------------------------------------------------------------------------------ -- -- -- GNAT COMPILER COMPONENTS -- -- -- -- S E M _ P R A G -- -- -- -- B o d y -- -- -- -- Copyright (C) 1992-2018, 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 3, 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 COPYING3. If not, go to -- -- http://www.gnu.org/licenses for a complete copy of the license. -- -- -- -- 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 Aspects; use Aspects; with Atree; use Atree; with Casing; use Casing; with Checks; use Checks; with Contracts; use Contracts; with Csets; use Csets; with Debug; use Debug; with Einfo; use Einfo; with Elists; use Elists; with Errout; use Errout; with Exp_Dist; use Exp_Dist; with Exp_Util; use Exp_Util; with Freeze; use Freeze; with Ghost; use Ghost; with Gnatvsn; use Gnatvsn; with Lib; use Lib; with Lib.Writ; use Lib.Writ; with Lib.Xref; use Lib.Xref; with Namet.Sp; use Namet.Sp; with Nlists; use Nlists; with Nmake; use Nmake; with Output; use Output; with Par_SCO; use Par_SCO; with Restrict; use Restrict; with Rident; use Rident; with Rtsfind; use Rtsfind; with Sem; use Sem; with Sem_Aux; use Sem_Aux; with Sem_Ch3; use Sem_Ch3; with Sem_Ch6; use Sem_Ch6; with Sem_Ch8; use Sem_Ch8; with Sem_Ch12; use Sem_Ch12; with Sem_Ch13; use Sem_Ch13; with Sem_Disp; use Sem_Disp; with Sem_Dist; use Sem_Dist; with Sem_Elab; use Sem_Elab; 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_Warn; use Sem_Warn; with Stand; use Stand; with Sinfo; use Sinfo; with Sinfo.CN; use Sinfo.CN; with Sinput; use Sinput; with Stringt; use Stringt; with Stylesw; use Stylesw; with Table; with Targparm; use Targparm; with Tbuild; use Tbuild; with Ttypes; with Uintp; use Uintp; with Uname; use Uname; with Urealp; use Urealp; with Validsw; use Validsw; with Warnsw; use Warnsw; with System.Case_Util; 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 lower case letters. -- 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. -------------------------------------------- -- Checking for Duplicated External Names -- -------------------------------------------- -- It is suspicious if two separate Export pragmas use the same external -- name. The following table is used to diagnose this situation so that -- an appropriate warning can be issued. -- The Node_Id stored is for the N_String_Literal node created to hold -- the value of the external name. The Sloc of this node is used to -- cross-reference the location of the duplication. package Externals is new Table.Table ( Table_Component_Type => Node_Id, Table_Index_Type => Int, Table_Low_Bound => 0, Table_Initial => 100, Table_Increment => 100, Table_Name => "Name_Externals"); ------------------------------------- -- 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. procedure Analyze_Part_Of (Indic : Node_Id; Item_Id : Entity_Id; Encap : Node_Id; Encap_Id : out Entity_Id; Legal : out Boolean); -- Subsidiary to Analyze_Part_Of_In_Decl_Part, Analyze_Part_Of_Option and -- Analyze_Pragma. Perform full analysis of indicator Part_Of. Indic is the -- Part_Of indicator. Item_Id is the entity of an abstract state, object or -- package instantiation. Encap denotes the encapsulating state or single -- concurrent type. Encap_Id is the entity of Encap. Flag Legal is set when -- the indicator is legal. function Appears_In (List : Elist_Id; Item_Id : Entity_Id) return Boolean; -- Subsidiary to analysis of pragmas Depends, Global and Refined_Depends. -- Query whether a particular item appears in a mixed list of nodes and -- entities. It is assumed that all nodes in the list have entities. procedure Check_Postcondition_Use_In_Inlined_Subprogram (Prag : Node_Id; Spec_Id : Entity_Id); -- Subsidiary to the analysis of pragmas Contract_Cases, Postcondition, -- Precondition, Refined_Post, and Test_Case. Emit a warning when pragma -- Prag is associated with subprogram Spec_Id subject to Inline_Always, -- and assertions are enabled. procedure Check_State_And_Constituent_Use (States : Elist_Id; Constits : Elist_Id; Context : Node_Id); -- Subsidiary to the analysis of pragmas [Refined_]Depends, [Refined_] -- Global and Initializes. Determine whether a state from list States and a -- corresponding constituent from list Constits (if any) appear in the same -- context denoted by Context. If this is the case, emit an error. procedure Contract_Freeze_Error (Contract_Id : Entity_Id; Freeze_Id : Entity_Id); -- Subsidiary to the analysis of pragmas Contract_Cases, Part_Of, Post, and -- Pre. Emit a freezing-related error message where Freeze_Id is the entity -- of a body which caused contract freezing and Contract_Id denotes the -- entity of the affected contstruct. procedure Duplication_Error (Prag : Node_Id; Prev : Node_Id); -- Subsidiary to all Find_Related_xxx routines. Emit an error on pragma -- Prag that duplicates previous pragma Prev. function Find_Encapsulating_State (States : Elist_Id; Constit_Id : Entity_Id) return Entity_Id; -- Given the entity of a constituent Constit_Id, find the corresponding -- encapsulating state which appears in States. The routine returns Empty -- if no such state is found. function Find_Related_Context (Prag : Node_Id; Do_Checks : Boolean := False) return Node_Id; -- Subsidiary to the analysis of pragmas -- Async_Readers -- Async_Writers -- Constant_After_Elaboration -- Effective_Reads -- Effective_Writers -- Part_Of -- Find the first source declaration or statement found while traversing -- the previous node chain starting from pragma Prag. If flag Do_Checks is -- set, the routine reports duplicate pragmas. The routine returns Empty -- when reaching the start of the node chain. 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??? function Get_SPARK_Mode_Type (N : Name_Id) return SPARK_Mode_Type; -- Subsidiary to the analysis of pragma SPARK_Mode as well as subprogram -- Get_SPARK_Mode_From_Annotation. Convert a name into a corresponding -- value of type SPARK_Mode_Type. function Has_Extra_Parentheses (Clause : Node_Id) return Boolean; -- Subsidiary to the analysis of pragmas Depends and Refined_Depends. -- Determine whether dependency clause Clause is surrounded by extra -- parentheses. If this is the case, issue an error message. function Is_Unconstrained_Or_Tagged_Item (Item : Entity_Id) return Boolean; -- Subsidiary to Collect_Subprogram_Inputs_Outputs and the analysis of -- pragma Depends. Determine whether the type of dependency item Item is -- tagged, unconstrained array, unconstrained record or a record with at -- least one unconstrained component. procedure Record_Possible_Body_Reference (State_Id : Entity_Id; Ref : Node_Id); -- Subsidiary to the analysis of pragmas [Refined_]Depends and [Refined_] -- Global. Given an abstract state denoted by State_Id and a reference Ref -- to it, determine whether the reference appears in a package body that -- will eventually refine the state. If this is the case, record the -- reference for future checks (see Analyze_Refined_State_In_Decls). procedure Resolve_State (N : Node_Id); -- Handle the overloading of state names by functions. When N denotes a -- function, this routine finds the corresponding state and sets the entity -- of N to that of the state. procedure Rewrite_Assertion_Kind (N : Node_Id; From_Policy : Boolean := False); -- If N is Pre'Class, Post'Class, Invariant'Class, or Type_Invariant'Class, -- then it is rewritten as an identifier with the corresponding special -- name _Pre, _Post, _Invariant, or _Type_Invariant. Used by pragmas Check -- and Check_Policy. If the names are Precondition or Postcondition, this -- combination is deprecated in favor of Assertion_Policy and Ada2012 -- Aspect names. The parameter From_Policy indicates that the pragma -- is the old non-standard Check_Policy and not a rewritten pragma. procedure Set_Elab_Unit_Name (N : Node_Id; With_Item : Node_Id); -- Place semantic information on the argument of an Elaborate/Elaborate_All -- pragma. Entity name for unit and its parents is taken from item in -- previous with_clause that mentions the unit. Dummy : Integer := 0; pragma Volatile (Dummy); -- Dummy volatile integer used in bodies of ip/rv to prevent optimization procedure ip; pragma No_Inline (ip); -- A dummy procedure called when pragma Inspection_Point is analyzed. This -- is just to help debugging the front end. If a pragma Inspection_Point -- is added to a source program, then breaking on ip will get you to that -- point in the program. procedure rv; pragma No_Inline (rv); -- This is a dummy function called by the processing for pragma Reviewable. -- It is there for assisting front end debugging. By placing a Reviewable -- pragma in the source program, a breakpoint on rv catches this place in -- the source, allowing convenient stepping to the point of interest. ------------------------------- -- 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_Contract_Cases_In_Decl_Part -- ----------------------------------------- -- WARNING: This routine manages Ghost regions. Return statements must be -- replaced by gotos which jump to the end of the routine and restore the -- Ghost mode. procedure Analyze_Contract_Cases_In_Decl_Part (N : Node_Id; Freeze_Id : Entity_Id := Empty) is Subp_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Subp_Decl); Others_Seen : Boolean := False; -- This flag is set when an "others" choice is encountered. It is used -- to detect multiple illegal occurrences of "others". procedure Analyze_Contract_Case (CCase : Node_Id); -- Verify the legality of a single contract case --------------------------- -- Analyze_Contract_Case -- --------------------------- procedure Analyze_Contract_Case (CCase : Node_Id) is Case_Guard : Node_Id; Conseq : Node_Id; Errors : Nat; Extra_Guard : Node_Id; begin if Nkind (CCase) = N_Component_Association then Case_Guard := First (Choices (CCase)); Conseq := Expression (CCase); -- Each contract case must have exactly one case guard Extra_Guard := Next (Case_Guard); if Present (Extra_Guard) then Error_Msg_N ("contract case must have exactly one case guard", Extra_Guard); end if; -- Check placement of OTHERS if available (SPARK RM 6.1.3(1)) if Nkind (Case_Guard) = N_Others_Choice then if Others_Seen then Error_Msg_N ("only one others choice allowed in contract cases", Case_Guard); else Others_Seen := True; end if; elsif Others_Seen then Error_Msg_N ("others must be the last choice in contract cases", N); end if; -- Preanalyze the case guard and consequence if Nkind (Case_Guard) /= N_Others_Choice then Errors := Serious_Errors_Detected; Preanalyze_Assert_Expression (Case_Guard, Standard_Boolean); -- Emit a clarification message when the case guard contains -- at least one undefined reference, possibly due to contract -- freezing. if Errors /= Serious_Errors_Detected and then Present (Freeze_Id) and then Has_Undefined_Reference (Case_Guard) then Contract_Freeze_Error (Spec_Id, Freeze_Id); end if; end if; Errors := Serious_Errors_Detected; Preanalyze_Assert_Expression (Conseq, Standard_Boolean); -- Emit a clarification message when the consequence contains -- at least one undefined reference, possibly due to contract -- freezing. if Errors /= Serious_Errors_Detected and then Present (Freeze_Id) and then Has_Undefined_Reference (Conseq) then Contract_Freeze_Error (Spec_Id, Freeze_Id); end if; -- The contract case is malformed else Error_Msg_N ("wrong syntax in contract case", CCase); end if; end Analyze_Contract_Case; -- Local variables CCases : constant Node_Id := Expression (Get_Argument (N, Spec_Id)); Saved_GM : constant Ghost_Mode_Type := Ghost_Mode; Saved_IGR : constant Node_Id := Ignored_Ghost_Region; -- Save the Ghost-related attributes to restore on exit CCase : Node_Id; Restore_Scope : Boolean := False; -- Start of processing for Analyze_Contract_Cases_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Set the Ghost mode in effect from the pragma. Due to the delayed -- analysis of the pragma, the Ghost mode at point of declaration and -- point of analysis may not necessarily be the same. Use the mode in -- effect at the point of declaration. Set_Ghost_Mode (N); -- Single and multiple contract cases must appear in aggregate form. If -- this is not the case, then either the parser of the analysis of the -- pragma failed to produce an aggregate. pragma Assert (Nkind (CCases) = N_Aggregate); if Present (Component_Associations (CCases)) then -- Ensure that the formal parameters are visible when analyzing all -- clauses. This falls out of the general rule of aspects pertaining -- to subprogram declarations. if not In_Open_Scopes (Spec_Id) then Restore_Scope := True; Push_Scope (Spec_Id); if Is_Generic_Subprogram (Spec_Id) then Install_Generic_Formals (Spec_Id); else Install_Formals (Spec_Id); end if; end if; CCase := First (Component_Associations (CCases)); while Present (CCase) loop Analyze_Contract_Case (CCase); Next (CCase); end loop; if Restore_Scope then End_Scope; end if; -- Currently it is not possible to inline pre/postconditions on a -- subprogram subject to pragma Inline_Always. Check_Postcondition_Use_In_Inlined_Subprogram (N, Spec_Id); -- Otherwise the pragma is illegal else Error_Msg_N ("wrong syntax for constract cases", N); end if; Set_Is_Analyzed_Pragma (N); Restore_Ghost_Region (Saved_GM, Saved_IGR); end Analyze_Contract_Cases_In_Decl_Part; ---------------------------------- -- Analyze_Depends_In_Decl_Part -- ---------------------------------- procedure Analyze_Depends_In_Decl_Part (N : Node_Id) is Loc : constant Source_Ptr := Sloc (N); Subp_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Subp_Decl); All_Inputs_Seen : Elist_Id := No_Elist; -- A list containing the entities of all the inputs processed so far. -- The list is populated with unique entities because the same input -- may appear in multiple input lists. All_Outputs_Seen : Elist_Id := No_Elist; -- A list containing the entities of all the outputs processed so far. -- The list is populated with unique entities because output items are -- unique in a dependence relation. Constits_Seen : Elist_Id := No_Elist; -- A list containing the entities of all constituents processed so far. -- It aids in detecting illegal usage of a state and a corresponding -- constituent in pragma [Refinde_]Depends. Global_Seen : Boolean := False; -- A flag set when pragma Global has been processed Null_Output_Seen : Boolean := False; -- A flag used to track the legality of a null output Result_Seen : Boolean := False; -- A flag set when Spec_Id'Result is processed States_Seen : Elist_Id := No_Elist; -- A list containing the entities of all states processed so far. It -- helps in detecting illegal usage of a state and a corresponding -- constituent in pragma [Refined_]Depends. Subp_Inputs : Elist_Id := No_Elist; Subp_Outputs : Elist_Id := No_Elist; -- Two lists containing the full set of inputs and output of the related -- subprograms. Note that these lists contain both nodes and entities. Task_Input_Seen : Boolean := False; Task_Output_Seen : Boolean := False; -- Flags used to track the implicit dependence of a task unit on itself procedure Add_Item_To_Name_Buffer (Item_Id : Entity_Id); -- Subsidiary routine to Check_Role and Check_Usage. Add the item kind -- to the name buffer. The individual kinds are as follows: -- E_Abstract_State - "state" -- E_Constant - "constant" -- E_Generic_In_Out_Parameter - "generic parameter" -- E_Generic_In_Parameter - "generic parameter" -- E_In_Parameter - "parameter" -- E_In_Out_Parameter - "parameter" -- E_Loop_Parameter - "loop parameter" -- E_Out_Parameter - "parameter" -- E_Protected_Type - "current instance of protected type" -- E_Task_Type - "current instance of task type" -- E_Variable - "global" procedure Analyze_Dependency_Clause (Clause : Node_Id; Is_Last : Boolean); -- Verify the legality of a single dependency clause. Flag Is_Last -- denotes whether Clause is the last clause in the relation. procedure Check_Function_Return; -- Verify that Funtion'Result appears as one of the outputs -- (SPARK RM 6.1.5(10)). procedure Check_Role (Item : Node_Id; Item_Id : Entity_Id; Is_Input : Boolean; Self_Ref : Boolean); -- Ensure that an item fulfills its designated input and/or output role -- as specified by pragma Global (if any) or the enclosing context. If -- this is not the case, emit an error. Item and Item_Id denote the -- attributes of an item. Flag Is_Input should be set when item comes -- from an input list. Flag Self_Ref should be set when the item is an -- output and the dependency clause has operator "+". procedure Check_Usage (Subp_Items : Elist_Id; Used_Items : Elist_Id; Is_Input : Boolean); -- Verify that all items from Subp_Items appear in Used_Items. Emit an -- error if this is not the case. procedure Normalize_Clause (Clause : Node_Id); -- Remove a self-dependency "+" from the input list of a clause ----------------------------- -- Add_Item_To_Name_Buffer -- ----------------------------- procedure Add_Item_To_Name_Buffer (Item_Id : Entity_Id) is begin if Ekind (Item_Id) = E_Abstract_State then Add_Str_To_Name_Buffer ("state"); elsif Ekind (Item_Id) = E_Constant then Add_Str_To_Name_Buffer ("constant"); elsif Ekind_In (Item_Id, E_Generic_In_Out_Parameter, E_Generic_In_Parameter) then Add_Str_To_Name_Buffer ("generic parameter"); elsif Is_Formal (Item_Id) then Add_Str_To_Name_Buffer ("parameter"); elsif Ekind (Item_Id) = E_Loop_Parameter then Add_Str_To_Name_Buffer ("loop parameter"); elsif Ekind (Item_Id) = E_Protected_Type or else Is_Single_Protected_Object (Item_Id) then Add_Str_To_Name_Buffer ("current instance of protected type"); elsif Ekind (Item_Id) = E_Task_Type or else Is_Single_Task_Object (Item_Id) then Add_Str_To_Name_Buffer ("current instance of task type"); elsif Ekind (Item_Id) = E_Variable then Add_Str_To_Name_Buffer ("global"); -- The routine should not be called with non-SPARK items else raise Program_Error; end if; end Add_Item_To_Name_Buffer; ------------------------------- -- Analyze_Dependency_Clause -- ------------------------------- procedure Analyze_Dependency_Clause (Clause : Node_Id; Is_Last : Boolean) is procedure Analyze_Input_List (Inputs : Node_Id); -- Verify the legality of a single input list procedure Analyze_Input_Output (Item : Node_Id; Is_Input : Boolean; Self_Ref : Boolean; Top_Level : Boolean; Seen : in out Elist_Id; Null_Seen : in out Boolean; Non_Null_Seen : in out Boolean); -- Verify the legality of a single input or output item. Flag -- Is_Input should be set whenever Item is an input, False when it -- denotes an output. Flag Self_Ref should be set when the item is an -- output and the dependency clause has a "+". Flag Top_Level should -- be set whenever Item appears immediately within an input or output -- list. Seen is a collection of all abstract states, objects and -- formals processed so far. Flag Null_Seen denotes whether a null -- input or output has been encountered. Flag Non_Null_Seen denotes -- whether a non-null input or output has been encountered. ------------------------ -- Analyze_Input_List -- ------------------------ procedure Analyze_Input_List (Inputs : Node_Id) is Inputs_Seen : Elist_Id := No_Elist; -- A list containing the entities of all inputs that appear in the -- current input list. Non_Null_Input_Seen : Boolean := False; Null_Input_Seen : Boolean := False; -- Flags used to check the legality of an input list Input : Node_Id; begin -- Multiple inputs appear as an aggregate if Nkind (Inputs) = N_Aggregate then if Present (Component_Associations (Inputs)) then SPARK_Msg_N ("nested dependency relations not allowed", Inputs); elsif Present (Expressions (Inputs)) then Input := First (Expressions (Inputs)); while Present (Input) loop Analyze_Input_Output (Item => Input, Is_Input => True, Self_Ref => False, Top_Level => False, Seen => Inputs_Seen, Null_Seen => Null_Input_Seen, Non_Null_Seen => Non_Null_Input_Seen); Next (Input); end loop; -- Syntax error, always report else Error_Msg_N ("malformed input dependency list", Inputs); end if; -- Process a solitary input else Analyze_Input_Output (Item => Inputs, Is_Input => True, Self_Ref => False, Top_Level => False, Seen => Inputs_Seen, Null_Seen => Null_Input_Seen, Non_Null_Seen => Non_Null_Input_Seen); end if; -- Detect an illegal dependency clause of the form -- (null =>[+] null) if Null_Output_Seen and then Null_Input_Seen then SPARK_Msg_N ("null dependency clause cannot have a null input list", Inputs); end if; end Analyze_Input_List; -------------------------- -- Analyze_Input_Output -- -------------------------- procedure Analyze_Input_Output (Item : Node_Id; Is_Input : Boolean; Self_Ref : Boolean; Top_Level : Boolean; Seen : in out Elist_Id; Null_Seen : in out Boolean; Non_Null_Seen : in out Boolean) is procedure Current_Task_Instance_Seen; -- Set the appropriate global flag when the current instance of a -- task unit is encountered. -------------------------------- -- Current_Task_Instance_Seen -- -------------------------------- procedure Current_Task_Instance_Seen is begin if Is_Input then Task_Input_Seen := True; else Task_Output_Seen := True; end if; end Current_Task_Instance_Seen; -- Local variables Is_Output : constant Boolean := not Is_Input; Grouped : Node_Id; Item_Id : Entity_Id; -- Start of processing for Analyze_Input_Output begin -- Multiple input or output items appear as an aggregate if Nkind (Item) = N_Aggregate then if not Top_Level then SPARK_Msg_N ("nested grouping of items not allowed", Item); elsif Present (Component_Associations (Item)) then SPARK_Msg_N ("nested dependency relations not allowed", Item); -- Recursively analyze the grouped items elsif Present (Expressions (Item)) then Grouped := First (Expressions (Item)); while Present (Grouped) loop Analyze_Input_Output (Item => Grouped, Is_Input => Is_Input, Self_Ref => Self_Ref, Top_Level => False, Seen => Seen, Null_Seen => Null_Seen, Non_Null_Seen => Non_Null_Seen); Next (Grouped); end loop; -- Syntax error, always report else Error_Msg_N ("malformed dependency list", Item); end if; -- Process attribute 'Result in the context of a dependency clause elsif Is_Attribute_Result (Item) then Non_Null_Seen := True; Analyze (Item); -- Attribute 'Result is allowed to appear on the output side of -- a dependency clause (SPARK RM 6.1.5(6)). if Is_Input then SPARK_Msg_N ("function result cannot act as input", Item); elsif Null_Seen then SPARK_Msg_N ("cannot mix null and non-null dependency items", Item); else Result_Seen := True; end if; -- Detect multiple uses of null in a single dependency list or -- throughout the whole relation. Verify the placement of a null -- output list relative to the other clauses (SPARK RM 6.1.5(12)). elsif Nkind (Item) = N_Null then if Null_Seen then SPARK_Msg_N ("multiple null dependency relations not allowed", Item); elsif Non_Null_Seen then SPARK_Msg_N ("cannot mix null and non-null dependency items", Item); else Null_Seen := True; if Is_Output then if not Is_Last then SPARK_Msg_N ("null output list must be the last clause in a " & "dependency relation", Item); -- Catch a useless dependence of the form: -- null =>+ ... elsif Self_Ref then SPARK_Msg_N ("useless dependence, null depends on itself", Item); end if; end if; end if; -- Default case else Non_Null_Seen := True; if Null_Seen then SPARK_Msg_N ("cannot mix null and non-null items", Item); end if; Analyze (Item); Resolve_State (Item); -- Find the entity of the item. If this is a renaming, climb -- the renaming chain to reach the root object. Renamings of -- non-entire objects do not yield an entity (Empty). Item_Id := Entity_Of (Item); if Present (Item_Id) then -- Constants if Ekind_In (Item_Id, E_Constant, E_Loop_Parameter) or else -- Current instances of concurrent types Ekind_In (Item_Id, E_Protected_Type, E_Task_Type) or else -- Formal parameters Ekind_In (Item_Id, E_Generic_In_Out_Parameter, E_Generic_In_Parameter, E_In_Parameter, E_In_Out_Parameter, E_Out_Parameter) or else -- States, variables Ekind_In (Item_Id, E_Abstract_State, E_Variable) then -- A [generic] function is not allowed to have Output -- items in its dependency relations. Note that "null" -- and attribute 'Result are still valid items. if Ekind_In (Spec_Id, E_Function, E_Generic_Function) and then not Is_Input then SPARK_Msg_N ("output item is not applicable to function", Item); end if; -- The item denotes a concurrent type. Note that single -- protected/task types are not considered here because -- they behave as objects in the context of pragma -- [Refined_]Depends. if Ekind_In (Item_Id, E_Protected_Type, E_Task_Type) then -- This use is legal as long as the concurrent type is -- the current instance of an enclosing type. if Is_CCT_Instance (Item_Id, Spec_Id) then -- The dependence of a task unit on itself is -- implicit and may or may not be explicitly -- specified (SPARK RM 6.1.4). if Ekind (Item_Id) = E_Task_Type then Current_Task_Instance_Seen; end if; -- Otherwise this is not the current instance else SPARK_Msg_N ("invalid use of subtype mark in dependency " & "relation", Item); end if; -- The dependency of a task unit on itself is implicit -- and may or may not be explicitly specified -- (SPARK RM 6.1.4). elsif Is_Single_Task_Object (Item_Id) and then Is_CCT_Instance (Etype (Item_Id), Spec_Id) then Current_Task_Instance_Seen; end if; -- Ensure that the item fulfills its role as input and/or -- output as specified by pragma Global or the enclosing -- context. Check_Role (Item, Item_Id, Is_Input, Self_Ref); -- Detect multiple uses of the same state, variable or -- formal parameter. If this is not the case, add the -- item to the list of processed relations. if Contains (Seen, Item_Id) then SPARK_Msg_NE ("duplicate use of item &", Item, Item_Id); else Append_New_Elmt (Item_Id, Seen); end if; -- Detect illegal use of an input related to a null -- output. Such input items cannot appear in other -- input lists (SPARK RM 6.1.5(13)). if Is_Input and then Null_Output_Seen and then Contains (All_Inputs_Seen, Item_Id) then SPARK_Msg_N ("input of a null output list cannot appear in " & "multiple input lists", Item); end if; -- Add an input or a self-referential output to the list -- of all processed inputs. if Is_Input or else Self_Ref then Append_New_Elmt (Item_Id, All_Inputs_Seen); end if; -- State related checks (SPARK RM 6.1.5(3)) if Ekind (Item_Id) = E_Abstract_State then -- Package and subprogram bodies are instantiated -- individually in a separate compiler pass. Due to -- this mode of instantiation, the refinement of a -- state may no longer be visible when a subprogram -- body contract is instantiated. Since the generic -- template is legal, do not perform this check in -- the instance to circumvent this oddity. if Is_Generic_Instance (Spec_Id) then null; -- An abstract state with visible refinement cannot -- appear in pragma [Refined_]Depends as its place -- must be taken by some of its constituents -- (SPARK RM 6.1.4(7)). elsif Has_Visible_Refinement (Item_Id) then SPARK_Msg_NE ("cannot mention state & in dependence relation", Item, Item_Id); SPARK_Msg_N ("\use its constituents instead", Item); return; -- If the reference to the abstract state appears in -- an enclosing package body that will eventually -- refine the state, record the reference for future -- checks. else Record_Possible_Body_Reference (State_Id => Item_Id, Ref => Item); end if; end if; -- When the item renames an entire object, replace the -- item with a reference to the object. if Entity (Item) /= Item_Id then Rewrite (Item, New_Occurrence_Of (Item_Id, Sloc (Item))); Analyze (Item); end if; -- Add the entity of the current item to the list of -- processed items. if Ekind (Item_Id) = E_Abstract_State then Append_New_Elmt (Item_Id, States_Seen); -- The variable may eventually become a constituent of a -- single protected/task type. Record the reference now -- and verify its legality when analyzing the contract of -- the variable (SPARK RM 9.3). elsif Ekind (Item_Id) = E_Variable then Record_Possible_Part_Of_Reference (Var_Id => Item_Id, Ref => Item); end if; if Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Variable) and then Present (Encapsulating_State (Item_Id)) then Append_New_Elmt (Item_Id, Constits_Seen); end if; -- All other input/output items are illegal -- (SPARK RM 6.1.5(1)). else SPARK_Msg_N ("item must denote parameter, variable, state or " & "current instance of concurrent type", Item); end if; -- All other input/output items are illegal -- (SPARK RM 6.1.5(1)). This is a syntax error, always report. else Error_Msg_N ("item must denote parameter, variable, state or current " & "instance of concurrent type", Item); end if; end if; end Analyze_Input_Output; -- Local variables Inputs : Node_Id; Output : Node_Id; Self_Ref : Boolean; Non_Null_Output_Seen : Boolean := False; -- Flag used to check the legality of an output list -- Start of processing for Analyze_Dependency_Clause begin Inputs := Expression (Clause); Self_Ref := False; -- An input list with a self-dependency appears as operator "+" where -- the actuals inputs are the right operand. if Nkind (Inputs) = N_Op_Plus then Inputs := Right_Opnd (Inputs); Self_Ref := True; end if; -- Process the output_list of a dependency_clause Output := First (Choices (Clause)); while Present (Output) loop Analyze_Input_Output (Item => Output, Is_Input => False, Self_Ref => Self_Ref, Top_Level => True, Seen => All_Outputs_Seen, Null_Seen => Null_Output_Seen, Non_Null_Seen => Non_Null_Output_Seen); Next (Output); end loop; -- Process the input_list of a dependency_clause Analyze_Input_List (Inputs); end Analyze_Dependency_Clause; --------------------------- -- Check_Function_Return -- --------------------------- procedure Check_Function_Return is begin if Ekind_In (Spec_Id, E_Function, E_Generic_Function) and then not Result_Seen then SPARK_Msg_NE ("result of & must appear in exactly one output list", N, Spec_Id); end if; end Check_Function_Return; ---------------- -- Check_Role -- ---------------- procedure Check_Role (Item : Node_Id; Item_Id : Entity_Id; Is_Input : Boolean; Self_Ref : Boolean) is procedure Find_Role (Item_Is_Input : out Boolean; Item_Is_Output : out Boolean); -- Find the input/output role of Item_Id. Flags Item_Is_Input and -- Item_Is_Output are set depending on the role. procedure Role_Error (Item_Is_Input : Boolean; Item_Is_Output : Boolean); -- Emit an error message concerning the incorrect use of Item in -- pragma [Refined_]Depends. Flags Item_Is_Input and Item_Is_Output -- denote whether the item is an input and/or an output. --------------- -- Find_Role -- --------------- procedure Find_Role (Item_Is_Input : out Boolean; Item_Is_Output : out Boolean) is begin case Ekind (Item_Id) is -- Abstract states when E_Abstract_State => -- When pragma Global is present it determines the mode of -- the abstract state. if Global_Seen then Item_Is_Input := Appears_In (Subp_Inputs, Item_Id); Item_Is_Output := Appears_In (Subp_Outputs, Item_Id); -- Otherwise the state has a default IN OUT mode, because it -- behaves as a variable. else Item_Is_Input := True; Item_Is_Output := True; end if; -- Constants and IN parameters when E_Constant | E_Generic_In_Parameter | E_In_Parameter | E_Loop_Parameter => -- When pragma Global is present it determines the mode -- of constant objects as inputs (and such objects cannot -- appear as outputs in the Global contract). if Global_Seen then Item_Is_Input := Appears_In (Subp_Inputs, Item_Id); else Item_Is_Input := True; end if; Item_Is_Output := False; -- Variables and IN OUT parameters when E_Generic_In_Out_Parameter | E_In_Out_Parameter | E_Variable => -- When pragma Global is present it determines the mode of -- the object. if Global_Seen then -- A variable has mode IN when its type is unconstrained -- or tagged because array bounds, discriminants or tags -- can be read. Item_Is_Input := Appears_In (Subp_Inputs, Item_Id) or else Is_Unconstrained_Or_Tagged_Item (Item_Id); Item_Is_Output := Appears_In (Subp_Outputs, Item_Id); -- Otherwise the variable has a default IN OUT mode else Item_Is_Input := True; Item_Is_Output := True; end if; when E_Out_Parameter => -- An OUT parameter of the related subprogram; it cannot -- appear in Global. if Scope (Item_Id) = Spec_Id then -- The parameter has mode IN if its type is unconstrained -- or tagged because array bounds, discriminants or tags -- can be read. Item_Is_Input := Is_Unconstrained_Or_Tagged_Item (Item_Id); Item_Is_Output := True; -- An OUT parameter of an enclosing subprogram; it can -- appear in Global and behaves as a read-write variable. else -- When pragma Global is present it determines the mode -- of the object. if Global_Seen then -- A variable has mode IN when its type is -- unconstrained or tagged because array -- bounds, discriminants or tags can be read. Item_Is_Input := Appears_In (Subp_Inputs, Item_Id) or else Is_Unconstrained_Or_Tagged_Item (Item_Id); Item_Is_Output := Appears_In (Subp_Outputs, Item_Id); -- Otherwise the variable has a default IN OUT mode else Item_Is_Input := True; Item_Is_Output := True; end if; end if; -- Protected types when E_Protected_Type => if Global_Seen then -- A variable has mode IN when its type is unconstrained -- or tagged because array bounds, discriminants or tags -- can be read. Item_Is_Input := Appears_In (Subp_Inputs, Item_Id) or else Is_Unconstrained_Or_Tagged_Item (Item_Id); Item_Is_Output := Appears_In (Subp_Outputs, Item_Id); else -- A protected type acts as a formal parameter of mode IN -- when it applies to a protected function. if Ekind (Spec_Id) = E_Function then Item_Is_Input := True; Item_Is_Output := False; -- Otherwise the protected type acts as a formal of mode -- IN OUT. else Item_Is_Input := True; Item_Is_Output := True; end if; end if; -- Task types when E_Task_Type => -- When pragma Global is present it determines the mode of -- the object. if Global_Seen then Item_Is_Input := Appears_In (Subp_Inputs, Item_Id) or else Is_Unconstrained_Or_Tagged_Item (Item_Id); Item_Is_Output := Appears_In (Subp_Outputs, Item_Id); -- Otherwise task types act as IN OUT parameters else Item_Is_Input := True; Item_Is_Output := True; end if; when others => raise Program_Error; end case; end Find_Role; ---------------- -- Role_Error -- ---------------- procedure Role_Error (Item_Is_Input : Boolean; Item_Is_Output : Boolean) is Error_Msg : Name_Id; begin Name_Len := 0; -- When the item is not part of the input and the output set of -- the related subprogram, then it appears as extra in pragma -- [Refined_]Depends. if not Item_Is_Input and then not Item_Is_Output then Add_Item_To_Name_Buffer (Item_Id); Add_Str_To_Name_Buffer (" & cannot appear in dependence relation"); Error_Msg := Name_Find; SPARK_Msg_NE (Get_Name_String (Error_Msg), Item, Item_Id); Error_Msg_Name_1 := Chars (Spec_Id); SPARK_Msg_NE (Fix_Msg (Spec_Id, "\& is not part of the input or output " & "set of subprogram %"), Item, Item_Id); -- The mode of the item and its role in pragma [Refined_]Depends -- are in conflict. Construct a detailed message explaining the -- illegality (SPARK RM 6.1.5(5-6)). else if Item_Is_Input then Add_Str_To_Name_Buffer ("read-only"); else Add_Str_To_Name_Buffer ("write-only"); end if; Add_Char_To_Name_Buffer (' '); Add_Item_To_Name_Buffer (Item_Id); Add_Str_To_Name_Buffer (" & cannot appear as "); if Item_Is_Input then Add_Str_To_Name_Buffer ("output"); else Add_Str_To_Name_Buffer ("input"); end if; Add_Str_To_Name_Buffer (" in dependence relation"); Error_Msg := Name_Find; SPARK_Msg_NE (Get_Name_String (Error_Msg), Item, Item_Id); end if; end Role_Error; -- Local variables Item_Is_Input : Boolean; Item_Is_Output : Boolean; -- Start of processing for Check_Role begin Find_Role (Item_Is_Input, Item_Is_Output); -- Input item if Is_Input then if not Item_Is_Input then Role_Error (Item_Is_Input, Item_Is_Output); end if; -- Self-referential item elsif Self_Ref then if not Item_Is_Input or else not Item_Is_Output then Role_Error (Item_Is_Input, Item_Is_Output); end if; -- Output item elsif not Item_Is_Output then Role_Error (Item_Is_Input, Item_Is_Output); end if; end Check_Role; ----------------- -- Check_Usage -- ----------------- procedure Check_Usage (Subp_Items : Elist_Id; Used_Items : Elist_Id; Is_Input : Boolean) is procedure Usage_Error (Item_Id : Entity_Id); -- Emit an error concerning the illegal usage of an item ----------------- -- Usage_Error -- ----------------- procedure Usage_Error (Item_Id : Entity_Id) is Error_Msg : Name_Id; begin -- Input case if Is_Input then -- Unconstrained and tagged items are not part of the explicit -- input set of the related subprogram, they do not have to be -- present in a dependence relation and should not be flagged -- (SPARK RM 6.1.5(5)). if not Is_Unconstrained_Or_Tagged_Item (Item_Id) then Name_Len := 0; Add_Item_To_Name_Buffer (Item_Id); Add_Str_To_Name_Buffer (" & is missing from input dependence list"); Error_Msg := Name_Find; SPARK_Msg_NE (Get_Name_String (Error_Msg), N, Item_Id); SPARK_Msg_NE ("\add `null ='> &` dependency to ignore this input", N, Item_Id); end if; -- Output case (SPARK RM 6.1.5(10)) else Name_Len := 0; Add_Item_To_Name_Buffer (Item_Id); Add_Str_To_Name_Buffer (" & is missing from output dependence list"); Error_Msg := Name_Find; SPARK_Msg_NE (Get_Name_String (Error_Msg), N, Item_Id); end if; end Usage_Error; -- Local variables Elmt : Elmt_Id; Item : Node_Id; Item_Id : Entity_Id; -- Start of processing for Check_Usage begin if No (Subp_Items) then return; end if; -- Each input or output of the subprogram must appear in a dependency -- relation. Elmt := First_Elmt (Subp_Items); while Present (Elmt) loop Item := Node (Elmt); if Nkind (Item) = N_Defining_Identifier then Item_Id := Item; else Item_Id := Entity_Of (Item); end if; -- The item does not appear in a dependency if Present (Item_Id) and then not Contains (Used_Items, Item_Id) then if Is_Formal (Item_Id) then Usage_Error (Item_Id); -- The current instance of a protected type behaves as a formal -- parameter (SPARK RM 6.1.4). elsif Ekind (Item_Id) = E_Protected_Type or else Is_Single_Protected_Object (Item_Id) then Usage_Error (Item_Id); -- The current instance of a task type behaves as a formal -- parameter (SPARK RM 6.1.4). elsif Ekind (Item_Id) = E_Task_Type or else Is_Single_Task_Object (Item_Id) then -- The dependence of a task unit on itself is implicit and -- may or may not be explicitly specified (SPARK RM 6.1.4). -- Emit an error if only one input/output is present. if Task_Input_Seen /= Task_Output_Seen then Usage_Error (Item_Id); end if; -- States and global objects are not used properly only when -- the subprogram is subject to pragma Global. elsif Global_Seen then Usage_Error (Item_Id); end if; end if; Next_Elmt (Elmt); end loop; end Check_Usage; ---------------------- -- Normalize_Clause -- ---------------------- procedure Normalize_Clause (Clause : Node_Id) is procedure Create_Or_Modify_Clause (Output : Node_Id; Outputs : Node_Id; Inputs : Node_Id; After : Node_Id; In_Place : Boolean; Multiple : Boolean); -- Create a brand new clause to represent the self-reference or -- modify the input and/or output lists of an existing clause. Output -- denotes a self-referencial output. Outputs is the output list of a -- clause. Inputs is the input list of a clause. After denotes the -- clause after which the new clause is to be inserted. Flag In_Place -- should be set when normalizing the last output of an output list. -- Flag Multiple should be set when Output comes from a list with -- multiple items. ----------------------------- -- Create_Or_Modify_Clause -- ----------------------------- procedure Create_Or_Modify_Clause (Output : Node_Id; Outputs : Node_Id; Inputs : Node_Id; After : Node_Id; In_Place : Boolean; Multiple : Boolean) is procedure Propagate_Output (Output : Node_Id; Inputs : Node_Id); -- Handle the various cases of output propagation to the input -- list. Output denotes a self-referencial output item. Inputs -- is the input list of a clause. ---------------------- -- Propagate_Output -- ---------------------- procedure Propagate_Output (Output : Node_Id; Inputs : Node_Id) is function In_Input_List (Item : Entity_Id; Inputs : List_Id) return Boolean; -- Determine whether a particulat item appears in the input -- list of a clause. ------------------- -- In_Input_List -- ------------------- function In_Input_List (Item : Entity_Id; Inputs : List_Id) return Boolean is Elmt : Node_Id; begin Elmt := First (Inputs); while Present (Elmt) loop if Entity_Of (Elmt) = Item then return True; end if; Next (Elmt); end loop; return False; end In_Input_List; -- Local variables Output_Id : constant Entity_Id := Entity_Of (Output); Grouped : List_Id; -- Start of processing for Propagate_Output begin -- The clause is of the form: -- (Output =>+ null) -- Remove null input and replace it with a copy of the output: -- (Output => Output) if Nkind (Inputs) = N_Null then Rewrite (Inputs, New_Copy_Tree (Output)); -- The clause is of the form: -- (Output =>+ (Input1, ..., InputN)) -- Determine whether the output is not already mentioned in the -- input list and if not, add it to the list of inputs: -- (Output => (Output, Input1, ..., InputN)) elsif Nkind (Inputs) = N_Aggregate then Grouped := Expressions (Inputs); if not In_Input_List (Item => Output_Id, Inputs => Grouped) then Prepend_To (Grouped, New_Copy_Tree (Output)); end if; -- The clause is of the form: -- (Output =>+ Input) -- If the input does not mention the output, group the two -- together: -- (Output => (Output, Input)) elsif Entity_Of (Inputs) /= Output_Id then Rewrite (Inputs, Make_Aggregate (Loc, Expressions => New_List ( New_Copy_Tree (Output), New_Copy_Tree (Inputs)))); end if; end Propagate_Output; -- Local variables Loc : constant Source_Ptr := Sloc (Clause); New_Clause : Node_Id; -- Start of processing for Create_Or_Modify_Clause begin -- A null output depending on itself does not require any -- normalization. if Nkind (Output) = N_Null then return; -- A function result cannot depend on itself because it cannot -- appear in the input list of a relation (SPARK RM 6.1.5(10)). elsif Is_Attribute_Result (Output) then SPARK_Msg_N ("function result cannot depend on itself", Output); return; end if; -- When performing the transformation in place, simply add the -- output to the list of inputs (if not already there). This -- case arises when dealing with the last output of an output -- list. Perform the normalization in place to avoid generating -- a malformed tree. if In_Place then Propagate_Output (Output, Inputs); -- A list with multiple outputs is slowly trimmed until only -- one element remains. When this happens, replace aggregate -- with the element itself. if Multiple then Remove (Output); Rewrite (Outputs, Output); end if; -- Default case else -- Unchain the output from its output list as it will appear in -- a new clause. Note that we cannot simply rewrite the output -- as null because this will violate the semantics of pragma -- Depends. Remove (Output); -- Generate a new clause of the form: -- (Output => Inputs) New_Clause := Make_Component_Association (Loc, Choices => New_List (Output), Expression => New_Copy_Tree (Inputs)); -- The new clause contains replicated content that has already -- been analyzed. There is not need to reanalyze or renormalize -- it again. Set_Analyzed (New_Clause); Propagate_Output (Output => First (Choices (New_Clause)), Inputs => Expression (New_Clause)); Insert_After (After, New_Clause); end if; end Create_Or_Modify_Clause; -- Local variables Outputs : constant Node_Id := First (Choices (Clause)); Inputs : Node_Id; Last_Output : Node_Id; Next_Output : Node_Id; Output : Node_Id; -- Start of processing for Normalize_Clause begin -- A self-dependency appears as operator "+". Remove the "+" from the -- tree by moving the real inputs to their proper place. if Nkind (Expression (Clause)) = N_Op_Plus then Rewrite (Expression (Clause), Right_Opnd (Expression (Clause))); Inputs := Expression (Clause); -- Multiple outputs appear as an aggregate if Nkind (Outputs) = N_Aggregate then Last_Output := Last (Expressions (Outputs)); Output := First (Expressions (Outputs)); while Present (Output) loop -- Normalization may remove an output from its list, -- preserve the subsequent output now. Next_Output := Next (Output); Create_Or_Modify_Clause (Output => Output, Outputs => Outputs, Inputs => Inputs, After => Clause, In_Place => Output = Last_Output, Multiple => True); Output := Next_Output; end loop; -- Solitary output else Create_Or_Modify_Clause (Output => Outputs, Outputs => Empty, Inputs => Inputs, After => Empty, In_Place => True, Multiple => False); end if; end if; end Normalize_Clause; -- Local variables Deps : constant Node_Id := Expression (Get_Argument (N, Spec_Id)); Subp_Id : constant Entity_Id := Defining_Entity (Subp_Decl); Clause : Node_Id; Errors : Nat; Last_Clause : Node_Id; Restore_Scope : Boolean := False; -- Start of processing for Analyze_Depends_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Empty dependency list if Nkind (Deps) = N_Null then -- Gather all states, objects and formal parameters that the -- subprogram may depend on. These items are obtained from the -- parameter profile or pragma [Refined_]Global (if available). Collect_Subprogram_Inputs_Outputs (Subp_Id => Subp_Id, Subp_Inputs => Subp_Inputs, Subp_Outputs => Subp_Outputs, Global_Seen => Global_Seen); -- Verify that every input or output of the subprogram appear in a -- dependency. Check_Usage (Subp_Inputs, All_Inputs_Seen, True); Check_Usage (Subp_Outputs, All_Outputs_Seen, False); Check_Function_Return; -- Dependency clauses appear as component associations of an aggregate elsif Nkind (Deps) = N_Aggregate then -- Do not attempt to perform analysis of a syntactically illegal -- clause as this will lead to misleading errors. if Has_Extra_Parentheses (Deps) then return; end if; if Present (Component_Associations (Deps)) then Last_Clause := Last (Component_Associations (Deps)); -- Gather all states, objects and formal parameters that the -- subprogram may depend on. These items are obtained from the -- parameter profile or pragma [Refined_]Global (if available). Collect_Subprogram_Inputs_Outputs (Subp_Id => Subp_Id, Subp_Inputs => Subp_Inputs, Subp_Outputs => Subp_Outputs, Global_Seen => Global_Seen); -- When pragma [Refined_]Depends appears on a single concurrent -- type, it is relocated to the anonymous object. if Is_Single_Concurrent_Object (Spec_Id) then null; -- Ensure that the formal parameters are visible when analyzing -- all clauses. This falls out of the general rule of aspects -- pertaining to subprogram declarations. elsif not In_Open_Scopes (Spec_Id) then Restore_Scope := True; Push_Scope (Spec_Id); if Ekind (Spec_Id) = E_Task_Type then if Has_Discriminants (Spec_Id) then Install_Discriminants (Spec_Id); end if; elsif Is_Generic_Subprogram (Spec_Id) then Install_Generic_Formals (Spec_Id); else Install_Formals (Spec_Id); end if; end if; Clause := First (Component_Associations (Deps)); while Present (Clause) loop Errors := Serious_Errors_Detected; -- The normalization mechanism may create extra clauses that -- contain replicated input and output names. There is no need -- to reanalyze them. if not Analyzed (Clause) then Set_Analyzed (Clause); Analyze_Dependency_Clause (Clause => Clause, Is_Last => Clause = Last_Clause); end if; -- Do not normalize a clause if errors were detected (count -- of Serious_Errors has increased) because the inputs and/or -- outputs may denote illegal items. Normalization is disabled -- in ASIS mode as it alters the tree by introducing new nodes -- similar to expansion. if Serious_Errors_Detected = Errors and then not ASIS_Mode then Normalize_Clause (Clause); end if; Next (Clause); end loop; if Restore_Scope then End_Scope; end if; -- Verify that every input or output of the subprogram appear in a -- dependency. Check_Usage (Subp_Inputs, All_Inputs_Seen, True); Check_Usage (Subp_Outputs, All_Outputs_Seen, False); Check_Function_Return; -- The dependency list is malformed. This is a syntax error, always -- report. else Error_Msg_N ("malformed dependency relation", Deps); return; end if; -- The top level dependency relation is malformed. This is a syntax -- error, always report. else Error_Msg_N ("malformed dependency relation", Deps); goto Leave; end if; -- Ensure that a state and a corresponding constituent do not appear -- together in pragma [Refined_]Depends. Check_State_And_Constituent_Use (States => States_Seen, Constits => Constits_Seen, Context => N); <> Set_Is_Analyzed_Pragma (N); end Analyze_Depends_In_Decl_Part; -------------------------------------------- -- Analyze_External_Property_In_Decl_Part -- -------------------------------------------- procedure Analyze_External_Property_In_Decl_Part (N : Node_Id; Expr_Val : out Boolean) is Arg1 : constant Node_Id := First (Pragma_Argument_Associations (N)); Obj_Decl : constant Node_Id := Find_Related_Context (N); Obj_Id : constant Entity_Id := Defining_Entity (Obj_Decl); Expr : Node_Id; begin Expr_Val := False; -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; Error_Msg_Name_1 := Pragma_Name (N); -- An external property pragma must apply to an effectively volatile -- object other than a formal subprogram parameter (SPARK RM 7.1.3(2)). -- The check is performed at the end of the declarative region due to a -- possible out-of-order arrangement of pragmas: -- Obj : ...; -- pragma Async_Readers (Obj); -- pragma Volatile (Obj); if not Is_Effectively_Volatile (Obj_Id) then SPARK_Msg_N ("external property % must apply to a volatile object", N); end if; -- Ensure that the Boolean expression (if present) is static. A missing -- argument defaults the value to True (SPARK RM 7.1.2(5)). Expr_Val := True; if Present (Arg1) then Expr := Get_Pragma_Arg (Arg1); if Is_OK_Static_Expression (Expr) then Expr_Val := Is_True (Expr_Value (Expr)); end if; end if; Set_Is_Analyzed_Pragma (N); end Analyze_External_Property_In_Decl_Part; --------------------------------- -- Analyze_Global_In_Decl_Part -- --------------------------------- procedure Analyze_Global_In_Decl_Part (N : Node_Id) is Subp_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Subp_Decl); Subp_Id : constant Entity_Id := Defining_Entity (Subp_Decl); Constits_Seen : Elist_Id := No_Elist; -- A list containing the entities of all constituents processed so far. -- It aids in detecting illegal usage of a state and a corresponding -- constituent in pragma [Refinde_]Global. Seen : Elist_Id := No_Elist; -- A list containing the entities of all the items processed so far. It -- plays a role in detecting distinct entities. States_Seen : Elist_Id := No_Elist; -- A list containing the entities of all states processed so far. It -- helps in detecting illegal usage of a state and a corresponding -- constituent in pragma [Refined_]Global. In_Out_Seen : Boolean := False; Input_Seen : Boolean := False; Output_Seen : Boolean := False; Proof_Seen : Boolean := False; -- Flags used to verify the consistency of modes procedure Analyze_Global_List (List : Node_Id; Global_Mode : Name_Id := Name_Input); -- Verify the legality of a single global list declaration. Global_Mode -- denotes the current mode in effect. ------------------------- -- Analyze_Global_List -- ------------------------- procedure Analyze_Global_List (List : Node_Id; Global_Mode : Name_Id := Name_Input) is procedure Analyze_Global_Item (Item : Node_Id; Global_Mode : Name_Id); -- Verify the legality of a single global item declaration denoted by -- Item. Global_Mode denotes the current mode in effect. procedure Check_Duplicate_Mode (Mode : Node_Id; Status : in out Boolean); -- Flag Status denotes whether a particular mode has been seen while -- processing a global list. This routine verifies that Mode is not a -- duplicate mode and sets the flag Status (SPARK RM 6.1.4(9)). procedure Check_Mode_Restriction_In_Enclosing_Context (Item : Node_Id; Item_Id : Entity_Id); -- Verify that an item of mode In_Out or Output does not appear as -- an input in the Global aspect of an enclosing subprogram or task -- unit. If this is the case, emit an error. Item and Item_Id are -- respectively the item and its entity. procedure Check_Mode_Restriction_In_Function (Mode : Node_Id); -- Mode denotes either In_Out or Output. Depending on the kind of the -- related subprogram, emit an error if those two modes apply to a -- function (SPARK RM 6.1.4(10)). ------------------------- -- Analyze_Global_Item -- ------------------------- procedure Analyze_Global_Item (Item : Node_Id; Global_Mode : Name_Id) is Item_Id : Entity_Id; begin -- Detect one of the following cases -- with Global => (null, Name) -- with Global => (Name_1, null, Name_2) -- with Global => (Name, null) if Nkind (Item) = N_Null then SPARK_Msg_N ("cannot mix null and non-null global items", Item); return; end if; Analyze (Item); Resolve_State (Item); -- Find the entity of the item. If this is a renaming, climb the -- renaming chain to reach the root object. Renamings of non- -- entire objects do not yield an entity (Empty). Item_Id := Entity_Of (Item); if Present (Item_Id) then -- A global item may denote a formal parameter of an enclosing -- subprogram (SPARK RM 6.1.4(6)). Do this check first to -- provide a better error diagnostic. if Is_Formal (Item_Id) then if Scope (Item_Id) = Spec_Id then SPARK_Msg_NE (Fix_Msg (Spec_Id, "global item cannot reference " & "parameter of subprogram &"), Item, Spec_Id); return; end if; -- A global item may denote a concurrent type as long as it is -- the current instance of an enclosing protected or task type -- (SPARK RM 6.1.4). elsif Ekind_In (Item_Id, E_Protected_Type, E_Task_Type) then if Is_CCT_Instance (Item_Id, Spec_Id) then -- Pragma [Refined_]Global associated with a protected -- subprogram cannot mention the current instance of a -- protected type because the instance behaves as a -- formal parameter. if Ekind (Item_Id) = E_Protected_Type then if Scope (Spec_Id) = Item_Id then Error_Msg_Name_1 := Chars (Item_Id); SPARK_Msg_NE (Fix_Msg (Spec_Id, "global item of subprogram & " & "cannot reference current instance of " & "protected type %"), Item, Spec_Id); return; end if; -- Pragma [Refined_]Global associated with a task type -- cannot mention the current instance of a task type -- because the instance behaves as a formal parameter. else pragma Assert (Ekind (Item_Id) = E_Task_Type); if Spec_Id = Item_Id then Error_Msg_Name_1 := Chars (Item_Id); SPARK_Msg_NE (Fix_Msg (Spec_Id, "global item of subprogram & " & "cannot reference current instance of task " & "type %"), Item, Spec_Id); return; end if; end if; -- Otherwise the global item denotes a subtype mark that is -- not a current instance. else SPARK_Msg_N ("invalid use of subtype mark in global list", Item); return; end if; -- A global item may denote the anonymous object created for a -- single protected/task type as long as the current instance -- is the same single type (SPARK RM 6.1.4). elsif Is_Single_Concurrent_Object (Item_Id) and then Is_CCT_Instance (Etype (Item_Id), Spec_Id) then -- Pragma [Refined_]Global associated with a protected -- subprogram cannot mention the current instance of a -- protected type because the instance behaves as a formal -- parameter. if Is_Single_Protected_Object (Item_Id) then if Scope (Spec_Id) = Etype (Item_Id) then Error_Msg_Name_1 := Chars (Item_Id); SPARK_Msg_NE (Fix_Msg (Spec_Id, "global item of subprogram & " & "cannot reference current instance of protected " & "type %"), Item, Spec_Id); return; end if; -- Pragma [Refined_]Global associated with a task type -- cannot mention the current instance of a task type -- because the instance behaves as a formal parameter. else pragma Assert (Is_Single_Task_Object (Item_Id)); if Spec_Id = Item_Id then Error_Msg_Name_1 := Chars (Item_Id); SPARK_Msg_NE (Fix_Msg (Spec_Id, "global item of subprogram & " & "cannot reference current instance of task " & "type %"), Item, Spec_Id); return; end if; end if; -- A formal object may act as a global item inside a generic elsif Is_Formal_Object (Item_Id) then null; -- The only legal references are those to abstract states, -- objects and various kinds of constants (SPARK RM 6.1.4(4)). elsif not Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Loop_Parameter, E_Variable) then SPARK_Msg_N ("global item must denote object, state or current " & "instance of concurrent type", Item); return; end if; -- State related checks if Ekind (Item_Id) = E_Abstract_State then -- Package and subprogram bodies are instantiated -- individually in a separate compiler pass. Due to this -- mode of instantiation, the refinement of a state may -- no longer be visible when a subprogram body contract -- is instantiated. Since the generic template is legal, -- do not perform this check in the instance to circumvent -- this oddity. if Is_Generic_Instance (Spec_Id) then null; -- An abstract state with visible refinement cannot appear -- in pragma [Refined_]Global as its place must be taken by -- some of its constituents (SPARK RM 6.1.4(7)). elsif Has_Visible_Refinement (Item_Id) then SPARK_Msg_NE ("cannot mention state & in global refinement", Item, Item_Id); SPARK_Msg_N ("\use its constituents instead", Item); return; -- An external state cannot appear as a global item of a -- nonvolatile function (SPARK RM 7.1.3(8)). elsif Is_External_State (Item_Id) and then Ekind_In (Spec_Id, E_Function, E_Generic_Function) and then not Is_Volatile_Function (Spec_Id) then SPARK_Msg_NE ("external state & cannot act as global item of " & "nonvolatile function", Item, Item_Id); return; -- If the reference to the abstract state appears in an -- enclosing package body that will eventually refine the -- state, record the reference for future checks. else Record_Possible_Body_Reference (State_Id => Item_Id, Ref => Item); end if; -- Constant related checks elsif Ekind (Item_Id) = E_Constant then -- A constant is a read-only item, therefore it cannot act -- as an output. if Nam_In (Global_Mode, Name_In_Out, Name_Output) then SPARK_Msg_NE ("constant & cannot act as output", Item, Item_Id); return; end if; -- Loop parameter related checks elsif Ekind (Item_Id) = E_Loop_Parameter then -- A loop parameter is a read-only item, therefore it cannot -- act as an output. if Nam_In (Global_Mode, Name_In_Out, Name_Output) then SPARK_Msg_NE ("loop parameter & cannot act as output", Item, Item_Id); return; end if; -- Variable related checks. These are only relevant when -- SPARK_Mode is on as they are not standard Ada legality -- rules. elsif SPARK_Mode = On and then Ekind (Item_Id) = E_Variable and then Is_Effectively_Volatile (Item_Id) then -- An effectively volatile object cannot appear as a global -- item of a nonvolatile function (SPARK RM 7.1.3(8)). if Ekind_In (Spec_Id, E_Function, E_Generic_Function) and then not Is_Volatile_Function (Spec_Id) then Error_Msg_NE ("volatile object & cannot act as global item of a " & "function", Item, Item_Id); return; -- An effectively volatile object with external property -- Effective_Reads set to True must have mode Output or -- In_Out (SPARK RM 7.1.3(10)). elsif Effective_Reads_Enabled (Item_Id) and then Global_Mode = Name_Input then Error_Msg_NE ("volatile object & with property Effective_Reads must " & "have mode In_Out or Output", Item, Item_Id); return; end if; end if; -- When the item renames an entire object, replace the item -- with a reference to the object. if Entity (Item) /= Item_Id then Rewrite (Item, New_Occurrence_Of (Item_Id, Sloc (Item))); Analyze (Item); end if; -- Some form of illegal construct masquerading as a name -- (SPARK RM 6.1.4(4)). else Error_Msg_N ("global item must denote object, state or current instance " & "of concurrent type", Item); return; end if; -- Verify that an output does not appear as an input in an -- enclosing subprogram. if Nam_In (Global_Mode, Name_In_Out, Name_Output) then Check_Mode_Restriction_In_Enclosing_Context (Item, Item_Id); end if; -- The same entity might be referenced through various way. -- Check the entity of the item rather than the item itself -- (SPARK RM 6.1.4(10)). if Contains (Seen, Item_Id) then SPARK_Msg_N ("duplicate global item", Item); -- Add the entity of the current item to the list of processed -- items. else Append_New_Elmt (Item_Id, Seen); if Ekind (Item_Id) = E_Abstract_State then Append_New_Elmt (Item_Id, States_Seen); -- The variable may eventually become a constituent of a single -- protected/task type. Record the reference now and verify its -- legality when analyzing the contract of the variable -- (SPARK RM 9.3). elsif Ekind (Item_Id) = E_Variable then Record_Possible_Part_Of_Reference (Var_Id => Item_Id, Ref => Item); end if; if Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Variable) and then Present (Encapsulating_State (Item_Id)) then Append_New_Elmt (Item_Id, Constits_Seen); end if; end if; end Analyze_Global_Item; -------------------------- -- Check_Duplicate_Mode -- -------------------------- procedure Check_Duplicate_Mode (Mode : Node_Id; Status : in out Boolean) is begin if Status then SPARK_Msg_N ("duplicate global mode", Mode); end if; Status := True; end Check_Duplicate_Mode; ------------------------------------------------- -- Check_Mode_Restriction_In_Enclosing_Context -- ------------------------------------------------- procedure Check_Mode_Restriction_In_Enclosing_Context (Item : Node_Id; Item_Id : Entity_Id) is Context : Entity_Id; Dummy : Boolean; Inputs : Elist_Id := No_Elist; Outputs : Elist_Id := No_Elist; begin -- Traverse the scope stack looking for enclosing subprograms or -- tasks subject to pragma [Refined_]Global. Context := Scope (Subp_Id); while Present (Context) and then Context /= Standard_Standard loop -- For a single task type, retrieve the corresponding object to -- which pragma [Refined_]Global is attached. if Ekind (Context) = E_Task_Type and then Is_Single_Concurrent_Type (Context) then Context := Anonymous_Object (Context); end if; if (Is_Subprogram (Context) or else Ekind (Context) = E_Task_Type or else Is_Single_Task_Object (Context)) and then (Present (Get_Pragma (Context, Pragma_Global)) or else Present (Get_Pragma (Context, Pragma_Refined_Global))) then Collect_Subprogram_Inputs_Outputs (Subp_Id => Context, Subp_Inputs => Inputs, Subp_Outputs => Outputs, Global_Seen => Dummy); -- The item is classified as In_Out or Output but appears as -- an Input in an enclosing subprogram or task unit (SPARK -- RM 6.1.4(12)). if Appears_In (Inputs, Item_Id) and then not Appears_In (Outputs, Item_Id) then SPARK_Msg_NE ("global item & cannot have mode In_Out or Output", Item, Item_Id); if Is_Subprogram (Context) then SPARK_Msg_NE (Fix_Msg (Subp_Id, "\item already appears as input " & "of subprogram &"), Item, Context); else SPARK_Msg_NE (Fix_Msg (Subp_Id, "\item already appears as input " & "of task &"), Item, Context); end if; -- Stop the traversal once an error has been detected exit; end if; end if; Context := Scope (Context); end loop; end Check_Mode_Restriction_In_Enclosing_Context; ---------------------------------------- -- Check_Mode_Restriction_In_Function -- ---------------------------------------- procedure Check_Mode_Restriction_In_Function (Mode : Node_Id) is begin if Ekind_In (Spec_Id, E_Function, E_Generic_Function) then SPARK_Msg_N ("global mode & is not applicable to functions", Mode); end if; end Check_Mode_Restriction_In_Function; -- Local variables Assoc : Node_Id; Item : Node_Id; Mode : Node_Id; -- Start of processing for Analyze_Global_List begin if Nkind (List) = N_Null then Set_Analyzed (List); -- Single global item declaration elsif Nkind_In (List, N_Expanded_Name, N_Identifier, N_Selected_Component) then Analyze_Global_Item (List, Global_Mode); -- Simple global list or moded global list declaration elsif Nkind (List) = N_Aggregate then Set_Analyzed (List); -- The declaration of a simple global list appear as a collection -- of expressions. if Present (Expressions (List)) then if Present (Component_Associations (List)) then SPARK_Msg_N ("cannot mix moded and non-moded global lists", List); end if; Item := First (Expressions (List)); while Present (Item) loop Analyze_Global_Item (Item, Global_Mode); Next (Item); end loop; -- The declaration of a moded global list appears as a collection -- of component associations where individual choices denote -- modes. elsif Present (Component_Associations (List)) then if Present (Expressions (List)) then SPARK_Msg_N ("cannot mix moded and non-moded global lists", List); end if; Assoc := First (Component_Associations (List)); while Present (Assoc) loop Mode := First (Choices (Assoc)); if Nkind (Mode) = N_Identifier then if Chars (Mode) = Name_In_Out then Check_Duplicate_Mode (Mode, In_Out_Seen); Check_Mode_Restriction_In_Function (Mode); elsif Chars (Mode) = Name_Input then Check_Duplicate_Mode (Mode, Input_Seen); elsif Chars (Mode) = Name_Output then Check_Duplicate_Mode (Mode, Output_Seen); Check_Mode_Restriction_In_Function (Mode); elsif Chars (Mode) = Name_Proof_In then Check_Duplicate_Mode (Mode, Proof_Seen); else SPARK_Msg_N ("invalid mode selector", Mode); end if; else SPARK_Msg_N ("invalid mode selector", Mode); end if; -- Items in a moded list appear as a collection of -- expressions. Reuse the existing machinery to analyze -- them. Analyze_Global_List (List => Expression (Assoc), Global_Mode => Chars (Mode)); Next (Assoc); end loop; -- Invalid tree else raise Program_Error; end if; -- Any other attempt to declare a global item is illegal. This is a -- syntax error, always report. else Error_Msg_N ("malformed global list", List); end if; end Analyze_Global_List; -- Local variables Items : constant Node_Id := Expression (Get_Argument (N, Spec_Id)); Restore_Scope : Boolean := False; -- Start of processing for Analyze_Global_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- There is nothing to be done for a null global list if Nkind (Items) = N_Null then Set_Analyzed (Items); -- Analyze the various forms of global lists and items. Note that some -- of these may be malformed in which case the analysis emits error -- messages. else -- When pragma [Refined_]Global appears on a single concurrent type, -- it is relocated to the anonymous object. if Is_Single_Concurrent_Object (Spec_Id) then null; -- Ensure that the formal parameters are visible when processing an -- item. This falls out of the general rule of aspects pertaining to -- subprogram declarations. elsif not In_Open_Scopes (Spec_Id) then Restore_Scope := True; Push_Scope (Spec_Id); if Ekind (Spec_Id) = E_Task_Type then if Has_Discriminants (Spec_Id) then Install_Discriminants (Spec_Id); end if; elsif Is_Generic_Subprogram (Spec_Id) then Install_Generic_Formals (Spec_Id); else Install_Formals (Spec_Id); end if; end if; Analyze_Global_List (Items); if Restore_Scope then End_Scope; end if; end if; -- Ensure that a state and a corresponding constituent do not appear -- together in pragma [Refined_]Global. Check_State_And_Constituent_Use (States => States_Seen, Constits => Constits_Seen, Context => N); Set_Is_Analyzed_Pragma (N); end Analyze_Global_In_Decl_Part; -------------------------------------------- -- Analyze_Initial_Condition_In_Decl_Part -- -------------------------------------------- -- WARNING: This routine manages Ghost regions. Return statements must be -- replaced by gotos which jump to the end of the routine and restore the -- Ghost mode. procedure Analyze_Initial_Condition_In_Decl_Part (N : Node_Id) is Pack_Decl : constant Node_Id := Find_Related_Package_Or_Body (N); Pack_Id : constant Entity_Id := Defining_Entity (Pack_Decl); Expr : constant Node_Id := Expression (Get_Argument (N, Pack_Id)); Saved_GM : constant Ghost_Mode_Type := Ghost_Mode; Saved_IGR : constant Node_Id := Ignored_Ghost_Region; -- Save the Ghost-related attributes to restore on exit begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Set the Ghost mode in effect from the pragma. Due to the delayed -- analysis of the pragma, the Ghost mode at point of declaration and -- point of analysis may not necessarily be the same. Use the mode in -- effect at the point of declaration. Set_Ghost_Mode (N); -- The expression is preanalyzed because it has not been moved to its -- final place yet. A direct analysis may generate side effects and this -- is not desired at this point. Preanalyze_Assert_Expression (Expr, Standard_Boolean); Set_Is_Analyzed_Pragma (N); Restore_Ghost_Region (Saved_GM, Saved_IGR); end Analyze_Initial_Condition_In_Decl_Part; -------------------------------------- -- Analyze_Initializes_In_Decl_Part -- -------------------------------------- procedure Analyze_Initializes_In_Decl_Part (N : Node_Id) is Pack_Decl : constant Node_Id := Find_Related_Package_Or_Body (N); Pack_Id : constant Entity_Id := Defining_Entity (Pack_Decl); Constits_Seen : Elist_Id := No_Elist; -- A list containing the entities of all constituents processed so far. -- It aids in detecting illegal usage of a state and a corresponding -- constituent in pragma Initializes. Items_Seen : Elist_Id := No_Elist; -- A list of all initialization items processed so far. This list is -- used to detect duplicate items. States_And_Objs : Elist_Id := No_Elist; -- A list of all abstract states and objects declared in the visible -- declarations of the related package. This list is used to detect the -- legality of initialization items. States_Seen : Elist_Id := No_Elist; -- A list containing the entities of all states processed so far. It -- helps in detecting illegal usage of a state and a corresponding -- constituent in pragma Initializes. procedure Analyze_Initialization_Item (Item : Node_Id); -- Verify the legality of a single initialization item procedure Analyze_Initialization_Item_With_Inputs (Item : Node_Id); -- Verify the legality of a single initialization item followed by a -- list of input items. procedure Collect_States_And_Objects; -- Inspect the visible declarations of the related package and gather -- the entities of all abstract states and objects in States_And_Objs. --------------------------------- -- Analyze_Initialization_Item -- --------------------------------- procedure Analyze_Initialization_Item (Item : Node_Id) is Item_Id : Entity_Id; begin Analyze (Item); Resolve_State (Item); if Is_Entity_Name (Item) then Item_Id := Entity_Of (Item); if Present (Item_Id) and then Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Variable) then -- When the initialization item is undefined, it appears as -- Any_Id. Do not continue with the analysis of the item. if Item_Id = Any_Id then null; -- The state or variable must be declared in the visible -- declarations of the package (SPARK RM 7.1.5(7)). elsif not Contains (States_And_Objs, Item_Id) then Error_Msg_Name_1 := Chars (Pack_Id); SPARK_Msg_NE ("initialization item & must appear in the visible " & "declarations of package %", Item, Item_Id); -- Detect a duplicate use of the same initialization item -- (SPARK RM 7.1.5(5)). elsif Contains (Items_Seen, Item_Id) then SPARK_Msg_N ("duplicate initialization item", Item); -- The item is legal, add it to the list of processed states -- and variables. else Append_New_Elmt (Item_Id, Items_Seen); if Ekind (Item_Id) = E_Abstract_State then Append_New_Elmt (Item_Id, States_Seen); end if; if Present (Encapsulating_State (Item_Id)) then Append_New_Elmt (Item_Id, Constits_Seen); end if; end if; -- The item references something that is not a state or object -- (SPARK RM 7.1.5(3)). else SPARK_Msg_N ("initialization item must denote object or state", Item); end if; -- Some form of illegal construct masquerading as a name -- (SPARK RM 7.1.5(3)). This is a syntax error, always report. else Error_Msg_N ("initialization item must denote object or state", Item); end if; end Analyze_Initialization_Item; --------------------------------------------- -- Analyze_Initialization_Item_With_Inputs -- --------------------------------------------- procedure Analyze_Initialization_Item_With_Inputs (Item : Node_Id) is Inputs_Seen : Elist_Id := No_Elist; -- A list of all inputs processed so far. This list is used to detect -- duplicate uses of an input. Non_Null_Seen : Boolean := False; Null_Seen : Boolean := False; -- Flags used to check the legality of an input list procedure Analyze_Input_Item (Input : Node_Id); -- Verify the legality of a single input item ------------------------ -- Analyze_Input_Item -- ------------------------ procedure Analyze_Input_Item (Input : Node_Id) is Input_Id : Entity_Id; begin -- Null input list if Nkind (Input) = N_Null then if Null_Seen then SPARK_Msg_N ("multiple null initializations not allowed", Item); elsif Non_Null_Seen then SPARK_Msg_N ("cannot mix null and non-null initialization item", Item); else Null_Seen := True; end if; -- Input item else Non_Null_Seen := True; if Null_Seen then SPARK_Msg_N ("cannot mix null and non-null initialization item", Item); end if; Analyze (Input); Resolve_State (Input); if Is_Entity_Name (Input) then Input_Id := Entity_Of (Input); if Present (Input_Id) and then Ekind_In (Input_Id, E_Abstract_State, E_Constant, E_Generic_In_Out_Parameter, E_Generic_In_Parameter, E_In_Parameter, E_In_Out_Parameter, E_Out_Parameter, E_Protected_Type, E_Task_Type, E_Variable) then -- The input cannot denote states or objects declared -- within the related package (SPARK RM 7.1.5(4)). if Within_Scope (Input_Id, Current_Scope) then -- Do not consider generic formal parameters or their -- respective mappings to generic formals. Even though -- the formals appear within the scope of the package, -- it is allowed for an initialization item to depend -- on an input item. if Ekind_In (Input_Id, E_Generic_In_Out_Parameter, E_Generic_In_Parameter) then null; elsif Ekind_In (Input_Id, E_Constant, E_Variable) and then Present (Corresponding_Generic_Association (Declaration_Node (Input_Id))) then null; else Error_Msg_Name_1 := Chars (Pack_Id); SPARK_Msg_NE ("input item & cannot denote a visible object or " & "state of package %", Input, Input_Id); return; end if; end if; -- Detect a duplicate use of the same input item -- (SPARK RM 7.1.5(5)). if Contains (Inputs_Seen, Input_Id) then SPARK_Msg_N ("duplicate input item", Input); return; end if; -- At this point it is known that the input is legal. Add -- it to the list of processed inputs. Append_New_Elmt (Input_Id, Inputs_Seen); if Ekind (Input_Id) = E_Abstract_State then Append_New_Elmt (Input_Id, States_Seen); end if; if Ekind_In (Input_Id, E_Abstract_State, E_Constant, E_Variable) and then Present (Encapsulating_State (Input_Id)) then Append_New_Elmt (Input_Id, Constits_Seen); end if; -- The input references something that is not a state or an -- object (SPARK RM 7.1.5(3)). else SPARK_Msg_N ("input item must denote object or state", Input); end if; -- Some form of illegal construct masquerading as a name -- (SPARK RM 7.1.5(3)). This is a syntax error, always report. else Error_Msg_N ("input item must denote object or state", Input); end if; end if; end Analyze_Input_Item; -- Local variables Inputs : constant Node_Id := Expression (Item); Elmt : Node_Id; Input : Node_Id; Name_Seen : Boolean := False; -- A flag used to detect multiple item names -- Start of processing for Analyze_Initialization_Item_With_Inputs begin -- Inspect the name of an item with inputs Elmt := First (Choices (Item)); while Present (Elmt) loop if Name_Seen then SPARK_Msg_N ("only one item allowed in initialization", Elmt); else Name_Seen := True; Analyze_Initialization_Item (Elmt); end if; Next (Elmt); end loop; -- Multiple input items appear as an aggregate if Nkind (Inputs) = N_Aggregate then if Present (Expressions (Inputs)) then Input := First (Expressions (Inputs)); while Present (Input) loop Analyze_Input_Item (Input); Next (Input); end loop; end if; if Present (Component_Associations (Inputs)) then SPARK_Msg_N ("inputs must appear in named association form", Inputs); end if; -- Single input item else Analyze_Input_Item (Inputs); end if; end Analyze_Initialization_Item_With_Inputs; -------------------------------- -- Collect_States_And_Objects -- -------------------------------- procedure Collect_States_And_Objects is Pack_Spec : constant Node_Id := Specification (Pack_Decl); Decl : Node_Id; begin -- Collect the abstract states defined in the package (if any) if Present (Abstract_States (Pack_Id)) then States_And_Objs := New_Copy_Elist (Abstract_States (Pack_Id)); end if; -- Collect all objects that appear in the visible declarations of the -- related package. if Present (Visible_Declarations (Pack_Spec)) then Decl := First (Visible_Declarations (Pack_Spec)); while Present (Decl) loop if Comes_From_Source (Decl) and then Nkind_In (Decl, N_Object_Declaration, N_Object_Renaming_Declaration) then Append_New_Elmt (Defining_Entity (Decl), States_And_Objs); elsif Is_Single_Concurrent_Type_Declaration (Decl) then Append_New_Elmt (Anonymous_Object (Defining_Entity (Decl)), States_And_Objs); end if; Next (Decl); end loop; end if; end Collect_States_And_Objects; -- Local variables Inits : constant Node_Id := Expression (Get_Argument (N, Pack_Id)); Init : Node_Id; -- Start of processing for Analyze_Initializes_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Nothing to do when the initialization list is empty if Nkind (Inits) = N_Null then return; end if; -- Single and multiple initialization clauses appear as an aggregate. If -- this is not the case, then either the parser or the analysis of the -- pragma failed to produce an aggregate. pragma Assert (Nkind (Inits) = N_Aggregate); -- Initialize the various lists used during analysis Collect_States_And_Objects; if Present (Expressions (Inits)) then Init := First (Expressions (Inits)); while Present (Init) loop Analyze_Initialization_Item (Init); Next (Init); end loop; end if; if Present (Component_Associations (Inits)) then Init := First (Component_Associations (Inits)); while Present (Init) loop Analyze_Initialization_Item_With_Inputs (Init); Next (Init); end loop; end if; -- Ensure that a state and a corresponding constituent do not appear -- together in pragma Initializes. Check_State_And_Constituent_Use (States => States_Seen, Constits => Constits_Seen, Context => N); Set_Is_Analyzed_Pragma (N); end Analyze_Initializes_In_Decl_Part; --------------------- -- Analyze_Part_Of -- --------------------- procedure Analyze_Part_Of (Indic : Node_Id; Item_Id : Entity_Id; Encap : Node_Id; Encap_Id : out Entity_Id; Legal : out Boolean) is procedure Check_Part_Of_Abstract_State; pragma Inline (Check_Part_Of_Abstract_State); -- Verify the legality of indicator Part_Of when the encapsulator is an -- abstract state. procedure Check_Part_Of_Concurrent_Type; pragma Inline (Check_Part_Of_Concurrent_Type); -- Verify the legality of indicator Part_Of when the encapsulator is a -- single concurrent type. ---------------------------------- -- Check_Part_Of_Abstract_State -- ---------------------------------- procedure Check_Part_Of_Abstract_State is Pack_Id : Entity_Id; Placement : State_Space_Kind; Parent_Unit : Entity_Id; begin -- Determine where the object, package instantiation or state lives -- with respect to the enclosing packages or package bodies. Find_Placement_In_State_Space (Item_Id => Item_Id, Placement => Placement, Pack_Id => Pack_Id); -- The item appears in a non-package construct with a declarative -- part (subprogram, block, etc). As such, the item is not allowed -- to be a part of an encapsulating state because the item is not -- visible. if Placement = Not_In_Package then SPARK_Msg_N ("indicator Part_Of cannot appear in this context " & "(SPARK RM 7.2.6(5))", Indic); Error_Msg_Name_1 := Chars (Scope (Encap_Id)); SPARK_Msg_NE ("\& is not part of the hidden state of package %", Indic, Item_Id); return; -- The item appears in the visible state space of some package. In -- general this scenario does not warrant Part_Of except when the -- package is a nongeneric private child unit and the encapsulating -- state is declared in a parent unit or a public descendant of that -- parent unit. elsif Placement = Visible_State_Space then if Is_Child_Unit (Pack_Id) and then not Is_Generic_Unit (Pack_Id) and then Is_Private_Descendant (Pack_Id) then -- A variable or state abstraction which is part of the visible -- state of a nongeneric private child unit or its public -- descendants must have its Part_Of indicator specified. The -- Part_Of indicator must denote a state declared by either the -- parent unit of the private unit or by a public descendant of -- that parent unit. -- Find the nearest private ancestor (which can be the current -- unit itself). Parent_Unit := Pack_Id; while Present (Parent_Unit) loop exit when Private_Present (Parent (Unit_Declaration_Node (Parent_Unit))); Parent_Unit := Scope (Parent_Unit); end loop; Parent_Unit := Scope (Parent_Unit); if not Is_Child_Or_Sibling (Pack_Id, Scope (Encap_Id)) then SPARK_Msg_NE ("indicator Part_Of must denote abstract state of & or of " & "its public descendant (SPARK RM 7.2.6(3))", Indic, Parent_Unit); return; elsif Scope (Encap_Id) = Parent_Unit or else (Is_Ancestor_Package (Parent_Unit, Scope (Encap_Id)) and then not Is_Private_Descendant (Scope (Encap_Id))) then null; else SPARK_Msg_NE ("indicator Part_Of must denote abstract state of & or of " & "its public descendant (SPARK RM 7.2.6(3))", Indic, Parent_Unit); return; end if; -- Indicator Part_Of is not needed when the related package is -- not a nongeneric private child unit or a public descendant -- thereof. else SPARK_Msg_N ("indicator Part_Of cannot appear in this context " & "(SPARK RM 7.2.6(5))", Indic); Error_Msg_Name_1 := Chars (Pack_Id); SPARK_Msg_NE ("\& is declared in the visible part of package %", Indic, Item_Id); return; end if; -- When the item appears in the private state space of a package, the -- encapsulating state must be declared in the same package. elsif Placement = Private_State_Space then if Scope (Encap_Id) /= Pack_Id then SPARK_Msg_NE ("indicator Part_Of must denote an abstract state of " & "package & (SPARK RM 7.2.6(2))", Indic, Pack_Id); Error_Msg_Name_1 := Chars (Pack_Id); SPARK_Msg_NE ("\& is declared in the private part of package %", Indic, Item_Id); return; end if; -- Items declared in the body state space of a package do not need -- Part_Of indicators as the refinement has already been seen. else SPARK_Msg_N ("indicator Part_Of cannot appear in this context " & "(SPARK RM 7.2.6(5))", Indic); if Scope (Encap_Id) = Pack_Id then Error_Msg_Name_1 := Chars (Pack_Id); SPARK_Msg_NE ("\& is declared in the body of package %", Indic, Item_Id); end if; return; end if; -- At this point it is known that the Part_Of indicator is legal Legal := True; end Check_Part_Of_Abstract_State; ----------------------------------- -- Check_Part_Of_Concurrent_Type -- ----------------------------------- procedure Check_Part_Of_Concurrent_Type is function In_Proper_Order (First : Node_Id; Second : Node_Id) return Boolean; pragma Inline (In_Proper_Order); -- Determine whether node First precedes node Second procedure Placement_Error; pragma Inline (Placement_Error); -- Emit an error concerning the illegal placement of the item with -- respect to the single concurrent type. --------------------- -- In_Proper_Order -- --------------------- function In_Proper_Order (First : Node_Id; Second : Node_Id) return Boolean is N : Node_Id; begin if List_Containing (First) = List_Containing (Second) then N := First; while Present (N) loop if N = Second then return True; end if; Next (N); end loop; end if; return False; end In_Proper_Order; --------------------- -- Placement_Error -- --------------------- procedure Placement_Error is begin SPARK_Msg_N ("indicator Part_Of must denote a previously declared single " & "protected type or single task type", Encap); end Placement_Error; -- Local variables Conc_Typ : constant Entity_Id := Etype (Encap_Id); Encap_Decl : constant Node_Id := Declaration_Node (Encap_Id); Encap_Context : constant Node_Id := Parent (Encap_Decl); Item_Context : Node_Id; Item_Decl : Node_Id; Prv_Decls : List_Id; Vis_Decls : List_Id; -- Start of processing for Check_Part_Of_Concurrent_Type begin -- Only abstract states and variables can act as constituents of an -- encapsulating single concurrent type. if Ekind_In (Item_Id, E_Abstract_State, E_Variable) then null; -- The constituent is a constant elsif Ekind (Item_Id) = E_Constant then Error_Msg_Name_1 := Chars (Encap_Id); SPARK_Msg_NE (Fix_Msg (Conc_Typ, "constant & cannot act as constituent of " & "single protected type %"), Indic, Item_Id); return; -- The constituent is a package instantiation else Error_Msg_Name_1 := Chars (Encap_Id); SPARK_Msg_NE (Fix_Msg (Conc_Typ, "package instantiation & cannot act as " & "constituent of single protected type %"), Indic, Item_Id); return; end if; -- When the item denotes an abstract state of a nested package, use -- the declaration of the package to detect proper placement. -- package Pack is -- task T; -- package Nested -- with Abstract_State => (State with Part_Of => T) if Ekind (Item_Id) = E_Abstract_State then Item_Decl := Unit_Declaration_Node (Scope (Item_Id)); else Item_Decl := Declaration_Node (Item_Id); end if; Item_Context := Parent (Item_Decl); -- The item and the single concurrent type must appear in the same -- declarative region, with the item following the declaration of -- the single concurrent type (SPARK RM 9(3)). if Item_Context = Encap_Context then if Nkind_In (Item_Context, N_Package_Specification, N_Protected_Definition, N_Task_Definition) then Prv_Decls := Private_Declarations (Item_Context); Vis_Decls := Visible_Declarations (Item_Context); -- The placement is OK when the single concurrent type appears -- within the visible declarations and the item in the private -- declarations. -- -- package Pack is -- protected PO ... -- private -- Constit : ... with Part_Of => PO; -- end Pack; if List_Containing (Encap_Decl) = Vis_Decls and then List_Containing (Item_Decl) = Prv_Decls then null; -- The placement is illegal when the item appears within the -- visible declarations and the single concurrent type is in -- the private declarations. -- -- package Pack is -- Constit : ... with Part_Of => PO; -- private -- protected PO ... -- end Pack; elsif List_Containing (Item_Decl) = Vis_Decls and then List_Containing (Encap_Decl) = Prv_Decls then Placement_Error; return; -- Otherwise both the item and the single concurrent type are -- in the same list. Ensure that the declaration of the single -- concurrent type precedes that of the item. elsif not In_Proper_Order (First => Encap_Decl, Second => Item_Decl) then Placement_Error; return; end if; -- Otherwise both the item and the single concurrent type are -- in the same list. Ensure that the declaration of the single -- concurrent type precedes that of the item. elsif not In_Proper_Order (First => Encap_Decl, Second => Item_Decl) then Placement_Error; return; end if; -- Otherwise the item and the single concurrent type reside within -- unrelated regions. else Error_Msg_Name_1 := Chars (Encap_Id); SPARK_Msg_NE (Fix_Msg (Conc_Typ, "constituent & must be declared " & "immediately within the same region as single protected " & "type %"), Indic, Item_Id); return; end if; -- At this point it is known that the Part_Of indicator is legal Legal := True; end Check_Part_Of_Concurrent_Type; -- Start of processing for Analyze_Part_Of begin -- Assume that the indicator is illegal Encap_Id := Empty; Legal := False; if Nkind_In (Encap, N_Expanded_Name, N_Identifier, N_Selected_Component) then Analyze (Encap); Resolve_State (Encap); Encap_Id := Entity (Encap); -- The encapsulator is an abstract state if Ekind (Encap_Id) = E_Abstract_State then null; -- The encapsulator is a single concurrent type (SPARK RM 9.3) elsif Is_Single_Concurrent_Object (Encap_Id) then null; -- Otherwise the encapsulator is not a legal choice else SPARK_Msg_N ("indicator Part_Of must denote abstract state, single " & "protected type or single task type", Encap); return; end if; -- This is a syntax error, always report else Error_Msg_N ("indicator Part_Of must denote abstract state, single protected " & "type or single task type", Encap); return; end if; -- Catch a case where indicator Part_Of denotes the abstract view of a -- variable which appears as an abstract state (SPARK RM 10.1.2 2). if From_Limited_With (Encap_Id) and then Present (Non_Limited_View (Encap_Id)) and then Ekind (Non_Limited_View (Encap_Id)) = E_Variable then SPARK_Msg_N ("indicator Part_Of must denote abstract state", Encap); SPARK_Msg_N ("\& denotes abstract view of object", Encap); return; end if; -- The encapsulator is an abstract state if Ekind (Encap_Id) = E_Abstract_State then Check_Part_Of_Abstract_State; -- The encapsulator is a single concurrent type else Check_Part_Of_Concurrent_Type; end if; end Analyze_Part_Of; ---------------------------------- -- Analyze_Part_Of_In_Decl_Part -- ---------------------------------- procedure Analyze_Part_Of_In_Decl_Part (N : Node_Id; Freeze_Id : Entity_Id := Empty) is Encap : constant Node_Id := Get_Pragma_Arg (First (Pragma_Argument_Associations (N))); Errors : constant Nat := Serious_Errors_Detected; Var_Decl : constant Node_Id := Find_Related_Context (N); Var_Id : constant Entity_Id := Defining_Entity (Var_Decl); Constits : Elist_Id; Encap_Id : Entity_Id; Legal : Boolean; begin -- Detect any discrepancies between the placement of the variable with -- respect to general state space and the encapsulating state or single -- concurrent type. Analyze_Part_Of (Indic => N, Item_Id => Var_Id, Encap => Encap, Encap_Id => Encap_Id, Legal => Legal); -- The Part_Of indicator turns the variable into a constituent of the -- encapsulating state or single concurrent type. if Legal then pragma Assert (Present (Encap_Id)); Constits := Part_Of_Constituents (Encap_Id); if No (Constits) then Constits := New_Elmt_List; Set_Part_Of_Constituents (Encap_Id, Constits); end if; Append_Elmt (Var_Id, Constits); Set_Encapsulating_State (Var_Id, Encap_Id); -- A Part_Of constituent partially refines an abstract state. This -- property does not apply to protected or task units. if Ekind (Encap_Id) = E_Abstract_State then Set_Has_Partial_Visible_Refinement (Encap_Id); end if; end if; -- Emit a clarification message when the encapsulator is undefined, -- possibly due to contract freezing. if Errors /= Serious_Errors_Detected and then Present (Freeze_Id) and then Has_Undefined_Reference (Encap) then Contract_Freeze_Error (Var_Id, Freeze_Id); end if; end Analyze_Part_Of_In_Decl_Part; -------------------- -- Analyze_Pragma -- -------------------- procedure Analyze_Pragma (N : Node_Id) is Loc : constant Source_Ptr := Sloc (N); Pname : Name_Id := Pragma_Name (N); -- Name of the source pragma, or name of the corresponding aspect for -- pragmas which originate in a source aspect. In the latter case, the -- name may be different from the pragma name. Prag_Id : constant Pragma_Id := Get_Pragma_Id (Pname); Pragma_Exit : exception; -- This exception is used to exit pragma processing completely. It -- is used when an error is detected, and no further processing is -- required. It is also used if an earlier error has left the tree in -- a state where the pragma should not be processed. 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). type Name_List is array (Natural range <>) of Name_Id; type Args_List is array (Natural range <>) of Node_Id; -- Types used for arguments to Check_Arg_Order and Gather_Associations ----------------------- -- Local Subprograms -- ----------------------- function Acc_First (N : Node_Id) return Node_Id; -- Helper function to iterate over arguments given to OpenAcc pragmas function Acc_Next (N : Node_Id) return Node_Id; -- Helper function to iterate over arguments given to OpenAcc pragmas procedure Acquire_Warning_Match_String (Arg : Node_Id); -- Used by pragma Warnings (Off, string), and Warn_As_Error (string) to -- get the given string argument, and place it in Name_Buffer, adding -- leading and trailing asterisks if they are not already present. The -- caller has already checked that Arg is a static string expression. procedure Ada_2005_Pragma; -- Called for pragmas defined in Ada 2005, that are not in Ada 95. In -- Ada 95 mode, these are implementation defined pragmas, so should be -- caught by the No_Implementation_Pragmas restriction. procedure Ada_2012_Pragma; -- Called for pragmas defined in Ada 2012, that are not in Ada 95 or 05. -- In Ada 95 or 05 mode, these are implementation defined pragmas, so -- should be caught by the No_Implementation_Pragmas restriction. procedure Analyze_Depends_Global (Spec_Id : out Entity_Id; Subp_Decl : out Node_Id; Legal : out Boolean); -- Subsidiary to the analysis of pragmas Depends and Global. Verify the -- legality of the placement and related context of the pragma. Spec_Id -- is the entity of the related subprogram. Subp_Decl is the declaration -- of the related subprogram. Sets flag Legal when the pragma is legal. procedure Analyze_If_Present (Id : Pragma_Id); -- Inspect the remainder of the list containing pragma N and look for -- a pragma that matches Id. If found, analyze the pragma. procedure Analyze_Pre_Post_Condition; -- Subsidiary to the analysis of pragmas Precondition and Postcondition procedure Analyze_Refined_Depends_Global_Post (Spec_Id : out Entity_Id; Body_Id : out Entity_Id; Legal : out Boolean); -- Subsidiary routine to the analysis of body pragmas Refined_Depends, -- Refined_Global and Refined_Post. Verify the legality of the placement -- and related context of the pragma. Spec_Id is the entity of the -- related subprogram. Body_Id is the entity of the subprogram body. -- Flag Legal is set when the pragma is legal. procedure Analyze_Unmodified_Or_Unused (Is_Unused : Boolean := False); -- Perform full analysis of pragma Unmodified and the write aspect of -- pragma Unused. Flag Is_Unused should be set when verifying the -- semantics of pragma Unused. procedure Analyze_Unreferenced_Or_Unused (Is_Unused : Boolean := False); -- Perform full analysis of pragma Unreferenced and the read aspect of -- pragma Unused. Flag Is_Unused should be set when verifying the -- semantics of pragma Unused. 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 Pragma_Exit. 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_External_Name (Arg : Node_Id); -- Check that an argument has the right form for an EXTERNAL_NAME -- parameter of an extended import/export pragma. The rule is that the -- name must be an identifier or string literal (in Ada 83 mode) or a -- static string expression (in Ada 95 mode). 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_Partition_Elaboration_Policy (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a valid -- elaboration 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); procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3, N4 : Name_Id); procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3, N4, N5 : Name_Id); -- Check the specified argument Arg to make sure that it is an -- identifier whose name matches either N1 or N2 (or N3, N4, N5 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_OK_Static_Expression (Arg : Node_Id; Typ : Entity_Id := Empty); -- 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. If -- Typ is left Empty, then any static expression is allowed. Includes -- checking that the argument does not raise Constraint_Error. procedure Check_Arg_Is_Task_Dispatching_Policy (Arg : Node_Id); -- Check the specified argument Arg to make sure that it is a valid task -- dispatching policy name. If not give error and raise Pragma_Exit. procedure Check_Arg_Order (Names : Name_List); -- Checks for an instance of two arguments with identifiers for the -- current pragma which are not in the sequence indicated by Names, -- and if so, generates a fatal message about bad order of arguments. 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_Component (Comp : Node_Id; UU_Typ : Entity_Id; In_Variant_Part : Boolean := False); -- Examine an Unchecked_Union component for correct use of per-object -- constrained subtypes, and for restrictions on finalizable components. -- UU_Typ is the related Unchecked_Union type. Flag In_Variant_Part -- should be set when Comp comes from a record variant. procedure Check_Duplicate_Pragma (E : Entity_Id); -- Check if a rep item of the same name as the current pragma is already -- chained as a rep pragma to the given entity. If so give a message -- about the duplicate, and then raise Pragma_Exit so does not return. -- Note that if E is a type, then this routine avoids flagging a pragma -- which applies to a parent type from which E is derived. procedure Check_Duplicated_Export_Name (Nam : Node_Id); -- Nam is an N_String_Literal node containing the external name set by -- an Import or Export pragma (or extended Import or Export pragma). -- This procedure checks for possible duplications if this is the export -- case, and if found, issues an appropriate error message. procedure Check_Expr_Is_OK_Static_Expression (Expr : Node_Id; Typ : Entity_Id := Empty); -- Check the specified expression Expr 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. If -- Typ is left Empty, then any static expression is allowed. Includes -- checking that the expression does not raise Constraint_Error. procedure Check_First_Subtype (Arg : Node_Id); -- Checks that Arg, whose expression is an entity name, references a -- first subtype. procedure Check_Identifier (Arg : Node_Id; Id : Name_Id); -- Checks that the given argument has an identifier, and if so, requires -- it to match the given identifier name. If there is no identifier, or -- a non-matching identifier, then an error message is given and -- Pragma_Exit is raised. procedure Check_Identifier_Is_One_Of (Arg : Node_Id; N1, N2 : Name_Id); -- Checks that the given argument has an identifier, and if so, requires -- it to match one of the given identifier names. If there is no -- identifier, or a non-matching identifier, then an error message is -- given and Pragma_Exit is raised. procedure Check_In_Main_Program; -- Common checks for pragmas that appear within a main program -- (Priority, Main_Storage, Time_Slice, Relative_Deadline, CPU). procedure Check_Interrupt_Or_Attach_Handler; -- Common processing for first argument of pragma Interrupt_Handler or -- pragma Attach_Handler. procedure Check_Loop_Pragma_Placement; -- Verify whether pragmas Loop_Invariant, Loop_Optimize and Loop_Variant -- appear immediately within a construct restricted to loops, and that -- pragmas Loop_Invariant and Loop_Variant are grouped together. 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_No_Link_Name; -- Checks that no link name is specified 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 Pragma_Exit is 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 Pragma_Exit is raised. -- In this version of the procedure, the identifier name is given as -- a string with lower case letters. procedure Check_Static_Boolean_Expression (Expr : Node_Id); -- Subsidiary to the analysis of pragmas Async_Readers, Async_Writers, -- Constant_After_Elaboration, Effective_Reads, Effective_Writes, -- Extensions_Visible and Volatile_Function. Ensure that expression Expr -- is an OK static boolean expression. Emit an error if this is not the -- case. 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 Check_Variant (Variant : Node_Id; UU_Typ : Entity_Id); -- Check an Unchecked_Union variant for lack of nested variants and -- presence of at least one component. UU_Typ is the related Unchecked_ -- Union type. procedure Ensure_Aggregate_Form (Arg : Node_Id); -- Subsidiary routine to the processing of pragmas Abstract_State, -- Contract_Cases, Depends, Global, Initializes, Refined_Depends, -- Refined_Global and Refined_State. Transform argument Arg into -- an aggregate if not one already. N_Null is never transformed. -- Arg may denote an aspect specification or a pragma argument -- association. procedure Error_Pragma (Msg : String); pragma No_Return (Error_Pragma); -- Outputs error message for current pragma. The message contains a % -- that will be replaced with the pragma name, and the flag is placed -- on the pragma itself. Pragma_Exit is then raised. Note: this routine -- calls Fix_Error (see spec of that procedure for details). 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. Note: this routine -- calls Fix_Error (see spec of that procedure for details). 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. -- Note: this routine calls Fix_Error (see spec of that procedure for -- details). procedure Error_Pragma_Ref (Msg : String; Ref : Entity_Id); pragma No_Return (Error_Pragma_Ref); -- Outputs error message for current pragma. The message may contain -- a % that will be replaced with the pragma name. The parameter Ref -- must be an entity whose name can be referenced by & and sloc by #. -- After placing the message, Pragma_Exit is raised. Note: this routine -- calls Fix_Error (see spec of that procedure for details). 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. function Find_Unique_Parameterless_Procedure (Name : Entity_Id; Arg : Node_Id) return Entity_Id; -- Used for a procedure pragma to find the unique parameterless -- procedure identified by Name, returns it if it exists, otherwise -- errors out and uses Arg as the pragma argument for the message. function Fix_Error (Msg : String) return String; -- This is called prior to issuing an error message. Msg is the normal -- error message issued in the pragma case. This routine checks for the -- case of a pragma coming from an aspect in the source, and returns a -- message suitable for the aspect case as follows: -- -- Each substring "pragma" is replaced by "aspect" -- -- If "argument of" is at the start of the error message text, it is -- replaced by "entity for". -- -- If "argument" is at the start of the error message text, it is -- replaced by "entity". -- -- So for example, "argument of pragma X must be discrete type" -- returns "entity for aspect X must be a discrete type". -- Finally Error_Msg_Name_1 is set to the name of the aspect (which may -- be different from the pragma name). If the current pragma results -- from rewriting another pragma, then Error_Msg_Name_1 is set to the -- original pragma name. 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. procedure GNAT_Pragma; -- Called for all GNAT defined pragmas to 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; -- Determines if the placement of the current pragma is appropriate -- for a configuration pragma. function Is_In_Context_Clause return Boolean; -- Returns True if pragma appears within the context clause of a unit, -- and False for any other placement (does not generate any messages). function Is_Static_String_Expression (Arg : Node_Id) return Boolean; -- Analyzes the argument, and determines if it is a static string -- expression, returns True if so, False if non-static or not String. -- A special case is that a string literal returns True in Ada 83 mode -- (which has no such thing as static string expressions). Note that -- the call analyzes its argument, so this cannot be used for the case -- where an identifier might not be declared. procedure Pragma_Misplaced; pragma No_Return (Pragma_Misplaced); -- Issue fatal error message for misplaced pragma procedure Process_Atomic_Independent_Shared_Volatile; -- Common processing for pragmas Atomic, Independent, Shared, Volatile, -- Volatile_Full_Access. Note that Shared is an obsolete Ada 83 pragma -- and treated as being identical in effect to pragma Atomic. procedure Process_Compile_Time_Warning_Or_Error; -- Common processing for Compile_Time_Error and Compile_Time_Warning procedure Process_Convention (C : out Convention_Id; Ent : out Entity_Id); -- Common processing 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, Ent is the referenced entity. procedure Process_Disable_Enable_Atomic_Sync (Nam : Name_Id); -- Common processing for Disable/Enable_Atomic_Synchronization. Nam is -- Name_Suppress for Disable and Name_Unsuppress for Enable. procedure Process_Extended_Import_Export_Object_Pragma (Arg_Internal : Node_Id; Arg_External : Node_Id; Arg_Size : Node_Id); -- Common processing for the pragmas 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); -- Common processing for all extended Import and Export pragmas applying -- to subprograms. The caller omits any arguments that do not 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 or Interface procedure Process_Import_Predefined_Type; -- Processing for completing a type with pragma Import. This is used -- to declare types that match predefined C types, especially for cases -- without corresponding Ada predefined type. type Inline_Status is (Suppressed, Disabled, Enabled); -- Inline status of a subprogram, indicated as follows: -- Suppressed: inlining is suppressed for the subprogram -- Disabled: no inlining is requested for the subprogram -- Enabled: inlining is requested/required for the subprogram procedure Process_Inline (Status : Inline_Status); -- Common processing for No_Inline, Inline and Inline_Always. Parameter -- indicates the inline status specified by the pragma. procedure Process_Interface_Name (Subprogram_Def : Entity_Id; Ext_Arg : Node_Id; Link_Arg : Node_Id; Prag : 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. In addition, the pragma itself is passed -- to analyze any expressions in the case the pragma came from an aspect -- specification. procedure Process_Interrupt_Or_Attach_Handler; -- Common processing for Interrupt and Attach_Handler pragmas procedure Process_Restrictions_Or_Restriction_Warnings (Warn : Boolean); -- Common processing for Restrictions and Restriction_Warnings pragmas. -- Warn is True for Restriction_Warnings, or for Restrictions if the -- flag Treat_Restrictions_As_Warnings is set, and False if this flag -- is not set in the Restrictions case. 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 Record_Independence_Check (N : Node_Id; E : Entity_Id); -- Subsidiary to the analysis of pragmas Independent[_Components]. -- Record such a pragma N applied to entity E for future checks. 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. procedure Set_Rational_Profile; -- Activate the set of configuration pragmas and permissions that make -- up the Rational profile. procedure Set_Ravenscar_Profile (Profile : Profile_Name; N : Node_Id); -- Activate the set of configuration pragmas and restrictions that make -- up the Profile. Profile must be either GNAT_Extended_Ravenscar, -- GNAT_Ravenscar_EDF, or Ravenscar. N is the corresponding pragma node, -- which is used for error messages on any constructs violating the -- profile. procedure Validate_Acc_Condition_Clause (Clause : Node_Id); -- Make sure the argument of a given Acc_If clause is a Boolean procedure Validate_Acc_Data_Clause (Clause : Node_Id); -- Make sure the argument of an OpenAcc data clause (e.g. Copy, Copyin, -- Copyout...) is an identifier or an aggregate of identifiers. procedure Validate_Acc_Int_Expr_Clause (Clause : Node_Id); -- Make sure the argument of an OpenAcc clause is an Integer expression procedure Validate_Acc_Int_Expr_List_Clause (Clause : Node_Id); -- Make sure the argument of an OpenAcc clause is an Integer expression -- or a list of Integer expressions. procedure Validate_Acc_Loop_Collapse (Clause : Node_Id); -- Make sure that the parent loop of the Acc_Loop(Collapse => N) pragma -- contains at least N-1 nested loops. procedure Validate_Acc_Loop_Gang (Clause : Node_Id); -- Make sure the argument of the Gang clause of a Loop directive is -- either an integer expression or a (Static => integer expressions) -- aggregate. procedure Validate_Acc_Loop_Vector (Clause : Node_Id); -- When this procedure is called in a construct offloaded by an -- Acc_Kernels pragma, makes sure that a Vector_Length clause does -- not exist on said pragma. In all cases, make sure the argument -- is an Integer expression. procedure Validate_Acc_Loop_Worker (Clause : Node_Id); -- When this procedure is called in a construct offloaded by an -- Acc_Parallel pragma, makes sure that no argument has been given. -- When this procedure is called in a construct offloaded by an -- Acc_Kernels pragma and if Loop_Worker was given an argument, -- makes sure that the Num_Workers clause does not appear on the -- Acc_Kernels pragma and that the argument is an integer. procedure Validate_Acc_Name_Reduction (Clause : Node_Id); -- Make sure the reduction clause is an aggregate made of a string -- representing a supported reduction operation (i.e. "+", "*", "and", -- "or", "min" or "max") and either an identifier or aggregate of -- identifiers. procedure Validate_Acc_Size_Expressions (Clause : Node_Id); -- Makes sure that Clause is either an integer expression or an -- association with a Static as name and a list of integer expressions -- or "*" strings on the right hand side. --------------- -- Acc_First -- --------------- function Acc_First (N : Node_Id) return Node_Id is begin if Nkind (N) = N_Aggregate then if Present (Expressions (N)) then return First (Expressions (N)); elsif Present (Component_Associations (N)) then return Expression (First (Component_Associations (N))); end if; end if; return N; end Acc_First; -------------- -- Acc_Next -- -------------- function Acc_Next (N : Node_Id) return Node_Id is begin if Nkind (Parent (N)) = N_Component_Association then return Expression (Next (Parent (N))); elsif Nkind (Parent (N)) = N_Aggregate then return Next (N); else return Empty; end if; end Acc_Next; ---------------------------------- -- Acquire_Warning_Match_String -- ---------------------------------- procedure Acquire_Warning_Match_String (Arg : Node_Id) is begin String_To_Name_Buffer (Strval (Expr_Value_S (Get_Pragma_Arg (Arg)))); -- Add asterisk at start if not already there if Name_Len > 0 and then Name_Buffer (1) /= '*' then Name_Buffer (2 .. Name_Len + 1) := Name_Buffer (1 .. Name_Len); Name_Buffer (1) := '*'; Name_Len := Name_Len + 1; end if; -- Add asterisk at end if not already there if Name_Buffer (Name_Len) /= '*' then Name_Len := Name_Len + 1; Name_Buffer (Name_Len) := '*'; end if; end Acquire_Warning_Match_String; --------------------- -- Ada_2005_Pragma -- --------------------- procedure Ada_2005_Pragma is begin if Ada_Version <= Ada_95 then Check_Restriction (No_Implementation_Pragmas, N); end if; end Ada_2005_Pragma; --------------------- -- Ada_2012_Pragma -- --------------------- procedure Ada_2012_Pragma is begin if Ada_Version <= Ada_2005 then Check_Restriction (No_Implementation_Pragmas, N); end if; end Ada_2012_Pragma; ---------------------------- -- Analyze_Depends_Global -- ---------------------------- procedure Analyze_Depends_Global (Spec_Id : out Entity_Id; Subp_Decl : out Node_Id; Legal : out Boolean) is begin -- Assume that the pragma is illegal Spec_Id := Empty; Subp_Decl := Empty; Legal := False; GNAT_Pragma; Check_Arg_Count (1); -- Ensure the proper placement of the pragma. Depends/Global must be -- associated with a subprogram declaration or a body that acts as a -- spec. Subp_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); -- Entry if Nkind (Subp_Decl) = N_Entry_Declaration then null; -- Generic subprogram elsif Nkind (Subp_Decl) = N_Generic_Subprogram_Declaration then null; -- Object declaration of a single concurrent type elsif Nkind (Subp_Decl) = N_Object_Declaration and then Is_Single_Concurrent_Object (Unique_Defining_Entity (Subp_Decl)) then null; -- Single task type elsif Nkind (Subp_Decl) = N_Single_Task_Declaration then null; -- Subprogram body acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body and then No (Corresponding_Spec (Subp_Decl)) then null; -- Subprogram body stub acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body_Stub and then No (Corresponding_Spec_Of_Stub (Subp_Decl)) then null; -- Subprogram declaration elsif Nkind (Subp_Decl) = N_Subprogram_Declaration then null; -- Task type elsif Nkind (Subp_Decl) = N_Task_Type_Declaration then null; else Pragma_Misplaced; return; end if; -- If we get here, then the pragma is legal Legal := True; Spec_Id := Unique_Defining_Entity (Subp_Decl); -- When the related context is an entry, the entry must belong to a -- protected unit (SPARK RM 6.1.4(6)). if Is_Entry_Declaration (Spec_Id) and then Ekind (Scope (Spec_Id)) /= E_Protected_Type then Pragma_Misplaced; return; -- When the related context is an anonymous object created for a -- simple concurrent type, the type must be a task -- (SPARK RM 6.1.4(6)). elsif Is_Single_Concurrent_Object (Spec_Id) and then Ekind (Etype (Spec_Id)) /= E_Task_Type then Pragma_Misplaced; return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Spec_Id); Ensure_Aggregate_Form (Get_Argument (N, Spec_Id)); end Analyze_Depends_Global; ------------------------ -- Analyze_If_Present -- ------------------------ procedure Analyze_If_Present (Id : Pragma_Id) is Stmt : Node_Id; begin pragma Assert (Is_List_Member (N)); -- Inspect the declarations or statements following pragma N looking -- for another pragma whose Id matches the caller's request. If it is -- available, analyze it. Stmt := Next (N); while Present (Stmt) loop if Nkind (Stmt) = N_Pragma and then Get_Pragma_Id (Stmt) = Id then Analyze_Pragma (Stmt); exit; -- The first source declaration or statement immediately following -- N ends the region where a pragma may appear. elsif Comes_From_Source (Stmt) then exit; end if; Next (Stmt); end loop; end Analyze_If_Present; -------------------------------- -- Analyze_Pre_Post_Condition -- -------------------------------- procedure Analyze_Pre_Post_Condition is Prag_Iden : constant Node_Id := Pragma_Identifier (N); Subp_Decl : Node_Id; Subp_Id : Entity_Id; Duplicates_OK : Boolean := False; -- Flag set when a pre/postcondition allows multiple pragmas of the -- same kind. In_Body_OK : Boolean := False; -- Flag set when a pre/postcondition is allowed to appear on a body -- even though the subprogram may have a spec. Is_Pre_Post : Boolean := False; -- Flag set when the pragma is one of Pre, Pre_Class, Post or -- Post_Class. function Inherits_Class_Wide_Pre (E : Entity_Id) return Boolean; -- Implement rules in AI12-0131: an overriding operation can have -- a class-wide precondition only if one of its ancestors has an -- explicit class-wide precondition. ----------------------------- -- Inherits_Class_Wide_Pre -- ----------------------------- function Inherits_Class_Wide_Pre (E : Entity_Id) return Boolean is Typ : constant Entity_Id := Find_Dispatching_Type (E); Cont : Node_Id; Prag : Node_Id; Prev : Entity_Id := Overridden_Operation (E); begin -- Check ancestors on the overriding operation to examine the -- preconditions that may apply to them. while Present (Prev) loop Cont := Contract (Prev); if Present (Cont) then Prag := Pre_Post_Conditions (Cont); while Present (Prag) loop if Pragma_Name (Prag) = Name_Precondition and then Class_Present (Prag) then return True; end if; Prag := Next_Pragma (Prag); end loop; end if; -- For a type derived from a generic formal type, the operation -- inheriting the condition is a renaming, not an overriding of -- the operation of the formal. Ditto for an inherited -- operation which has no explicit contracts. if Is_Generic_Type (Find_Dispatching_Type (Prev)) or else not Comes_From_Source (Prev) then Prev := Alias (Prev); else Prev := Overridden_Operation (Prev); end if; end loop; -- If the controlling type of the subprogram has progenitors, an -- interface operation implemented by the current operation may -- have a class-wide precondition. if Has_Interfaces (Typ) then declare Elmt : Elmt_Id; Ints : Elist_Id; Prim : Entity_Id; Prim_Elmt : Elmt_Id; Prim_List : Elist_Id; begin Collect_Interfaces (Typ, Ints); Elmt := First_Elmt (Ints); -- Iterate over the primitive operations of each interface while Present (Elmt) loop Prim_List := Direct_Primitive_Operations (Node (Elmt)); Prim_Elmt := First_Elmt (Prim_List); while Present (Prim_Elmt) loop Prim := Node (Prim_Elmt); if Chars (Prim) = Chars (E) and then Present (Contract (Prim)) and then Class_Present (Pre_Post_Conditions (Contract (Prim))) then return True; end if; Next_Elmt (Prim_Elmt); end loop; Next_Elmt (Elmt); end loop; end; end if; return False; end Inherits_Class_Wide_Pre; -- Start of processing for Analyze_Pre_Post_Condition begin -- Change the name of pragmas Pre, Pre_Class, Post and Post_Class to -- offer uniformity among the various kinds of pre/postconditions by -- rewriting the pragma identifier. This allows the retrieval of the -- original pragma name by routine Original_Aspect_Pragma_Name. if Comes_From_Source (N) then if Nam_In (Pname, Name_Pre, Name_Pre_Class) then Is_Pre_Post := True; Set_Class_Present (N, Pname = Name_Pre_Class); Rewrite (Prag_Iden, Make_Identifier (Loc, Name_Precondition)); elsif Nam_In (Pname, Name_Post, Name_Post_Class) then Is_Pre_Post := True; Set_Class_Present (N, Pname = Name_Post_Class); Rewrite (Prag_Iden, Make_Identifier (Loc, Name_Postcondition)); end if; end if; -- Determine the semantics with respect to duplicates and placement -- in a body. Pragmas Precondition and Postcondition were introduced -- before aspects and are not subject to the same aspect-like rules. if Nam_In (Pname, Name_Precondition, Name_Postcondition) then Duplicates_OK := True; In_Body_OK := True; end if; GNAT_Pragma; -- Pragmas Pre, Pre_Class, Post and Post_Class allow for a single -- argument without an identifier. if Is_Pre_Post then Check_Arg_Count (1); Check_No_Identifiers; -- Pragmas Precondition and Postcondition have complex argument -- profile. else Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); Check_Optional_Identifier (Arg1, Name_Check); if Present (Arg2) then Check_Optional_Identifier (Arg2, Name_Message); Preanalyze_Spec_Expression (Get_Pragma_Arg (Arg2), Standard_String); end if; end if; -- For a pragma PPC in the extended main source unit, record enabled -- status in SCO. -- ??? nothing checks that the pragma is in the main source unit if Is_Checked (N) and then not Split_PPC (N) then Set_SCO_Pragma_Enabled (Loc); end if; -- Ensure the proper placement of the pragma Subp_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => not Duplicates_OK); -- When a pre/postcondition pragma applies to an abstract subprogram, -- its original form must be an aspect with 'Class. if Nkind (Subp_Decl) = N_Abstract_Subprogram_Declaration then if not From_Aspect_Specification (N) then Error_Pragma ("pragma % cannot be applied to abstract subprogram"); elsif not Class_Present (N) then Error_Pragma ("aspect % requires ''Class for abstract subprogram"); end if; -- Entry declaration elsif Nkind (Subp_Decl) = N_Entry_Declaration then null; -- Generic subprogram declaration elsif Nkind (Subp_Decl) = N_Generic_Subprogram_Declaration then null; -- Subprogram body elsif Nkind (Subp_Decl) = N_Subprogram_Body and then (No (Corresponding_Spec (Subp_Decl)) or In_Body_OK) then null; -- Subprogram body stub elsif Nkind (Subp_Decl) = N_Subprogram_Body_Stub and then (No (Corresponding_Spec_Of_Stub (Subp_Decl)) or In_Body_OK) then null; -- Subprogram declaration elsif Nkind (Subp_Decl) = N_Subprogram_Declaration then -- AI05-0230: When a pre/postcondition pragma applies to a null -- procedure, its original form must be an aspect with 'Class. if Nkind (Specification (Subp_Decl)) = N_Procedure_Specification and then Null_Present (Specification (Subp_Decl)) and then From_Aspect_Specification (N) and then not Class_Present (N) then Error_Pragma ("aspect % requires ''Class for null procedure"); end if; -- Implement the legality checks mandated by AI12-0131: -- Pre'Class shall not be specified for an overriding primitive -- subprogram of a tagged type T unless the Pre'Class aspect is -- specified for the corresponding primitive subprogram of some -- ancestor of T. declare E : constant Entity_Id := Defining_Entity (Subp_Decl); begin if Class_Present (N) and then Pragma_Name (N) = Name_Precondition and then Present (Overridden_Operation (E)) and then not Inherits_Class_Wide_Pre (E) then Error_Msg_N ("illegal class-wide precondition on overriding operation", Corresponding_Aspect (N)); end if; end; -- A renaming declaration may inherit a generated pragma, its -- placement comes from expansion, not from source. elsif Nkind (Subp_Decl) = N_Subprogram_Renaming_Declaration and then not Comes_From_Source (N) then null; -- Otherwise the placement is illegal else Pragma_Misplaced; return; end if; Subp_Id := Defining_Entity (Subp_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Subp_Id); -- Chain the pragma on the contract for further processing by -- Analyze_Pre_Post_Condition_In_Decl_Part. Add_Contract_Item (N, Defining_Entity (Subp_Decl)); -- Fully analyze the pragma when it appears inside an entry or -- subprogram body because it cannot benefit from forward references. if Nkind_In (Subp_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub) then -- The legality checks of pragmas Precondition and Postcondition -- are affected by the SPARK mode in effect and the volatility of -- the context. Analyze all pragmas in a specific order. Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Pre_Post_Condition_In_Decl_Part (N); end if; end Analyze_Pre_Post_Condition; ----------------------------------------- -- Analyze_Refined_Depends_Global_Post -- ----------------------------------------- procedure Analyze_Refined_Depends_Global_Post (Spec_Id : out Entity_Id; Body_Id : out Entity_Id; Legal : out Boolean) is Body_Decl : Node_Id; Spec_Decl : Node_Id; begin -- Assume that the pragma is illegal Spec_Id := Empty; Body_Id := Empty; Legal := False; GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; -- Verify the placement of the pragma and check for duplicates. The -- pragma must apply to a subprogram body [stub]. Body_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); if not Nkind_In (Body_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub, N_Task_Body, N_Task_Body_Stub) then Pragma_Misplaced; return; end if; Body_Id := Defining_Entity (Body_Decl); Spec_Id := Unique_Defining_Entity (Body_Decl); -- The pragma must apply to the second declaration of a subprogram. -- In other words, the body [stub] cannot acts as a spec. if No (Spec_Id) then Error_Pragma ("pragma % cannot apply to a stand alone body"); return; -- Catch the case where the subprogram body is a subunit and acts as -- the third declaration of the subprogram. elsif Nkind (Parent (Body_Decl)) = N_Subunit then Error_Pragma ("pragma % cannot apply to a subunit"); return; end if; -- A refined pragma can only apply to the body [stub] of a subprogram -- declared in the visible part of a package. Retrieve the context of -- the subprogram declaration. Spec_Decl := Unit_Declaration_Node (Spec_Id); -- When dealing with protected entries or protected subprograms, use -- the enclosing protected type as the proper context. if Ekind_In (Spec_Id, E_Entry, E_Entry_Family, E_Function, E_Procedure) and then Ekind (Scope (Spec_Id)) = E_Protected_Type then Spec_Decl := Declaration_Node (Scope (Spec_Id)); end if; if Nkind (Parent (Spec_Decl)) /= N_Package_Specification then Error_Pragma (Fix_Msg (Spec_Id, "pragma % must apply to the body of " & "subprogram declared in a package specification")); return; end if; -- If we get here, then the pragma is legal Legal := True; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Spec_Id); if Nam_In (Pname, Name_Refined_Depends, Name_Refined_Global) then Ensure_Aggregate_Form (Get_Argument (N, Spec_Id)); end if; end Analyze_Refined_Depends_Global_Post; ---------------------------------- -- Analyze_Unmodified_Or_Unused -- ---------------------------------- procedure Analyze_Unmodified_Or_Unused (Is_Unused : Boolean := False) is Arg : Node_Id; Arg_Expr : Node_Id; Arg_Id : Entity_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost variables is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost variable encountered while -- processing the arguments of the pragma. begin GNAT_Pragma; Check_At_Least_N_Arguments (1); -- Loop through arguments Arg := Arg1; while Present (Arg) loop Check_No_Identifier (Arg); -- Note: the analyze call done by Check_Arg_Is_Local_Name will -- in fact generate 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); Arg_Expr := Get_Pragma_Arg (Arg); if Is_Entity_Name (Arg_Expr) then Arg_Id := Entity (Arg_Expr); -- Skip processing the argument if already flagged if Is_Assignable (Arg_Id) and then not Has_Pragma_Unmodified (Arg_Id) and then not Has_Pragma_Unused (Arg_Id) then Set_Has_Pragma_Unmodified (Arg_Id); if Is_Unused then Set_Has_Pragma_Unused (Arg_Id); end if; -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored -- Ghost code. Mark_Ghost_Pragma (N, Arg_Id); -- Capture the entity of the first Ghost variable being -- processed for error detection purposes. if Is_Ghost_Entity (Arg_Id) then if No (Ghost_Id) then Ghost_Id := Arg_Id; end if; -- Otherwise the variable is non-Ghost. It is illegal to mix -- references to Ghost and non-Ghost entities -- (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and non-ghost " & "variables", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (Arg_Id); Error_Msg_NE ("\& # declared as non-ghost", N, Arg_Id); end if; -- Warn if already flagged as Unused or Unmodified elsif Has_Pragma_Unmodified (Arg_Id) then if Has_Pragma_Unused (Arg_Id) then Error_Msg_NE ("??pragma Unused already given for &!", Arg_Expr, Arg_Id); else Error_Msg_NE ("??pragma Unmodified already given for &!", Arg_Expr, Arg_Id); end if; -- Otherwise the pragma referenced an illegal entity else Error_Pragma_Arg ("pragma% can only be applied to a variable", Arg_Expr); end if; end if; Next (Arg); end loop; end Analyze_Unmodified_Or_Unused; ------------------------------------ -- Analyze_Unreferenced_Or_Unused -- ------------------------------------ procedure Analyze_Unreferenced_Or_Unused (Is_Unused : Boolean := False) is Arg : Node_Id; Arg_Expr : Node_Id; Arg_Id : Entity_Id; Citem : Node_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost names is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost name encountered while processing -- the arguments of the pragma. begin GNAT_Pragma; Check_At_Least_N_Arguments (1); -- Check case of appearing within context clause if not Is_Unused and then Is_In_Context_Clause then -- The arguments must all be units mentioned in a with clause in -- the same context clause. Note that Par.Prag already checked -- that the arguments are either identifiers or selected -- components. Arg := Arg1; while Present (Arg) loop Citem := First (List_Containing (N)); while Citem /= N loop Arg_Expr := Get_Pragma_Arg (Arg); if Nkind (Citem) = N_With_Clause and then Same_Name (Name (Citem), Arg_Expr) then Set_Has_Pragma_Unreferenced (Cunit_Entity (Get_Source_Unit (Library_Unit (Citem)))); Set_Elab_Unit_Name (Arg_Expr, Name (Citem)); exit; end if; Next (Citem); end loop; if Citem = N then Error_Pragma_Arg ("argument of pragma% is not withed unit", Arg); end if; Next (Arg); end loop; -- Case of not in list of context items else Arg := Arg1; while Present (Arg) loop Check_No_Identifier (Arg); -- Note: the analyze call done by Check_Arg_Is_Local_Name will -- in fact generate 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); Arg_Expr := Get_Pragma_Arg (Arg); if Is_Entity_Name (Arg_Expr) then Arg_Id := Entity (Arg_Expr); -- Warn if already flagged as Unused or Unreferenced and -- skip processing the argument. if Has_Pragma_Unreferenced (Arg_Id) then if Has_Pragma_Unused (Arg_Id) then Error_Msg_NE ("??pragma Unused already given for &!", Arg_Expr, Arg_Id); else Error_Msg_NE ("??pragma Unreferenced already given for &!", Arg_Expr, Arg_Id); end if; -- Apply Unreferenced to the entity else -- 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_Id, N); end if; Set_Has_Pragma_Unreferenced (Arg_Id); if Is_Unused then Set_Has_Pragma_Unused (Arg_Id); end if; -- A pragma that applies to a Ghost entity becomes Ghost -- for the purposes of legality checks and removal of -- ignored Ghost code. Mark_Ghost_Pragma (N, Arg_Id); -- Capture the entity of the first Ghost name being -- processed for error detection purposes. if Is_Ghost_Entity (Arg_Id) then if No (Ghost_Id) then Ghost_Id := Arg_Id; end if; -- Otherwise the name is non-Ghost. It is illegal to mix -- references to Ghost and non-Ghost entities -- (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and non-ghost " & "names", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (Arg_Id); Error_Msg_NE ("\& # declared as non-ghost", N, Arg_Id); end if; end if; end if; Next (Arg); end loop; end if; end Analyze_Unreferenced_Or_Unused; -------------------------- -- Check_Ada_83_Warning -- -------------------------- procedure Check_Ada_83_Warning is begin if Ada_Version = 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_External_Name -- -------------------------------- procedure Check_Arg_Is_External_Name (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin if Nkind (Argx) = N_Identifier then return; else Analyze_And_Resolve (Argx, Standard_String); 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 expected Ada 83 mode -- use of external names which are string literals, even though -- technically these are not static in Ada 83. elsif Ada_Version = Ada_83 and then Nkind (Argx) = N_String_Literal then return; -- Here we have a real error (non-static expression) else Error_Msg_Name_1 := Pname; Flag_Non_Static_Expr (Fix_Error ("argument for pragma% must be a identifier or " & "static string expression!"), Argx); raise Pragma_Exit; end if; end if; end Check_Arg_Is_External_Name; ----------------------------- -- 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 it came from an aspect, we want to give the error just as if it -- came from source. if not Is_Library_Level_Entity (Entity (Get_Pragma_Arg (Arg))) and then (Comes_From_Source (N) or else Present (Corresponding_Aspect (Parent (Arg)))) 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 -- If this pragma came from an aspect specification, we don't want to -- check for this error, because that would cause spurious errors, in -- case a type is frozen in a scope more nested than the type. The -- aspect itself of course can't be anywhere but on the declaration -- itself. if Nkind (Arg) = N_Pragma_Argument_Association then if From_Aspect_Specification (Parent (Arg)) then return; end if; -- Arg is the Expression of an N_Pragma_Argument_Association else if From_Aspect_Specification (Parent (Parent (Arg))) then return; end if; end if; 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; -- No further check required if not an entity name if not Is_Entity_Name (Argx) then null; else declare OK : Boolean; Ent : constant Entity_Id := Entity (Argx); Scop : constant Entity_Id := Scope (Ent); begin -- Case of a pragma applied to a compilation unit: pragma must -- occur immediately after the program unit in the compilation. if Is_Compilation_Unit (Ent) then declare Decl : constant Node_Id := Unit_Declaration_Node (Ent); begin -- Case of pragma placed immediately after spec if Parent (N) = Aux_Decls_Node (Parent (Decl)) then OK := True; -- Case of pragma placed immediately after body elsif Nkind (Decl) = N_Subprogram_Declaration and then Present (Corresponding_Body (Decl)) then OK := Parent (N) = Aux_Decls_Node (Parent (Unit_Declaration_Node (Corresponding_Body (Decl)))); -- All other cases are illegal else OK := False; end if; end; -- Special restricted placement rule from 10.2.1(11.8/2) elsif Is_Generic_Formal (Ent) and then Prag_Id = Pragma_Preelaborable_Initialization then OK := List_Containing (N) = Generic_Formal_Declarations (Unit_Declaration_Node (Scop)); -- If this is an aspect applied to a subprogram body, the -- pragma is inserted in its declarative part. elsif From_Aspect_Specification (N) and then Ent = Current_Scope and then Nkind (Unit_Declaration_Node (Ent)) = N_Subprogram_Body then OK := True; -- If the aspect is a predicate (possibly others ???) and the -- context is a record type, this is a discriminant expression -- within a type declaration, that freezes the predicated -- subtype. elsif From_Aspect_Specification (N) and then Prag_Id = Pragma_Predicate and then Ekind (Current_Scope) = E_Record_Type and then Scop = Scope (Current_Scope) then OK := True; -- Default case, just check that the pragma occurs in the scope -- of the entity denoted by the name. else OK := Current_Scope = Scop; end if; if not OK then Error_Pragma_Arg ("pragma% argument must be in same declarative part", Arg); end if; end; 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_Partition_Elaboration_Policy -- ----------------------------------------------- procedure Check_Arg_Is_Partition_Elaboration_Policy (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Is_Partition_Elaboration_Policy_Name (Chars (Argx)) then Error_Pragma_Arg ("& is not a valid partition elaboration policy name", Argx); end if; end Check_Arg_Is_Partition_Elaboration_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 not Nam_In (Chars (Argx), N1, 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 not Nam_In (Chars (Argx), N1, N2, N3) then Error_Pragma_Arg ("invalid argument for pragma%", Argx); end if; end Check_Arg_Is_One_Of; procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3, N4 : Name_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Nam_In (Chars (Argx), N1, N2, N3, N4) then Error_Pragma_Arg ("invalid argument for pragma%", Argx); end if; end Check_Arg_Is_One_Of; procedure Check_Arg_Is_One_Of (Arg : Node_Id; N1, N2, N3, N4, N5 : Name_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Arg_Is_Identifier (Argx); if not Nam_In (Chars (Argx), N1, N2, N3, N4, N5) 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_OK_Static_Expression -- --------------------------------------- procedure Check_Arg_Is_OK_Static_Expression (Arg : Node_Id; Typ : Entity_Id := Empty) is begin Check_Expr_Is_OK_Static_Expression (Get_Pragma_Arg (Arg), Typ); end Check_Arg_Is_OK_Static_Expression; ------------------------------------------ -- 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 an allowed task dispatching policy name", Argx); end if; end Check_Arg_Is_Task_Dispatching_Policy; --------------------- -- Check_Arg_Order -- --------------------- procedure Check_Arg_Order (Names : Name_List) is Arg : Node_Id; Highest_So_Far : Natural := 0; -- Highest index in Names seen do far begin Arg := Arg1; for J in 1 .. Arg_Count loop if Chars (Arg) /= No_Name then for K in Names'Range loop if Chars (Arg) = Names (K) then if K < Highest_So_Far then Error_Msg_Name_1 := Pname; Error_Msg_N ("parameters out of order for pragma%", Arg); Error_Msg_Name_1 := Names (K); Error_Msg_Name_2 := Names (Highest_So_Far); Error_Msg_N ("\% must appear before %", Arg); raise Pragma_Exit; else Highest_So_Far := K; end if; end if; end loop; end if; Arg := Next (Arg); end loop; end Check_Arg_Order; -------------------------------- -- 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_Component -- --------------------- procedure Check_Component (Comp : Node_Id; UU_Typ : Entity_Id; In_Variant_Part : Boolean := False) is Comp_Id : constant Entity_Id := Defining_Identifier (Comp); Sindic : constant Node_Id := Subtype_Indication (Component_Definition (Comp)); Typ : constant Entity_Id := Etype (Comp_Id); begin -- Ada 2005 (AI-216): If a component subtype is subject to a per- -- object constraint, then the component type shall be an Unchecked_ -- Union. if Nkind (Sindic) = N_Subtype_Indication and then Has_Per_Object_Constraint (Comp_Id) and then not Is_Unchecked_Union (Etype (Subtype_Mark (Sindic))) then Error_Msg_N ("component subtype subject to per-object constraint " & "must be an Unchecked_Union", Comp); -- Ada 2012 (AI05-0026): For an unchecked union type declared within -- the body of a generic unit, or within the body of any of its -- descendant library units, no part of the type of a component -- declared in a variant_part of the unchecked union type shall be of -- a formal private type or formal private extension declared within -- the formal part of the generic unit. elsif Ada_Version >= Ada_2012 and then In_Generic_Body (UU_Typ) and then In_Variant_Part and then Is_Private_Type (Typ) and then Is_Generic_Type (Typ) then Error_Msg_N ("component of unchecked union cannot be of generic type", Comp); elsif Needs_Finalization (Typ) then Error_Msg_N ("component of unchecked union cannot be controlled", Comp); elsif Has_Task (Typ) then Error_Msg_N ("component of unchecked union cannot have tasks", Comp); end if; end Check_Component; ---------------------------- -- Check_Duplicate_Pragma -- ---------------------------- procedure Check_Duplicate_Pragma (E : Entity_Id) is Id : Entity_Id := E; P : Node_Id; begin -- Nothing to do if this pragma comes from an aspect specification, -- since we could not be duplicating a pragma, and we dealt with the -- case of duplicated aspects in Analyze_Aspect_Specifications. if From_Aspect_Specification (N) then return; end if; -- Otherwise current pragma may duplicate previous pragma or a -- previously given aspect specification or attribute definition -- clause for the same pragma. P := Get_Rep_Item (E, Pragma_Name (N), Check_Parents => False); if Present (P) then -- If the entity is a type, then we have to make sure that the -- ostensible duplicate is not for a parent type from which this -- type is derived. if Is_Type (E) then if Nkind (P) = N_Pragma then declare Args : constant List_Id := Pragma_Argument_Associations (P); begin if Present (Args) and then Is_Entity_Name (Expression (First (Args))) and then Is_Type (Entity (Expression (First (Args)))) and then Entity (Expression (First (Args))) /= E then return; end if; end; elsif Nkind (P) = N_Aspect_Specification and then Is_Type (Entity (P)) and then Entity (P) /= E then return; end if; end if; -- Here we have a definite duplicate Error_Msg_Name_1 := Pragma_Name (N); Error_Msg_Sloc := Sloc (P); -- For a single protected or a single task object, the error is -- issued on the original entity. if Ekind_In (Id, E_Task_Type, E_Protected_Type) then Id := Defining_Identifier (Original_Node (Parent (Id))); end if; if Nkind (P) = N_Aspect_Specification or else From_Aspect_Specification (P) then Error_Msg_NE ("aspect% for & previously given#", N, Id); else Error_Msg_NE ("pragma% for & duplicates pragma#", N, Id); end if; raise Pragma_Exit; end if; end Check_Duplicate_Pragma; ---------------------------------- -- Check_Duplicated_Export_Name -- ---------------------------------- procedure Check_Duplicated_Export_Name (Nam : Node_Id) is String_Val : constant String_Id := Strval (Nam); begin -- We are only interested in the export case, and in the case of -- generics, it is the instance, not the template, that is the -- problem (the template will generate a warning in any case). if not Inside_A_Generic and then (Prag_Id = Pragma_Export or else Prag_Id = Pragma_Export_Procedure or else Prag_Id = Pragma_Export_Valued_Procedure or else Prag_Id = Pragma_Export_Function) then for J in Externals.First .. Externals.Last loop if String_Equal (String_Val, Strval (Externals.Table (J))) then Error_Msg_Sloc := Sloc (Externals.Table (J)); Error_Msg_N ("external name duplicates name given#", Nam); exit; end if; end loop; Externals.Append (Nam); end if; end Check_Duplicated_Export_Name; ---------------------------------------- -- Check_Expr_Is_OK_Static_Expression -- ---------------------------------------- procedure Check_Expr_Is_OK_Static_Expression (Expr : Node_Id; Typ : Entity_Id := Empty) is begin if Present (Typ) then Analyze_And_Resolve (Expr, Typ); else Analyze_And_Resolve (Expr); end if; -- An expression cannot be considered static if its resolution failed -- or if it's erroneous. Stop the analysis of the related pragma. if Etype (Expr) = Any_Type or else Error_Posted (Expr) then raise Pragma_Exit; elsif Is_OK_Static_Expression (Expr) then return; -- 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_Version = Ada_83 and then Nkind (Expr) = N_String_Literal then return; -- Finally, we have a real error else Error_Msg_Name_1 := Pname; Flag_Non_Static_Expr (Fix_Error ("argument for pragma% must be a static expression!"), Expr); raise Pragma_Exit; end if; end Check_Expr_Is_OK_Static_Expression; ------------------------- -- Check_First_Subtype -- ------------------------- procedure Check_First_Subtype (Arg : Node_Id) is Argx : constant Node_Id := Get_Pragma_Arg (Arg); Ent : constant Entity_Id := Entity (Argx); begin if Is_First_Subtype (Ent) then null; elsif Is_Type (Ent) then Error_Pragma_Arg ("pragma% cannot apply to subtype", Argx); elsif Is_Object (Ent) then Error_Pragma_Arg ("pragma% cannot apply to object, requires a type", Argx); else Error_Pragma_Arg ("pragma% cannot apply to&, requires a type", Argx); end if; end Check_First_Subtype; ---------------------- -- Check_Identifier -- ---------------------- procedure Check_Identifier (Arg : Node_Id; Id : Name_Id) is begin if Present (Arg) and then Nkind (Arg) = N_Pragma_Argument_Association then if Chars (Arg) = No_Name or else Chars (Arg) /= Id then Error_Msg_Name_1 := Pname; Error_Msg_Name_2 := Id; Error_Msg_N ("pragma% argument expects identifier%", Arg); raise Pragma_Exit; end if; end if; end Check_Identifier; -------------------------------- -- Check_Identifier_Is_One_Of -- -------------------------------- procedure Check_Identifier_Is_One_Of (Arg : Node_Id; N1, N2 : Name_Id) is begin if Present (Arg) and then Nkind (Arg) = N_Pragma_Argument_Association then if Chars (Arg) = No_Name then Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma% argument expects an identifier", Arg); raise Pragma_Exit; elsif Chars (Arg) /= N1 and then Chars (Arg) /= N2 then Error_Msg_Name_1 := Pname; Error_Msg_N ("invalid identifier for pragma% argument", Arg); raise Pragma_Exit; end if; end if; end Check_Identifier_Is_One_Of; --------------------------- -- Check_In_Main_Program -- --------------------------- procedure Check_In_Main_Program is P : constant Node_Id := Parent (N); begin -- Must be 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 := Pname; 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 := Get_Pragma_Arg (Arg1); Handler_Proc, Proc_Scope : Entity_Id; begin Analyze (Arg1_X); if Prag_Id = Pragma_Interrupt_Handler then Check_Restriction (No_Dynamic_Attachment, N); end if; Handler_Proc := Find_Unique_Parameterless_Procedure (Arg1_X, Arg1); Proc_Scope := Scope (Handler_Proc); if Ekind (Proc_Scope) /= E_Protected_Type then Error_Pragma_Arg ("argument of pragma% must be protected procedure", Arg1); end if; -- For pragma case (as opposed to access case), check placement. -- We don't need to do that for aspects, because we have the -- check that they aspect applies an appropriate procedure. if not From_Aspect_Specification (N) and then Parent (N) /= Protected_Definition (Parent (Proc_Scope)) then Error_Pragma ("pragma% must be in protected definition"); end if; if not Is_Library_Level_Entity (Proc_Scope) then Error_Pragma_Arg ("argument for pragma% must be library level entity", Arg1); end if; -- AI05-0033: A pragma cannot appear within a generic body, because -- instance can be in a nested scope. The check that protected type -- is itself a library-level declaration is done elsewhere. -- Note: we omit this check in Relaxed_RM_Semantics mode to properly -- handle code prior to AI-0033. Analysis tools typically are not -- interested in this pragma in any case, so no need to worry too -- much about its placement. if Inside_A_Generic then if Ekind (Scope (Current_Scope)) = E_Generic_Package and then In_Package_Body (Scope (Current_Scope)) and then not Relaxed_RM_Semantics then Error_Pragma ("pragma% cannot be used inside a generic"); end if; end if; end Check_Interrupt_Or_Attach_Handler; --------------------------------- -- Check_Loop_Pragma_Placement -- --------------------------------- procedure Check_Loop_Pragma_Placement is procedure Check_Loop_Pragma_Grouping (Loop_Stmt : Node_Id); -- Verify whether the current pragma is properly grouped with other -- pragma Loop_Invariant and/or Loop_Variant. Node Loop_Stmt is the -- related loop where the pragma appears. function Is_Loop_Pragma (Stmt : Node_Id) return Boolean; -- Determine whether an arbitrary statement Stmt denotes pragma -- Loop_Invariant or Loop_Variant. procedure Placement_Error (Constr : Node_Id); pragma No_Return (Placement_Error); -- Node Constr denotes the last loop restricted construct before we -- encountered an illegal relation between enclosing constructs. Emit -- an error depending on what Constr was. -------------------------------- -- Check_Loop_Pragma_Grouping -- -------------------------------- procedure Check_Loop_Pragma_Grouping (Loop_Stmt : Node_Id) is Stop_Search : exception; -- This exception is used to terminate the recursive descent of -- routine Check_Grouping. procedure Check_Grouping (L : List_Id); -- Find the first group of pragmas in list L and if successful, -- ensure that the current pragma is part of that group. The -- routine raises Stop_Search once such a check is performed to -- halt the recursive descent. procedure Grouping_Error (Prag : Node_Id); pragma No_Return (Grouping_Error); -- Emit an error concerning the current pragma indicating that it -- should be placed after pragma Prag. -------------------- -- Check_Grouping -- -------------------- procedure Check_Grouping (L : List_Id) is HSS : Node_Id; Stmt : Node_Id; Prag : Node_Id := Empty; -- init to avoid warning begin -- Inspect the list of declarations or statements looking for -- the first grouping of pragmas: -- loop -- pragma Loop_Invariant ...; -- pragma Loop_Variant ...; -- . . . -- (1) -- pragma Loop_Variant ...; -- current pragma -- If the current pragma is not in the grouping, then it must -- either appear in a different declarative or statement list -- or the construct at (1) is separating the pragma from the -- grouping. Stmt := First (L); while Present (Stmt) loop -- First pragma of the first topmost grouping has been found if Is_Loop_Pragma (Stmt) then -- The group and the current pragma are not in the same -- declarative or statement list. if List_Containing (Stmt) /= List_Containing (N) then Grouping_Error (Stmt); -- Try to reach the current pragma from the first pragma -- of the grouping while skipping other members: -- pragma Loop_Invariant ...; -- first pragma -- pragma Loop_Variant ...; -- member -- . . . -- pragma Loop_Variant ...; -- current pragma else while Present (Stmt) loop -- The current pragma is either the first pragma -- of the group or is a member of the group. -- Stop the search as the placement is legal. if Stmt = N then raise Stop_Search; -- Skip group members, but keep track of the -- last pragma in the group. elsif Is_Loop_Pragma (Stmt) then Prag := Stmt; -- Skip declarations and statements generated by -- the compiler during expansion. Note that some -- source statements (e.g. pragma Assert) may have -- been transformed so that they do not appear as -- coming from source anymore, so we instead look -- at their Original_Node. elsif not Comes_From_Source (Original_Node (Stmt)) then null; -- A non-pragma is separating the group from the -- current pragma, the placement is illegal. else Grouping_Error (Prag); end if; Next (Stmt); end loop; -- If the traversal did not reach the current pragma, -- then the list must be malformed. raise Program_Error; end if; -- Pragmas Loop_Invariant and Loop_Variant may only appear -- inside a loop or a block housed inside a loop. Inspect -- the declarations and statements of the block as they may -- contain the first grouping. This case follows the one for -- loop pragmas, as block statements which originate in a -- loop pragma (and so Is_Loop_Pragma will return True on -- that block statement) should be treated in the previous -- case. elsif Nkind (Stmt) = N_Block_Statement then HSS := Handled_Statement_Sequence (Stmt); Check_Grouping (Declarations (Stmt)); if Present (HSS) then Check_Grouping (Statements (HSS)); end if; end if; Next (Stmt); end loop; end Check_Grouping; -------------------- -- Grouping_Error -- -------------------- procedure Grouping_Error (Prag : Node_Id) is begin Error_Msg_Sloc := Sloc (Prag); Error_Pragma ("pragma% must appear next to pragma#"); end Grouping_Error; -- Start of processing for Check_Loop_Pragma_Grouping begin -- Inspect the statements of the loop or nested blocks housed -- within to determine whether the current pragma is part of the -- first topmost grouping of Loop_Invariant and Loop_Variant. Check_Grouping (Statements (Loop_Stmt)); exception when Stop_Search => null; end Check_Loop_Pragma_Grouping; -------------------- -- Is_Loop_Pragma -- -------------------- function Is_Loop_Pragma (Stmt : Node_Id) return Boolean is begin -- Inspect the original node as Loop_Invariant and Loop_Variant -- pragmas are rewritten to null when assertions are disabled. if Nkind (Original_Node (Stmt)) = N_Pragma then return Nam_In (Pragma_Name_Unmapped (Original_Node (Stmt)), Name_Loop_Invariant, Name_Loop_Variant); else return False; end if; end Is_Loop_Pragma; --------------------- -- Placement_Error -- --------------------- procedure Placement_Error (Constr : Node_Id) is LA : constant String := " with Loop_Entry"; begin if Prag_Id = Pragma_Assert then Error_Msg_String (1 .. LA'Length) := LA; Error_Msg_Strlen := LA'Length; else Error_Msg_Strlen := 0; end if; if Nkind (Constr) = N_Pragma then Error_Pragma ("pragma %~ must appear immediately within the statements " & "of a loop"); else Error_Pragma_Arg ("block containing pragma %~ must appear immediately within " & "the statements of a loop", Constr); end if; end Placement_Error; -- Local declarations Prev : Node_Id; Stmt : Node_Id; -- Start of processing for Check_Loop_Pragma_Placement begin -- Check that pragma appears immediately within a loop statement, -- ignoring intervening block statements. Prev := N; Stmt := Parent (N); while Present (Stmt) loop -- The pragma or previous block must appear immediately within the -- current block's declarative or statement part. if Nkind (Stmt) = N_Block_Statement then if (No (Declarations (Stmt)) or else List_Containing (Prev) /= Declarations (Stmt)) and then List_Containing (Prev) /= Statements (Handled_Statement_Sequence (Stmt)) then Placement_Error (Prev); return; -- Keep inspecting the parents because we are now within a -- chain of nested blocks. else Prev := Stmt; Stmt := Parent (Stmt); end if; -- The pragma or previous block must appear immediately within the -- statements of the loop. elsif Nkind (Stmt) = N_Loop_Statement then if List_Containing (Prev) /= Statements (Stmt) then Placement_Error (Prev); end if; -- Stop the traversal because we reached the innermost loop -- regardless of whether we encountered an error or not. exit; -- Ignore a handled statement sequence. Note that this node may -- be related to a subprogram body in which case we will emit an -- error on the next iteration of the search. elsif Nkind (Stmt) = N_Handled_Sequence_Of_Statements then Stmt := Parent (Stmt); -- Any other statement breaks the chain from the pragma to the -- loop. else Placement_Error (Prev); return; end if; end loop; -- Check that the current pragma Loop_Invariant or Loop_Variant is -- grouped together with other such pragmas. if Is_Loop_Pragma (N) then -- The previous check should have located the related loop pragma Assert (Nkind (Stmt) = N_Loop_Statement); Check_Loop_Pragma_Grouping (Stmt); end if; end Check_Loop_Pragma_Placement; ------------------------------------------- -- 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_In (P, N_Package_Specification, 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_In (P, N_Subprogram_Body, N_Package_Body, N_Task_Body, 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 Nkind (Arg) = N_Pragma_Argument_Association and then 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 Arg_Node := Arg1; for J in 1 .. Arg_Count loop Check_No_Identifier (Arg_Node); Next (Arg_Node); end loop; end Check_No_Identifiers; ------------------------ -- Check_No_Link_Name -- ------------------------ procedure Check_No_Link_Name is begin if Present (Arg3) and then Chars (Arg3) = Name_Link_Name then Arg4 := Arg3; end if; if Present (Arg4) then Error_Pragma_Arg ("Link_Name argument not allowed for Import Intrinsic", Arg4); end if; end Check_No_Link_Name; ------------------------------- -- Check_Optional_Identifier -- ------------------------------- procedure Check_Optional_Identifier (Arg : Node_Id; Id : Name_Id) is begin if Present (Arg) and then Nkind (Arg) = N_Pragma_Argument_Association and then Chars (Arg) /= No_Name then if Chars (Arg) /= Id then Error_Msg_Name_1 := Pname; 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 Check_Optional_Identifier (Arg, Name_Find (Id)); end Check_Optional_Identifier; ------------------------------------- -- Check_Static_Boolean_Expression -- ------------------------------------- procedure Check_Static_Boolean_Expression (Expr : Node_Id) is begin if Present (Expr) then Analyze_And_Resolve (Expr, Standard_Boolean); if not Is_OK_Static_Expression (Expr) then Error_Pragma_Arg ("expression of pragma % must be static", Expr); end if; end if; end Check_Static_Boolean_Expression; ----------------------------- -- 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 procedure Require_Static (E : Node_Id); -- Require given expression to be static expression -------------------- -- Require_Static -- -------------------- 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; begin IDC := First (Constraints (Constr)); 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, and only other pragmas may precede it. Note that -- the test also allows use in a configuration pragma file. 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 (Get_Pragma_Arg (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 in N_Generic_Instantiation then Unit_Name := Defining_Entity (Unit_Node); else Unit_Name := Cunit_Entity (Current_Sem_Unit); end if; if Chars (Unit_Name) /= Chars (Entity (Get_Pragma_Arg (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 (Get_Pragma_Arg (Arg1)); if Entity (Get_Pragma_Arg (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; ------------------- -- Check_Variant -- ------------------- procedure Check_Variant (Variant : Node_Id; UU_Typ : Entity_Id) is Clist : constant Node_Id := Component_List (Variant); Comp : Node_Id; begin Comp := First_Non_Pragma (Component_Items (Clist)); while Present (Comp) loop Check_Component (Comp, UU_Typ, In_Variant_Part => True); Next_Non_Pragma (Comp); end loop; end Check_Variant; --------------------------- -- Ensure_Aggregate_Form -- --------------------------- procedure Ensure_Aggregate_Form (Arg : Node_Id) is CFSD : constant Boolean := Get_Comes_From_Source_Default; Expr : constant Node_Id := Expression (Arg); Loc : constant Source_Ptr := Sloc (Expr); Comps : List_Id := No_List; Exprs : List_Id := No_List; Nam : Name_Id := No_Name; Nam_Loc : Source_Ptr; begin -- The pragma argument is in positional form: -- pragma Depends (Nam => ...) -- ^ -- Chars field -- Note that the Sloc of the Chars field is the Sloc of the pragma -- argument association. if Nkind (Arg) = N_Pragma_Argument_Association then Nam := Chars (Arg); Nam_Loc := Sloc (Arg); -- Remove the pragma argument name as this will be captured in the -- aggregate. Set_Chars (Arg, No_Name); end if; -- The argument is already in aggregate form, but the presence of a -- name causes this to be interpreted as named association which in -- turn must be converted into an aggregate. -- pragma Global (In_Out => (A, B, C)) -- ^ ^ -- name aggregate -- pragma Global ((In_Out => (A, B, C))) -- ^ ^ -- aggregate aggregate if Nkind (Expr) = N_Aggregate then if Nam = No_Name then return; end if; -- Do not transform a null argument into an aggregate as N_Null has -- special meaning in formal verification pragmas. elsif Nkind (Expr) = N_Null then return; end if; -- Everything comes from source if the original comes from source Set_Comes_From_Source_Default (Comes_From_Source (Arg)); -- Positional argument is transformed into an aggregate with an -- Expressions list. if Nam = No_Name then Exprs := New_List (Relocate_Node (Expr)); -- An associative argument is transformed into an aggregate with -- Component_Associations. else Comps := New_List ( Make_Component_Association (Loc, Choices => New_List (Make_Identifier (Nam_Loc, Nam)), Expression => Relocate_Node (Expr))); end if; Set_Expression (Arg, Make_Aggregate (Loc, Component_Associations => Comps, Expressions => Exprs)); -- Restore Comes_From_Source default Set_Comes_From_Source_Default (CFSD); end Ensure_Aggregate_Form; ------------------ -- Error_Pragma -- ------------------ procedure Error_Pragma (Msg : String) is begin Error_Msg_Name_1 := Pname; Error_Msg_N (Fix_Error (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 := Pname; Error_Msg_N (Fix_Error (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 := Pname; Error_Msg_N (Fix_Error (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 := Pname; Error_Msg_N (Fix_Error (Msg), Arg); raise Pragma_Exit; end Error_Pragma_Arg_Ident; ---------------------- -- Error_Pragma_Ref -- ---------------------- procedure Error_Pragma_Ref (Msg : String; Ref : Entity_Id) is begin Error_Msg_Name_1 := Pname; Error_Msg_Sloc := Sloc (Ref); Error_Msg_NE (Fix_Error (Msg), N, Ref); raise Pragma_Exit; end Error_Pragma_Ref; ------------------------ -- 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 Nkind_In (Unit_Kind, N_Subprogram_Declaration, 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; ----------------------------------------- -- Find_Unique_Parameterless_Procedure -- ----------------------------------------- function Find_Unique_Parameterless_Procedure (Name : Entity_Id; Arg : Node_Id) return Entity_Id is Proc : Entity_Id := Empty; begin -- The body of this procedure needs some comments ??? if not Is_Entity_Name (Name) then Error_Pragma_Arg ("argument of pragma% must be entity name", Arg); elsif not Is_Overloaded (Name) then Proc := Entity (Name); if Ekind (Proc) /= E_Procedure or else Present (First_Formal (Proc)) then Error_Pragma_Arg ("argument of pragma% must be parameterless procedure", Arg); end if; else declare Found : Boolean := False; It : Interp; Index : Interp_Index; begin Get_First_Interp (Name, Index, It); while Present (It.Nam) loop Proc := It.Nam; if Ekind (Proc) = E_Procedure and then No (First_Formal (Proc)) then if not Found then Found := True; Set_Entity (Name, Proc); Set_Is_Overloaded (Name, False); else Error_Pragma_Arg ("ambiguous handler name for pragma% ", Arg); 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", Arg); else Proc := Entity (Name); end if; end; end if; return Proc; end Find_Unique_Parameterless_Procedure; --------------- -- Fix_Error -- --------------- function Fix_Error (Msg : String) return String is Res : String (Msg'Range) := Msg; Res_Last : Natural := Msg'Last; J : Natural; begin -- If we have a rewriting of another pragma, go to that pragma if Is_Rewrite_Substitution (N) and then Nkind (Original_Node (N)) = N_Pragma then Error_Msg_Name_1 := Pragma_Name (Original_Node (N)); end if; -- Case where pragma comes from an aspect specification if From_Aspect_Specification (N) then -- Change appearence of "pragma" in message to "aspect" J := Res'First; while J <= Res_Last - 5 loop if Res (J .. J + 5) = "pragma" then Res (J .. J + 5) := "aspect"; J := J + 6; else J := J + 1; end if; end loop; -- Change "argument of" at start of message to "entity for" if Res'Length > 11 and then Res (Res'First .. Res'First + 10) = "argument of" then Res (Res'First .. Res'First + 9) := "entity for"; Res (Res'First + 10 .. Res_Last - 1) := Res (Res'First + 11 .. Res_Last); Res_Last := Res_Last - 1; end if; -- Change "argument" at start of message to "entity" if Res'Length > 8 and then Res (Res'First .. Res'First + 7) = "argument" then Res (Res'First .. Res'First + 5) := "entity"; Res (Res'First + 6 .. Res_Last - 2) := Res (Res'First + 8 .. Res_Last); Res_Last := Res_Last - 2; end if; -- Get name from corresponding aspect Error_Msg_Name_1 := Original_Aspect_Pragma_Name (N); end if; -- Return possibly modified message return Res (Res'First .. Res_Last); end Fix_Error; ------------------------- -- 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) := Get_Pragma_Arg (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) := Get_Pragma_Arg (Arg); exit; end if; end if; if Index = Names'Last then Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma% does not allow & argument", Arg); -- Check for possible misspelling for Index1 in Names'Range loop if Is_Bad_Spelling_Of (Chars (Arg), Names (Index1)) then Error_Msg_Name_1 := Names (Index1); Error_Msg_N -- CODEFIX ("\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; ----------------- -- GNAT_Pragma -- ----------------- procedure GNAT_Pragma is begin -- We need to check the No_Implementation_Pragmas restriction for -- the case of a pragma from source. Note that the case of aspects -- generating corresponding pragmas marks these pragmas as not being -- from source, so this test also catches that case. if Comes_From_Source (N) then Check_Restriction (No_Implementation_Pragmas, N); end if; 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, and only other pragmas may precede it. Note that -- the test below also permits use in a configuration pragma file. 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; -------------------------- -- Is_In_Context_Clause -- -------------------------- function Is_In_Context_Clause return Boolean is Plist : List_Id; Parent_Node : Node_Id; begin if not Is_List_Member (N) then return False; 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 return False; end if; end if; return True; end Is_In_Context_Clause; --------------------------------- -- Is_Static_String_Expression -- --------------------------------- function Is_Static_String_Expression (Arg : Node_Id) return Boolean is Argx : constant Node_Id := Get_Pragma_Arg (Arg); Lit : constant Boolean := Nkind (Argx) = N_String_Literal; begin Analyze_And_Resolve (Argx); -- Special case Ada 83, where the expression will never be static, -- but we will return true if we had a string literal to start with. if Ada_Version = Ada_83 then return Lit; -- Normal case, true only if we end up with a string literal that -- is marked as being the result of evaluating a static expression. else return Is_OK_Static_Expression (Argx) and then Nkind (Argx) = N_String_Literal; end if; end Is_Static_String_Expression; ---------------------- -- Pragma_Misplaced -- ---------------------- procedure Pragma_Misplaced is begin Error_Pragma ("incorrect placement of pragma%"); end Pragma_Misplaced; ------------------------------------------------ -- Process_Atomic_Independent_Shared_Volatile -- ------------------------------------------------ procedure Process_Atomic_Independent_Shared_Volatile is procedure Check_VFA_Conflicts (Ent : Entity_Id); -- Apply additional checks for the GNAT pragma Volatile_Full_Access procedure Mark_Component_Or_Object (Ent : Entity_Id); -- Appropriately set flags on the given entity (either an array or -- record component, or an object declaration) according to the -- current pragma. procedure Set_Atomic_VFA (Ent : Entity_Id); -- Set given type as Is_Atomic or Is_Volatile_Full_Access. Also, if -- no explicit alignment was given, set alignment to unknown, since -- back end knows what the alignment requirements are for atomic and -- full access arrays. Note: this is necessary for derived types. ------------------------- -- Check_VFA_Conflicts -- ------------------------- procedure Check_VFA_Conflicts (Ent : Entity_Id) is Comp : Entity_Id; Typ : Entity_Id; VFA_And_Atomic : Boolean := False; -- Set True if atomic component present VFA_And_Aliased : Boolean := False; -- Set True if aliased component present begin -- Fetch the type in case we are dealing with an object or -- component. if Is_Type (Ent) then Typ := Ent; else pragma Assert (Is_Object (Ent) or else Nkind (Declaration_Node (Ent)) = N_Component_Declaration); Typ := Etype (Ent); end if; -- Check Atomic and VFA used together if Prag_Id = Pragma_Volatile_Full_Access or else Is_Volatile_Full_Access (Ent) then if Prag_Id = Pragma_Atomic or else Prag_Id = Pragma_Shared or else Is_Atomic (Ent) then VFA_And_Atomic := True; elsif Is_Array_Type (Typ) then VFA_And_Atomic := Has_Atomic_Components (Typ); -- Note: Has_Atomic_Components is not used below, as this flag -- represents the pragma of the same name, Atomic_Components, -- which only applies to arrays. elsif Is_Record_Type (Typ) then -- Attributes cannot be applied to discriminants, only -- regular record components. Comp := First_Component (Typ); while Present (Comp) loop if Is_Atomic (Comp) or else Is_Atomic (Typ) then VFA_And_Atomic := True; exit; end if; Next_Component (Comp); end loop; end if; if VFA_And_Atomic then Error_Pragma ("cannot have Volatile_Full_Access and Atomic for same " & "entity"); end if; end if; -- Check for the application of VFA to an entity that has aliased -- components. if Prag_Id = Pragma_Volatile_Full_Access then if Is_Array_Type (Typ) and then Has_Aliased_Components (Typ) then VFA_And_Aliased := True; -- Note: Has_Aliased_Components, like Has_Atomic_Components, -- and Has_Independent_Components, applies only to arrays. -- However, this flag does not have a corresponding pragma, so -- perhaps it should be possible to apply it to record types as -- well. Should this be done ??? elsif Is_Record_Type (Typ) then -- It is possible to have an aliased discriminant, so they -- must be checked along with normal components. Comp := First_Component_Or_Discriminant (Typ); while Present (Comp) loop if Is_Aliased (Comp) or else Is_Aliased (Etype (Comp)) then VFA_And_Aliased := True; Check_SPARK_05_Restriction ("aliased is not allowed", Comp); exit; end if; Next_Component_Or_Discriminant (Comp); end loop; end if; if VFA_And_Aliased then Error_Pragma ("cannot apply Volatile_Full_Access (aliased component " & "present)"); end if; end if; end Check_VFA_Conflicts; ------------------------------ -- Mark_Component_Or_Object -- ------------------------------ procedure Mark_Component_Or_Object (Ent : Entity_Id) is begin if Prag_Id = Pragma_Atomic or else Prag_Id = Pragma_Shared or else Prag_Id = Pragma_Volatile_Full_Access then if Prag_Id = Pragma_Volatile_Full_Access then Set_Is_Volatile_Full_Access (Ent); else Set_Is_Atomic (Ent); end if; -- If the object declaration has an explicit initialization, a -- temporary may have to be created to hold the expression, to -- ensure that access to the object remains atomic. if Nkind (Parent (Ent)) = N_Object_Declaration and then Present (Expression (Parent (Ent))) then Set_Has_Delayed_Freeze (Ent); end if; end if; -- Atomic/Shared/Volatile_Full_Access imply Independent if Prag_Id /= Pragma_Volatile then Set_Is_Independent (Ent); if Prag_Id = Pragma_Independent then Record_Independence_Check (N, Ent); end if; end if; -- Atomic/Shared/Volatile_Full_Access imply Volatile if Prag_Id /= Pragma_Independent then Set_Is_Volatile (Ent); Set_Treat_As_Volatile (Ent); end if; end Mark_Component_Or_Object; -------------------- -- Set_Atomic_VFA -- -------------------- procedure Set_Atomic_VFA (Ent : Entity_Id) is begin if Prag_Id = Pragma_Volatile_Full_Access then Set_Is_Volatile_Full_Access (Ent); else Set_Is_Atomic (Ent); end if; if not Has_Alignment_Clause (Ent) then Set_Alignment (Ent, Uint_0); end if; end Set_Atomic_VFA; -- Local variables Decl : Node_Id; E : Entity_Id; E_Arg : Node_Id; -- Start of processing for Process_Atomic_Independent_Shared_Volatile begin Check_Ada_83_Warning; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); E_Arg := Get_Pragma_Arg (Arg1); if Etype (E_Arg) = Any_Type then return; end if; E := Entity (E_Arg); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); -- Check duplicate before we chain ourselves Check_Duplicate_Pragma (E); -- Check appropriateness of the entity Decl := Declaration_Node (E); -- Deal with the case where the pragma/attribute is applied to a type 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; -- Attribute belongs on the base type. If the view of the type is -- currently private, it also belongs on the underlying type. if Prag_Id = Pragma_Atomic or else Prag_Id = Pragma_Shared or else Prag_Id = Pragma_Volatile_Full_Access then Set_Atomic_VFA (E); Set_Atomic_VFA (Base_Type (E)); Set_Atomic_VFA (Underlying_Type (E)); end if; -- Atomic/Shared/Volatile_Full_Access imply Independent if Prag_Id /= Pragma_Volatile then Set_Is_Independent (E); Set_Is_Independent (Base_Type (E)); Set_Is_Independent (Underlying_Type (E)); if Prag_Id = Pragma_Independent then Record_Independence_Check (N, Base_Type (E)); end if; end if; -- Atomic/Shared/Volatile_Full_Access imply Volatile if Prag_Id /= Pragma_Independent then Set_Is_Volatile (E); Set_Is_Volatile (Base_Type (E)); Set_Is_Volatile (Underlying_Type (E)); Set_Treat_As_Volatile (E); Set_Treat_As_Volatile (Underlying_Type (E)); end if; -- Apply Volatile to the composite type's individual components, -- (RM C.6(8/3)). if Prag_Id = Pragma_Volatile and then Is_Record_Type (Etype (E)) then declare Comp : Entity_Id; begin Comp := First_Component (E); while Present (Comp) loop Mark_Component_Or_Object (Comp); Next_Component (Comp); end loop; end; end if; -- Deal with the case where the pragma/attribute applies to a -- component or object declaration. elsif Nkind (Decl) = N_Object_Declaration or else (Nkind (Decl) = N_Component_Declaration and then Original_Record_Component (E) = E) then if Rep_Item_Too_Late (E, N) then return; end if; Mark_Component_Or_Object (E); else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; -- Perform the checks needed to assure the proper use of the GNAT -- pragma Volatile_Full_Access. Check_VFA_Conflicts (E); -- The following check is only relevant when SPARK_Mode is on as -- this is not a standard Ada legality rule. Pragma Volatile can -- only apply to a full type declaration or an object declaration -- (SPARK RM 7.1.3(2)). Original_Node is necessary to account for -- untagged derived types that are rewritten as subtypes of their -- respective root types. if SPARK_Mode = On and then Prag_Id = Pragma_Volatile and then not Nkind_In (Original_Node (Decl), N_Full_Type_Declaration, N_Object_Declaration, N_Single_Protected_Declaration, N_Single_Task_Declaration) then Error_Pragma_Arg ("argument of pragma % must denote a full type or object " & "declaration", Arg1); end if; end Process_Atomic_Independent_Shared_Volatile; ------------------------------------------- -- Process_Compile_Time_Warning_Or_Error -- ------------------------------------------- procedure Process_Compile_Time_Warning_Or_Error is Validation_Needed : Boolean := False; function Check_Node (N : Node_Id) return Traverse_Result; -- Tree visitor that checks if N is an attribute reference that can -- be statically computed by the back end. Validation_Needed is set -- to True if found. ---------------- -- Check_Node -- ---------------- function Check_Node (N : Node_Id) return Traverse_Result is begin if Nkind (N) = N_Attribute_Reference and then Is_Entity_Name (Prefix (N)) then declare Attr_Id : constant Attribute_Id := Get_Attribute_Id (Attribute_Name (N)); begin if Attr_Id = Attribute_Alignment or else Attr_Id = Attribute_Size then Validation_Needed := True; end if; end; end if; return OK; end Check_Node; procedure Check_Expression is new Traverse_Proc (Check_Node); -- Local variables Arg1x : constant Node_Id := Get_Pragma_Arg (Arg1); -- Start of processing for Process_Compile_Time_Warning_Or_Error begin -- In GNATprove mode, pragmas Compile_Time_Error and -- Compile_Time_Warning are ignored, as the analyzer may not have the -- same information as the compiler (in particular regarding size of -- objects decided in gigi) so it makes no sense to issue an error or -- warning in GNATprove. if GNATprove_Mode then Rewrite (N, Make_Null_Statement (Loc)); return; end if; Check_Arg_Count (2); Check_No_Identifiers; Check_Arg_Is_OK_Static_Expression (Arg2, Standard_String); Analyze_And_Resolve (Arg1x, Standard_Boolean); if Compile_Time_Known_Value (Arg1x) then Process_Compile_Time_Warning_Or_Error (N, Sloc (Arg1)); -- Register the expression for its validation after the back end has -- been called if it has occurrences of attributes Size or Alignment -- (because they may be statically computed by the back end and hence -- the whole expression needs to be reevaluated). else Check_Expression (Arg1x); if Validation_Needed then Sem_Ch13.Validate_Compile_Time_Warning_Error (N); end if; end if; end Process_Compile_Time_Warning_Or_Error; ------------------------ -- Process_Convention -- ------------------------ procedure Process_Convention (C : out Convention_Id; Ent : out Entity_Id) is Cname : Name_Id; procedure Diagnose_Multiple_Pragmas (S : Entity_Id); -- Called if we have more than one Export/Import/Convention pragma. -- This is generally illegal, but we have a special case of allowing -- Import and Interface to coexist if they specify the convention in -- a consistent manner. We are allowed to do this, since Interface is -- an implementation defined pragma, and we choose to do it since we -- know Rational allows this combination. S is the entity id of the -- subprogram in question. This procedure also sets the special flag -- Import_Interface_Present in both pragmas in the case where we do -- have matching Import and Interface pragmas. 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, -- and error checks for inappropriate convention specification. ------------------------------- -- Diagnose_Multiple_Pragmas -- ------------------------------- procedure Diagnose_Multiple_Pragmas (S : Entity_Id) is Pdec : constant Node_Id := Declaration_Node (S); Decl : Node_Id; Err : Boolean; function Same_Convention (Decl : Node_Id) return Boolean; -- Decl is a pragma node. This function returns True if this -- pragma has a first argument that is an identifier with a -- Chars field corresponding to the Convention_Id C. function Same_Name (Decl : Node_Id) return Boolean; -- Decl is a pragma node. This function returns True if this -- pragma has a second argument that is an identifier with a -- Chars field that matches the Chars of the current subprogram. --------------------- -- Same_Convention -- --------------------- function Same_Convention (Decl : Node_Id) return Boolean is Arg1 : constant Node_Id := First (Pragma_Argument_Associations (Decl)); begin if Present (Arg1) then declare Arg : constant Node_Id := Get_Pragma_Arg (Arg1); begin if Nkind (Arg) = N_Identifier and then Is_Convention_Name (Chars (Arg)) and then Get_Convention_Id (Chars (Arg)) = C then return True; end if; end; end if; return False; end Same_Convention; --------------- -- Same_Name -- --------------- function Same_Name (Decl : Node_Id) return Boolean is Arg1 : constant Node_Id := First (Pragma_Argument_Associations (Decl)); Arg2 : Node_Id; begin if No (Arg1) then return False; end if; Arg2 := Next (Arg1); if No (Arg2) then return False; end if; declare Arg : constant Node_Id := Get_Pragma_Arg (Arg2); begin if Nkind (Arg) = N_Identifier and then Chars (Arg) = Chars (S) then return True; end if; end; return False; end Same_Name; -- Start of processing for Diagnose_Multiple_Pragmas begin Err := True; -- Definitely give message if we have Convention/Export here if Prag_Id = Pragma_Convention or else Prag_Id = Pragma_Export then null; -- If we have an Import or Export, scan back from pragma to -- find any previous pragma applying to the same procedure. -- The scan will be terminated by the start of the list, or -- hitting the subprogram declaration. This won't allow one -- pragma to appear in the public part and one in the private -- part, but that seems very unlikely in practice. else Decl := Prev (N); while Present (Decl) and then Decl /= Pdec loop -- Look for pragma with same name as us if Nkind (Decl) = N_Pragma and then Same_Name (Decl) then -- Give error if same as our pragma or Export/Convention if Nam_In (Pragma_Name_Unmapped (Decl), Name_Export, Name_Convention, Pragma_Name_Unmapped (N)) then exit; -- Case of Import/Interface or the other way round elsif Nam_In (Pragma_Name_Unmapped (Decl), Name_Interface, Name_Import) then -- Here we know that we have Import and Interface. It -- doesn't matter which way round they are. See if -- they specify the same convention. If so, all OK, -- and set special flags to stop other messages if Same_Convention (Decl) then Set_Import_Interface_Present (N); Set_Import_Interface_Present (Decl); Err := False; -- If different conventions, special message else Error_Msg_Sloc := Sloc (Decl); Error_Pragma_Arg ("convention differs from that given#", Arg1); return; end if; end if; end if; Next (Decl); end loop; end if; -- Give message if needed if we fall through those tests -- except on Relaxed_RM_Semantics where we let go: either this -- is a case accepted/ignored by other Ada compilers (e.g. -- a mix of Convention and Import), or another error will be -- generated later (e.g. using both Import and Export). if Err and not Relaxed_RM_Semantics then Error_Pragma_Arg ("at most one Convention/Export/Import pragma is allowed", Arg2); end if; end Diagnose_Multiple_Pragmas; -------------------------------- -- Set_Convention_From_Pragma -- -------------------------------- procedure Set_Convention_From_Pragma (E : Entity_Id) is begin -- Ada 2005 (AI-430): Check invalid attempt to change convention -- for an overridden dispatching operation. Technically this is -- an amendment and should only be done in Ada 2005 mode. However, -- this is clearly a mistake, since the problem that is addressed -- by this AI is that there is a clear gap in the RM. if Is_Dispatching_Operation (E) and then Present (Overridden_Operation (E)) and then C /= Convention (Overridden_Operation (E)) then Error_Pragma_Arg ("cannot change convention for overridden dispatching " & "operation", Arg1); end if; -- Special checks for Convention_Stdcall if C = Convention_Stdcall then -- A dispatching call is not allowed. A dispatching subprogram -- cannot be used to interface to the Win32 API, so in fact -- this check does not impose any effective restriction. if Is_Dispatching_Operation (E) then Error_Msg_Sloc := Sloc (E); -- Note: make this unconditional so that if there is more -- than one call to which the pragma applies, we get a -- message for each call. Also don't use Error_Pragma, -- so that we get multiple messages. Error_Msg_N ("dispatching subprogram# cannot use Stdcall convention!", Arg1); -- Several allowed cases elsif Is_Subprogram_Or_Generic_Subprogram (E) -- A variable is OK or else Ekind (E) = E_Variable -- A component as well. The entity does not have its Ekind -- set until the enclosing record declaration is fully -- analyzed. or else Nkind (Parent (E)) = N_Component_Declaration -- An access to subprogram is also allowed or else (Is_Access_Type (E) and then Ekind (Designated_Type (E)) = E_Subprogram_Type) -- Allow internal call to set convention of subprogram type or else Ekind (E) = E_Subprogram_Type then null; else Error_Pragma_Arg ("second argument of pragma% must be subprogram (type)", Arg2); end if; end if; -- Set the convention Set_Convention (E, C); Set_Has_Convention_Pragma (E); -- For the case of a record base type, also set the convention of -- any anonymous access types declared in the record which do not -- currently have a specified convention. if Is_Record_Type (E) and then Is_Base_Type (E) then declare Comp : Node_Id; begin Comp := First_Component (E); while Present (Comp) loop if Present (Etype (Comp)) and then Ekind_In (Etype (Comp), E_Anonymous_Access_Type, E_Anonymous_Access_Subprogram_Type) and then not Has_Convention_Pragma (Comp) then Set_Convention (Comp, C); end if; Next_Component (Comp); end loop; end; end if; -- Deal with incomplete/private type case, where underlying type -- is available, so set convention of that underlying type. if Is_Incomplete_Or_Private_Type (E) and then Present (Underlying_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 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; -- Local variables Comp_Unit : Unit_Number_Type; E : Entity_Id; E1 : Entity_Id; Id : Node_Id; -- Start of processing for Process_Convention begin Check_At_Least_N_Arguments (2); Check_Optional_Identifier (Arg1, Name_Convention); Check_Arg_Is_Identifier (Arg1); Cname := Chars (Get_Pragma_Arg (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 (Get_Pragma_Arg (Arg1))); -- Otherwise warn on unrecognized convention else if Warn_On_Export_Import then Error_Msg_N ("??unrecognized convention name, C assumed", Get_Pragma_Arg (Arg1)); end if; C := Convention_C; end if; Check_Optional_Identifier (Arg2, Name_Entity); Check_Arg_Is_Local_Name (Arg2); Id := Get_Pragma_Arg (Arg2); Analyze (Id); if not Is_Entity_Name (Id) then Error_Pragma_Arg ("entity name required", Arg2); end if; E := Entity (Id); -- Set entity to return Ent := E; -- Ada_Pass_By_Copy special checking if C = Convention_Ada_Pass_By_Copy then if not Is_First_Subtype (E) then Error_Pragma_Arg ("convention `Ada_Pass_By_Copy` only allowed for types", Arg2); end if; if Is_By_Reference_Type (E) then Error_Pragma_Arg ("convention `Ada_Pass_By_Copy` not allowed for by-reference " & "type", Arg1); end if; -- Ada_Pass_By_Reference special checking elsif C = Convention_Ada_Pass_By_Reference then if not Is_First_Subtype (E) then Error_Pragma_Arg ("convention `Ada_Pass_By_Reference` only allowed for types", Arg2); end if; if Is_By_Copy_Type (E) then Error_Pragma_Arg ("convention `Ada_Pass_By_Reference` not allowed for by-copy " & "type", Arg1); end if; end if; -- Go to renamed subprogram if present, since convention applies to -- the actual renamed entity, not to the renaming entity. If the -- subprogram is inherited, go to parent subprogram. if Is_Subprogram (E) and then Present (Alias (E)) then if Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Renaming_Declaration then if Scope (E) /= Scope (Alias (E)) then Error_Pragma_Ref ("cannot apply pragma% to non-local entity&#", E); end if; E := Alias (E); elsif Nkind_In (Parent (E), N_Full_Type_Declaration, N_Private_Extension_Declaration) and then Scope (E) = Scope (Alias (E)) then E := Alias (E); -- Return the parent subprogram the entity was inherited from Ent := E; end if; end if; -- Check that we are not applying this to a specless body. Relax this -- check if Relaxed_RM_Semantics to accommodate other Ada compilers. if Is_Subprogram (E) and then Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Body and then not Relaxed_RM_Semantics 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_In (E, E_Named_Integer, E_Named_Real) then Error_Msg_Name_1 := Pname; Error_Msg_N ("cannot apply pragma% to named constant!", Get_Pragma_Arg (Arg2)); Error_Pragma_Arg ("\supply appropriate type for&!", Arg2); end if; if Ekind (E) = E_Enumeration_Literal then Error_Pragma ("enumeration literal not allowed for pragma%"); end if; -- Check for rep item appearing too early or too late if Etype (E) = Any_Type or else Rep_Item_Too_Early (E, N) then raise Pragma_Exit; elsif Present (Underlying_Type (E)) then 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 Diagnose_Multiple_Pragmas (E); 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_Or_Generic_Subprogram (E) then -- Accept Intrinsic Export on types if Relaxed_RM_Semantics if not (Is_Type (E) and then Relaxed_RM_Semantics) then Error_Pragma_Arg ("second argument of pragma% must be a subprogram", Arg2); end if; end if; -- Deal with non-subprogram cases if not Is_Subprogram_Or_Generic_Subprogram (E) then Set_Convention_From_Pragma (E); if Is_Type (E) then -- The pragma must apply to a first subtype, but it can also -- apply to a generic type in a generic formal part, in which -- case it will also appear in the corresponding instance. if Is_Generic_Type (E) or else In_Instance then null; else Check_First_Subtype (Arg2); end if; Set_Convention_From_Pragma (Base_Type (E)); -- For access 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 scope and the same declarative part, i.e. the same -- compilation unit. else Comp_Unit := Get_Source_Unit (E); Set_Convention_From_Pragma (E); -- Treat a pragma Import as an implicit body, and pragma import -- as implicit reference (for navigation in GPS). if Prag_Id = Pragma_Import then Generate_Reference (E, Id, 'b'); -- For exported entities we restrict the generation of references -- to entities exported to foreign languages since entities -- exported to Ada do not provide further information to GPS and -- add undesired references to the output of the gnatxref tool. elsif Prag_Id = Pragma_Export and then Convention (E) /= Convention_Ada then Generate_Reference (E, Id, 'i'); end if; -- If the pragma comes from an aspect, it only applies to the -- given entity, not its homonyms. if From_Aspect_Specification (N) then if C = Convention_Intrinsic and then Nkind (Ent) = N_Defining_Operator_Symbol then if Is_Fixed_Point_Type (Etype (Ent)) or else Is_Fixed_Point_Type (Etype (First_Entity (Ent))) or else Is_Fixed_Point_Type (Etype (Last_Entity (Ent))) then Error_Msg_N ("no intrinsic operator available for this fixed-point " & "operation", N); Error_Msg_N ("\use expression functions with the desired " & "conversions made explicit", N); end if; end if; return; end if; -- Otherwise Loop through the homonyms of the pragma argument's -- entity, an apply convention to those in the current scope. E1 := Ent; loop E1 := Homonym (E1); exit when No (E1) or else Scope (E1) /= Current_Scope; -- Ignore entry for which convention is already set if Has_Convention_Pragma (E1) then goto Continue; end if; if Is_Subprogram (E1) and then Nkind (Parent (Declaration_Node (E1))) = N_Subprogram_Body and then not Relaxed_RM_Semantics then Set_Has_Completion (E); -- to prevent cascaded error Error_Pragma_Ref ("pragma% requires separate spec and must come before " & "body#", E1); end if; -- Do not set the pragma on inherited operations or on formal -- subprograms. if Comes_From_Source (E1) and then Comp_Unit = Get_Source_Unit (E1) and then not Is_Formal_Subprogram (E1) and then Nkind (Original_Node (Parent (E1))) /= N_Full_Type_Declaration then if Present (Alias (E1)) and then Scope (E1) /= Scope (Alias (E1)) then Error_Pragma_Ref ("cannot apply pragma% to non-local entity& declared#", E1); end if; Set_Convention_From_Pragma (E1); if Prag_Id = Pragma_Import then Generate_Reference (E1, Id, 'b'); end if; end if; <> null; end loop; end if; end Process_Convention; ---------------------------------------- -- Process_Disable_Enable_Atomic_Sync -- ---------------------------------------- procedure Process_Disable_Enable_Atomic_Sync (Nam : Name_Id) is begin Check_No_Identifiers; Check_At_Most_N_Arguments (1); -- Modeled internally as -- pragma Suppress/Unsuppress (Atomic_Synchronization [,Entity]) Rewrite (N, Make_Pragma (Loc, Chars => Nam, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Name_Atomic_Synchronization))))); if Present (Arg1) then Append_To (Pragma_Argument_Associations (N), New_Copy (Arg1)); end if; Analyze (N); end Process_Disable_Enable_Atomic_Sync; ------------------------------------------------- -- Process_Extended_Import_Export_Internal_Arg -- ------------------------------------------------- procedure Process_Extended_Import_Export_Internal_Arg (Arg_Internal : Node_Id := Empty) is begin 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 not Ekind_In (Def_Id, E_Constant, E_Variable) then Error_Pragma_Arg ("pragma% must designate an object", Arg_Internal); end if; if Has_Rep_Pragma (Def_Id, Name_Common_Object) or else Has_Rep_Pragma (Def_Id, Name_Psect_Object) then Error_Pragma_Arg ("previous Common/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) then Check_Arg_Is_External_Name (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 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 ("imported entities cannot be initialized (RM B.1(24))", "\no initialization allowed for & declared#", Arg1); else Set_Imported (Def_Id); Note_Possible_Modification (Arg_Internal, Sure => False); 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) is Ent : Entity_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; Formal : Entity_Id; Ambiguous : Boolean; Match : Boolean; 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 designated 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); Ent := Empty; Ambiguous := False; -- Loop through homonyms (overloadings) of the entity Hom_Id := Entity (Arg_Internal); 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 Nam_In (Pname, Name_Export_Procedure, 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 := Pname; 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 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 entity 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)); -- Set entity on identifier (needed by ASIS) Set_Entity (Choice, Formal); exit; end if; Next_Formal (Formal); end loop; Next (Massoc); end loop; end if; end if; end; end if; end Process_Extended_Import_Export_Subprogram_Pragma; -------------------------- -- Process_Generic_List -- -------------------------- procedure Process_Generic_List is Arg : Node_Id; Exp : Node_Id; begin Check_No_Identifiers; Check_At_Least_N_Arguments (1); -- Check all arguments are names of generic units or instances Arg := Arg1; while Present (Arg) loop Exp := Get_Pragma_Arg (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_Predefined_Type -- ------------------------------------ procedure Process_Import_Predefined_Type is Loc : constant Source_Ptr := Sloc (N); Elmt : Elmt_Id; Ftyp : Node_Id := Empty; Decl : Node_Id; Def : Node_Id; Nam : Name_Id; begin Nam := String_To_Name (Strval (Expression (Arg3))); Elmt := First_Elmt (Predefined_Float_Types); while Present (Elmt) and then Chars (Node (Elmt)) /= Nam loop Next_Elmt (Elmt); end loop; Ftyp := Node (Elmt); if Present (Ftyp) then -- Don't build a derived type declaration, because predefined C -- types have no declaration anywhere, so cannot really be named. -- Instead build a full type declaration, starting with an -- appropriate type definition is built if Is_Floating_Point_Type (Ftyp) then Def := Make_Floating_Point_Definition (Loc, Make_Integer_Literal (Loc, Digits_Value (Ftyp)), Make_Real_Range_Specification (Loc, Make_Real_Literal (Loc, Realval (Type_Low_Bound (Ftyp))), Make_Real_Literal (Loc, Realval (Type_High_Bound (Ftyp))))); -- Should never have a predefined type we cannot handle else raise Program_Error; end if; -- Build and insert a Full_Type_Declaration, which will be -- analyzed as soon as this list entry has been analyzed. Decl := Make_Full_Type_Declaration (Loc, Make_Defining_Identifier (Loc, Chars (Expression (Arg2))), Type_Definition => Def); Insert_After (N, Decl); Mark_Rewrite_Insertion (Decl); else Error_Pragma_Arg ("no matching type found for pragma%", Arg2); end if; end Process_Import_Predefined_Type; --------------------------------- -- Process_Import_Or_Interface -- --------------------------------- procedure Process_Import_Or_Interface is C : Convention_Id; Def_Id : Entity_Id; Hom_Id : Entity_Id; begin -- In Relaxed_RM_Semantics, support old Ada 83 style: -- pragma Import (Entity, "external name"); if Relaxed_RM_Semantics and then Arg_Count = 2 and then Prag_Id = Pragma_Import and then Nkind (Expression (Arg2)) = N_String_Literal then C := Convention_C; Def_Id := Get_Pragma_Arg (Arg1); Analyze (Def_Id); if not Is_Entity_Name (Def_Id) then Error_Pragma_Arg ("entity name required", Arg1); end if; Def_Id := Entity (Def_Id); Kill_Size_Check_Code (Def_Id); Note_Possible_Modification (Get_Pragma_Arg (Arg1), Sure => False); else Process_Convention (C, Def_Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Def_Id); Kill_Size_Check_Code (Def_Id); Note_Possible_Modification (Get_Pragma_Arg (Arg2), Sure => False); end if; -- Various error checks if Ekind_In (Def_Id, E_Variable, E_Constant) then -- We do not permit Import to apply to a renaming declaration if Present (Renamed_Object (Def_Id)) then Error_Pragma_Arg ("pragma% not allowed for object renaming", Arg2); -- 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. elsif Present (Expression (Parent (Def_Id))) and then Comes_From_Source (Original_Node (Expression (Parent (Def_Id)))) then -- Set imported flag to prevent cascaded errors Set_Is_Imported (Def_Id); Error_Msg_Sloc := Sloc (Def_Id); Error_Pragma_Arg ("no initialization allowed for declaration of& #", "\imported entities cannot be initialized (RM B.1(24))", Arg2); else -- If the pragma comes from an aspect specification the -- Is_Imported flag has already been set. if not From_Aspect_Specification (N) then Set_Imported (Def_Id); end if; Process_Interface_Name (Def_Id, Arg3, Arg4, N); -- Note that we do not set Is_Public here. That's because we -- only want to set it if there is no address clause, and we -- don't know that yet, so we delay that processing till -- freeze time. -- pragma Import completes deferred constants if Ekind (Def_Id) = E_Constant then Set_Has_Completion (Def_Id); end if; -- 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_Or_Generic_Subprogram (Def_Id) then -- If the name is overloaded, pragma applies to all of the denoted -- entities in the same declarative part, unless the pragma comes -- from an aspect specification or was generated by the compiler -- (such as for pragma Provide_Shift_Operators). 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_Or_Generic_Subprogram (Def_Id) then null; -- The pragma does not apply to primitives of interfaces elsif Is_Dispatching_Operation (Def_Id) and then Present (Find_Dispatching_Type (Def_Id)) and then Is_Interface (Find_Dispatching_Type (Def_Id)) then null; -- Verify that the homonym is in the same declarative part (not -- just the same scope). If the pragma comes from an aspect -- specification we know that it is part of the declaration. elsif Parent (Unit_Declaration_Node (Def_Id)) /= Parent (N) and then Nkind (Parent (N)) /= N_Compilation_Unit_Aux and then not From_Aspect_Specification (N) then exit; else -- If the pragma comes from an aspect specification the -- Is_Imported flag has already been set. if not From_Aspect_Specification (N) then Set_Imported (Def_Id); end if; -- Reject an Import applied to an abstract subprogram if Is_Subprogram (Def_Id) and then Is_Abstract_Subprogram (Def_Id) then Error_Msg_Sloc := Sloc (Def_Id); Error_Msg_NE ("cannot import abstract subprogram& declared#", Arg2, Def_Id); end if; -- Special processing for Convention_Intrinsic if C = Convention_Intrinsic then -- Link_Name argument not allowed for intrinsic Check_No_Link_Name; Set_Is_Intrinsic_Subprogram (Def_Id); -- If no external name is present, then check that this -- is a valid intrinsic subprogram. If an external name -- is present, then this is handled by the back end. if No (Arg3) then Check_Intrinsic_Subprogram (Def_Id, Get_Pragma_Arg (Arg2)); end if; end if; -- 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&, renaming already provided for " & "declaration #", N, Def_Id); end if; end; -- If the pragma comes from an aspect specification, there -- must be an Import aspect specified as well. In the rare -- case where Import is set to False, the suprogram needs to -- have a local completion. declare Imp_Aspect : constant Node_Id := Find_Aspect (Def_Id, Aspect_Import); Expr : Node_Id; begin if Present (Imp_Aspect) and then Present (Expression (Imp_Aspect)) then Expr := Expression (Imp_Aspect); Analyze_And_Resolve (Expr, Standard_Boolean); if Is_Entity_Name (Expr) and then Entity (Expr) = Standard_True then Set_Has_Completion (Def_Id); end if; -- If there is no expression, the default is True, as for -- all boolean aspects. Same for the older pragma. else Set_Has_Completion (Def_Id); end if; end; Process_Interface_Name (Def_Id, Arg3, Arg4, N); 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; elsif From_Aspect_Specification (N) then exit; -- If the pragma was created by the compiler, then we don't -- want it to apply to other homonyms. This kind of case can -- occur when using pragma Provide_Shift_Operators, which -- generates implicit shift and rotate operators with Import -- pragmas that might apply to earlier explicit or implicit -- declarations marked with Import (for example, coming from -- an earlier pragma Provide_Shift_Operators for another type), -- and we don't generally want other homonyms being treated -- as imported or the pragma flagged as an illegal duplicate. elsif not Comes_From_Source (N) then exit; else Hom_Id := Homonym (Hom_Id); end if; end loop; -- Import a CPP class elsif C = Convention_CPP and then (Is_Record_Type (Def_Id) or else Ekind (Def_Id) = E_Incomplete_Type) then if Ekind (Def_Id) = E_Incomplete_Type then if Present (Full_View (Def_Id)) then Def_Id := Full_View (Def_Id); else Error_Msg_N ("cannot import 'C'P'P type before full declaration seen", Get_Pragma_Arg (Arg2)); -- Although we have reported the error we decorate it as -- CPP_Class to avoid reporting spurious errors Set_Is_CPP_Class (Def_Id); return; end if; end if; -- Types treated as CPP classes must be declared limited (note: -- this used to be a warning but there is no real benefit to it -- since we did effectively intend to treat the type as limited -- anyway). if not Is_Limited_Type (Def_Id) then Error_Msg_N ("imported 'C'P'P type must be limited", Get_Pragma_Arg (Arg2)); end if; if Etype (Def_Id) /= Def_Id and then not Is_CPP_Class (Root_Type (Def_Id)) then Error_Msg_N ("root type must be a 'C'P'P type", Arg1); end if; Set_Is_CPP_Class (Def_Id); -- Imported CPP types must not have discriminants (because C++ -- classes do not have discriminants). if Has_Discriminants (Def_Id) then Error_Msg_N ("imported 'C'P'P type cannot have discriminants", First (Discriminant_Specifications (Declaration_Node (Def_Id)))); end if; -- Check that components of imported CPP types do not have default -- expressions. For private types this check is performed when the -- full view is analyzed (see Process_Full_View). if not Is_Private_Type (Def_Id) then Check_CPP_Type_Has_No_Defaults (Def_Id); end if; -- Import a CPP exception elsif C = Convention_CPP and then Ekind (Def_Id) = E_Exception then if No (Arg3) then Error_Pragma_Arg ("'External_'Name arguments is required for 'Cpp exception", Arg3); else -- As only a string is allowed, Check_Arg_Is_External_Name -- isn't called. Check_Arg_Is_OK_Static_Expression (Arg3, Standard_String); end if; if Present (Arg4) then Error_Pragma_Arg ("Link_Name argument not allowed for imported Cpp exception", Arg4); end if; -- Do not call Set_Interface_Name as the name of the exception -- shouldn't be modified (and in particular it shouldn't be -- the External_Name). For exceptions, the External_Name is the -- name of the RTTI structure. -- ??? Emit an error if pragma Import/Export_Exception is present elsif Nkind (Parent (Def_Id)) = N_Incomplete_Type_Declaration then Check_No_Link_Name; Check_Arg_Count (3); Check_Arg_Is_OK_Static_Expression (Arg3, Standard_String); Process_Import_Predefined_Type; else Error_Pragma_Arg ("second argument of pragma% must be object, subprogram " & "or incomplete type", 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 (Status : Inline_Status) is Applies : Boolean; Assoc : Node_Id; Decl : Node_Id; Subp : Entity_Id; Subp_Id : Node_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost subprograms is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost subprogram encountered while -- processing the arguments of the pragma. procedure Check_Inline_Always_Placement (Spec_Id : Entity_Id); -- Verify the placement of pragma Inline_Always with respect to the -- initial declaration of subprogram Spec_Id. function Inlining_Not_Possible (Subp : Entity_Id) return Boolean; -- Returns True if it can be determined at this stage that inlining -- is not possible, for example if the body is available and contains -- exception handlers, we prevent inlining, since otherwise we can -- get undefined symbols at link time. This function also emits a -- warning if the pragma appears too late. -- -- ??? is business with link symbols still valid, or does it relate -- to front end ZCX which is being phased out ??? procedure Make_Inline (Subp : Entity_Id); -- Subp is the defining unit name of the subprogram declaration. If -- the pragma is valid, call Set_Inline_Flags on Subp, as well as on -- the corresponding body, if there is one present. procedure Set_Inline_Flags (Subp : Entity_Id); -- Set Has_Pragma_{No_Inline,Inline,Inline_Always} flag on Subp. -- Also set or clear Is_Inlined flag on Subp depending on Status. ----------------------------------- -- Check_Inline_Always_Placement -- ----------------------------------- procedure Check_Inline_Always_Placement (Spec_Id : Entity_Id) is Spec_Decl : constant Node_Id := Unit_Declaration_Node (Spec_Id); function Compilation_Unit_OK return Boolean; pragma Inline (Compilation_Unit_OK); -- Determine whether pragma Inline_Always applies to a compatible -- compilation unit denoted by Spec_Id. function Declarative_List_OK return Boolean; pragma Inline (Declarative_List_OK); -- Determine whether the initial declaration of subprogram Spec_Id -- and the pragma appear in compatible declarative lists. function Subprogram_Body_OK return Boolean; pragma Inline (Subprogram_Body_OK); -- Determine whether pragma Inline_Always applies to a compatible -- subprogram body denoted by Spec_Id. ------------------------- -- Compilation_Unit_OK -- ------------------------- function Compilation_Unit_OK return Boolean is Comp_Unit : constant Node_Id := Parent (Spec_Decl); begin -- The pragma appears after the initial declaration of a -- compilation unit. -- procedure Comp_Unit; -- pragma Inline_Always (Comp_Unit); -- Note that for compatibility reasons, the following case is -- also accepted. -- procedure Stand_Alone_Body_Comp_Unit is -- ... -- end Stand_Alone_Body_Comp_Unit; -- pragma Inline_Always (Stand_Alone_Body_Comp_Unit); return Nkind (Comp_Unit) = N_Compilation_Unit and then Present (Aux_Decls_Node (Comp_Unit)) and then Is_List_Member (N) and then List_Containing (N) = Pragmas_After (Aux_Decls_Node (Comp_Unit)); end Compilation_Unit_OK; ------------------------- -- Declarative_List_OK -- ------------------------- function Declarative_List_OK return Boolean is Context : constant Node_Id := Parent (Spec_Decl); Init_Decl : Node_Id; Init_List : List_Id; Prag_List : List_Id; begin -- Determine the proper initial declaration. In general this is -- the declaration node of the subprogram except when the input -- denotes a generic instantiation. -- procedure Inst is new Gen; -- pragma Inline_Always (Inst); -- In this case the original subprogram is moved inside an -- anonymous package while pragma Inline_Always remains at the -- level of the anonymous package. Use the declaration of the -- package because it reflects the placement of the original -- instantiation. -- package Anon_Pack is -- procedure Inst is ... end Inst; -- original -- end Anon_Pack; -- procedure Inst renames Anon_Pack.Inst; -- pragma Inline_Always (Inst); if Is_Generic_Instance (Spec_Id) then Init_Decl := Parent (Parent (Spec_Decl)); pragma Assert (Nkind (Init_Decl) = N_Package_Declaration); else Init_Decl := Spec_Decl; end if; if Is_List_Member (Init_Decl) and then Is_List_Member (N) then Init_List := List_Containing (Init_Decl); Prag_List := List_Containing (N); -- The pragma and then initial declaration appear within the -- same declarative list. if Init_List = Prag_List then return True; -- A special case of the above is when both the pragma and -- the initial declaration appear in different lists of a -- package spec, protected definition, or a task definition. -- package Pack is -- procedure Proc; -- private -- pragma Inline_Always (Proc); -- end Pack; elsif Nkind_In (Context, N_Package_Specification, N_Protected_Definition, N_Task_Definition) and then Init_List = Visible_Declarations (Context) and then Prag_List = Private_Declarations (Context) then return True; end if; end if; return False; end Declarative_List_OK; ------------------------ -- Subprogram_Body_OK -- ------------------------ function Subprogram_Body_OK return Boolean is Body_Decl : Node_Id; begin -- The pragma appears within the declarative list of a stand- -- alone subprogram body. -- procedure Stand_Alone_Body is -- pragma Inline_Always (Stand_Alone_Body); -- begin -- ... -- end Stand_Alone_Body; -- The compiler creates a dummy spec in this case, however the -- pragma remains within the declarative list of the body. if Nkind (Spec_Decl) = N_Subprogram_Declaration and then not Comes_From_Source (Spec_Decl) and then Present (Corresponding_Body (Spec_Decl)) then Body_Decl := Unit_Declaration_Node (Corresponding_Body (Spec_Decl)); if Present (Declarations (Body_Decl)) and then Is_List_Member (N) and then List_Containing (N) = Declarations (Body_Decl) then return True; end if; end if; return False; end Subprogram_Body_OK; -- Start of processing for Check_Inline_Always_Placement begin -- This check is relevant only for pragma Inline_Always if Pname /= Name_Inline_Always then return; -- Nothing to do when the pragma is internally generated on the -- assumption that it is properly placed. elsif not Comes_From_Source (N) then return; -- Nothing to do for internally generated subprograms that act -- as accidental homonyms of a source subprogram being inlined. elsif not Comes_From_Source (Spec_Id) then return; -- Nothing to do for generic formal subprograms that act as -- homonyms of another source subprogram being inlined. elsif Is_Formal_Subprogram (Spec_Id) then return; elsif Compilation_Unit_OK or else Declarative_List_OK or else Subprogram_Body_OK then return; end if; -- At this point it is known that the pragma applies to or appears -- within a completing body, a completing stub, or a subunit. Error_Msg_Name_1 := Pname; Error_Msg_Name_2 := Chars (Spec_Id); Error_Msg_Sloc := Sloc (Spec_Id); Error_Msg_N ("pragma % must appear on initial declaration of subprogram " & "% defined #", N); end Check_Inline_Always_Placement; --------------------------- -- Inlining_Not_Possible -- --------------------------- function Inlining_Not_Possible (Subp : Entity_Id) return Boolean is Decl : constant Node_Id := Unit_Declaration_Node (Subp); Stats : Node_Id; begin if Nkind (Decl) = N_Subprogram_Body then Stats := Handled_Statement_Sequence (Decl); return Present (Exception_Handlers (Stats)) or else Present (At_End_Proc (Stats)); elsif Nkind (Decl) = N_Subprogram_Declaration and then Present (Corresponding_Body (Decl)) then if Analyzed (Corresponding_Body (Decl)) then Error_Msg_N ("pragma appears too late, ignored??", N); return True; -- If the subprogram is a renaming as body, the body is just a -- call to the renamed subprogram, and inlining is trivially -- possible. elsif Nkind (Unit_Declaration_Node (Corresponding_Body (Decl))) = N_Subprogram_Renaming_Declaration then return False; else Stats := Handled_Statement_Sequence (Unit_Declaration_Node (Corresponding_Body (Decl))); return Present (Exception_Handlers (Stats)) or else Present (At_End_Proc (Stats)); 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 Inlining_Not_Possible; ----------------- -- Make_Inline -- ----------------- procedure Make_Inline (Subp : Entity_Id) is Kind : constant Entity_Kind := Ekind (Subp); Inner_Subp : Entity_Id := Subp; begin -- Ignore if bad type, avoid cascaded error if Etype (Subp) = Any_Type then Applies := True; return; -- If inlining is not possible, for now do not treat as an error elsif Status /= Suppressed and then Front_End_Inlining and then Inlining_Not_Possible (Subp) then Applies := True; return; -- Here we have a candidate for inlining, but we must exclude -- derived operations. Otherwise we would 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. We also need to recognize specs generated -- by the front-end for bodies that carry the pragma. Finally, -- predefined operators do not come from source but are not -- inlineable either. elsif Is_Generic_Instance (Subp) or else Nkind (Parent (Parent (Subp))) = N_Subprogram_Declaration then null; elsif not Comes_From_Source (Subp) and then Scope (Subp) /= Standard_Standard then Applies := True; return; end if; -- The referenced entity must either be the enclosing entity, or -- an entity declared within the current open scope. if 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 (if declared in the same unit) is inlined. -- If this is the anonymous subprogram created for a subprogram -- instance, the inlining applies to it directly. Otherwise we -- retrieve it as the alias of the visible subprogram instance. if Is_Subprogram (Subp) then -- Ensure that pragma Inline_Always is associated with the -- initial declaration of the subprogram. Check_Inline_Always_Placement (Subp); if Is_Wrapper_Package (Scope (Subp)) then Inner_Subp := Subp; else Inner_Subp := Ultimate_Alias (Inner_Subp); end if; if In_Same_Source_Unit (Subp, Inner_Subp) then 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)); elsif Is_Generic_Instance (Subp) and then Comes_From_Source (Subp) then -- Indicate that the body needs to be created for -- inlining subsequent calls. The instantiation node -- follows the declaration of the wrapper package -- created for it. The subprogram that requires the -- body is the anonymous one in the wrapper package. if Scope (Subp) /= Standard_Standard and then Need_Subprogram_Instance_Body (Next (Unit_Declaration_Node (Scope (Alias (Subp)))), Subp) then null; end if; -- Inline is a program unit pragma (RM 10.1.5) and cannot -- appear in a formal part to apply to a formal subprogram. -- Do not apply check within an instance or a formal package -- the test will have been applied to the original generic. elsif Nkind (Decl) in N_Formal_Subprogram_Declaration and then List_Containing (Decl) = List_Containing (N) and then not In_Instance then Error_Msg_N ("Inline cannot apply to a formal subprogram", N); -- If Subp is a renaming, it is the renamed entity that -- will appear in any call, and be inlined. However, for -- ASIS uses it is convenient to indicate that the renaming -- itself is an inlined subprogram, so that some gnatcheck -- rules can be applied in the absence of expansion. elsif Nkind (Decl) = N_Subprogram_Renaming_Declaration then Set_Inline_Flags (Subp); end if; 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 -- First set the Has_Pragma_XXX flags and issue the appropriate -- errors and warnings for suspicious combinations. if Prag_Id = Pragma_No_Inline then if Has_Pragma_Inline_Always (Subp) then Error_Msg_N ("Inline_Always and No_Inline are mutually exclusive", N); elsif Has_Pragma_Inline (Subp) then Error_Msg_NE ("Inline and No_Inline both specified for& ??", N, Entity (Subp_Id)); end if; Set_Has_Pragma_No_Inline (Subp); else if Prag_Id = Pragma_Inline_Always then if Has_Pragma_No_Inline (Subp) then Error_Msg_N ("Inline_Always and No_Inline are mutually exclusive", N); end if; Set_Has_Pragma_Inline_Always (Subp); else if Has_Pragma_No_Inline (Subp) then Error_Msg_NE ("Inline and No_Inline both specified for& ??", N, Entity (Subp_Id)); end if; end if; Set_Has_Pragma_Inline (Subp); end if; -- Then adjust the Is_Inlined flag. It can never be set if the -- subprogram is subject to pragma No_Inline. case Status is when Suppressed => Set_Is_Inlined (Subp, False); when Disabled => null; when Enabled => if not Has_Pragma_No_Inline (Subp) then Set_Is_Inlined (Subp, True); end if; end case; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Subp); -- Capture the entity of the first Ghost subprogram being -- processed for error detection purposes. if Is_Ghost_Entity (Subp) then if No (Ghost_Id) then Ghost_Id := Subp; end if; -- Otherwise the subprogram is non-Ghost. It is illegal to mix -- references to Ghost and non-Ghost entities (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and non-ghost subprograms", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (Subp); Error_Msg_NE ("\& # declared as non-ghost", N, Subp); end if; end Set_Inline_Flags; -- Start of processing for Process_Inline begin Check_No_Identifiers; Check_At_Least_N_Arguments (1); if Status = Enabled then Inline_Processing_Required := True; end if; Assoc := Arg1; while Present (Assoc) loop Subp_Id := Get_Pragma_Arg (Assoc); Analyze (Subp_Id); Applies := False; if Is_Entity_Name (Subp_Id) then Subp := Entity (Subp_Id); if Subp = Any_Id then -- If previous error, avoid cascaded errors Check_Error_Detected; Applies := True; else Make_Inline (Subp); -- For the pragma case, climb homonym chain. This is -- what implements allowing the pragma in the renaming -- case, with the result applying to the ancestors, and -- also allows Inline to apply to all previous homonyms. if not From_Aspect_Specification (N) then 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; end if; if not Applies then Error_Pragma_Arg ("inappropriate argument for pragma%", Assoc); end if; Next (Assoc); end loop; -- If the context is a package declaration, the pragma indicates -- that inlining will require the presence of the corresponding -- body. (this may be further refined). if not In_Instance and then Nkind (Unit (Cunit (Current_Sem_Unit))) = N_Package_Declaration then Set_Body_Needed_For_Inlining (Cunit_Entity (Current_Sem_Unit)); end if; end Process_Inline; ---------------------------- -- Process_Interface_Name -- ---------------------------- procedure Process_Interface_Name (Subprogram_Def : Entity_Id; Ext_Arg : Node_Id; Link_Arg : Node_Id; Prag : 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. ---------------------------------- -- Check_Form_Of_Interface_Name -- ---------------------------------- 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); -- Look for dubious character and issue unconditional warning. -- Definitely dubious if not in character range. if not In_Character_Range (C) -- Commas, spaces and (back)slashes are dubious or else Get_Character (C) = ',' or else Get_Character (C) = '\' or else Get_Character (C) = ' ' or else Get_Character (C) = '/' then Error_Msg ("??interface name contains illegal character", Sloc (SN) + Source_Ptr (J)); end if; end loop; end Check_Form_Of_Interface_Name; -- Start of processing for Process_Interface_Name begin -- If we are looking at a pragma that comes from an aspect then it -- needs to have its corresponding aspect argument expressions -- analyzed in addition to the generated pragma so that aspects -- within generic units get properly resolved. if Present (Prag) and then From_Aspect_Specification (Prag) then declare Asp : constant Node_Id := Corresponding_Aspect (Prag); Dummy_1 : Node_Id; Dummy_2 : Node_Id; Dummy_3 : Node_Id; EN : Node_Id; LN : Node_Id; begin -- Obtain all interfacing aspects used to construct the pragma Get_Interfacing_Aspects (Asp, Dummy_1, EN, Dummy_2, Dummy_3, LN); -- Analyze the expression of aspect External_Name if Present (EN) then Analyze (Expression (EN)); end if; -- Analyze the expressio of aspect Link_Name if Present (LN) then Analyze (Expression (LN)); end if; end; end if; 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_OK_Static_Expression (Ext_Nam, Standard_String); Check_Form_Of_Interface_Name (Ext_Nam); -- Verify that external name is not the name of a local entity, -- which would hide the imported one and could 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 will not conflict). declare Nam : Name_Id; E : Entity_Id; Par : Node_Id; begin if Prag_Id = Pragma_Import then Nam := String_To_Name (Strval (Expr_Value_S (Ext_Nam))); E := Entity_Id (Get_Name_Table_Int (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_OK_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 Link_Nam := 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)); Store_String_Chars (String_Val); Link_Nam := Make_String_Literal (Sloc (Link_Nam), Strval => End_String); end if; -- Set the interface name. If the entity is a generic instance, use -- its alias, which is the callable entity. if Is_Generic_Instance (Subprogram_Def) then Set_Encoded_Interface_Name (Alias (Get_Base_Subprogram (Subprogram_Def)), Link_Nam); else Set_Encoded_Interface_Name (Get_Base_Subprogram (Subprogram_Def), Link_Nam); end if; Check_Duplicated_Export_Name (Link_Nam); end Process_Interface_Name; ----------------------------------------- -- Process_Interrupt_Or_Attach_Handler -- ----------------------------------------- procedure Process_Interrupt_Or_Attach_Handler is Handler : constant Entity_Id := Entity (Get_Pragma_Arg (Arg1)); Prot_Typ : constant Entity_Id := Scope (Handler); begin -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Handler); Set_Is_Interrupt_Handler (Handler); pragma Assert (Ekind (Prot_Typ) = E_Protected_Type); Record_Rep_Item (Prot_Typ, N); -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Handler); end Process_Interrupt_Or_Attach_Handler; -------------------------------------------------- -- Process_Restrictions_Or_Restriction_Warnings -- -------------------------------------------------- -- Note: some of the simple identifier cases were handled in par-prag, -- but it is harmless (and more straightforward) to simply handle all -- cases here, even if it means we repeat a bit of work in some cases. procedure Process_Restrictions_Or_Restriction_Warnings (Warn : Boolean) is Arg : Node_Id; R_Id : Restriction_Id; Id : Name_Id; Expr : Node_Id; Val : Uint; begin -- Ignore all Restrictions pragmas in CodePeer mode if CodePeer_Mode then return; end if; Check_Ada_83_Warning; Check_At_Least_N_Arguments (1); Check_Valid_Configuration_Pragma; Arg := Arg1; while Present (Arg) loop Id := Chars (Arg); Expr := Get_Pragma_Arg (Arg); -- Case of no restriction identifier present if Id = No_Name then if Nkind (Expr) /= N_Identifier then Error_Pragma_Arg ("invalid form for restriction", Arg); end if; R_Id := Get_Restriction_Id (Process_Restriction_Synonyms (Expr)); if R_Id not in All_Boolean_Restrictions then Error_Msg_Name_1 := Pname; Error_Msg_N ("invalid restriction identifier&", Get_Pragma_Arg (Arg)); -- Check for possible misspelling for J in Restriction_Id loop declare Rnm : constant String := Restriction_Id'Image (J); begin Name_Buffer (1 .. Rnm'Length) := Rnm; Name_Len := Rnm'Length; Set_Casing (All_Lower_Case); if Is_Bad_Spelling_Of (Chars (Expr), Name_Enter) then Set_Casing (Identifier_Casing (Source_Index (Current_Sem_Unit))); Error_Msg_String (1 .. Rnm'Length) := Name_Buffer (1 .. Name_Len); Error_Msg_Strlen := Rnm'Length; Error_Msg_N -- CODEFIX ("\possible misspelling of ""~""", Get_Pragma_Arg (Arg)); exit; end if; end; end loop; raise Pragma_Exit; end if; if Implementation_Restriction (R_Id) then Check_Restriction (No_Implementation_Restrictions, Arg); end if; -- Special processing for No_Elaboration_Code restriction if R_Id = No_Elaboration_Code then -- Restriction is only recognized within a configuration -- pragma file, or within a unit of the main extended -- program. Note: the test for Main_Unit is needed to -- properly include the case of configuration pragma files. if not (Current_Sem_Unit = Main_Unit or else In_Extended_Main_Source_Unit (N)) then return; -- Don't allow in a subunit unless already specified in -- body or spec. elsif Nkind (Parent (N)) = N_Compilation_Unit and then Nkind (Unit (Parent (N))) = N_Subunit and then not Restriction_Active (No_Elaboration_Code) then Error_Msg_N ("invalid specification of ""No_Elaboration_Code""", N); Error_Msg_N ("\restriction cannot be specified in a subunit", N); Error_Msg_N ("\unless also specified in body or spec", N); return; -- If we accept a No_Elaboration_Code restriction, then it -- needs to be added to the configuration restriction set so -- that we get proper application to other units in the main -- extended source as required. else Add_To_Config_Boolean_Restrictions (No_Elaboration_Code); end if; end if; -- If this is a warning, then set the warning unless we already -- have a real restriction active (we never want a warning to -- override a real restriction). if Warn then if not Restriction_Active (R_Id) then Set_Restriction (R_Id, N); Restriction_Warnings (R_Id) := True; end if; -- If real restriction case, then set it and make sure that the -- restriction warning flag is off, since a real restriction -- always overrides a warning. else Set_Restriction (R_Id, N); Restriction_Warnings (R_Id) := False; end if; -- Check for obsolescent restrictions in Ada 2005 mode if not Warn and then Ada_Version >= Ada_2005 and then (R_Id = No_Asynchronous_Control or else R_Id = No_Unchecked_Deallocation or else R_Id = No_Unchecked_Conversion) then Check_Restriction (No_Obsolescent_Features, N); end if; -- 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). Restriction_Warnings never affects generated code -- so this is done only in the real restriction case. -- Atomic_Synchronization is not a real check, so it is not -- affected by this processing). -- Ignore the effect of pragma Restrictions (No_Exceptions) on -- run-time checks in CodePeer and GNATprove modes: we want to -- generate checks for analysis purposes, as set respectively -- by -gnatC and -gnatd.F if not Warn and then not (CodePeer_Mode or GNATprove_Mode) and then R_Id = No_Exceptions then for J in Scope_Suppress.Suppress'Range loop if J /= Atomic_Synchronization then Scope_Suppress.Suppress (J) := True; end if; end loop; end if; -- Case of No_Dependence => unit-name. Note that the parser -- already made the necessary entry in the No_Dependence table. elsif Id = Name_No_Dependence then if not OK_No_Dependence_Unit_Name (Expr) then raise Pragma_Exit; end if; -- Case of No_Specification_Of_Aspect => aspect-identifier elsif Id = Name_No_Specification_Of_Aspect then declare A_Id : Aspect_Id; begin if Nkind (Expr) /= N_Identifier then A_Id := No_Aspect; else A_Id := Get_Aspect_Id (Chars (Expr)); end if; if A_Id = No_Aspect then Error_Pragma_Arg ("invalid restriction name", Arg); else Set_Restriction_No_Specification_Of_Aspect (Expr, Warn); end if; end; -- Case of No_Use_Of_Attribute => attribute-identifier elsif Id = Name_No_Use_Of_Attribute then if Nkind (Expr) /= N_Identifier or else not Is_Attribute_Name (Chars (Expr)) then Error_Msg_N ("unknown attribute name??", Expr); else Set_Restriction_No_Use_Of_Attribute (Expr, Warn); end if; -- Case of No_Use_Of_Entity => fully-qualified-name elsif Id = Name_No_Use_Of_Entity then -- Restriction is only recognized within a configuration -- pragma file, or within a unit of the main extended -- program. Note: the test for Main_Unit is needed to -- properly include the case of configuration pragma files. if Current_Sem_Unit = Main_Unit or else In_Extended_Main_Source_Unit (N) then if not OK_No_Dependence_Unit_Name (Expr) then Error_Msg_N ("wrong form for entity name", Expr); else Set_Restriction_No_Use_Of_Entity (Expr, Warn, No_Profile); end if; end if; -- Case of No_Use_Of_Pragma => pragma-identifier elsif Id = Name_No_Use_Of_Pragma then if Nkind (Expr) /= N_Identifier or else not Is_Pragma_Name (Chars (Expr)) then Error_Msg_N ("unknown pragma name??", Expr); else Set_Restriction_No_Use_Of_Pragma (Expr, Warn); end if; -- All other cases of restriction identifier present else R_Id := Get_Restriction_Id (Process_Restriction_Synonyms (Arg)); 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); end if; -- Restriction pragma is active Val := Expr_Value (Expr); if not UI_Is_In_Int_Range (Val) then Error_Pragma_Arg ("pragma ignored, value too large??", Arg); end if; -- Warning case. If the real restriction is active, then we -- ignore the request, since warning never overrides a real -- restriction. Otherwise we set the proper warning. Note that -- this circuit sets the warning again if it is already set, -- which is what we want, since the constant may have changed. if Warn then if not Restriction_Active (R_Id) then Set_Restriction (R_Id, N, Integer (UI_To_Int (Val))); Restriction_Warnings (R_Id) := True; end if; -- Real restriction case, set restriction and make sure warning -- flag is off since real restriction always overrides warning. else Set_Restriction (R_Id, N, Integer (UI_To_Int (Val))); Restriction_Warnings (R_Id) := False; 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 : Entity_Id; E_Id : Node_Id; In_Package_Spec : constant Boolean := Is_Package_Or_Generic_Package (Current_Scope) 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 begin -- Check for error of trying to set atomic synchronization for -- a non-atomic variable. if C = Atomic_Synchronization and then not (Is_Atomic (E) or else Has_Atomic_Components (E)) then Error_Msg_N ("pragma & requires atomic type or variable", Pragma_Identifier (Original_Node (N))); end if; Set_Checks_May_Be_Suppressed (E); if In_Package_Spec then Push_Global_Suppress_Stack_Entry (Entity => E, Check => C, Suppress => Suppress_Case); else Push_Local_Suppress_Stack_Entry (Entity => E, Check => C, Suppress => Suppress_Case); 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 -- Ignore pragma Suppress/Unsuppress in CodePeer and GNATprove modes -- on user code: we want to generate checks for analysis purposes, as -- set respectively by -gnatC and -gnatd.F if Comes_From_Source (N) and then (CodePeer_Mode or GNATprove_Mode) then return; end if; -- 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); C := Get_Check_Id (Chars (Get_Pragma_Arg (Arg1))); if C = No_Check_Id then Error_Pragma_Arg ("argument of pragma% is not valid check name", Arg1); end if; -- Warn that suppress of Elaboration_Check has no effect in SPARK if C = Elaboration_Check and then SPARK_Mode = On then Error_Pragma_Arg ("Suppress of Elaboration_Check ignored in SPARK??", "\elaboration checking rules are statically enforced " & "(SPARK RM 7.7)", Arg1); end if; -- One-argument case 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 -- For All_Checks, we set all specific predefined checks with -- the exception of Elaboration_Check, which is handled -- specially because of not wanting All_Checks to have the -- effect of deactivating static elaboration order processing. -- Atomic_Synchronization is also not affected, since this is -- not a real check. for J in Scope_Suppress.Suppress'Range loop if J /= Elaboration_Check and then J /= Atomic_Synchronization then Scope_Suppress.Suppress (J) := Suppress_Case; end if; end loop; -- If not All_Checks, and predefined check, then set appropriate -- scope entry. Note that we will set Elaboration_Check if this -- is explicitly specified. Atomic_Synchronization is allowed -- only if internally generated and entity is atomic. elsif C in Predefined_Check_Id and then (not Comes_From_Source (N) or else C /= Atomic_Synchronization) then Scope_Suppress.Suppress (C) := Suppress_Case; end if; -- Also make an entry in the Local_Entity_Suppress table Push_Local_Suppress_Stack_Entry (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 -- This is obsolescent in Ada 2005 mode if Ada_Version >= Ada_2005 then Check_Restriction (No_Obsolescent_Features, Arg2); end if; Check_Optional_Identifier (Arg2, Name_On); E_Id := Get_Pragma_Arg (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; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); -- 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 (RM 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 if not aspect spec case exit when From_Aspect_Specification (N); 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; ------------------------------- -- Record_Independence_Check -- ------------------------------- procedure Record_Independence_Check (N : Node_Id; E : Entity_Id) is pragma Unreferenced (N, E); begin -- For GCC back ends the validation is done a priori -- ??? This code is dead, might be useful in the future -- if not AAMP_On_Target then -- return; -- end if; -- Independence_Checks.Append ((N, E)); return; end Record_Independence_Check; ------------------ -- 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)) and then not Relaxed_RM_Semantics 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); -- Warn if the corresponding W flag is set if Warn_On_Export_Import -- Only do this for something that was in the source. Not -- clear if this can be False now (there used for sure to be -- cases on some systems where it was False), but anyway the -- test is harmless if not needed, so it is retained. and then Comes_From_Source (Arg) then Error_Msg_NE ("?x?& has been made static as a result of Export", Arg, E); Error_Msg_N ("\?x?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?x?", 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?x?", 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; end if; Check_Arg_Is_External_Name (Arg_External); if 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); -- Check_Arg_Is_External_Name should let through only identifiers and -- string literals or static string expressions (which are folded to -- string literals). else raise Program_Error; 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 -- Ignore mismatching names in CodePeer mode, to support some -- old compilers which would export the same procedure under -- different names, e.g: -- procedure P; -- pragma Export_Procedure (P, "a"); -- pragma Export_Procedure (P, "b"); if CodePeer_Mode then return; end if; Check_Matching_Internal_Names : declare S1 : constant String_Id := Strval (Old_Name); S2 : constant String_Id := Strval (New_Name); procedure Mismatch; pragma No_Return (Mismatch); -- Called if names do not match -------------- -- Mismatch -- -------------- procedure Mismatch is begin Error_Msg_Sloc := Sloc (Old_Name); Error_Pragma_Arg ("external name does not match that given #", Arg_External); end Mismatch; -- Start of processing for Check_Matching_Internal_Names 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 Check_Matching_Internal_Names; -- Otherwise set the given name else Set_Encoded_Interface_Name (Internal_Ent, New_Name); Check_Duplicated_Export_Name (New_Name); end if; end Set_Extended_Import_Export_External_Name; ------------------ -- Set_Imported -- ------------------ procedure Set_Imported (E : Entity_Id) is begin -- Error message if already imported or exported if Is_Exported (E) or else Is_Imported (E) then -- Error if being set Exported twice if Is_Exported (E) then Error_Msg_NE ("entity& was previously exported", N, E); -- Ignore error in CodePeer mode where we treat all imported -- subprograms as unknown. elsif CodePeer_Mode then goto OK; -- OK if Import/Interface case elsif Import_Interface_Present (N) then goto OK; -- Error if being set Imported twice else Error_Msg_NE ("entity& was previously imported", N, E); end if; Error_Msg_Name_1 := Pname; Error_Msg_N ("\(pragma% applies to all previous entities)", N); Error_Msg_Sloc := Sloc (E); Error_Msg_NE ("\import not allowed for& declared#", N, E); -- Here if not previously imported or exported, OK to import else Set_Is_Imported (E); -- For subprogram, set Import_Pragma field if Is_Subprogram (E) then Set_Import_Pragma (E, N); end if; -- 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; <> null; 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 procedure Bad_Mechanism; pragma No_Return (Bad_Mechanism); -- Signal bad mechanism name ------------------- -- Bad_Mechanism -- ------------------- 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 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_Copy then Error_Pragma_Arg ("bad mechanism name, Value assumed", Mech_Name); else Bad_Mechanism; end if; else Bad_Mechanism; end if; end Set_Mechanism_Value; -------------------------- -- Set_Rational_Profile -- -------------------------- -- The Rational profile includes Implicit_Packing, Use_Vads_Size, and -- extension to the semantics of renaming declarations. procedure Set_Rational_Profile is begin Implicit_Packing := True; Overriding_Renamings := True; Use_VADS_Size := True; end Set_Rational_Profile; --------------------------- -- Set_Ravenscar_Profile -- --------------------------- -- The tasks to be done here are -- Set required policies -- pragma Task_Dispatching_Policy (FIFO_Within_Priorities) -- (For Ravenscar and GNAT_Extended_Ravenscar profiles) -- pragma Task_Dispatching_Policy (EDF_Across_Priorities) -- (For GNAT_Ravenscar_EDF profile) -- pragma Locking_Policy (Ceiling_Locking) -- Set Detect_Blocking mode -- Set required restrictions (see System.Rident for detailed list) -- Set the No_Dependence rules -- No_Dependence => Ada.Asynchronous_Task_Control -- No_Dependence => Ada.Calendar -- No_Dependence => Ada.Execution_Time.Group_Budget -- No_Dependence => Ada.Execution_Time.Timers -- No_Dependence => Ada.Task_Attributes -- No_Dependence => System.Multiprocessors.Dispatching_Domains procedure Set_Ravenscar_Profile (Profile : Profile_Name; N : Node_Id) is procedure Set_Error_Msg_To_Profile_Name; -- Set Error_Msg_String and Error_Msg_Strlen to the name of the -- profile. ----------------------------------- -- Set_Error_Msg_To_Profile_Name -- ----------------------------------- procedure Set_Error_Msg_To_Profile_Name is Prof_Nam : constant Node_Id := Get_Pragma_Arg (First (Pragma_Argument_Associations (N))); begin Get_Name_String (Chars (Prof_Nam)); Adjust_Name_Case (Global_Name_Buffer, Sloc (Prof_Nam)); Error_Msg_Strlen := Name_Len; Error_Msg_String (1 .. Name_Len) := Name_Buffer (1 .. Name_Len); end Set_Error_Msg_To_Profile_Name; -- Local variables Nod : Node_Id; Pref : Node_Id; Pref_Id : Node_Id; Sel_Id : Node_Id; Profile_Dispatching_Policy : Character; -- Start of processing for Set_Ravenscar_Profile begin -- pragma Task_Dispatching_Policy (EDF_Across_Priorities) if Profile = GNAT_Ravenscar_EDF then Profile_Dispatching_Policy := 'E'; -- pragma Task_Dispatching_Policy (FIFO_Within_Priorities) else Profile_Dispatching_Policy := 'F'; end if; if Task_Dispatching_Policy /= ' ' and then Task_Dispatching_Policy /= Profile_Dispatching_Policy then Error_Msg_Sloc := Task_Dispatching_Policy_Sloc; Set_Error_Msg_To_Profile_Name; Error_Pragma ("Profile (~) incompatible with policy#"); -- Set the FIFO_Within_Priorities policy, but always preserve -- System_Location since we like the error message with the run time -- name. else Task_Dispatching_Policy := Profile_Dispatching_Policy; if Task_Dispatching_Policy_Sloc /= System_Location then Task_Dispatching_Policy_Sloc := Loc; end if; end if; -- pragma Locking_Policy (Ceiling_Locking) if Locking_Policy /= ' ' and then Locking_Policy /= 'C' then Error_Msg_Sloc := Locking_Policy_Sloc; Set_Error_Msg_To_Profile_Name; Error_Pragma ("Profile (~) incompatible with policy#"); -- Set the Ceiling_Locking policy, but preserve System_Location since -- we like the error message with the run time name. else Locking_Policy := 'C'; if Locking_Policy_Sloc /= System_Location then Locking_Policy_Sloc := Loc; end if; end if; -- pragma Detect_Blocking Detect_Blocking := True; -- Set the corresponding restrictions Set_Profile_Restrictions (Profile, N, Warn => Treat_Restrictions_As_Warnings); -- Set the No_Dependence restrictions -- The following No_Dependence restrictions: -- No_Dependence => Ada.Asynchronous_Task_Control -- No_Dependence => Ada.Calendar -- No_Dependence => Ada.Task_Attributes -- are already set by previous call to Set_Profile_Restrictions. -- Set the following restrictions which were added to Ada 2005: -- No_Dependence => Ada.Execution_Time.Group_Budget -- No_Dependence => Ada.Execution_Time.Timers if Ada_Version >= Ada_2005 then Pref_Id := Make_Identifier (Loc, Name_Find ("ada")); Sel_Id := Make_Identifier (Loc, Name_Find ("execution_time")); Pref := Make_Selected_Component (Sloc => Loc, Prefix => Pref_Id, Selector_Name => Sel_Id); Sel_Id := Make_Identifier (Loc, Name_Find ("group_budgets")); Nod := Make_Selected_Component (Sloc => Loc, Prefix => Pref, Selector_Name => Sel_Id); Set_Restriction_No_Dependence (Unit => Nod, Warn => Treat_Restrictions_As_Warnings, Profile => Ravenscar); Sel_Id := Make_Identifier (Loc, Name_Find ("timers")); Nod := Make_Selected_Component (Sloc => Loc, Prefix => Pref, Selector_Name => Sel_Id); Set_Restriction_No_Dependence (Unit => Nod, Warn => Treat_Restrictions_As_Warnings, Profile => Ravenscar); end if; -- Set the following restriction which was added to Ada 2012 (see -- AI-0171): -- No_Dependence => System.Multiprocessors.Dispatching_Domains if Ada_Version >= Ada_2012 then Pref_Id := Make_Identifier (Loc, Name_Find ("system")); Sel_Id := Make_Identifier (Loc, Name_Find ("multiprocessors")); Pref := Make_Selected_Component (Sloc => Loc, Prefix => Pref_Id, Selector_Name => Sel_Id); Sel_Id := Make_Identifier (Loc, Name_Find ("dispatching_domains")); Nod := Make_Selected_Component (Sloc => Loc, Prefix => Pref, Selector_Name => Sel_Id); Set_Restriction_No_Dependence (Unit => Nod, Warn => Treat_Restrictions_As_Warnings, Profile => Ravenscar); end if; end Set_Ravenscar_Profile; ----------------------------------- -- Validate_Acc_Condition_Clause -- ----------------------------------- procedure Validate_Acc_Condition_Clause (Clause : Node_Id) is begin Analyze_And_Resolve (Clause); if not Is_Boolean_Type (Etype (Clause)) then Error_Pragma ("expected a boolean"); end if; end Validate_Acc_Condition_Clause; ------------------------------ -- Validate_Acc_Data_Clause -- ------------------------------ procedure Validate_Acc_Data_Clause (Clause : Node_Id) is Expr : Node_Id; begin Expr := Acc_First (Clause); while Present (Expr) loop if Nkind (Expr) /= N_Identifier then Error_Pragma ("expected an identifer"); end if; Analyze_And_Resolve (Expr); Expr := Acc_Next (Expr); end loop; end Validate_Acc_Data_Clause; ---------------------------------- -- Validate_Acc_Int_Expr_Clause -- ---------------------------------- procedure Validate_Acc_Int_Expr_Clause (Clause : Node_Id) is begin Analyze_And_Resolve (Clause); if not Is_Integer_Type (Etype (Clause)) then Error_Pragma_Arg ("expected an integer", Clause); end if; end Validate_Acc_Int_Expr_Clause; --------------------------------------- -- Validate_Acc_Int_Expr_List_Clause -- --------------------------------------- procedure Validate_Acc_Int_Expr_List_Clause (Clause : Node_Id) is Expr : Node_Id; begin Expr := Acc_First (Clause); while Present (Expr) loop Analyze_And_Resolve (Expr); if not Is_Integer_Type (Etype (Expr)) then Error_Pragma ("expected an integer"); end if; Expr := Acc_Next (Expr); end loop; end Validate_Acc_Int_Expr_List_Clause; -------------------------------- -- Validate_Acc_Loop_Collapse -- -------------------------------- procedure Validate_Acc_Loop_Collapse (Clause : Node_Id) is Count : Uint; Par_Loop : Node_Id; Stmt : Node_Id; begin -- Make sure the argument is a positive integer Analyze_And_Resolve (Clause); Count := Static_Integer (Clause); if Count = No_Uint or else Count < 1 then Error_Pragma_Arg ("expected a positive integer", Clause); end if; -- Then, make sure we have at least Count-1 tightly-nested loops -- (i.e. loops with no statements in between). Par_Loop := Parent (Parent (Parent (Clause))); Stmt := First (Statements (Par_Loop)); -- Skip first pragmas in the parent loop while Present (Stmt) and then Nkind (Stmt) = N_Pragma loop Next (Stmt); end loop; if not Present (Next (Stmt)) then while Nkind (Stmt) = N_Loop_Statement and Count > 1 loop Stmt := First (Statements (Stmt)); exit when Present (Next (Stmt)); Count := Count - 1; end loop; end if; if Count > 1 then Error_Pragma_Arg ("Collapse argument too high or loops not tightly nested", Clause); end if; end Validate_Acc_Loop_Collapse; ---------------------------- -- Validate_Acc_Loop_Gang -- ---------------------------- procedure Validate_Acc_Loop_Gang (Clause : Node_Id) is begin Error_Pragma_Arg ("Loop_Gang not implemented", Clause); end Validate_Acc_Loop_Gang; ------------------------------ -- Validate_Acc_Loop_Vector -- ------------------------------ procedure Validate_Acc_Loop_Vector (Clause : Node_Id) is begin Error_Pragma_Arg ("Loop_Vector not implemented", Clause); end Validate_Acc_Loop_Vector; ------------------------------- -- Validate_Acc_Loop_Worker -- ------------------------------- procedure Validate_Acc_Loop_Worker (Clause : Node_Id) is begin Error_Pragma_Arg ("Loop_Worker not implemented", Clause); end Validate_Acc_Loop_Worker; --------------------------------- -- Validate_Acc_Name_Reduction -- --------------------------------- procedure Validate_Acc_Name_Reduction (Clause : Node_Id) is -- ??? On top of the following operations, the OpenAcc spec adds the -- "bitwise and", "bitwise or" and modulo for C and ".eqv" and -- ".neqv" for Fortran. Can we, should we and how do we support them -- in Ada? type Reduction_Op is (Add_Op, Mul_Op, Max_Op, Min_Op, And_Op, Or_Op); function To_Reduction_Op (Op : String) return Reduction_Op; -- Convert operator Op described by a String into its corresponding -- enumeration value. --------------------- -- To_Reduction_Op -- --------------------- function To_Reduction_Op (Op : String) return Reduction_Op is begin if Op = "+" then return Add_Op; elsif Op = "*" then return Mul_Op; elsif Op = "max" then return Max_Op; elsif Op = "min" then return Min_Op; elsif Op = "and" then return And_Op; elsif Op = "or" then return Or_Op; else Error_Pragma ("unsuported reduction operation"); end if; end To_Reduction_Op; -- Local variables Seen : constant Elist_Id := New_Elmt_List; Expr : Node_Id; Reduc_Op : Node_Id; Reduc_Var : Node_Id; -- Start of processing for Validate_Acc_Name_Reduction begin -- Reduction operations appear in the following form: -- ("+" => (a, b), "*" => c) Expr := First (Component_Associations (Clause)); while Present (Expr) loop Reduc_Op := First (Choices (Expr)); String_To_Name_Buffer (Strval (Reduc_Op)); case To_Reduction_Op (Name_Buffer (1 .. Name_Len)) is when Add_Op | Mul_Op | Max_Op | Min_Op => Reduc_Var := Acc_First (Expression (Expr)); while Present (Reduc_Var) loop Analyze_And_Resolve (Reduc_Var); if Contains (Seen, Entity (Reduc_Var)) then Error_Pragma ("variable used in multiple reductions"); else if Nkind (Reduc_Var) /= N_Identifier or not Is_Numeric_Type (Etype (Reduc_Var)) then Error_Pragma ("expected an identifier for a Numeric"); end if; Append_Elmt (Entity (Reduc_Var), Seen); end if; Reduc_Var := Acc_Next (Reduc_Var); end loop; when And_Op | Or_Op => Reduc_Var := Acc_First (Expression (Expr)); while Present (Reduc_Var) loop Analyze_And_Resolve (Reduc_Var); if Contains (Seen, Entity (Reduc_Var)) then Error_Pragma ("variable used in multiple reductions"); else if Nkind (Reduc_Var) /= N_Identifier or not Is_Boolean_Type (Etype (Reduc_Var)) then Error_Pragma ("expected a variable of type boolean"); end if; Append_Elmt (Entity (Reduc_Var), Seen); end if; Reduc_Var := Acc_Next (Reduc_Var); end loop; end case; Next (Expr); end loop; end Validate_Acc_Name_Reduction; ----------------------------------- -- Validate_Acc_Size_Expressions -- ----------------------------------- procedure Validate_Acc_Size_Expressions (Clause : Node_Id) is function Validate_Size_Expr (Expr : Node_Id) return Boolean; -- A size expr is either an integer expression or "*" ------------------------ -- Validate_Size_Expr -- ------------------------ function Validate_Size_Expr (Expr : Node_Id) return Boolean is begin if Nkind (Expr) = N_Operator_Symbol then return Get_String_Char (Strval (Expr), 1) = Get_Char_Code ('*'); end if; Analyze_And_Resolve (Expr); return Is_Integer_Type (Etype (Expr)); end Validate_Size_Expr; -- Local variables Expr : Node_Id; -- Start of processing for Validate_Acc_Size_Expressions begin Expr := Acc_First (Clause); while Present (Expr) loop if not Validate_Size_Expr (Expr) then Error_Pragma ("Size expressions should be either integers or '*'"); end if; Expr := Acc_Next (Expr); end loop; end Validate_Acc_Size_Expressions; -- Start of processing for Analyze_Pragma begin -- The following code is a defense against recursion. Not clear that -- this can happen legitimately, but perhaps some error situations can -- cause it, and we did see this recursion during testing. if Analyzed (N) then return; else Set_Analyzed (N); end if; Check_Restriction_No_Use_Of_Pragma (N); -- Ignore pragma if Ignore_Pragma applies. Also ignore pragma -- Default_Scalar_Storage_Order if the -gnatI switch was given. if Should_Ignore_Pragma_Sem (N) or else (Prag_Id = Pragma_Default_Scalar_Storage_Order and then Ignore_Rep_Clauses) then return; end if; -- Deal with unrecognized pragma if not Is_Pragma_Name (Pname) then if Warn_On_Unrecognized_Pragma then Error_Msg_Name_1 := Pname; Error_Msg_N ("?g?unrecognized pragma%!", Pragma_Identifier (N)); for PN in First_Pragma_Name .. Last_Pragma_Name loop if Is_Bad_Spelling_Of (Pname, PN) then Error_Msg_Name_1 := PN; Error_Msg_N -- CODEFIX ("\?g?possible misspelling of %!", Pragma_Identifier (N)); exit; end if; end loop; end if; return; end if; -- Here to start processing for recognized pragma Pname := Original_Aspect_Pragma_Name (N); -- Capture setting of Opt.Uneval_Old case Opt.Uneval_Old is when 'A' => Set_Uneval_Old_Accept (N); when 'E' => null; when 'W' => Set_Uneval_Old_Warn (N); when others => raise Program_Error; end case; -- Check applicable policy. We skip this if Is_Checked or Is_Ignored -- is already set, indicating that we have already checked the policy -- at the right point. This happens for example in the case of a pragma -- that is derived from an Aspect. if Is_Ignored (N) or else Is_Checked (N) then null; -- For a pragma that is a rewriting of another pragma, copy the -- Is_Checked/Is_Ignored status from the rewritten pragma. elsif Is_Rewrite_Substitution (N) and then Nkind (Original_Node (N)) = N_Pragma then Set_Is_Ignored (N, Is_Ignored (Original_Node (N))); Set_Is_Checked (N, Is_Checked (Original_Node (N))); -- Otherwise query the applicable policy at this point else Check_Applicable_Policy (N); -- If pragma is disabled, rewrite as NULL and skip analysis if Is_Disabled (N) then Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); raise Pragma_Exit; end if; end if; -- Preset arguments Arg_Count := 0; Arg1 := Empty; Arg2 := Empty; Arg3 := Empty; Arg4 := Empty; if Present (Pragma_Argument_Associations (N)) then Arg_Count := List_Length (Pragma_Argument_Associations (N)); 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; -- An enumeration type defines the pragmas that are supported by the -- implementation. Get_Pragma_Id (in package Prag) transforms 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; -------------------- -- Abstract_State -- -------------------- -- pragma Abstract_State (ABSTRACT_STATE_LIST); -- ABSTRACT_STATE_LIST ::= -- null -- | STATE_NAME_WITH_OPTIONS -- | (STATE_NAME_WITH_OPTIONS {, STATE_NAME_WITH_OPTIONS}) -- STATE_NAME_WITH_OPTIONS ::= -- STATE_NAME -- | (STATE_NAME with OPTION_LIST) -- OPTION_LIST ::= OPTION {, OPTION} -- OPTION ::= -- SIMPLE_OPTION -- | NAME_VALUE_OPTION -- SIMPLE_OPTION ::= Ghost | Synchronous -- NAME_VALUE_OPTION ::= -- Part_Of => ABSTRACT_STATE -- | External [=> EXTERNAL_PROPERTY_LIST] -- EXTERNAL_PROPERTY_LIST ::= -- EXTERNAL_PROPERTY -- | (EXTERNAL_PROPERTY {, EXTERNAL_PROPERTY}) -- EXTERNAL_PROPERTY ::= -- Async_Readers [=> boolean_EXPRESSION] -- | Async_Writers [=> boolean_EXPRESSION] -- | Effective_Reads [=> boolean_EXPRESSION] -- | Effective_Writes [=> boolean_EXPRESSION] -- others => boolean_EXPRESSION -- STATE_NAME ::= defining_identifier -- ABSTRACT_STATE ::= name -- Characteristics: -- * Analysis - The annotation is fully analyzed immediately upon -- elaboration as it cannot forward reference entities. -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related package declaration. -- * Globals - The annotation cannot reference global entities. -- * Instance - The annotation is instantiated automatically when -- the related generic package is instantiated. when Pragma_Abstract_State => Abstract_State : declare Missing_Parentheses : Boolean := False; -- Flag set when a state declaration with options is not properly -- parenthesized. -- Flags used to verify the consistency of states Non_Null_Seen : Boolean := False; Null_Seen : Boolean := False; procedure Analyze_Abstract_State (State : Node_Id; Pack_Id : Entity_Id); -- Verify the legality of a single state declaration. Create and -- decorate a state abstraction entity and introduce it into the -- visibility chain. Pack_Id denotes the entity or the related -- package where pragma Abstract_State appears. procedure Malformed_State_Error (State : Node_Id); -- Emit an error concerning the illegal declaration of abstract -- state State. This routine diagnoses syntax errors that lead to -- a different parse tree. The error is issued regardless of the -- SPARK mode in effect. ---------------------------- -- Analyze_Abstract_State -- ---------------------------- procedure Analyze_Abstract_State (State : Node_Id; Pack_Id : Entity_Id) is -- Flags used to verify the consistency of options AR_Seen : Boolean := False; AW_Seen : Boolean := False; ER_Seen : Boolean := False; EW_Seen : Boolean := False; External_Seen : Boolean := False; Ghost_Seen : Boolean := False; Others_Seen : Boolean := False; Part_Of_Seen : Boolean := False; Synchronous_Seen : Boolean := False; -- Flags used to store the static value of all external states' -- expressions. AR_Val : Boolean := False; AW_Val : Boolean := False; ER_Val : Boolean := False; EW_Val : Boolean := False; State_Id : Entity_Id := Empty; -- The entity to be generated for the current state declaration procedure Analyze_External_Option (Opt : Node_Id); -- Verify the legality of option External procedure Analyze_External_Property (Prop : Node_Id; Expr : Node_Id := Empty); -- Verify the legailty of a single external property. Prop -- denotes the external property. Expr is the expression used -- to set the property. procedure Analyze_Part_Of_Option (Opt : Node_Id); -- Verify the legality of option Part_Of procedure Check_Duplicate_Option (Opt : Node_Id; Status : in out Boolean); -- Flag Status denotes whether a particular option has been -- seen while processing a state. This routine verifies that -- Opt is not a duplicate option and sets the flag Status -- (SPARK RM 7.1.4(1)). procedure Check_Duplicate_Property (Prop : Node_Id; Status : in out Boolean); -- Flag Status denotes whether a particular property has been -- seen while processing option External. This routine verifies -- that Prop is not a duplicate property and sets flag Status. -- Opt is not a duplicate property and sets the flag Status. -- (SPARK RM 7.1.4(2)) procedure Check_Ghost_Synchronous; -- Ensure that the abstract state is not subject to both Ghost -- and Synchronous simple options. Emit an error if this is the -- case. procedure Create_Abstract_State (Nam : Name_Id; Decl : Node_Id; Loc : Source_Ptr; Is_Null : Boolean); -- Generate an abstract state entity with name Nam and enter it -- into visibility. Decl is the "declaration" of the state as -- it appears in pragma Abstract_State. Loc is the location of -- the related state "declaration". Flag Is_Null should be set -- when the associated Abstract_State pragma defines a null -- state. ----------------------------- -- Analyze_External_Option -- ----------------------------- procedure Analyze_External_Option (Opt : Node_Id) is Errors : constant Nat := Serious_Errors_Detected; Prop : Node_Id; Props : Node_Id := Empty; begin if Nkind (Opt) = N_Component_Association then Props := Expression (Opt); end if; -- External state with properties if Present (Props) then -- Multiple properties appear as an aggregate if Nkind (Props) = N_Aggregate then -- Simple property form Prop := First (Expressions (Props)); while Present (Prop) loop Analyze_External_Property (Prop); Next (Prop); end loop; -- Property with expression form Prop := First (Component_Associations (Props)); while Present (Prop) loop Analyze_External_Property (Prop => First (Choices (Prop)), Expr => Expression (Prop)); Next (Prop); end loop; -- Single property else Analyze_External_Property (Props); end if; -- An external state defined without any properties defaults -- all properties to True. else AR_Val := True; AW_Val := True; ER_Val := True; EW_Val := True; end if; -- Once all external properties have been processed, verify -- their mutual interaction. Do not perform the check when -- at least one of the properties is illegal as this will -- produce a bogus error. if Errors = Serious_Errors_Detected then Check_External_Properties (State, AR_Val, AW_Val, ER_Val, EW_Val); end if; end Analyze_External_Option; ------------------------------- -- Analyze_External_Property -- ------------------------------- procedure Analyze_External_Property (Prop : Node_Id; Expr : Node_Id := Empty) is Expr_Val : Boolean; begin -- Check the placement of "others" (if available) if Nkind (Prop) = N_Others_Choice then if Others_Seen then SPARK_Msg_N ("only one others choice allowed in option External", Prop); else Others_Seen := True; end if; elsif Others_Seen then SPARK_Msg_N ("others must be the last property in option External", Prop); -- The only remaining legal options are the four predefined -- external properties. elsif Nkind (Prop) = N_Identifier and then Nam_In (Chars (Prop), Name_Async_Readers, Name_Async_Writers, Name_Effective_Reads, Name_Effective_Writes) then null; -- Otherwise the construct is not a valid property else SPARK_Msg_N ("invalid external state property", Prop); return; end if; -- Ensure that the expression of the external state property -- is static Boolean (if applicable) (SPARK RM 7.1.2(5)). if Present (Expr) then Analyze_And_Resolve (Expr, Standard_Boolean); if Is_OK_Static_Expression (Expr) then Expr_Val := Is_True (Expr_Value (Expr)); else SPARK_Msg_N ("expression of external state property must be " & "static", Expr); return; end if; -- The lack of expression defaults the property to True else Expr_Val := True; end if; -- Named properties if Nkind (Prop) = N_Identifier then if Chars (Prop) = Name_Async_Readers then Check_Duplicate_Property (Prop, AR_Seen); AR_Val := Expr_Val; elsif Chars (Prop) = Name_Async_Writers then Check_Duplicate_Property (Prop, AW_Seen); AW_Val := Expr_Val; elsif Chars (Prop) = Name_Effective_Reads then Check_Duplicate_Property (Prop, ER_Seen); ER_Val := Expr_Val; else Check_Duplicate_Property (Prop, EW_Seen); EW_Val := Expr_Val; end if; -- The handling of property "others" must take into account -- all other named properties that have been encountered so -- far. Only those that have not been seen are affected by -- "others". else if not AR_Seen then AR_Val := Expr_Val; end if; if not AW_Seen then AW_Val := Expr_Val; end if; if not ER_Seen then ER_Val := Expr_Val; end if; if not EW_Seen then EW_Val := Expr_Val; end if; end if; end Analyze_External_Property; ---------------------------- -- Analyze_Part_Of_Option -- ---------------------------- procedure Analyze_Part_Of_Option (Opt : Node_Id) is Encap : constant Node_Id := Expression (Opt); Constits : Elist_Id; Encap_Id : Entity_Id; Legal : Boolean; begin Check_Duplicate_Option (Opt, Part_Of_Seen); Analyze_Part_Of (Indic => First (Choices (Opt)), Item_Id => State_Id, Encap => Encap, Encap_Id => Encap_Id, Legal => Legal); -- The Part_Of indicator transforms the abstract state into -- a constituent of the encapsulating state or single -- concurrent type. if Legal then pragma Assert (Present (Encap_Id)); Constits := Part_Of_Constituents (Encap_Id); if No (Constits) then Constits := New_Elmt_List; Set_Part_Of_Constituents (Encap_Id, Constits); end if; Append_Elmt (State_Id, Constits); Set_Encapsulating_State (State_Id, Encap_Id); end if; end Analyze_Part_Of_Option; ---------------------------- -- Check_Duplicate_Option -- ---------------------------- procedure Check_Duplicate_Option (Opt : Node_Id; Status : in out Boolean) is begin if Status then SPARK_Msg_N ("duplicate state option", Opt); end if; Status := True; end Check_Duplicate_Option; ------------------------------ -- Check_Duplicate_Property -- ------------------------------ procedure Check_Duplicate_Property (Prop : Node_Id; Status : in out Boolean) is begin if Status then SPARK_Msg_N ("duplicate external property", Prop); end if; Status := True; end Check_Duplicate_Property; ----------------------------- -- Check_Ghost_Synchronous -- ----------------------------- procedure Check_Ghost_Synchronous is begin -- A synchronized abstract state cannot be Ghost and vice -- versa (SPARK RM 6.9(19)). if Ghost_Seen and Synchronous_Seen then SPARK_Msg_N ("synchronized state cannot be ghost", State); end if; end Check_Ghost_Synchronous; --------------------------- -- Create_Abstract_State -- --------------------------- procedure Create_Abstract_State (Nam : Name_Id; Decl : Node_Id; Loc : Source_Ptr; Is_Null : Boolean) is begin -- The abstract state may be semi-declared when the related -- package was withed through a limited with clause. In that -- case reuse the entity to fully declare the state. if Present (Decl) and then Present (Entity (Decl)) then State_Id := Entity (Decl); -- Otherwise the elaboration of pragma Abstract_State -- declares the state. else State_Id := Make_Defining_Identifier (Loc, Nam); if Present (Decl) then Set_Entity (Decl, State_Id); end if; end if; -- Null states never come from source Set_Comes_From_Source (State_Id, not Is_Null); Set_Parent (State_Id, State); Set_Ekind (State_Id, E_Abstract_State); Set_Etype (State_Id, Standard_Void_Type); Set_Encapsulating_State (State_Id, Empty); -- Set the SPARK mode from the current context Set_SPARK_Pragma (State_Id, SPARK_Mode_Pragma); Set_SPARK_Pragma_Inherited (State_Id); -- An abstract state declared within a Ghost region becomes -- Ghost (SPARK RM 6.9(2)). if Ghost_Mode > None or else Is_Ghost_Entity (Pack_Id) then Set_Is_Ghost_Entity (State_Id); end if; -- Establish a link between the state declaration and the -- abstract state entity. Note that a null state remains as -- N_Null and does not carry any linkages. if not Is_Null then if Present (Decl) then Set_Entity (Decl, State_Id); Set_Etype (Decl, Standard_Void_Type); end if; -- Every non-null state must be defined, nameable and -- resolvable. Push_Scope (Pack_Id); Generate_Definition (State_Id); Enter_Name (State_Id); Pop_Scope; end if; end Create_Abstract_State; -- Local variables Opt : Node_Id; Opt_Nam : Node_Id; -- Start of processing for Analyze_Abstract_State begin -- A package with a null abstract state is not allowed to -- declare additional states. if Null_Seen then SPARK_Msg_NE ("package & has null abstract state", State, Pack_Id); -- Null states appear as internally generated entities elsif Nkind (State) = N_Null then Create_Abstract_State (Nam => New_Internal_Name ('S'), Decl => Empty, Loc => Sloc (State), Is_Null => True); Null_Seen := True; -- Catch a case where a null state appears in a list of -- non-null states. if Non_Null_Seen then SPARK_Msg_NE ("package & has non-null abstract state", State, Pack_Id); end if; -- Simple state declaration elsif Nkind (State) = N_Identifier then Create_Abstract_State (Nam => Chars (State), Decl => State, Loc => Sloc (State), Is_Null => False); Non_Null_Seen := True; -- State declaration with various options. This construct -- appears as an extension aggregate in the tree. elsif Nkind (State) = N_Extension_Aggregate then if Nkind (Ancestor_Part (State)) = N_Identifier then Create_Abstract_State (Nam => Chars (Ancestor_Part (State)), Decl => Ancestor_Part (State), Loc => Sloc (Ancestor_Part (State)), Is_Null => False); Non_Null_Seen := True; else SPARK_Msg_N ("state name must be an identifier", Ancestor_Part (State)); end if; -- Options External, Ghost and Synchronous appear as -- expressions. Opt := First (Expressions (State)); while Present (Opt) loop if Nkind (Opt) = N_Identifier then -- External if Chars (Opt) = Name_External then Check_Duplicate_Option (Opt, External_Seen); Analyze_External_Option (Opt); -- Ghost elsif Chars (Opt) = Name_Ghost then Check_Duplicate_Option (Opt, Ghost_Seen); Check_Ghost_Synchronous; if Present (State_Id) then Set_Is_Ghost_Entity (State_Id); end if; -- Synchronous elsif Chars (Opt) = Name_Synchronous then Check_Duplicate_Option (Opt, Synchronous_Seen); Check_Ghost_Synchronous; -- Option Part_Of without an encapsulating state is -- illegal (SPARK RM 7.1.4(9)). elsif Chars (Opt) = Name_Part_Of then SPARK_Msg_N ("indicator Part_Of must denote abstract state, " & "single protected type or single task type", Opt); -- Do not emit an error message when a previous state -- declaration with options was not parenthesized as -- the option is actually another state declaration. -- -- with Abstract_State -- (State_1 with ..., -- missing parentheses -- (State_2 with ...), -- State_3) -- ok state declaration elsif Missing_Parentheses then null; -- Otherwise the option is not allowed. Note that it -- is not possible to distinguish between an option -- and a state declaration when a previous state with -- options not properly parentheses. -- -- with Abstract_State -- (State_1 with ..., -- missing parentheses -- State_2); -- could be an option else SPARK_Msg_N ("simple option not allowed in state declaration", Opt); end if; -- Catch a case where missing parentheses around a state -- declaration with options cause a subsequent state -- declaration with options to be treated as an option. -- -- with Abstract_State -- (State_1 with ..., -- missing parentheses -- (State_2 with ...)) elsif Nkind (Opt) = N_Extension_Aggregate then Missing_Parentheses := True; SPARK_Msg_N ("state declaration must be parenthesized", Ancestor_Part (State)); -- Otherwise the option is malformed else SPARK_Msg_N ("malformed option", Opt); end if; Next (Opt); end loop; -- Options External and Part_Of appear as component -- associations. Opt := First (Component_Associations (State)); while Present (Opt) loop Opt_Nam := First (Choices (Opt)); if Nkind (Opt_Nam) = N_Identifier then if Chars (Opt_Nam) = Name_External then Analyze_External_Option (Opt); elsif Chars (Opt_Nam) = Name_Part_Of then Analyze_Part_Of_Option (Opt); else SPARK_Msg_N ("invalid state option", Opt); end if; else SPARK_Msg_N ("invalid state option", Opt); end if; Next (Opt); end loop; -- Any other attempt to declare a state is illegal else Malformed_State_Error (State); return; end if; -- Guard against a junk state. In such cases no entity is -- generated and the subsequent checks cannot be applied. if Present (State_Id) then -- Verify whether the state does not introduce an illegal -- hidden state within a package subject to a null abstract -- state. Check_No_Hidden_State (State_Id); -- Check whether the lack of option Part_Of agrees with the -- placement of the abstract state with respect to the state -- space. if not Part_Of_Seen then Check_Missing_Part_Of (State_Id); end if; -- Associate the state with its related package if No (Abstract_States (Pack_Id)) then Set_Abstract_States (Pack_Id, New_Elmt_List); end if; Append_Elmt (State_Id, Abstract_States (Pack_Id)); end if; end Analyze_Abstract_State; --------------------------- -- Malformed_State_Error -- --------------------------- procedure Malformed_State_Error (State : Node_Id) is begin Error_Msg_N ("malformed abstract state declaration", State); -- An abstract state with a simple option is being declared -- with "=>" rather than the legal "with". The state appears -- as a component association. if Nkind (State) = N_Component_Association then Error_Msg_N ("\use WITH to specify simple option", State); end if; end Malformed_State_Error; -- Local variables Pack_Decl : Node_Id; Pack_Id : Entity_Id; State : Node_Id; States : Node_Id; -- Start of processing for Abstract_State begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Pack_Decl := Find_Related_Package_Or_Body (N, Do_Checks => True); if not Nkind_In (Pack_Decl, N_Generic_Package_Declaration, N_Package_Declaration) then Pragma_Misplaced; return; end if; Pack_Id := Defining_Entity (Pack_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Pack_Id); Ensure_Aggregate_Form (Get_Argument (N, Pack_Id)); -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Pack_Id); -- The legality checks of pragmas Abstract_State, Initializes, and -- Initial_Condition are affected by the SPARK mode in effect. In -- addition, these three pragmas are subject to an inherent order: -- 1) Abstract_State -- 2) Initializes -- 3) Initial_Condition -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); States := Expression (Get_Argument (N, Pack_Id)); -- Multiple non-null abstract states appear as an aggregate if Nkind (States) = N_Aggregate then State := First (Expressions (States)); while Present (State) loop Analyze_Abstract_State (State, Pack_Id); Next (State); end loop; -- An abstract state with a simple option is being illegaly -- declared with "=>" rather than "with". In this case the -- state declaration appears as a component association. if Present (Component_Associations (States)) then State := First (Component_Associations (States)); while Present (State) loop Malformed_State_Error (State); Next (State); end loop; end if; -- Various forms of a single abstract state. Note that these may -- include malformed state declarations. else Analyze_Abstract_State (States, Pack_Id); end if; Analyze_If_Present (Pragma_Initializes); Analyze_If_Present (Pragma_Initial_Condition); end Abstract_State; -------------- -- Acc_Data -- -------------- when Pragma_Acc_Data => Acc_Data : declare Clause_Names : constant Name_List := (Name_Attach, Name_Copy, Name_Copy_In, Name_Copy_Out, Name_Create, Name_Delete, Name_Detach, Name_Device_Ptr, Name_No_Create, Name_Present); Clause : Node_Id; Clauses : Args_List (Clause_Names'Range); begin if not OpenAcc_Enabled then return; end if; GNAT_Pragma; if Nkind (Parent (N)) /= N_Loop_Statement then Error_Pragma ("Acc_Data pragma should be placed in loop or block " & "statements"); end if; Gather_Associations (Clause_Names, Clauses); for Id in Clause_Names'First .. Clause_Names'Last loop Clause := Clauses (Id); if Present (Clause) then case Clause_Names (Id) is when Name_Copy | Name_Copy_In | Name_Copy_Out | Name_Create | Name_Device_Ptr | Name_Present => Validate_Acc_Data_Clause (Clause); when Name_Attach | Name_Detach | Name_Delete | Name_No_Create => Error_Pragma ("unsupported pragma clause"); when others => raise Program_Error; end case; end if; end loop; Set_Is_OpenAcc_Environment (Parent (N)); end Acc_Data; -------------- -- Acc_Loop -- -------------- when Pragma_Acc_Loop => Acc_Loop : declare Clause_Names : constant Name_List := (Name_Auto, Name_Collapse, Name_Gang, Name_Independent, Name_Acc_Private, Name_Reduction, Name_Seq, Name_Tile, Name_Vector, Name_Worker); Clause : Node_Id; Clauses : Args_List (Clause_Names'Range); Par : Node_Id; begin if not OpenAcc_Enabled then return; end if; GNAT_Pragma; -- Make sure the pragma is in an openacc construct Check_Loop_Pragma_Placement; Par := Parent (N); while Present (Par) and then (Nkind (Par) /= N_Loop_Statement or else not Is_OpenAcc_Environment (Par)) loop Par := Parent (Par); end loop; if not Is_OpenAcc_Environment (Par) then Error_Pragma ("Acc_Loop directive must be associated with an OpenAcc " & "construct region"); end if; Gather_Associations (Clause_Names, Clauses); for Id in Clause_Names'First .. Clause_Names'Last loop Clause := Clauses (Id); if Present (Clause) then case Clause_Names (Id) is when Name_Auto | Name_Independent | Name_Seq => null; when Name_Collapse => Validate_Acc_Loop_Collapse (Clause); when Name_Gang => Validate_Acc_Loop_Gang (Clause); when Name_Acc_Private => Validate_Acc_Data_Clause (Clause); when Name_Reduction => Validate_Acc_Name_Reduction (Clause); when Name_Tile => Validate_Acc_Size_Expressions (Clause); when Name_Vector => Validate_Acc_Loop_Vector (Clause); when Name_Worker => Validate_Acc_Loop_Worker (Clause); when others => raise Program_Error; end case; end if; end loop; Set_Is_OpenAcc_Loop (Parent (N)); end Acc_Loop; ---------------------------------- -- Acc_Parallel and Acc_Kernels -- ---------------------------------- when Pragma_Acc_Parallel | Pragma_Acc_Kernels => Acc_Kernels_Or_Parallel : declare Clause_Names : constant Name_List := (Name_Acc_If, Name_Async, Name_Copy, Name_Copy_In, Name_Copy_Out, Name_Create, Name_Default, Name_Device_Ptr, Name_Device_Type, Name_Num_Gangs, Name_Num_Workers, Name_Present, Name_Vector_Length, Name_Wait, -- Parallel only Name_Acc_Private, Name_First_Private, Name_Reduction, -- Kernels only Name_Attach, Name_No_Create); Clause : Node_Id; Clauses : Args_List (Clause_Names'Range); begin if not OpenAcc_Enabled then return; end if; GNAT_Pragma; Check_Loop_Pragma_Placement; if Nkind (Parent (N)) /= N_Loop_Statement then Error_Pragma ("pragma should be placed in loop or block statements"); end if; Gather_Associations (Clause_Names, Clauses); for Id in Clause_Names'First .. Clause_Names'Last loop Clause := Clauses (Id); if Present (Clause) then if Chars (Parent (Clause)) = No_Name then Error_Pragma ("all arguments should be associations"); else case Clause_Names (Id) is -- Note: According to the OpenAcc Standard v2.6, -- Async's argument should be optional. Because this -- complicates parsing the clause, the argument is -- made mandatory. The standard defines two negative -- values, acc_async_noval and acc_async_sync. When -- given acc_async_noval as value, the clause should -- behave as if no argument was given. According to -- the standard, acc_async_noval is defined in header -- files for C and Fortran, thus this value should -- probably be defined in the OpenAcc Ada library once -- it is implemented. when Name_Async | Name_Num_Gangs | Name_Num_Workers | Name_Vector_Length => Validate_Acc_Int_Expr_Clause (Clause); when Name_Acc_If => Validate_Acc_Condition_Clause (Clause); -- Unsupported by GCC when Name_Attach | Name_No_Create => Error_Pragma ("unsupported clause"); when Name_Acc_Private | Name_First_Private => if Prag_Id /= Pragma_Acc_Parallel then Error_Pragma ("argument is only available for 'Parallel' " & "construct"); else Validate_Acc_Data_Clause (Clause); end if; when Name_Copy | Name_Copy_In | Name_Copy_Out | Name_Create | Name_Device_Ptr | Name_Present => Validate_Acc_Data_Clause (Clause); when Name_Reduction => if Prag_Id /= Pragma_Acc_Parallel then Error_Pragma ("argument is only available for 'Parallel' " & "construct"); else Validate_Acc_Name_Reduction (Clause); end if; when Name_Default => if Chars (Clause) /= Name_None then Error_Pragma ("expected none"); end if; when Name_Device_Type => Error_Pragma ("unsupported pragma clause"); -- Similar to Name_Async, Name_Wait's arguments should -- be optional. However, this can be simulated using -- acc_async_noval, hence, we do not bother making the -- argument optional for now. when Name_Wait => Validate_Acc_Int_Expr_List_Clause (Clause); when others => raise Program_Error; end case; end if; end if; end loop; Set_Is_OpenAcc_Environment (Parent (N)); end Acc_Kernels_Or_Parallel; ------------ -- Ada_83 -- ------------ -- pragma Ada_83; -- Note: this pragma also has some specific processing in Par.Prag -- because we want to set the Ada version mode during parsing. when Pragma_Ada_83 => GNAT_Pragma; Check_Arg_Count (0); -- We really should check unconditionally for proper configuration -- pragma placement, since we really don't want mixed Ada modes -- within a single unit, and the GNAT reference manual has always -- said this was a configuration pragma, but we did not check and -- are hesitant to add the check now. -- However, we really cannot tolerate mixing Ada 2005 or Ada 2012 -- with Ada 83 or Ada 95, so we must check if we are in Ada 2005 -- or Ada 2012 mode. if Ada_Version >= Ada_2005 then Check_Valid_Configuration_Pragma; end if; -- Now set Ada 83 mode if Latest_Ada_Only then Error_Pragma ("??pragma% ignored"); else Ada_Version := Ada_83; Ada_Version_Explicit := Ada_83; Ada_Version_Pragma := N; end if; ------------ -- Ada_95 -- ------------ -- pragma Ada_95; -- Note: this pragma also has some specific processing in Par.Prag -- because we want to set the Ada 83 version mode during parsing. when Pragma_Ada_95 => GNAT_Pragma; Check_Arg_Count (0); -- We really should check unconditionally for proper configuration -- pragma placement, since we really don't want mixed Ada modes -- within a single unit, and the GNAT reference manual has always -- said this was a configuration pragma, but we did not check and -- are hesitant to add the check now. -- However, we really cannot tolerate mixing Ada 2005 with Ada 83 -- or Ada 95, so we must check if we are in Ada 2005 mode. if Ada_Version >= Ada_2005 then Check_Valid_Configuration_Pragma; end if; -- Now set Ada 95 mode if Latest_Ada_Only then Error_Pragma ("??pragma% ignored"); else Ada_Version := Ada_95; Ada_Version_Explicit := Ada_95; Ada_Version_Pragma := N; end if; --------------------- -- Ada_05/Ada_2005 -- --------------------- -- pragma Ada_05; -- pragma Ada_05 (LOCAL_NAME); -- pragma Ada_2005; -- pragma Ada_2005 (LOCAL_NAME): -- Note: these pragmas also have some specific processing in Par.Prag -- because we want to set the Ada 2005 version mode during parsing. -- The one argument form is used for managing the transition from -- Ada 95 to Ada 2005 in the run-time library. If an entity is marked -- as Ada_2005 only, then referencing the entity in Ada_83 or Ada_95 -- mode will generate a warning. In addition, in Ada_83 or Ada_95 -- mode, a preference rule is established which does not choose -- such an entity unless it is unambiguously specified. This avoids -- extra subprograms marked this way from generating ambiguities in -- otherwise legal pre-Ada_2005 programs. The one argument form is -- intended for exclusive use in the GNAT run-time library. when Pragma_Ada_05 | Pragma_Ada_2005 => declare E_Id : Node_Id; begin GNAT_Pragma; if Arg_Count = 1 then Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; Set_Is_Ada_2005_Only (Entity (E_Id)); Record_Rep_Item (Entity (E_Id), N); else Check_Arg_Count (0); -- For Ada_2005 we unconditionally enforce the documented -- configuration pragma placement, since we do not want to -- tolerate mixed modes in a unit involving Ada 2005. That -- would cause real difficulties for those cases where there -- are incompatibilities between Ada 95 and Ada 2005. Check_Valid_Configuration_Pragma; -- Now set appropriate Ada mode if Latest_Ada_Only then Error_Pragma ("??pragma% ignored"); else Ada_Version := Ada_2005; Ada_Version_Explicit := Ada_2005; Ada_Version_Pragma := N; end if; end if; end; --------------------- -- Ada_12/Ada_2012 -- --------------------- -- pragma Ada_12; -- pragma Ada_12 (LOCAL_NAME); -- pragma Ada_2012; -- pragma Ada_2012 (LOCAL_NAME): -- Note: these pragmas also have some specific processing in Par.Prag -- because we want to set the Ada 2012 version mode during parsing. -- The one argument form is used for managing the transition from Ada -- 2005 to Ada 2012 in the run-time library. If an entity is marked -- as Ada_2012 only, then referencing the entity in any pre-Ada_2012 -- mode will generate a warning. In addition, in any pre-Ada_2012 -- mode, a preference rule is established which does not choose -- such an entity unless it is unambiguously specified. This avoids -- extra subprograms marked this way from generating ambiguities in -- otherwise legal pre-Ada_2012 programs. The one argument form is -- intended for exclusive use in the GNAT run-time library. when Pragma_Ada_12 | Pragma_Ada_2012 => declare E_Id : Node_Id; begin GNAT_Pragma; if Arg_Count = 1 then Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; Set_Is_Ada_2012_Only (Entity (E_Id)); Record_Rep_Item (Entity (E_Id), N); else Check_Arg_Count (0); -- For Ada_2012 we unconditionally enforce the documented -- configuration pragma placement, since we do not want to -- tolerate mixed modes in a unit involving Ada 2012. That -- would cause real difficulties for those cases where there -- are incompatibilities between Ada 95 and Ada 2012. We could -- allow mixing of Ada 2005 and Ada 2012 but it's not worth it. Check_Valid_Configuration_Pragma; -- Now set appropriate Ada mode Ada_Version := Ada_2012; Ada_Version_Explicit := Ada_2012; Ada_Version_Pragma := N; end if; end; -------------- -- Ada_2020 -- -------------- -- pragma Ada_2020; -- Note: this pragma also has some specific processing in Par.Prag -- because we want to set the Ada 2020 version mode during parsing. when Pragma_Ada_2020 => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; -- Now set appropriate Ada mode Ada_Version := Ada_2020; Ada_Version_Explicit := Ada_2020; Ada_Version_Pragma := N; ---------------------- -- 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; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Lib_Entity); -- 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; --------------------------- -- Allow_Integer_Address -- --------------------------- -- pragma Allow_Integer_Address; when Pragma_Allow_Integer_Address => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (0); -- If Address is a private type, then set the flag to allow -- integer address values. If Address is not private, then this -- pragma has no purpose, so it is simply ignored. Not clear if -- there are any such targets now. if Opt.Address_Is_Private then Opt.Allow_Integer_Address := True; end if; -------------- -- Annotate -- -------------- -- pragma Annotate -- (IDENTIFIER [, IDENTIFIER {, ARG}] [,Entity => local_NAME]); -- ARG ::= NAME | EXPRESSION -- The first two arguments are by convention intended to refer to an -- external tool and a tool-specific function. These arguments are -- not analyzed. when Pragma_Annotate => Annotate : declare Arg : Node_Id; Expr : Node_Id; Nam_Arg : Node_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Nam_Arg := Last (Pragma_Argument_Associations (N)); -- Determine whether the last argument is "Entity => local_NAME" -- and if it is, perform the required semantic checks. Remove the -- argument from further processing. if Nkind (Nam_Arg) = N_Pragma_Argument_Association and then Chars (Nam_Arg) = Name_Entity then Check_Arg_Is_Local_Name (Nam_Arg); Arg_Count := Arg_Count - 1; -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. if Is_Entity_Name (Get_Pragma_Arg (Nam_Arg)) and then Present (Entity (Get_Pragma_Arg (Nam_Arg))) then Mark_Ghost_Pragma (N, Entity (Get_Pragma_Arg (Nam_Arg))); end if; -- Not allowed in compiler units (bootstrap issues) Check_Compiler_Unit ("Entity for pragma Annotate", N); end if; -- Continue the processing with last argument removed for now Check_Arg_Is_Identifier (Arg1); Check_No_Identifiers; Store_Note (N); -- The second parameter is optional, it is never analyzed if No (Arg2) then null; -- Otherwise there is a second parameter else -- The second parameter must be an identifier Check_Arg_Is_Identifier (Arg2); -- Process the remaining parameters (if any) Arg := Next (Arg2); while Present (Arg) loop Expr := Get_Pragma_Arg (Arg); Analyze (Expr); if Is_Entity_Name (Expr) then null; -- For string literals, we assume Standard_String as the -- type, unless the string contains wide or wide_wide -- characters. elsif Nkind (Expr) = N_String_Literal then if Has_Wide_Wide_Character (Expr) then Resolve (Expr, Standard_Wide_Wide_String); elsif Has_Wide_Character (Expr) then Resolve (Expr, Standard_Wide_String); else Resolve (Expr, Standard_String); end if; elsif Is_Overloaded (Expr) then Error_Pragma_Arg ("ambiguous argument for pragma%", Expr); else Resolve (Expr); end if; Next (Arg); end loop; end if; end Annotate; ------------------------------------------------- -- Assert/Assert_And_Cut/Assume/Loop_Invariant -- ------------------------------------------------- -- pragma Assert -- ( [Check => ] Boolean_EXPRESSION -- [, [Message =>] Static_String_EXPRESSION]); -- pragma Assert_And_Cut -- ( [Check => ] Boolean_EXPRESSION -- [, [Message =>] Static_String_EXPRESSION]); -- pragma Assume -- ( [Check => ] Boolean_EXPRESSION -- [, [Message =>] Static_String_EXPRESSION]); -- pragma Loop_Invariant -- ( [Check => ] Boolean_EXPRESSION -- [, [Message =>] Static_String_EXPRESSION]); when Pragma_Assert | Pragma_Assert_And_Cut | Pragma_Assume | Pragma_Loop_Invariant => Assert : declare function Contains_Loop_Entry (Expr : Node_Id) return Boolean; -- Determine whether expression Expr contains a Loop_Entry -- attribute reference. ------------------------- -- Contains_Loop_Entry -- ------------------------- function Contains_Loop_Entry (Expr : Node_Id) return Boolean is Has_Loop_Entry : Boolean := False; function Process (N : Node_Id) return Traverse_Result; -- Process function for traversal to look for Loop_Entry ------------- -- Process -- ------------- function Process (N : Node_Id) return Traverse_Result is begin if Nkind (N) = N_Attribute_Reference and then Attribute_Name (N) = Name_Loop_Entry then Has_Loop_Entry := True; return Abandon; else return OK; end if; end Process; procedure Traverse is new Traverse_Proc (Process); -- Start of processing for Contains_Loop_Entry begin Traverse (Expr); return Has_Loop_Entry; end Contains_Loop_Entry; -- Local variables Expr : Node_Id; New_Args : List_Id; -- Start of processing for Assert begin -- Assert is an Ada 2005 RM-defined pragma if Prag_Id = Pragma_Assert then Ada_2005_Pragma; -- The remaining ones are GNAT pragmas else GNAT_Pragma; end if; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); Check_Arg_Order ((Name_Check, Name_Message)); Check_Optional_Identifier (Arg1, Name_Check); Expr := Get_Pragma_Arg (Arg1); -- Special processing for Loop_Invariant, Loop_Variant or for -- other cases where a Loop_Entry attribute is present. If the -- assertion pragma contains attribute Loop_Entry, ensure that -- the related pragma is within a loop. if Prag_Id = Pragma_Loop_Invariant or else Prag_Id = Pragma_Loop_Variant or else Contains_Loop_Entry (Expr) then Check_Loop_Pragma_Placement; -- Perform preanalysis to deal with embedded Loop_Entry -- attributes. Preanalyze_Assert_Expression (Expr, Any_Boolean); end if; -- Implement Assert[_And_Cut]/Assume/Loop_Invariant by generating -- a corresponding Check pragma: -- pragma Check (name, condition [, msg]); -- Where name is the identifier matching the pragma name. So -- rewrite pragma in this manner, transfer the message argument -- if present, and analyze the result -- Note: When dealing with a semantically analyzed tree, the -- information that a Check node N corresponds to a source Assert, -- Assume, or Assert_And_Cut pragma can be retrieved from the -- pragma kind of Original_Node(N). New_Args := New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Pname)), Make_Pragma_Argument_Association (Sloc (Expr), Expression => Expr)); if Arg_Count > 1 then Check_Optional_Identifier (Arg2, Name_Message); -- Provide semantic annnotations for optional argument, for -- ASIS use, before rewriting. Preanalyze_And_Resolve (Expression (Arg2), Standard_String); Append_To (New_Args, New_Copy_Tree (Arg2)); end if; -- Rewrite as Check pragma Rewrite (N, Make_Pragma (Loc, Chars => Name_Check, Pragma_Argument_Associations => New_Args)); Analyze (N); end Assert; ---------------------- -- Assertion_Policy -- ---------------------- -- pragma Assertion_Policy (POLICY_IDENTIFIER); -- The following form is Ada 2012 only, but we allow it in all modes -- Pragma Assertion_Policy ( -- ASSERTION_KIND => POLICY_IDENTIFIER -- {, ASSERTION_KIND => POLICY_IDENTIFIER}); -- ASSERTION_KIND ::= RM_ASSERTION_KIND | ID_ASSERTION_KIND -- RM_ASSERTION_KIND ::= Assert | -- Static_Predicate | -- Dynamic_Predicate | -- Pre | -- Pre'Class | -- Post | -- Post'Class | -- Type_Invariant | -- Type_Invariant'Class -- ID_ASSERTION_KIND ::= Assert_And_Cut | -- Assume | -- Contract_Cases | -- Debug | -- Default_Initial_Condition | -- Ghost | -- Initial_Condition | -- Loop_Invariant | -- Loop_Variant | -- Postcondition | -- Precondition | -- Predicate | -- Refined_Post | -- Statement_Assertions -- Note: The RM_ASSERTION_KIND list is language-defined, and the -- ID_ASSERTION_KIND list contains implementation-defined additions -- recognized by GNAT. The effect is to control the behavior of -- identically named aspects and pragmas, depending on the specified -- policy identifier: -- POLICY_IDENTIFIER ::= Check | Disable | Ignore | Suppressible -- Note: Check and Ignore are language-defined. Disable is a GNAT -- implementation-defined addition that results in totally ignoring -- the corresponding assertion. If Disable is specified, then the -- argument of the assertion is not even analyzed. This is useful -- when the aspect/pragma argument references entities in a with'ed -- package that is replaced by a dummy package in the final build. -- Note: the attribute forms Pre'Class, Post'Class, Invariant'Class, -- and Type_Invariant'Class were recognized by the parser and -- transformed into references to the special internal identifiers -- _Pre, _Post, _Invariant, and _Type_Invariant, so no special -- processing is required here. when Pragma_Assertion_Policy => Assertion_Policy : declare procedure Resolve_Suppressible (Policy : Node_Id); -- Converts the assertion policy 'Suppressible' to either Check or -- Ignore based on whether checks are suppressed via -gnatp. -------------------------- -- Resolve_Suppressible -- -------------------------- procedure Resolve_Suppressible (Policy : Node_Id) is Arg : constant Node_Id := Get_Pragma_Arg (Policy); Nam : Name_Id; begin -- Transform policy argument Suppressible into either Ignore or -- Check depending on whether checks are enabled or suppressed. if Chars (Arg) = Name_Suppressible then if Suppress_Checks then Nam := Name_Ignore; else Nam := Name_Check; end if; Rewrite (Arg, Make_Identifier (Sloc (Arg), Nam)); end if; end Resolve_Suppressible; -- Local variables Arg : Node_Id; Kind : Name_Id; LocP : Source_Ptr; Policy : Node_Id; begin Ada_2005_Pragma; -- This can always appear as a configuration pragma if Is_Configuration_Pragma then null; -- It can also appear in a declarative part or package spec in Ada -- 2012 mode. We allow this in other modes, but in that case we -- consider that we have an Ada 2012 pragma on our hands. else Check_Is_In_Decl_Part_Or_Package_Spec; Ada_2012_Pragma; end if; -- One argument case with no identifier (first form above) if Arg_Count = 1 and then (Nkind (Arg1) /= N_Pragma_Argument_Association or else Chars (Arg1) = No_Name) then Check_Arg_Is_One_Of (Arg1, Name_Check, Name_Disable, Name_Ignore, Name_Suppressible); Resolve_Suppressible (Arg1); -- Treat one argument Assertion_Policy as equivalent to: -- pragma Check_Policy (Assertion, policy) -- So rewrite pragma in that manner and link on to the chain -- of Check_Policy pragmas, marking the pragma as analyzed. Policy := Get_Pragma_Arg (Arg1); Rewrite (N, Make_Pragma (Loc, Chars => Name_Check_Policy, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Name_Assertion)), Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Sloc (Policy), Chars (Policy)))))); Analyze (N); -- Here if we have two or more arguments else Check_At_Least_N_Arguments (1); Ada_2012_Pragma; -- Loop through arguments Arg := Arg1; while Present (Arg) loop LocP := Sloc (Arg); -- Kind must be specified if Nkind (Arg) /= N_Pragma_Argument_Association or else Chars (Arg) = No_Name then Error_Pragma_Arg ("missing assertion kind for pragma%", Arg); end if; -- Check Kind and Policy have allowed forms Kind := Chars (Arg); Policy := Get_Pragma_Arg (Arg); if not Is_Valid_Assertion_Kind (Kind) then Error_Pragma_Arg ("invalid assertion kind for pragma%", Arg); end if; Check_Arg_Is_One_Of (Arg, Name_Check, Name_Disable, Name_Ignore, Name_Suppressible); Resolve_Suppressible (Arg); if Kind = Name_Ghost then -- The Ghost policy must be either Check or Ignore -- (SPARK RM 6.9(6)). if not Nam_In (Chars (Policy), Name_Check, Name_Ignore) then Error_Pragma_Arg ("argument of pragma % Ghost must be Check or " & "Ignore", Policy); end if; -- Pragma Assertion_Policy specifying a Ghost policy -- cannot occur within a Ghost subprogram or package -- (SPARK RM 6.9(14)). if Ghost_Mode > None then Error_Pragma ("pragma % cannot appear within ghost subprogram or " & "package"); end if; end if; -- Rewrite the Assertion_Policy pragma as a series of -- Check_Policy pragmas of the form: -- Check_Policy (Kind, Policy); -- Note: the insertion of the pragmas cannot be done with -- Insert_Action because in the configuration case, there -- are no scopes on the scope stack and the mechanism will -- fail. Insert_Before_And_Analyze (N, Make_Pragma (LocP, Chars => Name_Check_Policy, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (LocP, Expression => Make_Identifier (LocP, Kind)), Make_Pragma_Argument_Association (LocP, Expression => Policy)))); Arg := Next (Arg); end loop; -- Rewrite the Assertion_Policy pragma as null since we have -- now inserted all the equivalent Check pragmas. Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); end if; end Assertion_Policy; ------------------------------ -- Assume_No_Invalid_Values -- ------------------------------ -- pragma Assume_No_Invalid_Values (On | Off); when Pragma_Assume_No_Invalid_Values => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); if Chars (Get_Pragma_Arg (Arg1)) = Name_On then Assume_No_Invalid_Values := True; else Assume_No_Invalid_Values := False; end if; -------------------------- -- Attribute_Definition -- -------------------------- -- pragma Attribute_Definition -- ([Attribute =>] ATTRIBUTE_DESIGNATOR, -- [Entity =>] LOCAL_NAME, -- [Expression =>] EXPRESSION | NAME); when Pragma_Attribute_Definition => Attribute_Definition : declare Attribute_Designator : constant Node_Id := Get_Pragma_Arg (Arg1); Aname : Name_Id; begin GNAT_Pragma; Check_Arg_Count (3); Check_Optional_Identifier (Arg1, "attribute"); Check_Optional_Identifier (Arg2, "entity"); Check_Optional_Identifier (Arg3, "expression"); if Nkind (Attribute_Designator) /= N_Identifier then Error_Msg_N ("attribute name expected", Attribute_Designator); return; end if; Check_Arg_Is_Local_Name (Arg2); -- If the attribute is not recognized, then issue a warning (not -- an error), and ignore the pragma. Aname := Chars (Attribute_Designator); if not Is_Attribute_Name (Aname) then Bad_Attribute (Attribute_Designator, Aname, Warn => True); return; end if; -- Otherwise, rewrite the pragma as an attribute definition clause Rewrite (N, Make_Attribute_Definition_Clause (Loc, Name => Get_Pragma_Arg (Arg2), Chars => Aname, Expression => Get_Pragma_Arg (Arg3))); Analyze (N); end Attribute_Definition; ------------------------------------------------------------------ -- Async_Readers/Async_Writers/Effective_Reads/Effective_Writes -- ------------------------------------------------------------------ -- pragma Asynch_Readers [ (boolean_EXPRESSION) ]; -- pragma Asynch_Writers [ (boolean_EXPRESSION) ]; -- pragma Effective_Reads [ (boolean_EXPRESSION) ]; -- pragma Effective_Writes [ (boolean_EXPRESSION) ]; when Pragma_Async_Readers | Pragma_Async_Writers | Pragma_Effective_Reads | Pragma_Effective_Writes => Async_Effective : declare Obj_Decl : Node_Id; Obj_Id : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Obj_Decl := Find_Related_Context (N, Do_Checks => True); -- Object declaration if Nkind (Obj_Decl) /= N_Object_Declaration then Pragma_Misplaced; return; end if; Obj_Id := Defining_Entity (Obj_Decl); -- Perform minimal verification to ensure that the argument is at -- least a variable. Subsequent finer grained checks will be done -- at the end of the declarative region the contains the pragma. if Ekind (Obj_Id) = E_Variable then -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. Mark_Ghost_Pragma (N, Obj_Id); -- Chain the pragma on the contract for further processing by -- Analyze_External_Property_In_Decl_Part. Add_Contract_Item (N, Obj_Id); -- Analyze the Boolean expression (if any) if Present (Arg1) then Check_Static_Boolean_Expression (Get_Pragma_Arg (Arg1)); end if; -- Otherwise the external property applies to a constant else Error_Pragma ("pragma % must apply to a volatile object"); end if; end Async_Effective; ------------------ -- Asynchronous -- ------------------ -- pragma Asynchronous (LOCAL_NAME); when Pragma_Asynchronous => Asynchronous : declare C_Ent : Entity_Id; Decl : Node_Id; Formal : Entity_Id; L : List_Id; Nm : Entity_Id; S : Node_Id; procedure Process_Async_Pragma; -- Common processing for procedure and access-to-procedure case -------------------------- -- Process_Async_Pragma -- -------------------------- procedure Process_Async_Pragma is begin if No (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 (Get_Pragma_Arg (Arg1)); Nm := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Nm); 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 Is_Remote_Access_To_Subprogram_Type (Nm) then if Is_Record_Type (Nm) then -- A record type that is the Equivalent_Type for a remote -- access-to-subprogram type. Decl := Declaration_Node (Corresponding_Remote_Type (Nm)); else -- A non-expanded RAS type (distribution is not enabled) Decl := Declaration_Node (Nm); end if; if Nkind (Decl) = N_Full_Type_Declaration and then Nkind (Type_Definition (Decl)) = N_Access_Procedure_Definition then L := Parameter_Specifications (Type_Definition (Decl)); Process_Async_Pragma; if Is_Asynchronous (Nm) and then Expander_Active and then Get_PCS_Name /= Name_No_DSA then RACW_Type_Is_Asynchronous (Underlying_RACW_Type (Nm)); end if; 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_Independent_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 D : Node_Id; E : Entity_Id; E_Id : 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 := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); Check_Duplicate_Pragma (E); 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; -- Atomic implies both Independent and Volatile if Prag_Id = Pragma_Atomic_Components then Set_Has_Atomic_Components (E); Set_Has_Independent_Components (E); end if; Set_Has_Volatile_Components (E); 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, then -- perform semantic checks on a copy only. declare Temp : Node_Id; Typ : Node_Id; Parg2 : constant Node_Id := Get_Pragma_Arg (Arg2); begin -- In Relaxed_RM_Semantics mode, we allow any static -- integer value, for compatibility with other compilers. if Relaxed_RM_Semantics and then Nkind (Parg2) = N_Integer_Literal then Typ := Standard_Integer; else Typ := RTE (RE_Interrupt_ID); end if; if Expander_Active then Temp := New_Copy_Tree (Parg2); Set_Parent (Temp, N); Preanalyze_And_Resolve (Temp, Typ); else Analyze (Parg2); Resolve (Parg2, Typ); end if; end; 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 := Get_Pragma_Arg (Arg1); Check_Arg_Is_OK_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; ----------- -- Check -- ----------- -- pragma Check ([Name =>] CHECK_KIND, -- [Check =>] Boolean_EXPRESSION -- [,[Message =>] String_EXPRESSION]); -- CHECK_KIND ::= IDENTIFIER | -- Pre'Class | -- Post'Class | -- Invariant'Class | -- Type_Invariant'Class -- The identifiers Assertions and Statement_Assertions are not -- allowed, since they have special meaning for Check_Policy. -- WARNING: The code below manages Ghost regions. Return statements -- must be replaced by gotos which jump to the end of the code and -- restore the Ghost mode. when Pragma_Check => Check : declare Saved_GM : constant Ghost_Mode_Type := Ghost_Mode; Saved_IGR : constant Node_Id := Ignored_Ghost_Region; -- Save the Ghost-related attributes to restore on exit Cname : Name_Id; Eloc : Source_Ptr; Expr : Node_Id; Str : Node_Id; pragma Warnings (Off, Str); begin -- Pragma Check is Ghost when it applies to a Ghost entity. Set -- the mode now to ensure that any nodes generated during analysis -- and expansion are marked as Ghost. Set_Ghost_Mode (N); GNAT_Pragma; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (3); Check_Optional_Identifier (Arg1, Name_Name); Check_Optional_Identifier (Arg2, Name_Check); if Arg_Count = 3 then Check_Optional_Identifier (Arg3, Name_Message); Str := Get_Pragma_Arg (Arg3); end if; Rewrite_Assertion_Kind (Get_Pragma_Arg (Arg1)); Check_Arg_Is_Identifier (Arg1); Cname := Chars (Get_Pragma_Arg (Arg1)); -- Check forbidden name Assertions or Statement_Assertions case Cname is when Name_Assertions => Error_Pragma_Arg ("""Assertions"" is not allowed as a check kind for " & "pragma%", Arg1); when Name_Statement_Assertions => Error_Pragma_Arg ("""Statement_Assertions"" is not allowed as a check kind " & "for pragma%", Arg1); when others => null; end case; -- Check applicable policy. We skip this if Checked/Ignored status -- is already set (e.g. in the case of a pragma from an aspect). if Is_Checked (N) or else Is_Ignored (N) then null; -- For a non-source pragma that is a rewriting of another pragma, -- copy the Is_Checked/Ignored status from the rewritten pragma. elsif Is_Rewrite_Substitution (N) and then Nkind (Original_Node (N)) = N_Pragma then Set_Is_Ignored (N, Is_Ignored (Original_Node (N))); Set_Is_Checked (N, Is_Checked (Original_Node (N))); -- Otherwise query the applicable policy at this point else case Check_Kind (Cname) is when Name_Ignore => Set_Is_Ignored (N, True); Set_Is_Checked (N, False); when Name_Check => Set_Is_Ignored (N, False); Set_Is_Checked (N, True); -- For disable, rewrite pragma as null statement and skip -- rest of the analysis of the pragma. when Name_Disable => Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); raise Pragma_Exit; -- No other possibilities when others => raise Program_Error; end case; end if; -- If check kind was not Disable, then continue pragma analysis Expr := Get_Pragma_Arg (Arg2); -- Deal with SCO generation if Is_Checked (N) and then not Split_PPC (N) then Set_SCO_Pragma_Enabled (Loc); end if; -- Deal with analyzing the string argument. If checks are not -- on we don't want any expansion (since such expansion would -- not get properly deleted) but we do want to analyze (to get -- proper references). The Preanalyze_And_Resolve routine does -- just what we want. Ditto if pragma is active, because it will -- be rewritten as an if-statement whose analysis will complete -- analysis and expansion of the string message. This makes a -- difference in the unusual case where the expression for the -- string may have a side effect, such as raising an exception. -- This is mandated by RM 11.4.2, which specifies that the string -- expression is only evaluated if the check fails and -- Assertion_Error is to be raised. if Arg_Count = 3 then Preanalyze_And_Resolve (Str, Standard_String); end if; -- Now you might think we could just do the same with the Boolean -- expression if checks are off (and expansion is on) and then -- rewrite the check as a null statement. This would work but we -- would lose the useful warnings about an assertion being bound -- to fail even if assertions are turned off. -- So instead we wrap the boolean expression in an if statement -- that looks like: -- 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 check code. -- Note that the Sloc for the if statement corresponds to the -- argument condition, not the pragma itself. The reason for -- this is that we may generate a warning if the condition is -- False at compile time, and we do not want to delete this -- warning when we delete the if statement. if Expander_Active and Is_Ignored (N) then Eloc := Sloc (Expr); Rewrite (N, Make_If_Statement (Eloc, Condition => Make_And_Then (Eloc, Left_Opnd => Make_Identifier (Eloc, Name_False), Right_Opnd => Expr), Then_Statements => New_List ( Make_Null_Statement (Eloc)))); -- Now go ahead and analyze the if statement In_Assertion_Expr := In_Assertion_Expr + 1; -- One rather special treatment. If we are now in Eliminated -- overflow mode, then suppress overflow checking since we do -- not want to drag in the bignum stuff if we are in Ignore -- mode anyway. This is particularly important if we are using -- a configurable run time that does not support bignum ops. if Scope_Suppress.Overflow_Mode_Assertions = Eliminated then declare Svo : constant Boolean := Scope_Suppress.Suppress (Overflow_Check); begin Scope_Suppress.Overflow_Mode_Assertions := Strict; Scope_Suppress.Suppress (Overflow_Check) := True; Analyze (N); Scope_Suppress.Suppress (Overflow_Check) := Svo; Scope_Suppress.Overflow_Mode_Assertions := Eliminated; end; -- Not that special case else Analyze (N); end if; -- All done with this check In_Assertion_Expr := In_Assertion_Expr - 1; -- Check is active or expansion not active. In these cases we can -- just go ahead and analyze the boolean with no worries. else In_Assertion_Expr := In_Assertion_Expr + 1; Analyze_And_Resolve (Expr, Any_Boolean); In_Assertion_Expr := In_Assertion_Expr - 1; end if; Restore_Ghost_Region (Saved_GM, Saved_IGR); end Check; -------------------------- -- Check_Float_Overflow -- -------------------------- -- pragma Check_Float_Overflow; when Pragma_Check_Float_Overflow => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (0); Check_Float_Overflow := not Machine_Overflows_On_Target; ---------------- -- Check_Name -- ---------------- -- pragma Check_Name (check_IDENTIFIER); when Pragma_Check_Name => GNAT_Pragma; Check_No_Identifiers; Check_Valid_Configuration_Pragma; Check_Arg_Count (1); Check_Arg_Is_Identifier (Arg1); declare Nam : constant Name_Id := Chars (Get_Pragma_Arg (Arg1)); begin for J in Check_Names.First .. Check_Names.Last loop if Check_Names.Table (J) = Nam then return; end if; end loop; Check_Names.Append (Nam); end; ------------------ -- Check_Policy -- ------------------ -- This is the old style syntax, which is still allowed in all modes: -- pragma Check_Policy ([Name =>] CHECK_KIND -- [Policy =>] POLICY_IDENTIFIER); -- POLICY_IDENTIFIER ::= On | Off | Check | Disable | Ignore -- CHECK_KIND ::= IDENTIFIER | -- Pre'Class | -- Post'Class | -- Type_Invariant'Class | -- Invariant'Class -- This is the new style syntax, compatible with Assertion_Policy -- and also allowed in all modes. -- Pragma Check_Policy ( -- CHECK_KIND => POLICY_IDENTIFIER -- {, CHECK_KIND => POLICY_IDENTIFIER}); -- Note: the identifiers Name and Policy are not allowed as -- Check_Kind values. This avoids ambiguities between the old and -- new form syntax. when Pragma_Check_Policy => Check_Policy : declare Kind : Node_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); -- A Check_Policy pragma can appear either as a configuration -- pragma, or in a declarative part or a package spec (see RM -- 11.5(5) for rules for Suppress/Unsuppress which are also -- followed for Check_Policy). if not Is_Configuration_Pragma then Check_Is_In_Decl_Part_Or_Package_Spec; end if; -- Figure out if we have the old or new syntax. We have the -- old syntax if the first argument has no identifier, or the -- identifier is Name. if Nkind (Arg1) /= N_Pragma_Argument_Association or else Nam_In (Chars (Arg1), No_Name, Name_Name) then -- Old syntax Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Name); Kind := Get_Pragma_Arg (Arg1); Rewrite_Assertion_Kind (Kind, From_Policy => Comes_From_Source (N)); Check_Arg_Is_Identifier (Arg1); -- Check forbidden check kind if Nam_In (Chars (Kind), Name_Name, Name_Policy) then Error_Msg_Name_2 := Chars (Kind); Error_Pragma_Arg ("pragma% does not allow% as check name", Arg1); end if; -- Check policy Check_Optional_Identifier (Arg2, Name_Policy); Check_Arg_Is_One_Of (Arg2, Name_On, Name_Off, Name_Check, Name_Disable, Name_Ignore); -- And chain pragma on the Check_Policy_List for search Set_Next_Pragma (N, Opt.Check_Policy_List); Opt.Check_Policy_List := N; -- For the new syntax, what we do is to convert each argument to -- an old syntax equivalent. We do that because we want to chain -- old style Check_Policy pragmas for the search (we don't want -- to have to deal with multiple arguments in the search). else declare Arg : Node_Id; Argx : Node_Id; LocP : Source_Ptr; New_P : Node_Id; begin Arg := Arg1; while Present (Arg) loop LocP := Sloc (Arg); Argx := Get_Pragma_Arg (Arg); -- Kind must be specified if Nkind (Arg) /= N_Pragma_Argument_Association or else Chars (Arg) = No_Name then Error_Pragma_Arg ("missing assertion kind for pragma%", Arg); end if; -- Construct equivalent old form syntax Check_Policy -- pragma and insert it to get remaining checks. New_P := Make_Pragma (LocP, Chars => Name_Check_Policy, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (LocP, Expression => Make_Identifier (LocP, Chars (Arg))), Make_Pragma_Argument_Association (Sloc (Argx), Expression => Argx))); Arg := Next (Arg); -- For a configuration pragma, insert old form in -- the corresponding file. if Is_Configuration_Pragma then Insert_After (N, New_P); Analyze (New_P); else Insert_Action (N, New_P); end if; end loop; -- Rewrite original Check_Policy pragma to null, since we -- have converted it into a series of old syntax pragmas. Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); end; end if; end Check_Policy; ------------- -- 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_Error -- ------------------------ -- pragma Compile_Time_Error -- (boolean_EXPRESSION, static_string_EXPRESSION); when Pragma_Compile_Time_Error => GNAT_Pragma; Process_Compile_Time_Warning_Or_Error; -------------------------- -- Compile_Time_Warning -- -------------------------- -- pragma Compile_Time_Warning -- (boolean_EXPRESSION, static_string_EXPRESSION); when Pragma_Compile_Time_Warning => GNAT_Pragma; Process_Compile_Time_Warning_Or_Error; --------------------------- -- Compiler_Unit_Warning -- --------------------------- -- pragma Compiler_Unit_Warning; -- Historical note -- Originally, we had only pragma Compiler_Unit, and it resulted in -- errors not warnings. This means that we had introduced a big extra -- inertia to compiler changes, since even if we implemented a new -- feature, and even if all versions to be used for bootstrapping -- implemented this new feature, we could not use it, since old -- compilers would give errors for using this feature in units -- having Compiler_Unit pragmas. -- By changing Compiler_Unit to Compiler_Unit_Warning, we solve the -- problem. We no longer have any units mentioning Compiler_Unit, -- so old compilers see Compiler_Unit_Warning which is unrecognized, -- and thus generates a warning which can be ignored. So that deals -- with the problem of old compilers not implementing the newer form -- of the pragma. -- Newer compilers recognize the new pragma, but generate warning -- messages instead of errors, which again can be ignored in the -- case of an old compiler which implements a wanted new feature -- but at the time felt like warning about it for older compilers. -- We retain Compiler_Unit so that new compilers can be used to build -- older run-times that use this pragma. That's an unusual case, but -- it's easy enough to handle, so why not? when Pragma_Compiler_Unit | Pragma_Compiler_Unit_Warning => GNAT_Pragma; Check_Arg_Count (0); -- Only recognized in main unit if Current_Sem_Unit = Main_Unit then Compiler_Unit := True; end if; ----------------------------- -- Complete_Representation -- ----------------------------- -- pragma Complete_Representation; when Pragma_Complete_Representation => GNAT_Pragma; Check_Arg_Count (0); if Nkind (Parent (N)) /= N_Record_Representation_Clause then Error_Pragma ("pragma & must appear within record representation clause"); end if; ---------------------------- -- 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 := Get_Pragma_Arg (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 the same " & "floating-point type", Arg1); else Set_Has_Complex_Representation (Base_Type (E)); -- We need to treat the type has having a non-standard -- representation, for back-end purposes, even though in -- general a complex will have the default representation -- of a record with two real components. Set_Has_Non_Standard_Rep (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; -- The pragma appears in a configuration file if No (Parent (N)) then Check_Valid_Configuration_Pragma; -- Capture the component alignment in a global variable when -- the pragma appears in a configuration file. Note that the -- scope stack is empty at this point and cannot be used to -- store the alignment value. Configuration_Component_Alignment := Atype; -- Case with no name, supplied, affects scope table entry elsif 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; -------------------------------- -- Constant_After_Elaboration -- -------------------------------- -- pragma Constant_After_Elaboration [ (boolean_EXPRESSION) ]; when Pragma_Constant_After_Elaboration => Constant_After_Elaboration : declare Obj_Decl : Node_Id; Obj_Id : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Obj_Decl := Find_Related_Context (N, Do_Checks => True); if Nkind (Obj_Decl) /= N_Object_Declaration then Pragma_Misplaced; return; end if; Obj_Id := Defining_Entity (Obj_Decl); -- The object declaration must be a library-level variable which -- is either explicitly initialized or obtains a value during the -- elaboration of a package body (SPARK RM 3.3.1). if Ekind (Obj_Id) = E_Variable then if not Is_Library_Level_Entity (Obj_Id) then Error_Pragma ("pragma % must apply to a library level variable"); return; end if; -- Otherwise the pragma applies to a constant, which is illegal else Error_Pragma ("pragma % must apply to a variable declaration"); return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Obj_Id); -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Obj_Id); -- Analyze the Boolean expression (if any) if Present (Arg1) then Check_Static_Boolean_Expression (Get_Pragma_Arg (Arg1)); end if; end Constant_After_Elaboration; -------------------- -- Contract_Cases -- -------------------- -- pragma Contract_Cases ((CONTRACT_CASE {, CONTRACT_CASE)); -- CONTRACT_CASE ::= CASE_GUARD => CONSEQUENCE -- CASE_GUARD ::= boolean_EXPRESSION | others -- CONSEQUENCE ::= boolean_EXPRESSION -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expressions in: -- Analyze_Contract_Cases_In_Decl_Part -- * Expansion - The annotation is expanded during the expansion of -- the related subprogram [body] contract as performed in: -- Expand_Subprogram_Contract -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Contract_Cases => Contract_Cases : declare Spec_Id : Entity_Id; Subp_Decl : Node_Id; Subp_Spec : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); -- Ensure the proper placement of the pragma. Contract_Cases must -- be associated with a subprogram declaration or a body that acts -- as a spec. Subp_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); -- Entry if Nkind (Subp_Decl) = N_Entry_Declaration then null; -- Generic subprogram elsif Nkind (Subp_Decl) = N_Generic_Subprogram_Declaration then null; -- Body acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body and then No (Corresponding_Spec (Subp_Decl)) then null; -- Body stub acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body_Stub and then No (Corresponding_Spec_Of_Stub (Subp_Decl)) then null; -- Subprogram elsif Nkind (Subp_Decl) = N_Subprogram_Declaration then Subp_Spec := Specification (Subp_Decl); -- Pragma Contract_Cases is forbidden on null procedures, as -- this may lead to potential ambiguities in behavior when -- interface null procedures are involved. if Nkind (Subp_Spec) = N_Procedure_Specification and then Null_Present (Subp_Spec) then Error_Msg_N (Fix_Error ("pragma % cannot apply to null procedure"), N); return; end if; else Pragma_Misplaced; return; end if; Spec_Id := Unique_Defining_Entity (Subp_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Spec_Id); Ensure_Aggregate_Form (Get_Argument (N, Spec_Id)); -- Chain the pragma on the contract for further processing by -- Analyze_Contract_Cases_In_Decl_Part. Add_Contract_Item (N, Defining_Entity (Subp_Decl)); -- Fully analyze the pragma when it appears inside an entry -- or subprogram body because it cannot benefit from forward -- references. if Nkind_In (Subp_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub) then -- The legality checks of pragma Contract_Cases are affected by -- the SPARK mode in effect and the volatility of the context. -- Analyze all pragmas in a specific order. Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Contract_Cases_In_Decl_Part (N); end if; end Contract_Cases; ---------------- -- 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 := Get_Pragma_Arg (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; pragma Warnings (Off, C); pragma Warnings (Off, E); begin Check_Arg_Order ((Name_Convention, Name_Entity)); Check_Ada_83_Warning; Check_Arg_Count (2); Process_Convention (C, E); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, 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_Order ((Name_Name, Name_Convention)); 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 (Arg2); Idnam := Chars (Get_Pragma_Arg (Arg1)); Cname := Chars (Get_Pragma_Arg (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 => GNAT_Pragma; if Warn_On_Obsolescent_Feature then Error_Msg_N ("'G'N'A'T pragma cpp'_class is now obsolete and has no " & "effect; replace it by pragma import?j?", N); end if; Check_Arg_Count (1); Rewrite (N, Make_Pragma (Loc, Chars => Name_Import, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Name_CPP)), New_Copy (First (Pragma_Argument_Associations (N)))))); Analyze (N); --------------------- -- CPP_Constructor -- --------------------- -- pragma CPP_Constructor ([Entity =>] LOCAL_NAME -- [, [External_Name =>] static_string_EXPRESSION ] -- [, [Link_Name =>] static_string_EXPRESSION ]); when Pragma_CPP_Constructor => CPP_Constructor : declare Elmt : Elmt_Id; Id : Entity_Id; Def_Id : Entity_Id; Tag_Typ : Entity_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (3); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Id := Get_Pragma_Arg (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); -- Check if already defined as constructor if Is_Constructor (Def_Id) then Error_Msg_N ("??duplicate argument for pragma 'C'P'P_Constructor", Arg1); return; end if; if Ekind (Def_Id) = E_Function and then (Is_CPP_Class (Etype (Def_Id)) or else (Is_Class_Wide_Type (Etype (Def_Id)) and then Is_CPP_Class (Root_Type (Etype (Def_Id))))) then if Scope (Def_Id) /= Scope (Etype (Def_Id)) then Error_Msg_N ("'C'P'P constructor must be defined in the scope of " & "its returned type", Arg1); end if; if Arg_Count >= 2 then Set_Imported (Def_Id); Set_Is_Public (Def_Id); Process_Interface_Name (Def_Id, Arg2, Arg3, N); end if; Set_Has_Completion (Def_Id); Set_Is_Constructor (Def_Id); Set_Convention (Def_Id, Convention_CPP); -- Imported C++ constructors are not dispatching primitives -- because in C++ they don't have a dispatch table slot. -- However, in Ada the constructor has the profile of a -- function that returns a tagged type and therefore it has -- been treated as a primitive operation during semantic -- analysis. We now remove it from the list of primitive -- operations of the type. if Is_Tagged_Type (Etype (Def_Id)) and then not Is_Class_Wide_Type (Etype (Def_Id)) and then Is_Dispatching_Operation (Def_Id) then Tag_Typ := Etype (Def_Id); Elmt := First_Elmt (Primitive_Operations (Tag_Typ)); while Present (Elmt) and then Node (Elmt) /= Def_Id loop Next_Elmt (Elmt); end loop; Remove_Elmt (Primitive_Operations (Tag_Typ), Elmt); Set_Is_Dispatching_Operation (Def_Id, False); end if; -- For backward compatibility, if the constructor returns a -- class wide type, and we internally change the return type to -- the corresponding root type. if Is_Class_Wide_Type (Etype (Def_Id)) then Set_Etype (Def_Id, Root_Type (Etype (Def_Id))); end if; else Error_Pragma_Arg ("pragma% requires function returning a 'C'P'P_Class type", Arg1); end if; end CPP_Constructor; ----------------- -- CPP_Virtual -- ----------------- when Pragma_CPP_Virtual => GNAT_Pragma; if Warn_On_Obsolescent_Feature then Error_Msg_N ("'G'N'A'T pragma Cpp'_Virtual is now obsolete and has no " & "effect?j?", N); end if; ---------------- -- CPP_Vtable -- ---------------- when Pragma_CPP_Vtable => GNAT_Pragma; if Warn_On_Obsolescent_Feature then Error_Msg_N ("'G'N'A'T pragma Cpp'_Vtable is now obsolete and has no " & "effect?j?", N); end if; --------- -- CPU -- --------- -- pragma CPU (EXPRESSION); when Pragma_CPU => CPU : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin Ada_2012_Pragma; Check_No_Identifiers; Check_Arg_Count (1); -- Subprogram case if Nkind (P) = N_Subprogram_Body then Check_In_Main_Program; Arg := Get_Pragma_Arg (Arg1); Analyze_And_Resolve (Arg, Any_Integer); Ent := Defining_Unit_Name (Specification (P)); if Nkind (Ent) = N_Defining_Program_Unit_Name then Ent := Defining_Identifier (Ent); end if; -- Must be static if not Is_OK_Static_Expression (Arg) then Flag_Non_Static_Expr ("main subprogram affinity 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 CPU_Id : constant Entity_Id := RTE (RE_CPU_Range); -- This is the entity System.Multiprocessors.CPU_Range; Val : constant Uint := Expr_Value (Arg); begin if Val < Expr_Value (Type_Low_Bound (CPU_Id)) or else Val > Expr_Value (Type_High_Bound (CPU_Id)) then Error_Pragma_Arg ("main subprogram CPU is out of range", Arg1); end if; end; end if; Set_Main_CPU (Current_Sem_Unit, UI_To_Int (Expr_Value (Arg))); -- Task case elsif Nkind (P) = N_Task_Definition then Arg := Get_Pragma_Arg (Arg1); Ent := Defining_Identifier (Parent (P)); -- The expression must be analyzed in the special manner -- described in "Handling of Default and Per-Object -- Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, RTE (RE_CPU_Range)); -- Anything else is incorrect else Pragma_Misplaced; end if; -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); end CPU; -------------------- -- Deadline_Floor -- -------------------- -- pragma Deadline_Floor (time_span_EXPRESSION); when Pragma_Deadline_Floor => Deadline_Floor : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Arg := Get_Pragma_Arg (Arg1); -- The expression must be analyzed in the special manner described -- in "Handling of Default and Per-Object Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, RTE (RE_Time_Span)); -- Only protected types allowed if Nkind (P) /= N_Protected_Definition then Pragma_Misplaced; else Ent := Defining_Identifier (Parent (P)); -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); end if; end Deadline_Floor; ----------- -- Debug -- ----------- -- pragma Debug ([boolean_EXPRESSION,] PROCEDURE_CALL_STATEMENT); when Pragma_Debug => Debug : declare Cond : Node_Id; Call : Node_Id; begin GNAT_Pragma; -- The condition for executing the call is that the expander -- is active and that we are not ignoring this debug pragma. Cond := New_Occurrence_Of (Boolean_Literals (Expander_Active and then not Is_Ignored (N)), Loc); if not Is_Ignored (N) then Set_SCO_Pragma_Enabled (Loc); end if; if Arg_Count = 2 then Cond := Make_And_Then (Loc, Left_Opnd => Relocate_Node (Cond), Right_Opnd => Get_Pragma_Arg (Arg1)); Call := Get_Pragma_Arg (Arg2); else Call := Get_Pragma_Arg (Arg1); end if; if Nkind_In (Call, N_Expanded_Name, N_Function_Call, N_Identifier, N_Indexed_Component, N_Selected_Component) then -- If this pragma Debug comes from source, its argument was -- parsed as a name form (which is syntactically identical). -- In a generic context a parameterless call will be left as -- an expanded name (if global) or selected_component if local. -- Change it to a procedure call statement now. Change_Name_To_Procedure_Call_Statement (Call); elsif Nkind (Call) = N_Procedure_Call_Statement then -- Already in the form of a procedure call statement: nothing -- to do (could happen in case of an internally generated -- pragma Debug). null; else -- All other cases: diagnose error Error_Msg ("argument of pragma ""Debug"" is not procedure call", Sloc (Call)); return; end if; -- Rewrite into a conditional with an appropriate condition. We -- wrap the procedure call in a block so that overhead from e.g. -- use of the secondary stack does not generate execution overhead -- for suppressed conditions. -- Normally the analysis that follows will freeze the subprogram -- being called. However, if the call is to a null procedure, -- we want to freeze it before creating the block, because the -- analysis that follows may be done with expansion disabled, in -- which case the body will not be generated, leading to spurious -- errors. if Nkind (Call) = N_Procedure_Call_Statement and then Is_Entity_Name (Name (Call)) then Analyze (Name (Call)); Freeze_Before (N, Entity (Name (Call))); end if; Rewrite (N, Make_Implicit_If_Statement (N, Condition => Cond, Then_Statements => New_List ( Make_Block_Statement (Loc, Handled_Statement_Sequence => Make_Handled_Sequence_Of_Statements (Loc, Statements => New_List (Relocate_Node (Call))))))); Analyze (N); -- Ignore pragma Debug in GNATprove mode. Do this rewriting -- after analysis of the normally rewritten node, to capture all -- references to entities, which avoids issuing wrong warnings -- about unused entities. if GNATprove_Mode then Rewrite (N, Make_Null_Statement (Loc)); end if; end Debug; ------------------ -- Debug_Policy -- ------------------ -- pragma Debug_Policy (On | Off | Check | Disable | Ignore) when Pragma_Debug_Policy => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Identifier (Arg1); -- Exactly equivalent to pragma Check_Policy (Debug, arg), so -- rewrite it that way, and let the rest of the checking come -- from analyzing the rewritten pragma. Rewrite (N, Make_Pragma (Loc, Chars => Name_Check_Policy, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Name_Debug)), Make_Pragma_Argument_Association (Loc, Expression => Get_Pragma_Arg (Arg1))))); Analyze (N); ------------------------------- -- Default_Initial_Condition -- ------------------------------- -- pragma Default_Initial_Condition [ (null | boolean_EXPRESSION) ]; when Pragma_Default_Initial_Condition => DIC : declare Discard : Boolean; Stmt : Node_Id; Typ : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Typ := Empty; Stmt := Prev (N); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates if Nkind (Stmt) = N_Pragma then if Pragma_Name (Stmt) = Pname then Duplication_Error (Prag => N, Prev => Stmt); raise Pragma_Exit; end if; -- Skip internally generated code. Note that derived type -- declarations of untagged types with discriminants are -- rewritten as private type declarations. elsif not Comes_From_Source (Stmt) and then Nkind (Stmt) /= N_Private_Type_Declaration then null; -- The associated private type [extension] has been found, stop -- the search. elsif Nkind_In (Stmt, N_Private_Extension_Declaration, N_Private_Type_Declaration) then Typ := Defining_Entity (Stmt); exit; -- The pragma does not apply to a legal construct, issue an -- error and stop the analysis. else Pragma_Misplaced; return; end if; Stmt := Prev (Stmt); end loop; -- The pragma does not apply to a legal construct, issue an error -- and stop the analysis. if No (Typ) then Pragma_Misplaced; return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- The pragma signals that the type defines its own DIC assertion -- expression. Set_Has_Own_DIC (Typ); -- Chain the pragma on the rep item chain for further processing Discard := Rep_Item_Too_Late (Typ, N, FOnly => True); -- Create the declaration of the procedure which verifies the -- assertion expression of pragma DIC at runtime. Build_DIC_Procedure_Declaration (Typ); end DIC; ---------------------------------- -- Default_Scalar_Storage_Order -- ---------------------------------- -- pragma Default_Scalar_Storage_Order -- (High_Order_First | Low_Order_First); when Pragma_Default_Scalar_Storage_Order => DSSO : declare Default : Character; begin GNAT_Pragma; Check_Arg_Count (1); -- Default_Scalar_Storage_Order can appear as a configuration -- pragma, or in a declarative part of a package spec. if not Is_Configuration_Pragma then Check_Is_In_Decl_Part_Or_Package_Spec; end if; Check_No_Identifiers; Check_Arg_Is_One_Of (Arg1, Name_High_Order_First, Name_Low_Order_First); Get_Name_String (Chars (Get_Pragma_Arg (Arg1))); Default := Fold_Upper (Name_Buffer (1)); if not Support_Nondefault_SSO_On_Target and then (Ttypes.Bytes_Big_Endian /= (Default = 'H')) then if Warn_On_Unrecognized_Pragma then Error_Msg_N ("non-default Scalar_Storage_Order not supported " & "on target?g?", N); Error_Msg_N ("\pragma Default_Scalar_Storage_Order ignored?g?", N); end if; -- Here set the specified default else Opt.Default_SSO := Default; end if; end DSSO; -------------------------- -- Default_Storage_Pool -- -------------------------- -- pragma Default_Storage_Pool (storage_pool_NAME | null); when Pragma_Default_Storage_Pool => Default_Storage_Pool : declare Pool : Node_Id; begin Ada_2012_Pragma; Check_Arg_Count (1); -- Default_Storage_Pool can appear as a configuration pragma, or -- in a declarative part of a package spec. if not Is_Configuration_Pragma then Check_Is_In_Decl_Part_Or_Package_Spec; end if; if From_Aspect_Specification (N) then declare E : constant Entity_Id := Entity (Corresponding_Aspect (N)); begin if not In_Open_Scopes (E) then Error_Msg_N ("aspect must apply to package or subprogram", N); end if; end; end if; if Present (Arg1) then Pool := Get_Pragma_Arg (Arg1); -- Case of Default_Storage_Pool (null); if Nkind (Pool) = N_Null then Analyze (Pool); -- This is an odd case, this is not really an expression, -- so we don't have a type for it. So just set the type to -- Empty. Set_Etype (Pool, Empty); -- Case of Default_Storage_Pool (storage_pool_NAME); else -- If it's a configuration pragma, then the only allowed -- argument is "null". if Is_Configuration_Pragma then Error_Pragma_Arg ("NULL expected", Arg1); end if; -- The expected type for a non-"null" argument is -- Root_Storage_Pool'Class, and the pool must be a variable. Analyze_And_Resolve (Pool, Class_Wide_Type (RTE (RE_Root_Storage_Pool))); if Is_Variable (Pool) then -- A pragma that applies to a Ghost entity becomes Ghost -- for the purposes of legality checks and removal of -- ignored Ghost code. Mark_Ghost_Pragma (N, Entity (Pool)); else Error_Pragma_Arg ("default storage pool must be a variable", Arg1); end if; end if; -- Record the pool name (or null). Freeze.Freeze_Entity for an -- access type will use this information to set the appropriate -- attributes of the access type. If the pragma appears in a -- generic unit it is ignored, given that it may refer to a -- local entity. if not Inside_A_Generic then Default_Pool := Pool; end if; end if; end Default_Storage_Pool; ------------- -- Depends -- ------------- -- pragma Depends (DEPENDENCY_RELATION); -- DEPENDENCY_RELATION ::= -- null -- | (DEPENDENCY_CLAUSE {, DEPENDENCY_CLAUSE}) -- DEPENDENCY_CLAUSE ::= -- OUTPUT_LIST =>[+] INPUT_LIST -- | NULL_DEPENDENCY_CLAUSE -- NULL_DEPENDENCY_CLAUSE ::= null => INPUT_LIST -- OUTPUT_LIST ::= OUTPUT | (OUTPUT {, OUTPUT}) -- INPUT_LIST ::= null | INPUT | (INPUT {, INPUT}) -- OUTPUT ::= NAME | FUNCTION_RESULT -- INPUT ::= NAME -- where FUNCTION_RESULT is a function Result attribute_reference -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks fully analyze -- the dependency clauses in: -- Analyze_Depends_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Depends => Depends : declare Legal : Boolean; Spec_Id : Entity_Id; Subp_Decl : Node_Id; begin Analyze_Depends_Global (Spec_Id, Subp_Decl, Legal); if Legal then -- Chain the pragma on the contract for further processing by -- Analyze_Depends_In_Decl_Part. Add_Contract_Item (N, Spec_Id); -- Fully analyze the pragma when it appears inside an entry -- or subprogram body because it cannot benefit from forward -- references. if Nkind_In (Subp_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub) then -- The legality checks of pragmas Depends and Global are -- affected by the SPARK mode in effect and the volatility -- of the context. In addition these two pragmas are subject -- to an inherent order: -- 1) Global -- 2) Depends -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_If_Present (Pragma_Global); Analyze_Depends_In_Decl_Part (N); end if; end if; end Depends; --------------------- -- Detect_Blocking -- --------------------- -- pragma Detect_Blocking; when Pragma_Detect_Blocking => Ada_2005_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Detect_Blocking := True; ------------------------------------ -- Disable_Atomic_Synchronization -- ------------------------------------ -- pragma Disable_Atomic_Synchronization [(Entity)]; when Pragma_Disable_Atomic_Synchronization => GNAT_Pragma; Process_Disable_Enable_Atomic_Sync (Name_Suppress); ------------------- -- Discard_Names -- ------------------- -- pragma Discard_Names [([On =>] LOCAL_NAME)]; when Pragma_Discard_Names => Discard_Names : declare E : Entity_Id; E_Id : Node_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, and recursively -- to any nested scope. 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 := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored -- Ghost code. Mark_Ghost_Pragma (N, E); 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); Record_Rep_Item (E, N); else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; end if; end if; end Discard_Names; ------------------------ -- Dispatching_Domain -- ------------------------ -- pragma Dispatching_Domain (EXPRESSION); when Pragma_Dispatching_Domain => Dispatching_Domain : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin Ada_2012_Pragma; Check_No_Identifiers; Check_Arg_Count (1); -- This pragma is born obsolete, but not the aspect if not From_Aspect_Specification (N) then Check_Restriction (No_Obsolescent_Features, Pragma_Identifier (N)); end if; if Nkind (P) = N_Task_Definition then Arg := Get_Pragma_Arg (Arg1); Ent := Defining_Identifier (Parent (P)); -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. Mark_Ghost_Pragma (N, Ent); -- The expression must be analyzed in the special manner -- described in "Handling of Default and Per-Object -- Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, RTE (RE_Dispatching_Domain)); -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); -- Anything else is incorrect else Pragma_Misplaced; end if; end Dispatching_Domain; --------------- -- Elaborate -- --------------- -- pragma Elaborate (library_unit_NAME {, library_unit_NAME}); when Pragma_Elaborate => Elaborate : declare Arg : Node_Id; Citem : Node_Id; begin -- Pragma must be in context items list of a compilation unit if not Is_In_Context_Clause then Pragma_Misplaced; 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_Version = 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 all identifiers or selected -- components. Arg := Arg1; Outer : while Present (Arg) loop Citem := First (List_Containing (N)); Inner : while Citem /= N loop if Nkind (Citem) = N_With_Clause and then Same_Name (Name (Citem), Get_Pragma_Arg (Arg)) then Set_Elaborate_Present (Citem, True); Set_Elab_Unit_Name (Get_Pragma_Arg (Arg), Name (Citem)); -- With the pragma present, elaboration calls on -- subprograms from the named unit need no further -- checks, as long as the pragma appears in the current -- compilation unit. If the pragma appears in some unit -- in the context, there might still be a need for an -- Elaborate_All_Desirable from the current compilation -- to the named unit, so we keep the check enabled. This -- does not apply in SPARK mode, where we allow pragma -- Elaborate, but we don't trust it to be right so we -- will still insist on the Elaborate_All. if Legacy_Elaboration_Checks and then In_Extended_Main_Source_Unit (N) and then SPARK_Mode /= On then Set_Suppress_Elaboration_Warnings (Entity (Name (Citem))); end if; exit Inner; end if; Next (Citem); end loop Inner; if Citem = N then Error_Pragma_Arg ("argument of pragma% is not withed unit", Arg); end if; Next (Arg); end loop Outer; end Elaborate; ------------------- -- Elaborate_All -- ------------------- -- pragma Elaborate_All (library_unit_NAME {, library_unit_NAME}); when Pragma_Elaborate_All => Elaborate_All : declare 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_In_Context_Clause then Pragma_Misplaced; 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 (List_Containing (N)); Innr : while Citem /= N loop if Nkind (Citem) = N_With_Clause and then Same_Name (Name (Citem), Get_Pragma_Arg (Arg)) then Set_Elaborate_All_Present (Citem, True); Set_Elab_Unit_Name (Get_Pragma_Arg (Arg), Name (Citem)); -- Suppress warnings and elaboration checks on the named -- unit if the pragma is in the current compilation, as -- for pragma Elaborate. if Legacy_Elaboration_Checks and then In_Extended_Main_Source_Unit (N) then Set_Suppress_Elaboration_Warnings (Entity (Name (Citem))); end if; 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 withed 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); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Cunit_Ent); if Nkind_In (Unit (Cunit_Node), N_Package_Body, N_Subprogram_Body) then Error_Pragma ("pragma% must refer to a spec, not a body"); else Set_Body_Required (Cunit_Node); 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 Legacy_Elaboration_Checks and then (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 => Elaboration_Checks : declare procedure Check_Duplicate_Elaboration_Checks_Pragma; -- Emit an error if the current context list already contains -- a previous Elaboration_Checks pragma. This routine raises -- Pragma_Exit if a duplicate is found. procedure Ignore_Elaboration_Checks_Pragma; -- Warn that the effects of the pragma are ignored. This routine -- raises Pragma_Exit. ----------------------------------------------- -- Check_Duplicate_Elaboration_Checks_Pragma -- ----------------------------------------------- procedure Check_Duplicate_Elaboration_Checks_Pragma is Item : Node_Id; begin Item := Prev (N); while Present (Item) loop if Nkind (Item) = N_Pragma and then Pragma_Name (Item) = Name_Elaboration_Checks then Duplication_Error (Prag => N, Prev => Item); raise Pragma_Exit; end if; Prev (Item); end loop; end Check_Duplicate_Elaboration_Checks_Pragma; -------------------------------------- -- Ignore_Elaboration_Checks_Pragma -- -------------------------------------- procedure Ignore_Elaboration_Checks_Pragma is begin Error_Msg_Name_1 := Pname; Error_Msg_N ("??effects of pragma % are ignored", N); Error_Msg_N ("\place pragma on initial declaration of library unit", N); raise Pragma_Exit; end Ignore_Elaboration_Checks_Pragma; -- Local variables Context : constant Node_Id := Parent (N); Unt : Node_Id; -- Start of processing for Elaboration_Checks begin GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_One_Of (Arg1, Name_Static, Name_Dynamic); -- The pragma appears in a configuration file if No (Context) then Check_Valid_Configuration_Pragma; Check_Duplicate_Elaboration_Checks_Pragma; -- The pragma acts as a configuration pragma in a compilation unit -- pragma Elaboration_Checks (...); -- package Pack is ...; elsif Nkind (Context) = N_Compilation_Unit and then List_Containing (N) = Context_Items (Context) then Check_Valid_Configuration_Pragma; Check_Duplicate_Elaboration_Checks_Pragma; Unt := Unit (Context); -- The pragma must appear on the initial declaration of a unit. -- If this is not the case, warn that the effects of the pragma -- are ignored. if Nkind (Unt) = N_Package_Body then Ignore_Elaboration_Checks_Pragma; -- Check the Acts_As_Spec flag of the compilation units itself -- to determine whether the subprogram body completes since it -- has not been analyzed yet. This is safe because compilation -- units are not overloadable. elsif Nkind (Unt) = N_Subprogram_Body and then not Acts_As_Spec (Context) then Ignore_Elaboration_Checks_Pragma; elsif Nkind (Unt) = N_Subunit then Ignore_Elaboration_Checks_Pragma; end if; -- Otherwise the pragma does not appear at the configuration level -- and is illegal. else Pragma_Misplaced; end if; -- At this point the pragma is not a duplicate, and appears in the -- proper context. Set the elaboration model in effect. Dynamic_Elaboration_Checks := Chars (Get_Pragma_Arg (Arg1)) = Name_Dynamic; end Elaboration_Checks; --------------- -- Eliminate -- --------------- -- pragma Eliminate ( -- [Unit_Name =>] IDENTIFIER | SELECTED_COMPONENT, -- [Entity =>] IDENTIFIER | -- SELECTED_COMPONENT | -- STRING_LITERAL] -- [, Source_Location => SOURCE_TRACE]); -- SOURCE_LOCATION ::= Source_Location => SOURCE_TRACE -- SOURCE_TRACE ::= 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_Source_Location); -- Note : Parameter_Types and Result_Type are leftovers from -- prior implementations of the pragma. They are not generated -- by the gnatelim tool, and play no role in selecting which -- of a set of overloaded names is chosen for elimination. 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); Source_Location : 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 (Source_Location)) then Error_Pragma ("missing Entity argument for pragma%"); end if; if (Present (Parameter_Types) or else Present (Result_Type)) and then Present (Source_Location) then Error_Pragma ("parameter profile and source location cannot be used " & "together in pragma%"); end if; Process_Eliminate_Pragma (N, Unit_Name, Entity, Parameter_Types, Result_Type, Source_Location); end Eliminate; ----------------------------------- -- Enable_Atomic_Synchronization -- ----------------------------------- -- pragma Enable_Atomic_Synchronization [(Entity)]; when Pragma_Enable_Atomic_Synchronization => GNAT_Pragma; Process_Disable_Enable_Atomic_Sync (Name_Unsuppress); ------------ -- 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; pragma Warnings (Off, C); begin Check_Ada_83_Warning; Check_Arg_Order ((Name_Convention, Name_Entity, Name_External_Name, Name_Link_Name)); Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); -- In Relaxed_RM_Semantics, support old Ada 83 style: -- pragma Export (Entity, "external name"); if Relaxed_RM_Semantics and then Arg_Count = 2 and then Nkind (Expression (Arg2)) = N_String_Literal then C := Convention_C; Def_Id := Get_Pragma_Arg (Arg1); Analyze (Def_Id); if not Is_Entity_Name (Def_Id) then Error_Pragma_Arg ("entity name required", Arg1); end if; Def_Id := Entity (Def_Id); Set_Exported (Def_Id, Arg1); else Process_Convention (C, Def_Id); -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. Mark_Ghost_Pragma (N, Def_Id); if Ekind (Def_Id) /= E_Constant then Note_Possible_Modification (Get_Pragma_Arg (Arg2), Sure => False); end if; Process_Interface_Name (Def_Id, Arg3, Arg4, N); Set_Exported (Def_Id, Arg2); end if; -- If the entity is a deferred constant, propagate the information -- to the full view, because gigi elaborates the full view only. if Ekind (Def_Id) = E_Constant and then Present (Full_View (Def_Id)) then declare Id2 : constant Entity_Id := Full_View (Def_Id); begin Set_Is_Exported (Id2, Is_Exported (Def_Id)); Set_First_Rep_Item (Id2, First_Rep_Item (Def_Id)); Set_Interface_Name (Id2, Einfo.Interface_Name (Def_Id)); end; end if; end Export; --------------------- -- 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 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 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 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_Order ((Name_Value, Name_Link_Name)); Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Value); Check_Arg_Is_OK_Static_Expression (Arg1, Any_Integer); Check_Optional_Identifier (Arg2, Name_Link_Name); Check_Arg_Is_OK_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 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 => 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 (Get_Pragma_Arg (Arg1))); if Name_Len > 4 and then Name_Buffer (1 .. 4) = "aux_" then if Present (System_Extend_Pragma_Arg) then if Chars (Get_Pragma_Arg (Arg1)) = Chars (Expression (System_Extend_Pragma_Arg)) then null; else Error_Msg_Sloc := Sloc (System_Extend_Pragma_Arg); Error_Pragma ("pragma% conflicts with that #"); 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; ------------------------ -- 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); if Chars (Get_Pragma_Arg (Arg1)) = Name_On then Extensions_Allowed := True; Ada_Version := Ada_Version_Type'Last; else Extensions_Allowed := False; Ada_Version := Ada_Version_Explicit; Ada_Version_Pragma := Empty; end if; ------------------------ -- Extensions_Visible -- ------------------------ -- pragma Extensions_Visible [ (boolean_EXPRESSION) ]; -- Characteristics: -- * Analysis - The annotation is fully analyzed immediately upon -- elaboration as its expression must be static. -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Extensions_Visible => Extensions_Visible : declare Formal : Entity_Id; Has_OK_Formal : Boolean := False; Spec_Id : Entity_Id; Subp_Decl : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Subp_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); -- Abstract subprogram declaration if Nkind (Subp_Decl) = N_Abstract_Subprogram_Declaration then null; -- Generic subprogram declaration elsif Nkind (Subp_Decl) = N_Generic_Subprogram_Declaration then null; -- Body acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body and then No (Corresponding_Spec (Subp_Decl)) then null; -- Body stub acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body_Stub and then No (Corresponding_Spec_Of_Stub (Subp_Decl)) then null; -- Subprogram declaration elsif Nkind (Subp_Decl) = N_Subprogram_Declaration then null; -- Otherwise the pragma is associated with an illegal construct else Error_Pragma ("pragma % must apply to a subprogram"); return; end if; -- Mark the pragma as Ghost if the related subprogram is also -- Ghost. This also ensures that any expansion performed further -- below will produce Ghost nodes. Spec_Id := Unique_Defining_Entity (Subp_Decl); Mark_Ghost_Pragma (N, Spec_Id); -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Defining_Entity (Subp_Decl)); -- The legality checks of pragma Extension_Visible are affected -- by the SPARK mode in effect. Analyze all pragmas in specific -- order. Analyze_If_Present (Pragma_SPARK_Mode); -- Examine the formals of the related subprogram Formal := First_Formal (Spec_Id); while Present (Formal) loop -- At least one of the formals is of a specific tagged type, -- the pragma is legal. if Is_Specific_Tagged_Type (Etype (Formal)) then Has_OK_Formal := True; exit; -- A generic subprogram with at least one formal of a private -- type ensures the legality of the pragma because the actual -- may be specifically tagged. Note that this is verified by -- the check above at instantiation time. elsif Is_Private_Type (Etype (Formal)) and then Is_Generic_Type (Etype (Formal)) then Has_OK_Formal := True; exit; end if; Next_Formal (Formal); end loop; if not Has_OK_Formal then Error_Msg_Name_1 := Pname; Error_Msg_N (Fix_Error ("incorrect placement of pragma %"), N); Error_Msg_NE ("\subprogram & lacks parameter of specific tagged or " & "generic private type", N, Spec_Id); return; end if; -- Analyze the Boolean expression (if any) if Present (Arg1) then Check_Static_Boolean_Expression (Expression (Get_Argument (N, Spec_Id))); end if; end Extensions_Visible; -------------- -- 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; E : Entity_Id; pragma Warnings (Off, C); begin GNAT_Pragma; Check_Arg_Order ((Name_Convention, Name_Entity, Name_External_Name, Name_Link_Name)); Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Convention (C, E); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); Note_Possible_Modification (Get_Pragma_Arg (Arg2), Sure => False); Process_Interface_Name (E, Arg3, Arg4, N); Set_Exported (E, Arg2); end External; -------------------------- -- External_Name_Casing -- -------------------------- -- pragma External_Name_Casing ( -- UPPERCASE | LOWERCASE -- [, AS_IS | UPPERCASE | LOWERCASE]); when Pragma_External_Name_Casing => 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; --------------- -- Fast_Math -- --------------- -- pragma Fast_Math; when Pragma_Fast_Math => GNAT_Pragma; Check_No_Identifiers; Check_Valid_Configuration_Pragma; Fast_Math := True; -------------------------- -- Favor_Top_Level -- -------------------------- -- pragma Favor_Top_Level (type_NAME); when Pragma_Favor_Top_Level => Favor_Top_Level : declare Typ : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Typ := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- If it's an access-to-subprogram type (in particular, not a -- subtype), set the flag on that type. if Is_Access_Subprogram_Type (Typ) then Set_Can_Use_Internal_Rep (Typ, False); -- Otherwise it's an error (name denotes the wrong sort of entity) else Error_Pragma_Arg ("access-to-subprogram type expected", Get_Pragma_Arg (Arg1)); end if; end Favor_Top_Level; --------------------------- -- 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 := Get_Pragma_Arg (Assoc); Typ : Entity_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 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; ----------- -- Ghost -- ----------- -- pragma Ghost [ (boolean_EXPRESSION) ]; when Pragma_Ghost => Ghost : declare Context : Node_Id; Expr : Node_Id; Id : Entity_Id; Orig_Stmt : Node_Id; Prev_Id : Entity_Id; Stmt : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Id := Empty; Stmt := Prev (N); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates if Nkind (Stmt) = N_Pragma then if Pragma_Name (Stmt) = Pname then Duplication_Error (Prag => N, Prev => Stmt); raise Pragma_Exit; end if; -- Task unit declared without a definition cannot be subject to -- pragma Ghost (SPARK RM 6.9(19)). elsif Nkind_In (Stmt, N_Single_Task_Declaration, N_Task_Type_Declaration) then Error_Pragma ("pragma % cannot apply to a task type"); return; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then Orig_Stmt := Original_Node (Stmt); -- When pragma Ghost applies to an untagged derivation, the -- derivation is transformed into a [sub]type declaration. if Nkind_In (Stmt, N_Full_Type_Declaration, N_Subtype_Declaration) and then Comes_From_Source (Orig_Stmt) and then Nkind (Orig_Stmt) = N_Full_Type_Declaration and then Nkind (Type_Definition (Orig_Stmt)) = N_Derived_Type_Definition then Id := Defining_Entity (Stmt); exit; -- When pragma Ghost applies to an object declaration which -- is initialized by means of a function call that returns -- on the secondary stack, the object declaration becomes a -- renaming. elsif Nkind (Stmt) = N_Object_Renaming_Declaration and then Comes_From_Source (Orig_Stmt) and then Nkind (Orig_Stmt) = N_Object_Declaration then Id := Defining_Entity (Stmt); exit; -- When pragma Ghost applies to an expression function, the -- expression function is transformed into a subprogram. elsif Nkind (Stmt) = N_Subprogram_Declaration and then Comes_From_Source (Orig_Stmt) and then Nkind (Orig_Stmt) = N_Expression_Function then Id := Defining_Entity (Stmt); exit; end if; -- The pragma applies to a legal construct, stop the traversal elsif Nkind_In (Stmt, N_Abstract_Subprogram_Declaration, N_Full_Type_Declaration, N_Generic_Subprogram_Declaration, N_Object_Declaration, N_Private_Extension_Declaration, N_Private_Type_Declaration, N_Subprogram_Declaration, N_Subtype_Declaration) then Id := Defining_Entity (Stmt); exit; -- The pragma does not apply to a legal construct, issue an -- error and stop the analysis. else Error_Pragma ("pragma % must apply to an object, package, subprogram " & "or type"); return; end if; Stmt := Prev (Stmt); end loop; Context := Parent (N); -- Handle compilation units if Nkind (Context) = N_Compilation_Unit_Aux then Context := Unit (Parent (Context)); end if; -- Protected and task types cannot be subject to pragma Ghost -- (SPARK RM 6.9(19)). if Nkind_In (Context, N_Protected_Body, N_Protected_Definition) then Error_Pragma ("pragma % cannot apply to a protected type"); return; elsif Nkind_In (Context, N_Task_Body, N_Task_Definition) then Error_Pragma ("pragma % cannot apply to a task type"); return; end if; if No (Id) then -- When pragma Ghost is associated with a [generic] package, it -- appears in the visible declarations. if Nkind (Context) = N_Package_Specification and then Present (Visible_Declarations (Context)) and then List_Containing (N) = Visible_Declarations (Context) then Id := Defining_Entity (Context); -- Pragma Ghost applies to a stand-alone subprogram body elsif Nkind (Context) = N_Subprogram_Body and then No (Corresponding_Spec (Context)) then Id := Defining_Entity (Context); -- Pragma Ghost applies to a subprogram declaration that acts -- as a compilation unit. elsif Nkind (Context) = N_Subprogram_Declaration then Id := Defining_Entity (Context); -- Pragma Ghost applies to a generic subprogram elsif Nkind (Context) = N_Generic_Subprogram_Declaration then Id := Defining_Entity (Specification (Context)); end if; end if; if No (Id) then Error_Pragma ("pragma % must apply to an object, package, subprogram or " & "type"); return; end if; -- Handle completions of types and constants that are subject to -- pragma Ghost. if Is_Record_Type (Id) or else Ekind (Id) = E_Constant then Prev_Id := Incomplete_Or_Partial_View (Id); if Present (Prev_Id) and then not Is_Ghost_Entity (Prev_Id) then Error_Msg_Name_1 := Pname; -- The full declaration of a deferred constant cannot be -- subject to pragma Ghost unless the deferred declaration -- is also Ghost (SPARK RM 6.9(9)). if Ekind (Prev_Id) = E_Constant then Error_Msg_Name_1 := Pname; Error_Msg_NE (Fix_Error ("pragma % must apply to declaration of deferred " & "constant &"), N, Id); return; -- Pragma Ghost may appear on the full view of an incomplete -- type because the incomplete declaration lacks aspects and -- cannot be subject to pragma Ghost. elsif Ekind (Prev_Id) = E_Incomplete_Type then null; -- The full declaration of a type cannot be subject to -- pragma Ghost unless the partial view is also Ghost -- (SPARK RM 6.9(9)). else Error_Msg_NE (Fix_Error ("pragma % must apply to partial view of type &"), N, Id); return; end if; end if; -- A synchronized object cannot be subject to pragma Ghost -- (SPARK RM 6.9(19)). elsif Ekind (Id) = E_Variable then if Is_Protected_Type (Etype (Id)) then Error_Pragma ("pragma % cannot apply to a protected object"); return; elsif Is_Task_Type (Etype (Id)) then Error_Pragma ("pragma % cannot apply to a task object"); return; end if; end if; -- Analyze the Boolean expression (if any) if Present (Arg1) then Expr := Get_Pragma_Arg (Arg1); Analyze_And_Resolve (Expr, Standard_Boolean); if Is_OK_Static_Expression (Expr) then -- "Ghostness" cannot be turned off once enabled within a -- region (SPARK RM 6.9(6)). if Is_False (Expr_Value (Expr)) and then Ghost_Mode > None then Error_Pragma ("pragma % with value False cannot appear in enabled " & "ghost region"); return; end if; -- Otherwie the expression is not static else Error_Pragma_Arg ("expression of pragma % must be static", Expr); return; end if; end if; Set_Is_Ghost_Entity (Id); end Ghost; ------------ -- Global -- ------------ -- pragma Global (GLOBAL_SPECIFICATION); -- GLOBAL_SPECIFICATION ::= -- null -- | (GLOBAL_LIST) -- | (MODED_GLOBAL_LIST {, MODED_GLOBAL_LIST}) -- MODED_GLOBAL_LIST ::= MODE_SELECTOR => GLOBAL_LIST -- MODE_SELECTOR ::= In_Out | Input | Output | Proof_In -- GLOBAL_LIST ::= GLOBAL_ITEM | (GLOBAL_ITEM {, GLOBAL_ITEM}) -- GLOBAL_ITEM ::= NAME -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks fully analyze -- the dependency clauses in: -- Analyze_Global_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Global => Global : declare Legal : Boolean; Spec_Id : Entity_Id; Subp_Decl : Node_Id; begin Analyze_Depends_Global (Spec_Id, Subp_Decl, Legal); if Legal then -- Chain the pragma on the contract for further processing by -- Analyze_Global_In_Decl_Part. Add_Contract_Item (N, Spec_Id); -- Fully analyze the pragma when it appears inside an entry -- or subprogram body because it cannot benefit from forward -- references. if Nkind_In (Subp_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub) then -- The legality checks of pragmas Depends and Global are -- affected by the SPARK mode in effect and the volatility -- of the context. In addition these two pragmas are subject -- to an inherent order: -- 1) Global -- 2) Depends -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Global_In_Decl_Part (N); Analyze_If_Present (Pragma_Depends); end if; end if; end Global; ----------- -- Ident -- ----------- -- pragma Ident (static_string_EXPRESSION) -- Note: pragma Comment shares this processing. Pragma Ident is -- identical in effect to pragma Commment. when Pragma_Comment | Pragma_Ident => Ident : declare Str : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_OK_Static_Expression (Arg1, Standard_String); Store_Note (N); Str := Expr_Value_S (Get_Pragma_Arg (Arg1)); declare CS : Node_Id; GP : Node_Id; begin GP := Parent (Parent (N)); if Nkind_In (GP, N_Package_Declaration, 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 -- If we have multiple instances, concatenate them, but -- not in ASIS, where we want the original tree. if not ASIS_Mode then Start_String (Strval (CS)); Store_String_Char (' '); Store_String_Chars (Strval (Str)); Set_Strval (CS, End_String); end if; else 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; end if; end; end Ident; ------------------- -- Ignore_Pragma -- ------------------- -- pragma Ignore_Pragma (pragma_IDENTIFIER); -- Entirely handled in the parser, nothing to do here when Pragma_Ignore_Pragma => null; ---------------------------- -- Implementation_Defined -- ---------------------------- -- pragma Implementation_Defined (LOCAL_NAME); -- Marks previously declared entity as implementation defined. For -- an overloaded entity, applies to the most recent homonym. -- pragma Implementation_Defined; -- The form with no arguments appears anywhere within a scope, most -- typically a package spec, and indicates that all entities that are -- defined within the package spec are Implementation_Defined. when Pragma_Implementation_Defined => Implementation_Defined : declare Ent : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; -- Form with no arguments if Arg_Count = 0 then Set_Is_Implementation_Defined (Current_Scope); -- Form with one argument else Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Ent := Entity (Get_Pragma_Arg (Arg1)); Set_Is_Implementation_Defined (Ent); end if; end Implementation_Defined; ----------------- -- Implemented -- ----------------- -- pragma Implemented (procedure_LOCAL_NAME, IMPLEMENTATION_KIND); -- IMPLEMENTATION_KIND ::= -- By_Entry | By_Protected_Procedure | By_Any | Optional -- "By_Any" and "Optional" are treated as synonyms in order to -- support Ada 2012 aspect Synchronization. when Pragma_Implemented => Implemented : declare Proc_Id : Entity_Id; Typ : Entity_Id; begin Ada_2012_Pragma; Check_Arg_Count (2); Check_No_Identifiers; Check_Arg_Is_Identifier (Arg1); Check_Arg_Is_Local_Name (Arg1); Check_Arg_Is_One_Of (Arg2, Name_By_Any, Name_By_Entry, Name_By_Protected_Procedure, Name_Optional); -- Extract the name of the local procedure Proc_Id := Entity (Get_Pragma_Arg (Arg1)); -- Ada 2012 (AI05-0030): The procedure_LOCAL_NAME must denote a -- primitive procedure of a synchronized tagged type. if Ekind (Proc_Id) = E_Procedure and then Is_Primitive (Proc_Id) and then Present (First_Formal (Proc_Id)) then Typ := Etype (First_Formal (Proc_Id)); if Is_Tagged_Type (Typ) and then -- Check for a protected, a synchronized or a task interface ((Is_Interface (Typ) and then Is_Synchronized_Interface (Typ)) -- Check for a protected type or a task type that implements -- an interface. or else (Is_Concurrent_Record_Type (Typ) and then Present (Interfaces (Typ))) -- In analysis-only mode, examine original protected type or else (Nkind (Parent (Typ)) = N_Protected_Type_Declaration and then Present (Interface_List (Parent (Typ)))) -- Check for a private record extension with keyword -- "synchronized". or else (Ekind_In (Typ, E_Record_Type_With_Private, E_Record_Subtype_With_Private) and then Synchronized_Present (Parent (Typ)))) then null; else Error_Pragma_Arg ("controlling formal must be of synchronized tagged type", Arg1); return; end if; -- Ada 2012 (AI05-0030): Cannot apply the implementation_kind -- By_Protected_Procedure to the primitive procedure of a task -- interface. if Chars (Arg2) = Name_By_Protected_Procedure and then Is_Interface (Typ) and then Is_Task_Interface (Typ) then Error_Pragma_Arg ("implementation kind By_Protected_Procedure cannot be " & "applied to a task interface primitive", Arg2); return; end if; -- Procedures declared inside a protected type must be accepted elsif Ekind (Proc_Id) = E_Procedure and then Is_Protected_Type (Scope (Proc_Id)) then null; -- The first argument is not a primitive procedure else Error_Pragma_Arg ("pragma % must be applied to a primitive procedure", Arg1); return; end if; Record_Rep_Item (Proc_Id, N); end Implemented; ---------------------- -- Implicit_Packing -- ---------------------- -- pragma Implicit_Packing; when Pragma_Implicit_Packing => GNAT_Pragma; Check_Arg_Count (0); Implicit_Packing := True; ------------ -- 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_Arg_Order ((Name_Convention, Name_Entity, Name_External_Name, Name_Link_Name)); Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Import_Or_Interface; --------------------- -- 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]); -- 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 when Pragma_Import_Function => Import_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 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]); -- 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 when Pragma_Import_Procedure => Import_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 Import_Procedure; ----------------------------- -- Import_Valued_Procedure -- ----------------------------- -- pragma Import_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 when Pragma_Import_Valued_Procedure => Import_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 Import_Valued_Procedure; ----------------- -- Independent -- ----------------- -- pragma Independent (LOCAL_NAME); when Pragma_Independent => Process_Atomic_Independent_Shared_Volatile; ---------------------------- -- Independent_Components -- ---------------------------- -- pragma Independent_Components (array_or_record_LOCAL_NAME); when Pragma_Independent_Components => Independent_Components : declare C : Node_Id; D : Node_Id; E_Id : Node_Id; E : Entity_Id; K : Node_Kind; begin Check_Ada_83_Warning; Ada_2012_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); -- A record type with a self-referential component of anonymous -- access type is given an incomplete view in order to handle the -- self reference: -- -- type Rec is record -- Self : access Rec; -- end record; -- -- becomes -- -- type Rec; -- type Ptr is access Rec; -- type Rec is record -- Self : Ptr; -- end record; -- -- Since the incomplete view is now the initial view of the type, -- the argument of the pragma will reference the incomplete view, -- but this view is illegal according to the semantics of the -- pragma. -- -- Obtain the full view of an internally-generated incomplete type -- only. This way an attempt to associate the pragma with a source -- incomplete type is still caught. if Ekind (E) = E_Incomplete_Type and then not Comes_From_Source (E) and then Present (Full_View (E)) then E := Full_View (E); end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); -- Check duplicate before we chain ourselves Check_Duplicate_Pragma (E); -- Check appropriate entity 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); -- The flag is set on the base type, or on the object if K = N_Full_Type_Declaration and then (Is_Array_Type (E) or else Is_Record_Type (E)) then Set_Has_Independent_Components (Base_Type (E)); Record_Independence_Check (N, Base_Type (E)); -- For record type, set all components independent if Is_Record_Type (E) then C := First_Component (E); while Present (C) loop Set_Is_Independent (C); Next_Component (C); end loop; end if; elsif (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 Set_Has_Independent_Components (E); Record_Independence_Check (N, E); else Error_Pragma_Arg ("inappropriate entity for pragma%", Arg1); end if; end Independent_Components; ----------------------- -- Initial_Condition -- ----------------------- -- pragma Initial_Condition (boolean_EXPRESSION); -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expression in: -- Analyze_Initial_Condition_In_Decl_Part -- * Expansion - The annotation is expanded during the expansion of -- the package body whose declaration is subject to the annotation -- as done in: -- Expand_Pragma_Initial_Condition -- * Template - The annotation utilizes the generic template of the -- related package declaration. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic package is instantiated. when Pragma_Initial_Condition => Initial_Condition : declare Pack_Decl : Node_Id; Pack_Id : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Pack_Decl := Find_Related_Package_Or_Body (N, Do_Checks => True); if not Nkind_In (Pack_Decl, N_Generic_Package_Declaration, N_Package_Declaration) then Pragma_Misplaced; return; end if; Pack_Id := Defining_Entity (Pack_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Pack_Id); -- Chain the pragma on the contract for further processing by -- Analyze_Initial_Condition_In_Decl_Part. Add_Contract_Item (N, Pack_Id); -- The legality checks of pragmas Abstract_State, Initializes, and -- Initial_Condition are affected by the SPARK mode in effect. In -- addition, these three pragmas are subject to an inherent order: -- 1) Abstract_State -- 2) Initializes -- 3) Initial_Condition -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Abstract_State); Analyze_If_Present (Pragma_Initializes); end Initial_Condition; ------------------------ -- Initialize_Scalars -- ------------------------ -- pragma Initialize_Scalars -- [ ( TYPE_VALUE_PAIR {, TYPE_VALUE_PAIR} ) ]; -- TYPE_VALUE_PAIR ::= -- SCALAR_TYPE => static_EXPRESSION -- SCALAR_TYPE := -- Short_Float -- | Float -- | Long_Float -- | Long_Long_Flat -- | Signed_8 -- | Signed_16 -- | Signed_32 -- | Signed_64 -- | Unsigned_8 -- | Unsigned_16 -- | Unsigned_32 -- | Unsigned_64 when Pragma_Initialize_Scalars => Do_Initialize_Scalars : declare Seen : array (Scalar_Id) of Node_Id := (others => Empty); -- This collection holds the individual pairs which specify the -- invalid values of their respective scalar types. procedure Analyze_Float_Value (Scal_Typ : Float_Scalar_Id; Val_Expr : Node_Id); -- Analyze a type value pair associated with float type Scal_Typ -- and expression Val_Expr. procedure Analyze_Integer_Value (Scal_Typ : Integer_Scalar_Id; Val_Expr : Node_Id); -- Analyze a type value pair associated with integer type Scal_Typ -- and expression Val_Expr. procedure Analyze_Type_Value_Pair (Pair : Node_Id); -- Analyze type value pair Pair ------------------------- -- Analyze_Float_Value -- ------------------------- procedure Analyze_Float_Value (Scal_Typ : Float_Scalar_Id; Val_Expr : Node_Id) is begin Analyze_And_Resolve (Val_Expr, Any_Real); if Is_OK_Static_Expression (Val_Expr) then Set_Invalid_Scalar_Value (Scal_Typ, Expr_Value_R (Val_Expr)); else Error_Msg_Name_1 := Scal_Typ; Error_Msg_N ("value for type % must be static", Val_Expr); end if; end Analyze_Float_Value; --------------------------- -- Analyze_Integer_Value -- --------------------------- procedure Analyze_Integer_Value (Scal_Typ : Integer_Scalar_Id; Val_Expr : Node_Id) is begin Analyze_And_Resolve (Val_Expr, Any_Integer); if Is_OK_Static_Expression (Val_Expr) then Set_Invalid_Scalar_Value (Scal_Typ, Expr_Value (Val_Expr)); else Error_Msg_Name_1 := Scal_Typ; Error_Msg_N ("value for type % must be static", Val_Expr); end if; end Analyze_Integer_Value; ----------------------------- -- Analyze_Type_Value_Pair -- ----------------------------- procedure Analyze_Type_Value_Pair (Pair : Node_Id) is Scal_Typ : constant Name_Id := Chars (Pair); Val_Expr : constant Node_Id := Expression (Pair); Prev_Pair : Node_Id; begin if Scal_Typ in Scalar_Id then Prev_Pair := Seen (Scal_Typ); -- Prevent multiple attempts to set a value for a scalar -- type. if Present (Prev_Pair) then Error_Msg_Name_1 := Scal_Typ; Error_Msg_N ("cannot specify multiple invalid values for type %", Pair); Error_Msg_Sloc := Sloc (Prev_Pair); Error_Msg_N ("previous value set #", Pair); -- Ignore the effects of the pair, but do not halt the -- analysis of the pragma altogether. return; -- Otherwise capture the first pair for this scalar type else Seen (Scal_Typ) := Pair; end if; if Scal_Typ in Float_Scalar_Id then Analyze_Float_Value (Scal_Typ, Val_Expr); else pragma Assert (Scal_Typ in Integer_Scalar_Id); Analyze_Integer_Value (Scal_Typ, Val_Expr); end if; -- Otherwise the scalar family is illegal else Error_Msg_Name_1 := Pname; Error_Msg_N ("argument of pragma % must denote valid scalar family", Pair); end if; end Analyze_Type_Value_Pair; -- Local variables Pairs : constant List_Id := Pragma_Argument_Associations (N); Pair : Node_Id; -- Start of processing for Do_Initialize_Scalars begin GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Restriction (No_Initialize_Scalars, N); -- Ignore the effects of the pragma when No_Initialize_Scalars is -- in effect. if Restriction_Active (No_Initialize_Scalars) then null; -- Initialize_Scalars creates false positives in CodePeer, and -- incorrect negative results in GNATprove mode, so ignore this -- pragma in these modes. elsif CodePeer_Mode or GNATprove_Mode then null; -- Otherwise analyze the pragma else if Present (Pairs) then -- Install Standard in order to provide access to primitive -- types in case the expressions contain attributes such as -- Integer'Last. Push_Scope (Standard_Standard); Pair := First (Pairs); while Present (Pair) loop Analyze_Type_Value_Pair (Pair); Next (Pair); end loop; -- Remove Standard Pop_Scope; end if; Init_Or_Norm_Scalars := True; Initialize_Scalars := True; end if; end Do_Initialize_Scalars; ----------------- -- Initializes -- ----------------- -- pragma Initializes (INITIALIZATION_LIST); -- INITIALIZATION_LIST ::= -- null -- | (INITIALIZATION_ITEM {, INITIALIZATION_ITEM}) -- INITIALIZATION_ITEM ::= name [=> INPUT_LIST] -- INPUT_LIST ::= -- null -- | INPUT -- | (INPUT {, INPUT}) -- INPUT ::= name -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expression in: -- Analyze_Initializes_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related package declaration. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic package is instantiated. when Pragma_Initializes => Initializes : declare Pack_Decl : Node_Id; Pack_Id : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Pack_Decl := Find_Related_Package_Or_Body (N, Do_Checks => True); if not Nkind_In (Pack_Decl, N_Generic_Package_Declaration, N_Package_Declaration) then Pragma_Misplaced; return; end if; Pack_Id := Defining_Entity (Pack_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Pack_Id); Ensure_Aggregate_Form (Get_Argument (N, Pack_Id)); -- Chain the pragma on the contract for further processing by -- Analyze_Initializes_In_Decl_Part. Add_Contract_Item (N, Pack_Id); -- The legality checks of pragmas Abstract_State, Initializes, and -- Initial_Condition are affected by the SPARK mode in effect. In -- addition, these three pragmas are subject to an inherent order: -- 1) Abstract_State -- 2) Initializes -- 3) Initial_Condition -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Abstract_State); Analyze_If_Present (Pragma_Initial_Condition); end Initializes; ------------ -- Inline -- ------------ -- pragma Inline ( NAME {, NAME} ); when Pragma_Inline => -- Pragma always active unless in GNATprove mode. It is disabled -- in GNATprove mode because frontend inlining is applied -- independently of pragmas Inline and Inline_Always for -- formal verification, see Can_Be_Inlined_In_GNATprove_Mode -- in inline.ads. if not GNATprove_Mode then -- Inline status is Enabled if option -gnatn is specified. -- However this status determines only the value of the -- Is_Inlined flag on the subprogram and does not prevent -- the pragma itself from being recorded for later use, -- in particular for a later modification of Is_Inlined -- independently of the -gnatn option. -- In other words, if -gnatn is specified for a unit, then -- all Inline pragmas processed for the compilation of this -- unit, including those in the spec of other units, are -- activated, so subprograms will be inlined across units. -- If -gnatn is not specified, no Inline pragma is activated -- here, which means that subprograms will not be inlined -- across units. The Is_Inlined flag will nevertheless be -- set later when bodies are analyzed, so subprograms will -- be inlined within the unit. if Inline_Active then Process_Inline (Enabled); else Process_Inline (Disabled); end if; end if; ------------------- -- Inline_Always -- ------------------- -- pragma Inline_Always ( NAME {, NAME} ); when Pragma_Inline_Always => GNAT_Pragma; -- Pragma always active unless in CodePeer mode or GNATprove -- mode. It is disabled in CodePeer mode because inlining is -- not helpful, and enabling it caused walk order issues. It -- is disabled in GNATprove mode because frontend inlining is -- applied independently of pragmas Inline and Inline_Always for -- formal verification, see Can_Be_Inlined_In_GNATprove_Mode in -- inline.ads. if not CodePeer_Mode and not GNATprove_Mode then Process_Inline (Enabled); end if; -------------------- -- Inline_Generic -- -------------------- -- pragma Inline_Generic (NAME {, NAME}); when Pragma_Inline_Generic => GNAT_Pragma; 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 ip; if Arg_Count > 0 then Arg := Arg1; loop Exp := Get_Pragma_Arg (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 =>] convention_IDENTIFIER, -- [ Entity =>] LOCAL_NAME -- [, [External_Name =>] static_string_EXPRESSION ] -- [, [Link_Name =>] static_string_EXPRESSION ]); when Pragma_Interface => GNAT_Pragma; Check_Arg_Order ((Name_Convention, Name_Entity, Name_External_Name, Name_Link_Name)); Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Process_Import_Or_Interface; -- In Ada 2005, the permission to use Interface (a reserved word) -- as a pragma name is considered an obsolescent feature, and this -- pragma was already obsolescent in Ada 95. if Ada_Version >= Ada_95 then Check_Restriction (No_Obsolescent_Features, Pragma_Identifier (N)); if Warn_On_Obsolescent_Feature then Error_Msg_N ("pragma Interface is an obsolescent feature?j?", N); Error_Msg_N ("|use pragma Import instead?j?", N); end if; end if; -------------------- -- 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_Arg_Order ((Name_Entity, Name_External_Name, Name_Link_Name)); Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (3); Id := Get_Pragma_Arg (Arg1); Analyze (Id); -- This is obsolete from Ada 95 on, but it is an implementation -- defined pragma, so we do not consider that it violates the -- restriction (No_Obsolescent_Features). if Ada_Version >= Ada_95 then if Warn_On_Obsolescent_Feature then Error_Msg_N ("pragma Interface_Name is an obsolescent feature?j?", N); Error_Msg_N ("|use pragma Import instead?j?", N); end if; end if; 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, Sure => False); -- 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 Pragma_Name (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, N); 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, N); Found := True; end if; exit when From_Aspect_Specification (N); 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; Ent : Entity_Id; begin Check_Ada_83_Warning; if Arg_Count /= 0 then Arg := Get_Pragma_Arg (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. Preanalyze_Spec_Expression (Arg, RTE (RE_Interrupt_Priority)); end if; if not Nkind_In (P, N_Task_Definition, N_Protected_Definition) then Pragma_Misplaced; return; else Ent := Defining_Identifier (Parent (P)); -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); -- Check the No_Task_At_Interrupt_Priority restriction if Nkind (P) = N_Task_Definition then Check_Restriction (No_Task_At_Interrupt_Priority, N); end if; 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_Order ((Name_Name, Name_State)); Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Name); Check_Optional_Identifier (Arg2, Name_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_OK_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 #", Arg2); exit; end if; IST_Num := IST_Num + 1; end loop; end Interrupt_State; --------------- -- Invariant -- --------------- -- pragma Invariant -- ([Entity =>] type_LOCAL_NAME, -- [Check =>] EXPRESSION -- [,[Message =>] String_Expression]); when Pragma_Invariant => Invariant : declare Discard : Boolean; Typ : Entity_Id; Typ_Arg : Node_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (3); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Check); if Arg_Count = 3 then Check_Optional_Identifier (Arg3, Name_Message); Check_Arg_Is_OK_Static_Expression (Arg3, Standard_String); end if; Check_Arg_Is_Local_Name (Arg1); Typ_Arg := Get_Pragma_Arg (Arg1); Find_Type (Typ_Arg); Typ := Entity (Typ_Arg); -- Nothing to do of the related type is erroneous in some way if Typ = Any_Type then return; -- AI12-0041: Invariants are allowed in interface types elsif Is_Interface (Typ) then null; -- An invariant must apply to a private type, or appear in the -- private part of a package spec and apply to a completion. -- a class-wide invariant can only appear on a private declaration -- or private extension, not a completion. -- A [class-wide] invariant may be associated a [limited] private -- type or a private extension. elsif Ekind_In (Typ, E_Limited_Private_Type, E_Private_Type, E_Record_Type_With_Private) then null; -- A non-class-wide invariant may be associated with the full view -- of a [limited] private type or a private extension. elsif Has_Private_Declaration (Typ) and then not Class_Present (N) then null; -- A class-wide invariant may appear on the partial view only elsif Class_Present (N) then Error_Pragma_Arg ("pragma % only allowed for private type", Arg1); return; -- A regular invariant may appear on both views else Error_Pragma_Arg ("pragma % only allowed for private type or corresponding " & "full view", Arg1); return; end if; -- An invariant associated with an abstract type (this includes -- interfaces) must be class-wide. if Is_Abstract_Type (Typ) and then not Class_Present (N) then Error_Pragma_Arg ("pragma % not allowed for abstract type", Arg1); return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- The pragma defines a type-specific invariant, the type is said -- to have invariants of its "own". Set_Has_Own_Invariants (Typ); -- If the invariant is class-wide, then it can be inherited by -- derived or interface implementing types. The type is said to -- have "inheritable" invariants. if Class_Present (N) then Set_Has_Inheritable_Invariants (Typ); end if; -- Chain the pragma on to the rep item chain, for processing when -- the type is frozen. Discard := Rep_Item_Too_Late (Typ, N, FOnly => True); -- Create the declaration of the invariant procedure that will -- verify the invariant at run time. Interfaces are treated as the -- partial view of a private type in order to achieve uniformity -- with the general case. As a result, an interface receives only -- a "partial" invariant procedure, which is never called. Build_Invariant_Procedure_Declaration (Typ => Typ, Partial_Invariant => Is_Interface (Typ)); end Invariant; ---------------- -- 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 := Get_Pragma_Arg (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 | UNRESTRICTED | GPL | MODIFIED_GPL); when Pragma_License => GNAT_Pragma; -- Do not analyze pragma any further in CodePeer mode, to avoid -- extraneous errors in this implementation-dependent pragma, -- which has a different profile on other compilers. if CodePeer_Mode then return; end if; 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_OK_Static_Expression (Arg1, Standard_String); Start_String; Arg := Arg1; while Present (Arg) loop Check_Arg_Is_OK_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). Arg_Store : declare C : constant Char_Code := Get_Char_Code (' '); S : constant String_Id := Strval (Expr_Value_S (Get_Pragma_Arg (Arg))); L : constant Nat := String_Length (S); F : Nat := 1; procedure Skip_Spaces; -- Advance F past any spaces ----------------- -- Skip_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; -- Start of processing for Arg_Store 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_Store; 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 -- [Target =>] static_string_EXPRESSION); when Pragma_Linker_Alias => GNAT_Pragma; Check_Arg_Order ((Name_Entity, Name_Target)); Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Target); Check_Arg_Is_Library_Level_Local_Name (Arg1); Check_Arg_Is_OK_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 (Get_Pragma_Arg (Arg1)), N) then return; else Set_Has_Gigi_Rep_Item (Entity (Get_Pragma_Arg (Arg1))); end if; ------------------------ -- Linker_Constructor -- ------------------------ -- pragma Linker_Constructor (procedure_LOCAL_NAME); -- Code is shared with Linker_Destructor ----------------------- -- Linker_Destructor -- ----------------------- -- pragma Linker_Destructor (procedure_LOCAL_NAME); when Pragma_Linker_Constructor | Pragma_Linker_Destructor => Linker_Constructor : declare Arg1_X : Node_Id; Proc : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Local_Name (Arg1); Arg1_X := Get_Pragma_Arg (Arg1); Analyze (Arg1_X); Proc := Find_Unique_Parameterless_Procedure (Arg1_X, Arg1); if not Is_Library_Level_Entity (Proc) then Error_Pragma_Arg ("argument for pragma% must be library level entity", Arg1); 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 (Proc, N) then return; else Set_Has_Gigi_Rep_Item (Proc); end if; end Linker_Constructor; -------------------- -- 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; Check_Arg_Is_OK_Static_Expression (Arg1, Standard_String); Start_String (Strval (Expr_Value_S (Get_Pragma_Arg (Arg1)))); Arg := Arg2; while Present (Arg) loop Check_Arg_Is_OK_Static_Expression (Arg, Standard_String); Store_String_Char (ASCII.NUL); Store_String_Chars (Strval (Expr_Value_S (Get_Pragma_Arg (Arg)))); Arg := Next (Arg); end loop; if Operating_Mode = Generate_Code and then In_Extended_Main_Source_Unit (N) then 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 => Linker_Section : declare Arg : Node_Id; Ent : Entity_Id; LPE : Node_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost subprograms is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost subprogram encountered while -- processing the arguments of the pragma. begin GNAT_Pragma; Check_Arg_Order ((Name_Entity, Name_Section)); 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_OK_Static_Expression (Arg2, Standard_String); -- Check kind of entity Arg := Get_Pragma_Arg (Arg1); Ent := Entity (Arg); case Ekind (Ent) is -- Objects (constants and variables) and types. For these cases -- all we need to do is to set the Linker_Section_pragma field, -- checking that we do not have a duplicate. when Type_Kind | E_Constant | E_Variable => LPE := Linker_Section_Pragma (Ent); if Present (LPE) then Error_Msg_Sloc := Sloc (LPE); Error_Msg_NE ("Linker_Section already specified for &#", Arg1, Ent); end if; Set_Linker_Section_Pragma (Ent, N); -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored -- Ghost code. Mark_Ghost_Pragma (N, Ent); -- Subprograms when Subprogram_Kind => -- Aspect case, entity already set if From_Aspect_Specification (N) then Set_Linker_Section_Pragma (Entity (Corresponding_Aspect (N)), N); -- Pragma case, we must climb the homonym chain, but skip -- any for which the linker section is already set. else loop if No (Linker_Section_Pragma (Ent)) then Set_Linker_Section_Pragma (Ent, N); -- A pragma that applies to a Ghost entity becomes -- Ghost for the purposes of legality checks and -- removal of ignored Ghost code. Mark_Ghost_Pragma (N, Ent); -- Capture the entity of the first Ghost subprogram -- being processed for error detection purposes. if Is_Ghost_Entity (Ent) then if No (Ghost_Id) then Ghost_Id := Ent; end if; -- Otherwise the subprogram is non-Ghost. It is -- illegal to mix references to Ghost and non-Ghost -- entities (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and " & "non-ghost subprograms", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (Ent); Error_Msg_NE ("\& # declared as non-ghost", N, Ent); end if; end if; Ent := Homonym (Ent); exit when No (Ent) or else Scope (Ent) /= Current_Scope; end loop; end if; -- All other cases are illegal when others => Error_Pragma_Arg ("pragma% applies only to objects, subprograms, and types", Arg1); end case; end Linker_Section; ---------- -- 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; --------------- -- Lock_Free -- --------------- -- pragma Lock_Free [(Boolean_EXPRESSION)]; when Pragma_Lock_Free => Lock_Free : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; Val : Boolean; begin Check_No_Identifiers; Check_At_Most_N_Arguments (1); -- Protected definition case if Nkind (P) = N_Protected_Definition then Ent := Defining_Identifier (Parent (P)); -- One argument if Arg_Count = 1 then Arg := Get_Pragma_Arg (Arg1); Val := Is_True (Static_Boolean (Arg)); -- No arguments (expression is considered to be True) else Val := True; end if; -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); Set_Uses_Lock_Free (Ent, Val); -- Anything else is incorrect placement else Pragma_Misplaced; end if; end Lock_Free; -------------------- -- Locking_Policy -- -------------------- -- pragma Locking_Policy (policy_IDENTIFIER); when Pragma_Locking_Policy => declare subtype LP_Range is Name_Id range First_Locking_Policy_Name .. Last_Locking_Policy_Name; LP_Val : LP_Range; LP : Character; begin Check_Ada_83_Warning; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Locking_Policy (Arg1); Check_Valid_Configuration_Pragma; LP_Val := Chars (Get_Pragma_Arg (Arg1)); case LP_Val is when Name_Ceiling_Locking => LP := 'C'; when Name_Concurrent_Readers_Locking => LP := 'R'; when Name_Inheritance_Locking => LP := 'I'; end case; 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; ------------------- -- Loop_Optimize -- ------------------- -- pragma Loop_Optimize ( OPTIMIZATION_HINT {, OPTIMIZATION_HINT } ); -- OPTIMIZATION_HINT ::= -- Ivdep | No_Unroll | Unroll | No_Vector | Vector when Pragma_Loop_Optimize => Loop_Optimize : declare Hint : Node_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_No_Identifiers; Hint := First (Pragma_Argument_Associations (N)); while Present (Hint) loop Check_Arg_Is_One_Of (Hint, Name_Ivdep, Name_No_Unroll, Name_Unroll, Name_No_Vector, Name_Vector); Next (Hint); end loop; Check_Loop_Pragma_Placement; end Loop_Optimize; ------------------ -- Loop_Variant -- ------------------ -- pragma Loop_Variant -- ( LOOP_VARIANT_ITEM {, LOOP_VARIANT_ITEM } ); -- LOOP_VARIANT_ITEM ::= CHANGE_DIRECTION => discrete_EXPRESSION -- CHANGE_DIRECTION ::= Increases | Decreases when Pragma_Loop_Variant => Loop_Variant : declare Variant : Node_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_Loop_Pragma_Placement; -- Process all increasing / decreasing expressions Variant := First (Pragma_Argument_Associations (N)); while Present (Variant) loop if Chars (Variant) = No_Name then Error_Pragma_Arg_Ident ("expect name `Increases`", Variant); elsif not Nam_In (Chars (Variant), Name_Decreases, Name_Increases) then declare Name : String := Get_Name_String (Chars (Variant)); begin -- It is a common mistake to write "Increasing" for -- "Increases" or "Decreasing" for "Decreases". Recognize -- specially names starting with "incr" or "decr" to -- suggest the corresponding name. System.Case_Util.To_Lower (Name); if Name'Length >= 4 and then Name (1 .. 4) = "incr" then Error_Pragma_Arg_Ident ("expect name `Increases`", Variant); elsif Name'Length >= 4 and then Name (1 .. 4) = "decr" then Error_Pragma_Arg_Ident ("expect name `Decreases`", Variant); else Error_Pragma_Arg_Ident ("expect name `Increases` or `Decreases`", Variant); end if; end; end if; Preanalyze_Assert_Expression (Expression (Variant), Any_Discrete); Next (Variant); end loop; end Loop_Variant; ----------------------- -- Machine_Attribute -- ----------------------- -- pragma Machine_Attribute ( -- [Entity =>] LOCAL_NAME, -- [Attribute_Name =>] static_string_EXPRESSION -- [, [Info =>] static_EXPRESSION] ); when Pragma_Machine_Attribute => Machine_Attribute : declare Def_Id : Entity_Id; begin GNAT_Pragma; Check_Arg_Order ((Name_Entity, Name_Attribute_Name, Name_Info)); if Arg_Count = 3 then Check_Optional_Identifier (Arg3, Name_Info); Check_Arg_Is_OK_Static_Expression (Arg3); else Check_Arg_Count (2); end if; Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Attribute_Name); Check_Arg_Is_Local_Name (Arg1); Check_Arg_Is_OK_Static_Expression (Arg2, Standard_String); Def_Id := Entity (Get_Pragma_Arg (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 (Get_Pragma_Arg (Arg1))); end if; end Machine_Attribute; ---------- -- Main -- ---------- -- pragma Main -- (MAIN_OPTION [, MAIN_OPTION]); -- MAIN_OPTION ::= -- [STACK_SIZE =>] static_integer_EXPRESSION -- | [TASK_STACK_SIZE_DEFAULT =>] static_integer_EXPRESSION -- | [TIME_SLICING_ENABLED =>] static_boolean_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_OK_Static_Expression (Args (J), Any_Integer); end if; end loop; if Present (Args (3)) then Check_Arg_Is_OK_Static_Expression (Args (3), Standard_Boolean); end if; Nod := Next (N); while Present (Nod) loop if Nkind (Nod) = N_Pragma and then Pragma_Name (Nod) = Name_Main then Error_Msg_Name_1 := Pname; 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_OK_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 Pragma_Name (Nod) = Name_Main_Storage then Error_Msg_Name_1 := Pname; Error_Msg_N ("duplicate pragma% not permitted", Nod); end if; Next (Nod); end loop; end Main_Storage; ---------------------- -- Max_Queue_Length -- ---------------------- -- pragma Max_Queue_Length (static_integer_EXPRESSION); -- This processing is shared by Pragma_Max_Entry_Queue_Depth when Pragma_Max_Queue_Length | Pragma_Max_Entry_Queue_Depth => Max_Queue_Length : declare Arg : Node_Id; Entry_Decl : Node_Id; Entry_Id : Entity_Id; Val : Uint; begin if Prag_Id = Pragma_Max_Queue_Length then GNAT_Pragma; end if; Check_Arg_Count (1); Entry_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); -- Entry declaration if Nkind (Entry_Decl) = N_Entry_Declaration then -- Entry illegally within a task if Nkind (Parent (N)) = N_Task_Definition then Error_Pragma ("pragma % cannot apply to task entries"); return; end if; Entry_Id := Defining_Entity (Entry_Decl); -- Otherwise the pragma is associated with an illegal construct else Error_Pragma ("pragma % must apply to a protected entry"); return; end if; -- Mark the pragma as Ghost if the related subprogram is also -- Ghost. This also ensures that any expansion performed further -- below will produce Ghost nodes. Mark_Ghost_Pragma (N, Entry_Id); -- Analyze the Integer expression Arg := Get_Pragma_Arg (Arg1); Check_Arg_Is_OK_Static_Expression (Arg, Any_Integer); Val := Expr_Value (Arg); if Val <= 0 then Error_Pragma_Arg ("argument for pragma% must be positive", Arg1); elsif not UI_Is_In_Int_Range (Val) then Error_Pragma_Arg ("argument for pragma% out of range of Integer", Arg1); end if; -- Manually substitute the expression value of the pragma argument -- if it's not an integer literal because this is not taken care -- of automatically elsewhere. if Nkind (Arg) /= N_Integer_Literal then Rewrite (Arg, Make_Integer_Literal (Sloc (Arg), Val)); Set_Etype (Arg, Etype (Original_Node (Arg))); end if; Record_Rep_Item (Entry_Id, N); end Max_Queue_Length; ----------------- -- 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_Body -- ------------- -- pragma No_Body; -- The only correct use of this pragma is on its own in a file, in -- which case it is specially processed (see Gnat1drv.Check_Bad_Body -- and Frontend, which use Sinput.L.Source_File_Is_Pragma_No_Body to -- check for a file containing nothing but a No_Body pragma). If we -- attempt to process it during normal semantics processing, it means -- it was misplaced. when Pragma_No_Body => GNAT_Pragma; Pragma_Misplaced; ----------------------------- -- No_Elaboration_Code_All -- ----------------------------- -- pragma No_Elaboration_Code_All; when Pragma_No_Elaboration_Code_All => GNAT_Pragma; Check_Valid_Library_Unit_Pragma; if Nkind (N) = N_Null_Statement then return; end if; -- Must appear for a spec or generic spec if not Nkind_In (Unit (Cunit (Current_Sem_Unit)), N_Generic_Package_Declaration, N_Generic_Subprogram_Declaration, N_Package_Declaration, N_Subprogram_Declaration) then Error_Pragma (Fix_Error ("pragma% can only occur for package " & "or subprogram spec")); end if; -- Set flag in unit table Set_No_Elab_Code_All (Current_Sem_Unit); -- Set restriction No_Elaboration_Code if this is the main unit if Current_Sem_Unit = Main_Unit then Set_Restriction (No_Elaboration_Code, N); end if; -- If we are in the main unit or in an extended main source unit, -- then we also add it to the configuration restrictions so that -- it will apply to all units in the extended main source. if Current_Sem_Unit = Main_Unit or else In_Extended_Main_Source_Unit (N) then Add_To_Config_Boolean_Restrictions (No_Elaboration_Code); end if; -- If in main extended unit, activate transitive with test if In_Extended_Main_Source_Unit (N) then Opt.No_Elab_Code_All_Pragma := N; end if; ----------------------------- -- No_Component_Reordering -- ----------------------------- -- pragma No_Component_Reordering [([Entity =>] type_LOCAL_NAME)]; when Pragma_No_Component_Reordering => No_Comp_Reordering : declare E : Entity_Id; E_Id : Node_Id; begin GNAT_Pragma; Check_At_Most_N_Arguments (1); if Arg_Count = 0 then Check_Valid_Configuration_Pragma; Opt.No_Component_Reordering := True; else Check_Optional_Identifier (Arg2, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (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 ("pragma% requires record type", Arg1); end if; Set_No_Reordering (Base_Type (E)); end if; end No_Comp_Reordering; -------------------------- -- No_Heap_Finalization -- -------------------------- -- pragma No_Heap_Finalization [ (first_subtype_LOCAL_NAME) ]; when Pragma_No_Heap_Finalization => No_Heap_Finalization : declare Context : constant Node_Id := Parent (N); Typ_Arg : constant Node_Id := Get_Pragma_Arg (Arg1); Prev : Node_Id; Typ : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; -- The pragma appears in a configuration file if No (Context) then Check_Arg_Count (0); Check_Valid_Configuration_Pragma; -- Detect a duplicate pragma if Present (No_Heap_Finalization_Pragma) then Duplication_Error (Prag => N, Prev => No_Heap_Finalization_Pragma); raise Pragma_Exit; end if; No_Heap_Finalization_Pragma := N; -- Otherwise the pragma should be associated with a library-level -- named access-to-object type. else Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Find_Type (Typ_Arg); Typ := Entity (Typ_Arg); -- The type being subjected to the pragma is erroneous if Typ = Any_Type then Error_Pragma ("cannot find type referenced by pragma %"); -- The pragma is applied to an incomplete or generic formal -- type way too early. elsif Rep_Item_Too_Early (Typ, N) then return; else Typ := Underlying_Type (Typ); end if; -- The pragma must apply to an access-to-object type if Ekind_In (Typ, E_Access_Type, E_General_Access_Type) then null; -- Give a detailed error message on all other access type kinds elsif Ekind (Typ) = E_Access_Protected_Subprogram_Type then Error_Pragma ("pragma % cannot apply to access protected subprogram " & "type"); elsif Ekind (Typ) = E_Access_Subprogram_Type then Error_Pragma ("pragma % cannot apply to access subprogram type"); elsif Is_Anonymous_Access_Type (Typ) then Error_Pragma ("pragma % cannot apply to anonymous access type"); -- Give a general error message in case the pragma applies to a -- non-access type. else Error_Pragma ("pragma % must apply to library level access type"); end if; -- At this point the argument denotes an access-to-object type. -- Ensure that the type is declared at the library level. if Is_Library_Level_Entity (Typ) then null; -- Quietly ignore an access-to-object type originally declared -- at the library level within a generic, but instantiated at -- a non-library level. As a result the access-to-object type -- "loses" its No_Heap_Finalization property. elsif In_Instance then raise Pragma_Exit; else Error_Pragma ("pragma % must apply to library level access type"); end if; -- Detect a duplicate pragma if Present (No_Heap_Finalization_Pragma) then Duplication_Error (Prag => N, Prev => No_Heap_Finalization_Pragma); raise Pragma_Exit; else Prev := Get_Pragma (Typ, Pragma_No_Heap_Finalization); if Present (Prev) then Duplication_Error (Prag => N, Prev => Prev); raise Pragma_Exit; end if; end if; Record_Rep_Item (Typ, N); end if; end No_Heap_Finalization; --------------- -- No_Inline -- --------------- -- pragma No_Inline ( NAME {, NAME} ); when Pragma_No_Inline => GNAT_Pragma; Process_Inline (Suppressed); --------------- -- No_Return -- --------------- -- pragma No_Return (procedure_LOCAL_NAME {, procedure_Local_Name}); when Pragma_No_Return => No_Return : declare Arg : Node_Id; E : Entity_Id; Found : Boolean; Id : Node_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost subprograms is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost procedure encountered while -- processing the arguments of the pragma. begin Ada_2005_Pragma; Check_At_Least_N_Arguments (1); -- Loop through arguments of pragma Arg := Arg1; while Present (Arg) loop Check_Arg_Is_Local_Name (Arg); Id := Get_Pragma_Arg (Arg); Analyze (Id); if not Is_Entity_Name (Id) then Error_Pragma_Arg ("entity name required", Arg); end if; if Etype (Id) = Any_Type then raise Pragma_Exit; end if; -- Loop to find matching procedures E := Entity (Id); Found := False; while Present (E) and then Scope (E) = Current_Scope loop if Ekind_In (E, E_Generic_Procedure, E_Procedure) then -- Check that the pragma is not applied to a body. -- First check the specless body case, to give a -- different error message. These checks do not apply -- if Relaxed_RM_Semantics, to accommodate other Ada -- compilers. Disable these checks under -gnatd.J. if not Debug_Flag_Dot_JJ then if Nkind (Parent (Declaration_Node (E))) = N_Subprogram_Body and then not Relaxed_RM_Semantics then Error_Pragma ("pragma% requires separate spec and must come " & "before body"); end if; -- Now the "specful" body case if Rep_Item_Too_Late (E, N) then raise Pragma_Exit; end if; end if; Set_No_Return (E); -- A pragma that applies to a Ghost entity becomes Ghost -- for the purposes of legality checks and removal of -- ignored Ghost code. Mark_Ghost_Pragma (N, E); -- Capture the entity of the first Ghost procedure being -- processed for error detection purposes. if Is_Ghost_Entity (E) then if No (Ghost_Id) then Ghost_Id := E; end if; -- Otherwise the subprogram is non-Ghost. It is illegal -- to mix references to Ghost and non-Ghost entities -- (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and non-ghost " & "procedures", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (E); Error_Msg_NE ("\& # declared as non-ghost", N, E); end if; -- Set flag on any alias as well if Is_Overloadable (E) and then Present (Alias (E)) then Set_No_Return (Alias (E)); end if; Found := True; end if; exit when From_Aspect_Specification (N); E := Homonym (E); end loop; -- If entity in not in current scope it may be the enclosing -- suprogram body to which the aspect applies. if not Found then if Entity (Id) = Current_Scope and then From_Aspect_Specification (N) then Set_No_Return (Entity (Id)); else Error_Pragma_Arg ("no procedure& found for pragma%", Arg); end if; end if; Next (Arg); end loop; end No_Return; ----------------- -- No_Run_Time -- ----------------- -- pragma No_Run_Time; -- Note: this pragma is retained for backwards compatibility. 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); -- Remove backward compatibility if Build_Type is FSF or GPL and -- generate a warning. declare Ignore : constant Boolean := Build_Type in FSF .. GPL; begin if Ignore then Error_Pragma ("pragma% is ignored, has no effect??"); else No_Run_Time_Mode := True; Configurable_Run_Time_Mode := True; -- Set Duration to 32 bits if word size is 32 if Ttypes.System_Word_Size = 32 then Duration_32_Bits_On_Target := True; end if; -- Set appropriate restrictions Set_Restriction (No_Finalization, N); Set_Restriction (No_Exception_Handlers, N); Set_Restriction (Max_Tasks, N, 0); Set_Restriction (No_Tasking, N); end if; end; ----------------------- -- No_Tagged_Streams -- ----------------------- -- pragma No_Tagged_Streams [([Entity => ]tagged_type_local_NAME)]; when Pragma_No_Tagged_Streams => No_Tagged_Strms : declare E : Entity_Id; E_Id : Node_Id; begin GNAT_Pragma; Check_At_Most_N_Arguments (1); -- One argument case if Arg_Count = 1 then Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); Check_Duplicate_Pragma (E); if not Is_Tagged_Type (E) or else Is_Derived_Type (E) then Error_Pragma_Arg ("argument for pragma% must be root tagged type", Arg1); end if; if Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N) then return; else Set_No_Tagged_Streams_Pragma (E, N); end if; -- Zero argument case else Check_Is_In_Decl_Part_Or_Package_Spec; No_Tagged_Streams := N; end if; end No_Tagged_Strms; ------------------------ -- No_Strict_Aliasing -- ------------------------ -- pragma No_Strict_Aliasing [([Entity =>] type_LOCAL_NAME)]; when Pragma_No_Strict_Aliasing => No_Strict_Aliasing : declare E : Entity_Id; E_Id : Node_Id; begin GNAT_Pragma; Check_At_Most_N_Arguments (1); if Arg_Count = 0 then Check_Valid_Configuration_Pragma; Opt.No_Strict_Aliasing := True; else Check_Optional_Identifier (Arg2, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); if not Is_Access_Type (E) then Error_Pragma_Arg ("pragma% requires access type", Arg1); end if; Set_No_Strict_Aliasing (Base_Type (E)); end if; end No_Strict_Aliasing; ----------------------- -- Normalize_Scalars -- ----------------------- -- pragma Normalize_Scalars; when Pragma_Normalize_Scalars => Check_Ada_83_Warning; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; -- Normalize_Scalars creates false positives in CodePeer, and -- incorrect negative results in GNATprove mode, so ignore this -- pragma in these modes. if not (CodePeer_Mode or GNATprove_Mode) then Normalize_Scalars := True; Init_Or_Norm_Scalars := True; end if; ----------------- -- Obsolescent -- ----------------- -- pragma Obsolescent; -- pragma Obsolescent ( -- [Message =>] static_string_EXPRESSION -- [,[Version =>] Ada_05]]); -- pragma Obsolescent ( -- [Entity =>] NAME -- [,[Message =>] static_string_EXPRESSION -- [,[Version =>] Ada_05]] ); when Pragma_Obsolescent => Obsolescent : declare Decl : Node_Id; Ename : Node_Id; procedure Set_Obsolescent (E : Entity_Id); -- Given an entity Ent, mark it as obsolescent if appropriate --------------------- -- Set_Obsolescent -- --------------------- procedure Set_Obsolescent (E : Entity_Id) is Active : Boolean; Ent : Entity_Id; S : String_Id; begin Active := True; Ent := E; -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. Mark_Ghost_Pragma (N, E); -- Entity name was given if Present (Ename) then -- If entity name matches, we are fine. Save entity in -- pragma argument, for ASIS use. if Chars (Ename) = Chars (Ent) then Set_Entity (Ename, Ent); Generate_Reference (Ent, Ename); -- If entity name does not match, only possibility is an -- enumeration literal from an enumeration type declaration. elsif Ekind (Ent) /= E_Enumeration_Type then Error_Pragma ("pragma % entity name does not match declaration"); else Ent := First_Literal (E); loop if No (Ent) then Error_Pragma ("pragma % entity name does not match any " & "enumeration literal"); elsif Chars (Ent) = Chars (Ename) then Set_Entity (Ename, Ent); Generate_Reference (Ent, Ename); exit; else Ent := Next_Literal (Ent); end if; end loop; end if; end if; -- Ent points to entity to be marked if Arg_Count >= 1 then -- Deal with static string argument Check_Arg_Is_OK_Static_Expression (Arg1, Standard_String); S := Strval (Get_Pragma_Arg (Arg1)); for J in 1 .. String_Length (S) loop if not In_Character_Range (Get_String_Char (S, J)) then Error_Pragma_Arg ("pragma% argument does not allow wide characters", Arg1); end if; end loop; Obsolescent_Warnings.Append ((Ent => Ent, Msg => Strval (Get_Pragma_Arg (Arg1)))); -- Check for Ada_05 parameter if Arg_Count /= 1 then Check_Arg_Count (2); declare Argx : constant Node_Id := Get_Pragma_Arg (Arg2); begin Check_Arg_Is_Identifier (Argx); if Chars (Argx) /= Name_Ada_05 then Error_Msg_Name_2 := Name_Ada_05; Error_Pragma_Arg ("only allowed argument for pragma% is %", Argx); end if; if Ada_Version_Explicit < Ada_2005 or else not Warn_On_Ada_2005_Compatibility then Active := False; end if; end; end if; end if; -- Set flag if pragma active if Active then Set_Is_Obsolescent (Ent); end if; return; end Set_Obsolescent; -- Start of processing for pragma Obsolescent begin GNAT_Pragma; Check_At_Most_N_Arguments (3); -- See if first argument specifies an entity name if Arg_Count >= 1 and then (Chars (Arg1) = Name_Entity or else Nkind_In (Get_Pragma_Arg (Arg1), N_Character_Literal, N_Identifier, N_Operator_Symbol)) then Ename := Get_Pragma_Arg (Arg1); -- Eliminate first argument, so we can share processing Arg1 := Arg2; Arg2 := Arg3; Arg_Count := Arg_Count - 1; -- No Entity name argument given else Ename := Empty; end if; if Arg_Count >= 1 then Check_Optional_Identifier (Arg1, Name_Message); if Arg_Count = 2 then Check_Optional_Identifier (Arg2, Name_Version); end if; end if; -- Get immediately preceding declaration Decl := Prev (N); while Present (Decl) and then Nkind (Decl) = N_Pragma loop Prev (Decl); end loop; -- Cases where we do not follow anything other than another pragma if No (Decl) then -- First case: library level compilation unit declaration with -- the pragma immediately following the declaration. if Nkind (Parent (N)) = N_Compilation_Unit_Aux then Set_Obsolescent (Defining_Entity (Unit (Parent (Parent (N))))); return; -- Case 2: library unit placement for package else declare Ent : constant Entity_Id := Find_Lib_Unit_Name; begin if Is_Package_Or_Generic_Package (Ent) then Set_Obsolescent (Ent); return; end if; end; end if; -- Cases where we must follow a declaration, including an -- abstract subprogram declaration, which is not in the -- other node subtypes. else if Nkind (Decl) not in N_Declaration and then Nkind (Decl) not in N_Later_Decl_Item and then Nkind (Decl) not in N_Generic_Declaration and then Nkind (Decl) not in N_Renaming_Declaration and then Nkind (Decl) /= N_Abstract_Subprogram_Declaration then Error_Pragma ("pragma% misplaced, " & "must immediately follow a declaration"); else Set_Obsolescent (Defining_Entity (Decl)); return; end if; end if; end Obsolescent; -------------- -- Optimize -- -------------- -- pragma Optimize (Time | Space | Off); -- 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); ------------------------ -- Optimize_Alignment -- ------------------------ -- pragma Optimize_Alignment (Time | Space | Off); when Pragma_Optimize_Alignment => Optimize_Alignment : begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Valid_Configuration_Pragma; declare Nam : constant Name_Id := Chars (Get_Pragma_Arg (Arg1)); begin case Nam is when Name_Off => Opt.Optimize_Alignment := 'O'; when Name_Space => Opt.Optimize_Alignment := 'S'; when Name_Time => Opt.Optimize_Alignment := 'T'; when others => Error_Pragma_Arg ("invalid argument for pragma%", Arg1); end case; end; -- Set indication that mode is set locally. If we are in fact in a -- configuration pragma file, this setting is harmless since the -- switch will get reset anyway at the start of each unit. Optimize_Alignment_Local := True; end Optimize_Alignment; ------------- -- Ordered -- ------------- -- pragma Ordered (first_enumeration_subtype_LOCAL_NAME); when Pragma_Ordered => Ordered : declare Assoc : constant Node_Id := Arg1; Type_Id : Node_Id; Typ : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Type_Id := Get_Pragma_Arg (Assoc); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type then return; else Typ := Underlying_Type (Typ); end if; if not Is_Enumeration_Type (Typ) then Error_Pragma ("pragma% must specify enumeration type"); end if; Check_First_Subtype (Arg1); Set_Has_Pragma_Ordered (Base_Type (Typ)); end Ordered; ------------------- -- Overflow_Mode -- ------------------- -- pragma Overflow_Mode -- ([General => ] MODE [, [Assertions => ] MODE]); -- MODE := STRICT | MINIMIZED | ELIMINATED -- Note: ELIMINATED is allowed only if Long_Long_Integer'Size is 64 -- since System.Bignums makes this assumption. This is true of nearly -- all (all?) targets. when Pragma_Overflow_Mode => Overflow_Mode : declare function Get_Overflow_Mode (Name : Name_Id; Arg : Node_Id) return Overflow_Mode_Type; -- Function to process one pragma argument, Arg. If an identifier -- is present, it must be Name. Mode type is returned if a valid -- argument exists, otherwise an error is signalled. ----------------------- -- Get_Overflow_Mode -- ----------------------- function Get_Overflow_Mode (Name : Name_Id; Arg : Node_Id) return Overflow_Mode_Type is Argx : constant Node_Id := Get_Pragma_Arg (Arg); begin Check_Optional_Identifier (Arg, Name); Check_Arg_Is_Identifier (Argx); if Chars (Argx) = Name_Strict then return Strict; elsif Chars (Argx) = Name_Minimized then return Minimized; elsif Chars (Argx) = Name_Eliminated then if Ttypes.Standard_Long_Long_Integer_Size /= 64 then Error_Pragma_Arg ("Eliminated not implemented on this target", Argx); else return Eliminated; end if; else Error_Pragma_Arg ("invalid argument for pragma%", Argx); end if; end Get_Overflow_Mode; -- Start of processing for Overflow_Mode begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Check_At_Most_N_Arguments (2); -- Process first argument Scope_Suppress.Overflow_Mode_General := Get_Overflow_Mode (Name_General, Arg1); -- Case of only one argument if Arg_Count = 1 then Scope_Suppress.Overflow_Mode_Assertions := Scope_Suppress.Overflow_Mode_General; -- Case of two arguments present else Scope_Suppress.Overflow_Mode_Assertions := Get_Overflow_Mode (Name_Assertions, Arg2); end if; end Overflow_Mode; -------------------------- -- Overriding Renamings -- -------------------------- -- pragma Overriding_Renamings; when Pragma_Overriding_Renamings => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Overriding_Renamings := True; ---------- -- Pack -- ---------- -- pragma Pack (first_subtype_LOCAL_NAME); when Pragma_Pack => Pack : declare Assoc : constant Node_Id := Arg1; Ctyp : Entity_Id; Ignore : Boolean := False; Typ : Entity_Id; Type_Id : Node_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Type_Id := Get_Pragma_Arg (Assoc); if not Is_Entity_Name (Type_Id) or else not Is_Type (Entity (Type_Id)) then Error_Pragma_Arg ("argument for pragma% must be type or subtype", Arg1); end if; 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; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); 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); Check_Duplicate_Pragma (Typ); -- Array type if Is_Array_Type (Typ) then Ctyp := Component_Type (Typ); -- Ignore pack that does nothing if Known_Static_Esize (Ctyp) and then Known_Static_RM_Size (Ctyp) and then Esize (Ctyp) = RM_Size (Ctyp) and then Addressable (Esize (Ctyp)) then Ignore := True; end if; -- Process OK pragma Pack. Note that if there is a separate -- component clause present, the Pack will be cancelled. This -- processing is in Freeze. if not Rep_Item_Too_Late (Typ, N) then -- In CodePeer mode, we do not need complex front-end -- expansions related to pragma Pack, so disable handling -- of pragma Pack. if CodePeer_Mode then null; -- Normal case where we do the pack action else if not Ignore then Set_Is_Packed (Base_Type (Typ)); Set_Has_Non_Standard_Rep (Base_Type (Typ)); end if; Set_Has_Pragma_Pack (Base_Type (Typ)); end if; end if; -- 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_Is_Packed (Base_Type (Typ)); Set_Has_Pragma_Pack (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; ------------- -- Part_Of -- ------------- -- pragma Part_Of (ABSTRACT_STATE); -- ABSTRACT_STATE ::= NAME when Pragma_Part_Of => Part_Of : declare procedure Propagate_Part_Of (Pack_Id : Entity_Id; State_Id : Entity_Id; Instance : Node_Id); -- Propagate the Part_Of indicator to all abstract states and -- objects declared in the visible state space of a package -- denoted by Pack_Id. State_Id is the encapsulating state. -- Instance is the package instantiation node. ----------------------- -- Propagate_Part_Of -- ----------------------- procedure Propagate_Part_Of (Pack_Id : Entity_Id; State_Id : Entity_Id; Instance : Node_Id) is Has_Item : Boolean := False; -- Flag set when the visible state space contains at least one -- abstract state or variable. procedure Propagate_Part_Of (Pack_Id : Entity_Id); -- Propagate the Part_Of indicator to all abstract states and -- objects declared in the visible state space of a package -- denoted by Pack_Id. ----------------------- -- Propagate_Part_Of -- ----------------------- procedure Propagate_Part_Of (Pack_Id : Entity_Id) is Constits : Elist_Id; Item_Id : Entity_Id; begin -- Traverse the entity chain of the package and set relevant -- attributes of abstract states and objects declared in the -- visible state space of the package. Item_Id := First_Entity (Pack_Id); while Present (Item_Id) and then not In_Private_Part (Item_Id) loop -- Do not consider internally generated items if not Comes_From_Source (Item_Id) then null; -- Do not consider generic formals or their corresponding -- actuals because they are not part of a visible state. -- Note that both entities are marked as hidden. elsif Is_Hidden (Item_Id) then null; -- The Part_Of indicator turns an abstract state or an -- object into a constituent of the encapsulating state. -- Note that constants are considered here even though -- they may not depend on variable input. This check is -- left to the SPARK prover. elsif Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Variable) then Has_Item := True; Constits := Part_Of_Constituents (State_Id); if No (Constits) then Constits := New_Elmt_List; Set_Part_Of_Constituents (State_Id, Constits); end if; Append_Elmt (Item_Id, Constits); Set_Encapsulating_State (Item_Id, State_Id); -- Recursively handle nested packages and instantiations elsif Ekind (Item_Id) = E_Package then Propagate_Part_Of (Item_Id); end if; Next_Entity (Item_Id); end loop; end Propagate_Part_Of; -- Start of processing for Propagate_Part_Of begin Propagate_Part_Of (Pack_Id); -- Detect a package instantiation that is subject to a Part_Of -- indicator, but has no visible state. if not Has_Item then SPARK_Msg_NE ("package instantiation & has Part_Of indicator but " & "lacks visible state", Instance, Pack_Id); end if; end Propagate_Part_Of; -- Local variables Constits : Elist_Id; Encap : Node_Id; Encap_Id : Entity_Id; Item_Id : Entity_Id; Legal : Boolean; Stmt : Node_Id; -- Start of processing for Part_Of begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Stmt := Find_Related_Context (N, Do_Checks => True); -- Object declaration if Nkind (Stmt) = N_Object_Declaration then null; -- Package instantiation elsif Nkind (Stmt) = N_Package_Instantiation then null; -- Single concurrent type declaration elsif Is_Single_Concurrent_Type_Declaration (Stmt) then null; -- Otherwise the pragma is associated with an illegal construct else Pragma_Misplaced; return; end if; -- Extract the entity of the related object declaration or package -- instantiation. In the case of the instantiation, use the entity -- of the instance spec. if Nkind (Stmt) = N_Package_Instantiation then Stmt := Instance_Spec (Stmt); end if; Item_Id := Defining_Entity (Stmt); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Item_Id); -- Chain the pragma on the contract for further processing by -- Analyze_Part_Of_In_Decl_Part or for completeness. Add_Contract_Item (N, Item_Id); -- A variable may act as constituent of a single concurrent type -- which in turn could be declared after the variable. Due to this -- discrepancy, the full analysis of indicator Part_Of is delayed -- until the end of the enclosing declarative region (see routine -- Analyze_Part_Of_In_Decl_Part). if Ekind (Item_Id) = E_Variable then null; -- Otherwise indicator Part_Of applies to a constant or a package -- instantiation. else Encap := Get_Pragma_Arg (Arg1); -- Detect any discrepancies between the placement of the -- constant or package instantiation with respect to state -- space and the encapsulating state. Analyze_Part_Of (Indic => N, Item_Id => Item_Id, Encap => Encap, Encap_Id => Encap_Id, Legal => Legal); if Legal then pragma Assert (Present (Encap_Id)); if Ekind (Item_Id) = E_Constant then Constits := Part_Of_Constituents (Encap_Id); if No (Constits) then Constits := New_Elmt_List; Set_Part_Of_Constituents (Encap_Id, Constits); end if; Append_Elmt (Item_Id, Constits); Set_Encapsulating_State (Item_Id, Encap_Id); -- Propagate the Part_Of indicator to the visible state -- space of the package instantiation. else Propagate_Part_Of (Pack_Id => Item_Id, State_Id => Encap_Id, Instance => Stmt); end if; end if; end if; end Part_Of; ---------------------------------- -- Partition_Elaboration_Policy -- ---------------------------------- -- pragma Partition_Elaboration_Policy (policy_IDENTIFIER); when Pragma_Partition_Elaboration_Policy => PEP : declare subtype PEP_Range is Name_Id range First_Partition_Elaboration_Policy_Name .. Last_Partition_Elaboration_Policy_Name; PEP_Val : PEP_Range; PEP : Character; begin Ada_2005_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Partition_Elaboration_Policy (Arg1); Check_Valid_Configuration_Pragma; PEP_Val := Chars (Get_Pragma_Arg (Arg1)); case PEP_Val is when Name_Concurrent => PEP := 'C'; when Name_Sequential => PEP := 'S'; end case; if Partition_Elaboration_Policy /= ' ' and then Partition_Elaboration_Policy /= PEP then Error_Msg_Sloc := Partition_Elaboration_Policy_Sloc; Error_Pragma ("partition elaboration policy incompatible with policy#"); -- Set new policy, but always preserve System_Location since we -- like the error message with the run time name. else Partition_Elaboration_Policy := PEP; if Partition_Elaboration_Policy_Sloc /= System_Location then Partition_Elaboration_Policy_Sloc := Loc; end if; end if; end PEP; ------------- -- 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; ---------------------------------- -- Preelaborable_Initialization -- ---------------------------------- -- pragma Preelaborable_Initialization (DIRECT_NAME); when Pragma_Preelaborable_Initialization => Preelab_Init : declare Ent : Entity_Id; begin Ada_2005_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_Identifier (Arg1); Check_Arg_Is_Local_Name (Arg1); Check_First_Subtype (Arg1); Ent := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Ent); -- The pragma may come from an aspect on a private declaration, -- even if the freeze point at which this is analyzed in the -- private part after the full view. if Has_Private_Declaration (Ent) and then From_Aspect_Specification (N) then null; -- Check appropriate type argument elsif Is_Private_Type (Ent) or else Is_Protected_Type (Ent) or else (Is_Generic_Type (Ent) and then Is_Derived_Type (Ent)) -- AI05-0028: The pragma applies to all composite types. Note -- that we apply this binding interpretation to earlier versions -- of Ada, so there is no Ada 2012 guard. Seems a reasonable -- choice since there are other compilers that do the same. or else Is_Composite_Type (Ent) then null; else Error_Pragma_Arg ("pragma % can only be applied to private, formal derived, " & "protected, or composite type", Arg1); end if; -- Give an error if the pragma is applied to a protected type that -- does not qualify (due to having entries, or due to components -- that do not qualify). if Is_Protected_Type (Ent) and then not Has_Preelaborable_Initialization (Ent) then Error_Msg_N ("protected type & does not have preelaborable " & "initialization", Ent); -- Otherwise mark the type as definitely having preelaborable -- initialization. else Set_Known_To_Have_Preelab_Init (Ent); end if; if Has_Pragma_Preelab_Init (Ent) and then Warn_On_Redundant_Constructs then Error_Pragma ("?r?duplicate pragma%!"); else Set_Has_Pragma_Preelab_Init (Ent); end if; end Preelab_Init; -------------------- -- Persistent_BSS -- -------------------- -- pragma Persistent_BSS [(object_NAME)]; when Pragma_Persistent_BSS => Persistent_BSS : declare Decl : Node_Id; Ent : Entity_Id; Prag : Node_Id; begin GNAT_Pragma; Check_At_Most_N_Arguments (1); -- Case of application to specific object (one argument) if Arg_Count = 1 then Check_Arg_Is_Library_Level_Local_Name (Arg1); if not Is_Entity_Name (Get_Pragma_Arg (Arg1)) or else not Ekind_In (Entity (Get_Pragma_Arg (Arg1)), E_Variable, E_Constant) then Error_Pragma_Arg ("pragma% only applies to objects", Arg1); end if; Ent := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for -- the purposes of legality checks and removal of ignored Ghost -- code. Mark_Ghost_Pragma (N, Ent); -- Check for duplication before inserting in list of -- representation items. Check_Duplicate_Pragma (Ent); if Rep_Item_Too_Late (Ent, N) then return; end if; Decl := Parent (Ent); if Present (Expression (Decl)) then Error_Pragma_Arg ("object for pragma% cannot have initialization", Arg1); end if; if not Is_Potentially_Persistent_Type (Etype (Ent)) then Error_Pragma_Arg ("object type for pragma% is not potentially persistent", Arg1); end if; Prag := Make_Linker_Section_Pragma (Ent, Sloc (N), ".persistent.bss"); Insert_After (N, Prag); Analyze (Prag); -- Case of use as configuration pragma with no arguments else Check_Valid_Configuration_Pragma; Persistent_BSS_Mode := True; end if; end Persistent_BSS; -------------------- -- Rename_Pragma -- -------------------- -- pragma Rename_Pragma ( -- [New_Name =>] IDENTIFIER, -- [Renamed =>] pragma_IDENTIFIER); when Pragma_Rename_Pragma => Rename_Pragma : declare New_Name : constant Node_Id := Get_Pragma_Arg (Arg1); Old_Name : constant Node_Id := Get_Pragma_Arg (Arg2); begin GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_New_Name); Check_Optional_Identifier (Arg2, Name_Renamed); if Nkind (New_Name) /= N_Identifier then Error_Pragma_Arg ("identifier expected", Arg1); end if; if Nkind (Old_Name) /= N_Identifier then Error_Pragma_Arg ("identifier expected", Arg2); end if; -- The New_Name arg should not be an existing pragma (but we allow -- it; it's just a warning). The Old_Name arg must be an existing -- pragma. if Is_Pragma_Name (Chars (New_Name)) then Error_Pragma_Arg ("??pragma is already defined", Arg1); end if; if not Is_Pragma_Name (Chars (Old_Name)) then Error_Pragma_Arg ("existing pragma name expected", Arg1); end if; Map_Pragma_Name (From => Chars (New_Name), To => Chars (Old_Name)); end Rename_Pragma; ------------- -- 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 (Get_Pragma_Arg (Arg1)) = Name_On); ----------------------------------- -- Post/Post_Class/Postcondition -- ----------------------------------- -- pragma Post (Boolean_EXPRESSION); -- pragma Post_Class (Boolean_EXPRESSION); -- pragma Postcondition ([Check =>] Boolean_EXPRESSION -- [,[Message =>] String_EXPRESSION]); -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expression in: -- Analyze_Pre_Post_Condition_In_Decl_Part -- * Expansion - The annotation is expanded during the expansion of -- the related subprogram [body] contract as performed in: -- Expand_Subprogram_Contract -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Post | Pragma_Post_Class | Pragma_Postcondition => Analyze_Pre_Post_Condition; -------------------------------- -- Pre/Pre_Class/Precondition -- -------------------------------- -- pragma Pre (Boolean_EXPRESSION); -- pragma Pre_Class (Boolean_EXPRESSION); -- pragma Precondition ([Check =>] Boolean_EXPRESSION -- [,[Message =>] String_EXPRESSION]); -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expression in: -- Analyze_Pre_Post_Condition_In_Decl_Part -- * Expansion - The annotation is expanded during the expansion of -- the related subprogram [body] contract as performed in: -- Expand_Subprogram_Contract -- * Template - The annotation utilizes the generic template of the -- related subprogram [body] when it is: -- aspect on subprogram declaration -- aspect on stand-alone subprogram body -- pragma on stand-alone subprogram body -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram [body] is instantiated except for -- the "pragma on subprogram declaration" case. In that scenario -- the annotation must instantiate itself. when Pragma_Pre | Pragma_Pre_Class | Pragma_Precondition => Analyze_Pre_Post_Condition; --------------- -- Predicate -- --------------- -- pragma Predicate -- ([Entity =>] type_LOCAL_NAME, -- [Check =>] boolean_EXPRESSION); when Pragma_Predicate => Predicate : declare Discard : Boolean; Typ : Entity_Id; Type_Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Check); Check_Arg_Is_Local_Name (Arg1); Type_Id := Get_Pragma_Arg (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type then return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- The remaining processing is simply to link the pragma on to -- the rep item chain, for processing when the type is frozen. -- This is accomplished by a call to Rep_Item_Too_Late. We also -- mark the type as having predicates. -- If the current policy for predicate checking is Ignore mark the -- subtype accordingly. In the case of predicates we consider them -- enabled unless Ignore is specified (either directly or with a -- general Assertion_Policy pragma) to preserve existing warnings. Set_Has_Predicates (Typ); -- Indicate that the pragma must be processed at the point the -- type is frozen, as is done for the corresponding aspect. Set_Has_Delayed_Aspects (Typ); Set_Has_Delayed_Freeze (Typ); Set_Predicates_Ignored (Typ, Present (Check_Policy_List) and then Policy_In_Effect (Name_Dynamic_Predicate) = Name_Ignore); Discard := Rep_Item_Too_Late (Typ, N, FOnly => True); end Predicate; ----------------------- -- Predicate_Failure -- ----------------------- -- pragma Predicate_Failure -- ([Entity =>] type_LOCAL_NAME, -- [Message =>] string_EXPRESSION); when Pragma_Predicate_Failure => Predicate_Failure : declare Discard : Boolean; Typ : Entity_Id; Type_Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (2); Check_Optional_Identifier (Arg1, Name_Entity); Check_Optional_Identifier (Arg2, Name_Message); Check_Arg_Is_Local_Name (Arg1); Type_Id := Get_Pragma_Arg (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type then return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- The remaining processing is simply to link the pragma on to -- the rep item chain, for processing when the type is frozen. -- This is accomplished by a call to Rep_Item_Too_Late. Discard := Rep_Item_Too_Late (Typ, N, FOnly => True); end Predicate_Failure; ------------------ -- 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; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Ent); Check_Duplicate_Pragma (Ent); -- This filters out pragmas inside generic parents that show up -- inside instantiations. Pragmas that come from aspects in the -- unit are not ignored. if Present (Ent) then if Pk = N_Package_Specification and then Present (Generic_Parent (Pa)) and then not From_Aspect_Specification (N) then null; else if not Debug_Flag_U then Set_Is_Preelaborated (Ent); if Legacy_Elaboration_Checks then Set_Suppress_Elaboration_Warnings (Ent); end if; end if; end if; end if; end Preelaborate; ------------------------------- -- Prefix_Exception_Messages -- ------------------------------- -- pragma Prefix_Exception_Messages; when Pragma_Prefix_Exception_Messages => GNAT_Pragma; Check_Valid_Configuration_Pragma; Check_Arg_Count (0); Prefix_Exception_Messages := True; -------------- -- Priority -- -------------- -- pragma Priority (EXPRESSION); when Pragma_Priority => Priority : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin Check_No_Identifiers; Check_Arg_Count (1); -- Subprogram case if Nkind (P) = N_Subprogram_Body then Check_In_Main_Program; Ent := Defining_Unit_Name (Specification (P)); if Nkind (Ent) = N_Defining_Program_Unit_Name then Ent := Defining_Identifier (Ent); end if; Arg := Get_Pragma_Arg (Arg1); Analyze_And_Resolve (Arg, Standard_Integer); -- Must be static if not Is_OK_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 except if Relaxed_RM_Semantics -- where we ignore the value if out of range. else if not Relaxed_RM_Semantics and then not Is_In_Range (Arg, RTE (RE_Priority)) then Error_Pragma_Arg ("main subprogram priority is out of range", Arg1); else Set_Main_Priority (Current_Sem_Unit, UI_To_Int (Expr_Value (Arg))); end if; end if; -- Load an arbitrary entity from System.Tasking.Stages or -- System.Tasking.Restricted.Stages (depending on the -- supported profile) to make sure that one of these packages -- is implicitly with'ed, since we need to have the tasking -- run time active for the pragma Priority to have any effect. -- Previously we with'ed the package System.Tasking, but this -- package does not trigger the required initialization of the -- run-time library. declare Discard : Entity_Id; pragma Warnings (Off, Discard); begin if Restricted_Profile then Discard := RTE (RE_Activate_Restricted_Tasks); else Discard := RTE (RE_Activate_Tasks); end if; end; -- Task or Protected, must be of type Integer elsif Nkind_In (P, N_Protected_Definition, N_Task_Definition) then Arg := Get_Pragma_Arg (Arg1); Ent := Defining_Identifier (Parent (P)); -- The expression must be analyzed in the special manner -- described in "Handling of Default and Per-Object -- Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, RTE (RE_Any_Priority)); if not Is_OK_Static_Expression (Arg) then Check_Restriction (Static_Priorities, Arg); end if; -- Anything else is incorrect else Pragma_Misplaced; end if; -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); end Priority; ----------------------------------- -- Priority_Specific_Dispatching -- ----------------------------------- -- pragma Priority_Specific_Dispatching ( -- policy_IDENTIFIER, -- first_priority_EXPRESSION, -- last_priority_EXPRESSION); when Pragma_Priority_Specific_Dispatching => Priority_Specific_Dispatching : declare Prio_Id : constant Entity_Id := RTE (RE_Any_Priority); -- This is the entity System.Any_Priority; DP : Character; Lower_Bound : Node_Id; Upper_Bound : Node_Id; Lower_Val : Uint; Upper_Val : Uint; begin Ada_2005_Pragma; Check_Arg_Count (3); Check_No_Identifiers; Check_Arg_Is_Task_Dispatching_Policy (Arg1); Check_Valid_Configuration_Pragma; Get_Name_String (Chars (Get_Pragma_Arg (Arg1))); DP := Fold_Upper (Name_Buffer (1)); Lower_Bound := Get_Pragma_Arg (Arg2); Check_Arg_Is_OK_Static_Expression (Lower_Bound, Standard_Integer); Lower_Val := Expr_Value (Lower_Bound); Upper_Bound := Get_Pragma_Arg (Arg3); Check_Arg_Is_OK_Static_Expression (Upper_Bound, Standard_Integer); Upper_Val := Expr_Value (Upper_Bound); -- It is not allowed to use Task_Dispatching_Policy and -- Priority_Specific_Dispatching in the same partition. if Task_Dispatching_Policy /= ' ' then Error_Msg_Sloc := Task_Dispatching_Policy_Sloc; Error_Pragma ("pragma% incompatible with Task_Dispatching_Policy#"); -- Check lower bound in range elsif Lower_Val < Expr_Value (Type_Low_Bound (Prio_Id)) or else Lower_Val > Expr_Value (Type_High_Bound (Prio_Id)) then Error_Pragma_Arg ("first_priority is out of range", Arg2); -- Check upper bound in range elsif Upper_Val < Expr_Value (Type_Low_Bound (Prio_Id)) or else Upper_Val > Expr_Value (Type_High_Bound (Prio_Id)) then Error_Pragma_Arg ("last_priority is out of range", Arg3); -- Check that the priority range is valid elsif Lower_Val > Upper_Val then Error_Pragma ("last_priority_expression must be greater than or equal to " & "first_priority_expression"); -- Store the new policy, but always preserve System_Location since -- we like the error message with the run-time name. else -- Check overlapping in the priority ranges specified in other -- Priority_Specific_Dispatching pragmas within the same -- partition. We can only check those we know about. for J in Specific_Dispatching.First .. Specific_Dispatching.Last loop if Specific_Dispatching.Table (J).First_Priority in UI_To_Int (Lower_Val) .. UI_To_Int (Upper_Val) or else Specific_Dispatching.Table (J).Last_Priority in UI_To_Int (Lower_Val) .. UI_To_Int (Upper_Val) then Error_Msg_Sloc := Specific_Dispatching.Table (J).Pragma_Loc; Error_Pragma ("priority range overlaps with " & "Priority_Specific_Dispatching#"); end if; end loop; -- The use of Priority_Specific_Dispatching is incompatible -- with Task_Dispatching_Policy. if Task_Dispatching_Policy /= ' ' then Error_Msg_Sloc := Task_Dispatching_Policy_Sloc; Error_Pragma ("Priority_Specific_Dispatching incompatible " & "with Task_Dispatching_Policy#"); end if; -- The use of Priority_Specific_Dispatching forces ceiling -- locking policy. if Locking_Policy /= ' ' and then Locking_Policy /= 'C' then Error_Msg_Sloc := Locking_Policy_Sloc; Error_Pragma ("Priority_Specific_Dispatching incompatible " & "with Locking_Policy#"); -- Set the Ceiling_Locking policy, but preserve System_Location -- since we like the error message with the run time name. else Locking_Policy := 'C'; if Locking_Policy_Sloc /= System_Location then Locking_Policy_Sloc := Loc; end if; end if; -- Add entry in the table Specific_Dispatching.Append ((Dispatching_Policy => DP, First_Priority => UI_To_Int (Lower_Val), Last_Priority => UI_To_Int (Upper_Val), Pragma_Loc => Loc)); end if; end Priority_Specific_Dispatching; ------------- -- Profile -- ------------- -- pragma Profile (profile_IDENTIFIER); -- profile_IDENTIFIER => Restricted | Ravenscar | Rational when Pragma_Profile => Ada_2005_Pragma; Check_Arg_Count (1); Check_Valid_Configuration_Pragma; Check_No_Identifiers; declare Argx : constant Node_Id := Get_Pragma_Arg (Arg1); begin if Chars (Argx) = Name_Ravenscar then Set_Ravenscar_Profile (Ravenscar, N); elsif Chars (Argx) = Name_Gnat_Extended_Ravenscar then Set_Ravenscar_Profile (GNAT_Extended_Ravenscar, N); elsif Chars (Argx) = Name_Gnat_Ravenscar_EDF then Set_Ravenscar_Profile (GNAT_Ravenscar_EDF, N); elsif Chars (Argx) = Name_Restricted then Set_Profile_Restrictions (Restricted, N, Warn => Treat_Restrictions_As_Warnings); elsif Chars (Argx) = Name_Rational then Set_Rational_Profile; elsif Chars (Argx) = Name_No_Implementation_Extensions then Set_Profile_Restrictions (No_Implementation_Extensions, N, Warn => Treat_Restrictions_As_Warnings); else Error_Pragma_Arg ("& is not a valid profile", Argx); end if; end; ---------------------- -- Profile_Warnings -- ---------------------- -- pragma Profile_Warnings (profile_IDENTIFIER); -- profile_IDENTIFIER => Restricted | Ravenscar when Pragma_Profile_Warnings => GNAT_Pragma; Check_Arg_Count (1); Check_Valid_Configuration_Pragma; Check_No_Identifiers; declare Argx : constant Node_Id := Get_Pragma_Arg (Arg1); begin if Chars (Argx) = Name_Ravenscar then Set_Profile_Restrictions (Ravenscar, N, Warn => True); elsif Chars (Argx) = Name_Restricted then Set_Profile_Restrictions (Restricted, N, Warn => True); elsif Chars (Argx) = Name_No_Implementation_Extensions then Set_Profile_Restrictions (No_Implementation_Extensions, N, Warn => True); else Error_Pragma_Arg ("& is not a valid profile", Argx); end if; end; -------------------------- -- Propagate_Exceptions -- -------------------------- -- pragma Propagate_Exceptions; -- Note: this pragma is obsolete and has no effect when Pragma_Propagate_Exceptions => GNAT_Pragma; Check_Arg_Count (0); if Warn_On_Obsolescent_Feature then Error_Msg_N ("'G'N'A'T pragma Propagate'_Exceptions is now obsolete " & "and has no effect?j?", N); end if; ----------------------------- -- Provide_Shift_Operators -- ----------------------------- -- pragma Provide_Shift_Operators (integer_subtype_LOCAL_NAME); when Pragma_Provide_Shift_Operators => Provide_Shift_Operators : declare Ent : Entity_Id; procedure Declare_Shift_Operator (Nam : Name_Id); -- Insert declaration and pragma Instrinsic for named shift op ---------------------------- -- Declare_Shift_Operator -- ---------------------------- procedure Declare_Shift_Operator (Nam : Name_Id) is Func : Node_Id; Import : Node_Id; begin Func := Make_Subprogram_Declaration (Loc, Make_Function_Specification (Loc, Defining_Unit_Name => Make_Defining_Identifier (Loc, Chars => Nam), Result_Definition => Make_Identifier (Loc, Chars => Chars (Ent)), Parameter_Specifications => New_List ( Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Value), Parameter_Type => Make_Identifier (Loc, Chars => Chars (Ent))), Make_Parameter_Specification (Loc, Defining_Identifier => Make_Defining_Identifier (Loc, Name_Amount), Parameter_Type => New_Occurrence_Of (Standard_Natural, Loc))))); Import := Make_Pragma (Loc, Chars => Name_Import, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Name_Intrinsic)), Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Nam)))); Insert_After (N, Import); Insert_After (N, Func); end Declare_Shift_Operator; -- Start of processing for Provide_Shift_Operators begin GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Arg1 := Get_Pragma_Arg (Arg1); -- We must have an entity name if not Is_Entity_Name (Arg1) then Error_Pragma_Arg ("pragma % must apply to integer first subtype", Arg1); end if; -- If no Entity, means there was a prior error so ignore if Present (Entity (Arg1)) then Ent := Entity (Arg1); -- Apply error checks if not Is_First_Subtype (Ent) then Error_Pragma_Arg ("cannot apply pragma %", "\& is not a first subtype", Arg1); elsif not Is_Integer_Type (Ent) then Error_Pragma_Arg ("cannot apply pragma %", "\& is not an integer type", Arg1); elsif Has_Shift_Operator (Ent) then Error_Pragma_Arg ("cannot apply pragma %", "\& already has declared shift operators", Arg1); elsif Is_Frozen (Ent) then Error_Pragma_Arg ("pragma % appears too late", "\& is already frozen", Arg1); end if; -- Now declare the operators. We do this during analysis rather -- than expansion, since we want the operators available if we -- are operating in -gnatc or ASIS mode. Declare_Shift_Operator (Name_Rotate_Left); Declare_Shift_Operator (Name_Rotate_Right); Declare_Shift_Operator (Name_Shift_Left); Declare_Shift_Operator (Name_Shift_Right); Declare_Shift_Operator (Name_Shift_Right_Arithmetic); end if; end Provide_Shift_Operators; ------------------ -- Psect_Object -- ------------------ -- pragma Psect_Object ( -- [Internal =>] LOCAL_NAME, -- [, [External =>] EXTERNAL_SYMBOL] -- [, [Size =>] EXTERNAL_SYMBOL]); when Pragma_Common_Object | Pragma_Psect_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); Def_Id : Entity_Id; procedure Check_Arg (Arg : Node_Id); -- Checks that argument is either a string literal or an -- identifier, and posts error message if not. --------------- -- Check_Arg -- --------------- procedure Check_Arg (Arg : Node_Id) is begin if not Nkind_In (Original_Node (Arg), N_String_Literal, N_Identifier) then Error_Pragma_Arg ("inappropriate argument for pragma %", Arg); end if; end Check_Arg; -- Start of processing for Common_Object/Psect_Object begin GNAT_Pragma; Gather_Associations (Names, Args); Process_Extended_Import_Export_Internal_Arg (Internal); Def_Id := Entity (Internal); if not Ekind_In (Def_Id, E_Constant, E_Variable) then Error_Pragma_Arg ("pragma% must designate an object", Internal); end if; Check_Arg (Internal); if Is_Imported (Def_Id) or else Is_Exported (Def_Id) then Error_Pragma_Arg ("cannot use pragma% for imported/exported object", Internal); end if; if Is_Concurrent_Type (Etype (Internal)) then Error_Pragma_Arg ("cannot specify pragma % for task/protected object", Internal); end if; if Has_Rep_Pragma (Def_Id, Name_Common_Object) or else Has_Rep_Pragma (Def_Id, Name_Psect_Object) then Error_Msg_N ("??duplicate Common/Psect_Object pragma", N); end if; if Ekind (Def_Id) = E_Constant then Error_Pragma_Arg ("cannot specify pragma % for a constant", Internal); end if; if Is_Record_Type (Etype (Internal)) then declare Ent : Entity_Id; Decl : Entity_Id; begin Ent := First_Entity (Etype (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 ("?x?object for pragma % has defaults", Internal); exit; else Next_Entity (Ent); end if; end loop; end; end if; if Present (Size) then Check_Arg (Size); end if; if Present (External) then Check_Arg_Is_External_Name (External); end if; -- If all error tests pass, link pragma on to the rep item chain Record_Rep_Item (Def_Id, N); end Psect_Object; ---------- -- Pure -- ---------- -- pragma Pure [(library_unit_NAME)]; when Pragma_Pure => Pure : declare Ent : Entity_Id; begin Check_Ada_83_Warning; -- If the pragma comes from a subprogram instantiation, nothing to -- check, this can happen at any level of nesting. if Is_Wrapper_Package (Current_Scope) then return; else Check_Valid_Library_Unit_Pragma; end if; if Nkind (N) = N_Null_Statement then return; end if; Ent := Find_Lib_Unit_Name; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Ent); if not Debug_Flag_U then Set_Is_Pure (Ent); Set_Has_Pragma_Pure (Ent); if Legacy_Elaboration_Checks then Set_Suppress_Elaboration_Warnings (Ent); end if; end if; end Pure; ------------------- -- Pure_Function -- ------------------- -- pragma Pure_Function ([Entity =>] function_LOCAL_NAME); when Pragma_Pure_Function => Pure_Function : declare Def_Id : Entity_Id; E : Entity_Id; E_Id : Node_Id; Effective : Boolean := False; Orig_Def : Entity_Id; Same_Decl : Boolean := False; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; -- Loop through homonyms (overloadings) of referenced entity E := Entity (E_Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); if Present (E) then loop Def_Id := Get_Base_Subprogram (E); if not Ekind_In (Def_Id, E_Function, E_Generic_Function, E_Operator) then Error_Pragma_Arg ("pragma% requires a function name", Arg1); end if; -- When we have a generic function we must jump up a level -- to the declaration of the wrapper package itself. Orig_Def := Def_Id; if Is_Generic_Instance (Def_Id) then while Nkind (Orig_Def) /= N_Package_Declaration loop Orig_Def := Parent (Orig_Def); end loop; end if; if In_Same_Declarative_Part (Parent (N), Orig_Def) then Same_Decl := True; 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; end if; exit when From_Aspect_Specification (N); 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?r?", N, Entity (E_Id)); elsif not Same_Decl then Error_Pragma_Arg ("pragma% argument must be in same declarative part", Arg1); 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 (Get_Pragma_Arg (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; -------------- -- Rational -- -------------- -- pragma Rational, for compatibility with foreign compiler when Pragma_Rational => Set_Rational_Profile; --------------------- -- Refined_Depends -- --------------------- -- pragma Refined_Depends (DEPENDENCY_RELATION); -- DEPENDENCY_RELATION ::= -- null -- | (DEPENDENCY_CLAUSE {, DEPENDENCY_CLAUSE}) -- DEPENDENCY_CLAUSE ::= -- OUTPUT_LIST =>[+] INPUT_LIST -- | NULL_DEPENDENCY_CLAUSE -- NULL_DEPENDENCY_CLAUSE ::= null => INPUT_LIST -- OUTPUT_LIST ::= OUTPUT | (OUTPUT {, OUTPUT}) -- INPUT_LIST ::= null | INPUT | (INPUT {, INPUT}) -- OUTPUT ::= NAME | FUNCTION_RESULT -- INPUT ::= NAME -- where FUNCTION_RESULT is a function Result attribute_reference -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks fully analyze -- the dependency clauses/global list in: -- Analyze_Refined_Depends_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram body. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram body is instantiated. when Pragma_Refined_Depends => Refined_Depends : declare Body_Id : Entity_Id; Legal : Boolean; Spec_Id : Entity_Id; begin Analyze_Refined_Depends_Global_Post (Spec_Id, Body_Id, Legal); if Legal then -- Chain the pragma on the contract for further processing by -- Analyze_Refined_Depends_In_Decl_Part. Add_Contract_Item (N, Body_Id); -- The legality checks of pragmas Refined_Depends and -- Refined_Global are affected by the SPARK mode in effect and -- the volatility of the context. In addition these two pragmas -- are subject to an inherent order: -- 1) Refined_Global -- 2) Refined_Depends -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_If_Present (Pragma_Refined_Global); Analyze_Refined_Depends_In_Decl_Part (N); end if; end Refined_Depends; -------------------- -- Refined_Global -- -------------------- -- pragma Refined_Global (GLOBAL_SPECIFICATION); -- GLOBAL_SPECIFICATION ::= -- null -- | (GLOBAL_LIST) -- | (MODED_GLOBAL_LIST {, MODED_GLOBAL_LIST}) -- MODED_GLOBAL_LIST ::= MODE_SELECTOR => GLOBAL_LIST -- MODE_SELECTOR ::= In_Out | Input | Output | Proof_In -- GLOBAL_LIST ::= GLOBAL_ITEM | (GLOBAL_ITEM {, GLOBAL_ITEM}) -- GLOBAL_ITEM ::= NAME -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks fully analyze -- the dependency clauses/global list in: -- Analyze_Refined_Global_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram body. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram body is instantiated. when Pragma_Refined_Global => Refined_Global : declare Body_Id : Entity_Id; Legal : Boolean; Spec_Id : Entity_Id; begin Analyze_Refined_Depends_Global_Post (Spec_Id, Body_Id, Legal); if Legal then -- Chain the pragma on the contract for further processing by -- Analyze_Refined_Global_In_Decl_Part. Add_Contract_Item (N, Body_Id); -- The legality checks of pragmas Refined_Depends and -- Refined_Global are affected by the SPARK mode in effect and -- the volatility of the context. In addition these two pragmas -- are subject to an inherent order: -- 1) Refined_Global -- 2) Refined_Depends -- Analyze all these pragmas in the order outlined above Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Refined_Global_In_Decl_Part (N); Analyze_If_Present (Pragma_Refined_Depends); end if; end Refined_Global; ------------------ -- Refined_Post -- ------------------ -- pragma Refined_Post (boolean_EXPRESSION); -- Characteristics: -- * Analysis - The annotation is fully analyzed immediately upon -- elaboration as it cannot forward reference entities. -- * Expansion - The annotation is expanded during the expansion of -- the related subprogram body contract as performed in: -- Expand_Subprogram_Contract -- * Template - The annotation utilizes the generic template of the -- related subprogram body. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram body is instantiated. when Pragma_Refined_Post => Refined_Post : declare Body_Id : Entity_Id; Legal : Boolean; Spec_Id : Entity_Id; begin Analyze_Refined_Depends_Global_Post (Spec_Id, Body_Id, Legal); -- Fully analyze the pragma when it appears inside a subprogram -- body because it cannot benefit from forward references. if Legal then -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Body_Id); -- The legality checks of pragma Refined_Post are affected by -- the SPARK mode in effect and the volatility of the context. -- Analyze all pragmas in a specific order. Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Pre_Post_Condition_In_Decl_Part (N); -- Currently it is not possible to inline pre/postconditions on -- a subprogram subject to pragma Inline_Always. Check_Postcondition_Use_In_Inlined_Subprogram (N, Spec_Id); end if; end Refined_Post; ------------------- -- Refined_State -- ------------------- -- pragma Refined_State (REFINEMENT_LIST); -- REFINEMENT_LIST ::= -- (REFINEMENT_CLAUSE {, REFINEMENT_CLAUSE}) -- REFINEMENT_CLAUSE ::= state_NAME => CONSTITUENT_LIST -- CONSTITUENT_LIST ::= -- null -- | CONSTITUENT -- | (CONSTITUENT {, CONSTITUENT}) -- CONSTITUENT ::= object_NAME | state_NAME -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- refinement clauses in: -- Analyze_Refined_State_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the template of the related -- package body. -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic package body is instantiated. when Pragma_Refined_State => Refined_State : declare Pack_Decl : Node_Id; Spec_Id : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Pack_Decl := Find_Related_Package_Or_Body (N, Do_Checks => True); if Nkind (Pack_Decl) /= N_Package_Body then Pragma_Misplaced; return; end if; Spec_Id := Corresponding_Spec (Pack_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Spec_Id); -- Chain the pragma on the contract for further processing by -- Analyze_Refined_State_In_Decl_Part. Add_Contract_Item (N, Defining_Entity (Pack_Decl)); -- The legality checks of pragma Refined_State are affected by the -- SPARK mode in effect. Analyze all pragmas in a specific order. Analyze_If_Present (Pragma_SPARK_Mode); -- State refinement is allowed only when the corresponding package -- declaration has non-null pragma Abstract_State. Refinement not -- enforced when SPARK checks are suppressed (SPARK RM 7.2.2(3)). if SPARK_Mode /= Off and then (No (Abstract_States (Spec_Id)) or else Has_Null_Abstract_State (Spec_Id)) then Error_Msg_NE ("useless refinement, package & does not define abstract " & "states", N, Spec_Id); return; end if; end Refined_State; ----------------------- -- Relative_Deadline -- ----------------------- -- pragma Relative_Deadline (time_span_EXPRESSION); when Pragma_Relative_Deadline => Relative_Deadline : declare P : constant Node_Id := Parent (N); Arg : Node_Id; begin Ada_2005_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Arg := Get_Pragma_Arg (Arg1); -- The expression must be analyzed in the special manner described -- in "Handling of Default and Per-Object Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, RTE (RE_Time_Span)); -- Subprogram case if Nkind (P) = N_Subprogram_Body then Check_In_Main_Program; -- Only Task and subprogram cases allowed elsif Nkind (P) /= N_Task_Definition then Pragma_Misplaced; end if; -- Check duplicate pragma before we set the corresponding flag if Has_Relative_Deadline_Pragma (P) then Error_Pragma ("duplicate pragma% not allowed"); end if; -- Set Has_Relative_Deadline_Pragma only for tasks. Note that -- Relative_Deadline pragma node cannot be inserted in the Rep -- Item chain of Ent since it is rewritten by the expander as a -- procedure call statement that will break the chain. Set_Has_Relative_Deadline_Pragma (P); end Relative_Deadline; ------------------------ -- Remote_Access_Type -- ------------------------ -- pragma Remote_Access_Type ([Entity =>] formal_type_LOCAL_NAME); when Pragma_Remote_Access_Type => Remote_Access_Type : declare E : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); if Nkind (Parent (E)) = N_Formal_Type_Declaration and then Ekind (E) = E_General_Access_Type and then Is_Class_Wide_Type (Directly_Designated_Type (E)) and then Scope (Root_Type (Directly_Designated_Type (E))) = Scope (E) and then Is_Valid_Remote_Object_Type (Root_Type (Directly_Designated_Type (E))) then Set_Is_Remote_Types (E); else Error_Pragma_Arg ("pragma% applies only to formal access-to-class-wide types", Arg1); end if; end Remote_Access_Type; --------------------------- -- 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); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Cunit_Ent); 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); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Cunit_Ent); if not Nkind_In (Unit (Cunit_Node), N_Package_Declaration, 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_Profile (Ravenscar, N); if Warn_On_Obsolescent_Feature then Error_Msg_N ("pragma Ravenscar is an obsolescent feature?j?", N); Error_Msg_N ("|use pragma Profile (Ravenscar) instead?j?", N); end if; ------------------------- -- Restricted_Run_Time -- ------------------------- -- pragma Restricted_Run_Time; when Pragma_Restricted_Run_Time => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Set_Profile_Restrictions (Restricted, N, Warn => Treat_Restrictions_As_Warnings); if Warn_On_Obsolescent_Feature then Error_Msg_N ("pragma Restricted_Run_Time is an obsolescent feature?j?", N); Error_Msg_N ("|use pragma Profile (Restricted) instead?j?", N); end if; ------------------ -- Restrictions -- ------------------ -- pragma Restrictions (RESTRICTION {, RESTRICTION}); -- RESTRICTION ::= -- restriction_IDENTIFIER -- | restriction_parameter_IDENTIFIER => EXPRESSION when Pragma_Restrictions => Process_Restrictions_Or_Restriction_Warnings (Warn => Treat_Restrictions_As_Warnings); -------------------------- -- Restriction_Warnings -- -------------------------- -- pragma Restriction_Warnings (RESTRICTION {, RESTRICTION}); -- RESTRICTION ::= -- restriction_IDENTIFIER -- | restriction_parameter_IDENTIFIER => EXPRESSION when Pragma_Restriction_Warnings => GNAT_Pragma; Process_Restrictions_Or_Restriction_Warnings (Warn => True); ---------------- -- Reviewable -- ---------------- -- pragma Reviewable; when Pragma_Reviewable => Check_Ada_83_Warning; Check_Arg_Count (0); -- Call dummy debugging function rv. This is done to assist front -- end debugging. By placing a Reviewable pragma in the source -- program, a breakpoint on rv catches this place in the source, -- allowing convenient stepping to the point of interest. rv; -------------------------- -- Secondary_Stack_Size -- -------------------------- -- pragma Secondary_Stack_Size (EXPRESSION); when Pragma_Secondary_Stack_Size => Secondary_Stack_Size : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_Arg_Count (1); if Nkind (P) = N_Task_Definition then Arg := Get_Pragma_Arg (Arg1); Ent := Defining_Identifier (Parent (P)); -- The expression must be analyzed in the special manner -- described in "Handling of Default Expressions" in sem.ads. Preanalyze_Spec_Expression (Arg, Any_Integer); -- The pragma cannot appear if the No_Secondary_Stack -- restriction is in effect. Check_Restriction (No_Secondary_Stack, Arg); -- Anything else is incorrect else Pragma_Misplaced; end if; -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. Check_Duplicate_Pragma (Ent); Record_Rep_Item (Ent, N); end Secondary_Stack_Size; -------------------------- -- Short_Circuit_And_Or -- -------------------------- -- pragma Short_Circuit_And_Or; when Pragma_Short_Circuit_And_Or => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; Short_Circuit_And_Or := True; ------------------- -- Share_Generic -- ------------------- -- pragma Share_Generic (GNAME {, GNAME}); -- GNAME ::= generic_unit_NAME | generic_instance_NAME when Pragma_Share_Generic => GNAT_Pragma; Process_Generic_List; ------------ -- Shared -- ------------ -- pragma Shared (LOCAL_NAME); when Pragma_Shared => GNAT_Pragma; Process_Atomic_Independent_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); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Cunit_Ent); if not Nkind_In (Unit (Cunit_Node), N_Package_Declaration, 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; ----------------------- -- Short_Descriptors -- ----------------------- -- pragma Short_Descriptors; -- Recognize and validate, but otherwise ignore when Pragma_Short_Descriptors => GNAT_Pragma; Check_Arg_Count (0); Check_Valid_Configuration_Pragma; ------------------------------ -- Simple_Storage_Pool_Type -- ------------------------------ -- pragma Simple_Storage_Pool_Type (type_LOCAL_NAME); when Pragma_Simple_Storage_Pool_Type => Simple_Storage_Pool_Type : declare Typ : Entity_Id; Type_Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Arg_Is_Library_Level_Local_Name (Arg1); Type_Id := Get_Pragma_Arg (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); if Typ = Any_Type then return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); -- We require the pragma to apply to a type declared in a package -- declaration, but not (immediately) within a package body. if Ekind (Current_Scope) /= E_Package or else In_Package_Body (Current_Scope) then Error_Pragma ("pragma% can only apply to type declared immediately " & "within a package declaration"); end if; -- A simple storage pool type must be an immutably limited record -- or private type. If the pragma is given for a private type, -- the full type is similarly restricted (which is checked later -- in Freeze_Entity). if Is_Record_Type (Typ) and then not Is_Limited_View (Typ) then Error_Pragma ("pragma% can only apply to explicitly limited record type"); elsif Is_Private_Type (Typ) and then not Is_Limited_Type (Typ) then Error_Pragma ("pragma% can only apply to a private type that is limited"); elsif not Is_Record_Type (Typ) and then not Is_Private_Type (Typ) then Error_Pragma ("pragma% can only apply to limited record or private type"); end if; Record_Rep_Item (Typ, N); end Simple_Storage_Pool_Type; ---------------------- -- Source_File_Name -- ---------------------- -- There are five forms for this pragma: -- pragma Source_File_Name ( -- [UNIT_NAME =>] unit_NAME, -- BODY_FILE_NAME => STRING_LITERAL -- [, [INDEX =>] INTEGER_LITERAL]); -- pragma Source_File_Name ( -- [UNIT_NAME =>] unit_NAME, -- SPEC_FILE_NAME => STRING_LITERAL -- [, [INDEX =>] INTEGER_LITERAL]); -- pragma Source_File_Name ( -- BODY_FILE_NAME => STRING_LITERAL -- [, DOT_REPLACEMENT => STRING_LITERAL] -- [, CASING => CASING_SPEC]); -- pragma Source_File_Name ( -- SPEC_FILE_NAME => STRING_LITERAL -- [, DOT_REPLACEMENT => STRING_LITERAL] -- [, CASING => CASING_SPEC]); -- pragma Source_File_Name ( -- SUBUNIT_FILE_NAME => STRING_LITERAL -- [, DOT_REPLACEMENT => STRING_LITERAL] -- [, CASING => CASING_SPEC]); -- CASING_SPEC ::= Uppercase | Lowercase | Mixedcase -- Pragma Source_File_Name_Project (SFNP) is equivalent to pragma -- Source_File_Name (SFN), however their usage is exclusive: SFN can -- only be used when no project file is used, while SFNP can only be -- used when a project file is used. -- 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 -- ------------------------------ -- See Source_File_Name for syntax -- 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; ---------------- -- SPARK_Mode -- ---------------- -- pragma SPARK_Mode [(On | Off)]; when Pragma_SPARK_Mode => Do_SPARK_Mode : declare Mode_Id : SPARK_Mode_Type; procedure Check_Pragma_Conformance (Context_Pragma : Node_Id; Entity : Entity_Id; Entity_Pragma : Node_Id); -- Subsidiary to routines Process_xxx. Verify the SPARK_Mode -- conformance of pragma N depending the following scenarios: -- -- If pragma Context_Pragma is not Empty, verify that pragma N is -- compatible with the pragma Context_Pragma that was inherited -- from the context: -- * If the mode of Context_Pragma is ON, then the new mode can -- be anything. -- * If the mode of Context_Pragma is OFF, then the only allowed -- new mode is also OFF. Emit error if this is not the case. -- -- If Entity is not Empty, verify that pragma N is compatible with -- pragma Entity_Pragma that belongs to Entity. -- * If Entity_Pragma is Empty, always issue an error as this -- corresponds to the case where a previous section of Entity -- has no SPARK_Mode set. -- * If the mode of Entity_Pragma is ON, then the new mode can -- be anything. -- * If the mode of Entity_Pragma is OFF, then the only allowed -- new mode is also OFF. Emit error if this is not the case. procedure Check_Library_Level_Entity (E : Entity_Id); -- Subsidiary to routines Process_xxx. Verify that the related -- entity E subject to pragma SPARK_Mode is library-level. procedure Process_Body (Decl : Node_Id); -- Verify the legality of pragma SPARK_Mode when it appears as the -- top of the body declarations of entry, package, protected unit, -- subprogram or task unit body denoted by Decl. procedure Process_Overloadable (Decl : Node_Id); -- Verify the legality of pragma SPARK_Mode when it applies to an -- entry or [generic] subprogram declaration denoted by Decl. procedure Process_Private_Part (Decl : Node_Id); -- Verify the legality of pragma SPARK_Mode when it appears at the -- top of the private declarations of a package spec, protected or -- task unit declaration denoted by Decl. procedure Process_Statement_Part (Decl : Node_Id); -- Verify the legality of pragma SPARK_Mode when it appears at the -- top of the statement sequence of a package body denoted by node -- Decl. procedure Process_Visible_Part (Decl : Node_Id); -- Verify the legality of pragma SPARK_Mode when it appears at the -- top of the visible declarations of a package spec, protected or -- task unit declaration denoted by Decl. The routine is also used -- on protected or task units declared without a definition. procedure Set_SPARK_Context; -- Subsidiary to routines Process_xxx. Set the global variables -- which represent the mode of the context from pragma N. Ensure -- that Dynamic_Elaboration_Checks are off if the new mode is On. ------------------------------ -- Check_Pragma_Conformance -- ------------------------------ procedure Check_Pragma_Conformance (Context_Pragma : Node_Id; Entity : Entity_Id; Entity_Pragma : Node_Id) is Err_Id : Entity_Id; Err_N : Node_Id; begin -- The current pragma may appear without an argument. If this -- is the case, associate all error messages with the pragma -- itself. if Present (Arg1) then Err_N := Arg1; else Err_N := N; end if; -- The mode of the current pragma is compared against that of -- an enclosing context. if Present (Context_Pragma) then pragma Assert (Nkind (Context_Pragma) = N_Pragma); -- Issue an error if the new mode is less restrictive than -- that of the context. if Get_SPARK_Mode_From_Annotation (Context_Pragma) = Off and then Get_SPARK_Mode_From_Annotation (N) = On then Error_Msg_N ("cannot change SPARK_Mode from Off to On", Err_N); Error_Msg_Sloc := Sloc (SPARK_Mode_Pragma); Error_Msg_N ("\SPARK_Mode was set to Off#", Err_N); raise Pragma_Exit; end if; end if; -- The mode of the current pragma is compared against that of -- an initial package, protected type, subprogram or task type -- declaration. if Present (Entity) then -- A simple protected or task type is transformed into an -- anonymous type whose name cannot be used to issue error -- messages. Recover the original entity of the type. if Ekind_In (Entity, E_Protected_Type, E_Task_Type) then Err_Id := Defining_Entity (Original_Node (Unit_Declaration_Node (Entity))); else Err_Id := Entity; end if; -- Both the initial declaration and the completion carry -- SPARK_Mode pragmas. if Present (Entity_Pragma) then pragma Assert (Nkind (Entity_Pragma) = N_Pragma); -- Issue an error if the new mode is less restrictive -- than that of the initial declaration. if Get_SPARK_Mode_From_Annotation (Entity_Pragma) = Off and then Get_SPARK_Mode_From_Annotation (N) = On then Error_Msg_N ("incorrect use of SPARK_Mode", Err_N); Error_Msg_Sloc := Sloc (Entity_Pragma); Error_Msg_NE ("\value Off was set for SPARK_Mode on&#", Err_N, Err_Id); raise Pragma_Exit; end if; -- Otherwise the initial declaration lacks a SPARK_Mode -- pragma in which case the current pragma is illegal as -- it cannot "complete". else Error_Msg_N ("incorrect use of SPARK_Mode", Err_N); Error_Msg_Sloc := Sloc (Err_Id); Error_Msg_NE ("\no value was set for SPARK_Mode on&#", Err_N, Err_Id); raise Pragma_Exit; end if; end if; end Check_Pragma_Conformance; -------------------------------- -- Check_Library_Level_Entity -- -------------------------------- procedure Check_Library_Level_Entity (E : Entity_Id) is procedure Add_Entity_To_Name_Buffer; -- Add the E_Kind of entity E to the name buffer ------------------------------- -- Add_Entity_To_Name_Buffer -- ------------------------------- procedure Add_Entity_To_Name_Buffer is begin if Ekind_In (E, E_Entry, E_Entry_Family) then Add_Str_To_Name_Buffer ("entry"); elsif Ekind_In (E, E_Generic_Package, E_Package, E_Package_Body) then Add_Str_To_Name_Buffer ("package"); elsif Ekind_In (E, E_Protected_Body, E_Protected_Type) then Add_Str_To_Name_Buffer ("protected type"); elsif Ekind_In (E, E_Function, E_Generic_Function, E_Generic_Procedure, E_Procedure, E_Subprogram_Body) then Add_Str_To_Name_Buffer ("subprogram"); else pragma Assert (Ekind_In (E, E_Task_Body, E_Task_Type)); Add_Str_To_Name_Buffer ("task type"); end if; end Add_Entity_To_Name_Buffer; -- Local variables Msg_1 : constant String := "incorrect placement of pragma%"; Msg_2 : Name_Id; -- Start of processing for Check_Library_Level_Entity begin if not Is_Library_Level_Entity (E) then Error_Msg_Name_1 := Pname; Error_Msg_N (Fix_Error (Msg_1), N); Name_Len := 0; Add_Str_To_Name_Buffer ("\& is not a library-level "); Add_Entity_To_Name_Buffer; Msg_2 := Name_Find; Error_Msg_NE (Get_Name_String (Msg_2), N, E); raise Pragma_Exit; end if; end Check_Library_Level_Entity; ------------------ -- Process_Body -- ------------------ procedure Process_Body (Decl : Node_Id) is Body_Id : constant Entity_Id := Defining_Entity (Decl); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Decl); begin -- Ignore pragma when applied to the special body created for -- inlining, recognized by its internal name _Parent. if Chars (Body_Id) = Name_uParent then return; end if; Check_Library_Level_Entity (Body_Id); -- For entry bodies, verify the legality against: -- * The mode of the context -- * The mode of the spec (if any) if Nkind_In (Decl, N_Entry_Body, N_Subprogram_Body) then -- A stand-alone subprogram body if Body_Id = Spec_Id then Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Body_Id), Entity => Empty, Entity_Pragma => Empty); -- An entry or subprogram body that completes a previous -- declaration. else Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Body_Id), Entity => Spec_Id, Entity_Pragma => SPARK_Pragma (Spec_Id)); end if; Set_SPARK_Context; Set_SPARK_Pragma (Body_Id, N); Set_SPARK_Pragma_Inherited (Body_Id, False); -- For package bodies, verify the legality against: -- * The mode of the context -- * The mode of the private part -- This case is separated from protected and task bodies -- because the statement part of the package body inherits -- the mode of the body declarations. elsif Nkind (Decl) = N_Package_Body then Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Body_Id), Entity => Spec_Id, Entity_Pragma => SPARK_Aux_Pragma (Spec_Id)); Set_SPARK_Context; Set_SPARK_Pragma (Body_Id, N); Set_SPARK_Pragma_Inherited (Body_Id, False); Set_SPARK_Aux_Pragma (Body_Id, N); Set_SPARK_Aux_Pragma_Inherited (Body_Id, True); -- For protected and task bodies, verify the legality against: -- * The mode of the context -- * The mode of the private part else pragma Assert (Nkind_In (Decl, N_Protected_Body, N_Task_Body)); Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Body_Id), Entity => Spec_Id, Entity_Pragma => SPARK_Aux_Pragma (Spec_Id)); Set_SPARK_Context; Set_SPARK_Pragma (Body_Id, N); Set_SPARK_Pragma_Inherited (Body_Id, False); end if; end Process_Body; -------------------------- -- Process_Overloadable -- -------------------------- procedure Process_Overloadable (Decl : Node_Id) is Spec_Id : constant Entity_Id := Defining_Entity (Decl); Spec_Typ : constant Entity_Id := Etype (Spec_Id); begin Check_Library_Level_Entity (Spec_Id); -- Verify the legality against: -- * The mode of the context Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Spec_Id), Entity => Empty, Entity_Pragma => Empty); Set_SPARK_Pragma (Spec_Id, N); Set_SPARK_Pragma_Inherited (Spec_Id, False); -- When the pragma applies to the anonymous object created for -- a single task type, decorate the type as well. This scenario -- arises when the single task type lacks a task definition, -- therefore there is no issue with respect to a potential -- pragma SPARK_Mode in the private part. -- task type Anon_Task_Typ; -- Obj : Anon_Task_Typ; -- pragma SPARK_Mode ...; if Is_Single_Task_Object (Spec_Id) then Set_SPARK_Pragma (Spec_Typ, N); Set_SPARK_Pragma_Inherited (Spec_Typ, False); Set_SPARK_Aux_Pragma (Spec_Typ, N); Set_SPARK_Aux_Pragma_Inherited (Spec_Typ, True); end if; end Process_Overloadable; -------------------------- -- Process_Private_Part -- -------------------------- procedure Process_Private_Part (Decl : Node_Id) is Spec_Id : constant Entity_Id := Defining_Entity (Decl); begin Check_Library_Level_Entity (Spec_Id); -- Verify the legality against: -- * The mode of the visible declarations Check_Pragma_Conformance (Context_Pragma => Empty, Entity => Spec_Id, Entity_Pragma => SPARK_Pragma (Spec_Id)); Set_SPARK_Context; Set_SPARK_Aux_Pragma (Spec_Id, N); Set_SPARK_Aux_Pragma_Inherited (Spec_Id, False); end Process_Private_Part; ---------------------------- -- Process_Statement_Part -- ---------------------------- procedure Process_Statement_Part (Decl : Node_Id) is Body_Id : constant Entity_Id := Defining_Entity (Decl); begin Check_Library_Level_Entity (Body_Id); -- Verify the legality against: -- * The mode of the body declarations Check_Pragma_Conformance (Context_Pragma => Empty, Entity => Body_Id, Entity_Pragma => SPARK_Pragma (Body_Id)); Set_SPARK_Context; Set_SPARK_Aux_Pragma (Body_Id, N); Set_SPARK_Aux_Pragma_Inherited (Body_Id, False); end Process_Statement_Part; -------------------------- -- Process_Visible_Part -- -------------------------- procedure Process_Visible_Part (Decl : Node_Id) is Spec_Id : constant Entity_Id := Defining_Entity (Decl); Obj_Id : Entity_Id; begin Check_Library_Level_Entity (Spec_Id); -- Verify the legality against: -- * The mode of the context Check_Pragma_Conformance (Context_Pragma => SPARK_Pragma (Spec_Id), Entity => Empty, Entity_Pragma => Empty); -- A task unit declared without a definition does not set the -- SPARK_Mode of the context because the task does not have any -- entries that could inherit the mode. if not Nkind_In (Decl, N_Single_Task_Declaration, N_Task_Type_Declaration) then Set_SPARK_Context; end if; Set_SPARK_Pragma (Spec_Id, N); Set_SPARK_Pragma_Inherited (Spec_Id, False); Set_SPARK_Aux_Pragma (Spec_Id, N); Set_SPARK_Aux_Pragma_Inherited (Spec_Id, True); -- When the pragma applies to a single protected or task type, -- decorate the corresponding anonymous object as well. -- protected Anon_Prot_Typ is -- pragma SPARK_Mode ...; -- ... -- end Anon_Prot_Typ; -- Obj : Anon_Prot_Typ; if Is_Single_Concurrent_Type (Spec_Id) then Obj_Id := Anonymous_Object (Spec_Id); Set_SPARK_Pragma (Obj_Id, N); Set_SPARK_Pragma_Inherited (Obj_Id, False); end if; end Process_Visible_Part; ----------------------- -- Set_SPARK_Context -- ----------------------- procedure Set_SPARK_Context is begin SPARK_Mode := Mode_Id; SPARK_Mode_Pragma := N; end Set_SPARK_Context; -- Local variables Context : Node_Id; Mode : Name_Id; Stmt : Node_Id; -- Start of processing for Do_SPARK_Mode begin -- When a SPARK_Mode pragma appears inside an instantiation whose -- enclosing context has SPARK_Mode set to "off", the pragma has -- no semantic effect. if Ignore_SPARK_Mode_Pragmas_In_Instance then Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); return; end if; GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); -- Check the legality of the mode (no argument = ON) if Arg_Count = 1 then Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); Mode := Chars (Get_Pragma_Arg (Arg1)); else Mode := Name_On; end if; Mode_Id := Get_SPARK_Mode_Type (Mode); Context := Parent (N); -- The pragma appears in a configuration file if No (Context) then Check_Valid_Configuration_Pragma; if Present (SPARK_Mode_Pragma) then Duplication_Error (Prag => N, Prev => SPARK_Mode_Pragma); raise Pragma_Exit; end if; Set_SPARK_Context; -- The pragma acts as a configuration pragma in a compilation unit -- pragma SPARK_Mode ...; -- package Pack is ...; elsif Nkind (Context) = N_Compilation_Unit and then List_Containing (N) = Context_Items (Context) then Check_Valid_Configuration_Pragma; Set_SPARK_Context; -- Otherwise the placement of the pragma within the tree dictates -- its associated construct. Inspect the declarative list where -- the pragma resides to find a potential construct. else Stmt := Prev (N); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates. Note that -- this also takes care of pragmas generated for aspects. if Nkind (Stmt) = N_Pragma then if Pragma_Name (Stmt) = Pname then Duplication_Error (Prag => N, Prev => Stmt); raise Pragma_Exit; end if; -- The pragma applies to an expression function that has -- already been rewritten into a subprogram declaration. -- function Expr_Func return ... is (...); -- pragma SPARK_Mode ...; elsif Nkind (Stmt) = N_Subprogram_Declaration and then Nkind (Original_Node (Stmt)) = N_Expression_Function then Process_Overloadable (Stmt); return; -- The pragma applies to the anonymous object created for a -- single concurrent type. -- protected type Anon_Prot_Typ ...; -- Obj : Anon_Prot_Typ; -- pragma SPARK_Mode ...; elsif Nkind (Stmt) = N_Object_Declaration and then Is_Single_Concurrent_Object (Defining_Entity (Stmt)) then Process_Overloadable (Stmt); return; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then null; -- The pragma applies to an entry or [generic] subprogram -- declaration. -- entry Ent ...; -- pragma SPARK_Mode ...; -- [generic] -- procedure Proc ...; -- pragma SPARK_Mode ...; elsif Nkind_In (Stmt, N_Generic_Subprogram_Declaration, N_Subprogram_Declaration) or else (Nkind (Stmt) = N_Entry_Declaration and then Is_Protected_Type (Scope (Defining_Entity (Stmt)))) then Process_Overloadable (Stmt); return; -- Otherwise the pragma does not apply to a legal construct -- or it does not appear at the top of a declarative or a -- statement list. Issue an error and stop the analysis. else Pragma_Misplaced; exit; end if; Prev (Stmt); end loop; -- The pragma applies to a package or a subprogram that acts as -- a compilation unit. -- procedure Proc ...; -- pragma SPARK_Mode ...; if Nkind (Context) = N_Compilation_Unit_Aux then Context := Unit (Parent (Context)); end if; -- The pragma appears at the top of entry, package, protected -- unit, subprogram or task unit body declarations. -- entry Ent when ... is -- pragma SPARK_Mode ...; -- package body Pack is -- pragma SPARK_Mode ...; -- procedure Proc ... is -- pragma SPARK_Mode; -- protected body Prot is -- pragma SPARK_Mode ...; if Nkind_In (Context, N_Entry_Body, N_Package_Body, N_Protected_Body, N_Subprogram_Body, N_Task_Body) then Process_Body (Context); -- The pragma appears at the top of the visible or private -- declaration of a package spec, protected or task unit. -- package Pack is -- pragma SPARK_Mode ...; -- private -- pragma SPARK_Mode ...; -- protected [type] Prot is -- pragma SPARK_Mode ...; -- private -- pragma SPARK_Mode ...; elsif Nkind_In (Context, N_Package_Specification, N_Protected_Definition, N_Task_Definition) then if List_Containing (N) = Visible_Declarations (Context) then Process_Visible_Part (Parent (Context)); else Process_Private_Part (Parent (Context)); end if; -- The pragma appears at the top of package body statements -- package body Pack is -- begin -- pragma SPARK_Mode; elsif Nkind (Context) = N_Handled_Sequence_Of_Statements and then Nkind (Parent (Context)) = N_Package_Body then Process_Statement_Part (Parent (Context)); -- The pragma appeared as an aspect of a [generic] subprogram -- declaration that acts as a compilation unit. -- [generic] -- procedure Proc ...; -- pragma SPARK_Mode ...; elsif Nkind_In (Context, N_Generic_Subprogram_Declaration, N_Subprogram_Declaration) then Process_Overloadable (Context); -- The pragma does not apply to a legal construct, issue error else Pragma_Misplaced; end if; end if; end Do_SPARK_Mode; -------------------------------- -- Static_Elaboration_Desired -- -------------------------------- -- pragma Static_Elaboration_Desired (DIRECT_NAME); when Pragma_Static_Elaboration_Desired => GNAT_Pragma; Check_At_Most_N_Arguments (1); if Is_Compilation_Unit (Current_Scope) and then Ekind (Current_Scope) = E_Package then Set_Static_Elaboration_Desired (Current_Scope, True); else Error_Pragma ("pragma% must apply to a library-level package"); end if; ------------------ -- 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. Arg := Get_Pragma_Arg (Arg1); Preanalyze_Spec_Expression (Arg, Any_Integer); if not Is_OK_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); 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 (Get_Pragma_Arg (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 (Get_Pragma_Arg (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 processing for Stream_Convert begin GNAT_Pragma; Check_Arg_Order ((Name_Entity, Name_Read, Name_Write)); 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 (Get_Pragma_Arg (Arg1))); Read : constant Entity_Id := Entity (Get_Pragma_Arg (Arg2)); Write : constant Entity_Id := Entity (Get_Pragma_Arg (Arg3)); begin Check_First_Subtype (Arg1); -- Check for too early or too late. Note that we don't enforce -- the rule about primitive operations in this case, since, as -- is the case for explicit stream attributes themselves, these -- restrictions are not appropriate. Note that the chaining of -- the pragma by Rep_Item_Too_Late is actually the critical -- processing done for this pragma. if Rep_Item_Too_Early (Typ, N) or else Rep_Item_Too_Late (Typ, N, FOnly => True) then return; end if; -- Return if previous error if Etype (Typ) = Any_Type or else Etype (Read) = Any_Type or else Etype (Write) = Any_Type then return; end if; -- Error checks 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 -- ------------------ -- 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 := Get_Pragma_Arg (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 := Get_Pragma_Arg (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 not Ignore_Style_Checks_Pragmas then if E = Any_Id then return; else loop Set_Suppress_Style_Checks (E, Chars (Get_Pragma_Arg (Arg1)) = Name_Off); exit when No (Homonym (E)); E := Homonym (E); end loop; end if; 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 : Positive; begin J := 1; loop C := Get_String_Char (S, Pos (J)); exit when not In_Character_Range (C); Options (J) := Get_Character (C); -- If at end of string, set options. As per discussion -- above, no need to check for errors, since we issued -- them in the parser. if J = Slen then if not Ignore_Style_Checks_Pragmas then Set_Style_Check_Options (Options); end if; exit; end if; J := J + 1; end loop; end; elsif Nkind (A) = N_Identifier then if Chars (A) = Name_All_Checks then if not Ignore_Style_Checks_Pragmas then if GNAT_Mode then Set_GNAT_Style_Check_Options; else Set_Default_Style_Check_Options; end if; end if; elsif Chars (A) = Name_On then if not Ignore_Style_Checks_Pragmas then Style_Check := True; end if; elsif Chars (A) = Name_Off then if not Ignore_Style_Checks_Pragmas then Style_Check := False; end if; 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_OK_Static_Expression (Arg1, Standard_String); Store_Note (N); -------------- -- Suppress -- -------------- -- pragma Suppress (IDENTIFIER [, [On =>] NAME]); when Pragma_Suppress => Process_Suppress_Unsuppress (Suppress_Case => True); ------------------ -- Suppress_All -- ------------------ -- pragma Suppress_All; -- The only check made here is that the pragma has no arguments. -- There are no placement rules, and the processing required (setting -- the Has_Pragma_Suppress_All flag in the compilation unit node was -- taken care of by the parser). Process_Compilation_Unit_Pragmas -- then creates and inserts a pragma Suppress (All_Checks). when Pragma_Suppress_All => GNAT_Pragma; Check_Arg_Count (0); ------------------------- -- Suppress_Debug_Info -- ------------------------- -- pragma Suppress_Debug_Info ([Entity =>] LOCAL_NAME); when Pragma_Suppress_Debug_Info => Suppress_Debug_Info : declare Nam_Id : Entity_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); Nam_Id := Entity (Get_Pragma_Arg (Arg1)); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Nam_Id); Set_Debug_Info_Off (Nam_Id); end Suppress_Debug_Info; ---------------------------------- -- 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 : Entity_Id; E_Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); if not Is_Type (E) and then Ekind (E) /= E_Variable then Error_Pragma_Arg ("pragma% requires variable, type or subtype", Arg1); end if; if Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N, FOnly => True) then return; end if; -- For incomplete/private type, set flag on full view 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_Initialization (Full_View (Base_Type (E))); end if; -- For first subtype, set flag on base type elsif Is_First_Subtype (E) then Set_Suppress_Initialization (Base_Type (E)); -- For other than first subtype, set flag on subtype or variable else Set_Suppress_Initialization (E); 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 => GNAT_Pragma; 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 (Get_Pragma_Arg (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); Ent : Entity_Id; begin GNAT_Pragma; if Warn_On_Obsolescent_Feature then Error_Msg_N ("'G'N'A'T pragma Task_Info is now obsolete, use 'C'P'U " & "instead?j?", N); end if; 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 (Get_Pragma_Arg (Arg1), RTE (RE_Task_Info_Type)); if Etype (Get_Pragma_Arg (Arg1)) = Any_Type then return; end if; Ent := Defining_Identifier (Parent (P)); -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. if Has_Rep_Pragma (Ent, Name_Task_Info, Check_Parents => False) then Error_Pragma ("duplicate pragma% not allowed"); end if; Record_Rep_Item (Ent, N); end Task_Info; --------------- -- Task_Name -- --------------- -- pragma Task_Name (string_EXPRESSION); when Pragma_Task_Name => Task_Name : declare P : constant Node_Id := Parent (N); Arg : Node_Id; Ent : Entity_Id; begin Check_No_Identifiers; Check_Arg_Count (1); Arg := Get_Pragma_Arg (Arg1); -- The expression is used in the call to Create_Task, and must be -- expanded there, not in the context of the current spec. It must -- however be analyzed to capture global references, in case it -- appears in a generic context. Preanalyze_And_Resolve (Arg, Standard_String); if Nkind (P) /= N_Task_Definition then Pragma_Misplaced; end if; Ent := Defining_Identifier (Parent (P)); -- Check duplicate pragma before we chain the pragma in the Rep -- Item chain of Ent. if Has_Rep_Pragma (Ent, Name_Task_Name, Check_Parents => False) then Error_Pragma ("duplicate pragma% not allowed"); end if; Record_Rep_Item (Ent, N); 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_OK_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; --------------- -- Test_Case -- --------------- -- pragma Test_Case -- ([Name =>] Static_String_EXPRESSION -- ,[Mode =>] MODE_TYPE -- [, Requires => Boolean_EXPRESSION] -- [, Ensures => Boolean_EXPRESSION]); -- MODE_TYPE ::= Nominal | Robustness -- Characteristics: -- * Analysis - The annotation undergoes initial checks to verify -- the legal placement and context. Secondary checks preanalyze the -- expressions in: -- Analyze_Test_Case_In_Decl_Part -- * Expansion - None. -- * Template - The annotation utilizes the generic template of the -- related subprogram when it is: -- aspect on subprogram declaration -- The annotation must prepare its own template when it is: -- pragma on subprogram declaration -- * Globals - Capture of global references must occur after full -- analysis. -- * Instance - The annotation is instantiated automatically when -- the related generic subprogram is instantiated except for the -- "pragma on subprogram declaration" case. In that scenario the -- annotation must instantiate itself. when Pragma_Test_Case => Test_Case : declare procedure Check_Distinct_Name (Subp_Id : Entity_Id); -- Ensure that the contract of subprogram Subp_Id does not contain -- another Test_Case pragma with the same Name as the current one. ------------------------- -- Check_Distinct_Name -- ------------------------- procedure Check_Distinct_Name (Subp_Id : Entity_Id) is Items : constant Node_Id := Contract (Subp_Id); Name : constant String_Id := Get_Name_From_CTC_Pragma (N); Prag : Node_Id; begin -- Inspect all Test_Case pragma of the related subprogram -- looking for one with a duplicate "Name" argument. if Present (Items) then Prag := Contract_Test_Cases (Items); while Present (Prag) loop if Pragma_Name (Prag) = Name_Test_Case and then Prag /= N and then String_Equal (Name, Get_Name_From_CTC_Pragma (Prag)) then Error_Msg_Sloc := Sloc (Prag); Error_Pragma ("name for pragma % is already used #"); end if; Prag := Next_Pragma (Prag); end loop; end if; end Check_Distinct_Name; -- Local variables Pack_Decl : constant Node_Id := Unit (Cunit (Current_Sem_Unit)); Asp_Arg : Node_Id; Context : Node_Id; Subp_Decl : Node_Id; Subp_Id : Entity_Id; -- Start of processing for Test_Case begin GNAT_Pragma; Check_At_Least_N_Arguments (2); Check_At_Most_N_Arguments (4); Check_Arg_Order ((Name_Name, Name_Mode, Name_Requires, Name_Ensures)); -- Argument "Name" Check_Optional_Identifier (Arg1, Name_Name); Check_Arg_Is_OK_Static_Expression (Arg1, Standard_String); -- Argument "Mode" Check_Optional_Identifier (Arg2, Name_Mode); Check_Arg_Is_One_Of (Arg2, Name_Nominal, Name_Robustness); -- Arguments "Requires" and "Ensures" if Present (Arg3) then if Present (Arg4) then Check_Identifier (Arg3, Name_Requires); Check_Identifier (Arg4, Name_Ensures); else Check_Identifier_Is_One_Of (Arg3, Name_Requires, Name_Ensures); end if; end if; -- Pragma Test_Case must be associated with a subprogram declared -- in a library-level package. First determine whether the current -- compilation unit is a legal context. if Nkind_In (Pack_Decl, N_Package_Declaration, N_Generic_Package_Declaration) then null; -- Otherwise the placement is illegal else Error_Pragma ("pragma % must be specified within a package declaration"); return; end if; Subp_Decl := Find_Related_Declaration_Or_Body (N); -- Find the enclosing context Context := Parent (Subp_Decl); if Present (Context) then Context := Parent (Context); end if; -- Verify the placement of the pragma if Nkind (Subp_Decl) = N_Abstract_Subprogram_Declaration then Error_Pragma ("pragma % cannot be applied to abstract subprogram"); return; elsif Nkind (Subp_Decl) = N_Entry_Declaration then Error_Pragma ("pragma % cannot be applied to entry"); return; -- The context is a [generic] subprogram declared at the top level -- of the [generic] package unit. elsif Nkind_In (Subp_Decl, N_Generic_Subprogram_Declaration, N_Subprogram_Declaration) and then Present (Context) and then Nkind_In (Context, N_Generic_Package_Declaration, N_Package_Declaration) then null; -- Otherwise the placement is illegal else Error_Pragma ("pragma % must be applied to a library-level subprogram " & "declaration"); return; end if; Subp_Id := Defining_Entity (Subp_Decl); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Subp_Id); -- Chain the pragma on the contract for further processing by -- Analyze_Test_Case_In_Decl_Part. Add_Contract_Item (N, Subp_Id); -- Preanalyze the original aspect argument "Name" for ASIS or for -- a generic subprogram to properly capture global references. if ASIS_Mode or else Is_Generic_Subprogram (Subp_Id) then Asp_Arg := Test_Case_Arg (N, Name_Name, From_Aspect => True); if Present (Asp_Arg) then -- The argument appears with an identifier in association -- form. if Nkind (Asp_Arg) = N_Component_Association then Asp_Arg := Expression (Asp_Arg); end if; Check_Expr_Is_OK_Static_Expression (Asp_Arg, Standard_String); end if; end if; -- Ensure that the all Test_Case pragmas of the related subprogram -- have distinct names. Check_Distinct_Name (Subp_Id); -- Fully analyze the pragma when it appears inside an entry -- or subprogram body because it cannot benefit from forward -- references. if Nkind_In (Subp_Decl, N_Entry_Body, N_Subprogram_Body, N_Subprogram_Body_Stub) then -- The legality checks of pragma Test_Case are affected by the -- SPARK mode in effect and the volatility of the context. -- Analyze all pragmas in a specific order. Analyze_If_Present (Pragma_SPARK_Mode); Analyze_If_Present (Pragma_Volatile_Function); Analyze_Test_Case_In_Decl_Part (N); end if; end Test_Case; -------------------------- -- Thread_Local_Storage -- -------------------------- -- pragma Thread_Local_Storage ([Entity =>] LOCAL_NAME); when Pragma_Thread_Local_Storage => Thread_Local_Storage : declare E : Entity_Id; Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg1, Name_Entity); Check_Arg_Is_Library_Level_Local_Name (Arg1); Id := Get_Pragma_Arg (Arg1); Analyze (Id); if not Is_Entity_Name (Id) or else Ekind (Entity (Id)) /= E_Variable then Error_Pragma_Arg ("local variable name required", Arg1); end if; E := Entity (Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); if Rep_Item_Too_Early (E, N) or else Rep_Item_Too_Late (E, N) then raise Pragma_Exit; end if; Set_Has_Pragma_Thread_Local_Storage (E); Set_Has_Gigi_Rep_Item (E); end Thread_Local_Storage; ---------------- -- 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_OK_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 Pragma_Name (Nod) = Name_Time_Slice then Error_Msg_Name_1 := Pname; 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 (Get_Pragma_Arg (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); Store_Note (N); for J in 1 .. 2 loop if Present (Args (J)) then Check_Arg_Is_OK_Static_Expression (Args (J), Standard_String); end if; end loop; end Title; ---------------------------- -- Type_Invariant[_Class] -- ---------------------------- -- pragma Type_Invariant[_Class] -- ([Entity =>] type_LOCAL_NAME, -- [Check =>] EXPRESSION); when Pragma_Type_Invariant | Pragma_Type_Invariant_Class => Type_Invariant : declare I_Pragma : Node_Id; begin Check_Arg_Count (2); -- Rewrite Type_Invariant[_Class] pragma as an Invariant pragma, -- setting Class_Present for the Type_Invariant_Class case. Set_Class_Present (N, Prag_Id = Pragma_Type_Invariant_Class); I_Pragma := New_Copy (N); Set_Pragma_Identifier (I_Pragma, Make_Identifier (Loc, Name_Invariant)); Rewrite (N, I_Pragma); Set_Analyzed (N, False); Analyze (N); end Type_Invariant; --------------------- -- 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 := Get_Pragma_Arg (Assoc); Clist : Node_Id; Comp : Node_Id; Tdef : Node_Id; Typ : Entity_Id; Variant : Node_Id; Vpart : Node_Id; begin Ada_2005_Pragma; Check_No_Identifiers; Check_Arg_Count (1); Check_Arg_Is_Local_Name (Arg1); Find_Type (Type_Id); Typ := Entity (Type_Id); -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Typ); 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 not Has_Discriminants (Typ) then Error_Msg_N ("unchecked union must have one discriminant", Typ); return; -- Note: in previous versions of GNAT we used to check for limited -- types and give an error, but in fact the standard does allow -- Unchecked_Union on limited types, so this check was removed. -- Similarly, GNAT used to require that all discriminants have -- default values, but this is not mandated by the RM. -- Proceed with basic error checks completed else Tdef := Type_Definition (Declaration_Node (Typ)); Clist := Component_List (Tdef); -- Check presence of component list and variant part if No (Clist) or else No (Variant_Part (Clist)) then Error_Msg_N ("unchecked union must have variant part", Tdef); return; end if; -- Check components Comp := First_Non_Pragma (Component_Items (Clist)); while Present (Comp) loop Check_Component (Comp, Typ); Next_Non_Pragma (Comp); end loop; -- Check variant part Vpart := Variant_Part (Clist); Variant := First_Non_Pragma (Variants (Vpart)); while Present (Variant) loop Check_Variant (Variant, Typ); Next_Non_Pragma (Variant); end loop; end if; Set_Is_Unchecked_Union (Typ); Set_Convention (Typ, Convention_C); Set_Has_Unchecked_Union (Base_Type (Typ)); Set_Is_Unchecked_Union (Base_Type (Typ)); end Unchecked_Union; ---------------------------- -- Unevaluated_Use_Of_Old -- ---------------------------- -- pragma Unevaluated_Use_Of_Old (Error | Warn | Allow); when Pragma_Unevaluated_Use_Of_Old => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Arg_Is_One_Of (Arg1, Name_Error, Name_Warn, Name_Allow); -- Suppress/Unsuppress can appear as a configuration pragma, or in -- a declarative part or a package spec. if not Is_Configuration_Pragma then Check_Is_In_Decl_Part_Or_Package_Spec; end if; -- Store proper setting of Uneval_Old Get_Name_String (Chars (Get_Pragma_Arg (Arg1))); Uneval_Old := Fold_Upper (Name_Buffer (1)); ------------------------ -- 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 supported in this configuration"); Write_Eol; raise Unrecoverable_Error; end if; end Unimplemented_Unit; ------------------------ -- Universal_Aliasing -- ------------------------ -- pragma Universal_Aliasing [([Entity =>] type_LOCAL_NAME)]; when Pragma_Universal_Aliasing => Universal_Alias : declare E : Entity_Id; E_Id : Node_Id; begin GNAT_Pragma; Check_Arg_Count (1); Check_Optional_Identifier (Arg2, Name_Entity); Check_Arg_Is_Local_Name (Arg1); E_Id := Get_Pragma_Arg (Arg1); if Etype (E_Id) = Any_Type then return; end if; E := Entity (E_Id); if not Is_Type (E) then Error_Pragma_Arg ("pragma% requires type", Arg1); end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, E); Set_Universal_Aliasing (Base_Type (E)); Record_Rep_Item (E, N); end Universal_Alias; -------------------- -- Universal_Data -- -------------------- -- pragma Universal_Data [(library_unit_NAME)]; when Pragma_Universal_Data => GNAT_Pragma; Error_Pragma ("??pragma% ignored (applies only to AAMP)"); ---------------- -- Unmodified -- ---------------- -- pragma Unmodified (LOCAL_NAME {, LOCAL_NAME}); when Pragma_Unmodified => Analyze_Unmodified_Or_Unused; ------------------ -- Unreferenced -- ------------------ -- pragma Unreferenced (LOCAL_NAME {, LOCAL_NAME}); -- or when used in a context clause: -- pragma Unreferenced (library_unit_NAME {, library_unit_NAME} when Pragma_Unreferenced => Analyze_Unreferenced_Or_Unused; -------------------------- -- Unreferenced_Objects -- -------------------------- -- pragma Unreferenced_Objects (LOCAL_NAME {, LOCAL_NAME}); when Pragma_Unreferenced_Objects => Unreferenced_Objects : declare Arg : Node_Id; Arg_Expr : Node_Id; Arg_Id : Entity_Id; Ghost_Error_Posted : Boolean := False; -- Flag set when an error concerning the illegal mix of Ghost and -- non-Ghost types is emitted. Ghost_Id : Entity_Id := Empty; -- The entity of the first Ghost type encountered while processing -- the arguments of the pragma. begin GNAT_Pragma; Check_At_Least_N_Arguments (1); Arg := Arg1; while Present (Arg) loop Check_No_Identifier (Arg); Check_Arg_Is_Local_Name (Arg); Arg_Expr := Get_Pragma_Arg (Arg); if Is_Entity_Name (Arg_Expr) then Arg_Id := Entity (Arg_Expr); if Is_Type (Arg_Id) then Set_Has_Pragma_Unreferenced_Objects (Arg_Id); -- A pragma that applies to a Ghost entity becomes Ghost -- for the purposes of legality checks and removal of -- ignored Ghost code. Mark_Ghost_Pragma (N, Arg_Id); -- Capture the entity of the first Ghost type being -- processed for error detection purposes. if Is_Ghost_Entity (Arg_Id) then if No (Ghost_Id) then Ghost_Id := Arg_Id; end if; -- Otherwise the type is non-Ghost. It is illegal to mix -- references to Ghost and non-Ghost entities -- (SPARK RM 6.9). elsif Present (Ghost_Id) and then not Ghost_Error_Posted then Ghost_Error_Posted := True; Error_Msg_Name_1 := Pname; Error_Msg_N ("pragma % cannot mention ghost and non-ghost types", N); Error_Msg_Sloc := Sloc (Ghost_Id); Error_Msg_NE ("\& # declared as ghost", N, Ghost_Id); Error_Msg_Sloc := Sloc (Arg_Id); Error_Msg_NE ("\& # declared as non-ghost", N, Arg_Id); end if; else Error_Pragma_Arg ("argument for pragma% must be type or subtype", Arg); end if; else Error_Pragma_Arg ("argument for pragma% must be type or subtype", Arg); end if; Next (Arg); end loop; end Unreferenced_Objects; ------------------------------ -- 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 => Ada_2005_Pragma; Process_Suppress_Unsuppress (Suppress_Case => False); ------------ -- Unused -- ------------ -- pragma Unused (LOCAL_NAME {, LOCAL_NAME}); when Pragma_Unused => Analyze_Unmodified_Or_Unused (Is_Unused => True); Analyze_Unreferenced_Or_Unused (Is_Unused => True); ------------------- -- 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 := Get_Pragma_Arg (Arg1); S : String_Id; C : Char_Code; begin GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; -- Pragma always active unless in CodePeer or GNATprove modes, -- which use a fixed configuration of validity checks. if not (CodePeer_Mode or GNATprove_Mode) then if Nkind (A) = N_String_Literal then S := Strval (A); declare Slen : constant Natural := Natural (String_Length (S)); Options : String (1 .. Slen); J : Positive; begin -- Couldn't we use a for loop here over Options'Range??? J := 1; loop C := Get_String_Char (S, Pos (J)); -- This is a weird test, it skips setting validity -- checks entirely if any element of S is out of -- range of Character, what is that about ??? 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 if; end Validity_Checks; -------------- -- Volatile -- -------------- -- pragma Volatile (LOCAL_NAME); when Pragma_Volatile => Process_Atomic_Independent_Shared_Volatile; ------------------------- -- Volatile_Components -- ------------------------- -- pragma Volatile_Components (array_LOCAL_NAME); -- Volatile is handled by the same circuit as Atomic_Components -------------------------- -- Volatile_Full_Access -- -------------------------- -- pragma Volatile_Full_Access (LOCAL_NAME); when Pragma_Volatile_Full_Access => GNAT_Pragma; Process_Atomic_Independent_Shared_Volatile; ----------------------- -- Volatile_Function -- ----------------------- -- pragma Volatile_Function [ (boolean_EXPRESSION) ]; when Pragma_Volatile_Function => Volatile_Function : declare Over_Id : Entity_Id; Spec_Id : Entity_Id; Subp_Decl : Node_Id; begin GNAT_Pragma; Check_No_Identifiers; Check_At_Most_N_Arguments (1); Subp_Decl := Find_Related_Declaration_Or_Body (N, Do_Checks => True); -- Generic subprogram if Nkind (Subp_Decl) = N_Generic_Subprogram_Declaration then null; -- Body acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body and then No (Corresponding_Spec (Subp_Decl)) then null; -- Body stub acts as spec elsif Nkind (Subp_Decl) = N_Subprogram_Body_Stub and then No (Corresponding_Spec_Of_Stub (Subp_Decl)) then null; -- Subprogram elsif Nkind (Subp_Decl) = N_Subprogram_Declaration then null; else Pragma_Misplaced; return; end if; Spec_Id := Unique_Defining_Entity (Subp_Decl); if not Ekind_In (Spec_Id, E_Function, E_Generic_Function) then Pragma_Misplaced; return; end if; -- A pragma that applies to a Ghost entity becomes Ghost for the -- purposes of legality checks and removal of ignored Ghost code. Mark_Ghost_Pragma (N, Spec_Id); -- Chain the pragma on the contract for completeness Add_Contract_Item (N, Spec_Id); -- The legality checks of pragma Volatile_Function are affected by -- the SPARK mode in effect. Analyze all pragmas in a specific -- order. Analyze_If_Present (Pragma_SPARK_Mode); -- A volatile function cannot override a non-volatile function -- (SPARK RM 7.1.2(15)). Overriding checks are usually performed -- in New_Overloaded_Entity, however at that point the pragma has -- not been processed yet. Over_Id := Overridden_Operation (Spec_Id); if Present (Over_Id) and then not Is_Volatile_Function (Over_Id) then Error_Msg_N ("incompatible volatile function values in effect", Spec_Id); Error_Msg_Sloc := Sloc (Over_Id); Error_Msg_N ("\& declared # with Volatile_Function value False", Spec_Id); Error_Msg_Sloc := Sloc (Spec_Id); Error_Msg_N ("\overridden # with Volatile_Function value True", Spec_Id); end if; -- Analyze the Boolean expression (if any) if Present (Arg1) then Check_Static_Boolean_Expression (Get_Pragma_Arg (Arg1)); end if; end Volatile_Function; ---------------------- -- Warning_As_Error -- ---------------------- -- pragma Warning_As_Error (static_string_EXPRESSION); when Pragma_Warning_As_Error => GNAT_Pragma; Check_Arg_Count (1); Check_No_Identifiers; Check_Valid_Configuration_Pragma; if not Is_Static_String_Expression (Arg1) then Error_Pragma_Arg ("argument of pragma% must be static string expression", Arg1); -- OK static string expression else Acquire_Warning_Match_String (Arg1); Warnings_As_Errors_Count := Warnings_As_Errors_Count + 1; Warnings_As_Errors (Warnings_As_Errors_Count) := new String'(Name_Buffer (1 .. Name_Len)); end if; -------------- -- Warnings -- -------------- -- pragma Warnings ([TOOL_NAME,] DETAILS [, REASON]); -- DETAILS ::= On | Off -- DETAILS ::= On | Off, local_NAME -- DETAILS ::= static_string_EXPRESSION -- DETAILS ::= On | Off, static_string_EXPRESSION -- TOOL_NAME ::= GNAT | GNATProve -- REASON ::= Reason => STRING_LITERAL {& STRING_LITERAL} -- Note: If the first argument matches an allowed tool name, it is -- always considered to be a tool name, even if there is a string -- variable of that name. -- Note if the second argument of DETAILS is a local_NAME then the -- second form is always understood. If the intention is to use -- the fourth form, then you can write NAME & "" to force the -- intepretation as a static_string_EXPRESSION. when Pragma_Warnings => Warnings : declare Reason : String_Id; begin GNAT_Pragma; Check_At_Least_N_Arguments (1); -- See if last argument is labeled Reason. If so, make sure we -- have a string literal or a concatenation of string literals, -- and acquire the REASON string. Then remove the REASON argument -- by decreasing Num_Args by one; Remaining processing looks only -- at first Num_Args arguments). declare Last_Arg : constant Node_Id := Last (Pragma_Argument_Associations (N)); begin if Nkind (Last_Arg) = N_Pragma_Argument_Association and then Chars (Last_Arg) = Name_Reason then Start_String; Get_Reason_String (Get_Pragma_Arg (Last_Arg)); Reason := End_String; Arg_Count := Arg_Count - 1; -- Not allowed in compiler units (bootstrap issues) Check_Compiler_Unit ("Reason for pragma Warnings", N); -- No REASON string, set null string as reason else Reason := Null_String_Id; end if; end; -- Now proceed with REASON taken care of and eliminated Check_No_Identifiers; -- If debug flag -gnatd.i is set, pragma is ignored if Debug_Flag_Dot_I then return; end if; -- Process various forms of the pragma declare Argx : constant Node_Id := Get_Pragma_Arg (Arg1); Shifted_Args : List_Id; begin -- See if first argument is a tool name, currently either -- GNAT or GNATprove. If so, either ignore the pragma if the -- tool used does not match, or continue as if no tool name -- was given otherwise, by shifting the arguments. if Nkind (Argx) = N_Identifier and then Nam_In (Chars (Argx), Name_Gnat, Name_Gnatprove) then if Chars (Argx) = Name_Gnat then if CodePeer_Mode or GNATprove_Mode or ASIS_Mode then Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); raise Pragma_Exit; end if; elsif Chars (Argx) = Name_Gnatprove then if not GNATprove_Mode then Rewrite (N, Make_Null_Statement (Loc)); Analyze (N); raise Pragma_Exit; end if; else raise Program_Error; end if; -- At this point, the pragma Warnings applies to the tool, -- so continue with shifted arguments. Arg_Count := Arg_Count - 1; if Arg_Count = 1 then Shifted_Args := New_List (New_Copy (Arg2)); elsif Arg_Count = 2 then Shifted_Args := New_List (New_Copy (Arg2), New_Copy (Arg3)); elsif Arg_Count = 3 then Shifted_Args := New_List (New_Copy (Arg2), New_Copy (Arg3), New_Copy (Arg4)); else raise Program_Error; end if; Rewrite (N, Make_Pragma (Loc, Chars => Name_Warnings, Pragma_Argument_Associations => Shifted_Args)); Analyze (N); raise Pragma_Exit; end if; -- One argument case if Arg_Count = 1 then -- On/Off one argument case was processed by parser if Nkind (Argx) = N_Identifier and then Nam_In (Chars (Argx), Name_On, Name_Off) then null; -- One argument case must be ON/OFF or static string expr elsif not Is_Static_String_Expression (Arg1) then Error_Pragma_Arg ("argument of pragma% must be On/Off or static string " & "expression", Arg1); -- One argument string expression case else declare Lit : constant Node_Id := Expr_Value_S (Argx); Str : constant String_Id := Strval (Lit); Len : constant Nat := String_Length (Str); C : Char_Code; J : Nat; OK : Boolean; Chr : Character; begin J := 1; while J <= Len loop C := Get_String_Char (Str, J); OK := In_Character_Range (C); if OK then Chr := Get_Character (C); -- Dash case: only -Wxxx is accepted if J = 1 and then J < Len and then Chr = '-' then J := J + 1; C := Get_String_Char (Str, J); Chr := Get_Character (C); exit when Chr = 'W'; OK := False; -- Dot case elsif J < Len and then Chr = '.' then J := J + 1; C := Get_String_Char (Str, J); Chr := Get_Character (C); if not Set_Dot_Warning_Switch (Chr) then Error_Pragma_Arg ("invalid warning switch character " & '.' & Chr, Arg1); end if; -- Non-Dot case else OK := Set_Warning_Switch (Chr); end if; if not OK then Error_Pragma_Arg ("invalid warning switch character " & Chr, Arg1); end if; else Error_Pragma_Arg ("invalid wide character in warning switch ", Arg1); end if; J := J + 1; end loop; end; end if; -- Two or more arguments (must be two) else Check_Arg_Is_One_Of (Arg1, Name_On, Name_Off); Check_Arg_Count (2); declare E_Id : Node_Id; E : Entity_Id; Err : Boolean; begin E_Id := Get_Pragma_Arg (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 In_Inlined_Body) and then Nkind (E_Id) = N_Unchecked_Type_Conversion then E_Id := Expression (E_Id); end if; -- Entity name case if Is_Entity_Name (E_Id) then E := Entity (E_Id); if E = Any_Id then return; else loop Set_Warnings_Off (E, (Chars (Get_Pragma_Arg (Arg1)) = Name_Off)); -- Suppress elaboration warnings if the entity -- denotes an elaboration target. if Is_Elaboration_Target (E) then Set_Is_Elaboration_Warnings_OK_Id (E, False); end if; -- For OFF case, make entry in warnings off -- pragma table for later processing. But we do -- not do that within an instance, since these -- warnings are about what is needed in the -- template, not an instance of it. if Chars (Get_Pragma_Arg (Arg1)) = Name_Off and then Warn_On_Warnings_Off and then not In_Instance then Warnings_Off_Pragmas.Append ((N, E, Reason)); end if; if Is_Enumeration_Type (E) then declare Lit : Entity_Id; begin Lit := First_Literal (E); 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; -- Error if not entity or static string expression case elsif not Is_Static_String_Expression (Arg2) then Error_Pragma_Arg ("second argument of pragma% must be entity name " & "or static string expression", Arg2); -- Static string expression case else Acquire_Warning_Match_String (Arg2); -- Note on configuration pragma case: If this is a -- configuration pragma, then for an OFF pragma, we -- just set Config True in the call, which is all -- that needs to be done. For the case of ON, this -- is normally an error, unless it is canceling the -- effect of a previous OFF pragma in the same file. -- In any other case, an error will be signalled (ON -- with no matching OFF). -- Note: We set Used if we are inside a generic to -- disable the test that the non-config case actually -- cancels a warning. That's because we can't be sure -- there isn't an instantiation in some other unit -- where a warning is suppressed. -- We could do a little better here by checking if the -- generic unit we are inside is public, but for now -- we don't bother with that refinement. if Chars (Argx) = Name_Off then Set_Specific_Warning_Off (Loc, Name_Buffer (1 .. Name_Len), Reason, Config => Is_Configuration_Pragma, Used => Inside_A_Generic or else In_Instance); elsif Chars (Argx) = Name_On then Set_Specific_Warning_On (Loc, Name_Buffer (1 .. Name_Len), Err); if Err then Error_Msg ("??pragma Warnings On with no matching " & "Warnings Off", Loc); end if; end if; end if; end; end if; end; 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 (Get_Pragma_Arg (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; ----------------------------- -- Wide_Character_Encoding -- ----------------------------- -- pragma Wide_Character_Encoding (IDENTIFIER); when Pragma_Wide_Character_Encoding => GNAT_Pragma; -- Nothing to do, handled in parser. Note that we do not enforce -- configuration pragma placement, this pragma can appear at any -- place in the source, allowing mixed encodings within a single -- source program. null; -------------------- -- 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; -- AI05-0144: detect dangerous order dependence. Disabled for now, -- until AI is formally approved. -- Check_Order_Dependence; exception when Pragma_Exit => null; end Analyze_Pragma; --------------------------------------------- -- Analyze_Pre_Post_Condition_In_Decl_Part -- --------------------------------------------- -- WARNING: This routine manages Ghost regions. Return statements must be -- replaced by gotos which jump to the end of the routine and restore the -- Ghost mode. procedure Analyze_Pre_Post_Condition_In_Decl_Part (N : Node_Id; Freeze_Id : Entity_Id := Empty) is Subp_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Subp_Decl); Disp_Typ : Entity_Id; -- The dispatching type of the subprogram subject to the pre- or -- postcondition. function Check_References (Nod : Node_Id) return Traverse_Result; -- Check that expression Nod does not mention non-primitives of the -- type, global objects of the type, or other illegalities described -- and implied by AI12-0113. ---------------------- -- Check_References -- ---------------------- function Check_References (Nod : Node_Id) return Traverse_Result is begin if Nkind (Nod) = N_Function_Call and then Is_Entity_Name (Name (Nod)) then declare Func : constant Entity_Id := Entity (Name (Nod)); Form : Entity_Id; begin -- An operation of the type must be a primitive if No (Find_Dispatching_Type (Func)) then Form := First_Formal (Func); while Present (Form) loop if Etype (Form) = Disp_Typ then Error_Msg_NE ("operation in class-wide condition must be " & "primitive of &", Nod, Disp_Typ); end if; Next_Formal (Form); end loop; -- A return object of the type is illegal as well if Etype (Func) = Disp_Typ or else Etype (Func) = Class_Wide_Type (Disp_Typ) then Error_Msg_NE ("operation in class-wide condition must be primitive " & "of &", Nod, Disp_Typ); end if; -- Otherwise we have a call to an overridden primitive, and we -- will create a common class-wide clone for the body of -- original operation and its eventual inherited versions. If -- the original operation dispatches on result it is never -- inherited and there is no need for a clone. There is not -- need for a clone either in GNATprove mode, as cases that -- would require it are rejected (when an inherited primitive -- calls an overridden operation in a class-wide contract), and -- the clone would make proof impossible in some cases. elsif not Is_Abstract_Subprogram (Spec_Id) and then No (Class_Wide_Clone (Spec_Id)) and then not Has_Controlling_Result (Spec_Id) and then not GNATprove_Mode then Build_Class_Wide_Clone_Decl (Spec_Id); end if; end; elsif Is_Entity_Name (Nod) and then (Etype (Nod) = Disp_Typ or else Etype (Nod) = Class_Wide_Type (Disp_Typ)) and then Ekind_In (Entity (Nod), E_Constant, E_Variable) then Error_Msg_NE ("object in class-wide condition must be formal of type &", Nod, Disp_Typ); elsif Nkind (Nod) = N_Explicit_Dereference and then (Etype (Nod) = Disp_Typ or else Etype (Nod) = Class_Wide_Type (Disp_Typ)) and then (not Is_Entity_Name (Prefix (Nod)) or else not Is_Formal (Entity (Prefix (Nod)))) then Error_Msg_NE ("operation in class-wide condition must be primitive of &", Nod, Disp_Typ); end if; return OK; end Check_References; procedure Check_Class_Wide_Condition is new Traverse_Proc (Check_References); -- Local variables Expr : constant Node_Id := Expression (Get_Argument (N, Spec_Id)); Saved_GM : constant Ghost_Mode_Type := Ghost_Mode; Saved_IGR : constant Node_Id := Ignored_Ghost_Region; -- Save the Ghost-related attributes to restore on exit Errors : Nat; Restore_Scope : Boolean := False; -- Start of processing for Analyze_Pre_Post_Condition_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Set the Ghost mode in effect from the pragma. Due to the delayed -- analysis of the pragma, the Ghost mode at point of declaration and -- point of analysis may not necessarily be the same. Use the mode in -- effect at the point of declaration. Set_Ghost_Mode (N); -- Ensure that the subprogram and its formals are visible when analyzing -- the expression of the pragma. if not In_Open_Scopes (Spec_Id) then Restore_Scope := True; Push_Scope (Spec_Id); if Is_Generic_Subprogram (Spec_Id) then Install_Generic_Formals (Spec_Id); else Install_Formals (Spec_Id); end if; end if; Errors := Serious_Errors_Detected; Preanalyze_Assert_Expression (Expr, Standard_Boolean); -- Emit a clarification message when the expression contains at least -- one undefined reference, possibly due to contract freezing. if Errors /= Serious_Errors_Detected and then Present (Freeze_Id) and then Has_Undefined_Reference (Expr) then Contract_Freeze_Error (Spec_Id, Freeze_Id); end if; if Class_Present (N) then -- Verify that a class-wide condition is legal, i.e. the operation is -- a primitive of a tagged type. Note that a generic subprogram is -- not a primitive operation. Disp_Typ := Find_Dispatching_Type (Spec_Id); if No (Disp_Typ) or else Is_Generic_Subprogram (Spec_Id) then Error_Msg_Name_1 := Original_Aspect_Pragma_Name (N); if From_Aspect_Specification (N) then Error_Msg_N ("aspect % can only be specified for a primitive operation " & "of a tagged type", Corresponding_Aspect (N)); -- The pragma is a source construct else Error_Msg_N ("pragma % can only be specified for a primitive operation " & "of a tagged type", N); end if; -- Remaining semantic checks require a full tree traversal else Check_Class_Wide_Condition (Expr); end if; end if; if Restore_Scope then End_Scope; end if; -- If analysis of the condition indicates that a class-wide clone -- has been created, build and analyze its declaration. if Is_Subprogram (Spec_Id) and then Present (Class_Wide_Clone (Spec_Id)) then Analyze (Unit_Declaration_Node (Class_Wide_Clone (Spec_Id))); end if; -- Currently it is not possible to inline pre/postconditions on a -- subprogram subject to pragma Inline_Always. Check_Postcondition_Use_In_Inlined_Subprogram (N, Spec_Id); Set_Is_Analyzed_Pragma (N); Restore_Ghost_Region (Saved_GM, Saved_IGR); end Analyze_Pre_Post_Condition_In_Decl_Part; ------------------------------------------ -- Analyze_Refined_Depends_In_Decl_Part -- ------------------------------------------ procedure Analyze_Refined_Depends_In_Decl_Part (N : Node_Id) is procedure Check_Dependency_Clause (Spec_Id : Entity_Id; Dep_Clause : Node_Id; Dep_States : Elist_Id; Refinements : List_Id; Matched_Items : in out Elist_Id); -- Try to match a single dependency clause Dep_Clause against one or -- more refinement clauses found in list Refinements. Each successful -- match eliminates at least one refinement clause from Refinements. -- Spec_Id denotes the entity of the related subprogram. Dep_States -- denotes the entities of all abstract states which appear in pragma -- Depends. Matched_Items contains the entities of all successfully -- matched items found in pragma Depends. procedure Check_Output_States (Spec_Id : Entity_Id; Spec_Inputs : Elist_Id; Spec_Outputs : Elist_Id; Body_Inputs : Elist_Id; Body_Outputs : Elist_Id); -- Determine whether pragma Depends contains an output state with a -- visible refinement and if so, ensure that pragma Refined_Depends -- mentions all its constituents as outputs. Spec_Id is the entity of -- the related subprograms. Spec_Inputs and Spec_Outputs denote the -- inputs and outputs of the subprogram spec synthesized from pragma -- Depends. Body_Inputs and Body_Outputs denote the inputs and outputs -- of the subprogram body synthesized from pragma Refined_Depends. function Collect_States (Clauses : List_Id) return Elist_Id; -- Given a normalized list of dependencies obtained from calling -- Normalize_Clauses, return a list containing the entities of all -- states appearing in dependencies. It helps in checking refinements -- involving a state and a corresponding constituent which is not a -- direct constituent of the state. procedure Normalize_Clauses (Clauses : List_Id); -- Given a list of dependence or refinement clauses Clauses, normalize -- each clause by creating multiple dependencies with exactly one input -- and one output. procedure Remove_Extra_Clauses (Clauses : List_Id; Matched_Items : Elist_Id); -- Given a list of refinement clauses Clauses, remove all clauses whose -- inputs and/or outputs have been previously matched. See the body for -- all special cases. Matched_Items contains the entities of all matched -- items found in pragma Depends. procedure Report_Extra_Clauses (Spec_Id : Entity_Id; Clauses : List_Id); -- Emit an error for each extra clause found in list Clauses. Spec_Id -- denotes the entity of the related subprogram. ----------------------------- -- Check_Dependency_Clause -- ----------------------------- procedure Check_Dependency_Clause (Spec_Id : Entity_Id; Dep_Clause : Node_Id; Dep_States : Elist_Id; Refinements : List_Id; Matched_Items : in out Elist_Id) is Dep_Input : constant Node_Id := Expression (Dep_Clause); Dep_Output : constant Node_Id := First (Choices (Dep_Clause)); function Is_Already_Matched (Dep_Item : Node_Id) return Boolean; -- Determine whether dependency item Dep_Item has been matched in a -- previous clause. function Is_In_Out_State_Clause return Boolean; -- Determine whether dependence clause Dep_Clause denotes an abstract -- state that depends on itself (State => State). function Is_Null_Refined_State (Item : Node_Id) return Boolean; -- Determine whether item Item denotes an abstract state with visible -- null refinement. procedure Match_Items (Dep_Item : Node_Id; Ref_Item : Node_Id; Matched : out Boolean); -- Try to match dependence item Dep_Item against refinement item -- Ref_Item. To match against a possible null refinement (see 2, 9), -- set Ref_Item to Empty. Flag Matched is set to True when one of -- the following conformance scenarios is in effect: -- 1) Both items denote null -- 2) Dep_Item denotes null and Ref_Item is Empty (special case) -- 3) Both items denote attribute 'Result -- 4) Both items denote the same object -- 5) Both items denote the same formal parameter -- 6) Both items denote the same current instance of a type -- 7) Both items denote the same discriminant -- 8) Dep_Item is an abstract state with visible null refinement -- and Ref_Item denotes null. -- 9) Dep_Item is an abstract state with visible null refinement -- and Ref_Item is Empty (special case). -- 10) Dep_Item is an abstract state with full or partial visible -- non-null refinement and Ref_Item denotes one of its -- constituents. -- 11) Dep_Item is an abstract state without a full visible -- refinement and Ref_Item denotes the same state. -- When scenario 10 is in effect, the entity of the abstract state -- denoted by Dep_Item is added to list Refined_States. procedure Record_Item (Item_Id : Entity_Id); -- Store the entity of an item denoted by Item_Id in Matched_Items ------------------------ -- Is_Already_Matched -- ------------------------ function Is_Already_Matched (Dep_Item : Node_Id) return Boolean is Item_Id : Entity_Id := Empty; begin -- When the dependency item denotes attribute 'Result, check for -- the entity of the related subprogram. if Is_Attribute_Result (Dep_Item) then Item_Id := Spec_Id; elsif Is_Entity_Name (Dep_Item) then Item_Id := Available_View (Entity_Of (Dep_Item)); end if; return Present (Item_Id) and then Contains (Matched_Items, Item_Id); end Is_Already_Matched; ---------------------------- -- Is_In_Out_State_Clause -- ---------------------------- function Is_In_Out_State_Clause return Boolean is Dep_Input_Id : Entity_Id; Dep_Output_Id : Entity_Id; begin -- Detect the following clause: -- State => State if Is_Entity_Name (Dep_Input) and then Is_Entity_Name (Dep_Output) then -- Handle abstract views generated for limited with clauses Dep_Input_Id := Available_View (Entity_Of (Dep_Input)); Dep_Output_Id := Available_View (Entity_Of (Dep_Output)); return Ekind (Dep_Input_Id) = E_Abstract_State and then Dep_Input_Id = Dep_Output_Id; else return False; end if; end Is_In_Out_State_Clause; --------------------------- -- Is_Null_Refined_State -- --------------------------- function Is_Null_Refined_State (Item : Node_Id) return Boolean is Item_Id : Entity_Id; begin if Is_Entity_Name (Item) then -- Handle abstract views generated for limited with clauses Item_Id := Available_View (Entity_Of (Item)); return Ekind (Item_Id) = E_Abstract_State and then Has_Null_Visible_Refinement (Item_Id); else return False; end if; end Is_Null_Refined_State; ----------------- -- Match_Items -- ----------------- procedure Match_Items (Dep_Item : Node_Id; Ref_Item : Node_Id; Matched : out Boolean) is Dep_Item_Id : Entity_Id; Ref_Item_Id : Entity_Id; begin -- Assume that the two items do not match Matched := False; -- A null matches null or Empty (special case) if Nkind (Dep_Item) = N_Null and then (No (Ref_Item) or else Nkind (Ref_Item) = N_Null) then Matched := True; -- Attribute 'Result matches attribute 'Result elsif Is_Attribute_Result (Dep_Item) and then Is_Attribute_Result (Ref_Item) then -- Put the entity of the related function on the list of -- matched items because attribute 'Result does not carry -- an entity similar to states and constituents. Record_Item (Spec_Id); Matched := True; -- Abstract states, current instances of concurrent types, -- discriminants, formal parameters and objects. elsif Is_Entity_Name (Dep_Item) then -- Handle abstract views generated for limited with clauses Dep_Item_Id := Available_View (Entity_Of (Dep_Item)); if Ekind (Dep_Item_Id) = E_Abstract_State then -- An abstract state with visible null refinement matches -- null or Empty (special case). if Has_Null_Visible_Refinement (Dep_Item_Id) and then (No (Ref_Item) or else Nkind (Ref_Item) = N_Null) then Record_Item (Dep_Item_Id); Matched := True; -- An abstract state with visible non-null refinement -- matches one of its constituents, or itself for an -- abstract state with partial visible refinement. elsif Has_Non_Null_Visible_Refinement (Dep_Item_Id) then if Is_Entity_Name (Ref_Item) then Ref_Item_Id := Entity_Of (Ref_Item); if Ekind_In (Ref_Item_Id, E_Abstract_State, E_Constant, E_Variable) and then Present (Encapsulating_State (Ref_Item_Id)) and then Find_Encapsulating_State (Dep_States, Ref_Item_Id) = Dep_Item_Id then Record_Item (Dep_Item_Id); Matched := True; elsif not Has_Visible_Refinement (Dep_Item_Id) and then Ref_Item_Id = Dep_Item_Id then Record_Item (Dep_Item_Id); Matched := True; end if; end if; -- An abstract state without a visible refinement matches -- itself. elsif Is_Entity_Name (Ref_Item) and then Entity_Of (Ref_Item) = Dep_Item_Id then Record_Item (Dep_Item_Id); Matched := True; end if; -- A current instance of a concurrent type, discriminant, -- formal parameter or an object matches itself. elsif Is_Entity_Name (Ref_Item) and then Entity_Of (Ref_Item) = Dep_Item_Id then Record_Item (Dep_Item_Id); Matched := True; end if; end if; end Match_Items; ----------------- -- Record_Item -- ----------------- procedure Record_Item (Item_Id : Entity_Id) is begin if No (Matched_Items) then Matched_Items := New_Elmt_List; end if; Append_Unique_Elmt (Item_Id, Matched_Items); end Record_Item; -- Local variables Clause_Matched : Boolean := False; Dummy : Boolean := False; Inputs_Match : Boolean; Next_Ref_Clause : Node_Id; Outputs_Match : Boolean; Ref_Clause : Node_Id; Ref_Input : Node_Id; Ref_Output : Node_Id; -- Start of processing for Check_Dependency_Clause begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then return; end if; -- Examine all refinement clauses and compare them against the -- dependence clause. Ref_Clause := First (Refinements); while Present (Ref_Clause) loop Next_Ref_Clause := Next (Ref_Clause); -- Obtain the attributes of the current refinement clause Ref_Input := Expression (Ref_Clause); Ref_Output := First (Choices (Ref_Clause)); -- The current refinement clause matches the dependence clause -- when both outputs match and both inputs match. See routine -- Match_Items for all possible conformance scenarios. -- Depends Dep_Output => Dep_Input -- ^ ^ -- match ? match ? -- v v -- Refined_Depends Ref_Output => Ref_Input Match_Items (Dep_Item => Dep_Input, Ref_Item => Ref_Input, Matched => Inputs_Match); Match_Items (Dep_Item => Dep_Output, Ref_Item => Ref_Output, Matched => Outputs_Match); -- An In_Out state clause may be matched against a refinement with -- a null input or null output as long as the non-null side of the -- relation contains a valid constituent of the In_Out_State. if Is_In_Out_State_Clause then -- Depends => (State => State) -- Refined_Depends => (null => Constit) -- OK if Inputs_Match and then not Outputs_Match and then Nkind (Ref_Output) = N_Null then Outputs_Match := True; end if; -- Depends => (State => State) -- Refined_Depends => (Constit => null) -- OK if not Inputs_Match and then Outputs_Match and then Nkind (Ref_Input) = N_Null then Inputs_Match := True; end if; end if; -- The current refinement clause is legally constructed following -- the rules in SPARK RM 7.2.5, therefore it can be removed from -- the pool of candidates. The seach continues because a single -- dependence clause may have multiple matching refinements. if Inputs_Match and Outputs_Match then Clause_Matched := True; Remove (Ref_Clause); end if; Ref_Clause := Next_Ref_Clause; end loop; -- Depending on the order or composition of refinement clauses, an -- In_Out state clause may not be directly refinable. -- Refined_State => (State => (Constit_1, Constit_2)) -- Depends => ((Output, State) => (Input, State)) -- Refined_Depends => (Constit_1 => Input, Output => Constit_2) -- Matching normalized clause (State => State) fails because there is -- no direct refinement capable of satisfying this relation. Another -- similar case arises when clauses (Constit_1 => Input) and (Output -- => Constit_2) are matched first, leaving no candidates for clause -- (State => State). Both scenarios are legal as long as one of the -- previous clauses mentioned a valid constituent of State. if not Clause_Matched and then Is_In_Out_State_Clause and then Is_Already_Matched (Dep_Input) then Clause_Matched := True; end if; -- A clause where the input is an abstract state with visible null -- refinement or a 'Result attribute is implicitly matched when the -- output has already been matched in a previous clause. -- Refined_State => (State => null) -- Depends => (Output => State) -- implicitly OK -- Refined_Depends => (Output => ...) -- Depends => (...'Result => State) -- implicitly OK -- Refined_Depends => (...'Result => ...) if not Clause_Matched and then Is_Null_Refined_State (Dep_Input) and then Is_Already_Matched (Dep_Output) then Clause_Matched := True; end if; -- A clause where the output is an abstract state with visible null -- refinement is implicitly matched when the input has already been -- matched in a previous clause. -- Refined_State => (State => null) -- Depends => (State => Input) -- implicitly OK -- Refined_Depends => (... => Input) if not Clause_Matched and then Is_Null_Refined_State (Dep_Output) and then Is_Already_Matched (Dep_Input) then Clause_Matched := True; end if; -- At this point either all refinement clauses have been examined or -- pragma Refined_Depends contains a solitary null. Only an abstract -- state with null refinement can possibly match these cases. -- Refined_State => (State => null) -- Depends => (State => null) -- Refined_Depends => null -- OK if not Clause_Matched then Match_Items (Dep_Item => Dep_Input, Ref_Item => Empty, Matched => Inputs_Match); Match_Items (Dep_Item => Dep_Output, Ref_Item => Empty, Matched => Outputs_Match); Clause_Matched := Inputs_Match and Outputs_Match; end if; -- If the contents of Refined_Depends are legal, then the current -- dependence clause should be satisfied either by an explicit match -- or by one of the special cases. if not Clause_Matched then SPARK_Msg_NE (Fix_Msg (Spec_Id, "dependence clause of subprogram & has no " & "matching refinement in body"), Dep_Clause, Spec_Id); end if; end Check_Dependency_Clause; ------------------------- -- Check_Output_States -- ------------------------- procedure Check_Output_States (Spec_Id : Entity_Id; Spec_Inputs : Elist_Id; Spec_Outputs : Elist_Id; Body_Inputs : Elist_Id; Body_Outputs : Elist_Id) is procedure Check_Constituent_Usage (State_Id : Entity_Id); -- Determine whether all constituents of state State_Id with full -- visible refinement are used as outputs in pragma Refined_Depends. -- Emit an error if this is not the case (SPARK RM 7.2.4(5)). ----------------------------- -- Check_Constituent_Usage -- ----------------------------- procedure Check_Constituent_Usage (State_Id : Entity_Id) is Constits : constant Elist_Id := Partial_Refinement_Constituents (State_Id); Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; Only_Partial : constant Boolean := not Has_Visible_Refinement (State_Id); Posted : Boolean := False; begin if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- Issue an error when a constituent of State_Id is used, -- and State_Id has only partial visible refinement -- (SPARK RM 7.2.4(3d)). if Only_Partial then if (Present (Body_Inputs) and then Appears_In (Body_Inputs, Constit_Id)) or else (Present (Body_Outputs) and then Appears_In (Body_Outputs, Constit_Id)) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % cannot be used in " & "dependence refinement", N, Constit_Id); Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_N ("\use state % instead", N); end if; -- The constituent acts as an input (SPARK RM 7.2.5(3)) elsif Present (Body_Inputs) and then Appears_In (Body_Inputs, Constit_Id) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % must act as output in " & "dependence refinement", N, Constit_Id); -- The constituent is altogether missing (SPARK RM 7.2.5(3)) elsif No (Body_Outputs) or else not Appears_In (Body_Outputs, Constit_Id) then if not Posted then Posted := True; SPARK_Msg_NE ("output state & must be replaced by all its " & "constituents in dependence refinement", N, State_Id); end if; SPARK_Msg_NE ("\constituent & is missing in output list", N, Constit_Id); end if; Next_Elmt (Constit_Elmt); end loop; end if; end Check_Constituent_Usage; -- Local variables Item : Node_Id; Item_Elmt : Elmt_Id; Item_Id : Entity_Id; -- Start of processing for Check_Output_States begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; -- Inspect the outputs of pragma Depends looking for a state with a -- visible refinement. elsif Present (Spec_Outputs) then Item_Elmt := First_Elmt (Spec_Outputs); while Present (Item_Elmt) loop Item := Node (Item_Elmt); -- Deal with the mixed nature of the input and output lists if Nkind (Item) = N_Defining_Identifier then Item_Id := Item; else Item_Id := Available_View (Entity_Of (Item)); end if; if Ekind (Item_Id) = E_Abstract_State then -- The state acts as an input-output, skip it if Present (Spec_Inputs) and then Appears_In (Spec_Inputs, Item_Id) then null; -- Ensure that all of the constituents are utilized as -- outputs in pragma Refined_Depends. elsif Has_Non_Null_Visible_Refinement (Item_Id) then Check_Constituent_Usage (Item_Id); end if; end if; Next_Elmt (Item_Elmt); end loop; end if; end Check_Output_States; -------------------- -- Collect_States -- -------------------- function Collect_States (Clauses : List_Id) return Elist_Id is procedure Collect_State (Item : Node_Id; States : in out Elist_Id); -- Add the entity of Item to list States when it denotes to a state ------------------- -- Collect_State -- ------------------- procedure Collect_State (Item : Node_Id; States : in out Elist_Id) is Id : Entity_Id; begin if Is_Entity_Name (Item) then Id := Entity_Of (Item); if Ekind (Id) = E_Abstract_State then if No (States) then States := New_Elmt_List; end if; Append_Unique_Elmt (Id, States); end if; end if; end Collect_State; -- Local variables Clause : Node_Id; Input : Node_Id; Output : Node_Id; States : Elist_Id := No_Elist; -- Start of processing for Collect_States begin Clause := First (Clauses); while Present (Clause) loop Input := Expression (Clause); Output := First (Choices (Clause)); Collect_State (Input, States); Collect_State (Output, States); Next (Clause); end loop; return States; end Collect_States; ----------------------- -- Normalize_Clauses -- ----------------------- procedure Normalize_Clauses (Clauses : List_Id) is procedure Normalize_Inputs (Clause : Node_Id); -- Normalize clause Clause by creating multiple clauses for each -- input item of Clause. It is assumed that Clause has exactly one -- output. The transformation is as follows: -- -- Output => (Input_1, Input_2) -- original -- -- Output => Input_1 -- normalizations -- Output => Input_2 procedure Normalize_Outputs (Clause : Node_Id); -- Normalize clause Clause by creating multiple clause for each -- output item of Clause. The transformation is as follows: -- -- (Output_1, Output_2) => Input -- original -- -- Output_1 => Input -- normalization -- Output_2 => Input ---------------------- -- Normalize_Inputs -- ---------------------- procedure Normalize_Inputs (Clause : Node_Id) is Inputs : constant Node_Id := Expression (Clause); Loc : constant Source_Ptr := Sloc (Clause); Output : constant List_Id := Choices (Clause); Last_Input : Node_Id; Input : Node_Id; New_Clause : Node_Id; Next_Input : Node_Id; begin -- Normalization is performed only when the original clause has -- more than one input. Multiple inputs appear as an aggregate. if Nkind (Inputs) = N_Aggregate then Last_Input := Last (Expressions (Inputs)); -- Create a new clause for each input Input := First (Expressions (Inputs)); while Present (Input) loop Next_Input := Next (Input); -- Unhook the current input from the original input list -- because it will be relocated to a new clause. Remove (Input); -- Special processing for the last input. At this point the -- original aggregate has been stripped down to one element. -- Replace the aggregate by the element itself. if Input = Last_Input then Rewrite (Inputs, Input); -- Generate a clause of the form: -- Output => Input else New_Clause := Make_Component_Association (Loc, Choices => New_Copy_List_Tree (Output), Expression => Input); -- The new clause contains replicated content that has -- already been analyzed, mark the clause as analyzed. Set_Analyzed (New_Clause); Insert_After (Clause, New_Clause); end if; Input := Next_Input; end loop; end if; end Normalize_Inputs; ----------------------- -- Normalize_Outputs -- ----------------------- procedure Normalize_Outputs (Clause : Node_Id) is Inputs : constant Node_Id := Expression (Clause); Loc : constant Source_Ptr := Sloc (Clause); Outputs : constant Node_Id := First (Choices (Clause)); Last_Output : Node_Id; New_Clause : Node_Id; Next_Output : Node_Id; Output : Node_Id; begin -- Multiple outputs appear as an aggregate. Nothing to do when -- the clause has exactly one output. if Nkind (Outputs) = N_Aggregate then Last_Output := Last (Expressions (Outputs)); -- Create a clause for each output. Note that each time a new -- clause is created, the original output list slowly shrinks -- until there is one item left. Output := First (Expressions (Outputs)); while Present (Output) loop Next_Output := Next (Output); -- Unhook the output from the original output list as it -- will be relocated to a new clause. Remove (Output); -- Special processing for the last output. At this point -- the original aggregate has been stripped down to one -- element. Replace the aggregate by the element itself. if Output = Last_Output then Rewrite (Outputs, Output); else -- Generate a clause of the form: -- (Output => Inputs) New_Clause := Make_Component_Association (Loc, Choices => New_List (Output), Expression => New_Copy_Tree (Inputs)); -- The new clause contains replicated content that has -- already been analyzed. There is not need to reanalyze -- them. Set_Analyzed (New_Clause); Insert_After (Clause, New_Clause); end if; Output := Next_Output; end loop; end if; end Normalize_Outputs; -- Local variables Clause : Node_Id; -- Start of processing for Normalize_Clauses begin Clause := First (Clauses); while Present (Clause) loop Normalize_Outputs (Clause); Next (Clause); end loop; Clause := First (Clauses); while Present (Clause) loop Normalize_Inputs (Clause); Next (Clause); end loop; end Normalize_Clauses; -------------------------- -- Remove_Extra_Clauses -- -------------------------- procedure Remove_Extra_Clauses (Clauses : List_Id; Matched_Items : Elist_Id) is Clause : Node_Id; Input : Node_Id; Input_Id : Entity_Id; Next_Clause : Node_Id; Output : Node_Id; State_Id : Entity_Id; begin Clause := First (Clauses); while Present (Clause) loop Next_Clause := Next (Clause); Input := Expression (Clause); Output := First (Choices (Clause)); -- Recognize a clause of the form -- null => Input -- where Input is a constituent of a state which was already -- successfully matched. This clause must be removed because it -- simply indicates that some of the constituents of the state -- are not used. -- Refined_State => (State => (Constit_1, Constit_2)) -- Depends => (Output => State) -- Refined_Depends => ((Output => Constit_1), -- State matched -- (null => Constit_2)) -- OK if Nkind (Output) = N_Null and then Is_Entity_Name (Input) then -- Handle abstract views generated for limited with clauses Input_Id := Available_View (Entity_Of (Input)); -- The input must be a constituent of a state if Ekind_In (Input_Id, E_Abstract_State, E_Constant, E_Variable) and then Present (Encapsulating_State (Input_Id)) then State_Id := Encapsulating_State (Input_Id); -- The state must have a non-null visible refinement and be -- matched in a previous clause. if Has_Non_Null_Visible_Refinement (State_Id) and then Contains (Matched_Items, State_Id) then Remove (Clause); end if; end if; -- Recognize a clause of the form -- Output => null -- where Output is an arbitrary item. This clause must be removed -- because a null input legitimately matches anything. elsif Nkind (Input) = N_Null then Remove (Clause); end if; Clause := Next_Clause; end loop; end Remove_Extra_Clauses; -------------------------- -- Report_Extra_Clauses -- -------------------------- procedure Report_Extra_Clauses (Spec_Id : Entity_Id; Clauses : List_Id) is Clause : Node_Id; begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; elsif Present (Clauses) then Clause := First (Clauses); while Present (Clause) loop SPARK_Msg_N ("unmatched or extra clause in dependence refinement", Clause); Next (Clause); end loop; end if; end Report_Extra_Clauses; -- Local variables Body_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Body_Id : constant Entity_Id := Defining_Entity (Body_Decl); Errors : constant Nat := Serious_Errors_Detected; Clause : Node_Id; Deps : Node_Id; Dummy : Boolean; Refs : Node_Id; Body_Inputs : Elist_Id := No_Elist; Body_Outputs : Elist_Id := No_Elist; -- The inputs and outputs of the subprogram body synthesized from pragma -- Refined_Depends. Dependencies : List_Id := No_List; Depends : Node_Id; -- The corresponding Depends pragma along with its clauses Matched_Items : Elist_Id := No_Elist; -- A list containing the entities of all successfully matched items -- found in pragma Depends. Refinements : List_Id := No_List; -- The clauses of pragma Refined_Depends Spec_Id : Entity_Id; -- The entity of the subprogram subject to pragma Refined_Depends Spec_Inputs : Elist_Id := No_Elist; Spec_Outputs : Elist_Id := No_Elist; -- The inputs and outputs of the subprogram spec synthesized from pragma -- Depends. States : Elist_Id := No_Elist; -- A list containing the entities of all states whose constituents -- appear in pragma Depends. -- Start of processing for Analyze_Refined_Depends_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; Spec_Id := Unique_Defining_Entity (Body_Decl); -- Use the anonymous object as the proper spec when Refined_Depends -- applies to the body of a single task type. The object carries the -- proper Chars as well as all non-refined versions of pragmas. if Is_Single_Concurrent_Type (Spec_Id) then Spec_Id := Anonymous_Object (Spec_Id); end if; Depends := Get_Pragma (Spec_Id, Pragma_Depends); -- Subprogram declarations lacks pragma Depends. Refined_Depends is -- rendered useless as there is nothing to refine (SPARK RM 7.2.5(2)). if No (Depends) then SPARK_Msg_NE (Fix_Msg (Spec_Id, "useless refinement, declaration of subprogram " & "& lacks aspect or pragma Depends"), N, Spec_Id); goto Leave; end if; Deps := Expression (Get_Argument (Depends, Spec_Id)); -- A null dependency relation renders the refinement useless because it -- cannot possibly mention abstract states with visible refinement. Note -- that the inverse is not true as states may be refined to null -- (SPARK RM 7.2.5(2)). if Nkind (Deps) = N_Null then SPARK_Msg_NE (Fix_Msg (Spec_Id, "useless refinement, subprogram & does not " & "depend on abstract state with visible refinement"), N, Spec_Id); goto Leave; end if; -- Analyze Refined_Depends as if it behaved as a regular pragma Depends. -- This ensures that the categorization of all refined dependency items -- is consistent with their role. Analyze_Depends_In_Decl_Part (N); -- Do not match dependencies against refinements if Refined_Depends is -- illegal to avoid emitting misleading error. if Serious_Errors_Detected = Errors then -- The related subprogram lacks pragma [Refined_]Global. Synthesize -- the inputs and outputs of the subprogram spec and body to verify -- the use of states with visible refinement and their constituents. if No (Get_Pragma (Spec_Id, Pragma_Global)) or else No (Get_Pragma (Body_Id, Pragma_Refined_Global)) then Collect_Subprogram_Inputs_Outputs (Subp_Id => Spec_Id, Synthesize => True, Subp_Inputs => Spec_Inputs, Subp_Outputs => Spec_Outputs, Global_Seen => Dummy); Collect_Subprogram_Inputs_Outputs (Subp_Id => Body_Id, Synthesize => True, Subp_Inputs => Body_Inputs, Subp_Outputs => Body_Outputs, Global_Seen => Dummy); -- For an output state with a visible refinement, ensure that all -- constituents appear as outputs in the dependency refinement. Check_Output_States (Spec_Id => Spec_Id, Spec_Inputs => Spec_Inputs, Spec_Outputs => Spec_Outputs, Body_Inputs => Body_Inputs, Body_Outputs => Body_Outputs); end if; -- Matching is disabled in ASIS because clauses are not normalized as -- this is a tree altering activity similar to expansion. if ASIS_Mode then goto Leave; end if; -- Multiple dependency clauses appear as component associations of an -- aggregate. Note that the clauses are copied because the algorithm -- modifies them and this should not be visible in Depends. pragma Assert (Nkind (Deps) = N_Aggregate); Dependencies := New_Copy_List_Tree (Component_Associations (Deps)); Normalize_Clauses (Dependencies); -- Gather all states which appear in Depends States := Collect_States (Dependencies); Refs := Expression (Get_Argument (N, Spec_Id)); if Nkind (Refs) = N_Null then Refinements := No_List; -- Multiple dependency clauses appear as component associations of an -- aggregate. Note that the clauses are copied because the algorithm -- modifies them and this should not be visible in Refined_Depends. else pragma Assert (Nkind (Refs) = N_Aggregate); Refinements := New_Copy_List_Tree (Component_Associations (Refs)); Normalize_Clauses (Refinements); end if; -- At this point the clauses of pragmas Depends and Refined_Depends -- have been normalized into simple dependencies between one output -- and one input. Examine all clauses of pragma Depends looking for -- matching clauses in pragma Refined_Depends. Clause := First (Dependencies); while Present (Clause) loop Check_Dependency_Clause (Spec_Id => Spec_Id, Dep_Clause => Clause, Dep_States => States, Refinements => Refinements, Matched_Items => Matched_Items); Next (Clause); end loop; -- Pragma Refined_Depends may contain multiple clarification clauses -- which indicate that certain constituents do not influence the data -- flow in any way. Such clauses must be removed as long as the state -- has been matched, otherwise they will be incorrectly flagged as -- unmatched. -- Refined_State => (State => (Constit_1, Constit_2)) -- Depends => (Output => State) -- Refined_Depends => ((Output => Constit_1), -- State matched -- (null => Constit_2)) -- must be removed Remove_Extra_Clauses (Refinements, Matched_Items); if Serious_Errors_Detected = Errors then Report_Extra_Clauses (Spec_Id, Refinements); end if; end if; <> Set_Is_Analyzed_Pragma (N); end Analyze_Refined_Depends_In_Decl_Part; ----------------------------------------- -- Analyze_Refined_Global_In_Decl_Part -- ----------------------------------------- procedure Analyze_Refined_Global_In_Decl_Part (N : Node_Id) is Global : Node_Id; -- The corresponding Global pragma Has_In_State : Boolean := False; Has_In_Out_State : Boolean := False; Has_Out_State : Boolean := False; Has_Proof_In_State : Boolean := False; -- These flags are set when the corresponding Global pragma has a state -- of mode Input, In_Out, Output or Proof_In respectively with a visible -- refinement. Has_Null_State : Boolean := False; -- This flag is set when the corresponding Global pragma has at least -- one state with a null refinement. In_Constits : Elist_Id := No_Elist; In_Out_Constits : Elist_Id := No_Elist; Out_Constits : Elist_Id := No_Elist; Proof_In_Constits : Elist_Id := No_Elist; -- These lists contain the entities of all Input, In_Out, Output and -- Proof_In constituents that appear in Refined_Global and participate -- in state refinement. In_Items : Elist_Id := No_Elist; In_Out_Items : Elist_Id := No_Elist; Out_Items : Elist_Id := No_Elist; Proof_In_Items : Elist_Id := No_Elist; -- These lists contain the entities of all Input, In_Out, Output and -- Proof_In items defined in the corresponding Global pragma. Repeat_Items : Elist_Id := No_Elist; -- A list of all global items without full visible refinement found -- in pragma Global. These states should be repeated in the global -- refinement (SPARK RM 7.2.4(3c)) unless they have a partial visible -- refinement, in which case they may be repeated (SPARK RM 7.2.4(3d)). Spec_Id : Entity_Id; -- The entity of the subprogram subject to pragma Refined_Global States : Elist_Id := No_Elist; -- A list of all states with full or partial visible refinement found in -- pragma Global. procedure Check_In_Out_States; -- Determine whether the corresponding Global pragma mentions In_Out -- states with visible refinement and if so, ensure that one of the -- following completions apply to the constituents of the state: -- 1) there is at least one constituent of mode In_Out -- 2) there is at least one Input and one Output constituent -- 3) not all constituents are present and one of them is of mode -- Output. -- This routine may remove elements from In_Constits, In_Out_Constits, -- Out_Constits and Proof_In_Constits. procedure Check_Input_States; -- Determine whether the corresponding Global pragma mentions Input -- states with visible refinement and if so, ensure that at least one of -- its constituents appears as an Input item in Refined_Global. -- This routine may remove elements from In_Constits, In_Out_Constits, -- Out_Constits and Proof_In_Constits. procedure Check_Output_States; -- Determine whether the corresponding Global pragma mentions Output -- states with visible refinement and if so, ensure that all of its -- constituents appear as Output items in Refined_Global. -- This routine may remove elements from In_Constits, In_Out_Constits, -- Out_Constits and Proof_In_Constits. procedure Check_Proof_In_States; -- Determine whether the corresponding Global pragma mentions Proof_In -- states with visible refinement and if so, ensure that at least one of -- its constituents appears as a Proof_In item in Refined_Global. -- This routine may remove elements from In_Constits, In_Out_Constits, -- Out_Constits and Proof_In_Constits. procedure Check_Refined_Global_List (List : Node_Id; Global_Mode : Name_Id := Name_Input); -- Verify the legality of a single global list declaration. Global_Mode -- denotes the current mode in effect. procedure Collect_Global_Items (List : Node_Id; Mode : Name_Id := Name_Input); -- Gather all Input, In_Out, Output and Proof_In items from node List -- and separate them in lists In_Items, In_Out_Items, Out_Items and -- Proof_In_Items. Flags Has_In_State, Has_In_Out_State, Has_Out_State -- and Has_Proof_In_State are set when there is at least one abstract -- state with full or partial visible refinement available in the -- corresponding mode. Flag Has_Null_State is set when at least state -- has a null refinement. Mode denotes the current global mode in -- effect. function Present_Then_Remove (List : Elist_Id; Item : Entity_Id) return Boolean; -- Search List for a particular entity Item. If Item has been found, -- remove it from List. This routine is used to strip lists In_Constits, -- In_Out_Constits and Out_Constits of valid constituents. procedure Present_Then_Remove (List : Elist_Id; Item : Entity_Id); -- Same as function Present_Then_Remove, but do not report the presence -- of Item in List. procedure Report_Extra_Constituents; -- Emit an error for each constituent found in lists In_Constits, -- In_Out_Constits and Out_Constits. procedure Report_Missing_Items; -- Emit an error for each global item not repeated found in list -- Repeat_Items. ------------------------- -- Check_In_Out_States -- ------------------------- procedure Check_In_Out_States is procedure Check_Constituent_Usage (State_Id : Entity_Id); -- Determine whether one of the following coverage scenarios is in -- effect: -- 1) there is at least one constituent of mode In_Out or Output -- 2) there is at least one pair of constituents with modes Input -- and Output, or Proof_In and Output. -- 3) there is at least one constituent of mode Output and not all -- constituents are present. -- If this is not the case, emit an error (SPARK RM 7.2.4(5)). ----------------------------- -- Check_Constituent_Usage -- ----------------------------- procedure Check_Constituent_Usage (State_Id : Entity_Id) is Constits : constant Elist_Id := Partial_Refinement_Constituents (State_Id); Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; Has_Missing : Boolean := False; In_Out_Seen : Boolean := False; Input_Seen : Boolean := False; Output_Seen : Boolean := False; Proof_In_Seen : Boolean := False; begin -- Process all the constituents of the state and note their modes -- within the global refinement. if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); if Present_Then_Remove (In_Constits, Constit_Id) then Input_Seen := True; elsif Present_Then_Remove (In_Out_Constits, Constit_Id) then In_Out_Seen := True; elsif Present_Then_Remove (Out_Constits, Constit_Id) then Output_Seen := True; elsif Present_Then_Remove (Proof_In_Constits, Constit_Id) then Proof_In_Seen := True; else Has_Missing := True; end if; Next_Elmt (Constit_Elmt); end loop; end if; -- An In_Out constituent is a valid completion if In_Out_Seen then null; -- A pair of one Input/Proof_In and one Output constituent is a -- valid completion. elsif (Input_Seen or Proof_In_Seen) and Output_Seen then null; elsif Output_Seen then -- A single Output constituent is a valid completion only when -- some of the other constituents are missing. if Has_Missing then null; -- Otherwise all constituents are of mode Output else SPARK_Msg_NE ("global refinement of state & must include at least one " & "constituent of mode `In_Out`, `Input`, or `Proof_In`", N, State_Id); end if; -- The state lacks a completion. When full refinement is visible, -- always emit an error (SPARK RM 7.2.4(3a)). When only partial -- refinement is visible, emit an error if the abstract state -- itself is not utilized (SPARK RM 7.2.4(3d)). In the case where -- both are utilized, Check_State_And_Constituent_Use. will issue -- the error. elsif not Input_Seen and then not In_Out_Seen and then not Output_Seen and then not Proof_In_Seen then if Has_Visible_Refinement (State_Id) or else Contains (Repeat_Items, State_Id) then SPARK_Msg_NE ("missing global refinement of state &", N, State_Id); end if; -- Otherwise the state has a malformed completion where at least -- one of the constituents has a different mode. else SPARK_Msg_NE ("global refinement of state & redefines the mode of its " & "constituents", N, State_Id); end if; end Check_Constituent_Usage; -- Local variables Item_Elmt : Elmt_Id; Item_Id : Entity_Id; -- Start of processing for Check_In_Out_States begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; -- Inspect the In_Out items of the corresponding Global pragma -- looking for a state with a visible refinement. elsif Has_In_Out_State and then Present (In_Out_Items) then Item_Elmt := First_Elmt (In_Out_Items); while Present (Item_Elmt) loop Item_Id := Node (Item_Elmt); -- Ensure that one of the three coverage variants is satisfied if Ekind (Item_Id) = E_Abstract_State and then Has_Non_Null_Visible_Refinement (Item_Id) then Check_Constituent_Usage (Item_Id); end if; Next_Elmt (Item_Elmt); end loop; end if; end Check_In_Out_States; ------------------------ -- Check_Input_States -- ------------------------ procedure Check_Input_States is procedure Check_Constituent_Usage (State_Id : Entity_Id); -- Determine whether at least one constituent of state State_Id with -- full or partial visible refinement is used and has mode Input. -- Ensure that the remaining constituents do not have In_Out or -- Output modes. Emit an error if this is not the case -- (SPARK RM 7.2.4(5)). ----------------------------- -- Check_Constituent_Usage -- ----------------------------- procedure Check_Constituent_Usage (State_Id : Entity_Id) is Constits : constant Elist_Id := Partial_Refinement_Constituents (State_Id); Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; In_Seen : Boolean := False; begin if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- At least one of the constituents appears as an Input if Present_Then_Remove (In_Constits, Constit_Id) then In_Seen := True; -- A Proof_In constituent can refine an Input state as long -- as there is at least one Input constituent present. elsif Present_Then_Remove (Proof_In_Constits, Constit_Id) then null; -- The constituent appears in the global refinement, but has -- mode In_Out or Output (SPARK RM 7.2.4(5)). elsif Present_Then_Remove (In_Out_Constits, Constit_Id) or else Present_Then_Remove (Out_Constits, Constit_Id) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % must have mode `Input` in " & "global refinement", N, Constit_Id); end if; Next_Elmt (Constit_Elmt); end loop; end if; -- Not one of the constituents appeared as Input. Always emit an -- error when the full refinement is visible (SPARK RM 7.2.4(3a)). -- When only partial refinement is visible, emit an error if the -- abstract state itself is not utilized (SPARK RM 7.2.4(3d)). In -- the case where both are utilized, an error will be issued in -- Check_State_And_Constituent_Use. if not In_Seen and then (Has_Visible_Refinement (State_Id) or else Contains (Repeat_Items, State_Id)) then SPARK_Msg_NE ("global refinement of state & must include at least one " & "constituent of mode `Input`", N, State_Id); end if; end Check_Constituent_Usage; -- Local variables Item_Elmt : Elmt_Id; Item_Id : Entity_Id; -- Start of processing for Check_Input_States begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; -- Inspect the Input items of the corresponding Global pragma looking -- for a state with a visible refinement. elsif Has_In_State and then Present (In_Items) then Item_Elmt := First_Elmt (In_Items); while Present (Item_Elmt) loop Item_Id := Node (Item_Elmt); -- When full refinement is visible, ensure that at least one of -- the constituents is utilized and is of mode Input. When only -- partial refinement is visible, ensure that either one of -- the constituents is utilized and is of mode Input, or the -- abstract state is repeated and no constituent is utilized. if Ekind (Item_Id) = E_Abstract_State and then Has_Non_Null_Visible_Refinement (Item_Id) then Check_Constituent_Usage (Item_Id); end if; Next_Elmt (Item_Elmt); end loop; end if; end Check_Input_States; ------------------------- -- Check_Output_States -- ------------------------- procedure Check_Output_States is procedure Check_Constituent_Usage (State_Id : Entity_Id); -- Determine whether all constituents of state State_Id with full -- visible refinement are used and have mode Output. Emit an error -- if this is not the case (SPARK RM 7.2.4(5)). ----------------------------- -- Check_Constituent_Usage -- ----------------------------- procedure Check_Constituent_Usage (State_Id : Entity_Id) is Constits : constant Elist_Id := Partial_Refinement_Constituents (State_Id); Only_Partial : constant Boolean := not Has_Visible_Refinement (State_Id); Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; Posted : Boolean := False; begin if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- Issue an error when a constituent of State_Id is utilized -- and State_Id has only partial visible refinement -- (SPARK RM 7.2.4(3d)). if Only_Partial then if Present_Then_Remove (Out_Constits, Constit_Id) or else Present_Then_Remove (In_Constits, Constit_Id) or else Present_Then_Remove (In_Out_Constits, Constit_Id) or else Present_Then_Remove (Proof_In_Constits, Constit_Id) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % cannot be used in global " & "refinement", N, Constit_Id); Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_N ("\use state % instead", N); end if; elsif Present_Then_Remove (Out_Constits, Constit_Id) then null; -- The constituent appears in the global refinement, but has -- mode Input, In_Out or Proof_In (SPARK RM 7.2.4(5)). elsif Present_Then_Remove (In_Constits, Constit_Id) or else Present_Then_Remove (In_Out_Constits, Constit_Id) or else Present_Then_Remove (Proof_In_Constits, Constit_Id) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % must have mode `Output` in " & "global refinement", N, Constit_Id); -- The constituent is altogether missing (SPARK RM 7.2.5(3)) else if not Posted then Posted := True; SPARK_Msg_NE ("`Output` state & must be replaced by all its " & "constituents in global refinement", N, State_Id); end if; SPARK_Msg_NE ("\constituent & is missing in output list", N, Constit_Id); end if; Next_Elmt (Constit_Elmt); end loop; end if; end Check_Constituent_Usage; -- Local variables Item_Elmt : Elmt_Id; Item_Id : Entity_Id; -- Start of processing for Check_Output_States begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; -- Inspect the Output items of the corresponding Global pragma -- looking for a state with a visible refinement. elsif Has_Out_State and then Present (Out_Items) then Item_Elmt := First_Elmt (Out_Items); while Present (Item_Elmt) loop Item_Id := Node (Item_Elmt); -- When full refinement is visible, ensure that all of the -- constituents are utilized and they have mode Output. When -- only partial refinement is visible, ensure that no -- constituent is utilized. if Ekind (Item_Id) = E_Abstract_State and then Has_Non_Null_Visible_Refinement (Item_Id) then Check_Constituent_Usage (Item_Id); end if; Next_Elmt (Item_Elmt); end loop; end if; end Check_Output_States; --------------------------- -- Check_Proof_In_States -- --------------------------- procedure Check_Proof_In_States is procedure Check_Constituent_Usage (State_Id : Entity_Id); -- Determine whether at least one constituent of state State_Id with -- full or partial visible refinement is used and has mode Proof_In. -- Ensure that the remaining constituents do not have Input, In_Out, -- or Output modes. Emit an error if this is not the case -- (SPARK RM 7.2.4(5)). ----------------------------- -- Check_Constituent_Usage -- ----------------------------- procedure Check_Constituent_Usage (State_Id : Entity_Id) is Constits : constant Elist_Id := Partial_Refinement_Constituents (State_Id); Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; Proof_In_Seen : Boolean := False; begin if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- At least one of the constituents appears as Proof_In if Present_Then_Remove (Proof_In_Constits, Constit_Id) then Proof_In_Seen := True; -- The constituent appears in the global refinement, but has -- mode Input, In_Out or Output (SPARK RM 7.2.4(5)). elsif Present_Then_Remove (In_Constits, Constit_Id) or else Present_Then_Remove (In_Out_Constits, Constit_Id) or else Present_Then_Remove (Out_Constits, Constit_Id) then Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("constituent & of state % must have mode `Proof_In` " & "in global refinement", N, Constit_Id); end if; Next_Elmt (Constit_Elmt); end loop; end if; -- Not one of the constituents appeared as Proof_In. Always emit -- an error when full refinement is visible (SPARK RM 7.2.4(3a)). -- When only partial refinement is visible, emit an error if the -- abstract state itself is not utilized (SPARK RM 7.2.4(3d)). In -- the case where both are utilized, an error will be issued by -- Check_State_And_Constituent_Use. if not Proof_In_Seen and then (Has_Visible_Refinement (State_Id) or else Contains (Repeat_Items, State_Id)) then SPARK_Msg_NE ("global refinement of state & must include at least one " & "constituent of mode `Proof_In`", N, State_Id); end if; end Check_Constituent_Usage; -- Local variables Item_Elmt : Elmt_Id; Item_Id : Entity_Id; -- Start of processing for Check_Proof_In_States begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; -- Inspect the Proof_In items of the corresponding Global pragma -- looking for a state with a visible refinement. elsif Has_Proof_In_State and then Present (Proof_In_Items) then Item_Elmt := First_Elmt (Proof_In_Items); while Present (Item_Elmt) loop Item_Id := Node (Item_Elmt); -- Ensure that at least one of the constituents is utilized -- and is of mode Proof_In. When only partial refinement is -- visible, ensure that either one of the constituents is -- utilized and is of mode Proof_In, or the abstract state -- is repeated and no constituent is utilized. if Ekind (Item_Id) = E_Abstract_State and then Has_Non_Null_Visible_Refinement (Item_Id) then Check_Constituent_Usage (Item_Id); end if; Next_Elmt (Item_Elmt); end loop; end if; end Check_Proof_In_States; ------------------------------- -- Check_Refined_Global_List -- ------------------------------- procedure Check_Refined_Global_List (List : Node_Id; Global_Mode : Name_Id := Name_Input) is procedure Check_Refined_Global_Item (Item : Node_Id; Global_Mode : Name_Id); -- Verify the legality of a single global item declaration. Parameter -- Global_Mode denotes the current mode in effect. ------------------------------- -- Check_Refined_Global_Item -- ------------------------------- procedure Check_Refined_Global_Item (Item : Node_Id; Global_Mode : Name_Id) is Item_Id : constant Entity_Id := Entity_Of (Item); procedure Inconsistent_Mode_Error (Expect : Name_Id); -- Issue a common error message for all mode mismatches. Expect -- denotes the expected mode. ----------------------------- -- Inconsistent_Mode_Error -- ----------------------------- procedure Inconsistent_Mode_Error (Expect : Name_Id) is begin SPARK_Msg_NE ("global item & has inconsistent modes", Item, Item_Id); Error_Msg_Name_1 := Global_Mode; Error_Msg_Name_2 := Expect; SPARK_Msg_N ("\expected mode %, found mode %", Item); end Inconsistent_Mode_Error; -- Local variables Enc_State : Entity_Id := Empty; -- Encapsulating state for constituent, Empty otherwise -- Start of processing for Check_Refined_Global_Item begin if Ekind_In (Item_Id, E_Abstract_State, E_Constant, E_Variable) then Enc_State := Find_Encapsulating_State (States, Item_Id); end if; -- When the state or object acts as a constituent of another -- state with a visible refinement, collect it for the state -- completeness checks performed later on. Note that the item -- acts as a constituent only when the encapsulating state is -- present in pragma Global. if Present (Enc_State) and then (Has_Visible_Refinement (Enc_State) or else Has_Partial_Visible_Refinement (Enc_State)) and then Contains (States, Enc_State) then -- If the state has only partial visible refinement, remove it -- from the list of items that should be repeated from pragma -- Global. if not Has_Visible_Refinement (Enc_State) then Present_Then_Remove (Repeat_Items, Enc_State); end if; if Global_Mode = Name_Input then Append_New_Elmt (Item_Id, In_Constits); elsif Global_Mode = Name_In_Out then Append_New_Elmt (Item_Id, In_Out_Constits); elsif Global_Mode = Name_Output then Append_New_Elmt (Item_Id, Out_Constits); elsif Global_Mode = Name_Proof_In then Append_New_Elmt (Item_Id, Proof_In_Constits); end if; -- When not a constituent, ensure that both occurrences of the -- item in pragmas Global and Refined_Global match. Also remove -- it when present from the list of items that should be repeated -- from pragma Global. else Present_Then_Remove (Repeat_Items, Item_Id); if Contains (In_Items, Item_Id) then if Global_Mode /= Name_Input then Inconsistent_Mode_Error (Name_Input); end if; elsif Contains (In_Out_Items, Item_Id) then if Global_Mode /= Name_In_Out then Inconsistent_Mode_Error (Name_In_Out); end if; elsif Contains (Out_Items, Item_Id) then if Global_Mode /= Name_Output then Inconsistent_Mode_Error (Name_Output); end if; elsif Contains (Proof_In_Items, Item_Id) then null; -- The item does not appear in the corresponding Global pragma, -- it must be an extra (SPARK RM 7.2.4(3)). else pragma Assert (Present (Global)); Error_Msg_Sloc := Sloc (Global); SPARK_Msg_NE ("extra global item & does not refine or " & "repeat any global item #", Item, Item_Id); end if; end if; end Check_Refined_Global_Item; -- Local variables Item : Node_Id; -- Start of processing for Check_Refined_Global_List begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; elsif Nkind (List) = N_Null then null; -- Single global item declaration elsif Nkind_In (List, N_Expanded_Name, N_Identifier, N_Selected_Component) then Check_Refined_Global_Item (List, Global_Mode); -- Simple global list or moded global list declaration elsif Nkind (List) = N_Aggregate then -- The declaration of a simple global list appear as a collection -- of expressions. if Present (Expressions (List)) then Item := First (Expressions (List)); while Present (Item) loop Check_Refined_Global_Item (Item, Global_Mode); Next (Item); end loop; -- The declaration of a moded global list appears as a collection -- of component associations where individual choices denote -- modes. elsif Present (Component_Associations (List)) then Item := First (Component_Associations (List)); while Present (Item) loop Check_Refined_Global_List (List => Expression (Item), Global_Mode => Chars (First (Choices (Item)))); Next (Item); end loop; -- Invalid tree else raise Program_Error; end if; -- Invalid list else raise Program_Error; end if; end Check_Refined_Global_List; -------------------------- -- Collect_Global_Items -- -------------------------- procedure Collect_Global_Items (List : Node_Id; Mode : Name_Id := Name_Input) is procedure Collect_Global_Item (Item : Node_Id; Item_Mode : Name_Id); -- Add a single item to the appropriate list. Item_Mode denotes the -- current mode in effect. ------------------------- -- Collect_Global_Item -- ------------------------- procedure Collect_Global_Item (Item : Node_Id; Item_Mode : Name_Id) is Item_Id : constant Entity_Id := Available_View (Entity_Of (Item)); -- The above handles abstract views of variables and states built -- for limited with clauses. begin -- Signal that the global list contains at least one abstract -- state with a visible refinement. Note that the refinement may -- be null in which case there are no constituents. if Ekind (Item_Id) = E_Abstract_State then if Has_Null_Visible_Refinement (Item_Id) then Has_Null_State := True; elsif Has_Non_Null_Visible_Refinement (Item_Id) then Append_New_Elmt (Item_Id, States); if Item_Mode = Name_Input then Has_In_State := True; elsif Item_Mode = Name_In_Out then Has_In_Out_State := True; elsif Item_Mode = Name_Output then Has_Out_State := True; elsif Item_Mode = Name_Proof_In then Has_Proof_In_State := True; end if; end if; end if; -- Record global items without full visible refinement found in -- pragma Global which should be repeated in the global refinement -- (SPARK RM 7.2.4(3c), SPARK RM 7.2.4(3d)). if Ekind (Item_Id) /= E_Abstract_State or else not Has_Visible_Refinement (Item_Id) then Append_New_Elmt (Item_Id, Repeat_Items); end if; -- Add the item to the proper list if Item_Mode = Name_Input then Append_New_Elmt (Item_Id, In_Items); elsif Item_Mode = Name_In_Out then Append_New_Elmt (Item_Id, In_Out_Items); elsif Item_Mode = Name_Output then Append_New_Elmt (Item_Id, Out_Items); elsif Item_Mode = Name_Proof_In then Append_New_Elmt (Item_Id, Proof_In_Items); end if; end Collect_Global_Item; -- Local variables Item : Node_Id; -- Start of processing for Collect_Global_Items begin if Nkind (List) = N_Null then null; -- Single global item declaration elsif Nkind_In (List, N_Expanded_Name, N_Identifier, N_Selected_Component) then Collect_Global_Item (List, Mode); -- Single global list or moded global list declaration elsif Nkind (List) = N_Aggregate then -- The declaration of a simple global list appear as a collection -- of expressions. if Present (Expressions (List)) then Item := First (Expressions (List)); while Present (Item) loop Collect_Global_Item (Item, Mode); Next (Item); end loop; -- The declaration of a moded global list appears as a collection -- of component associations where individual choices denote mode. elsif Present (Component_Associations (List)) then Item := First (Component_Associations (List)); while Present (Item) loop Collect_Global_Items (List => Expression (Item), Mode => Chars (First (Choices (Item)))); Next (Item); end loop; -- Invalid tree else raise Program_Error; end if; -- To accommodate partial decoration of disabled SPARK features, this -- routine may be called with illegal input. If this is the case, do -- not raise Program_Error. else null; end if; end Collect_Global_Items; ------------------------- -- Present_Then_Remove -- ------------------------- function Present_Then_Remove (List : Elist_Id; Item : Entity_Id) return Boolean is Elmt : Elmt_Id; begin if Present (List) then Elmt := First_Elmt (List); while Present (Elmt) loop if Node (Elmt) = Item then Remove_Elmt (List, Elmt); return True; end if; Next_Elmt (Elmt); end loop; end if; return False; end Present_Then_Remove; procedure Present_Then_Remove (List : Elist_Id; Item : Entity_Id) is Ignore : Boolean; begin Ignore := Present_Then_Remove (List, Item); end Present_Then_Remove; ------------------------------- -- Report_Extra_Constituents -- ------------------------------- procedure Report_Extra_Constituents is procedure Report_Extra_Constituents_In_List (List : Elist_Id); -- Emit an error for every element of List --------------------------------------- -- Report_Extra_Constituents_In_List -- --------------------------------------- procedure Report_Extra_Constituents_In_List (List : Elist_Id) is Constit_Elmt : Elmt_Id; begin if Present (List) then Constit_Elmt := First_Elmt (List); while Present (Constit_Elmt) loop SPARK_Msg_NE ("extra constituent &", N, Node (Constit_Elmt)); Next_Elmt (Constit_Elmt); end loop; end if; end Report_Extra_Constituents_In_List; -- Start of processing for Report_Extra_Constituents begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; else Report_Extra_Constituents_In_List (In_Constits); Report_Extra_Constituents_In_List (In_Out_Constits); Report_Extra_Constituents_In_List (Out_Constits); Report_Extra_Constituents_In_List (Proof_In_Constits); end if; end Report_Extra_Constituents; -------------------------- -- Report_Missing_Items -- -------------------------- procedure Report_Missing_Items is Item_Elmt : Elmt_Id; Item_Id : Entity_Id; begin -- Do not perform this check in an instance because it was already -- performed successfully in the generic template. if Is_Generic_Instance (Spec_Id) then null; else if Present (Repeat_Items) then Item_Elmt := First_Elmt (Repeat_Items); while Present (Item_Elmt) loop Item_Id := Node (Item_Elmt); SPARK_Msg_NE ("missing global item &", N, Item_Id); Next_Elmt (Item_Elmt); end loop; end if; end if; end Report_Missing_Items; -- Local variables Body_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Errors : constant Nat := Serious_Errors_Detected; Items : Node_Id; No_Constit : Boolean; -- Start of processing for Analyze_Refined_Global_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; Spec_Id := Unique_Defining_Entity (Body_Decl); -- Use the anonymous object as the proper spec when Refined_Global -- applies to the body of a single task type. The object carries the -- proper Chars as well as all non-refined versions of pragmas. if Is_Single_Concurrent_Type (Spec_Id) then Spec_Id := Anonymous_Object (Spec_Id); end if; Global := Get_Pragma (Spec_Id, Pragma_Global); Items := Expression (Get_Argument (N, Spec_Id)); -- The subprogram declaration lacks pragma Global. This renders -- Refined_Global useless as there is nothing to refine. if No (Global) then SPARK_Msg_NE (Fix_Msg (Spec_Id, "useless refinement, declaration of subprogram " & "& lacks aspect or pragma Global"), N, Spec_Id); goto Leave; end if; -- Extract all relevant items from the corresponding Global pragma Collect_Global_Items (Expression (Get_Argument (Global, Spec_Id))); -- Package and subprogram bodies are instantiated individually in -- a separate compiler pass. Due to this mode of instantiation, the -- refinement of a state may no longer be visible when a subprogram -- body contract is instantiated. Since the generic template is legal, -- do not perform this check in the instance to circumvent this oddity. if Is_Generic_Instance (Spec_Id) then null; -- Non-instance case else -- The corresponding Global pragma must mention at least one -- state with a visible refinement at the point Refined_Global -- is processed. States with null refinements need Refined_Global -- pragma (SPARK RM 7.2.4(2)). if not Has_In_State and then not Has_In_Out_State and then not Has_Out_State and then not Has_Proof_In_State and then not Has_Null_State then SPARK_Msg_NE (Fix_Msg (Spec_Id, "useless refinement, subprogram & does not " & "depend on abstract state with visible refinement"), N, Spec_Id); goto Leave; -- The global refinement of inputs and outputs cannot be null when -- the corresponding Global pragma contains at least one item except -- in the case where we have states with null refinements. elsif Nkind (Items) = N_Null and then (Present (In_Items) or else Present (In_Out_Items) or else Present (Out_Items) or else Present (Proof_In_Items)) and then not Has_Null_State then SPARK_Msg_NE (Fix_Msg (Spec_Id, "refinement cannot be null, subprogram & has " & "global items"), N, Spec_Id); goto Leave; end if; end if; -- Analyze Refined_Global as if it behaved as a regular pragma Global. -- This ensures that the categorization of all refined global items is -- consistent with their role. Analyze_Global_In_Decl_Part (N); -- Perform all refinement checks with respect to completeness and mode -- matching. if Serious_Errors_Detected = Errors then Check_Refined_Global_List (Items); end if; -- Store the information that no constituent is used in the global -- refinement, prior to calling checking procedures which remove items -- from the list of constituents. No_Constit := No (In_Constits) and then No (In_Out_Constits) and then No (Out_Constits) and then No (Proof_In_Constits); -- For Input states with visible refinement, at least one constituent -- must be used as an Input in the global refinement. if Serious_Errors_Detected = Errors then Check_Input_States; end if; -- Verify all possible completion variants for In_Out states with -- visible refinement. if Serious_Errors_Detected = Errors then Check_In_Out_States; end if; -- For Output states with visible refinement, all constituents must be -- used as Outputs in the global refinement. if Serious_Errors_Detected = Errors then Check_Output_States; end if; -- For Proof_In states with visible refinement, at least one constituent -- must be used as Proof_In in the global refinement. if Serious_Errors_Detected = Errors then Check_Proof_In_States; end if; -- Emit errors for all constituents that belong to other states with -- visible refinement that do not appear in Global. if Serious_Errors_Detected = Errors then Report_Extra_Constituents; end if; -- Emit errors for all items in Global that are not repeated in the -- global refinement and for which there is no full visible refinement -- and, in the case of states with partial visible refinement, no -- constituent is mentioned in the global refinement. if Serious_Errors_Detected = Errors then Report_Missing_Items; end if; -- Emit an error if no constituent is used in the global refinement -- (SPARK RM 7.2.4(3f)). Emit this error last, in case a more precise -- one may be issued by the checking procedures. Do not perform this -- check in an instance because it was already performed successfully -- in the generic template. if Serious_Errors_Detected = Errors and then not Is_Generic_Instance (Spec_Id) and then not Has_Null_State and then No_Constit then SPARK_Msg_N ("missing refinement", N); end if; <> Set_Is_Analyzed_Pragma (N); end Analyze_Refined_Global_In_Decl_Part; ---------------------------------------- -- Analyze_Refined_State_In_Decl_Part -- ---------------------------------------- procedure Analyze_Refined_State_In_Decl_Part (N : Node_Id; Freeze_Id : Entity_Id := Empty) is Body_Decl : constant Node_Id := Find_Related_Package_Or_Body (N); Body_Id : constant Entity_Id := Defining_Entity (Body_Decl); Spec_Id : constant Entity_Id := Corresponding_Spec (Body_Decl); Available_States : Elist_Id := No_Elist; -- A list of all abstract states defined in the package declaration that -- are available for refinement. The list is used to report unrefined -- states. Body_States : Elist_Id := No_Elist; -- A list of all hidden states that appear in the body of the related -- package. The list is used to report unused hidden states. Constituents_Seen : Elist_Id := No_Elist; -- A list that contains all constituents processed so far. The list is -- used to detect multiple uses of the same constituent. Freeze_Posted : Boolean := False; -- A flag that controls the output of a freezing-related error (see use -- below). Refined_States_Seen : Elist_Id := No_Elist; -- A list that contains all refined states processed so far. The list is -- used to detect duplicate refinements. procedure Analyze_Refinement_Clause (Clause : Node_Id); -- Perform full analysis of a single refinement clause procedure Report_Unrefined_States (States : Elist_Id); -- Emit errors for all unrefined abstract states found in list States ------------------------------- -- Analyze_Refinement_Clause -- ------------------------------- procedure Analyze_Refinement_Clause (Clause : Node_Id) is AR_Constit : Entity_Id := Empty; AW_Constit : Entity_Id := Empty; ER_Constit : Entity_Id := Empty; EW_Constit : Entity_Id := Empty; -- The entities of external constituents that contain one of the -- following enabled properties: Async_Readers, Async_Writers, -- Effective_Reads and Effective_Writes. External_Constit_Seen : Boolean := False; -- Flag used to mark when at least one external constituent is part -- of the state refinement. Non_Null_Seen : Boolean := False; Null_Seen : Boolean := False; -- Flags used to detect multiple uses of null in a single clause or a -- mixture of null and non-null constituents. Part_Of_Constits : Elist_Id := No_Elist; -- A list of all candidate constituents subject to indicator Part_Of -- where the encapsulating state is the current state. State : Node_Id; State_Id : Entity_Id; -- The current state being refined procedure Analyze_Constituent (Constit : Node_Id); -- Perform full analysis of a single constituent procedure Check_External_Property (Prop_Nam : Name_Id; Enabled : Boolean; Constit : Entity_Id); -- Determine whether a property denoted by name Prop_Nam is present -- in the refined state. Emit an error if this is not the case. Flag -- Enabled should be set when the property applies to the refined -- state. Constit denotes the constituent (if any) which introduces -- the property in the refinement. procedure Match_State; -- Determine whether the state being refined appears in list -- Available_States. Emit an error when attempting to re-refine the -- state or when the state is not defined in the package declaration, -- otherwise remove the state from Available_States. procedure Report_Unused_Constituents (Constits : Elist_Id); -- Emit errors for all unused Part_Of constituents in list Constits ------------------------- -- Analyze_Constituent -- ------------------------- procedure Analyze_Constituent (Constit : Node_Id) is procedure Match_Constituent (Constit_Id : Entity_Id); -- Determine whether constituent Constit denoted by its entity -- Constit_Id appears in Body_States. Emit an error when the -- constituent is not a valid hidden state of the related package -- or when it is used more than once. Otherwise remove the -- constituent from Body_States. ----------------------- -- Match_Constituent -- ----------------------- procedure Match_Constituent (Constit_Id : Entity_Id) is procedure Collect_Constituent; -- Verify the legality of constituent Constit_Id and add it to -- the refinements of State_Id. ------------------------- -- Collect_Constituent -- ------------------------- procedure Collect_Constituent is Constits : Elist_Id; begin -- The Ghost policy in effect at the point of abstract state -- declaration and constituent must match (SPARK RM 6.9(15)) Check_Ghost_Refinement (State, State_Id, Constit, Constit_Id); -- A synchronized state must be refined by a synchronized -- object or another synchronized state (SPARK RM 9.6). if Is_Synchronized_State (State_Id) and then not Is_Synchronized_Object (Constit_Id) and then not Is_Synchronized_State (Constit_Id) then SPARK_Msg_NE ("constituent of synchronized state & must be " & "synchronized", Constit, State_Id); end if; -- Add the constituent to the list of processed items to aid -- with the detection of duplicates. Append_New_Elmt (Constit_Id, Constituents_Seen); -- Collect the constituent in the list of refinement items -- and establish a relation between the refined state and -- the item. Constits := Refinement_Constituents (State_Id); if No (Constits) then Constits := New_Elmt_List; Set_Refinement_Constituents (State_Id, Constits); end if; Append_Elmt (Constit_Id, Constits); Set_Encapsulating_State (Constit_Id, State_Id); -- The state has at least one legal constituent, mark the -- start of the refinement region. The region ends when the -- body declarations end (see routine Analyze_Declarations). Set_Has_Visible_Refinement (State_Id); -- When the constituent is external, save its relevant -- property for further checks. if Async_Readers_Enabled (Constit_Id) then AR_Constit := Constit_Id; External_Constit_Seen := True; end if; if Async_Writers_Enabled (Constit_Id) then AW_Constit := Constit_Id; External_Constit_Seen := True; end if; if Effective_Reads_Enabled (Constit_Id) then ER_Constit := Constit_Id; External_Constit_Seen := True; end if; if Effective_Writes_Enabled (Constit_Id) then EW_Constit := Constit_Id; External_Constit_Seen := True; end if; end Collect_Constituent; -- Local variables State_Elmt : Elmt_Id; -- Start of processing for Match_Constituent begin -- Detect a duplicate use of a constituent if Contains (Constituents_Seen, Constit_Id) then SPARK_Msg_NE ("duplicate use of constituent &", Constit, Constit_Id); return; end if; -- The constituent is subject to a Part_Of indicator if Present (Encapsulating_State (Constit_Id)) then if Encapsulating_State (Constit_Id) = State_Id then Remove (Part_Of_Constits, Constit_Id); Collect_Constituent; -- The constituent is part of another state and is used -- incorrectly in the refinement of the current state. else Error_Msg_Name_1 := Chars (State_Id); SPARK_Msg_NE ("& cannot act as constituent of state %", Constit, Constit_Id); SPARK_Msg_NE ("\Part_Of indicator specifies encapsulator &", Constit, Encapsulating_State (Constit_Id)); end if; -- The only other source of legal constituents is the body -- state space of the related package. else if Present (Body_States) then State_Elmt := First_Elmt (Body_States); while Present (State_Elmt) loop -- Consume a valid constituent to signal that it has -- been encountered. if Node (State_Elmt) = Constit_Id then Remove_Elmt (Body_States, State_Elmt); Collect_Constituent; return; end if; Next_Elmt (State_Elmt); end loop; end if; -- At this point it is known that the constituent is not -- part of the package hidden state and cannot be used in -- a refinement (SPARK RM 7.2.2(9)). Error_Msg_Name_1 := Chars (Spec_Id); SPARK_Msg_NE ("cannot use & in refinement, constituent is not a hidden " & "state of package %", Constit, Constit_Id); end if; end Match_Constituent; -- Local variables Constit_Id : Entity_Id; Constits : Elist_Id; -- Start of processing for Analyze_Constituent begin -- Detect multiple uses of null in a single refinement clause or a -- mixture of null and non-null constituents. if Nkind (Constit) = N_Null then if Null_Seen then SPARK_Msg_N ("multiple null constituents not allowed", Constit); elsif Non_Null_Seen then SPARK_Msg_N ("cannot mix null and non-null constituents", Constit); else Null_Seen := True; -- Collect the constituent in the list of refinement items Constits := Refinement_Constituents (State_Id); if No (Constits) then Constits := New_Elmt_List; Set_Refinement_Constituents (State_Id, Constits); end if; Append_Elmt (Constit, Constits); -- The state has at least one legal constituent, mark the -- start of the refinement region. The region ends when the -- body declarations end (see Analyze_Declarations). Set_Has_Visible_Refinement (State_Id); end if; -- Non-null constituents else Non_Null_Seen := True; if Null_Seen then SPARK_Msg_N ("cannot mix null and non-null constituents", Constit); end if; Analyze (Constit); Resolve_State (Constit); -- Ensure that the constituent denotes a valid state or a -- whole object (SPARK RM 7.2.2(5)). if Is_Entity_Name (Constit) then Constit_Id := Entity_Of (Constit); -- When a constituent is declared after a subprogram body -- that caused freezing of the related contract where -- pragma Refined_State resides, the constituent appears -- undefined and carries Any_Id as its entity. -- package body Pack -- with Refined_State => (State => Constit) -- is -- procedure Proc -- with Refined_Global => (Input => Constit) -- is -- ... -- end Proc; -- Constit : ...; -- end Pack; if Constit_Id = Any_Id then SPARK_Msg_NE ("& is undefined", Constit, Constit_Id); -- Emit a specialized info message when the contract of -- the related package body was "frozen" by another body. -- Note that it is not possible to precisely identify why -- the constituent is undefined because it is not visible -- when pragma Refined_State is analyzed. This message is -- a reasonable approximation. if Present (Freeze_Id) and then not Freeze_Posted then Freeze_Posted := True; Error_Msg_Name_1 := Chars (Body_Id); Error_Msg_Sloc := Sloc (Freeze_Id); SPARK_Msg_NE ("body & declared # freezes the contract of %", N, Freeze_Id); SPARK_Msg_N ("\all constituents must be declared before body #", N); -- A misplaced constituent is a critical error because -- pragma Refined_Depends or Refined_Global depends on -- the proper link between a state and a constituent. -- Stop the compilation, as this leads to a multitude -- of misleading cascaded errors. raise Unrecoverable_Error; end if; -- The constituent is a valid state or object elsif Ekind_In (Constit_Id, E_Abstract_State, E_Constant, E_Variable) then Match_Constituent (Constit_Id); -- The variable may eventually become a constituent of a -- single protected/task type. Record the reference now -- and verify its legality when analyzing the contract of -- the variable (SPARK RM 9.3). if Ekind (Constit_Id) = E_Variable then Record_Possible_Part_Of_Reference (Var_Id => Constit_Id, Ref => Constit); end if; -- Otherwise the constituent is illegal else SPARK_Msg_NE ("constituent & must denote object or state", Constit, Constit_Id); end if; -- The constituent is illegal else SPARK_Msg_N ("malformed constituent", Constit); end if; end if; end Analyze_Constituent; ----------------------------- -- Check_External_Property -- ----------------------------- procedure Check_External_Property (Prop_Nam : Name_Id; Enabled : Boolean; Constit : Entity_Id) is begin -- The property is missing in the declaration of the state, but -- a constituent is introducing it in the state refinement -- (SPARK RM 7.2.8(2)). if not Enabled and then Present (Constit) then Error_Msg_Name_1 := Prop_Nam; Error_Msg_Name_2 := Chars (State_Id); SPARK_Msg_NE ("constituent & introduces external property % in refinement " & "of state %", State, Constit); Error_Msg_Sloc := Sloc (State_Id); SPARK_Msg_N ("\property is missing in abstract state declaration #", State); end if; end Check_External_Property; ----------------- -- Match_State -- ----------------- procedure Match_State is State_Elmt : Elmt_Id; begin -- Detect a duplicate refinement of a state (SPARK RM 7.2.2(8)) if Contains (Refined_States_Seen, State_Id) then SPARK_Msg_NE ("duplicate refinement of state &", State, State_Id); return; end if; -- Inspect the abstract states defined in the package declaration -- looking for a match. State_Elmt := First_Elmt (Available_States); while Present (State_Elmt) loop -- A valid abstract state is being refined in the body. Add -- the state to the list of processed refined states to aid -- with the detection of duplicate refinements. Remove the -- state from Available_States to signal that it has already -- been refined. if Node (State_Elmt) = State_Id then Append_New_Elmt (State_Id, Refined_States_Seen); Remove_Elmt (Available_States, State_Elmt); return; end if; Next_Elmt (State_Elmt); end loop; -- If we get here, we are refining a state that is not defined in -- the package declaration. Error_Msg_Name_1 := Chars (Spec_Id); SPARK_Msg_NE ("cannot refine state, & is not defined in package %", State, State_Id); end Match_State; -------------------------------- -- Report_Unused_Constituents -- -------------------------------- procedure Report_Unused_Constituents (Constits : Elist_Id) is Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; Posted : Boolean := False; begin if Present (Constits) then Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- Generate an error message of the form: -- state ... has unused Part_Of constituents -- abstract state ... defined at ... -- constant ... defined at ... -- variable ... defined at ... if not Posted then Posted := True; SPARK_Msg_NE ("state & has unused Part_Of constituents", State, State_Id); end if; Error_Msg_Sloc := Sloc (Constit_Id); if Ekind (Constit_Id) = E_Abstract_State then SPARK_Msg_NE ("\abstract state & defined #", State, Constit_Id); elsif Ekind (Constit_Id) = E_Constant then SPARK_Msg_NE ("\constant & defined #", State, Constit_Id); else pragma Assert (Ekind (Constit_Id) = E_Variable); SPARK_Msg_NE ("\variable & defined #", State, Constit_Id); end if; Next_Elmt (Constit_Elmt); end loop; end if; end Report_Unused_Constituents; -- Local declarations Body_Ref : Node_Id; Body_Ref_Elmt : Elmt_Id; Constit : Node_Id; Extra_State : Node_Id; -- Start of processing for Analyze_Refinement_Clause begin -- A refinement clause appears as a component association where the -- sole choice is the state and the expressions are the constituents. -- This is a syntax error, always report. if Nkind (Clause) /= N_Component_Association then Error_Msg_N ("malformed state refinement clause", Clause); return; end if; -- Analyze the state name of a refinement clause State := First (Choices (Clause)); Analyze (State); Resolve_State (State); -- Ensure that the state name denotes a valid abstract state that is -- defined in the spec of the related package. if Is_Entity_Name (State) then State_Id := Entity_Of (State); -- When the abstract state is undefined, it appears as Any_Id. Do -- not continue with the analysis of the clause. if State_Id = Any_Id then return; -- Catch any attempts to re-refine a state or refine a state that -- is not defined in the package declaration. elsif Ekind (State_Id) = E_Abstract_State then Match_State; else SPARK_Msg_NE ("& must denote abstract state", State, State_Id); return; end if; -- References to a state with visible refinement are illegal. -- When nested packages are involved, detecting such references is -- tricky because pragma Refined_State is analyzed later than the -- offending pragma Depends or Global. References that occur in -- such nested context are stored in a list. Emit errors for all -- references found in Body_References (SPARK RM 6.1.4(8)). if Present (Body_References (State_Id)) then Body_Ref_Elmt := First_Elmt (Body_References (State_Id)); while Present (Body_Ref_Elmt) loop Body_Ref := Node (Body_Ref_Elmt); SPARK_Msg_N ("reference to & not allowed", Body_Ref); Error_Msg_Sloc := Sloc (State); SPARK_Msg_N ("\refinement of & is visible#", Body_Ref); Next_Elmt (Body_Ref_Elmt); end loop; end if; -- The state name is illegal. This is a syntax error, always report. else Error_Msg_N ("malformed state name in refinement clause", State); return; end if; -- A refinement clause may only refine one state at a time Extra_State := Next (State); if Present (Extra_State) then SPARK_Msg_N ("refinement clause cannot cover multiple states", Extra_State); end if; -- Replicate the Part_Of constituents of the refined state because -- the algorithm will consume items. Part_Of_Constits := New_Copy_Elist (Part_Of_Constituents (State_Id)); -- Analyze all constituents of the refinement. Multiple constituents -- appear as an aggregate. Constit := Expression (Clause); if Nkind (Constit) = N_Aggregate then if Present (Component_Associations (Constit)) then SPARK_Msg_N ("constituents of refinement clause must appear in " & "positional form", Constit); else pragma Assert (Present (Expressions (Constit))); Constit := First (Expressions (Constit)); while Present (Constit) loop Analyze_Constituent (Constit); Next (Constit); end loop; end if; -- Various forms of a single constituent. Note that these may include -- malformed constituents. else Analyze_Constituent (Constit); end if; -- Verify that external constituents do not introduce new external -- property in the state refinement (SPARK RM 7.2.8(2)). if Is_External_State (State_Id) then Check_External_Property (Prop_Nam => Name_Async_Readers, Enabled => Async_Readers_Enabled (State_Id), Constit => AR_Constit); Check_External_Property (Prop_Nam => Name_Async_Writers, Enabled => Async_Writers_Enabled (State_Id), Constit => AW_Constit); Check_External_Property (Prop_Nam => Name_Effective_Reads, Enabled => Effective_Reads_Enabled (State_Id), Constit => ER_Constit); Check_External_Property (Prop_Nam => Name_Effective_Writes, Enabled => Effective_Writes_Enabled (State_Id), Constit => EW_Constit); -- When a refined state is not external, it should not have external -- constituents (SPARK RM 7.2.8(1)). elsif External_Constit_Seen then SPARK_Msg_NE ("non-external state & cannot contain external constituents in " & "refinement", State, State_Id); end if; -- Ensure that all Part_Of candidate constituents have been mentioned -- in the refinement clause. Report_Unused_Constituents (Part_Of_Constits); end Analyze_Refinement_Clause; ----------------------------- -- Report_Unrefined_States -- ----------------------------- procedure Report_Unrefined_States (States : Elist_Id) is State_Elmt : Elmt_Id; begin if Present (States) then State_Elmt := First_Elmt (States); while Present (State_Elmt) loop SPARK_Msg_N ("abstract state & must be refined", Node (State_Elmt)); Next_Elmt (State_Elmt); end loop; end if; end Report_Unrefined_States; -- Local declarations Clauses : constant Node_Id := Expression (Get_Argument (N, Spec_Id)); Clause : Node_Id; -- Start of processing for Analyze_Refined_State_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Save the scenario for examination by the ABE Processing phase Record_Elaboration_Scenario (N); -- Replicate the abstract states declared by the package because the -- matching algorithm will consume states. Available_States := New_Copy_Elist (Abstract_States (Spec_Id)); -- Gather all abstract states and objects declared in the visible -- state space of the package body. These items must be utilized as -- constituents in a state refinement. Body_States := Collect_Body_States (Body_Id); -- Multiple non-null state refinements appear as an aggregate if Nkind (Clauses) = N_Aggregate then if Present (Expressions (Clauses)) then SPARK_Msg_N ("state refinements must appear as component associations", Clauses); else pragma Assert (Present (Component_Associations (Clauses))); Clause := First (Component_Associations (Clauses)); while Present (Clause) loop Analyze_Refinement_Clause (Clause); Next (Clause); end loop; end if; -- Various forms of a single state refinement. Note that these may -- include malformed refinements. else Analyze_Refinement_Clause (Clauses); end if; -- List all abstract states that were left unrefined Report_Unrefined_States (Available_States); Set_Is_Analyzed_Pragma (N); end Analyze_Refined_State_In_Decl_Part; ------------------------------------ -- Analyze_Test_Case_In_Decl_Part -- ------------------------------------ procedure Analyze_Test_Case_In_Decl_Part (N : Node_Id) is Subp_Decl : constant Node_Id := Find_Related_Declaration_Or_Body (N); Spec_Id : constant Entity_Id := Unique_Defining_Entity (Subp_Decl); procedure Preanalyze_Test_Case_Arg (Arg_Nam : Name_Id); -- Preanalyze one of the optional arguments "Requires" or "Ensures" -- denoted by Arg_Nam. ------------------------------ -- Preanalyze_Test_Case_Arg -- ------------------------------ procedure Preanalyze_Test_Case_Arg (Arg_Nam : Name_Id) is Arg : Node_Id; begin -- Preanalyze the original aspect argument for ASIS or for a generic -- subprogram to properly capture global references. if ASIS_Mode or else Is_Generic_Subprogram (Spec_Id) then Arg := Test_Case_Arg (Prag => N, Arg_Nam => Arg_Nam, From_Aspect => True); if Present (Arg) then Preanalyze_Assert_Expression (Expression (Arg), Standard_Boolean); end if; end if; Arg := Test_Case_Arg (N, Arg_Nam); if Present (Arg) then Preanalyze_Assert_Expression (Expression (Arg), Standard_Boolean); end if; end Preanalyze_Test_Case_Arg; -- Local variables Restore_Scope : Boolean := False; -- Start of processing for Analyze_Test_Case_In_Decl_Part begin -- Do not analyze the pragma multiple times if Is_Analyzed_Pragma (N) then return; end if; -- Ensure that the formal parameters are visible when analyzing all -- clauses. This falls out of the general rule of aspects pertaining -- to subprogram declarations. if not In_Open_Scopes (Spec_Id) then Restore_Scope := True; Push_Scope (Spec_Id); if Is_Generic_Subprogram (Spec_Id) then Install_Generic_Formals (Spec_Id); else Install_Formals (Spec_Id); end if; end if; Preanalyze_Test_Case_Arg (Name_Requires); Preanalyze_Test_Case_Arg (Name_Ensures); if Restore_Scope then End_Scope; end if; -- Currently it is not possible to inline pre/postconditions on a -- subprogram subject to pragma Inline_Always. Check_Postcondition_Use_In_Inlined_Subprogram (N, Spec_Id); Set_Is_Analyzed_Pragma (N); end Analyze_Test_Case_In_Decl_Part; ---------------- -- Appears_In -- ---------------- function Appears_In (List : Elist_Id; Item_Id : Entity_Id) return Boolean is Elmt : Elmt_Id; Id : Entity_Id; begin if Present (List) then Elmt := First_Elmt (List); while Present (Elmt) loop if Nkind (Node (Elmt)) = N_Defining_Identifier then Id := Node (Elmt); else Id := Entity_Of (Node (Elmt)); end if; if Id = Item_Id then return True; end if; Next_Elmt (Elmt); end loop; end if; return False; end Appears_In; ----------------------------------- -- Build_Pragma_Check_Equivalent -- ----------------------------------- function Build_Pragma_Check_Equivalent (Prag : Node_Id; Subp_Id : Entity_Id := Empty; Inher_Id : Entity_Id := Empty; Keep_Pragma_Id : Boolean := False) return Node_Id is function Suppress_Reference (N : Node_Id) return Traverse_Result; -- Detect whether node N references a formal parameter subject to -- pragma Unreferenced. If this is the case, set Comes_From_Source -- to False to suppress the generation of a reference when analyzing -- N later on. ------------------------ -- Suppress_Reference -- ------------------------ function Suppress_Reference (N : Node_Id) return Traverse_Result is Formal : Entity_Id; begin if Is_Entity_Name (N) and then Present (Entity (N)) then Formal := Entity (N); -- The formal parameter is subject to pragma Unreferenced. Prevent -- the generation of references by resetting the Comes_From_Source -- flag. if Is_Formal (Formal) and then Has_Pragma_Unreferenced (Formal) then Set_Comes_From_Source (N, False); end if; end if; return OK; end Suppress_Reference; procedure Suppress_References is new Traverse_Proc (Suppress_Reference); -- Local variables Loc : constant Source_Ptr := Sloc (Prag); Prag_Nam : constant Name_Id := Pragma_Name (Prag); Check_Prag : Node_Id; Msg_Arg : Node_Id; Nam : Name_Id; Needs_Wrapper : Boolean; pragma Unreferenced (Needs_Wrapper); -- Start of processing for Build_Pragma_Check_Equivalent begin -- When the pre- or postcondition is inherited, map the formals of the -- inherited subprogram to those of the current subprogram. In addition, -- map primitive operations of the parent type into the corresponding -- primitive operations of the descendant. if Present (Inher_Id) then pragma Assert (Present (Subp_Id)); Update_Primitives_Mapping (Inher_Id, Subp_Id); -- Use generic machinery to copy inherited pragma, as if it were an -- instantiation, resetting source locations appropriately, so that -- expressions inside the inherited pragma use chained locations. -- This is used in particular in GNATprove to locate precisely -- messages on a given inherited pragma. Set_Copied_Sloc_For_Inherited_Pragma (Unit_Declaration_Node (Subp_Id), Inher_Id); Check_Prag := New_Copy_Tree (Source => Prag); -- Build the inherited class-wide condition Build_Class_Wide_Expression (Prag => Check_Prag, Subp => Subp_Id, Par_Subp => Inher_Id, Adjust_Sloc => True, Needs_Wrapper => Needs_Wrapper); -- If not an inherited condition simply copy the original pragma else Check_Prag := New_Copy_Tree (Source => Prag); end if; -- Mark the pragma as being internally generated and reset the Analyzed -- flag. Set_Analyzed (Check_Prag, False); Set_Comes_From_Source (Check_Prag, False); -- The tree of the original pragma may contain references to the -- formal parameters of the related subprogram. At the same time -- the corresponding body may mark the formals as unreferenced: -- procedure Proc (Formal : ...) -- with Pre => Formal ...; -- procedure Proc (Formal : ...) is -- pragma Unreferenced (Formal); -- ... -- This creates problems because all pragma Check equivalents are -- analyzed at the end of the body declarations. Since all source -- references have already been accounted for, reset any references -- to such formals in the generated pragma Check equivalent. Suppress_References (Check_Prag); if Present (Corresponding_Aspect (Prag)) then Nam := Chars (Identifier (Corresponding_Aspect (Prag))); else Nam := Prag_Nam; end if; -- Unless Keep_Pragma_Id is True in order to keep the identifier of -- the copied pragma in the newly created pragma, convert the copy into -- pragma Check by correcting the name and adding a check_kind argument. if not Keep_Pragma_Id then Set_Class_Present (Check_Prag, False); Set_Pragma_Identifier (Check_Prag, Make_Identifier (Loc, Name_Check)); Prepend_To (Pragma_Argument_Associations (Check_Prag), Make_Pragma_Argument_Association (Loc, Expression => Make_Identifier (Loc, Nam))); end if; -- Update the error message when the pragma is inherited if Present (Inher_Id) then Msg_Arg := Last (Pragma_Argument_Associations (Check_Prag)); if Chars (Msg_Arg) = Name_Message then String_To_Name_Buffer (Strval (Expression (Msg_Arg))); -- Insert "inherited" to improve the error message if Name_Buffer (1 .. 8) = "failed p" then Insert_Str_In_Name_Buffer ("inherited ", 8); Set_Strval (Expression (Msg_Arg), String_From_Name_Buffer); end if; end if; end if; return Check_Prag; end Build_Pragma_Check_Equivalent; ----------------------------- -- Check_Applicable_Policy -- ----------------------------- procedure Check_Applicable_Policy (N : Node_Id) is PP : Node_Id; Policy : Name_Id; Ename : constant Name_Id := Original_Aspect_Pragma_Name (N); begin -- No effect if not valid assertion kind name if not Is_Valid_Assertion_Kind (Ename) then return; end if; -- Loop through entries in check policy list PP := Opt.Check_Policy_List; while Present (PP) loop declare PPA : constant List_Id := Pragma_Argument_Associations (PP); Pnm : constant Name_Id := Chars (Get_Pragma_Arg (First (PPA))); begin if Ename = Pnm or else Pnm = Name_Assertion or else (Pnm = Name_Statement_Assertions and then Nam_In (Ename, Name_Assert, Name_Assert_And_Cut, Name_Assume, Name_Loop_Invariant, Name_Loop_Variant)) then Policy := Chars (Get_Pragma_Arg (Last (PPA))); case Policy is when Name_Ignore | Name_Off => -- In CodePeer mode and GNATprove mode, we need to -- consider all assertions, unless they are disabled. -- Force Is_Checked on ignored assertions, in particular -- because transformations of the AST may depend on -- assertions being checked (e.g. the translation of -- attribute 'Loop_Entry). if CodePeer_Mode or GNATprove_Mode then Set_Is_Checked (N, True); Set_Is_Ignored (N, False); else Set_Is_Checked (N, False); Set_Is_Ignored (N, True); end if; when Name_Check | Name_On => Set_Is_Checked (N, True); Set_Is_Ignored (N, False); when Name_Disable => Set_Is_Ignored (N, True); Set_Is_Checked (N, False); Set_Is_Disabled (N, True); -- That should be exhaustive, the null here is a defence -- against a malformed tree from previous errors. when others => null; end case; return; end if; PP := Next_Pragma (PP); end; end loop; -- If there are no specific entries that matched, then we let the -- setting of assertions govern. Note that this provides the needed -- compatibility with the RM for the cases of assertion, invariant, -- precondition, predicate, and postcondition. Note also that -- Assertions_Enabled is forced in CodePeer mode and GNATprove mode. if Assertions_Enabled then Set_Is_Checked (N, True); Set_Is_Ignored (N, False); else Set_Is_Checked (N, False); Set_Is_Ignored (N, True); end if; end Check_Applicable_Policy; ------------------------------- -- Check_External_Properties -- ------------------------------- procedure Check_External_Properties (Item : Node_Id; AR : Boolean; AW : Boolean; ER : Boolean; EW : Boolean) is begin -- All properties enabled if AR and AW and ER and EW then null; -- Async_Readers + Effective_Writes -- Async_Readers + Async_Writers + Effective_Writes elsif AR and EW and not ER then null; -- Async_Writers + Effective_Reads -- Async_Readers + Async_Writers + Effective_Reads elsif AW and ER and not EW then null; -- Async_Readers + Async_Writers elsif AR and AW and not ER and not EW then null; -- Async_Readers elsif AR and not AW and not ER and not EW then null; -- Async_Writers elsif AW and not AR and not ER and not EW then null; else SPARK_Msg_N ("illegal combination of external properties (SPARK RM 7.1.2(6))", Item); end if; end Check_External_Properties; ---------------- -- Check_Kind -- ---------------- function Check_Kind (Nam : Name_Id) return Name_Id is PP : Node_Id; begin -- Loop through entries in check policy list PP := Opt.Check_Policy_List; while Present (PP) loop declare PPA : constant List_Id := Pragma_Argument_Associations (PP); Pnm : constant Name_Id := Chars (Get_Pragma_Arg (First (PPA))); begin if Nam = Pnm or else (Pnm = Name_Assertion and then Is_Valid_Assertion_Kind (Nam)) or else (Pnm = Name_Statement_Assertions and then Nam_In (Nam, Name_Assert, Name_Assert_And_Cut, Name_Assume, Name_Loop_Invariant, Name_Loop_Variant)) then case (Chars (Get_Pragma_Arg (Last (PPA)))) is when Name_Check | Name_On => return Name_Check; when Name_Ignore | Name_Off => return Name_Ignore; when Name_Disable => return Name_Disable; when others => raise Program_Error; end case; else PP := Next_Pragma (PP); end if; end; end loop; -- If there are no specific entries that matched, then we let the -- setting of assertions govern. Note that this provides the needed -- compatibility with the RM for the cases of assertion, invariant, -- precondition, predicate, and postcondition. if Assertions_Enabled then return Name_Check; else return Name_Ignore; end if; end Check_Kind; --------------------------- -- Check_Missing_Part_Of -- --------------------------- procedure Check_Missing_Part_Of (Item_Id : Entity_Id) is function Has_Visible_State (Pack_Id : Entity_Id) return Boolean; -- Determine whether a package denoted by Pack_Id declares at least one -- visible state. ----------------------- -- Has_Visible_State -- ----------------------- function Has_Visible_State (Pack_Id : Entity_Id) return Boolean is Item_Id : Entity_Id; begin -- Traverse the entity chain of the package trying to find at least -- one visible abstract state, variable or a package [instantiation] -- that declares a visible state. Item_Id := First_Entity (Pack_Id); while Present (Item_Id) and then not In_Private_Part (Item_Id) loop -- Do not consider internally generated items if not Comes_From_Source (Item_Id) then null; -- Do not consider generic formals or their corresponding actuals -- because they are not part of a visible state. Note that both -- entities are marked as hidden. elsif Is_Hidden (Item_Id) then null; -- A visible state has been found. Note that constants are not -- considered here because it is not possible to determine whether -- they depend on variable input. This check is left to the SPARK -- prover. elsif Ekind_In (Item_Id, E_Abstract_State, E_Variable) then return True; -- Recursively peek into nested packages and instantiations elsif Ekind (Item_Id) = E_Package and then Has_Visible_State (Item_Id) then return True; end if; Next_Entity (Item_Id); end loop; return False; end Has_Visible_State; -- Local variables Pack_Id : Entity_Id; Placement : State_Space_Kind; -- Start of processing for Check_Missing_Part_Of begin -- Do not consider abstract states, variables or package instantiations -- coming from an instance as those always inherit the Part_Of indicator -- of the instance itself. if In_Instance then return; -- Do not consider internally generated entities as these can never -- have a Part_Of indicator. elsif not Comes_From_Source (Item_Id) then return; -- Perform these checks only when SPARK_Mode is enabled as they will -- interfere with standard Ada rules and produce false positives. elsif SPARK_Mode /= On then return; -- Do not consider constants, because the compiler cannot accurately -- determine whether they have variable input (SPARK RM 7.1.1(2)) and -- act as a hidden state of a package. elsif Ekind (Item_Id) = E_Constant then return; end if; -- Find where the abstract state, variable or package instantiation -- lives with respect to the state space. Find_Placement_In_State_Space (Item_Id => Item_Id, Placement => Placement, Pack_Id => Pack_Id); -- Items that appear in a non-package construct (subprogram, block, etc) -- do not require a Part_Of indicator because they can never act as a -- hidden state. if Placement = Not_In_Package then null; -- An item declared in the body state space of a package always act as a -- constituent and does not need explicit Part_Of indicator. elsif Placement = Body_State_Space then null; -- In general an item declared in the visible state space of a package -- does not require a Part_Of indicator. The only exception is when the -- related package is a nongeneric private child unit, in which case -- Part_Of must denote a state in the parent unit or in one of its -- descendants. elsif Placement = Visible_State_Space then if Is_Child_Unit (Pack_Id) and then not Is_Generic_Unit (Pack_Id) and then Is_Private_Descendant (Pack_Id) then -- A package instantiation does not need a Part_Of indicator when -- the related generic template has no visible state. if Ekind (Item_Id) = E_Package and then Is_Generic_Instance (Item_Id) and then not Has_Visible_State (Item_Id) then null; -- All other cases require Part_Of else Error_Msg_N ("indicator Part_Of is required in this context " & "(SPARK RM 7.2.6(3))", Item_Id); Error_Msg_Name_1 := Chars (Pack_Id); Error_Msg_N ("\& is declared in the visible part of private child " & "unit %", Item_Id); end if; end if; -- When the item appears in the private state space of a package, it -- must be a part of some state declared by the said package. else pragma Assert (Placement = Private_State_Space); -- The related package does not declare a state, the item cannot act -- as a Part_Of constituent. if No (Get_Pragma (Pack_Id, Pragma_Abstract_State)) then null; -- A package instantiation does not need a Part_Of indicator when the -- related generic template has no visible state. elsif Ekind (Item_Id) = E_Package and then Is_Generic_Instance (Item_Id) and then not Has_Visible_State (Item_Id) then null; -- All other cases require Part_Of else Error_Msg_N ("indicator Part_Of is required in this context " & "(SPARK RM 7.2.6(2))", Item_Id); Error_Msg_Name_1 := Chars (Pack_Id); Error_Msg_N ("\& is declared in the private part of package %", Item_Id); end if; end if; end Check_Missing_Part_Of; --------------------------------------------------- -- Check_Postcondition_Use_In_Inlined_Subprogram -- --------------------------------------------------- procedure Check_Postcondition_Use_In_Inlined_Subprogram (Prag : Node_Id; Spec_Id : Entity_Id) is begin if Warn_On_Redundant_Constructs and then Has_Pragma_Inline_Always (Spec_Id) and then Assertions_Enabled then Error_Msg_Name_1 := Original_Aspect_Pragma_Name (Prag); if From_Aspect_Specification (Prag) then Error_Msg_NE ("aspect % not enforced on inlined subprogram &?r?", Corresponding_Aspect (Prag), Spec_Id); else Error_Msg_NE ("pragma % not enforced on inlined subprogram &?r?", Prag, Spec_Id); end if; end if; end Check_Postcondition_Use_In_Inlined_Subprogram; ------------------------------------- -- Check_State_And_Constituent_Use -- ------------------------------------- procedure Check_State_And_Constituent_Use (States : Elist_Id; Constits : Elist_Id; Context : Node_Id) is Constit_Elmt : Elmt_Id; Constit_Id : Entity_Id; State_Id : Entity_Id; begin -- Nothing to do if there are no states or constituents if No (States) or else No (Constits) then return; end if; -- Inspect the list of constituents and try to determine whether its -- encapsulating state is in list States. Constit_Elmt := First_Elmt (Constits); while Present (Constit_Elmt) loop Constit_Id := Node (Constit_Elmt); -- Determine whether the constituent is part of an encapsulating -- state that appears in the same context and if this is the case, -- emit an error (SPARK RM 7.2.6(7)). State_Id := Find_Encapsulating_State (States, Constit_Id); if Present (State_Id) then Error_Msg_Name_1 := Chars (Constit_Id); SPARK_Msg_NE ("cannot mention state & and its constituent % in the same " & "context", Context, State_Id); exit; end if; Next_Elmt (Constit_Elmt); end loop; end Check_State_And_Constituent_Use; --------------------------------------------- -- Collect_Inherited_Class_Wide_Conditions -- --------------------------------------------- procedure Collect_Inherited_Class_Wide_Conditions (Subp : Entity_Id) is Parent_Subp : constant Entity_Id := Ultimate_Alias (Overridden_Operation (Subp)); -- The Overridden_Operation may itself be inherited and as such have no -- explicit contract. Prags : constant Node_Id := Contract (Parent_Subp); In_Spec_Expr : Boolean; Installed : Boolean; Prag : Node_Id; New_Prag : Node_Id; begin Installed := False; -- Iterate over the contract of the overridden subprogram to find all -- inherited class-wide pre- and postconditions. if Present (Prags) then Prag := Pre_Post_Conditions (Prags); while Present (Prag) loop if Nam_In (Pragma_Name_Unmapped (Prag), Name_Precondition, Name_Postcondition) and then Class_Present (Prag) then -- The generated pragma must be analyzed in the context of -- the subprogram, to make its formals visible. In addition, -- we must inhibit freezing and full analysis because the -- controlling type of the subprogram is not frozen yet, and -- may have further primitives. if not Installed then Installed := True; Push_Scope (Subp); Install_Formals (Subp); In_Spec_Expr := In_Spec_Expression; In_Spec_Expression := True; end if; New_Prag := Build_Pragma_Check_Equivalent (Prag, Subp, Parent_Subp, Keep_Pragma_Id => True); Insert_After (Unit_Declaration_Node (Subp), New_Prag); Preanalyze (New_Prag); -- Prevent further analysis in subsequent processing of the -- current list of declarations Set_Analyzed (New_Prag); end if; Prag := Next_Pragma (Prag); end loop; if Installed then In_Spec_Expression := In_Spec_Expr; End_Scope; end if; end if; end Collect_Inherited_Class_Wide_Conditions; --------------------------------------- -- Collect_Subprogram_Inputs_Outputs -- --------------------------------------- procedure Collect_Subprogram_Inputs_Outputs (Subp_Id : Entity_Id; Synthesize : Boolean := False; Subp_Inputs : in out Elist_Id; Subp_Outputs : in out Elist_Id; Global_Seen : out Boolean) is procedure Collect_Dependency_Clause (Clause : Node_Id); -- Collect all relevant items from a dependency clause procedure Collect_Global_List (List : Node_Id; Mode : Name_Id := Name_Input); -- Collect all relevant items from a global list ------------------------------- -- Collect_Dependency_Clause -- ------------------------------- procedure Collect_Dependency_Clause (Clause : Node_Id) is procedure Collect_Dependency_Item (Item : Node_Id; Is_Input : Boolean); -- Add an item to the proper subprogram input or output collection ----------------------------- -- Collect_Dependency_Item -- ----------------------------- procedure Collect_Dependency_Item (Item : Node_Id; Is_Input : Boolean) is Extra : Node_Id; begin -- Nothing to collect when the item is null if Nkind (Item) = N_Null then null; -- Ditto for attribute 'Result elsif Is_Attribute_Result (Item) then null; -- Multiple items appear as an aggregate elsif Nkind (Item) = N_Aggregate then Extra := First (Expressions (Item)); while Present (Extra) loop Collect_Dependency_Item (Extra, Is_Input); Next (Extra); end loop; -- Otherwise this is a solitary item else if Is_Input then Append_New_Elmt (Item, Subp_Inputs); else Append_New_Elmt (Item, Subp_Outputs); end if; end if; end Collect_Dependency_Item; -- Start of processing for Collect_Dependency_Clause begin if Nkind (Clause) = N_Null then null; -- A dependency clause appears as component association elsif Nkind (Clause) = N_Component_Association then Collect_Dependency_Item (Item => Expression (Clause), Is_Input => True); Collect_Dependency_Item (Item => First (Choices (Clause)), Is_Input => False); -- To accommodate partial decoration of disabled SPARK features, this -- routine may be called with illegal input. If this is the case, do -- not raise Program_Error. else null; end if; end Collect_Dependency_Clause; ------------------------- -- Collect_Global_List -- ------------------------- procedure Collect_Global_List (List : Node_Id; Mode : Name_Id := Name_Input) is procedure Collect_Global_Item (Item : Node_Id; Mode : Name_Id); -- Add an item to the proper subprogram input or output collection ------------------------- -- Collect_Global_Item -- ------------------------- procedure Collect_Global_Item (Item : Node_Id; Mode : Name_Id) is begin if Nam_In (Mode, Name_In_Out, Name_Input) then Append_New_Elmt (Item, Subp_Inputs); end if; if Nam_In (Mode, Name_In_Out, Name_Output) then Append_New_Elmt (Item, Subp_Outputs); end if; end Collect_Global_Item; -- Local variables Assoc : Node_Id; Item : Node_Id; -- Start of processing for Collect_Global_List begin if Nkind (List) = N_Null then null; -- Single global item declaration elsif Nkind_In (List, N_Expanded_Name, N_Identifier, N_Selected_Component) then Collect_Global_Item (List, Mode); -- Simple global list or moded global list declaration elsif Nkind (List) = N_Aggregate then if Present (Expressions (List)) then Item := First (Expressions (List)); while Present (Item) loop Collect_Global_Item (Item, Mode); Next (Item); end loop; else Assoc := First (Component_Associations (List)); while Present (Assoc) loop Collect_Global_List (List => Expression (Assoc), Mode => Chars (First (Choices (Assoc)))); Next (Assoc); end loop; end if; -- To accommodate partial decoration of disabled SPARK features, this -- routine may be called with illegal input. If this is the case, do -- not raise Program_Error. else null; end if; end Collect_Global_List; -- Local variables Clause : Node_Id; Clauses : Node_Id; Depends : Node_Id; Formal : Entity_Id; Global : Node_Id; Spec_Id : Entity_Id := Empty; Subp_Decl : Node_Id; Typ : Entity_Id; -- Start of processing for Collect_Subprogram_Inputs_Outputs begin Global_Seen := False; -- Process all formal parameters of entries, [generic] subprograms, and -- their bodies. if Ekind_In (Subp_Id, E_Entry, E_Entry_Family, E_Function, E_Generic_Function, E_Generic_Procedure, E_Procedure, E_Subprogram_Body) then Subp_Decl := Unit_Declaration_Node (Subp_Id); Spec_Id := Unique_Defining_Entity (Subp_Decl); -- Process all formal parameters Formal := First_Entity (Spec_Id); while Present (Formal) loop if Ekind_In (Formal, E_In_Out_Parameter, E_In_Parameter) then Append_New_Elmt (Formal, Subp_Inputs); end if; if Ekind_In (Formal, E_In_Out_Parameter, E_Out_Parameter) then Append_New_Elmt (Formal, Subp_Outputs); -- Out parameters can act as inputs when the related type is -- tagged, unconstrained array, unconstrained record, or record -- with unconstrained components. if Ekind (Formal) = E_Out_Parameter and then Is_Unconstrained_Or_Tagged_Item (Formal) then Append_New_Elmt (Formal, Subp_Inputs); end if; end if; Next_Entity (Formal); end loop; -- Otherwise the input denotes a task type, a task body, or the -- anonymous object created for a single task type. elsif Ekind_In (Subp_Id, E_Task_Type, E_Task_Body) or else Is_Single_Task_Object (Subp_Id) then Subp_Decl := Declaration_Node (Subp_Id); Spec_Id := Unique_Defining_Entity (Subp_Decl); end if; -- When processing an entry, subprogram or task body, look for pragmas -- Refined_Depends and Refined_Global as they specify the inputs and -- outputs. if Is_Entry_Body (Subp_Id) or else Ekind_In (Subp_Id, E_Subprogram_Body, E_Task_Body) then Depends := Get_Pragma (Subp_Id, Pragma_Refined_Depends); Global := Get_Pragma (Subp_Id, Pragma_Refined_Global); -- Subprogram declaration or stand-alone body case, look for pragmas -- Depends and Global else Depends := Get_Pragma (Spec_Id, Pragma_Depends); Global := Get_Pragma (Spec_Id, Pragma_Global); end if; -- Pragma [Refined_]Global takes precedence over [Refined_]Depends -- because it provides finer granularity of inputs and outputs. if Present (Global) then Global_Seen := True; Collect_Global_List (Expression (Get_Argument (Global, Spec_Id))); -- When the related subprogram lacks pragma [Refined_]Global, fall back -- to [Refined_]Depends if the caller requests this behavior. Synthesize -- the inputs and outputs from [Refined_]Depends. elsif Synthesize and then Present (Depends) then Clauses := Expression (Get_Argument (Depends, Spec_Id)); -- Multiple dependency clauses appear as an aggregate if Nkind (Clauses) = N_Aggregate then Clause := First (Component_Associations (Clauses)); while Present (Clause) loop Collect_Dependency_Clause (Clause); Next (Clause); end loop; -- Otherwise this is a single dependency clause else Collect_Dependency_Clause (Clauses); end if; end if; -- The current instance of a protected type acts as a formal parameter -- of mode IN for functions and IN OUT for entries and procedures -- (SPARK RM 6.1.4). if Ekind (Scope (Spec_Id)) = E_Protected_Type then Typ := Scope (Spec_Id); -- Use the anonymous object when the type is single protected if Is_Single_Concurrent_Type_Declaration (Declaration_Node (Typ)) then Typ := Anonymous_Object (Typ); end if; Append_New_Elmt (Typ, Subp_Inputs); if Ekind_In (Spec_Id, E_Entry, E_Entry_Family, E_Procedure) then Append_New_Elmt (Typ, Subp_Outputs); end if; -- The current instance of a task type acts as a formal parameter of -- mode IN OUT (SPARK RM 6.1.4). elsif Ekind (Spec_Id) = E_Task_Type then Typ := Spec_Id; -- Use the anonymous object when the type is single task if Is_Single_Concurrent_Type_Declaration (Declaration_Node (Typ)) then Typ := Anonymous_Object (Typ); end if; Append_New_Elmt (Typ, Subp_Inputs); Append_New_Elmt (Typ, Subp_Outputs); elsif Is_Single_Task_Object (Spec_Id) then Append_New_Elmt (Spec_Id, Subp_Inputs); Append_New_Elmt (Spec_Id, Subp_Outputs); end if; end Collect_Subprogram_Inputs_Outputs; --------------------------- -- Contract_Freeze_Error -- --------------------------- procedure Contract_Freeze_Error (Contract_Id : Entity_Id; Freeze_Id : Entity_Id) is begin Error_Msg_Name_1 := Chars (Contract_Id); Error_Msg_Sloc := Sloc (Freeze_Id); SPARK_Msg_NE ("body & declared # freezes the contract of%", Contract_Id, Freeze_Id); SPARK_Msg_N ("\all contractual items must be declared before body #", Contract_Id); end Contract_Freeze_Error; --------------------------------- -- Delay_Config_Pragma_Analyze -- --------------------------------- function Delay_Config_Pragma_Analyze (N : Node_Id) return Boolean is begin return Nam_In (Pragma_Name_Unmapped (N), Name_Interrupt_State, Name_Priority_Specific_Dispatching); end Delay_Config_Pragma_Analyze; ----------------------- -- Duplication_Error -- ----------------------- procedure Duplication_Error (Prag : Node_Id; Prev : Node_Id) is Prag_From_Asp : constant Boolean := From_Aspect_Specification (Prag); Prev_From_Asp : constant Boolean := From_Aspect_Specification (Prev); begin Error_Msg_Sloc := Sloc (Prev); Error_Msg_Name_1 := Original_Aspect_Pragma_Name (Prag); -- Emit a precise message to distinguish between source pragmas and -- pragmas generated from aspects. The ordering of the two pragmas is -- the following: -- Prev -- ok -- Prag -- duplicate -- No error is emitted when both pragmas come from aspects because this -- is already detected by the general aspect analysis mechanism. if Prag_From_Asp and Prev_From_Asp then null; elsif Prag_From_Asp then Error_Msg_N ("aspect % duplicates pragma declared #", Prag); elsif Prev_From_Asp then Error_Msg_N ("pragma % duplicates aspect declared #", Prag); else Error_Msg_N ("pragma % duplicates pragma declared #", Prag); end if; end Duplication_Error; ------------------------------ -- Find_Encapsulating_State -- ------------------------------ function Find_Encapsulating_State (States : Elist_Id; Constit_Id : Entity_Id) return Entity_Id is State_Id : Entity_Id; begin -- Since a constituent may be part of a larger constituent set, climb -- the encapsulating state chain looking for a state that appears in -- States. State_Id := Encapsulating_State (Constit_Id); while Present (State_Id) loop if Contains (States, State_Id) then return State_Id; end if; State_Id := Encapsulating_State (State_Id); end loop; return Empty; end Find_Encapsulating_State; -------------------------- -- Find_Related_Context -- -------------------------- function Find_Related_Context (Prag : Node_Id; Do_Checks : Boolean := False) return Node_Id is Stmt : Node_Id; begin Stmt := Prev (Prag); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates if Nkind (Stmt) = N_Pragma then if Do_Checks and then Pragma_Name (Stmt) = Pragma_Name (Prag) then Duplication_Error (Prag => Prag, Prev => Stmt); end if; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then -- The anonymous object created for a single concurrent type is a -- suitable context. if Nkind (Stmt) = N_Object_Declaration and then Is_Single_Concurrent_Object (Defining_Entity (Stmt)) then return Stmt; end if; -- Return the current source construct else return Stmt; end if; Prev (Stmt); end loop; return Empty; end Find_Related_Context; -------------------------------------- -- Find_Related_Declaration_Or_Body -- -------------------------------------- function Find_Related_Declaration_Or_Body (Prag : Node_Id; Do_Checks : Boolean := False) return Node_Id is Prag_Nam : constant Name_Id := Original_Aspect_Pragma_Name (Prag); procedure Expression_Function_Error; -- Emit an error concerning pragma Prag that illegaly applies to an -- expression function. ------------------------------- -- Expression_Function_Error -- ------------------------------- procedure Expression_Function_Error is begin Error_Msg_Name_1 := Prag_Nam; -- Emit a precise message to distinguish between source pragmas and -- pragmas generated from aspects. if From_Aspect_Specification (Prag) then Error_Msg_N ("aspect % cannot apply to a stand alone expression function", Prag); else Error_Msg_N ("pragma % cannot apply to a stand alone expression function", Prag); end if; end Expression_Function_Error; -- Local variables Context : constant Node_Id := Parent (Prag); Stmt : Node_Id; Look_For_Body : constant Boolean := Nam_In (Prag_Nam, Name_Refined_Depends, Name_Refined_Global, Name_Refined_Post, Name_Refined_State); -- Refinement pragmas must be associated with a subprogram body [stub] -- Start of processing for Find_Related_Declaration_Or_Body begin Stmt := Prev (Prag); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates. Pragmas produced -- by splitting a complex pre/postcondition are not considered to -- be duplicates. if Nkind (Stmt) = N_Pragma then if Do_Checks and then not Split_PPC (Stmt) and then Original_Aspect_Pragma_Name (Stmt) = Prag_Nam then Duplication_Error (Prag => Prag, Prev => Stmt); end if; -- Emit an error when a refinement pragma appears on an expression -- function without a completion. elsif Do_Checks and then Look_For_Body and then Nkind (Stmt) = N_Subprogram_Declaration and then Nkind (Original_Node (Stmt)) = N_Expression_Function and then not Has_Completion (Defining_Entity (Stmt)) then Expression_Function_Error; return Empty; -- The refinement pragma applies to a subprogram body stub elsif Look_For_Body and then Nkind (Stmt) = N_Subprogram_Body_Stub then return Stmt; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then -- The anonymous object created for a single concurrent type is a -- suitable context. if Nkind (Stmt) = N_Object_Declaration and then Is_Single_Concurrent_Object (Defining_Entity (Stmt)) then return Stmt; elsif Nkind (Stmt) = N_Subprogram_Declaration then -- The subprogram declaration is an internally generated spec -- for an expression function. if Nkind (Original_Node (Stmt)) = N_Expression_Function then return Stmt; -- The subprogram declaration is an internally generated spec -- for a stand-alone subrogram body declared inside a protected -- body. elsif Present (Corresponding_Body (Stmt)) and then Comes_From_Source (Corresponding_Body (Stmt)) and then Is_Protected_Type (Current_Scope) then return Stmt; -- The subprogram is actually an instance housed within an -- anonymous wrapper package. elsif Present (Generic_Parent (Specification (Stmt))) then return Stmt; end if; end if; -- Return the current construct which is either a subprogram body, -- a subprogram declaration or is illegal. else return Stmt; end if; Prev (Stmt); end loop; -- If we fall through, then the pragma was either the first declaration -- or it was preceded by other pragmas and no source constructs. -- The pragma is associated with a library-level subprogram if Nkind (Context) = N_Compilation_Unit_Aux then return Unit (Parent (Context)); -- The pragma appears inside the declarations of an entry body elsif Nkind (Context) = N_Entry_Body then return Context; -- The pragma appears inside the statements of a subprogram body. This -- placement is the result of subprogram contract expansion. elsif Nkind (Context) = N_Handled_Sequence_Of_Statements then return Parent (Context); -- The pragma appears inside the declarative part of a package body elsif Nkind (Context) = N_Package_Body then return Context; -- The pragma appears inside the declarative part of a subprogram body elsif Nkind (Context) = N_Subprogram_Body then return Context; -- The pragma appears inside the declarative part of a task body elsif Nkind (Context) = N_Task_Body then return Context; -- The pragma appears inside the visible part of a package specification elsif Nkind (Context) = N_Package_Specification then return Parent (Context); -- The pragma is a byproduct of aspect expansion, return the related -- context of the original aspect. This case has a lower priority as -- the above circuitry pinpoints precisely the related context. elsif Present (Corresponding_Aspect (Prag)) then return Parent (Corresponding_Aspect (Prag)); -- No candidate subprogram [body] found else return Empty; end if; end Find_Related_Declaration_Or_Body; ---------------------------------- -- Find_Related_Package_Or_Body -- ---------------------------------- function Find_Related_Package_Or_Body (Prag : Node_Id; Do_Checks : Boolean := False) return Node_Id is Context : constant Node_Id := Parent (Prag); Prag_Nam : constant Name_Id := Pragma_Name (Prag); Stmt : Node_Id; begin Stmt := Prev (Prag); while Present (Stmt) loop -- Skip prior pragmas, but check for duplicates if Nkind (Stmt) = N_Pragma then if Do_Checks and then Pragma_Name (Stmt) = Prag_Nam then Duplication_Error (Prag => Prag, Prev => Stmt); end if; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then if Nkind (Stmt) = N_Subprogram_Declaration then -- The subprogram declaration is an internally generated spec -- for an expression function. if Nkind (Original_Node (Stmt)) = N_Expression_Function then return Stmt; -- The subprogram is actually an instance housed within an -- anonymous wrapper package. elsif Present (Generic_Parent (Specification (Stmt))) then return Stmt; end if; end if; -- Return the current source construct which is illegal else return Stmt; end if; Prev (Stmt); end loop; -- If we fall through, then the pragma was either the first declaration -- or it was preceded by other pragmas and no source constructs. -- The pragma is associated with a package. The immediate context in -- this case is the specification of the package. if Nkind (Context) = N_Package_Specification then return Parent (Context); -- The pragma appears in the declarations of a package body elsif Nkind (Context) = N_Package_Body then return Context; -- The pragma appears in the statements of a package body elsif Nkind (Context) = N_Handled_Sequence_Of_Statements and then Nkind (Parent (Context)) = N_Package_Body then return Parent (Context); -- The pragma is a byproduct of aspect expansion, return the related -- context of the original aspect. This case has a lower priority as -- the above circuitry pinpoints precisely the related context. elsif Present (Corresponding_Aspect (Prag)) then return Parent (Corresponding_Aspect (Prag)); -- No candidate package [body] found else return Empty; end if; end Find_Related_Package_Or_Body; ------------------ -- Get_Argument -- ------------------ function Get_Argument (Prag : Node_Id; Context_Id : Entity_Id := Empty) return Node_Id is Args : constant List_Id := Pragma_Argument_Associations (Prag); begin -- Use the expression of the original aspect when compiling for ASIS or -- when analyzing the template of a generic unit. In both cases the -- aspect's tree must be decorated to allow for ASIS queries or to save -- the global references in the generic context. if From_Aspect_Specification (Prag) and then (ASIS_Mode or else (Present (Context_Id) and then Is_Generic_Unit (Context_Id))) then return Corresponding_Aspect (Prag); -- Otherwise use the expression of the pragma elsif Present (Args) then return First (Args); else return Empty; end if; end Get_Argument; ------------------------- -- Get_Base_Subprogram -- ------------------------- function Get_Base_Subprogram (Def_Id : Entity_Id) return Entity_Id is begin -- Follow subprogram renaming chain if Is_Subprogram (Def_Id) and then Nkind (Parent (Declaration_Node (Def_Id))) = N_Subprogram_Renaming_Declaration and then Present (Alias (Def_Id)) then return Alias (Def_Id); else return Def_Id; end if; end Get_Base_Subprogram; ----------------------- -- Get_SPARK_Mode_Type -- ----------------------- function Get_SPARK_Mode_Type (N : Name_Id) return SPARK_Mode_Type is begin if N = Name_On then return On; elsif N = Name_Off then return Off; -- Any other argument is illegal. Assume that no SPARK mode applies to -- avoid potential cascaded errors. else return None; end if; end Get_SPARK_Mode_Type; ------------------------------------ -- Get_SPARK_Mode_From_Annotation -- ------------------------------------ function Get_SPARK_Mode_From_Annotation (N : Node_Id) return SPARK_Mode_Type is Mode : Node_Id; begin if Nkind (N) = N_Aspect_Specification then Mode := Expression (N); else pragma Assert (Nkind (N) = N_Pragma); Mode := First (Pragma_Argument_Associations (N)); if Present (Mode) then Mode := Get_Pragma_Arg (Mode); end if; end if; -- Aspect or pragma SPARK_Mode specifies an explicit mode if Present (Mode) then if Nkind (Mode) = N_Identifier then return Get_SPARK_Mode_Type (Chars (Mode)); -- In case of a malformed aspect or pragma, return the default None else return None; end if; -- Otherwise the lack of an expression defaults SPARK_Mode to On else return On; end if; end Get_SPARK_Mode_From_Annotation; --------------------------- -- Has_Extra_Parentheses -- --------------------------- function Has_Extra_Parentheses (Clause : Node_Id) return Boolean is Expr : Node_Id; begin -- The aggregate should not have an expression list because a clause -- is always interpreted as a component association. The only way an -- expression list can sneak in is by adding extra parentheses around -- the individual clauses: -- Depends (Output => Input) -- proper form -- Depends ((Output => Input)) -- extra parentheses -- Since the extra parentheses are not allowed by the syntax of the -- pragma, flag them now to avoid emitting misleading errors down the -- line. if Nkind (Clause) = N_Aggregate and then Present (Expressions (Clause)) then Expr := First (Expressions (Clause)); while Present (Expr) loop -- A dependency clause surrounded by extra parentheses appears -- as an aggregate of component associations with an optional -- Paren_Count set. if Nkind (Expr) = N_Aggregate and then Present (Component_Associations (Expr)) then SPARK_Msg_N ("dependency clause contains extra parentheses", Expr); -- Otherwise the expression is a malformed construct else SPARK_Msg_N ("malformed dependency clause", Expr); end if; Next (Expr); end loop; return True; end if; return False; end Has_Extra_Parentheses; ---------------- -- Initialize -- ---------------- procedure Initialize is begin Externals.Init; end Initialize; -------- -- ip -- -------- procedure ip is begin Dummy := Dummy + 1; end ip; ----------------------------- -- Is_Config_Static_String -- ----------------------------- function Is_Config_Static_String (Arg : Node_Id) return Boolean is function Add_Config_Static_String (Arg : Node_Id) return Boolean; -- This is an internal recursive function that is just like the outer -- function except that it adds the string to the name buffer rather -- than placing the string in the name buffer. ------------------------------ -- Add_Config_Static_String -- ------------------------------ function Add_Config_Static_String (Arg : Node_Id) return Boolean is N : Node_Id; C : Char_Code; begin N := Arg; if Nkind (N) = N_Op_Concat then if Add_Config_Static_String (Left_Opnd (N)) then N := Right_Opnd (N); else return False; end if; end if; if Nkind (N) /= N_String_Literal then Error_Msg_N ("string literal expected for pragma argument", N); return False; else for J in 1 .. String_Length (Strval (N)) loop C := Get_String_Char (Strval (N), J); if not In_Character_Range (C) then Error_Msg ("string literal contains invalid wide character", Sloc (N) + 1 + Source_Ptr (J)); return False; end if; Add_Char_To_Name_Buffer (Get_Character (C)); end loop; end if; return True; end Add_Config_Static_String; -- Start of processing for Is_Config_Static_String begin Name_Len := 0; return Add_Config_Static_String (Arg); end Is_Config_Static_String; ------------------------------- -- Is_Elaboration_SPARK_Mode -- ------------------------------- function Is_Elaboration_SPARK_Mode (N : Node_Id) return Boolean is begin pragma Assert (Nkind (N) = N_Pragma and then Pragma_Name (N) = Name_SPARK_Mode and then Is_List_Member (N)); -- Pragma SPARK_Mode affects the elaboration of a package body when it -- appears in the statement part of the body. return Present (Parent (N)) and then Nkind (Parent (N)) = N_Handled_Sequence_Of_Statements and then List_Containing (N) = Statements (Parent (N)) and then Present (Parent (Parent (N))) and then Nkind (Parent (Parent (N))) = N_Package_Body; end Is_Elaboration_SPARK_Mode; ----------------------- -- Is_Enabled_Pragma -- ----------------------- function Is_Enabled_Pragma (Prag : Node_Id) return Boolean is Arg : Node_Id; begin if Present (Prag) then Arg := First (Pragma_Argument_Associations (Prag)); if Present (Arg) then return Is_True (Expr_Value (Get_Pragma_Arg (Arg))); -- The lack of a Boolean argument automatically enables the pragma else return True; end if; -- The pragma is missing, therefore it is not enabled else return False; end if; end Is_Enabled_Pragma; ----------------------------------------- -- Is_Non_Significant_Pragma_Reference -- ----------------------------------------- -- This function makes use of the following static table which indicates -- whether appearance of some name in a given pragma is to be considered -- as a reference for the purposes of warnings about unreferenced objects. -- -1 indicates that appearence in any argument is significant -- 0 indicates that appearance in any argument is not significant -- +n indicates that appearance as argument n is significant, but all -- other arguments are not significant -- 9n arguments from n on are significant, before n insignificant Sig_Flags : constant array (Pragma_Id) of Int := (Pragma_Abort_Defer => -1, Pragma_Abstract_State => -1, Pragma_Acc_Data => 0, Pragma_Acc_Kernels => 0, Pragma_Acc_Loop => 0, Pragma_Acc_Parallel => 0, Pragma_Ada_83 => -1, Pragma_Ada_95 => -1, Pragma_Ada_05 => -1, Pragma_Ada_2005 => -1, Pragma_Ada_12 => -1, Pragma_Ada_2012 => -1, Pragma_Ada_2020 => -1, Pragma_All_Calls_Remote => -1, Pragma_Allow_Integer_Address => -1, Pragma_Annotate => 93, Pragma_Assert => -1, Pragma_Assert_And_Cut => -1, Pragma_Assertion_Policy => 0, Pragma_Assume => -1, Pragma_Assume_No_Invalid_Values => 0, Pragma_Async_Readers => 0, Pragma_Async_Writers => 0, Pragma_Asynchronous => 0, Pragma_Atomic => 0, Pragma_Atomic_Components => 0, Pragma_Attach_Handler => -1, Pragma_Attribute_Definition => 92, Pragma_Check => -1, Pragma_Check_Float_Overflow => 0, Pragma_Check_Name => 0, Pragma_Check_Policy => 0, Pragma_CPP_Class => 0, Pragma_CPP_Constructor => 0, Pragma_CPP_Virtual => 0, Pragma_CPP_Vtable => 0, Pragma_CPU => -1, Pragma_C_Pass_By_Copy => 0, Pragma_Comment => -1, Pragma_Common_Object => 0, Pragma_Compile_Time_Error => -1, Pragma_Compile_Time_Warning => -1, Pragma_Compiler_Unit => -1, Pragma_Compiler_Unit_Warning => -1, Pragma_Complete_Representation => 0, Pragma_Complex_Representation => 0, Pragma_Component_Alignment => 0, Pragma_Constant_After_Elaboration => 0, Pragma_Contract_Cases => -1, Pragma_Controlled => 0, Pragma_Convention => 0, Pragma_Convention_Identifier => 0, Pragma_Deadline_Floor => -1, Pragma_Debug => -1, Pragma_Debug_Policy => 0, Pragma_Detect_Blocking => 0, Pragma_Default_Initial_Condition => -1, Pragma_Default_Scalar_Storage_Order => 0, Pragma_Default_Storage_Pool => 0, Pragma_Depends => -1, Pragma_Disable_Atomic_Synchronization => 0, Pragma_Discard_Names => 0, Pragma_Dispatching_Domain => -1, Pragma_Effective_Reads => 0, Pragma_Effective_Writes => 0, Pragma_Elaborate => 0, Pragma_Elaborate_All => 0, Pragma_Elaborate_Body => 0, Pragma_Elaboration_Checks => 0, Pragma_Eliminate => 0, Pragma_Enable_Atomic_Synchronization => 0, Pragma_Export => -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 => 0, Pragma_Extensions_Visible => 0, Pragma_External => -1, Pragma_Favor_Top_Level => 0, Pragma_External_Name_Casing => 0, Pragma_Fast_Math => 0, Pragma_Finalize_Storage_Only => 0, Pragma_Ghost => 0, Pragma_Global => -1, Pragma_Ident => -1, Pragma_Ignore_Pragma => 0, Pragma_Implementation_Defined => -1, Pragma_Implemented => -1, Pragma_Implicit_Packing => 0, Pragma_Import => 93, Pragma_Import_Function => 0, Pragma_Import_Object => 0, Pragma_Import_Procedure => 0, Pragma_Import_Valued_Procedure => 0, Pragma_Independent => 0, Pragma_Independent_Components => 0, Pragma_Initial_Condition => -1, Pragma_Initialize_Scalars => 0, Pragma_Initializes => -1, Pragma_Inline => 0, Pragma_Inline_Always => 0, Pragma_Inline_Generic => 0, Pragma_Inspection_Point => -1, Pragma_Interface => 92, Pragma_Interface_Name => 0, Pragma_Interrupt_Handler => -1, Pragma_Interrupt_Priority => -1, Pragma_Interrupt_State => -1, Pragma_Invariant => -1, Pragma_Keep_Names => 0, Pragma_License => 0, Pragma_Link_With => -1, Pragma_Linker_Alias => -1, Pragma_Linker_Constructor => -1, Pragma_Linker_Destructor => -1, Pragma_Linker_Options => -1, Pragma_Linker_Section => -1, Pragma_List => 0, Pragma_Lock_Free => 0, Pragma_Locking_Policy => 0, Pragma_Loop_Invariant => -1, Pragma_Loop_Optimize => 0, Pragma_Loop_Variant => -1, Pragma_Machine_Attribute => -1, Pragma_Main => -1, Pragma_Main_Storage => -1, Pragma_Max_Entry_Queue_Depth => 0, Pragma_Max_Queue_Length => 0, Pragma_Memory_Size => 0, Pragma_No_Return => 0, Pragma_No_Body => 0, Pragma_No_Component_Reordering => -1, Pragma_No_Elaboration_Code_All => 0, Pragma_No_Heap_Finalization => 0, Pragma_No_Inline => 0, Pragma_No_Run_Time => -1, Pragma_No_Strict_Aliasing => -1, Pragma_No_Tagged_Streams => 0, Pragma_Normalize_Scalars => 0, Pragma_Obsolescent => 0, Pragma_Optimize => 0, Pragma_Optimize_Alignment => 0, Pragma_Overflow_Mode => 0, Pragma_Overriding_Renamings => 0, Pragma_Ordered => 0, Pragma_Pack => 0, Pragma_Page => 0, Pragma_Part_Of => 0, Pragma_Partition_Elaboration_Policy => 0, Pragma_Passive => 0, Pragma_Persistent_BSS => 0, Pragma_Polling => 0, Pragma_Prefix_Exception_Messages => 0, Pragma_Post => -1, Pragma_Postcondition => -1, Pragma_Post_Class => -1, Pragma_Pre => -1, Pragma_Precondition => -1, Pragma_Predicate => -1, Pragma_Predicate_Failure => -1, Pragma_Preelaborable_Initialization => -1, Pragma_Preelaborate => 0, Pragma_Pre_Class => -1, Pragma_Priority => -1, Pragma_Priority_Specific_Dispatching => 0, Pragma_Profile => 0, Pragma_Profile_Warnings => 0, Pragma_Propagate_Exceptions => 0, Pragma_Provide_Shift_Operators => 0, Pragma_Psect_Object => 0, Pragma_Pure => 0, Pragma_Pure_Function => 0, Pragma_Queuing_Policy => 0, Pragma_Rational => 0, Pragma_Ravenscar => 0, Pragma_Refined_Depends => -1, Pragma_Refined_Global => -1, Pragma_Refined_Post => -1, Pragma_Refined_State => -1, Pragma_Relative_Deadline => 0, Pragma_Rename_Pragma => 0, Pragma_Remote_Access_Type => -1, Pragma_Remote_Call_Interface => -1, Pragma_Remote_Types => -1, Pragma_Restricted_Run_Time => 0, Pragma_Restriction_Warnings => 0, Pragma_Restrictions => 0, Pragma_Reviewable => -1, Pragma_Secondary_Stack_Size => -1, Pragma_Short_Circuit_And_Or => 0, Pragma_Share_Generic => 0, Pragma_Shared => 0, Pragma_Shared_Passive => 0, Pragma_Short_Descriptors => 0, Pragma_Simple_Storage_Pool_Type => 0, Pragma_Source_File_Name => 0, Pragma_Source_File_Name_Project => 0, Pragma_Source_Reference => 0, Pragma_SPARK_Mode => 0, Pragma_Storage_Size => -1, Pragma_Storage_Unit => 0, Pragma_Static_Elaboration_Desired => 0, Pragma_Stream_Convert => 0, Pragma_Style_Checks => 0, Pragma_Subtitle => 0, Pragma_Suppress => 0, Pragma_Suppress_Exception_Locations => 0, Pragma_Suppress_All => 0, Pragma_Suppress_Debug_Info => 0, Pragma_Suppress_Initialization => 0, Pragma_System_Name => 0, Pragma_Task_Dispatching_Policy => 0, Pragma_Task_Info => -1, Pragma_Task_Name => -1, Pragma_Task_Storage => -1, Pragma_Test_Case => -1, Pragma_Thread_Local_Storage => -1, Pragma_Time_Slice => -1, Pragma_Title => 0, Pragma_Type_Invariant => -1, Pragma_Type_Invariant_Class => -1, Pragma_Unchecked_Union => 0, Pragma_Unevaluated_Use_Of_Old => 0, Pragma_Unimplemented_Unit => 0, Pragma_Universal_Aliasing => 0, Pragma_Universal_Data => 0, Pragma_Unmodified => 0, Pragma_Unreferenced => 0, Pragma_Unreferenced_Objects => 0, Pragma_Unreserve_All_Interrupts => 0, Pragma_Unsuppress => 0, Pragma_Unused => 0, Pragma_Use_VADS_Size => 0, Pragma_Validity_Checks => 0, Pragma_Volatile => 0, Pragma_Volatile_Components => 0, Pragma_Volatile_Full_Access => 0, Pragma_Volatile_Function => 0, Pragma_Warning_As_Error => 0, Pragma_Warnings => 0, Pragma_Weak_External => 0, Pragma_Wide_Character_Encoding => 0, Unknown_Pragma => 0); function Is_Non_Significant_Pragma_Reference (N : Node_Id) return Boolean is Id : Pragma_Id; P : Node_Id; C : Int; AN : Nat; function Arg_No return Nat; -- Returns an integer showing what argument we are in. A value of -- zero means we are not in any of the arguments. ------------ -- Arg_No -- ------------ function Arg_No return Nat is A : Node_Id; N : Nat; begin A := First (Pragma_Argument_Associations (Parent (P))); N := 1; loop if No (A) then return 0; elsif A = P then return N; end if; Next (A); N := N + 1; end loop; end Arg_No; -- Start of processing for Non_Significant_Pragma_Reference begin P := Parent (N); if Nkind (P) /= N_Pragma_Argument_Association then return False; else Id := Get_Pragma_Id (Parent (P)); C := Sig_Flags (Id); AN := Arg_No; if AN = 0 then return False; end if; case C is when -1 => return False; when 0 => return True; when 92 .. 99 => return AN < (C - 90); when others => return AN /= C; 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 := Pragma_Name (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; --------------------------- -- Is_Private_SPARK_Mode -- --------------------------- function Is_Private_SPARK_Mode (N : Node_Id) return Boolean is begin pragma Assert (Nkind (N) = N_Pragma and then Pragma_Name (N) = Name_SPARK_Mode and then Is_List_Member (N)); -- For pragma SPARK_Mode to be private, it has to appear in the private -- declarations of a package. return Present (Parent (N)) and then Nkind (Parent (N)) = N_Package_Specification and then List_Containing (N) = Private_Declarations (Parent (N)); end Is_Private_SPARK_Mode; ------------------------------------- -- Is_Unconstrained_Or_Tagged_Item -- ------------------------------------- function Is_Unconstrained_Or_Tagged_Item (Item : Entity_Id) return Boolean is function Has_Unconstrained_Component (Typ : Entity_Id) return Boolean; -- Determine whether record type Typ has at least one unconstrained -- component. --------------------------------- -- Has_Unconstrained_Component -- --------------------------------- function Has_Unconstrained_Component (Typ : Entity_Id) return Boolean is Comp : Entity_Id; begin Comp := First_Component (Typ); while Present (Comp) loop if Is_Unconstrained_Or_Tagged_Item (Comp) then return True; end if; Next_Component (Comp); end loop; return False; end Has_Unconstrained_Component; -- Local variables Typ : constant Entity_Id := Etype (Item); -- Start of processing for Is_Unconstrained_Or_Tagged_Item begin if Is_Tagged_Type (Typ) then return True; elsif Is_Array_Type (Typ) and then not Is_Constrained (Typ) then return True; elsif Is_Record_Type (Typ) then if Has_Discriminants (Typ) and then not Is_Constrained (Typ) then return True; else return Has_Unconstrained_Component (Typ); end if; elsif Is_Private_Type (Typ) and then Has_Discriminants (Typ) then return True; else return False; end if; end Is_Unconstrained_Or_Tagged_Item; ----------------------------- -- Is_Valid_Assertion_Kind -- ----------------------------- function Is_Valid_Assertion_Kind (Nam : Name_Id) return Boolean is begin case Nam is when -- RM defined Name_Assert | Name_Assertion_Policy | Name_Static_Predicate | Name_Dynamic_Predicate | Name_Pre | Name_uPre | Name_Post | Name_uPost | Name_Type_Invariant | Name_uType_Invariant -- Impl defined | Name_Assert_And_Cut | Name_Assume | Name_Contract_Cases | Name_Debug | Name_Default_Initial_Condition | Name_Ghost | Name_Initial_Condition | Name_Invariant | Name_uInvariant | Name_Loop_Invariant | Name_Loop_Variant | Name_Postcondition | Name_Precondition | Name_Predicate | Name_Refined_Post | Name_Statement_Assertions => return True; when others => return False; end case; end Is_Valid_Assertion_Kind; -------------------------------------- -- Process_Compilation_Unit_Pragmas -- -------------------------------------- procedure Process_Compilation_Unit_Pragmas (N : Node_Id) is begin -- A special check for pragma Suppress_All, a very strange DEC pragma, -- strange because it comes at the end of the unit. Rational has the -- same name for a pragma, but treats it as a program unit pragma, In -- GNAT we just decide to allow it anywhere at all. If it appeared then -- the flag Has_Pragma_Suppress_All was set on the compilation unit -- node, and we insert a pragma Suppress (All_Checks) at the start of -- the context clause to ensure the correct processing. if Has_Pragma_Suppress_All (N) then Prepend_To (Context_Items (N), Make_Pragma (Sloc (N), Chars => Name_Suppress, Pragma_Argument_Associations => New_List ( Make_Pragma_Argument_Association (Sloc (N), Expression => Make_Identifier (Sloc (N), Name_All_Checks))))); end if; -- Nothing else to do at the current time end Process_Compilation_Unit_Pragmas; ------------------------------------------- -- Process_Compile_Time_Warning_Or_Error -- ------------------------------------------- procedure Process_Compile_Time_Warning_Or_Error (N : Node_Id; Eloc : Source_Ptr) is Arg1 : constant Node_Id := First (Pragma_Argument_Associations (N)); Arg1x : constant Node_Id := Get_Pragma_Arg (Arg1); Arg2 : constant Node_Id := Next (Arg1); begin Analyze_And_Resolve (Arg1x, Standard_Boolean); if Compile_Time_Known_Value (Arg1x) then if Is_True (Expr_Value (Arg1x)) then -- We have already verified that the second argument is a static -- string expression. Its string value must be retrieved -- explicitly if it is a declared constant, otherwise it has -- been constant-folded previously. declare Cent : constant Entity_Id := Cunit_Entity (Current_Sem_Unit); Pname : constant Name_Id := Pragma_Name_Unmapped (N); Prag_Id : constant Pragma_Id := Get_Pragma_Id (Pname); Str : constant String_Id := Strval (Expr_Value_S (Get_Pragma_Arg (Arg2))); Str_Len : constant Nat := String_Length (Str); Force : constant Boolean := Prag_Id = Pragma_Compile_Time_Warning and then Is_Spec_Name (Unit_Name (Current_Sem_Unit)) and then (Ekind (Cent) /= E_Package or else not In_Private_Part (Cent)); -- Set True if this is the warning case, and we are in the -- visible part of a package spec, or in a subprogram spec, -- in which case we want to force the client to see the -- warning, even though it is not in the main unit. C : Character; CC : Char_Code; Cont : Boolean; Ptr : Nat; begin -- Loop through segments of message separated by line feeds. -- We output these segments as separate messages with -- continuation marks for all but the first. Cont := False; Ptr := 1; loop Error_Msg_Strlen := 0; -- Loop to copy characters from argument to error message -- string buffer. loop exit when Ptr > Str_Len; CC := Get_String_Char (Str, Ptr); Ptr := Ptr + 1; -- Ignore wide chars ??? else store character if In_Character_Range (CC) then C := Get_Character (CC); exit when C = ASCII.LF; Error_Msg_Strlen := Error_Msg_Strlen + 1; Error_Msg_String (Error_Msg_Strlen) := C; end if; end loop; -- Here with one line ready to go Error_Msg_Warn := Prag_Id = Pragma_Compile_Time_Warning; -- If this is a warning in a spec, then we want clients -- to see the warning, so mark the message with the -- special sequence !! to force the warning. In the case -- of a package spec, we do not force this if we are in -- the private part of the spec. if Force then if Cont = False then Error_Msg ("<<~!!", Eloc); Cont := True; else Error_Msg ("\<<~!!", Eloc); end if; -- Error, rather than warning, or in a body, so we do not -- need to force visibility for client (error will be -- output in any case, and this is the situation in which -- we do not want a client to get a warning, since the -- warning is in the body or the spec private part). else if Cont = False then Error_Msg ("<<~", Eloc); Cont := True; else Error_Msg ("\<<~", Eloc); end if; end if; exit when Ptr > Str_Len; end loop; end; end if; end if; end Process_Compile_Time_Warning_Or_Error; ------------------------------------ -- Record_Possible_Body_Reference -- ------------------------------------ procedure Record_Possible_Body_Reference (State_Id : Entity_Id; Ref : Node_Id) is Context : Node_Id; Spec_Id : Entity_Id; begin -- Ensure that we are dealing with a reference to a state pragma Assert (Ekind (State_Id) = E_Abstract_State); -- Climb the tree starting from the reference looking for a package body -- whose spec declares the referenced state. This criteria automatically -- excludes references in package specs which are legal. Note that it is -- not wise to emit an error now as the package body may lack pragma -- Refined_State or the referenced state may not be mentioned in the -- refinement. This approach avoids the generation of misleading errors. Context := Ref; while Present (Context) loop if Nkind (Context) = N_Package_Body then Spec_Id := Corresponding_Spec (Context); if Present (Abstract_States (Spec_Id)) and then Contains (Abstract_States (Spec_Id), State_Id) then if No (Body_References (State_Id)) then Set_Body_References (State_Id, New_Elmt_List); end if; Append_Elmt (Ref, To => Body_References (State_Id)); exit; end if; end if; Context := Parent (Context); end loop; end Record_Possible_Body_Reference; ------------------------------------------ -- Relocate_Pragmas_To_Anonymous_Object -- ------------------------------------------ procedure Relocate_Pragmas_To_Anonymous_Object (Typ_Decl : Node_Id; Obj_Decl : Node_Id) is Decl : Node_Id; Def : Node_Id; Next_Decl : Node_Id; begin if Nkind (Typ_Decl) = N_Protected_Type_Declaration then Def := Protected_Definition (Typ_Decl); else pragma Assert (Nkind (Typ_Decl) = N_Task_Type_Declaration); Def := Task_Definition (Typ_Decl); end if; -- The concurrent definition has a visible declaration list. Inspect it -- and relocate all canidate pragmas. if Present (Def) and then Present (Visible_Declarations (Def)) then Decl := First (Visible_Declarations (Def)); while Present (Decl) loop -- Preserve the following declaration for iteration purposes due -- to possible relocation of a pragma. Next_Decl := Next (Decl); if Nkind (Decl) = N_Pragma and then Pragma_On_Anonymous_Object_OK (Get_Pragma_Id (Decl)) then Remove (Decl); Insert_After (Obj_Decl, Decl); -- Skip internally generated code elsif not Comes_From_Source (Decl) then null; -- No candidate pragmas are available for relocation else exit; end if; Decl := Next_Decl; end loop; end if; end Relocate_Pragmas_To_Anonymous_Object; ------------------------------ -- Relocate_Pragmas_To_Body -- ------------------------------ procedure Relocate_Pragmas_To_Body (Subp_Body : Node_Id; Target_Body : Node_Id := Empty) is procedure Relocate_Pragma (Prag : Node_Id); -- Remove a single pragma from its current list and add it to the -- declarations of the proper body (either Subp_Body or Target_Body). --------------------- -- Relocate_Pragma -- --------------------- procedure Relocate_Pragma (Prag : Node_Id) is Decls : List_Id; Target : Node_Id; begin -- When subprogram stubs or expression functions are involves, the -- destination declaration list belongs to the proper body. if Present (Target_Body) then Target := Target_Body; else Target := Subp_Body; end if; Decls := Declarations (Target); if No (Decls) then Decls := New_List; Set_Declarations (Target, Decls); end if; -- Unhook the pragma from its current list Remove (Prag); Prepend (Prag, Decls); end Relocate_Pragma; -- Local variables Body_Id : constant Entity_Id := Defining_Unit_Name (Specification (Subp_Body)); Next_Stmt : Node_Id; Stmt : Node_Id; -- Start of processing for Relocate_Pragmas_To_Body begin -- Do not process a body that comes from a separate unit as no construct -- can possibly follow it. if not Is_List_Member (Subp_Body) then return; -- Do not relocate pragmas that follow a stub if the stub does not have -- a proper body. elsif Nkind (Subp_Body) = N_Subprogram_Body_Stub and then No (Target_Body) then return; -- Do not process internally generated routine _Postconditions elsif Ekind (Body_Id) = E_Procedure and then Chars (Body_Id) = Name_uPostconditions then return; end if; -- Look at what is following the body. We are interested in certain kind -- of pragmas (either from source or byproducts of expansion) that can -- apply to a body [stub]. Stmt := Next (Subp_Body); while Present (Stmt) loop -- Preserve the following statement for iteration purposes due to a -- possible relocation of a pragma. Next_Stmt := Next (Stmt); -- Move a candidate pragma following the body to the declarations of -- the body. if Nkind (Stmt) = N_Pragma and then Pragma_On_Body_Or_Stub_OK (Get_Pragma_Id (Stmt)) then -- If a source pragma Warnings follows the body, it applies to -- following statements and does not belong in the body. if Get_Pragma_Id (Stmt) = Pragma_Warnings and then Comes_From_Source (Stmt) then null; else Relocate_Pragma (Stmt); end if; -- Skip internally generated code elsif not Comes_From_Source (Stmt) then null; -- No candidate pragmas are available for relocation else exit; end if; Stmt := Next_Stmt; end loop; end Relocate_Pragmas_To_Body; ------------------- -- Resolve_State -- ------------------- procedure Resolve_State (N : Node_Id) is Func : Entity_Id; State : Entity_Id; begin if Is_Entity_Name (N) and then Present (Entity (N)) then Func := Entity (N); -- Handle overloading of state names by functions. Traverse the -- homonym chain looking for an abstract state. if Ekind (Func) = E_Function and then Has_Homonym (Func) then pragma Assert (Is_Overloaded (N)); State := Homonym (Func); while Present (State) loop if Ekind (State) = E_Abstract_State then -- Resolve the overloading by setting the proper entity of -- the reference to that of the state. Set_Etype (N, Standard_Void_Type); Set_Entity (N, State); Set_Is_Overloaded (N, False); Generate_Reference (State, N); return; end if; State := Homonym (State); end loop; -- A function can never act as a state. If the homonym chain does -- not contain a corresponding state, then something went wrong in -- the overloading mechanism. raise Program_Error; end if; end if; end Resolve_State; ---------------------------- -- Rewrite_Assertion_Kind -- ---------------------------- procedure Rewrite_Assertion_Kind (N : Node_Id; From_Policy : Boolean := False) is Nam : Name_Id; begin Nam := No_Name; if Nkind (N) = N_Attribute_Reference and then Attribute_Name (N) = Name_Class and then Nkind (Prefix (N)) = N_Identifier then case Chars (Prefix (N)) is when Name_Pre => Nam := Name_uPre; when Name_Post => Nam := Name_uPost; when Name_Type_Invariant => Nam := Name_uType_Invariant; when Name_Invariant => Nam := Name_uInvariant; when others => return; end case; -- Recommend standard use of aspect names Pre/Post elsif Nkind (N) = N_Identifier and then From_Policy and then Serious_Errors_Detected = 0 and then not ASIS_Mode then if Chars (N) = Name_Precondition or else Chars (N) = Name_Postcondition then Error_Msg_N ("Check_Policy is a non-standard pragma??", N); Error_Msg_N ("\use Assertion_Policy and aspect names Pre/Post for " & "Ada2012 conformance?", N); end if; return; end if; if Nam /= No_Name then Rewrite (N, Make_Identifier (Sloc (N), Chars => Nam)); end if; end Rewrite_Assertion_Kind; -------- -- rv -- -------- procedure rv is begin Dummy := Dummy + 1; end rv; -------------------------------- -- Set_Encoded_Interface_Name -- -------------------------------- procedure Set_Encoded_Interface_Name (E : Entity_Id; S : Node_Id) is Str : constant String_Id := Strval (S); Len : constant Nat := String_Length (Str); CC : Char_Code; C : Character; J : Pos; 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. ------------ -- Encode -- ------------ 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). if Len = 0 or else Get_String_Char (Str, 1) = Get_Char_Code ('*') 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_Elab_Unit_Name -- ------------------------ procedure Set_Elab_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; Generate_Reference (Entity (With_Item), N, Set_Ref => False); end Set_Elab_Unit_Name; ------------------- -- Test_Case_Arg -- ------------------- function Test_Case_Arg (Prag : Node_Id; Arg_Nam : Name_Id; From_Aspect : Boolean := False) return Node_Id is Aspect : constant Node_Id := Corresponding_Aspect (Prag); Arg : Node_Id; Args : Node_Id; begin pragma Assert (Nam_In (Arg_Nam, Name_Ensures, Name_Mode, Name_Name, Name_Requires)); -- The caller requests the aspect argument if From_Aspect then if Present (Aspect) and then Nkind (Expression (Aspect)) = N_Aggregate then Args := Expression (Aspect); -- "Name" and "Mode" may appear without an identifier as a -- positional association. if Present (Expressions (Args)) then Arg := First (Expressions (Args)); if Present (Arg) and then Arg_Nam = Name_Name then return Arg; end if; -- Skip "Name" Arg := Next (Arg); if Present (Arg) and then Arg_Nam = Name_Mode then return Arg; end if; end if; -- Some or all arguments may appear as component associatons if Present (Component_Associations (Args)) then Arg := First (Component_Associations (Args)); while Present (Arg) loop if Chars (First (Choices (Arg))) = Arg_Nam then return Arg; end if; Next (Arg); end loop; end if; end if; -- Otherwise retrieve the argument directly from the pragma else Arg := First (Pragma_Argument_Associations (Prag)); if Present (Arg) and then Arg_Nam = Name_Name then return Arg; end if; -- Skip argument "Name" Arg := Next (Arg); if Present (Arg) and then Arg_Nam = Name_Mode then return Arg; end if; -- Skip argument "Mode" Arg := Next (Arg); -- Arguments "Requires" and "Ensures" are optional and may not be -- present at all. while Present (Arg) loop if Chars (Arg) = Arg_Nam then return Arg; end if; Next (Arg); end loop; end if; return Empty; end Test_Case_Arg; end Sem_Prag;