- -------------------- -- pragma Attach_Handler (handler_NAME, EXPRESSION); when Pragma_Attach_Handler => Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (2); if No_Run_Time_Mode then Error_Msg_CRT ("Attach_Handler pragma", N); else Check_Interrupt_Or_Attach_Handler; -- The expression that designates the attribute may -- depend on a discriminant, and is therefore a per- -- object expression, to be expanded in the init proc. -- If expansion is enabled, perform semantic checks -- on a copy only. if Expander_Active then declare Temp : constant Node_Id := New_Copy_Tree (Expression (Arg2)); begin Set_Parent (Temp, N); Pre_Analyze_And_Resolve (Temp, RTE (RE_Interrupt_ID)); end; else Analyze (Expression (Arg2)); Resolve (Expression (Arg2), RTE (RE_Interrupt_ID)); end if; Process_Interrupt_Or_Attach_Handler; end if; -------------------- -- C_Pass_By_Copy -- -------------------- -- pragma C_Pass_By_Copy ([Max_Size =>] static_integer_EXPRESSION); when Pragma_C_Pass_By_Copy => C_Pass_By_Copy : declare Arg : Node_Id; Val : Uint; begin GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, "max_size"); Arg := Expression (Arg1); Check_Arg_Is_Static_Expression (Arg, Any_Integer); Val := Expr_Value (Arg); if Val <= 0 then Error_Pragma_Arg ("maximum size for pragma% must be positive", Arg1); elsif UI_Is_In_Int_Range (Val) then Default_C_Record_Mechanism := UI_To_Int (Val); -- If a giant value is given, Int'Last will do well enough. -- If sometime someone complains that a record larger than -- two gigabytes is not copied, we will worry about it then! else Default_C_Record_Mechanism := Mechanism_Type'Last; end if; end C_Pass_By_Copy; ------------- -- Comment -- ------------- -- pragma Comment (static_string_EXPRESSION) -- Processing for pragma Comment shares the circuitry for -- pragma Ident. The only differences are that Ident enforces -- a limit of 31 characters on its argument, and also enforces -- limitations on placement for DEC compatibility. Pragma -- Comment shares neither of these restrictions. ------------------- -- Common_Object -- ------------------- -- pragma Common_Object ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Size =>] EXTERNAL_SYMBOL]); -- Processing for this pragma is shared with Psect_Object -------------------------- -- Compile_Time_Warning -- -------------------------- -- pragma Compile_Time_Warning -- (boolean_EXPRESSION, static_string_EXPRESSION); when Pragma_Compile_Time_Warning => Compile_Time_Warning : declare Arg1x : constant Node_Id := Get_Pragma_Arg (Arg1); begin GNAT_Pragma; Check_Arg_Count (2); Check_No_Identifiers; Check_Arg_Is_Static_Expression (Arg2, Standard_String); Analyze_And_Resolve (Arg1x, Standard_Boolean); if Compile_Time_Known_Value (Arg1x) then if Is_True (Expr_Value (Get_Pragma_Arg (Arg1))) then String_To_Name_Buffer (Strval (Get_Pragma_Arg (Arg2))); Add_Char_To_Name_Buffer ('?'); declare Msg : String (1 .. Name_Len) := Name_Buffer (1 .. Name_Len); B : Natural; begin -- This loop looks for multiple lines separated by -- ASCII.LF and breaks them into continuation error -- messages marked with the usual back slash. B := 1; for S in 2 .. Msg'Length - 1 loop if Msg (S) = ASCII.LF then Msg (S) := '?'; Error_Msg_N (Msg (B .. S), Arg1); B := S; Msg (B) := '\'; end if; end loop; Error_Msg_N (Msg (B .. Msg'Length), Arg1); end; end if; end if; end Compile_Time_Warning; ---------------------------- -- Complex_Representation -- ---------------------------- -- pragma Complex_Representation ([Entity =>] LOCAL_NAME); when Pragma_Complex_Representation => Complex_Representation : declare E_Id : Entity_Id; E : Entity_Id; Ent : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); if not Is_Record_Type (E) then Error_Pragma_Arg ("argument for pragma% must be record type", Arg1); end if; Ent := First_Entity (E); if No (Ent) or else No (Next_Entity (Ent)) or else Present (Next_Entity (Next_Entity (Ent))) or else not Is_Floating_Point_Type (Etype (Ent)) or else Etype (Ent) /= Etype (Next_Entity (Ent)) then Error_Pragma_Arg ("record for pragma% must have two fields of same fpt type", Arg1); else Set_Has_Complex_Representation (Base_Type (E)); end if; end Complex_Representation; ------------------------- -- Component_Alignment -- ------------------------- -- pragma Component_Alignment ( -- [Form =>] ALIGNMENT_CHOICE -- [, [Name =>] type_LOCAL_NAME]); -- -- ALIGNMENT_CHOICE ::= -- Component_Size -- | Component_Size_4 -- | Storage_Unit -- | Default when Pragma_Component_Alignment => Component_AlignmentP : declare Args : Args_List (1 .. 2); Names : constant Name_List (1 .. 2) := ( Name_Form, Name_Name); Form : Node_Id renames Args (1); Name : Node_Id renames Args (2); Atype : Component_Alignment_Kind; Typ : Entity_Id; begin GNAT_Pragma; Gather_Associations (Names, Args); if No (Form) then Error_Pragma ("missing Form argument for pragma%"); end if; Check_Arg_Is_Identifier (Form); -- Get proper alignment, note that Default = Component_Size -- on all machines we have so far, and we want to set this -- value rather than the default value to indicate that it -- has been explicitly set (and thus will not get overridden -- by the default component alignment for the current scope) if Chars (Form) = Name_Component_Size then Atype := Calign_Component_Size; elsif Chars (Form) = Name_Component_Size_4 then Atype := Calign_Component_Size_4; elsif Chars (Form) = Name_Default then Atype := Calign_Component_Size; elsif Chars (Form) = Name_Storage_Unit then Atype := Calign_Storage_Unit; else Error_Pragma_Arg ("invalid Form parameter for pragma%", Form); end if; -- Case with no name, supplied, affects scope table entry if No (Name) then Scope_Stack.Table (Scope_Stack.Last).Component_Alignment_Default := Atype; -- Case of name supplied else Check_Arg_Is_Local_Name (Name); Find_Type (Name); Typ := Entity (Name); if Typ = Any_Type or else Rep_Item_Too_Early (Typ, N) then return; else Typ := Underlying_Type (Typ); end if; if not Is_Record_Type (Typ) and then not Is_Array_Type (Typ) then Error_Pragma_Arg ("Name parameter of pragma% must identify record or " & "array type", Name); end if; -- An explicit Component_Alignment pragma overrides an -- implicit pragma Pack, but not an explicit one. if not Has_Pragma_Pack (Base_Type (Typ)) then Set_Is_Packed (Base_Type (Typ), False); Set_Component_Alignment (Base_Type (Typ), Atype); end if; end if; end Component_AlignmentP; ---------------- -- Controlled -- ---------------- -- pragma Controlled (first_subtype_LOCAL_NAME); when Pragma_Controlled => Controlled : declare Arg : Node_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Arg := Expression (Arg1); if not Is_Entity_Name (Arg) or else not Is_Access_Type (Entity (Arg)) then Error_Pragma_Arg ("pragma% requires access type", Arg1); else Set_Has_Pragma_Controlled (Base_Type (Entity (Arg))); end if; end Controlled; ---------------- -- Convention -- ---------------- -- pragma Convention ([Convention =>] convention_IDENTIFIER, -- [Entity =>] LOCAL_NAME); when Pragma_Convention => Convention : declare C : Convention_Id; E : Entity_Id; begin Check_Ada_83_Warning; Check_Arg_Count (2); Process_Convention (C, E); end Convention; --------------------------- -- Convention_Identifier -- --------------------------- -- pragma Convention_Identifier ([Name =>] IDENTIFIER, -- [Convention =>] convention_IDENTIFIER); when Pragma_Convention_Identifier => Convention_Identifier : declare Idnam : Name_Id; Cname : Name_Id; begin GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Name); Check_Optional_Identifier (Arg2, Name_Convention); Check_Arg_Is_Identifier (Arg1); Check_Arg_Is_Identifier (Arg1); Idnam := Chars (Expression (Arg1)); Cname := Chars (Expression (Arg2)); if Is_Convention_Name (Cname) then Record_Convention_Identifier (Idnam, Get_Convention_Id (Cname)); else Error_Pragma_Arg ("second arg for % pragma must be convention", Arg2); end if; end Convention_Identifier; --------------- -- CPP_Class -- --------------- -- pragma CPP_Class ([Entity =>] local_NAME) when Pragma_CPP_Class => CPP_Class : declare Arg : Node_Id; Typ : Entity_Id; Default_DTC : Entity_Id := Empty; VTP_Type : constant Entity_Id := RTE (RE_Vtable_Ptr); C : Entity_Id; Tag_C : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Arg := Expression (Arg1); Analyze (Arg); if Etype (Arg) = Any_Type then return; end if; if not Is_Entity_Name (Arg) or else not Is_Type (Entity (Arg)) then Error_Pragma_Arg ("pragma% requires a type mark", Arg1); end if; Typ := Entity (Arg); if not Is_Record_Type (Typ) then Error_Pragma_Arg ("pragma% applicable to a record, " & "tagged record or record extension", Arg1); end if; Default_DTC := First_Component (Typ); while Present (Default_DTC) and then Etype (Default_DTC) /= VTP_Type loop Next_Component (Default_DTC); end loop; -- Case of non tagged type if not Is_Tagged_Type (Typ) then Set_Is_CPP_Class (Typ); if Present (Default_DTC) then Error_Pragma_Arg ("only tagged records can contain vtable pointers", Arg1); end if; -- Case of tagged type with no vtable ptr -- What is test for Typ = Root_Typ (Typ) about here ??? elsif Is_Tagged_Type (Typ) and then Typ = Root_Type (Typ) and then No (Default_DTC) then Error_Pragma_Arg ("a cpp_class must contain a vtable pointer", Arg1); -- Tagged type that has a vtable ptr elsif Present (Default_DTC) then Set_Is_CPP_Class (Typ); Set_Is_Limited_Record (Typ); Set_Is_Tag (Default_DTC); Set_DT_Entry_Count (Default_DTC, No_Uint); -- Since a CPP type has no direct link to its associated tag -- most tags checks cannot be performed Set_Kill_Tag_Checks (Typ); Set_Kill_Tag_Checks (Class_Wide_Type (Typ)); -- Get rid of the _tag component when there was one. -- It is only useful for regular tagged types if Expander_Active and then Typ = Root_Type (Typ) then Tag_C := Tag_Component (Typ); C := First_Entity (Typ); if C = Tag_C then Set_First_Entity (Typ, Next_Entity (Tag_C)); else while Next_Entity (C) /= Tag_C loop Next_Entity (C); end loop; Set_Next_Entity (C, Next_Entity (Tag_C)); end if; end if; end if; end CPP_Class; --------------------- -- CPP_Constructor -- --------------------- -- pragma CPP_Constructor ([Entity =>] LOCAL_NAME); when Pragma_CPP_Constructor => CPP_Constructor : declare Id : Entity_Id; Def_Id : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Id := Expression (Arg1); Find_Program_Unit_Name (Id); -- If we did not find the name, we are done if Etype (Id) = Any_Type then return; end if; Def_Id := Entity (Id); if Ekind (Def_Id) = E_Function and then Is_Class_Wide_Type (Etype (Def_Id)) and then Is_CPP_Class (Etype (Etype (Def_Id))) then -- What the heck is this??? this pragma allows only 1 arg if Arg_Count >= 2 then Check_At_Most_N_Arguments (3); Process_Interface_Name (Def_Id, Arg2, Arg3); end if; if No (Parameter_Specifications (Parent (Def_Id))) then Set_Has_Completion (Def_Id); Set_Is_Constructor (Def_Id); else Error_Pragma_Arg ("non-default constructors not implemented", Arg1); end if; else Error_Pragma_Arg ("pragma% requires function returning a 'C'P'P_Class type", Arg1); end if; end CPP_Constructor; ----------------- -- CPP_Virtual -- ----------------- -- pragma CPP_Virtual -- [Entity =>] LOCAL_NAME -- [ [Vtable_Ptr =>] LOCAL_NAME, -- [Position =>] static_integer_EXPRESSION]); when Pragma_CPP_Virtual => CPP_Virtual : declare Arg : Node_Id; Typ : Entity_Id; Subp : Entity_Id; VTP_Type : constant Entity_Id := RTE (RE_Vtable_Ptr); DTC : Entity_Id; V : Uint; begin GNAT_Pragma; if Arg_Count = 3 then Check_Optional_Identifier (Arg2, "vtable_ptr"); -- We allow Entry_Count as well as Position for the third -- parameter for back compatibility with versions of GNAT -- before version 3.12. The documentation has always said -- Position, but the code up to 3.12 said Entry_Count. if Chars (Arg3) /= Name_Position then Check_Optional_Identifier (Arg3, "entry_count"); end if; else Check_Arg_Count (1); end if; Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); -- First argument must be a subprogram name Arg := Expression (Arg1); Find_Program_Unit_Name (Arg); if Etype (Arg) = Any_Type then return; else Subp := Entity (Arg); end if; if not (Is_Subprogram (Subp) and then Is_Dispatching_Operation (Subp)) then Error_Pragma_Arg ("pragma% must reference a primitive operation", Arg1); end if; Typ := Find_Dispatching_Type (Subp); -- If only one Argument defaults are : -- . DTC_Entity is the default Vtable pointer -- . DT_Position will be set at the freezing point if Arg_Count = 1 then Set_DTC_Entity (Subp, Tag_Component (Typ)); return; end if; -- Second argument is a component name of type Vtable_Ptr Arg := Expression (Arg2); if Nkind (Arg) /= N_Identifier then Error_Msg_NE ("must be a& component name", Arg, Typ); raise Pragma_Exit; end if; DTC := First_Component (Typ); while Present (DTC) and then Chars (DTC) /= Chars (Arg) loop Next_Component (DTC); end loop; if No (DTC) then Error_Msg_NE ("must be a& component name", Arg, Typ); raise Pragma_Exit; elsif Etype (DTC) /= VTP_Type then Wrong_Type (Arg, VTP_Type); return; end if; -- Third argument is an integer (DT_Position) Arg := Expression (Arg3); Analyze_And_Resolve (Arg, Any_Integer); if not Is_Static_Expression (Arg) then Flag_Non_Static_Expr ("third argument of pragma CPP_Virtual must be static!", Arg3); raise Pragma_Exit; else V := Expr_Value (Expression (Arg3)); if V <= 0 then Error_Pragma_Arg ("third argument of pragma% must be positive", Arg3); else Set_DTC_Entity (Subp, DTC); Set_DT_Position (Subp, V); end if; end if; end CPP_Virtual; ---------------- -- CPP_Vtable -- ---------------- -- pragma CPP_Vtable ( -- [Entity =>] LOCAL_NAME -- [Vtable_Ptr =>] LOCAL_NAME, -- [Entry_Count =>] static_integer_EXPRESSION); when Pragma_CPP_Vtable => CPP_Vtable : declare Arg : Node_Id; Typ : Entity_Id; VTP_Type : constant Entity_Id := RTE (RE_Vtable_Ptr); DTC : Entity_Id; V : Uint; Elmt : Elmt_Id; begin GNAT_Pragma; Check_Arg_Count (3); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, "vtable_ptr"); Check_Optional_Identifier (Arg3, "entry_count"); Check_Arg_Is_Local_Name (Arg1); -- First argument is a record type name Arg := Expression (Arg1); Analyze (Arg); if Etype (Arg) = Any_Type then return; else Typ := Entity (Arg); end if; if not (Is_Tagged_Type (Typ) and then Is_CPP_Class (Typ)) then Error_Pragma_Arg ("'C'P'P_Class tagged type expected", Arg1); end if; -- Second argument is a component name of type Vtable_Ptr Arg := Expression (Arg2); if Nkind (Arg) /= N_Identifier then Error_Msg_NE ("must be a& component name", Arg, Typ); raise Pragma_Exit; end if; DTC := First_Component (Typ); while Present (DTC) and then Chars (DTC) /= Chars (Arg) loop Next_Component (DTC); end loop; if No (DTC) then Error_Msg_NE ("must be a& component name", Arg, Typ); raise Pragma_Exit; elsif Etype (DTC) /= VTP_Type then Wrong_Type (DTC, VTP_Type); return; -- If it is the first pragma Vtable, This becomes the default tag elsif (not Is_Tag (DTC)) and then DT_Entry_Count (Tag_Component (Typ)) = No_Uint then Set_Is_Tag (Tag_Component (Typ), False); Set_Is_Tag (DTC, True); Set_DT_Entry_Count (DTC, No_Uint); end if; -- Those pragmas must appear before any primitive operation -- definition (except inherited ones) otherwise the default -- may be wrong Elmt := First_Elmt (Primitive_Operations (Typ)); while Present (Elmt) loop if No (Alias (Node (Elmt))) then Error_Msg_Sloc := Sloc (Node (Elmt)); Error_Pragma ("pragma% must appear before this primitive operation"); end if; Next_Elmt (Elmt); end loop; -- Third argument is an integer (DT_Entry_Count) Arg := Expression (Arg3); Analyze_And_Resolve (Arg, Any_Integer); if not Is_Static_Expression (Arg) then Flag_Non_Static_Expr ("entry count for pragma CPP_Vtable must be a static " & "expression!", Arg3); raise Pragma_Exit; else V := Expr_Value (Expression (Arg3)); if V <= 0 then Error_Pragma_Arg ("entry count for pragma% must be positive", Arg3); else Set_DT_Entry_Count (DTC, V); end if; end if; end CPP_Vtable; ----------- -- Debug -- ----------- -- pragma Debug (PROCEDURE_CALL_STATEMENT); when Pragma_Debug => Debug : begin GNAT_Pragma; -- If assertions are enabled, and we are expanding code, then -- we rewrite the pragma with its corresponding procedure call -- and then analyze the call. if Assertions_Enabled and Expander_Active then Rewrite (N, Relocate_Node (Debug_Statement (N))); Analyze (N); -- Otherwise we work a bit to get a tree that makes sense -- for ASIS purposes, namely a pragma with an analyzed -- argument that looks like a procedure call. else Expander_Mode_Save_And_Set (False); Rewrite (N, Relocate_Node (Debug_Statement (N))); Analyze (N); Rewrite (N, Make_Pragma (Loc, Chars => Name_Debug, Pragma_Argument_Associations => New_List (Relocate_Node (N)))); Expander_Mode_Restore; end if; end Debug; ------------------- -- Discard_Names -- ------------------- -- pragma Discard_Names [([On =>] LOCAL_NAME)]; when Pragma_Discard_Names => Discard_Names : declare E_Id : Entity_Id; E : Entity_Id; begin Check_Ada_83_Warning; -- Deal with configuration pragma case if Arg_Count = 0 and then Is_Configuration_Pragma then Global_Discard_Names := True; return; -- Otherwise, check correct appropriate context else Check_Is_In_Decl_Part_Or_Package_Spec; if Arg_Count = 0 then -- If there is no parameter, then from now on this pragma -- applies to any enumeration, exception or tagged type -- defined in the current declarative part. Set_Discard_Names (Current_Scope); return; else Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_On); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Etype (E_Id) = Any_Type then return; else E := Entity (E_Id); end if; if (Is_First_Subtype (E) and then (Is_Enumeration_Type (E) or else Is_Tagged_Type (E))) or else Ekind (E) = E_Exception then Set_Discard_Names (E); else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; end if; end if; end Discard_Names; --------------- -- Elaborate -- --------------- -- pragma Elaborate (library_unit_NAME {, library_unit_NAME}); when Pragma_Elaborate => Elaborate : declare Plist : List_Id; Parent_Node : Node_Id; Arg : Node_Id; Citem : Node_Id; begin -- Pragma must be in context items list of a compilation unit if not Is_List_Member (N) then Pragma_Misplaced; return; else Plist := List_Containing (N); Parent_Node := Parent (Plist); if Parent_Node = Empty or else Nkind (Parent_Node) /= N_Compilation_Unit or else Context_Items (Parent_Node) /= Plist then Pragma_Misplaced; return; end if; end if; -- Must be at least one argument if Arg_Count = 0 then Error_Pragma ("pragma% requires at least one argument"); end if; -- In Ada 83 mode, there can be no items following it in the -- context list except other pragmas and implicit with clauses -- (e.g. those added by use of Rtsfind). In Ada 95 mode, this -- placement rule does not apply. if Ada_83 and then Comes_From_Source (N) then Citem := Next (N); while Present (Citem) loop if Nkind (Citem) = N_Pragma or else (Nkind (Citem) = N_With_Clause and then Implicit_With (Citem)) then null; else Error_Pragma ("(Ada 83) pragma% must be at end of context clause"); end if; Next (Citem); end loop; end if; -- Finally, the arguments must all be units mentioned in a with -- clause in the same context clause. Note we already checked -- (in Par.Prag) that the arguments are either identifiers or Arg := Arg1; Outer : while Present (Arg) loop Citem := First (Plist); Inner : while Citem /= N loop if Nkind (Citem) = N_With_Clause and then Same_Name (Name (Citem), Expression (Arg)) then Set_Elaborate_Present (Citem, True); Set_Unit_Name (Expression (Arg), Name (Citem)); Set_Suppress_Elaboration_Warnings (Entity (Name (Citem))); exit Inner; end if; Next (Citem); end loop Inner; if Citem = N then Error_Pragma_Arg ("argument of pragma% is not with'ed unit", Arg); end if; Next (Arg); end loop Outer; -- Give a warning if operating in static mode with -gnatwl -- (elaboration warnings eanbled) switch set. if Elab_Warnings and not Dynamic_Elaboration_Checks then Error_Msg_N ("?use of pragma Elaborate may not be safe", N); Error_Msg_N ("?use pragma Elaborate_All instead if possible", N); end if; end Elaborate; ------------------- -- Elaborate_All -- ------------------- -- pragma Elaborate_All (library_unit_NAME {, library_unit_NAME}); when Pragma_Elaborate_All => Elaborate_All : declare Plist : List_Id; Parent_Node : Node_Id; Arg : Node_Id; Citem : Node_Id; begin Check_Ada_83_Warning; -- Pragma must be in context items list of a compilation unit if not Is_List_Member (N) then Pragma_Misplaced; return; else Plist := List_Containing (N); Parent_Node := Parent (Plist); if Parent_Node = Empty or else Nkind (Parent_Node) /= N_Compilation_Unit or else Context_Items (Parent_Node) /= Plist then Pragma_Misplaced; return; end if; end if; -- Must be at least one argument if Arg_Count = 0 then Error_Pragma ("pragma% requires at least one argument"); end if; -- Note: unlike pragma Elaborate, pragma Elaborate_All does not -- have to appear at the end of the context clause, but may -- appear mixed in with other items, even in Ada 83 mode. -- Final check: the arguments must all be units mentioned in -- a with clause in the same context clause. Note that we -- already checked (in Par.Prag) that all the arguments are -- either identifiers or selected components. Arg := Arg1; Outr : while Present (Arg) loop Citem := First (Plist); Innr : while Citem /= N loop if Nkind (Citem) = N_With_Clause and then Same_Name (Name (Citem), Expression (Arg)) then Set_Elaborate_All_Present (Citem, True); Set_Unit_Name (Expression (Arg), Name (Citem)); Set_Suppress_Elaboration_Warnings (Entity (Name (Citem))); exit Innr; end if; Next (Citem); end loop Innr; if Citem = N then Set_Error_Posted (N); Error_Pragma_Arg ("argument of pragma% is not with'ed unit", Arg); end if; Next (Arg); end loop Outr; end Elaborate_All; -------------------- -- Elaborate_Body -- -------------------- -- pragma Elaborate_Body [( library_unit_NAME )]; when Pragma_Elaborate_Body => Elaborate_Body : declare Cunit_Node : Node_Id; Cunit_Ent : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Cunit_Node := Cunit (Current_Sem_Unit); Cunit_Ent := Cunit_Entity (Current_Sem_Unit); if Nkind (Unit (Cunit_Node)) = N_Package_Body or else Nkind (Unit (Cunit_Node)) = N_Subprogram_Body then Error_Pragma ("pragma% must refer to a spec, not a body"); else Set_Body_Required (Cunit_Node, True); Set_Has_Pragma_Elaborate_Body (Cunit_Ent); -- If we are in dynamic elaboration mode, then we suppress -- elaboration warnings for the unit, since it is definitely -- fine NOT to do dynamic checks at the first level (and such -- checks will be suppressed because no elaboration boolean -- is created for Elaborate_Body packages). -- But in the static model of elaboration, Elaborate_Body is -- definitely NOT good enough to ensure elaboration safety on -- its own, since the body may WITH other units that are not -- safe from an elaboration point of view, so a client must -- still do an Elaborate_All on such units. -- Debug flag -gnatdD restores the old behavior of 3.13, -- where Elaborate_Body always suppressed elab warnings. if Dynamic_Elaboration_Checks or Debug_Flag_DD then Set_Suppress_Elaboration_Warnings (Cunit_Ent); end if; end if; end Elaborate_Body; ------------------------ -- Elaboration_Checks -- ------------------------ -- pragma Elaboration_Checks (Static | Dynamic); when Pragma_Elaboration_Checks => GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_One_Of (Arg1, Name_Static, Name_Dynamic); Dynamic_Elaboration_Checks := (Chars (Get_Pragma_Arg (Arg1)) = Name_Dynamic); --------------- -- Eliminate -- --------------- -- pragma Eliminate ( -- [Unit_Name =>] IDENTIFIER | -- SELECTED_COMPONENT -- [,[Entity =>] IDENTIFIER | -- SELECTED_COMPONENT | -- STRING_LITERAL] -- [,[Parameter_Types =>] PARAMETER_TYPES] -- [,[Result_Type =>] result_SUBTYPE_NAME] -- [,[Homonym_Number =>] INTEGER_LITERAL]); -- PARAMETER_TYPES ::= (SUBTYPE_NAME {, SUBTYPE_NAME}) -- SUBTYPE_NAME ::= STRING_LITERAL when Pragma_Eliminate => Eliminate : declare Args : Args_List (1 .. 5); Names : constant Name_List (1 .. 5) := ( Name_Unit_Name, Name_Entity, Name_Parameter_Types, Name_Result_Type, Name_Homonym_Number); Unit_Name : Node_Id renames Args (1); Entity : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Result_Type : Node_Id renames Args (4); Homonym_Number : Node_Id renames Args (5); begin GNAT_Pragma; Check_Valid_Configuration_Pragma; Gather_Associations (Names, Args); if No (Unit_Name) then Error_Pragma ("missing Unit_Name argument for pragma%"); end if; if No (Entity) and then (Present (Parameter_Types) or else Present (Result_Type) or else Present (Homonym_Number)) then Error_Pragma ("missing Entity argument for pragma%"); end if; Process_Eliminate_Pragma (N, Unit_Name, Entity, Parameter_Types, Result_Type, Homonym_Number); end Eliminate; -------------------------- -- Explicit_Overriding -- -------------------------- when Pragma_Explicit_Overriding => Check_Valid_Configuration_Pragma; Check_Arg_Count (0); Explicit_Overriding := True; ------------ -- Export -- ------------ -- pragma Export ( -- [ Convention =>] convention_IDENTIFIER, -- [ Entity =>] local_NAME -- [, [External_Name =>] static_string_EXPRESSION ] -- [, [Link_Name =>] static_string_EXPRESSION ]); when Pragma_Export => Export : declare C : Convention_Id; Def_Id : Entity_Id; begin Check_Ada_83_Warning; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Convention (C, Def_Id); if Ekind (Def_Id) /= E_Constant then Note_Possible_Modification (Expression (Arg2)); end if; Process_Interface_Name (Def_Id, Arg3, Arg4); Set_Exported (Def_Id, Arg2); end Export; ---------------------- -- Export_Exception -- ---------------------- -- pragma Export_Exception ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL,] -- [, [Form =>] Ada | VMS] -- [, [Code =>] static_integer_EXPRESSION]); when Pragma_Export_Exception => Export_Exception : declare Args : Args_List (1 .. 4); Names : constant Name_List (1 .. 4) := ( Name_Internal, Name_External, Name_Form, Name_Code); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Form : Node_Id renames Args (3); Code : Node_Id renames Args (4); begin if Inside_A_Generic then Error_Pragma ("pragma% cannot be used for generic entities"); end if; Gather_Associations (Names, Args); Process_Extended_Import_Export_Exception_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Form => Form, Arg_Code => Code); if not Is_VMS_Exception (Entity (Internal)) then Set_Exported (Entity (Internal), Internal); end if; end Export_Exception; --------------------- -- Export_Function -- --------------------- -- pragma Export_Function ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL,] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Result_Type =>] TYPE_DESIGNATOR] -- [, [Mechanism =>] MECHANISM] -- [, [Result_Mechanism =>] MECHANISM_NAME]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Export_Function => Export_Function : declare Args : Args_List (1 .. 6); Names : constant Name_List (1 .. 6) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Result_Type, Name_Mechanism, Name_Result_Mechanism); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Result_Type : Node_Id renames Args (4); Mechanism : Node_Id renames Args (5); Result_Mechanism : Node_Id renames Args (6); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Result_Type => Result_Type, Arg_Mechanism => Mechanism, Arg_Result_Mechanism => Result_Mechanism); end Export_Function; ------------------- -- Export_Object -- ------------------- -- pragma Export_Object ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Size =>] EXTERNAL_SYMBOL]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Export_Object => Export_Object : declare Args : Args_List (1 .. 3); Names : constant Name_List (1 .. 3) := ( Name_Internal, Name_External, Name_Size); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Size : Node_Id renames Args (3); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Object_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Size => Size); end Export_Object; ---------------------- -- Export_Procedure -- ---------------------- -- pragma Export_Procedure ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL,] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Mechanism =>] MECHANISM]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Export_Procedure => Export_Procedure : declare Args : Args_List (1 .. 4); Names : constant Name_List (1 .. 4) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Mechanism); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Mechanism : Node_Id renames Args (4); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Mechanism => Mechanism); end Export_Procedure; ------------------ -- Export_Value -- ------------------ -- pragma Export_Value ( -- [Value =>] static_integer_EXPRESSION, -- [Link_Name =>] static_string_EXPRESSION); when Pragma_Export_Value => GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Value); Check_Arg_Is_Static_Expression (Arg1, Any_Integer); Check_Optional_Identifier (Arg2, Name_Link_Name); Check_Arg_Is_Static_Expression (Arg2, Standard_String); ----------------------------- -- Export_Valued_Procedure -- ----------------------------- -- pragma Export_Valued_Procedure ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL,] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Mechanism =>] MECHANISM]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Export_Valued_Procedure => Export_Valued_Procedure : declare Args : Args_List (1 .. 4); Names : constant Name_List (1 .. 4) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Mechanism); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Mechanism : Node_Id renames Args (4); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Mechanism => Mechanism); end Export_Valued_Procedure; ------------------- -- Extend_System -- ------------------- -- pragma Extend_System ([Name =>] Identifier); when Pragma_Extend_System => Extend_System : declare begin GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Name); Check_Arg_Is_Identifier (Arg1); Get_Name_String (Chars (Expression (Arg1))); if Name_Len > 4 and then Name_Buffer (1 .. 4) = "aux_" then if Present (System_Extend_Pragma_Arg) then if Chars (Expression (Arg1)) = Chars (Expression (System_Extend_Pragma_Arg)) then null; else Error_Msg_Sloc := Sloc (System_Extend_Pragma_Arg); Error_Pragma ("pragma% conflicts with that at#"); end if; else System_Extend_Pragma_Arg := Arg1; if not GNAT_Mode then System_Extend_Unit := Arg1; end if; end if; else Error_Pragma ("incorrect name for pragma%, must be Aux_xxx"); end if; end Extend_System; ------------------------ -- Extensions_Allowed -- ------------------------ -- pragma Extensions_Allowed (ON | OFF); when Pragma_Extensions_Allowed => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); Extensions_Allowed := (Chars (Expression (Arg1)) = Name_On); -------------- -- External -- -------------- -- pragma External ( -- [ Convention =>] convention_IDENTIFIER, -- [ Entity =>] local_NAME -- [, [External_Name =>] static_string_EXPRESSION ] -- [, [Link_Name =>] static_string_EXPRESSION ]); when Pragma_External => External : declare C : Convention_Id; Def_Id : Entity_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Convention (C, Def_Id); Note_Possible_Modification (Expression (Arg2)); Process_Interface_Name (Def_Id, Arg3, Arg4); Set_Exported (Def_Id, Arg2); end External; -------------------------- -- External_Name_Casing -- -------------------------- -- pragma External_Name_Casing ( -- UPPERCASE | LOWERCASE -- [, AS_IS | UPPERCASE | LOWERCASE]); when Pragma_External_Name_Casing => External_Name_Casing : declare begin GNAT_Pragma; Check_No_Identifiers; if Arg_Count = 2 then Check_Arg_Is_One_Of (Arg2, Name_As_Is, Name_Uppercase, Name_Lowercase); case Chars (Get_Pragma_Arg (Arg2)) is when Name_As_Is => Opt.External_Name_Exp_Casing := As_Is; when Name_Uppercase => Opt.External_Name_Exp_Casing := Uppercase; when Name_Lowercase => Opt.External_Name_Exp_Casing := Lowercase; when others => null; end case; else Check_Arg_Count (1); end if; Check_Arg_Is_One_Of (Arg1, Name_Uppercase, Name_Lowercase); case Chars (Get_Pragma_Arg (Arg1)) is when Name_Uppercase => Opt.External_Name_Imp_Casing := Uppercase; when Name_Lowercase => Opt.External_Name_Imp_Casing := Lowercase; when others => null; end case; end External_Name_Casing; --------------------------- -- Finalize_Storage_Only -- --------------------------- -- pragma Finalize_Storage_Only (first_subtype_LOCAL_NAME); when Pragma_Finalize_Storage_Only => Finalize_Storage : declare Assoc : constant Node_Id := Arg1; Type_Id : constant Node_Id := Expression (Assoc); Typ : Entity_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type or else Rep_Item_Too_Early (Typ, N) then return; else Typ := Underlying_Type (Typ); end if; if not Is_Controlled (Typ) then Error_Pragma ("pragma% must specify controlled type"); end if; Check_First_Subtype (Arg1); if Finalize_Storage_Only (Typ) then Error_Pragma ("duplicate pragma%, only one allowed"); elsif not Rep_Item_Too_Late (Typ, N) then Set_Finalize_Storage_Only (Base_Type (Typ), True); end if; end Finalize_Storage; -------------------------- -- Float_Representation -- -------------------------- -- pragma Float_Representation (VAX_Float | IEEE_Float); when Pragma_Float_Representation => Float_Representation : declare Argx : Node_Id; Digs : Nat; Ent : Entity_Id; begin GNAT_Pragma; if Arg_Count = 1 then Check_Valid_Configuration_Pragma; else Check_Arg_Count (2); Check_Optional_Identifier (Arg2, Name_Entity); Check_Arg_Is_Local_Name (Arg2); end if; Check_No_Identifier (Arg1); Check_Arg_Is_One_Of (Arg1, Name_VAX_Float, Name_IEEE_Float); if not OpenVMS_On_Target then if Chars (Expression (Arg1)) = Name_VAX_Float then Error_Pragma ("?pragma% ignored (applies only to Open'V'M'S)"); end if; return; end if; -- One argument case if Arg_Count = 1 then if Chars (Expression (Arg1)) = Name_VAX_Float then if Opt.Float_Format = 'I' then Error_Pragma ("'I'E'E'E format previously specified"); end if; Opt.Float_Format := 'V'; else if Opt.Float_Format = 'V' then Error_Pragma ("'V'A'X format previously specified"); end if; Opt.Float_Format := 'I'; end if; Set_Standard_Fpt_Formats; -- Two argument case else Argx := Get_Pragma_Arg (Arg2); if not Is_Entity_Name (Argx) or else not Is_Floating_Point_Type (Entity (Argx)) then Error_Pragma_Arg ("second argument of% pragma must be floating-point type", Arg2); end if; Ent := Entity (Argx); Digs := UI_To_Int (Digits_Value (Ent)); -- Two arguments, VAX_Float case if Chars (Expression (Arg1)) = Name_VAX_Float then case Digs is when 6 => Set_F_Float (Ent); when 9 => Set_D_Float (Ent); when 15 => Set_G_Float (Ent); when others => Error_Pragma_Arg ("wrong digits value, must be 6,9 or 15", Arg2); end case; -- Two arguments, IEEE_Float case else case Digs is when 6 => Set_IEEE_Short (Ent); when 15 => Set_IEEE_Long (Ent); when others => Error_Pragma_Arg ("wrong digits value, must be 6 or 15", Arg2); end case; end if; end if; end Float_Representation; ----------- -- Ident -- ----------- -- pragma Ident (static_string_EXPRESSION) -- Note: pragma Comment shares this processing. Pragma Comment -- is identical to Ident, except that the restriction of the -- argument to 31 characters and the placement restrictions -- are not enforced for pragma Comment. when Pragma_Ident | Pragma_Comment => Ident : declare Str : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Static_Expression (Arg1, Standard_String); -- For pragma Ident, preserve DEC compatibility by requiring -- the pragma to appear in a declarative part or package spec. if Prag_Id = Pragma_Ident then Check_Is_In_Decl_Part_Or_Package_Spec; end if; Str := Expr_Value_S (Expression (Arg1)); declare CS : Node_Id; GP : Node_Id; begin GP := Parent (Parent (N)); if Nkind (GP) = N_Package_Declaration or else Nkind (GP) = N_Generic_Package_Declaration then GP := Parent (GP); end if; -- If we have a compilation unit, then record the ident -- value, checking for improper duplication. if Nkind (GP) = N_Compilation_Unit then CS := Ident_String (Current_Sem_Unit); if Present (CS) then -- For Ident, we do not permit multiple instances if Prag_Id = Pragma_Ident then Error_Pragma ("duplicate% pragma not permitted"); -- For Comment, we concatenate the string, unless we -- want to preserve the tree structure for ASIS. elsif not ASIS_Mode then Start_String (Strval (CS)); Store_String_Char (' '); Store_String_Chars (Strval (Str)); Set_Strval (CS, End_String); end if; else -- In VMS, the effect of IDENT is achieved by passing -- IDENTIFICATION=name as a --for-linker switch. if OpenVMS_On_Target then Start_String; Store_String_Chars ("--for-linker=IDENTIFICATION="); String_To_Name_Buffer (Strval (Str)); Store_String_Chars (Name_Buffer (1 .. Name_Len)); -- Only the last processed IDENT is saved. The main -- purpose is so an IDENT associated with a main -- procedure will be used in preference to an IDENT -- associated with a with'd package. Replace_Linker_Option_String (End_String, "--for-linker=IDENTIFICATION="); end if; Set_Ident_String (Current_Sem_Unit, Str); end if; -- For subunits, we just ignore the Ident, since in GNAT -- these are not separate object files, and hence not -- separate units in the unit table. elsif Nkind (GP) = N_Subunit then null; -- Otherwise we have a misplaced pragma Ident, but we ignore -- this if we are in an instantiation, since it comes from -- a generic, and has no relevance to the instantiation. elsif Prag_Id = Pragma_Ident then if Instantiation_Location (Loc) = No_Location then Error_Pragma ("pragma% only allowed at outer level"); end if; end if; end; end Ident; ------------ -- Import -- ------------ -- pragma Import ( -- [ Convention =>] convention_IDENTIFIER, -- [ Entity =>] local_NAME -- [, [External_Name =>] static_string_EXPRESSION ] -- [, [Link_Name =>] static_string_EXPRESSION ]); when Pragma_Import => Check_Ada_83_Warning; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Import_Or_Interface; ---------------------- -- Import_Exception -- ---------------------- -- pragma Import_Exception ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL,] -- [, [Form =>] Ada | VMS] -- [, [Code =>] static_integer_EXPRESSION]); when Pragma_Import_Exception => Import_Exception : declare Args : Args_List (1 .. 4); Names : constant Name_List (1 .. 4) := ( Name_Internal, Name_External, Name_Form, Name_Code); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Form : Node_Id renames Args (3); Code : Node_Id renames Args (4); begin Gather_Associations (Names, Args); if Present (External) and then Present (Code) then Error_Pragma ("cannot give both External and Code options for pragma%"); end if; Process_Extended_Import_Export_Exception_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Form => Form, Arg_Code => Code); if not Is_VMS_Exception (Entity (Internal)) then Set_Imported (Entity (Internal)); end if; end Import_Exception; --------------------- -- Import_Function -- --------------------- -- pragma Import_Function ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Result_Type =>] SUBTYPE_MARK] -- [, [Mechanism =>] MECHANISM] -- [, [Result_Mechanism =>] MECHANISM_NAME] -- [, [First_Optional_Parameter =>] IDENTIFIER]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Import_Function => Import_Function : declare Args : Args_List (1 .. 7); Names : constant Name_List (1 .. 7) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Result_Type, Name_Mechanism, Name_Result_Mechanism, Name_First_Optional_Parameter); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Result_Type : Node_Id renames Args (4); Mechanism : Node_Id renames Args (5); Result_Mechanism : Node_Id renames Args (6); First_Optional_Parameter : Node_Id renames Args (7); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Result_Type => Result_Type, Arg_Mechanism => Mechanism, Arg_Result_Mechanism => Result_Mechanism, Arg_First_Optional_Parameter => First_Optional_Parameter); end Import_Function; ------------------- -- Import_Object -- ------------------- -- pragma Import_Object ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Size =>] EXTERNAL_SYMBOL]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION when Pragma_Import_Object => Import_Object : declare Args : Args_List (1 .. 3); Names : constant Name_List (1 .. 3) := ( Name_Internal, Name_External, Name_Size); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Size : Node_Id renames Args (3); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Object_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Size => Size); end Import_Object; ---------------------- -- Import_Procedure -- ---------------------- -- pragma Import_Procedure ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Mechanism =>] MECHANISM] -- [, [First_Optional_Parameter =>] IDENTIFIER]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Import_Procedure => Import_Procedure : declare Args : Args_List (1 .. 5); Names : constant Name_List (1 .. 5) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Mechanism, Name_First_Optional_Parameter); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Mechanism : Node_Id renames Args (4); First_Optional_Parameter : Node_Id renames Args (5); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Mechanism => Mechanism, Arg_First_Optional_Parameter => First_Optional_Parameter); end Import_Procedure; ----------------------------- -- Import_Valued_Procedure -- ----------------------------- -- pragma Import_Valued_Procedure ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Parameter_Types =>] (PARAMETER_TYPES)] -- [, [Mechanism =>] MECHANISM] -- [, [First_Optional_Parameter =>] IDENTIFIER]); -- EXTERNAL_SYMBOL ::= -- IDENTIFIER -- | static_string_EXPRESSION -- PARAMETER_TYPES ::= -- null -- | TYPE_DESIGNATOR @{, TYPE_DESIGNATOR@} -- TYPE_DESIGNATOR ::= -- subtype_NAME -- | subtype_Name ' Access -- MECHANISM ::= -- MECHANISM_NAME -- | (MECHANISM_ASSOCIATION @{, MECHANISM_ASSOCIATION@}) -- MECHANISM_ASSOCIATION ::= -- [formal_parameter_NAME =>] MECHANISM_NAME -- MECHANISM_NAME ::= -- Value -- | Reference -- | Descriptor [([Class =>] CLASS_NAME)] -- CLASS_NAME ::= ubs | ubsb | uba | s | sb | a | nca when Pragma_Import_Valued_Procedure => Import_Valued_Procedure : declare Args : Args_List (1 .. 5); Names : constant Name_List (1 .. 5) := ( Name_Internal, Name_External, Name_Parameter_Types, Name_Mechanism, Name_First_Optional_Parameter); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Parameter_Types : Node_Id renames Args (3); Mechanism : Node_Id renames Args (4); First_Optional_Parameter : Node_Id renames Args (5); begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Subprogram_Pragma ( Arg_Internal => Internal, Arg_External => External, Arg_Parameter_Types => Parameter_Types, Arg_Mechanism => Mechanism, Arg_First_Optional_Parameter => First_Optional_Parameter); end Import_Valued_Procedure; ------------------------ -- Initialize_Scalars -- ------------------------ -- pragma Initialize_Scalars; when Pragma_Initialize_Scalars => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Check_Restriction (No_Initialize_Scalars, N); if not Restriction_Active (No_Initialize_Scalars) then Init_Or_Norm_Scalars := True; Initialize_Scalars := True; end if; ------------ -- Inline -- ------------ -- pragma Inline ( NAME {, NAME} ); when Pragma_Inline => -- Pragma is active if inlining option is active if Inline_Active then Process_Inline (True); -- Pragma is active in a predefined file in config run time mode elsif Configurable_Run_Time_Mode and then Is_Predefined_File_Name (Unit_File_Name (Current_Sem_Unit)) then Process_Inline (True); -- Otherwise inlining is not active else Process_Inline (False); end if; ------------------- -- Inline_Always -- ------------------- -- pragma Inline_Always ( NAME {, NAME} ); when Pragma_Inline_Always => Process_Inline (True); -------------------- -- Inline_Generic -- -------------------- -- pragma Inline_Generic (NAME {, NAME}); when Pragma_Inline_Generic => Process_Generic_List; ---------------------- -- Inspection_Point -- ---------------------- -- pragma Inspection_Point [(object_NAME {, object_NAME})]; when Pragma_Inspection_Point => Inspection_Point : declare Arg : Node_Id; Exp : Node_Id; begin if Arg_Count > 0 then Arg := Arg1; loop Exp := Expression (Arg); Analyze (Exp); if not Is_Entity_Name (Exp) or else not Is_Object (Entity (Exp)) then Error_Pragma_Arg ("object name required", Arg); end if; Next (Arg); exit when No (Arg); end loop; end if; end Inspection_Point; --------------- -- Interface -- --------------- -- pragma Interface ( -- convention_IDENTIFIER, -- local_NAME ); when Pragma_Interface => GNAT_Pragma; Check_Arg_Count (2); Check_No_Identifiers; Process_Import_Or_Interface; -------------------- -- Interface_Name -- -------------------- -- pragma Interface_Name ( -- [ Entity =>] local_NAME -- [,[External_Name =>] static_string_EXPRESSION ] -- [,[Link_Name =>] static_string_EXPRESSION ]); when Pragma_Interface_Name => Interface_Name : declare Id : Node_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; Found : Boolean; begin GNAT_Pragma; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (3); Id := Expression (Arg1); Analyze (Id); if not Is_Entity_Name (Id) then Error_Pragma_Arg ("first argument for pragma% must be entity name", Arg1); elsif Etype (Id) = Any_Type then return; else Def_Id := Entity (Id); end if; -- Special DEC-compatible processing for the object case, -- forces object to be imported. if Ekind (Def_Id) = E_Variable then Kill_Size_Check_Code (Def_Id); Note_Possible_Modification (Id); -- Initialization is not allowed for imported variable if Present (Expression (Parent (Def_Id))) and then Comes_From_Source (Expression (Parent (Def_Id))) then Error_Msg_Sloc := Sloc (Def_Id); Error_Pragma_Arg ("no initialization allowed for declaration of& #", Arg2); else -- For compatibility, support VADS usage of providing both -- pragmas Interface and Interface_Name to obtain the effect -- of a single Import pragma. if Is_Imported (Def_Id) and then Present (First_Rep_Item (Def_Id)) and then Nkind (First_Rep_Item (Def_Id)) = N_Pragma and then Chars (First_Rep_Item (Def_Id)) = Name_Interface then null; else Set_Imported (Def_Id); end if; Set_Is_Public (Def_Id); Process_Interface_Name (Def_Id, Arg2, Arg3); end if; -- Otherwise must be subprogram elsif not Is_Subprogram (Def_Id) then Error_Pragma_Arg ("argument of pragma% is not subprogram", Arg1); else Check_At_Most_N_Arguments (3); Hom_Id := Def_Id; Found := False; -- Loop through homonyms loop Def_Id := Get_Base_Subprogram (Hom_Id); if Is_Imported (Def_Id) then Process_Interface_Name (Def_Id, Arg2, Arg3); Found := True; end if; Hom_Id := Homonym (Hom_Id); exit when No (Hom_Id) or else Scope (Hom_Id) /= Current_Scope; end loop; if not Found then Error_Pragma_Arg ("argument of pragma% is not imported subprogram", Arg1); end if; end if; end Interface_Name; ----------------------- -- Interrupt_Handler -- ----------------------- -- pragma Interrupt_Handler (handler_NAME); when Pragma_Interrupt_Handler => Check_Ada_83_Warning; Check_Arg_Count (1); Check_No_Identifiers; if No_Run_Time_Mode then Error_Msg_CRT ("Interrupt_Handler pragma", N); else Check_Interrupt_Or_Attach_Handler; Process_Interrupt_Or_Attach_Handler; end if; ------------------------ -- Interrupt_Priority -- ------------------------ -- pragma Interrupt_Priority [(EXPRESSION)]; when Pragma_Interrupt_Priority => Interrupt_Priority : declare P : constant Node_Id := Parent (N); Arg : Node_Id; begin Check_Ada_83_Warning; if Arg_Count /= 0 then Arg := Expression (Arg1); Check_Arg_Count (1); Check_No_Identifiers; -- The expression must be analyzed in the special manner -- described in "Handling of Default and Per-Object -- Expressions" in sem.ads. Analyze_Per_Use_Expression (Arg, RTE (RE_Interrupt_Priority)); end if; if Nkind (P) /= N_Task_Definition and then Nkind (P) /= N_Protected_Definition then Pragma_Misplaced; return; elsif Has_Priority_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); else Set_Has_Priority_Pragma (P, True); Record_Rep_Item (Defining_Identifier (Parent (P)), N); end if; end Interrupt_Priority; --------------------- -- Interrupt_State -- --------------------- -- pragma Interrupt_State ( -- [Name =>] INTERRUPT_ID, -- [State =>] INTERRUPT_STATE); -- INTERRUPT_ID => IDENTIFIER | static_integer_EXPRESSION -- INTERRUPT_STATE => System | Runtime | User -- Note: if the interrupt id is given as an identifier, then -- it must be one of the identifiers in Ada.Interrupts.Names. -- Otherwise it is given as a static integer expression which -- must be in the range of Ada.Interrupts.Interrupt_ID. when Pragma_Interrupt_State => Interrupt_State : declare Int_Id : constant Entity_Id := RTE (RE_Interrupt_ID); -- This is the entity Ada.Interrupts.Interrupt_ID; State_Type : Character; -- Set to 's'/'r'/'u' for System/Runtime/User IST_Num : Pos; -- Index to entry in Interrupt_States table Int_Val : Uint; -- Value of interrupt Arg1X : constant Node_Id := Get_Pragma_Arg (Arg1); -- The first argument to the pragma Int_Ent : Entity_Id; -- Interrupt entity in Ada.Interrupts.Names begin GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Name); Check_Optional_Identifier (Arg2, "state"); Check_Arg_Is_Identifier (Arg2); -- First argument is identifier if Nkind (Arg1X) = N_Identifier then -- Search list of names in Ada.Interrupts.Names Int_Ent := First_Entity (RTE (RE_Names)); loop if No (Int_Ent) then Error_Pragma_Arg ("invalid interrupt name", Arg1); elsif Chars (Int_Ent) = Chars (Arg1X) then Int_Val := Expr_Value (Constant_Value (Int_Ent)); exit; end if; Next_Entity (Int_Ent); end loop; -- First argument is not an identifier, so it must be a -- static expression of type Ada.Interrupts.Interrupt_ID. else Check_Arg_Is_Static_Expression (Arg1, Any_Integer); Int_Val := Expr_Value (Arg1X); if Int_Val < Expr_Value (Type_Low_Bound (Int_Id)) or else Int_Val > Expr_Value (Type_High_Bound (Int_Id)) then Error_Pragma_Arg ("value not in range of type " & """Ada.Interrupts.Interrupt_'I'D""", Arg1); end if; end if; -- Check OK state case Chars (Get_Pragma_Arg (Arg2)) is when Name_Runtime => State_Type := 'r'; when Name_System => State_Type := 's'; when Name_User => State_Type := 'u'; when others => Error_Pragma_Arg ("invalid interrupt state", Arg2); end case; -- Check if entry is already stored IST_Num := Interrupt_States.First; loop -- If entry not found, add it if IST_Num > Interrupt_States.Last then Interrupt_States.Append ((Interrupt_Number => UI_To_Int (Int_Val), Interrupt_State => State_Type, Pragma_Loc => Loc)); exit; -- Case of entry for the same entry elsif Int_Val = Interrupt_States.Table (IST_Num). Interrupt_Number then -- If state matches, done, no need to make redundant entry exit when State_Type = Interrupt_States.Table (IST_Num). Interrupt_State; -- Otherwise if state does not match, error Error_Msg_Sloc := Interrupt_States.Table (IST_Num).Pragma_Loc; Error_Pragma_Arg ("state conflicts with that given at #", Arg2); exit; end if; IST_Num := IST_Num + 1; end loop; end Interrupt_State; ---------------------- -- Java_Constructor -- ---------------------- -- pragma Java_Constructor ([Entity =>] LOCAL_NAME); when Pragma_Java_Constructor => Java_Constructor : declare Id : Entity_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Id := Expression (Arg1); Find_Program_Unit_Name (Id); -- If we did not find the name, we are done if Etype (Id) = Any_Type then return; end if; Hom_Id := Entity (Id); -- Loop through homonyms loop Def_Id := Get_Base_Subprogram (Hom_Id); -- The constructor is required to be a function returning -- an access type whose designated type has convention Java. if Ekind (Def_Id) = E_Function and then Ekind (Etype (Def_Id)) in Access_Kind and then (Atree.Convention (Designated_Type (Etype (Def_Id))) = Convention_Java or else Atree.Convention (Root_Type (Designated_Type (Etype (Def_Id)))) = Convention_Java) then Set_Is_Constructor (Def_Id); Set_Convention (Def_Id, Convention_Java); else Error_Pragma_Arg ("pragma% requires function returning a 'Java access type", Arg1); end if; Hom_Id := Homonym (Hom_Id); exit when No (Hom_Id) or else Scope (Hom_Id) /= Current_Scope; end loop; end Java_Constructor; ---------------------- -- Java_Interface -- ---------------------- -- pragma Java_Interface ([Entity =>] LOCAL_NAME); when Pragma_Java_Interface => Java_Interface : declare Arg : Node_Id; Typ : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Arg := Expression (Arg1); Analyze (Arg); if Etype (Arg) = Any_Type then return; end if; if not Is_Entity_Name (Arg) or else not Is_Type (Entity (Arg)) then Error_Pragma_Arg ("pragma% requires a type mark", Arg1); end if; Typ := Underlying_Type (Entity (Arg)); -- For now we simply check some of the semantic constraints -- on the type. This currently leaves out some restrictions -- on interface types, namely that the parent type must be -- java.lang.Object.Typ and that all primitives of the type -- should be declared abstract. ??? if not Is_Tagged_Type (Typ) or else not Is_Abstract (Typ) then Error_Pragma_Arg ("pragma% requires an abstract " & "tagged type", Arg1); elsif not Has_Discriminants (Typ) or else Ekind (Etype (First_Discriminant (Typ))) /= E_Anonymous_Access_Type or else not Is_Class_Wide_Type (Designated_Type (Etype (First_Discriminant (Typ)))) then Error_Pragma_Arg ("type must have a class-wide access discriminant", Arg1); end if; end Java_Interface; ---------------- -- Keep_Names -- ---------------- -- pragma Keep_Names ([On => ] local_NAME); when Pragma_Keep_Names => Keep_Names : declare Arg : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_On); Check_Arg_Is_Local_Name (Arg1); Arg := Expression (Arg1); Analyze (Arg); if Etype (Arg) = Any_Type then return; end if; if not Is_Entity_Name (Arg) or else Ekind (Entity (Arg)) /= E_Enumeration_Type then Error_Pragma_Arg ("pragma% requires a local enumeration type", Arg1); end if; Set_Discard_Names (Entity (Arg), False); end Keep_Names; ------------- -- License -- ------------- -- pragma License (RESTRICTED | UNRESRICTED | GPL | MODIFIED_GPL); when Pragma_License => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Valid_Configuration_Pragma; Check_Arg_Is_Identifier (Arg1); declare Sind : constant Source_File_Index := Source_Index (Current_Sem_Unit); begin case Chars (Get_Pragma_Arg (Arg1)) is when Name_GPL => Set_License (Sind, GPL); when Name_Modified_GPL => Set_License (Sind, Modified_GPL); when Name_Restricted => Set_License (Sind, Restricted); when Name_Unrestricted => Set_License (Sind, Unrestricted); when others => Error_Pragma_Arg ("invalid license name", Arg1); end case; end; --------------- -- Link_With -- --------------- -- pragma Link_With (string_EXPRESSION {, string_EXPRESSION}); when Pragma_Link_With => Link_With : declare Arg : Node_Id; begin GNAT_Pragma; if Operating_Mode = Generate_Code and then In_Extended_Main_Source_Unit (N) then Check_At_Least_N_Arguments (1); Check_No_Identifiers; Check_Is_In_Decl_Part_Or_Package_Spec; Check_Arg_Is_Static_Expression (Arg1, Standard_String); Start_String; Arg := Arg1; while Present (Arg) loop Check_Arg_Is_Static_Expression (Arg, Standard_String); -- Store argument, converting sequences of spaces -- to a single null character (this is one of the -- differences in processing between Link_With -- and Linker_Options). declare C : constant Char_Code := Get_Char_Code (' '); S : constant String_Id := Strval (Expr_Value_S (Expression (Arg))); L : constant Nat := String_Length (S); F : Nat := 1; procedure Skip_Spaces; -- Advance F past any spaces procedure Skip_Spaces is begin while F <= L and then Get_String_Char (S, F) = C loop F := F + 1; end loop; end Skip_Spaces; begin Skip_Spaces; -- skip leading spaces -- Loop through characters, changing any embedded -- sequence of spaces to a single null character -- (this is how Link_With/Linker_Options differ) while F <= L loop if Get_String_Char (S, F) = C then Skip_Spaces; exit when F > L; Store_String_Char (ASCII.NUL); else Store_String_Char (Get_String_Char (S, F)); F := F + 1; end if; end loop; end; Arg := Next (Arg); if Present (Arg) then Store_String_Char (ASCII.NUL); end if; end loop; Store_Linker_Option_String (End_String); end if; end Link_With; ------------------ -- Linker_Alias -- ------------------ -- pragma Linker_Alias ( -- [Entity =>] LOCAL_NAME -- [Alias =>] static_string_EXPRESSION); when Pragma_Linker_Alias => GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, "alias"); Check_Arg_Is_Library_Level_Local_Name (Arg1); Check_Arg_Is_Static_Expression (Arg2, Standard_String); -- The only processing required is to link this item on to the -- list of rep items for the given entity. This is accomplished -- by the call to Rep_Item_Too_Late (when no error is detected -- and False is returned). if Rep_Item_Too_Late (Entity (Expression (Arg1)), N) then return; else Set_Has_Gigi_Rep_Item (Entity (Expression (Arg1))); end if; -------------------- -- Linker_Options -- -------------------- -- pragma Linker_Options (string_EXPRESSION {, string_EXPRESSION}); when Pragma_Linker_Options => Linker_Options : declare Arg : Node_Id; begin Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (1); Check_Is_In_Decl_Part_Or_Package_Spec; if Operating_Mode = Generate_Code and then In_Extended_Main_Source_Unit (N) then Check_Arg_Is_Static_Expression (Arg1, Standard_String); Start_String (Strval (Expr_Value_S (Expression (Arg1)))); Arg := Arg2; while Present (Arg) loop Check_Arg_Is_Static_Expression (Arg, Standard_String); Store_String_Char (ASCII.NUL); Store_String_Chars (Strval (Expr_Value_S (Expression (Arg)))); Arg := Next (Arg); end loop; Store_Linker_Option_String (End_String); end if; end Linker_Options; -------------------- -- Linker_Section -- -------------------- -- pragma Linker_Section ( -- [Entity =>] LOCAL_NAME -- [Section =>] static_string_EXPRESSION); when Pragma_Linker_Section => GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Section); Check_Arg_Is_Library_Level_Local_Name (Arg1); Check_Arg_Is_Static_Expression (Arg2, Standard_String); -- The only processing required is to link this item on to the -- list of rep items for the given entity. This is accomplished -- by the call to Rep_Item_Too_Late (when no error is detected -- and False is returned). if Rep_Item_Too_Late (Entity (Expression (Arg1)), N) then return; else Set_Has_Gigi_Rep_Item (Entity (Expression (Arg1))); end if; ---------- -- List -- ---------- -- pragma List (On | Off) -- There is nothing to do here, since we did all the processing -- for this pragma in Par.Prag (so that it works properly even in -- syntax only mode) when Pragma_List => null; -------------------- -- Locking_Policy -- -------------------- -- pragma Locking_Policy (policy_IDENTIFIER); when Pragma_Locking_Policy => declare LP : Character; begin Check_Ada_83_Warning; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Locking_Policy (Arg1); Check_Valid_Configuration_Pragma; Get_Name_String (Chars (Expression (Arg1))); LP := Fold_Upper (Name_Buffer (1)); if Locking_Policy /= ' ' and then Locking_Policy /= LP then Error_Msg_Sloc := Locking_Policy_Sloc; Error_Pragma ("locking policy incompatible with policy#"); -- Set new policy, but always preserve System_Location since -- we like the error message with the run time name. else Locking_Policy := LP; if Locking_Policy_Sloc /= System_Location then Locking_Policy_Sloc := Loc; end if; end if; end; ---------------- -- Long_Float -- ---------------- -- pragma Long_Float (D_Float | G_Float); when Pragma_Long_Float => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (1); Check_No_Identifier (Arg1); Check_Arg_Is_One_Of (Arg1, Name_D_Float, Name_G_Float); if not OpenVMS_On_Target then Error_Pragma ("?pragma% ignored (applies only to Open'V'M'S)"); end if; -- D_Float case if Chars (Expression (Arg1)) = Name_D_Float then if Opt.Float_Format_Long = 'G' then Error_Pragma ("G_Float previously specified"); end if; Opt.Float_Format_Long := 'D'; -- G_Float case (this is the default, does not need overriding) else if Opt.Float_Format_Long = 'D' then Error_Pragma ("D_Float previously specified"); end if; Opt.Float_Format_Long := 'G'; end if; Set_Standard_Fpt_Formats; ----------------------- -- Machine_Attribute -- ----------------------- -- pragma Machine_Attribute ( -- [Entity =>] LOCAL_NAME, -- [Attribute_Name =>] static_string_EXPRESSION -- [,[Info =>] static_string_EXPRESSION] ); when Pragma_Machine_Attribute => Machine_Attribute : declare Def_Id : Entity_Id; begin GNAT_Pragma; if Arg_Count = 3 then Check_Optional_Identifier (Arg3, "info"); Check_Arg_Is_Static_Expression (Arg3, Standard_String); else Check_Arg_Count (2); end if; Check_Arg_Is_Local_Name (Arg1); Check_Optional_Identifier (Arg2, "attribute_name"); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Static_Expression (Arg2, Standard_String); Def_Id := Entity (Expression (Arg1)); if Is_Access_Type (Def_Id) then Def_Id := Designated_Type (Def_Id); end if; if Rep_Item_Too_Early (Def_Id, N) then return; end if; Def_Id := Underlying_Type (Def_Id); -- The only processing required is to link this item on to the -- list of rep items for the given entity. This is accomplished -- by the call to Rep_Item_Too_Late (when no error is detected -- and False is returned). if Rep_Item_Too_Late (Def_Id, N) then return; else Set_Has_Gigi_Rep_Item (Entity (Expression (Arg1))); end if; end Machine_Attribute; ---------- -- Main -- ---------- -- pragma Main_Storage -- (MAIN_STORAGE_OPTION [, MAIN_STORAGE_OPTION]); -- MAIN_STORAGE_OPTION ::= -- [WORKING_STORAGE =>] static_SIMPLE_EXPRESSION -- | [TOP_GUARD =>] static_SIMPLE_EXPRESSION when Pragma_Main => Main : declare Args : Args_List (1 .. 3); Names : constant Name_List (1 .. 3) := ( Name_Stack_Size, Name_Task_Stack_Size_Default, Name_Time_Slicing_Enabled); Nod : Node_Id; begin GNAT_Pragma; Gather_Associations (Names, Args); for J in 1 .. 2 loop if Present (Args (J)) then Check_Arg_Is_Static_Expression (Args (J), Any_Integer); end if; end loop; if Present (Args (3)) then Check_Arg_Is_Static_Expression (Args (3), Standard_Boolean); end if; Nod := Next (N); while Present (Nod) loop if Nkind (Nod) = N_Pragma and then Chars (Nod) = Name_Main then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("duplicate pragma% not permitted", Nod); end if; Next (Nod); end loop; end Main; ------------------ -- Main_Storage -- ------------------ -- pragma Main_Storage -- (MAIN_STORAGE_OPTION [, MAIN_STORAGE_OPTION]); -- MAIN_STORAGE_OPTION ::= -- [WORKING_STORAGE =>] static_SIMPLE_EXPRESSION -- | [TOP_GUARD =>] static_SIMPLE_EXPRESSION when Pragma_Main_Storage => Main_Storage : declare Args : Args_List (1 .. 2); Names : constant Name_List (1 .. 2) := ( Name_Working_Storage, Name_Top_Guard); Nod : Node_Id; begin GNAT_Pragma; Gather_Associations (Names, Args); for J in 1 .. 2 loop if Present (Args (J)) then Check_Arg_Is_Static_Expression (Args (J), Any_Integer); end if; end loop; Check_In_Main_Program; Nod := Next (N); while Present (Nod) loop if Nkind (Nod) = N_Pragma and then Chars (Nod) = Name_Main_Storage then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("duplicate pragma% not permitted", Nod); end if; Next (Nod); end loop; end Main_Storage; ----------------- -- Memory_Size -- ----------------- -- pragma Memory_Size (NUMERIC_LITERAL) when Pragma_Memory_Size => GNAT_Pragma; -- Memory size is simply ignored Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Integer_Literal (Arg1); --------------- -- No_Return -- --------------- -- pragma No_Return (procedure_LOCAL_NAME); when Pragma_No_Return => No_Return : declare Id : Node_Id; E : Entity_Id; Found : Boolean; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Local_Name (Arg1); Id := Expression (Arg1); Analyze (Id); if not Is_Entity_Name (Id) then Error_Pragma_Arg ("entity name required", Arg1); end if; if Etype (Id) = Any_Type then raise Pragma_Exit; end if; E := Entity (Id); Found := False; while Present (E) and then Scope (E) = Current_Scope loop if Ekind (E) = E_Procedure or else Ekind (E) = E_Generic_Procedure then Set_No_Return (E); Found := True; end if; E := Homonym (E); end loop; if not Found then Error_Pragma ("no procedures found for pragma%"); end if; end No_Return; ----------------- -- Obsolescent -- ----------------- -- pragma Obsolescent [(static_string_EXPRESSION)]; when Pragma_Obsolescent => Obsolescent : declare begin GNAT_Pragma; Check_At_Most_N_Arguments (1); Check_No_Identifiers; if Arg_Count = 1 then Check_Arg_Is_Static_Expression (Arg1, Standard_String); end if; if No (Prev (N)) or else (Nkind (Prev (N))) /= N_Subprogram_Declaration then Error_Pragma ("pragma% misplaced, must immediately " & "follow subprogram spec"); end if; end Obsolescent; ----------------- -- No_Run_Time -- ----------------- -- pragma No_Run_Time -- Note: this pragma is retained for backwards compatibiltiy. -- See body of Rtsfind for full details on its handling. when Pragma_No_Run_Time => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (0); No_Run_Time_Mode := True; Configurable_Run_Time_Mode := True; declare Word32 : constant Boolean := Ttypes.System_Word_Size = 32; begin if Word32 then Duration_32_Bits_On_Target := True; end if; end; Set_Restriction (No_Finalization, N); Set_Restriction (No_Exception_Handlers, N); Set_Restriction (Max_Tasks, N, 0); Set_Restriction (No_Tasking, N); ----------------------- -- Normalize_Scalars -- ----------------------- -- pragma Normalize_Scalars; when Pragma_Normalize_Scalars => Check_Ada_83_Warning; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Normalize_Scalars := True; Init_Or_Norm_Scalars := True; -------------- -- Optimize -- -------------- -- pragma Optimize (Time | Space); -- The actual check for optimize is done in Gigi. Note that this -- pragma does not actually change the optimization setting, it -- simply checks that it is consistent with the pragma. when Pragma_Optimize => Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_One_Of (Arg1, Name_Time, Name_Space, Name_Off); ------------------------- -- Optional_Overriding -- ------------------------- -- These pragmas are treated as part of the previous subprogram -- declaration, and analyzed immediately after it (see sem_ch6, -- Check_Overriding_Operation). If the pragma has not been analyzed -- yet, it appears in the wrong place. when Pragma_Optional_Overriding => Error_Msg_N ("pragma must appear immediately after subprogram", N); ---------------- -- Overriding -- ---------------- when Pragma_Overriding => Error_Msg_N ("pragma must appear immediately after subprogram", N); ---------- -- Pack -- ---------- -- pragma Pack (first_subtype_LOCAL_NAME); when Pragma_Pack => Pack : declare Assoc : constant Node_Id := Arg1; Type_Id : Node_Id; Typ : Entity_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Type_Id := Expression (Assoc); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type or else Rep_Item_Too_Early (Typ, N) then return; else Typ := Underlying_Type (Typ); end if; if not Is_Array_Type (Typ) and then not Is_Record_Type (Typ) then Error_Pragma ("pragma% must specify array or record type"); end if; Check_First_Subtype (Arg1); if Has_Pragma_Pack (Typ) then Error_Pragma ("duplicate pragma%, only one allowed"); -- Array type. We set the Has_Pragma_Pack flag, and Is_Packed, -- but not Has_Non_Standard_Rep, because we don't actually know -- till freeze time if the array can have packed representation. -- That's because in the general case we do not know enough about -- the component type until it in turn is frozen, which certainly -- happens before the array type is frozen, but not necessarily -- till that point (i.e. right now it may be unfrozen). elsif Is_Array_Type (Typ) then if Has_Aliased_Components (Base_Type (Typ)) then Error_Pragma ("pragma% ignored, cannot pack aliased components?"); elsif Has_Atomic_Components (Typ) or else Is_Atomic (Component_Type (Typ)) then Error_Pragma ("?pragma% ignored, cannot pack atomic components"); elsif not Rep_Item_Too_Late (Typ, N) then Set_Is_Packed (Base_Type (Typ)); Set_Has_Pragma_Pack (Base_Type (Typ)); Set_Has_Non_Standard_Rep (Base_Type (Typ)); end if; -- Record type. For record types, the pack is always effective else pragma Assert (Is_Record_Type (Typ)); if not Rep_Item_Too_Late (Typ, N) then Set_Has_Pragma_Pack (Base_Type (Typ)); Set_Is_Packed (Base_Type (Typ)); Set_Has_Non_Standard_Rep (Base_Type (Typ)); end if; end if; end Pack; ---------- -- Page -- ---------- -- pragma Page; -- There is nothing to do here, since we did all the processing -- for this pragma in Par.Prag (so that it works properly even in -- syntax only mode) when Pragma_Page => null; ------------- -- Passive -- ------------- -- pragma Passive [(PASSIVE_FORM)]; -- PASSIVE_FORM ::= Semaphore | No when Pragma_Passive => GNAT_Pragma; if Nkind (Parent (N)) /= N_Task_Definition then Error_Pragma ("pragma% must be within task definition"); end if; if Arg_Count /= 0 then Check_Arg_Count (1); Check_Arg_Is_One_Of (Arg1, Name_Semaphore, Name_No); end if; ------------- -- Polling -- ------------- -- pragma Polling (ON | OFF); when Pragma_Polling => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); Polling_Required := (Chars (Expression (Arg1)) = Name_On); --------------------- -- Persistent_Data -- --------------------- when Pragma_Persistent_Data => declare Ent : Entity_Id; begin -- Register the pragma as applying to the compilation unit. -- Individual Persistent_Object pragmas for relevant objects -- are generated the end of the compilation. GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (0); Ent := Find_Lib_Unit_Name; Set_Is_Preelaborated (Ent); end; ----------------------- -- Persistent_Object -- ----------------------- when Pragma_Persistent_Object => declare Decl : Node_Id; Ent : Entity_Id; MA : Node_Id; Str : String_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_Library_Level_Local_Name (Arg1); if not Is_Entity_Name (Expression (Arg1)) or else (Ekind (Entity (Expression (Arg1))) /= E_Variable and then Ekind (Entity (Expression (Arg1))) /= E_Constant) then Error_Pragma_Arg ("pragma only applies to objects", Arg1); end if; Ent := Entity (Expression (Arg1)); Decl := Parent (Ent); if Nkind (Decl) /= N_Object_Declaration then return; end if; -- Placement of the object depends on whether there is -- an initial value or none. If the No_Initialization flag -- is set, the initialization has been transformed into -- assignments, which is disallowed elaboration code. if No_Initialization (Decl) then Error_Msg_N ("initialization for persistent object" & "must be static expression", Decl); return; end if; if No (Expression (Decl)) then Start_String; Store_String_Chars ("section ("".persistent.bss"")"); Str := End_String; else if not Is_OK_Static_Expression (Expression (Decl)) then Flag_Non_Static_Expr ("initialization for persistent object" & "must be static expression!", Expression (Decl)); return; end if; Start_String; Store_String_Chars ("section ("".persistent.data"")"); Str := End_String; end if; MA := Make_Pragma (Sloc (N), Name_Machine_Attribute, New_List (Make_Pragma_Argument_Association (Sloc => Sloc (Arg1), Expression => New_Occurrence_Of (Ent, Sloc (Ent))), Make_Pragma_Argument_Association (Sloc => Sloc (Arg1), Expression => Make_String_Literal (Sloc => Sloc (Arg1), Strval => Str)))); Insert_After (N, MA); Analyze (MA); Set_Has_Gigi_Rep_Item (Ent); end; ------------------ -- Preelaborate -- ------------------ -- pragma Preelaborate [(library_unit_NAME)]; -- Set the flag Is_Preelaborated of program unit name entity when Pragma_Preelaborate => Preelaborate : declare Pa : constant Node_Id := Parent (N); Pk : constant Node_Kind := Nkind (Pa); Ent : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Ent := Find_Lib_Unit_Name; -- This filters out pragmas inside generic parent then -- show up inside instantiation if Present (Ent) and then not (Pk = N_Package_Specification and then Present (Generic_Parent (Pa))) then if not Debug_Flag_U then Set_Is_Preelaborated (Ent); Set_Suppress_Elaboration_Warnings (Ent); end if; end if; end Preelaborate; -------------- -- Priority -- -------------- -- pragma Priority (EXPRESSION); when Pragma_Priority => Priority : declare P : constant Node_Id := Parent (N); Arg : Node_Id; begin Check_No_Identifiers; Check_Arg_Count (1); -- Subprogram case if Nkind (P) = N_Subprogram_Body then Check_In_Main_Program; Arg := Expression (Arg1); Analyze_And_Resolve (Arg, Standard_Integer); -- Must be static if not Is_Static_Expression (Arg) then Flag_Non_Static_Expr ("main subprogram priority is not static!", Arg); raise Pragma_Exit; -- If constraint error, then we already signalled an error elsif Raises_Constraint_Error (Arg) then null; -- Otherwise check in range else declare Val : constant Uint := Expr_Value (Arg); begin if Val < 0 or else Val > Expr_Value (Expression (Parent (RTE (RE_Max_Priority)))) then Error_Pragma_Arg ("main subprogram priority is out of range", Arg1); end if; end; end if; Set_Main_Priority (Current_Sem_Unit, UI_To_Int (Expr_Value (Arg))); -- Task or Protected, must be of type Integer elsif Nkind (P) = N_Protected_Definition or else Nkind (P) = N_Task_Definition then Arg := Expression (Arg1); -- The expression must be analyzed in the special manner -- described in "Handling of Default and Per-Object -- Expressions" in sem.ads. Analyze_Per_Use_Expression (Arg, Standard_Integer); if not Is_Static_Expression (Arg) then Check_Restriction (Static_Priorities, Arg); end if; -- Anything else is incorrect else Pragma_Misplaced; end if; if Has_Priority_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); else Set_Has_Priority_Pragma (P, True); if Nkind (P) = N_Protected_Definition or else Nkind (P) = N_Task_Definition then Record_Rep_Item (Defining_Identifier (Parent (P)), N); -- exp_ch9 should use this ??? end if; end if; end Priority; ------------- -- Profile -- ------------- -- pragma Profile (profile_IDENTIFIER); -- profile_IDENTIFIER => Ravenscar when Pragma_Profile => GNAT_Pragma; Check_Arg_Count (1); Check_Valid_Configuration_Pragma; Check_No_Identifiers; Set_Ravenscar (N); declare Argx : constant Node_Id := Get_Pragma_Arg (Arg1); begin if Chars (Argx) = Name_Ravenscar then Set_Ravenscar (N); else Error_Pragma_Arg ("& is not a valid profile", Argx); end if; end; -------------------------- -- Propagate_Exceptions -- -------------------------- -- pragma Propagate_Exceptions; when Pragma_Propagate_Exceptions => GNAT_Pragma; Check_Arg_Count (0); if In_Extended_Main_Source_Unit (N) then Propagate_Exceptions := True; end if; ------------------ -- Psect_Object -- ------------------ -- pragma Psect_Object ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Size =>] EXTERNAL_SYMBOL]); when Pragma_Psect_Object | Pragma_Common_Object => Psect_Object : declare Args : Args_List (1 .. 3); Names : constant Name_List (1 .. 3) := ( Name_Internal, Name_External, Name_Size); Internal : Node_Id renames Args (1); External : Node_Id renames Args (2); Size : Node_Id renames Args (3); R_Internal : Node_Id; R_External : Node_Id; MA : Node_Id; Str : String_Id; Def_Id : Entity_Id; procedure Check_Too_Long (Arg : Node_Id); -- Posts message if the argument is an identifier with more -- than 31 characters, or a string literal with more than -- 31 characters, and we are operating under VMS -------------------- -- Check_Too_Long -- -------------------- procedure Check_Too_Long (Arg : Node_Id) is X : constant Node_Id := Original_Node (Arg); begin if Nkind (X) /= N_String_Literal and then Nkind (X) /= N_Identifier then Error_Pragma_Arg ("inappropriate argument for pragma %", Arg); end if; if OpenVMS_On_Target then if (Nkind (X) = N_String_Literal and then String_Length (Strval (X)) > 31) or else (Nkind (X) = N_Identifier and then Length_Of_Name (Chars (X)) > 31) then Error_Pragma_Arg ("argument for pragma % is longer than 31 characters", Arg); end if; end if; end Check_Too_Long; -- Start of processing for Common_Object/Psect_Object begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Internal_Arg (Internal); R_Internal := Relocate_Node (Internal); Def_Id := Entity (R_Internal); if Ekind (Def_Id) /= E_Constant and then Ekind (Def_Id) /= E_Variable then Error_Pragma_Arg ("pragma% must designate an object", Internal); end if; Check_Too_Long (R_Internal); if Is_Imported (Def_Id) or else Is_Exported (Def_Id) then Error_Pragma_Arg ("cannot use pragma% for imported/exported object", R_Internal); end if; if Is_Concurrent_Type (Etype (R_Internal)) then Error_Pragma_Arg ("cannot specify pragma % for task/protected object", R_Internal); end if; if Is_Psected (Def_Id) then Error_Msg_N ("?duplicate Psect_Object pragma", N); else Set_Is_Psected (Def_Id); end if; if Ekind (Def_Id) = E_Constant then Error_Pragma_Arg ("cannot specify pragma % for a constant", R_Internal); end if; if Is_Record_Type (Etype (R_Internal)) then declare Ent : Entity_Id; Decl : Entity_Id; begin Ent := First_Entity (Etype (R_Internal)); while Present (Ent) loop Decl := Declaration_Node (Ent); if Ekind (Ent) = E_Component and then Nkind (Decl) = N_Component_Declaration and then Present (Expression (Decl)) and then Warn_On_Export_Import then Error_Msg_N ("?object for pragma % has defaults", R_Internal); exit; else Next_Entity (Ent); end if; end loop; end; end if; if Present (Size) then Check_Too_Long (Size); end if; -- Make Psect case-insensitive. if Present (External) then Check_Too_Long (External); if Nkind (External) = N_String_Literal then String_To_Name_Buffer (Strval (External)); else Get_Name_String (Chars (External)); end if; Set_All_Upper_Case; Start_String; Store_String_Chars (Name_Buffer (1 .. Name_Len)); Str := End_String; R_External := Make_String_Literal (Sloc => Sloc (External), Strval => Str); else Get_Name_String (Chars (Internal)); Set_All_Upper_Case; Start_String; Store_String_Chars (Name_Buffer (1 .. Name_Len)); Str := End_String; R_External := Make_String_Literal (Sloc => Sloc (Internal), Strval => Str); end if; -- Transform into pragma Linker_Section, add attributes to -- match what DEC Ada does. Ignore size for now? Rewrite (N, Make_Pragma (Sloc (N), Name_Linker_Section, New_List (Make_Pragma_Argument_Association (Sloc => Sloc (R_Internal), Expression => R_Internal), Make_Pragma_Argument_Association (Sloc => Sloc (R_External), Expression => R_External)))); Analyze (N); -- Add Machine_Attribute of "overlaid", so the section overlays -- other sections of the same name. Start_String; Store_String_Chars ("overlaid"); Str := End_String; MA := Make_Pragma (Sloc (N), Name_Machine_Attribute, New_List (Make_Pragma_Argument_Association (Sloc => Sloc (R_Internal), Expression => R_Internal), Make_Pragma_Argument_Association (Sloc => Sloc (R_External), Expression => Make_String_Literal (Sloc => Sloc (R_External), Strval => Str)))); Analyze (MA); -- Add Machine_Attribute of "global", so the section is visible -- everywhere Start_String; Store_String_Chars ("global"); Str := End_String; MA := Make_Pragma (Sloc (N), Name_Machine_Attribute, New_List (Make_Pragma_Argument_Association (Sloc => Sloc (R_Internal), Expression => R_Internal), Make_Pragma_Argument_Association (Sloc => Sloc (R_External), Expression => Make_String_Literal (Sloc => Sloc (R_External), Strval => Str)))); Analyze (MA); -- Add Machine_Attribute of "initialize", so the section is -- demand zeroed. Start_String; Store_String_Chars ("initialize"); Str := End_String; MA := Make_Pragma (Sloc (N), Name_Machine_Attribute, New_List (Make_Pragma_Argument_Association (Sloc => Sloc (R_Internal), Expression => R_Internal), Make_Pragma_Argument_Association (Sloc => Sloc (R_External), Expression => Make_String_Literal (Sloc => Sloc (R_External), Strval => Str)))); Analyze (MA); end Psect_Object; ---------- -- Pure -- ---------- -- pragma Pure [(library_unit_NAME)]; when Pragma_Pure => Pure : declare Ent : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Ent := Find_Lib_Unit_Name; Set_Is_Pure (Ent); Set_Suppress_Elaboration_Warnings (Ent); end Pure; ------------------- -- Pure_Function -- ------------------- -- pragma Pure_Function ([Entity =>] function_LOCAL_NAME); when Pragma_Pure_Function => Pure_Function : declare E_Id : Node_Id; E : Entity_Id; Def_Id : Entity_Id; Effective : Boolean := False; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Error_Posted (E_Id) then return; end if; -- Loop through homonyms (overloadings) of referenced entity E := Entity (E_Id); if Present (E) then loop Def_Id := Get_Base_Subprogram (E); if Ekind (Def_Id) /= E_Function and then Ekind (Def_Id) /= E_Generic_Function and then Ekind (Def_Id) /= E_Operator then Error_Pragma_Arg ("pragma% requires a function name", Arg1); end if; Set_Is_Pure (Def_Id); if not Has_Pragma_Pure_Function (Def_Id) then Set_Has_Pragma_Pure_Function (Def_Id); Effective := True; end if; E := Homonym (E); exit when No (E) or else Scope (E) /= Current_Scope; end loop; if not Effective and then Warn_On_Redundant_Constructs then Error_Msg_NE ("pragma Pure_Function on& is redundant?", N, Entity (E_Id)); end if; end if; end Pure_Function; -------------------- -- Queuing_Policy -- -------------------- -- pragma Queuing_Policy (policy_IDENTIFIER); when Pragma_Queuing_Policy => declare QP : Character; begin Check_Ada_83_Warning; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Queuing_Policy (Arg1); Check_Valid_Configuration_Pragma; Get_Name_String (Chars (Expression (Arg1))); QP := Fold_Upper (Name_Buffer (1)); if Queuing_Policy /= ' ' and then Queuing_Policy /= QP then Error_Msg_Sloc := Queuing_Policy_Sloc; Error_Pragma ("queuing policy incompatible with policy#"); -- Set new policy, but always preserve System_Location since -- we like the error message with the run time name. else Queuing_Policy := QP; if Queuing_Policy_Sloc /= System_Location then Queuing_Policy_Sloc := Loc; end if; end if; end; --------------------------- -- Remote_Call_Interface -- --------------------------- -- pragma Remote_Call_Interface [(library_unit_NAME)]; when Pragma_Remote_Call_Interface => Remote_Call_Interface : declare Cunit_Node : Node_Id; Cunit_Ent : Entity_Id; K : Node_Kind; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Cunit_Node := Cunit (Current_Sem_Unit); K := Nkind (Unit (Cunit_Node)); Cunit_Ent := Cunit_Entity (Current_Sem_Unit); if K = N_Package_Declaration or else K = N_Generic_Package_Declaration or else K = N_Subprogram_Declaration or else K = N_Generic_Subprogram_Declaration or else (K = N_Subprogram_Body and then Acts_As_Spec (Unit (Cunit_Node))) then null; else Error_Pragma ( "pragma% must apply to package or subprogram declaration"); end if; Set_Is_Remote_Call_Interface (Cunit_Ent); end Remote_Call_Interface; ------------------ -- Remote_Types -- ------------------ -- pragma Remote_Types [(library_unit_NAME)]; when Pragma_Remote_Types => Remote_Types : declare Cunit_Node : Node_Id; Cunit_Ent : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Cunit_Node := Cunit (Current_Sem_Unit); Cunit_Ent := Cunit_Entity (Current_Sem_Unit); if Nkind (Unit (Cunit_Node)) /= N_Package_Declaration and then Nkind (Unit (Cunit_Node)) /= N_Generic_Package_Declaration then Error_Pragma ( "pragma% can only apply to a package declaration"); end if; Set_Is_Remote_Types (Cunit_Ent); end Remote_Types; --------------- -- Ravenscar -- --------------- -- pragma Ravenscar; when Pragma_Ravenscar => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Set_Ravenscar (N); ------------------------- -- Restricted_Run_Time -- ------------------------- -- pragma Restricted_Run_Time; when Pragma_Restricted_Run_Time => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Set_Restricted_Profile (N); ------------------ -- Restrictions -- ------------------ -- pragma Restrictions (RESTRICTION {, RESTRICTION}); -- RESTRICTION ::= -- restriction_IDENTIFIER -- | restriction_parameter_IDENTIFIER => EXPRESSION when Pragma_Restrictions => Process_Restrictions_Or_Restriction_Warnings; -------------------------- -- Restriction_Warnings -- -------------------------- -- pragma Restriction_Warnings (RESTRICTION {, RESTRICTION}); -- RESTRICTION ::= -- restriction_IDENTIFIER -- | restriction_parameter_IDENTIFIER => EXPRESSION when Pragma_Restriction_Warnings => Process_Restrictions_Or_Restriction_Warnings; ---------------- -- Reviewable -- ---------------- -- pragma Reviewable; when Pragma_Reviewable => Check_Ada_83_Warning; Check_Arg_Count (0); ------------------- -- Share_Generic -- ------------------- -- pragma Share_Generic (NAME {, NAME}); when Pragma_Share_Generic => GNAT_Pragma; Process_Generic_List; ------------ -- Shared -- ------------ -- pragma Shared (LOCAL_NAME); when Pragma_Shared => GNAT_Pragma; Process_Atomic_Shared_Volatile; -------------------- -- Shared_Passive -- -------------------- -- pragma Shared_Passive [(library_unit_NAME)]; -- Set the flag Is_Shared_Passive of program unit name entity when Pragma_Shared_Passive => Shared_Passive : declare Cunit_Node : Node_Id; Cunit_Ent : Entity_Id; begin Check_Ada_83_Warning; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; Cunit_Node := Cunit (Current_Sem_Unit); Cunit_Ent := Cunit_Entity (Current_Sem_Unit); if Nkind (Unit (Cunit_Node)) /= N_Package_Declaration and then Nkind (Unit (Cunit_Node)) /= N_Generic_Package_Declaration then Error_Pragma ( "pragma% can only apply to a package declaration"); end if; Set_Is_Shared_Passive (Cunit_Ent); end Shared_Passive; ---------------------- -- Source_File_Name -- ---------------------- -- pragma Source_File_Name ( -- [UNIT_NAME =>] unit_NAME, -- [BODY_FILE_NAME | SPEC_FILE_NAME] => STRING_LITERAL); -- No processing here. Processing was completed during parsing, -- since we need to have file names set as early as possible. -- Units are loaded well before semantic processing starts. -- The only processing we defer to this point is the check -- for correct placement. when Pragma_Source_File_Name => GNAT_Pragma; Check_Valid_Configuration_Pragma; ------------------------------ -- Source_File_Name_Project -- ------------------------------ -- pragma Source_File_Name_Project ( -- [UNIT_NAME =>] unit_NAME, -- [BODY_FILE_NAME | SPEC_FILE_NAME] => STRING_LITERAL); -- No processing here. Processing was completed during parsing, -- since we need to have file names set as early as possible. -- Units are loaded well before semantic processing starts. -- The only processing we defer to this point is the check -- for correct placement. when Pragma_Source_File_Name_Project => GNAT_Pragma; Check_Valid_Configuration_Pragma; -- Check that a pragma Source_File_Name_Project is used only -- in a configuration pragmas file. -- Pragmas Source_File_Name_Project should only be generated -- by the Project Manager in configuration pragmas files. -- This is really an ugly test. It seems to depend on some -- accidental and undocumented property. At the very least -- it needs to be documented, but it would be better to have -- a clean way of testing if we are in a configuration file??? if Present (Parent (N)) then Error_Pragma ("pragma% can only appear in a configuration pragmas file"); end if; ---------------------- -- Source_Reference -- ---------------------- -- pragma Source_Reference (INTEGER_LITERAL [, STRING_LITERAL]); -- Nothing to do, all processing completed in Par.Prag, since we -- need the information for possible parser messages that are output when Pragma_Source_Reference => GNAT_Pragma; ------------------ -- Storage_Size -- ------------------ -- pragma Storage_Size (EXPRESSION); when Pragma_Storage_Size => Storage_Size : declare P : constant Node_Id := Parent (N); Arg : Node_Id; begin Check_No_Identifiers; Check_Arg_Count (1); -- The expression must be analyzed in the special manner -- described in "Handling of Default Expressions" in sem.ads. -- Set In_Default_Expression for per-object case ??? Arg := Expression (Arg1); Analyze_Per_Use_Expression (Arg, Any_Integer); if not Is_Static_Expression (Arg) then Check_Restriction (Static_Storage_Size, Arg); end if; if Nkind (P) /= N_Task_Definition then Pragma_Misplaced; return; else if Has_Storage_Size_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); else Set_Has_Storage_Size_Pragma (P, True); end if; Record_Rep_Item (Defining_Identifier (Parent (P)), N); -- ??? exp_ch9 should use this! end if; end Storage_Size; ------------------ -- Storage_Unit -- ------------------ -- pragma Storage_Unit (NUMERIC_LITERAL); -- Only permitted argument is System'Storage_Unit value when Pragma_Storage_Unit => Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Integer_Literal (Arg1); if Intval (Expression (Arg1)) /= UI_From_Int (Ttypes.System_Storage_Unit) then Error_Msg_Uint_1 := UI_From_Int (Ttypes.System_Storage_Unit); Error_Pragma_Arg ("the only allowed argument for pragma% is ^", Arg1); end if; -------------------- -- Stream_Convert -- -------------------- -- pragma Stream_Convert ( -- [Entity =>] type_LOCAL_NAME, -- [Read =>] function_NAME, -- [Write =>] function NAME); when Pragma_Stream_Convert => Stream_Convert : declare procedure Check_OK_Stream_Convert_Function (Arg : Node_Id); -- Check that the given argument is the name of a local -- function of one argument that is not overloaded earlier -- in the current local scope. A check is also made that the -- argument is a function with one parameter. -------------------------------------- -- Check_OK_Stream_Convert_Function -- -------------------------------------- procedure Check_OK_Stream_Convert_Function (Arg : Node_Id) is Ent : Entity_Id; begin Check_Arg_Is_Local_Name (Arg); Ent := Entity (Expression (Arg)); if Has_Homonym (Ent) then Error_Pragma_Arg ("argument for pragma% may not be overloaded", Arg); end if; if Ekind (Ent) /= E_Function or else No (First_Formal (Ent)) or else Present (Next_Formal (First_Formal (Ent))) then Error_Pragma_Arg ("argument for pragma% must be" & " function of one argument", Arg); end if; end Check_OK_Stream_Convert_Function; -- Start of procecessing for Stream_Convert begin GNAT_Pragma; Check_Arg_Count (3); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Read); Check_Optional_Identifier (Arg3, Name_Write); Check_Arg_Is_Local_Name (Arg1); Check_OK_Stream_Convert_Function (Arg2); Check_OK_Stream_Convert_Function (Arg3); declare Typ : constant Entity_Id := Underlying_Type (Entity (Expression (Arg1))); Read : constant Entity_Id := Entity (Expression (Arg2)); Write : constant Entity_Id := Entity (Expression (Arg3)); begin if Etype (Typ) = Any_Type or else Etype (Read) = Any_Type or else Etype (Write) = Any_Type then return; end if; Check_First_Subtype (Arg1); if Rep_Item_Too_Early (Typ, N) or else Rep_Item_Too_Late (Typ, N) then return; end if; if Underlying_Type (Etype (Read)) /= Typ then Error_Pragma_Arg ("incorrect return type for function&", Arg2); end if; if Underlying_Type (Etype (First_Formal (Write))) /= Typ then Error_Pragma_Arg ("incorrect parameter type for function&", Arg3); end if; if Underlying_Type (Etype (First_Formal (Read))) /= Underlying_Type (Etype (Write)) then Error_Pragma_Arg ("result type of & does not match Read parameter type", Arg3); end if; end; end Stream_Convert; ------------------------- -- Style_Checks (GNAT) -- ------------------------- -- pragma Style_Checks (On | Off | ALL_CHECKS | STRING_LITERAL); -- This is processed by the parser since some of the style -- checks take place during source scanning and parsing. This -- means that we don't need to issue error messages here. when Pragma_Style_Checks => Style_Checks : declare A : constant Node_Id := Expression (Arg1); S : String_Id; C : Char_Code; begin GNAT_Pragma; Check_No_Identifiers; -- Two argument form if Arg_Count = 2 then Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); declare E_Id : Node_Id; E : Entity_Id; begin E_Id := Expression (Arg2); Analyze (E_Id); if not Is_Entity_Name (E_Id) then Error_Pragma_Arg ("second argument of pragma% must be entity name", Arg2); end if; E := Entity (E_Id); if E = Any_Id then return; else loop Set_Suppress_Style_Checks (E, (Chars (Expression (Arg1)) = Name_Off)); exit when No (Homonym (E)); E := Homonym (E); end loop; end if; end; -- One argument form else Check_Arg_Count (1); if Nkind (A) = N_String_Literal then S := Strval (A); declare Slen : constant Natural := Natural (String_Length (S)); Options : String (1 .. Slen); J : Natural; begin J := 1; loop C := Get_String_Char (S, Int (J)); exit when not In_Character_Range (C); Options (J) := Get_Character (C); if J = Slen then Set_Style_Check_Options (Options); exit; else J := J + 1; end if; end loop; end; elsif Nkind (A) = N_Identifier then if Chars (A) = Name_All_Checks then Set_Default_Style_Check_Options; elsif Chars (A) = Name_On then Style_Check := True; elsif Chars (A) = Name_Off then Style_Check := False; end if; end if; end if; end Style_Checks; -------------- -- Subtitle -- -------------- -- pragma Subtitle ([Subtitle =>] STRING_LITERAL); when Pragma_Subtitle => GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Subtitle); Check_Arg_Is_String_Literal (Arg1); -------------- -- Suppress -- -------------- -- pragma Suppress (IDENTIFIER [, [On =>] NAME]); when Pragma_Suppress => Process_Suppress_Unsuppress (True); ------------------ -- Suppress_All -- ------------------ -- pragma Suppress_All; -- The only check made here is that the pragma appears in the -- proper place, i.e. following a compilation unit. If indeed -- it appears in this context, then the parser has already -- inserted an equivalent pragma Suppress (All_Checks) to get -- the required effect. when Pragma_Suppress_All => GNAT_Pragma; Check_Arg_Count (0); if Nkind (Parent (N)) /= N_Compilation_Unit_Aux or else not Is_List_Member (N) or else List_Containing (N) /= Pragmas_After (Parent (N)) then Error_Pragma ("misplaced pragma%, must follow compilation unit"); end if; ------------------------- -- Suppress_Debug_Info -- ------------------------- -- pragma Suppress_Debug_Info ([Entity =>] LOCAL_NAME); when Pragma_Suppress_Debug_Info => GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Check_Optional_Identifier (Arg1, Name_Entity); Set_Debug_Info_Off (Entity (Get_Pragma_Arg (Arg1))); ---------------------------------- -- Suppress_Exception_Locations -- ---------------------------------- -- pragma Suppress_Exception_Locations; when Pragma_Suppress_Exception_Locations => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Exception_Locations_Suppressed := True; ----------------------------- -- Suppress_Initialization -- ----------------------------- -- pragma Suppress_Initialization ([Entity =>] type_Name); when Pragma_Suppress_Initialization => Suppress_Init : declare E_Id : Node_Id; E : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Expression (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); if Is_Type (E) then if Is_Incomplete_Or_Private_Type (E) then if No (Full_View (Base_Type (E))) then Error_Pragma_Arg ("argument of pragma% cannot be an incomplete type", Arg1); else Set_Suppress_Init_Proc (Full_View (Base_Type (E))); end if; else Set_Suppress_Init_Proc (Base_Type (E)); end if; else Error_Pragma_Arg ("pragma% requires argument that is a type name", Arg1); end if; end Suppress_Init; ----------------- -- System_Name -- ----------------- -- pragma System_Name (DIRECT_NAME); -- Syntax check: one argument, which must be the identifier GNAT -- or the identifier GCC, no other identifiers are acceptable. when Pragma_System_Name => Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_One_Of (Arg1, Name_Gcc, Name_Gnat); ----------------------------- -- Task_Dispatching_Policy -- ----------------------------- -- pragma Task_Dispatching_Policy (policy_IDENTIFIER); when Pragma_Task_Dispatching_Policy => declare DP : Character; begin Check_Ada_83_Warning; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Task_Dispatching_Policy (Arg1); Check_Valid_Configuration_Pragma; Get_Name_String (Chars (Expression (Arg1))); DP := Fold_Upper (Name_Buffer (1)); if Task_Dispatching_Policy /= ' ' and then Task_Dispatching_Policy /= DP then Error_Msg_Sloc := Task_Dispatching_Policy_Sloc; Error_Pragma ("task dispatching policy incompatible with policy#"); -- Set new policy, but always preserve System_Location since -- we like the error message with the run time name. else Task_Dispatching_Policy := DP; if Task_Dispatching_Policy_Sloc /= System_Location then Task_Dispatching_Policy_Sloc := Loc; end if; end if; end; -------------- -- Task_Info -- -------------- -- pragma Task_Info (EXPRESSION); when Pragma_Task_Info => Task_Info : declare P : constant Node_Id := Parent (N); begin GNAT_Pragma; if Nkind (P) /= N_Task_Definition then Error_Pragma ("pragma% must appear in task definition"); end if; Check_No_Identifiers; Check_Arg_Count (1); Analyze_And_Resolve (Expression (Arg1), RTE (RE_Task_Info_Type)); if Etype (Expression (Arg1)) = Any_Type then return; end if; if Has_Task_Info_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); else Set_Has_Task_Info_Pragma (P, True); end if; end Task_Info; --------------- -- Task_Name -- --------------- -- pragma Task_Name (string_EXPRESSION); when Pragma_Task_Name => Task_Name : declare -- pragma Priority (EXPRESSION); P : constant Node_Id := Parent (N); Arg : Node_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Arg := Expression (Arg1); Analyze_And_Resolve (Arg, Standard_String); if Nkind (P) /= N_Task_Definition then Pragma_Misplaced; end if; if Has_Task_Name_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); else Set_Has_Task_Name_Pragma (P, True); Record_Rep_Item (Defining_Identifier (Parent (P)), N); end if; end Task_Name; ------------------ -- Task_Storage -- ------------------ -- pragma Task_Storage ( -- [Task_Type =>] LOCAL_NAME, -- [Top_Guard =>] static_integer_EXPRESSION); when Pragma_Task_Storage => Task_Storage : declare Args : Args_List (1 .. 2); Names : constant Name_List (1 .. 2) := ( Name_Task_Type, Name_Top_Guard); Task_Type : Node_Id renames Args (1); Top_Guard : Node_Id renames Args (2); Ent : Entity_Id; begin GNAT_Pragma; Gather_Associations (Names, Args); if No (Task_Type) then Error_Pragma ("missing task_type argument for pragma%"); end if; Check_Arg_Is_Local_Name (Task_Type); Ent := Entity (Task_Type); if not Is_Task_Type (Ent) then Error_Pragma_Arg ("argument for pragma% must be task type", Task_Type); end if; if No (Top_Guard) then Error_Pragma_Arg ("pragma% takes two arguments", Task_Type); else Check_Arg_Is_Static_Expression (Top_Guard, Any_Integer); end if; Check_First_Subtype (Task_Type); if Rep_Item_Too_Late (Ent, N) then raise Pragma_Exit; end if; end Task_Storage; ----------------- -- Thread_Body -- ----------------- -- pragma Thread_Body -- ( [Entity =>] LOCAL_NAME -- [,[Secondary_Stack_Size =>] static_integer_EXPRESSION]); when Pragma_Thread_Body => Thread_Body : declare Id : Node_Id; SS : Node_Id; E : Entity_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Id := Expression (Arg1); if not Is_Entity_Name (Id) or else not Is_Subprogram (Entity (Id)) then Error_Pragma_Arg ("subprogram name required", Arg1); end if; E := Entity (Id); -- Go to renamed subprogram if present, since Thread_Body applies -- to the actual renamed entity, not to the renaming entity. if Present (Alias (E)) and then Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Renaming_Declaration then E := Alias (E); end if; -- Various error checks if Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Body then Error_Pragma ("pragma% requires separate spec and must come before body"); elsif Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N) then raise Pragma_Exit; elsif Is_Thread_Body (E) then Error_Pragma_Arg ("only one thread body pragma allowed", Arg1); elsif Present (Homonym (E)) and then Scope (Homonym (E)) = Current_Scope then Error_Pragma_Arg ("thread body subprogram must not be overloaded", Arg1); end if; Set_Is_Thread_Body (E); -- Deal with secondary stack argument if Arg_Count = 2 then Check_Optional_Identifier (Arg2, Name_Secondary_Stack_Size); SS := Expression (Arg2); Analyze_And_Resolve (SS, Any_Integer); end if; end Thread_Body; ---------------- -- Time_Slice -- ---------------- -- pragma Time_Slice (static_duration_EXPRESSION); when Pragma_Time_Slice => Time_Slice : declare Val : Ureal; Nod : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_In_Main_Program; Check_Arg_Is_Static_Expression (Arg1, Standard_Duration); if not Error_Posted (Arg1) then Nod := Next (N); while Present (Nod) loop if Nkind (Nod) = N_Pragma and then Chars (Nod) = Name_Time_Slice then Error_Msg_Name_1 := Chars (N); Error_Msg_N ("duplicate pragma% not permitted", Nod); end if; Next (Nod); end loop; end if; -- Process only if in main unit if Get_Source_Unit (Loc) = Main_Unit then Opt.Time_Slice_Set := True; Val := Expr_Value_R (Expression (Arg1)); if Val <= Ureal_0 then Opt.Time_Slice_Value := 0; elsif Val > UR_From_Uint (UI_From_Int (1000)) then Opt.Time_Slice_Value := 1_000_000_000; else Opt.Time_Slice_Value := UI_To_Int (UR_To_Uint (Val * UI_From_Int (1_000_000))); end if; end if; end Time_Slice; ----------- -- Title -- ----------- -- pragma Title (TITLING_OPTION [, TITLING OPTION]); -- TITLING_OPTION ::= -- [Title =>] STRING_LITERAL -- | [Subtitle =>] STRING_LITERAL when Pragma_Title => Title : declare Args : Args_List (1 .. 2); Names : constant Name_List (1 .. 2) := ( Name_Title, Name_Subtitle); begin GNAT_Pragma; Gather_Associations (Names, Args); for J in 1 .. 2 loop if Present (Args (J)) then Check_Arg_Is_String_Literal (Args (J)); end if; end loop; end Title; --------------------- -- Unchecked_Union -- --------------------- -- pragma Unchecked_Union (first_subtype_LOCAL_NAME) when Pragma_Unchecked_Union => Unchecked_Union : declare Assoc : constant Node_Id := Arg1; Type_Id : constant Node_Id := Expression (Assoc); Typ : Entity_Id; Discr : Entity_Id; Tdef : Node_Id; Clist : Node_Id; Vpart : Node_Id; Comp : Node_Id; Variant : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type or else Rep_Item_Too_Early (Typ, N) then return; else Typ := Underlying_Type (Typ); end if; if Rep_Item_Too_Late (Typ, N) then return; end if; Check_First_Subtype (Arg1); -- Note remaining cases are references to a type in the current -- declarative part. If we find an error, we post the error on -- the relevant type declaration at an appropriate point. if not Is_Record_Type (Typ) then Error_Msg_N ("Unchecked_Union must be record type", Typ); return; elsif Is_Tagged_Type (Typ) then Error_Msg_N ("Unchecked_Union must not be tagged", Typ); return; elsif Is_Limited_Type (Typ) then Error_Msg_N ("Unchecked_Union must not be limited record type", Typ); Explain_Limited_Type (Typ, Typ); return; else if not Has_Discriminants (Typ) then Error_Msg_N ("Unchecked_Union must have one discriminant", Typ); return; end if; Discr := First_Discriminant (Typ); if Present (Next_Discriminant (Discr)) then Error_Msg_N ("Unchecked_Union must have exactly one discriminant", Next_Discriminant (Discr)); return; end if; if No (Discriminant_Default_Value (Discr)) then Error_Msg_N ("Unchecked_Union discriminant must have default value", Discr); end if; Tdef := Type_Definition (Declaration_Node (Typ)); Clist := Component_List (Tdef); if No (Clist) or else No (Variant_Part (Clist)) then Error_Msg_N ("Unchecked_Union must have variant part", Tdef); return; end if; Vpart := Variant_Part (Clist); if Is_Non_Empty_List (Component_Items (Clist)) then Error_Msg_N ("components before variant not allowed " & "in Unchecked_Union", First (Component_Items (Clist))); end if; Variant := First (Variants (Vpart)); while Present (Variant) loop Clist := Component_List (Variant); if Present (Variant_Part (Clist)) then Error_Msg_N ("Unchecked_Union may not have nested variants", Variant_Part (Clist)); end if; if not Is_Non_Empty_List (Component_Items (Clist)) then Error_Msg_N ("Unchecked_Union may not have empty component list", Variant); return; end if; Comp := First (Component_Items (Clist)); if Nkind (Comp) = N_Component_Declaration then if Present (Expression (Comp)) then Error_Msg_N ("default initialization not allowed " & "in Unchecked_Union", Expression (Comp)); end if; declare Sindic : constant Node_Id := Subtype_Indication (Component_Definition (Comp)); begin if Nkind (Sindic) = N_Subtype_Indication then Check_Static_Constraint (Constraint (Sindic)); end if; end; end if; if Present (Next (Comp)) then Error_Msg_N ("Unchecked_Union variant can have only one component", Next (Comp)); end if; Next (Variant); end loop; end if; Set_Is_Unchecked_Union (Typ, True); Set_Convention (Typ, Convention_C); Set_Has_Unchecked_Union (Base_Type (Typ), True); Set_Is_Unchecked_Union (Base_Type (Typ), True); end Unchecked_Union; ------------------------ -- Unimplemented_Unit -- ------------------------ -- pragma Unimplemented_Unit; -- Note: this only gives an error if we are generating code, -- or if we are in a generic library unit (where the pragma -- appears in the body, not in the spec). when Pragma_Unimplemented_Unit => Unimplemented_Unit : declare Cunitent : constant Entity_Id := Cunit_Entity (Get_Source_Unit (Loc)); Ent_Kind : constant Entity_Kind := Ekind (Cunitent); begin GNAT_Pragma; Check_Arg_Count (0); if Operating_Mode = Generate_Code or else Ent_Kind = E_Generic_Function or else Ent_Kind = E_Generic_Procedure or else Ent_Kind = E_Generic_Package then Get_Name_String (Chars (Cunitent)); Set_Casing (Mixed_Case); Write_Str (Name_Buffer (1 .. Name_Len)); Write_Str (" is not implemented"); Write_Eol; raise Unrecoverable_Error; end if; end Unimplemented_Unit; -------------------- -- Universal_Data -- -------------------- -- pragma Universal_Data [(library_unit_NAME)]; when Pragma_Universal_Data => GNAT_Pragma; -- If this is a configuration pragma, then set the universal -- addressing option, otherwise confirm that the pragma -- satisfies the requirements of library unit pragma placement -- and leave it to the GNAAMP back end to detect the pragma -- (avoids transitive setting of the option due to withed units). if Is_Configuration_Pragma then Universal_Addressing_On_AAMP := True; else Check_Valid_Library_Unit_Pragma; end if; if not AAMP_On_Target then Error_Pragma ("?pragma% ignored (applies only to AAMP)"); end if; ------------------ -- Unreferenced -- ------------------ -- pragma Unreferenced (local_Name {, local_Name}); when Pragma_Unreferenced => Unreferenced : declare Arg_Node : Node_Id; Arg_Expr : Node_Id; Arg_Ent : Entity_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Arg_Node := Arg1; while Present (Arg_Node) loop Check_No_Identifier (Arg_Node); -- Note that the analyze call done by Check_Arg_Is_Local_Name -- will in fact generate a reference, so that the entity will -- have a reference, which will inhibit any warnings about it -- not being referenced, and also properly show up in the ali -- file as a reference. But this reference is recorded before -- the Has_Pragma_Unreferenced flag is set, so that no warning -- is generated for this reference. Check_Arg_Is_Local_Name (Arg_Node); Arg_Expr := Get_Pragma_Arg (Arg_Node); if Is_Entity_Name (Arg_Expr) then Arg_Ent := Entity (Arg_Expr); -- If the entity is overloaded, the pragma applies to the -- most recent overloading, as documented. In this case, -- name resolution does not generate a reference, so it -- must be done here explicitly. if Is_Overloaded (Arg_Expr) then Generate_Reference (Arg_Ent, N); end if; Set_Has_Pragma_Unreferenced (Arg_Ent); end if; Next (Arg_Node); end loop; end Unreferenced; ------------------------------ -- Unreserve_All_Interrupts -- ------------------------------ -- pragma Unreserve_All_Interrupts; when Pragma_Unreserve_All_Interrupts => GNAT_Pragma; Check_Arg_Count (0); if In_Extended_Main_Code_Unit (Main_Unit_Entity) then Unreserve_All_Interrupts := True; end if; ---------------- -- Unsuppress -- ---------------- -- pragma Unsuppress (IDENTIFIER [, [On =>] NAME]); when Pragma_Unsuppress => GNAT_Pragma; Process_Suppress_Unsuppress (False); ------------------- -- Use_VADS_Size -- ------------------- -- pragma Use_VADS_Size; when Pragma_Use_VADS_Size => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Use_VADS_Size := True; --------------------- -- Validity_Checks -- --------------------- -- pragma Validity_Checks (On | Off | ALL_CHECKS | STRING_LITERAL); when Pragma_Validity_Checks => Validity_Checks : declare A : constant Node_Id := Expression (Arg1); S : String_Id; C : Char_Code; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; if Nkind (A) = N_String_Literal then S := Strval (A); declare Slen : constant Natural := Natural (String_Length (S)); Options : String (1 .. Slen); J : Natural; begin J := 1; loop C := Get_String_Char (S, Int (J)); exit when not In_Character_Range (C); Options (J) := Get_Character (C); if J = Slen then Set_Validity_Check_Options (Options); exit; else J := J + 1; end if; end loop; end; elsif Nkind (A) = N_Identifier then if Chars (A) = Name_All_Checks then Set_Validity_Check_Options ("a"); elsif Chars (A) = Name_On then Validity_Checks_On := True; elsif Chars (A) = Name_Off then Validity_Checks_On := False; end if; end if; end Validity_Checks; -------------- -- Volatile -- -------------- -- pragma Volatile (LOCAL_NAME); when Pragma_Volatile => Process_Atomic_Shared_Volatile; ------------------------- -- Volatile_Components -- ------------------------- -- pragma Volatile_Components (array_LOCAL_NAME); -- Volatile is handled by the same circuit as Atomic_Components -------------- -- Warnings -- -------------- -- pragma Warnings (On | Off, [LOCAL_NAME]) when Pragma_Warnings => Warnings : begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); Check_No_Identifiers; -- One argument case was processed by parser in Par.Prag if Arg_Count /= 1 then Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); Check_Arg_Count (2); declare E_Id : Node_Id; E : Entity_Id; begin E_Id := Expression (Arg2); Analyze (E_Id); -- In the expansion of an inlined body, a reference to -- the formal may be wrapped in a conversion if the actual -- is a conversion. Retrieve the real entity name. if (In_Instance_Body or else In_Inlined_Body) and then Nkind (E_Id) = N_Unchecked_Type_Conversion then E_Id := Expression (E_Id); end if; if not Is_Entity_Name (E_Id) then Error_Pragma_Arg ("second argument of pragma% must be entity name", Arg2); end if; E := Entity (E_Id); if E = Any_Id then return; else loop Set_Warnings_Off (E, (Chars (Expression (Arg1)) = Name_Off)); if Is_Enumeration_Type (E) then declare Lit : Entity_Id := First_Literal (E); begin while Present (Lit) loop Set_Warnings_Off (Lit); Next_Literal (Lit); end loop; end; end if; exit when No (Homonym (E)); E := Homonym (E); end loop; end if; end; end if; end Warnings; ------------------- -- Weak_External -- ------------------- -- pragma Weak_External ([Entity =>] LOCAL_NAME); when Pragma_Weak_External => Weak_External : declare Ent : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Library_Level_Local_Name (Arg1); Ent := Entity (Expression (Arg1)); if Rep_Item_Too_Early (Ent, N) then return; else Ent := Underlying_Type (Ent); end if; -- The only processing required is to link this item on to the -- list of rep items for the given entity. This is accomplished -- by the call to Rep_Item_Too_Late (when no error is detected -- and False is returned). if Rep_Item_Too_Late (Ent, N) then return; else Set_Has_Gigi_Rep_Item (Ent); end if; end Weak_External; -------------------- -- Unknown_Pragma -- -------------------- -- Should be impossible, since the case of an unknown pragma is -- separately processed before the case statement is entered. when Unknown_Pragma => raise Program_Error; end case; exception when Pragma_Exit => null; end Analyze_Pragma; --------------------------------- -- Delay_Config_Pragma_Analyze -- --------------------------------- function Delay_Config_Pragma_Analyze (N : Node_Id) return Boolean is begin return Chars (N) = Name_Interrupt_State; end Delay_Config_Pragma_Analyze; ------------------------- -- Get_Base_Subprogram -- ------------------------- function Get_Base_Subprogram (Def_Id : Entity_Id) return Entity_Id is Result : Entity_Id; begin Result := Def_Id; -- Follow subprogram renaming chain while Is_Subprogram (Result) and then (Is_Generic_Instance (Result) or else Nkind (Parent (Declaration_Node (Result))) = N_Subprogram_Renaming_Declaration) and then Present (Alias (Result)) loop Result := Alias (Result); end loop; return Result; end Get_Base_Subprogram; ----------------------------------------- -- Is_Non_Significant_Pragma_Reference -- ----------------------------------------- -- This function makes use of the following static table which indicates -- whether a given pragma is significant. A value of -1 in this table -- indicates that the reference is significant. A value of zero indicates -- than appearence as any argument is insignificant, a positive value -- indicates that appearence in that parameter position is significant. Sig_Flags : constant array (Pragma_Id) of Int := (Pragma_AST_Entry => -1, Pragma_Abort_Defer => -1, Pragma_Ada_83 => -1, Pragma_Ada_95 => -1, Pragma_All_Calls_Remote => -1, Pragma_Annotate => -1, Pragma_Assert => -1, Pragma_Asynchronous => -1, Pragma_Atomic => 0, Pragma_Atomic_Components => 0, Pragma_Attach_Handler => -1, Pragma_CPP_Class => 0, Pragma_CPP_Constructor => 0, Pragma_CPP_Virtual => 0, Pragma_CPP_Vtable => 0, Pragma_C_Pass_By_Copy => 0, Pragma_Comment => 0, Pragma_Common_Object => -1, Pragma_Compile_Time_Warning => -1, Pragma_Complex_Representation => 0, Pragma_Component_Alignment => -1, Pragma_Controlled => 0, Pragma_Convention => 0, Pragma_Convention_Identifier => 0, Pragma_Debug => -1, Pragma_Discard_Names => 0, Pragma_Elaborate => -1, Pragma_Elaborate_All => -1, Pragma_Elaborate_Body => -1, Pragma_Elaboration_Checks => -1, Pragma_Eliminate => -1, Pragma_Explicit_Overriding => -1, Pragma_Export => -1, Pragma_Export_Exception => -1, Pragma_Export_Function => -1, Pragma_Export_Object => -1, Pragma_Export_Procedure => -1, Pragma_Export_Value => -1, Pragma_Export_Valued_Procedure => -1, Pragma_Extend_System => -1, Pragma_Extensions_Allowed => -1, Pragma_External => -1, Pragma_External_Name_Casing => -1, Pragma_Finalize_Storage_Only => 0, Pragma_Float_Representation => 0, Pragma_Ident => -1, Pragma_Import => +2, Pragma_Import_Exception => 0, Pragma_Import_Function => 0, Pragma_Import_Object => 0, Pragma_Import_Procedure => 0, Pragma_Import_Valued_Procedure => 0, Pragma_Initialize_Scalars => -1, Pragma_Inline => 0, Pragma_Inline_Always => 0, Pragma_Inline_Generic => 0, Pragma_Inspection_Point => -1, Pragma_Interface => +2, Pragma_Interface_Name => +2, Pragma_Interrupt_Handler => -1, Pragma_Interrupt_Priority => -1, Pragma_Interrupt_State => -1, Pragma_Java_Constructor => -1, Pragma_Java_Interface => -1, Pragma_Keep_Names => 0, Pragma_License => -1, Pragma_Link_With => -1, Pragma_Linker_Alias => -1, Pragma_Linker_Options => -1, Pragma_Linker_Section => -1, Pragma_List => -1, Pragma_Locking_Policy => -1, Pragma_Long_Float => -1, Pragma_Machine_Attribute => -1, Pragma_Main => -1, Pragma_Main_Storage => -1, Pragma_Memory_Size => -1, Pragma_No_Return => 0, Pragma_No_Run_Time => -1, Pragma_Normalize_Scalars => -1, Pragma_Obsolescent => 0, Pragma_Optimize => -1, Pragma_Optional_Overriding => -1, Pragma_Overriding => -1, Pragma_Pack => 0, Pragma_Page => -1, Pragma_Passive => -1, Pragma_Polling => -1, Pragma_Persistent_Data => -1, Pragma_Persistent_Object => -1, Pragma_Preelaborate => -1, Pragma_Priority => -1, Pragma_Profile => 0, Pragma_Propagate_Exceptions => -1, Pragma_Psect_Object => -1, Pragma_Pure => 0, Pragma_Pure_Function => 0, Pragma_Queuing_Policy => -1, Pragma_Ravenscar => -1, Pragma_Remote_Call_Interface => -1, Pragma_Remote_Types => -1, Pragma_Restricted_Run_Time => -1, Pragma_Restriction_Warnings => -1, Pragma_Restrictions => -1, Pragma_Reviewable => -1, Pragma_Share_Generic => -1, Pragma_Shared => -1, Pragma_Shared_Passive => -1, Pragma_Source_File_Name => -1, Pragma_Source_File_Name_Project => -1, Pragma_Source_Reference => -1, Pragma_Storage_Size => -1, Pragma_Storage_Unit => -1, Pragma_Stream_Convert => -1, Pragma_Style_Checks => -1, Pragma_Subtitle => -1, Pragma_Suppress => 0, Pragma_Suppress_Exception_Locations => 0, Pragma_Suppress_All => -1, Pragma_Suppress_Debug_Info => 0, Pragma_Suppress_Initialization => 0, Pragma_System_Name => -1, Pragma_Task_Dispatching_Policy => -1, Pragma_Task_Info => -1, Pragma_Task_Name => -1, Pragma_Task_Storage => 0, Pragma_Thread_Body => +2, Pragma_Time_Slice => -1, Pragma_Title => -1, Pragma_Unchecked_Union => -1, Pragma_Unimplemented_Unit => -1, Pragma_Universal_Data => -1, Pragma_Unreferenced => -1, Pragma_Unreserve_All_Interrupts => -1, Pragma_Unsuppress => 0, Pragma_Use_VADS_Size => -1, Pragma_Validity_Checks => -1, Pragma_Volatile => 0, Pragma_Volatile_Components => 0, Pragma_Warnings => -1, Pragma_Weak_External => 0, Unknown_Pragma => 0); function Is_Non_Significant_Pragma_Reference (N : Node_Id) return Boolean is P : Node_Id; C : Int; A : Node_Id; begin P := Parent (N); if Nkind (P) /= N_Pragma_Argument_Association then return False; else C := Sig_Flags (Get_Pragma_Id (Chars (Parent (P)))); case C is when -1 => return False; when 0 => return True; when others => A := First (Pragma_Argument_Associations (Parent (P))); for J in 1 .. C - 1 loop if No (A) then return False; end if; Next (A); end loop; return A = P; end case; end if; end Is_Non_Significant_Pragma_Reference; ------------------------------ -- Is_Pragma_String_Literal -- ------------------------------ -- This function returns true if the corresponding pragma argument is -- a static string expression. These are the only cases in which string -- literals can appear as pragma arguments. We also allow a string -- literal as the first argument to pragma Assert (although it will -- of course always generate a type error). function Is_Pragma_String_Literal (Par : Node_Id) return Boolean is Pragn : constant Node_Id := Parent (Par); Assoc : constant List_Id := Pragma_Argument_Associations (Pragn); Pname : constant Name_Id := Chars (Pragn); Argn : Natural; N : Node_Id; begin Argn := 1; N := First (Assoc); loop exit when N = Par; Argn := Argn + 1; Next (N); end loop; if Pname = Name_Assert then return True; elsif Pname = Name_Export then return Argn > 2; elsif Pname = Name_Ident then return Argn = 1; elsif Pname = Name_Import then return Argn > 2; elsif Pname = Name_Interface_Name then return Argn > 1; elsif Pname = Name_Linker_Alias then return Argn = 2; elsif Pname = Name_Linker_Section then return Argn = 2; elsif Pname = Name_Machine_Attribute then return Argn = 2; elsif Pname = Name_Source_File_Name then return True; elsif Pname = Name_Source_Reference then return Argn = 2; elsif Pname = Name_Title then return True; elsif Pname = Name_Subtitle then return True; else return False; end if; end Is_Pragma_String_Literal; -------------------------------------- -- Process_Compilation_Unit_Pragmas -- -------------------------------------- procedure Process_Compilation_Unit_Pragmas (N : Node_Id) is begin -- A special check for pragma Suppress_All. This is a strange DEC -- pragma, strange because it comes at the end of the unit. If we -- have a pragma Suppress_All in the Pragmas_After of the current -- unit, then we insert a pragma Suppress (All_Checks) at the start -- of the context clause to ensure the correct processing. declare PA : constant List_Id := Pragmas_After (Aux_Decls_Node (N)); P : Node_Id; begin if Present (PA) then P := First (PA); while Present (P) loop if Chars (P) = Name_Suppress_All then Prepend_To (Context_Items (N), Make_Pragma (Sloc (P), Chars => Name_Suppress, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Sloc (P), Expression => Make_Identifier (Sloc (P), Chars => Name_All_Checks))))); exit; end if; Next (P); end loop; end if; end; end Process_Compilation_Unit_Pragmas; -------------------------------- -- Set_Encoded_Interface_Name -- -------------------------------- procedure Set_Encoded_Interface_Name (E : Entity_Id; S : Node_Id) is Str : constant String_Id := Strval (S); Len : constant Int := String_Length (Str); CC : Char_Code; C : Character; J : Int; Hex : constant array (0 .. 15) of Character := "0123456789abcdef"; procedure Encode; -- Stores encoded value of character code CC. The encoding we -- use an underscore followed by four lower case hex digits. procedure Encode is begin Store_String_Char (Get_Char_Code ('_')); Store_String_Char (Get_Char_Code (Hex (Integer (CC / 2 ** 12)))); Store_String_Char (Get_Char_Code (Hex (Integer (CC / 2 ** 8 and 16#0F#)))); Store_String_Char (Get_Char_Code (Hex (Integer (CC / 2 ** 4 and 16#0F#)))); Store_String_Char (Get_Char_Code (Hex (Integer (CC and 16#0F#)))); end Encode; -- Start of processing for Set_Encoded_Interface_Name begin -- If first character is asterisk, this is a link name, and we -- leave it completely unmodified. We also ignore null strings -- (the latter case happens only in error cases) and no encoding -- should occur for Java interface names. if Len = 0 or else Get_String_Char (Str, 1) = Get_Char_Code ('*') or else Java_VM then Set_Interface_Name (E, S); else J := 1; loop CC := Get_String_Char (Str, J); exit when not In_Character_Range (CC); C := Get_Character (CC); exit when C /= '_' and then C /= '$' and then C not in '0' .. '9' and then C not in 'a' .. 'z' and then C not in 'A' .. 'Z'; if J = Len then Set_Interface_Name (E, S); return; else J := J + 1; end if; end loop; -- Here we need to encode. The encoding we use as follows: -- three underscores + four hex digits (lower case) Start_String; for J in 1 .. String_Length (Str) loop CC := Get_String_Char (Str, J); if not In_Character_Range (CC) then Encode; else C := Get_Character (CC); if C = '_' or else C = '$' or else C in '0' .. '9' or else C in 'a' .. 'z' or else C in 'A' .. 'Z' then Store_String_Char (CC); else Encode; end if; end if; end loop; Set_Interface_Name (E, Make_String_Literal (Sloc (S), Strval => End_String)); end if; end Set_Encoded_Interface_Name; ------------------- -- Set_Unit_Name -- ------------------- procedure Set_Unit_Name (N : Node_Id; With_Item : Node_Id) is Pref : Node_Id; Scop : Entity_Id; begin if Nkind (N) = N_Identifier and then Nkind (With_Item) = N_Identifier then Set_Entity (N, Entity (With_Item)); elsif Nkind (N) = N_Selected_Component then Change_Selected_Component_To_Expanded_Name (N); Set_Entity (N, Entity (With_Item)); Set_Entity (Selector_Name (N), Entity (N)); Pref := Prefix (N); Scop := Scope (Entity (N)); while Nkind (Pref) = N_Selected_Component loop Change_Selected_Component_To_Expanded_Name (Pref); Set_Entity (Selector_Name (Pref), Scop); Set_Entity (Pref, Scop); Pref := Prefix (Pref); Scop := Scope (Scop); end loop; Set_Entity (Pref, Scop); end if; end Set_Unit_Name; end Sem_Prag;