-- Semantic analysis. -- Copyright (C) 2002, 2003, 2004, 2005 Tristan Gingold -- -- This program is free software: you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation, either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT 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 -- along with this program. If not, see . with Vhdl.Evaluation; use Vhdl.Evaluation; with Errorout; use Errorout; with Vhdl.Errors; use Vhdl.Errors; with Flags; use Flags; with Types; use Types; with Vhdl.Utils; use Vhdl.Utils; with Vhdl.Parse; with Std_Names; with Vhdl.Sem_Names; use Vhdl.Sem_Names; with Vhdl.Sem_Types; with Vhdl.Sem_Decls; with Vhdl.Std_Package; with Vhdl.Sem_Scopes; with Vhdl.Nodes_Utils; use Vhdl.Nodes_Utils; with Vhdl.Xrefs; package body Vhdl.Sem_Assocs is function Rewrite_Non_Object_Association (Assoc : Iir; Inter : Iir) return Iir is N_Assoc : Iir; Actual : Iir; begin Actual := Get_Actual (Assoc); case Get_Kind (Inter) is when Iir_Kind_Interface_Package_Declaration => N_Assoc := Create_Iir (Iir_Kind_Association_Element_Package); when Iir_Kind_Interface_Type_Declaration => N_Assoc := Create_Iir (Iir_Kind_Association_Element_Type); if Get_Kind (Actual) = Iir_Kind_Parenthesis_Name then -- Convert parenthesis name to array subtype. declare N_Actual : Iir; Sub_Assoc : Iir; Indexes : Iir_List; Old : Iir; begin N_Actual := Create_Iir (Iir_Kind_Array_Subtype_Definition); Location_Copy (N_Actual, Actual); Set_Subtype_Type_Mark (N_Actual, Get_Prefix (Actual)); Sub_Assoc := Get_Association_Chain (Actual); Indexes := Create_Iir_List; while Is_Valid (Sub_Assoc) loop if Get_Kind (Sub_Assoc) /= Iir_Kind_Association_Element_By_Expression then Error_Msg_Sem (+Sub_Assoc, "index constraint must be a range"); else if Get_Formal (Sub_Assoc) /= Null_Iir then Error_Msg_Sem (+Sub_Assoc, "formal part not allowed"); end if; Append_Element (Indexes, Get_Actual (Sub_Assoc)); end if; Old := Sub_Assoc; Sub_Assoc := Get_Chain (Sub_Assoc); Free_Iir (Old); end loop; Old := Actual; Free_Iir (Old); Set_Index_Constraint_List (N_Actual, List_To_Flist (Indexes)); Actual := N_Actual; end; end if; when Iir_Kinds_Interface_Subprogram_Declaration => N_Assoc := Create_Iir (Iir_Kind_Association_Element_Subprogram); if Get_Kind (Actual) = Iir_Kind_String_Literal8 then Actual := Vhdl.Parse.String_To_Operator_Symbol (Actual); end if; when Iir_Kind_Interface_Terminal_Declaration => N_Assoc := Create_Iir (Iir_Kind_Association_Element_Terminal); when others => Error_Kind ("rewrite_non_object_association", Inter); end case; Location_Copy (N_Assoc, Assoc); Set_Formal (N_Assoc, Get_Formal (Assoc)); Set_Actual (N_Assoc, Actual); Set_Chain (N_Assoc, Get_Chain (Assoc)); Set_Whole_Association_Flag (N_Assoc, True); Free_Iir (Assoc); return N_Assoc; end Rewrite_Non_Object_Association; function Extract_Non_Object_Association (Assoc_Chain : Iir; Inter_Chain : Iir) return Iir is Inter : Iir; Assoc : Iir; -- N_Assoc : Iir; Prev_Assoc : Iir; Formal : Iir; Res : Iir; begin Inter := Inter_Chain; Assoc := Assoc_Chain; Prev_Assoc := Null_Iir; Res := Null_Iir; -- Common case: only objects in interfaces. while Is_Valid (Inter) loop exit when Get_Kind (Inter) not in Iir_Kinds_Interface_Object_Declaration; Inter := Get_Chain (Inter); end loop; if Is_Null (Inter) then -- Only interface object, nothing to to. return Assoc_Chain; end if; Inter := Inter_Chain; loop -- Don't try to detect errors. if Is_Null (Assoc) then return Res; end if; Formal := Get_Formal (Assoc); if Formal = Null_Iir then -- Positional association. if Inter = Null_Iir then -- But after a named one. Be silent on that error. null; elsif Get_Kind (Inter) not in Iir_Kinds_Interface_Object_Declaration then Assoc := Rewrite_Non_Object_Association (Assoc, Inter); end if; else if Kind_In (Formal, Iir_Kind_Simple_Name, Iir_Kind_Operator_Symbol) then -- A candidate. Search the corresponding interface. Inter := Find_Name_In_Chain (Inter_Chain, Get_Identifier (Formal)); if Inter /= Null_Iir and then Get_Kind (Inter) not in Iir_Kinds_Interface_Object_Declaration then Assoc := Rewrite_Non_Object_Association (Assoc, Inter); end if; end if; -- No more association by position. Inter := Null_Iir; end if; if Prev_Assoc = Null_Iir then Res := Assoc; else Set_Chain (Prev_Assoc, Assoc); end if; Prev_Assoc := Assoc; Assoc := Get_Chain (Assoc); if Is_Valid (Inter) then Inter := Get_Chain (Inter); end if; end loop; end Extract_Non_Object_Association; -- Analyze all arguments of ASSOC_CHAIN -- Return TRUE if no error. function Sem_Actual_Of_Association_Chain (Assoc_Chain : Iir) return Boolean is Has_Named : Boolean; Ok : Boolean; Assoc : Iir; Res : Iir; Formal : Iir; begin -- Analyze all arguments. -- OK is false if there is an error during semantic of one of the -- argument, but continue analyze. Has_Named := False; Ok := True; Assoc := Assoc_Chain; while Assoc /= Null_Iir loop Formal := Get_Formal (Assoc); if Formal /= Null_Iir then Has_Named := True; -- FIXME: check FORMAL is well composed. elsif Has_Named then -- FIXME: do the check in parser. Error_Msg_Sem (+Assoc, "positional argument after named argument"); Ok := False; end if; if Get_Kind (Assoc) = Iir_Kind_Association_Element_By_Expression then Res := Sem_Expression_Ov (Get_Actual (Assoc), Null_Iir); if Res = Null_Iir then Ok := False; else Set_Actual (Assoc, Res); end if; end if; Assoc := Get_Chain (Assoc); end loop; return Ok; end Sem_Actual_Of_Association_Chain; procedure Check_Parameter_Association_Restriction (Inter : Iir; Base_Actual : Iir; Loc : Iir) is begin case Iir_Parameter_Modes (Get_Mode (Inter)) is when Iir_In_Mode => if Can_Interface_Be_Read (Base_Actual) then return; end if; when Iir_Out_Mode => if Can_Interface_Be_Updated (Base_Actual) then return; end if; when Iir_Inout_Mode => if Can_Interface_Be_Read (Base_Actual) and then Can_Interface_Be_Updated (Base_Actual) then return; end if; end case; Error_Msg_Sem (+Loc, "cannot associate an " & Get_Mode_Name (Get_Mode (Base_Actual)) & " object with " & Get_Mode_Name (Get_Mode (Inter)) & " %n", +Inter); end Check_Parameter_Association_Restriction; procedure Check_Subprogram_Association_Expression (Formal : Iir; Actual : Iir; Assoc : Iir; Loc : Iir) is Prefix : Iir; Object : Iir; begin if Actual = Null_Iir then -- Skip in case of errors. return; end if; Object := Name_To_Object (Actual); if Object /= Null_Iir then Prefix := Get_Object_Prefix (Object); else Prefix := Actual; end if; case Get_Kind (Formal) is when Iir_Kind_Interface_Signal_Declaration => -- LRM93 2.1.1 -- In a subprogram call, the actual designator -- associated with a formal parameter of class -- signal must be a signal. case Get_Kind (Prefix) is when Iir_Kind_Interface_Signal_Declaration | Iir_Kind_Signal_Declaration | Iir_Kind_Guard_Signal_Declaration | Iir_Kinds_Signal_Attribute => -- LRM93 2.1.1.2 -- If an actual signal is associated with -- a signal parameter of any mode, the actual -- must be denoted by a static signal name. if Get_Name_Staticness (Object) < Globally then Error_Msg_Sem (+Actual, "actual signal must be a static name"); else -- Inherit has_active_flag. Set_Has_Active_Flag (Prefix, Get_Has_Active_Flag (Formal)); end if; when others => Error_Msg_Sem (+Loc, "signal parameter requires a signal expression"); end case; case Get_Kind (Prefix) is when Iir_Kind_Interface_Signal_Declaration => Check_Parameter_Association_Restriction (Formal, Prefix, Loc); when Iir_Kind_Guard_Signal_Declaration => if Get_Mode (Formal) /= Iir_In_Mode then Error_Msg_Sem (+Loc, "cannot associate a guard signal with " & Get_Mode_Name (Get_Mode (Formal)) & " %n", +Formal); end if; when Iir_Kinds_Signal_Attribute => if Get_Mode (Formal) /= Iir_In_Mode then Error_Msg_Sem (+Loc, "cannot associate a signal attribute with " & Get_Mode_Name (Get_Mode (Formal)) & " %n", +Formal); end if; when others => null; end case; -- LRM 2.1.1.2 Signal parameters -- It is an error if a conversion function or type -- conversion appears in either the formal part or the -- actual part of an association element that associates -- an actual signal with a formal signal parameter. if Assoc /= Null_Iir and then (Get_Actual_Conversion (Assoc) /= Null_Iir or Get_Formal_Conversion (Assoc) /= Null_Iir) then Error_Msg_Sem (+Assoc, "conversion are not allowed for signal parameters"); end if; when Iir_Kind_Interface_Variable_Declaration => -- LRM93 2.1.1 -- The actual designator associated with a formal of -- class variable must be a variable. case Get_Kind (Prefix) is when Iir_Kind_Interface_Variable_Declaration => Check_Parameter_Association_Restriction (Formal, Prefix, Loc); when Iir_Kind_Variable_Declaration | Iir_Kind_Dereference | Iir_Kind_Implicit_Dereference => null; when Iir_Kind_Interface_File_Declaration | Iir_Kind_File_Declaration => -- LRM87 4.3.1.4 -- Such an object is a member of the variable -- class of objects; if Flags.Vhdl_Std >= Vhdl_93 and then not Flags.Flag_Relaxed_Files87 then Error_Msg_Sem (+Loc, "variable parameter cannot be a file (vhdl93)"); end if; when others => Error_Msg_Sem (+Loc, "variable parameter must be a variable"); end case; when Iir_Kind_Interface_File_Declaration => -- LRM93 2.1.1 -- The actual designator associated with a formal -- of class file must be a file. case Get_Kind (Prefix) is when Iir_Kind_Interface_File_Declaration | Iir_Kind_File_Declaration => null; when Iir_Kind_Variable_Declaration | Iir_Kind_Interface_Variable_Declaration => if Flags.Vhdl_Std >= Vhdl_93 and then not Flags.Flag_Relaxed_Files87 then Error_Msg_Sem (+Loc, "file parameter must be a file (vhdl93)"); end if; when others => Error_Msg_Sem (+Loc, "file parameter must be a file"); end case; -- LRM 2.1.1.3 File parameters -- It is an error if an association element associates -- an actual with a formal parameter of a file type and -- that association element contains a conversion -- function or type conversion. if Assoc /= Null_Iir and then (Get_Actual_Conversion (Assoc) /= Null_Iir or Get_Formal_Conversion (Assoc) /= Null_Iir) then Error_Msg_Sem (+Assoc, "conversion are not allowed " & "for file parameters"); end if; when Iir_Kind_Interface_Constant_Declaration => -- LRM93 2.1.1 -- The actual designator associated with a formal of -- class constant must be an expression. -- GHDL: unless this is in a formal_part. if Assoc = Null_Iir or else not Get_In_Formal_Flag (Assoc) then Check_Read (Actual); end if; when others => Error_Kind ("check_subprogram_association_expression", Formal); end case; case Get_Kind (Prefix) is when Iir_Kind_Signal_Declaration | Iir_Kind_Variable_Declaration => Set_Use_Flag (Prefix, True); when others => null; end case; end Check_Subprogram_Association_Expression; procedure Check_Subprogram_Associations (Inter_Chain : Iir; Assoc_Chain : Iir) is Assoc : Iir; Formal_Inter : Iir; Actual : Iir; Inter : Iir; begin Assoc := Assoc_Chain; Inter := Inter_Chain; while Assoc /= Null_Iir loop Formal_Inter := Get_Association_Interface (Assoc, Inter); case Get_Kind (Assoc) is when Iir_Kind_Association_Element_Open => if Get_Default_Value (Formal_Inter) = Null_Iir then Error_Msg_Sem (+Assoc, "no parameter for %n", +Formal_Inter); end if; when Iir_Kind_Association_Element_By_Expression => Actual := Get_Actual (Assoc); Check_Subprogram_Association_Expression (Formal_Inter, Actual, Assoc, Assoc); when Iir_Kind_Association_Element_By_Individual => null; when others => Error_Kind ("check_subprogram_associations", Assoc); end case; Next_Association_Interface (Assoc, Inter); end loop; end Check_Subprogram_Associations; -- Assocs_Right_Map (FORMAL_MODE, ACTUAL_MODE) is true iff it is allowed -- to associate a formal port of mode FORMAL_MODE with an actual port of -- mode ACTUAL_MODE. subtype Iir_Known_Mode is Iir_Mode range Iir_Linkage_Mode .. Iir_In_Mode; type Assocs_Right_Map is array (Iir_Known_Mode, Iir_Known_Mode) of Boolean; -- LRM93 1.1.1.2 Ports Vhdl93_Assocs_Map : constant Assocs_Right_Map := (Iir_In_Mode => (Iir_In_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Out_Mode => (Iir_Out_Mode | Iir_Inout_Mode => True, others => False), Iir_Inout_Mode => (Iir_Inout_Mode => True, others => False), Iir_Buffer_Mode => (Iir_Buffer_Mode => True, others => False), Iir_Linkage_Mode => (others => True)); -- LRM02 1.1.1.2 Ports Vhdl02_Assocs_Map : constant Assocs_Right_Map := (Iir_In_Mode => (Iir_In_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Out_Mode => (Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Inout_Mode => (Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Buffer_Mode => (Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Linkage_Mode => (others => True)); -- LRM08 6.5.6.3 Port clauses Vhdl08_Assocs_Map : constant Assocs_Right_Map := (Iir_In_Mode => (Iir_In_Mode | Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Out_Mode => (Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Inout_Mode => (Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Buffer_Mode => (Iir_Out_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => True, others => False), Iir_Linkage_Mode => (others => True)); -- Check for restrictions in LRM 1.1.1.2 -- Return FALSE in case of error. function Check_Port_Association_Mode_Restrictions (Formal : Iir_Interface_Signal_Declaration; Actual : Iir_Interface_Signal_Declaration; Assoc : Iir) return Boolean is Fmode : constant Iir_Mode := Get_Mode (Formal); Amode : constant Iir_Mode := Get_Mode (Actual); begin pragma Assert (Fmode /= Iir_Unknown_Mode); pragma Assert (Amode /= Iir_Unknown_Mode); case Flags.Vhdl_Std is when Vhdl_87 | Vhdl_93 | Vhdl_00 => if Vhdl93_Assocs_Map (Fmode, Amode) then return True; end if; when Vhdl_02 => if Vhdl02_Assocs_Map (Fmode, Amode) then return True; end if; when Vhdl_08 | Vhdl_19 => if Vhdl08_Assocs_Map (Fmode, Amode) then return True; end if; end case; if Assoc /= Null_Iir then Error_Msg_Sem (+Assoc, "cannot associate " & Get_Mode_Name (Fmode) & " %n" & " with actual port of mode " & Get_Mode_Name (Amode), +Formal); end if; return False; end Check_Port_Association_Mode_Restrictions; -- Check restrictions of LRM02 12.2.4 procedure Check_Port_Association_Bounds_Restrictions (Formal : Iir; Actual : Iir; Assoc : Iir) is Inter : constant Iir := Get_Object_Prefix (Formal, False); function Is_Scalar_Type_Compatible (Src : Iir; Dest : Iir) return Boolean is Src_Range : Iir; Dst_Range : Iir; begin if Get_Kind (Src) not in Iir_Kinds_Scalar_Type_And_Subtype_Definition then -- It's only for scalar types. return True; end if; if Get_Kind (Dest) not in Iir_Kinds_Scalar_Type_And_Subtype_Definition then -- Avoid a crash in case of errors. return True; end if; if Get_Kind (Src) = Iir_Kind_Foreign_Vector_Type_Definition or else Get_Kind (Dest) = Iir_Kind_Foreign_Vector_Type_Definition then return True; end if; Src_Range := Get_Range_Constraint (Src); Dst_Range := Get_Range_Constraint (Dest); if Get_Expr_Staticness (Src_Range) /= Locally or else Get_Expr_Staticness (Dst_Range) /= Locally then return True; end if; -- FIXME: non-static bounds have to be checked at run-time -- (during elaboration). -- In vhdl08, the subtypes must be compatible. Use the that rule -- for relaxed rules. if Vhdl_Std >= Vhdl_08 or else Flag_Relaxed_Rules then return Eval_Is_Range_In_Bound (Src, Dest, True); end if; -- Prior vhdl08, the subtypes must be identical. if not Eval_Is_Eq (Get_Left_Limit (Src_Range), Get_Left_Limit (Dst_Range)) or else not Eval_Is_Eq (Get_Right_Limit (Src_Range), Get_Right_Limit (Dst_Range)) or else Get_Direction (Src_Range) /= Get_Direction (Dst_Range) then return False; end if; return True; end Is_Scalar_Type_Compatible; procedure Error_Msg is Id : Msgid_Type; Orig : Report_Origin; begin if Flag_Elaborate then Id := Msgid_Error; Orig := Elaboration; else Id := Warnid_Port_Bounds; Orig := Semantic; end if; Report_Msg (Id, Orig, +Assoc, "bounds or direction of actual don't match with %n", (1 => +Inter)); end Error_Msg; Ftype : constant Iir := Get_Type (Formal); Atype : constant Iir := Get_Type (Actual); F_Conv : constant Iir := Get_Formal_Conversion (Assoc); A_Conv : constant Iir := Get_Actual_Conversion (Assoc); F2a_Type : Iir; A2f_Type : Iir; begin -- LRM02 12.2.4 The port map aspect -- If an actual signal is associated with a port of any mode, and if -- the type of the formal is a scalar type, then it is an error if -- (after applying any conversion function or type conversion -- expression present in the actual part) the bounds and direction of -- the subtype denoted by the subtype indication of the formal are not -- identical to the bounds and direction of the subtype denoted by the -- subtype indication of the actual. -- LRM08 14.3.5 Port map aspect -- If an actual signal is associated with a port of mode IN or INOUT, -- and if the type of the formal is a scalar type, then it is an error -- if (after applying any conversion function or type conversion -- expression present in the actual part) the subtype of the actual is -- not compatible with the subtype of the formal. [...] -- -- Similarly, if an actual signal is associated with a port of mode -- OUT, INOUT, or BUFFER, and the type of the actual is a scalar type, -- then it is an error if (after applying any conversion function or -- type conversion expression present in the formal part) the subtype -- or the formal is not compatible with the subtype of the actual. if Is_Valid (F_Conv) then F2a_Type := Get_Type (F_Conv); else F2a_Type := Ftype; end if; if Is_Valid (A_Conv) then A2f_Type := Get_Type (A_Conv); else A2f_Type := Atype; end if; if Get_Mode (Inter) in Iir_In_Modes and then not Is_Scalar_Type_Compatible (A2f_Type, Ftype) then Error_Msg; end if; if Get_Mode (Inter) in Iir_Out_Modes and then not Is_Scalar_Type_Compatible (F2a_Type, Atype) then Error_Msg; end if; end Check_Port_Association_Bounds_Restrictions; -- Handle indexed name -- FORMAL is the formal name to be handled. -- BASE_ASSOC is an association_by_individual in which the formal will be -- inserted. procedure Add_Individual_Assoc_Indexed_Name (Choice : out Iir; Base_Assoc : Iir; Formal : Iir) is Index_List : constant Iir_Flist := Get_Index_List (Formal); Nbr : constant Natural := Get_Nbr_Elements (Index_List); Last_Choice : Iir; Index : Iir; Staticness : Iir_Staticness; Sub_Assoc : Iir; begin -- Find element. Sub_Assoc := Base_Assoc; for I in 0 .. Nbr - 1 loop Index := Get_Nth_Element (Index_List, I); -- Evaluate index. Staticness := Get_Expr_Staticness (Index); if Staticness = Locally then Index := Eval_Expr (Index); Set_Nth_Element (Index_List, I, Index); else Error_Msg_Sem (+Index, "index expression must be locally static"); Set_Choice_Staticness (Base_Assoc, None); end if; -- Find index in choice list. Last_Choice := Null_Iir; Choice := Get_Individual_Association_Chain (Sub_Assoc); while Choice /= Null_Iir loop case Get_Kind (Choice) is when Iir_Kind_Choice_By_Expression => if Eval_Pos (Get_Choice_Expression (Choice)) = Eval_Pos (Index) then goto Found; end if; when Iir_Kind_Choice_By_Range => declare Choice_Range : constant Iir := Get_Choice_Range (Choice); begin if Get_Expr_Staticness (Choice_Range) = Locally and then Eval_Int_In_Range (Eval_Pos (Index), Choice_Range) then -- FIXME: overlap. raise Internal_Error; end if; end; when others => Error_Kind ("add_individual_assoc_index_name", Choice); end case; Last_Choice := Choice; Choice := Get_Chain (Choice); end loop; -- If not found, append it. Choice := Create_Iir (Iir_Kind_Choice_By_Expression); Set_Choice_Expression (Choice, Index); Set_Choice_Staticness (Choice, Staticness); Location_Copy (Choice, Formal); if Last_Choice = Null_Iir then Set_Individual_Association_Chain (Sub_Assoc, Choice); else Set_Chain (Last_Choice, Choice); end if; << Found >> null; if I < Nbr - 1 then -- Create an intermediate assoc by individual. Sub_Assoc := Get_Associated_Expr (Choice); if Sub_Assoc = Null_Iir then Sub_Assoc := Create_Iir (Iir_Kind_Association_Element_By_Individual); Location_Copy (Sub_Assoc, Index); Set_Associated_Expr (Choice, Sub_Assoc); Set_Choice_Staticness (Sub_Assoc, Locally); end if; end if; end loop; end Add_Individual_Assoc_Indexed_Name; procedure Add_Individual_Assoc_Slice_Name (Choice : out Iir; Sub_Assoc : Iir; Formal : Iir) is Index : Iir; Staticness : Iir_Staticness; begin -- FIXME: handle cases such as param(5 to 6)(5) -- Find element. Index := Get_Suffix (Formal); -- Evaluate index. Staticness := Get_Expr_Staticness (Index); if Staticness = Locally then Index := Eval_Range (Index); Set_Suffix (Formal, Index); else Error_Msg_Sem (+Index, "range expression must be locally static"); Set_Choice_Staticness (Sub_Assoc, None); end if; Choice := Create_Iir (Iir_Kind_Choice_By_Range); Location_Copy (Choice, Formal); Set_Choice_Range (Choice, Index); Set_Chain (Choice, Get_Individual_Association_Chain (Sub_Assoc)); Set_Choice_Staticness (Choice, Staticness); Set_Individual_Association_Chain (Sub_Assoc, Choice); end Add_Individual_Assoc_Slice_Name; procedure Add_Individual_Assoc_Selected_Name (Choice : out Iir; Sub_Assoc : Iir; Formal : Iir) is Element : constant Iir := Get_Named_Entity (Formal); Last_Choice : Iir; begin -- Try to find the existing choice. Last_Choice := Null_Iir; Choice := Get_Individual_Association_Chain (Sub_Assoc); while Choice /= Null_Iir loop if Get_Choice_Name (Choice) = Element then return; end if; Last_Choice := Choice; Choice := Get_Chain (Choice); end loop; -- If not found, append it. Choice := Create_Iir (Iir_Kind_Choice_By_Name); Location_Copy (Choice, Formal); Set_Choice_Name (Choice, Element); if Last_Choice = Null_Iir then Set_Individual_Association_Chain (Sub_Assoc, Choice); else Set_Chain (Last_Choice, Choice); end if; end Add_Individual_Assoc_Selected_Name; -- Subroutine of Add_Individual_Association. -- Search/build the tree of choices for FORMAL, starting for IASSOC. -- The root of the tree is an association by individual node. Each node -- points to a chain of choices, whose associated expression is either an -- association by individual (and the tree continue) or an association -- by expression coming from the initial association (and this is a leaf). procedure Add_Individual_Association_1 (Iassoc : in out Iir; Formal : Iir; Last : Boolean) is Base_Assoc : constant Iir := Iassoc; Formal_Object : constant Iir := Name_To_Object (Formal); Sub : Iir; Choice : Iir; begin pragma Assert (Get_Kind (Iassoc) = Iir_Kind_Association_Element_By_Individual); -- Recurse to start from the basename of the formal. case Get_Kind (Formal_Object) is when Iir_Kind_Indexed_Name | Iir_Kind_Slice_Name | Iir_Kind_Selected_Element => Add_Individual_Association_1 (Iassoc, Get_Prefix (Formal_Object), False); when Iir_Kinds_Interface_Object_Declaration => -- At the root of the formal. pragma Assert (Formal_Object = Get_Named_Entity (Get_Formal (Iassoc))); return; when others => Error_Kind ("add_individual_association_1", Formal); end case; -- Add the choices for the indexes/slice/element. case Get_Kind (Formal_Object) is when Iir_Kind_Indexed_Name => Add_Individual_Assoc_Indexed_Name (Choice, Iassoc, Formal_Object); when Iir_Kind_Slice_Name => Add_Individual_Assoc_Slice_Name (Choice, Iassoc, Formal_Object); when Iir_Kind_Selected_Element => Add_Individual_Assoc_Selected_Name (Choice, Iassoc, Formal_Object); when others => Error_Kind ("add_individual_association_1(3)", Formal); end case; Sub := Get_Associated_Expr (Choice); if Sub = Null_Iir then if not Last then -- Create the individual association for the choice. Sub := Create_Iir (Iir_Kind_Association_Element_By_Individual); Location_Copy (Sub, Formal); Set_Choice_Staticness (Sub, Locally); Set_Formal (Sub, Formal); Set_Associated_Expr (Choice, Sub); end if; else if Last or else Get_Kind (Sub) /= Iir_Kind_Association_Element_By_Individual then -- A final association. pragma Assert (Get_Kind (Sub) = Iir_Kind_Association_Element_By_Expression); Error_Msg_Sem (+Formal, "individual association of %n" & " conflicts with that at %l", (+Get_Interface_Of_Formal (Get_Formal (Iassoc)), +Sub)); else if Get_Choice_Staticness (Sub) /= Locally then -- Propagate error. Set_Choice_Staticness (Base_Assoc, None); end if; end if; end if; if Last then Iassoc := Choice; else Iassoc := Sub; end if; end Add_Individual_Association_1; -- Insert ASSOC into the tree of individual assoc rooted by IASSOC. -- This is done so that duplicate or missing associations are found (using -- the same routine for aggregate/case statement). procedure Add_Individual_Association (Iassoc : Iir; Assoc : Iir) is Formal : constant Iir := Get_Formal (Assoc); Res_Iass : Iir; Prev : Iir; begin -- Create the individual association for the formal. Res_Iass := Iassoc; Add_Individual_Association_1 (Res_Iass, Formal, True); Prev := Get_Associated_Expr (Res_Iass); if Prev = Null_Iir then -- It is the first one, add it. Set_Associated_Expr (Res_Iass, Assoc); end if; end Add_Individual_Association; procedure Finish_Individual_Association1 (Assoc : Iir; Atype : Iir); procedure Finish_Individual_Assoc_Array_Subtype (Assoc : Iir; Atype : Iir; Dim : Positive) is Index_Tlist : constant Iir_Flist := Get_Index_Subtype_List (Atype); Nbr_Dims : constant Natural := Get_Nbr_Elements (Index_Tlist); Index_Type : constant Iir := Get_Nth_Element (Index_Tlist, Dim - 1); Chain : constant Iir := Get_Individual_Association_Chain (Assoc); Low, High : Iir; El_Type : Iir; El : Iir; begin Sem_Check_Continuous_Choices (Chain, Index_Type, Low, High, Get_Location (Assoc), False); if Dim < Nbr_Dims then El := Chain; while El /= Null_Iir loop pragma Assert (Get_Kind (El) = Iir_Kind_Choice_By_Expression); Finish_Individual_Assoc_Array_Subtype (Get_Associated_Expr (El), Atype, Dim + 1); El := Get_Chain (El); end loop; else El_Type := Get_Element_Subtype (Atype); El := Chain; while El /= Null_Iir loop Finish_Individual_Association1 (Get_Associated_Expr (El), El_Type); El := Get_Chain (El); end loop; end if; end Finish_Individual_Assoc_Array_Subtype; procedure Finish_Individual_Assoc_Array (Actual : Iir; Assoc : Iir; Dim : Natural) is Actual_Type : constant Iir := Get_Actual_Type (Actual); Index_Tlist : constant Iir_Flist := Get_Index_Subtype_List (Actual_Type); Actual_Index : Iir; Base_Type : Iir; Base_Index : Iir; Low, High : Iir; Chain : Iir; begin Actual_Index := Get_Nth_Element (Index_Tlist, Dim - 1); if Actual_Index /= Null_Iir then Base_Index := Actual_Index; else Base_Type := Get_Base_Type (Actual_Type); Base_Index := Get_Index_Type (Base_Type, Dim - 1); end if; Chain := Get_Individual_Association_Chain (Assoc); Sem_Choices_Range (Chain, Base_Index, Low, High, Get_Location (Assoc), True, False); Set_Individual_Association_Chain (Assoc, Chain); if Actual_Index = Null_Iir then declare Index_Constraint : Iir; Index_Subtype_Constraint : Iir; begin -- Create an index subtype. case Get_Kind (Base_Index) is when Iir_Kind_Integer_Subtype_Definition => Actual_Index := Create_Iir (Iir_Kind_Integer_Subtype_Definition); when Iir_Kind_Enumeration_Type_Definition | Iir_Kind_Enumeration_Subtype_Definition => Actual_Index := Create_Iir (Iir_Kind_Enumeration_Subtype_Definition); when others => Error_Kind ("finish_individual_assoc_array", Base_Index); end case; Location_Copy (Actual_Index, Actual); Set_Parent_Type (Actual_Index, Base_Index); Index_Constraint := Get_Range_Constraint (Base_Index); Index_Subtype_Constraint := Create_Iir (Iir_Kind_Range_Expression); Location_Copy (Index_Subtype_Constraint, Actual); Set_Range_Constraint (Actual_Index, Index_Subtype_Constraint); Set_Type_Staticness (Actual_Index, Locally); Set_Direction (Index_Subtype_Constraint, Get_Direction (Index_Constraint)); -- For ownership purpose, the bounds must be copied otherwise -- they would be referenced before being defined. This is non -- optimal but it doesn't happen often. Low := Copy_Constant (Low); High := Copy_Constant (High); case Get_Direction (Index_Constraint) is when Dir_To => Set_Left_Limit (Index_Subtype_Constraint, Low); Set_Left_Limit_Expr (Index_Subtype_Constraint, Low); Set_Right_Limit (Index_Subtype_Constraint, High); Set_Right_Limit_Expr (Index_Subtype_Constraint, High); when Dir_Downto => Set_Left_Limit (Index_Subtype_Constraint, High); Set_Left_Limit_Expr (Index_Subtype_Constraint, High); Set_Right_Limit (Index_Subtype_Constraint, Low); Set_Right_Limit_Expr (Index_Subtype_Constraint, Low); end case; Set_Expr_Staticness (Index_Subtype_Constraint, Locally); Set_Nth_Element (Get_Index_Subtype_List (Actual_Type), Dim - 1, Actual_Index); end; else declare Act_High, Act_Low : Iir; begin Get_Low_High_Limit (Get_Range_Constraint (Actual_Type), Act_Low, Act_High); if Eval_Pos (Act_Low) /= Eval_Pos (Low) or Eval_Pos (Act_High) /= Eval_Pos (High) then Error_Msg_Sem (+Assoc, "indexes of individual association mismatch"); end if; end; end if; declare Nbr_Dims : constant Natural := Get_Nbr_Elements (Index_Tlist); El_Type : Iir; El : Iir; begin if Dim = Nbr_Dims then El_Type := Get_Element_Subtype (Actual_Type); El := Chain; while El /= Null_Iir loop Finish_Individual_Association1 (Get_Associated_Expr (El), El_Type); El := Get_Chain (El); end loop; end if; end; end Finish_Individual_Assoc_Array; procedure Finish_Individual_Assoc_Record (Assoc : Iir; Atype : Iir) is El_List : constant Iir_Flist := Get_Elements_Declaration_List (Atype); Nbr_El : constant Natural := Get_Nbr_Elements (El_List); Matches : Iir_Array (0 .. Nbr_El - 1); Ch : Iir; Pos : Natural; Rec_El : Iir; begin -- Check for duplicate associations. Matches := (others => Null_Iir); Ch := Get_Individual_Association_Chain (Assoc); while Ch /= Null_Iir loop Rec_El := Get_Choice_Name (Ch); Pos := Natural (Get_Element_Position (Rec_El)); if Matches (Pos) /= Null_Iir then Error_Msg_Sem (+Ch, "individual %n already associated at %l", (+Rec_El, +Matches (Pos))); else Matches (Pos) := Ch; end if; Ch := Get_Chain (Ch); end loop; -- Check for missing associations. for I in Matches'Range loop Rec_El := Get_Nth_Element (El_List, I); if Matches (I) = Null_Iir then Error_Msg_Sem (+Assoc, "%n not associated", +Rec_El); else Finish_Individual_Association1 (Get_Associated_Expr (Matches (I)), Get_Type (Rec_El)); end if; end loop; if Get_Constraint_State (Atype) /= Fully_Constrained then -- Some (sub-)elements are unbounded, create a bounded subtype. declare Inter : constant Iir := Get_Interface_Of_Formal (Get_Formal (Assoc)); Ntype : Iir; Nel_List : Iir_Flist; Nrec_El : Iir; Rec_El_Type : Iir; Staticness : Iir_Staticness; Assoc_Expr : Iir; Assoc_Type : Iir; begin Ntype := Create_Iir (Iir_Kind_Record_Subtype_Definition); Set_Is_Ref (Ntype, True); Location_Copy (Ntype, Assoc); Set_Parent_Type (Ntype, Atype); if Get_Kind (Atype) = Iir_Kind_Record_Subtype_Definition then Set_Resolution_Indication (Ntype, Get_Resolution_Indication (Atype)); end if; if Get_Kind (Inter) = Iir_Kind_Interface_Signal_Declaration then -- The subtype is used for signals. Set_Has_Signal_Flag (Ntype, True); end if; Nel_List := Create_Iir_Flist (Nbr_El); Set_Elements_Declaration_List (Ntype, Nel_List); Staticness := Locally; for I in Matches'Range loop Rec_El := Get_Nth_Element (El_List, I); Rec_El_Type := Get_Type (Rec_El); if (Get_Kind (Rec_El_Type) not in Iir_Kinds_Composite_Type_Definition) or else Get_Constraint_State (Rec_El_Type) = Fully_Constrained or else Matches (I) = Null_Iir -- In case of error. then Nrec_El := Rec_El; else Nrec_El := Create_Iir (Iir_Kind_Record_Element_Constraint); Ch := Matches (I); Location_Copy (Nrec_El, Ch); Set_Parent (Nrec_El, Ntype); Set_Identifier (Nrec_El, Get_Identifier (Rec_El)); pragma Assert (I = Natural (Get_Element_Position (Rec_El))); Set_Element_Position (Nrec_El, Iir_Index32 (I)); Assoc_Expr := Get_Associated_Expr (Ch); if (Get_Kind (Assoc_Expr) = Iir_Kind_Association_Element_By_Individual) then Assoc_Type := Get_Actual_Type (Assoc_Expr); Set_Subtype_Indication (Nrec_El, Assoc_Type); else Assoc_Type := Get_Type (Get_Actual (Assoc_Expr)); end if; Set_Type (Nrec_El, Assoc_Type); Append_Owned_Element_Constraint (Ntype, Nrec_El); end if; Staticness := Min (Staticness, Get_Type_Staticness (Get_Type (Nrec_El))); Set_Nth_Element (Nel_List, I, Nrec_El); end loop; Set_Type_Staticness (Ntype, Staticness); Set_Constraint_State (Ntype, Fully_Constrained); Set_Actual_Type (Assoc, Ntype); Set_Actual_Type_Definition (Assoc, Ntype); end; else Set_Actual_Type (Assoc, Atype); end if; end Finish_Individual_Assoc_Record; -- Free recursively all the choices of ASSOC. Once the type is computed -- this is not needed anymore. procedure Clean_Individual_Association (Assoc : Iir) is El, N_El : Iir; Expr : Iir; begin El := Get_Individual_Association_Chain (Assoc); Set_Individual_Association_Chain (Assoc, Null_Iir); while Is_Valid (El) loop N_El := Get_Chain (El); pragma Assert (Get_Kind (El) in Iir_Kinds_Choice); Expr := Get_Associated_Expr (El); if Get_Kind (Expr) = Iir_Kind_Association_Element_By_Individual then Clean_Individual_Association (Expr); Free_Iir (Expr); end if; Free_Iir (El); El := N_El; end loop; end Clean_Individual_Association; procedure Finish_Individual_Association1 (Assoc : Iir; Atype : Iir) is Ntype : Iir; begin if Get_Kind (Assoc) /= Iir_Kind_Association_Element_By_Individual then -- End of recursion. The association is an element association, -- not an individual one. return; end if; case Get_Kind (Atype) is when Iir_Kind_Array_Subtype_Definition | Iir_Kind_Array_Type_Definition => if Get_Constraint_State (Atype) = Fully_Constrained then Finish_Individual_Assoc_Array_Subtype (Assoc, Atype, 1); Set_Actual_Type (Assoc, Atype); else Ntype := Create_Array_Subtype (Atype, Get_Location (Assoc)); Set_Index_Constraint_Flag (Ntype, True); Set_Constraint_State (Ntype, Fully_Constrained); Set_Has_Signal_Flag (Ntype, Get_Has_Signal_Flag (Atype)); Set_Actual_Type (Assoc, Ntype); Set_Actual_Type_Definition (Assoc, Ntype); Finish_Individual_Assoc_Array (Assoc, Assoc, 1); end if; when Iir_Kind_Record_Type_Definition | Iir_Kind_Record_Subtype_Definition => Finish_Individual_Assoc_Record (Assoc, Atype); when Iir_Kinds_Scalar_Type_And_Subtype_Definition => null; when others => Error_Kind ("finish_individual_association", Atype); end case; end Finish_Individual_Association1; -- Called by sem_individual_association to finish the analyze of -- individual association ASSOC: compute bounds, detect missing elements. procedure Finish_Individual_Association (Assoc : Iir) is Inter : Iir; Atype : Iir; begin -- Guard. if Get_Choice_Staticness (Assoc) /= Locally then return; end if; Inter := Get_Interface_Of_Formal (Get_Formal (Assoc)); Atype := Get_Type (Inter); Set_Whole_Association_Flag (Assoc, True); Finish_Individual_Association1 (Assoc, Atype); -- Free the hierarchy, keep only the top individual association. Clean_Individual_Association (Assoc); end Finish_Individual_Association; -- Analyze all individual associations of ASSOCS: -- Create an Iir_Kind_Association_Element_By_Individual node before each -- group of individual association for the same formal, call -- and call Add_Individual_Association for each individual association for -- the same formal, and finally call Finish_Individual_Association at the -- end of each group. -- -- The purpose of By_Individual association is to have the type of the -- actual (might be an array subtype), and also to be sure that all -- sub-elements are associated. For that a tree is created. The tree is -- rooted by the top Association_Element_By_Individual, which contains a -- chain of choices (like the aggregate). The child of a choice is either -- an Association_Element written by the user, or a new subtree rooted -- by another Association_Element_By_Individual. -- -- Eg: -- formal (1, 0).ela => act1, -- formal (1, 0).elb => act2, -- formal (1, 1) => act3, -- formal (2, 0) => act4, -- formal (2, 1) => act5, -- -- Association_Element_By_Individual (Root) -- +- Choice_By_Expression (1) -- | +- Association_Element_By_Individual -- | +- Choice_By_Expression (0) -- | | +- Association_Element_By_Individual -- | | +- Choice_By_Name (ela) -- | | +- Association_Element_By_Expression (act1) -- | | +- Choice_By_Name (elb) -- | | +- Association_Element_By_Expression (act2) -- | +- Choice_By_Expression (1) -- | +- Association_Element_By_Expression (act3) -- +- Choice_By_Expression (2) -- +- Association_Element_By_Individual -- +- Choice_By_Expression (0) -- | +- Association_Element_By_Expression (act4) -- +- Choice_By_Expression (1) -- +- Association_Element_By_Expression (act5) -- -- The tree doesn't follow all the ownership rules: the formal of -- sub association_element are directly set to the association, -- and the associated_expr of the choices are directly set to -- formals. -- -- This tree is temporary (used only during analysis of the individual -- association) and removed once the check is done. procedure Sem_Individual_Association (Assoc_Chain : in out Iir) is Assoc : Iir; Prev_Assoc : Iir; Iassoc : Iir_Association_Element_By_Individual; Cur_Iface : Iir; Formal : Iir; begin Iassoc := Null_Iir; Cur_Iface := Null_Iir; Prev_Assoc := Null_Iir; Assoc := Assoc_Chain; while Assoc /= Null_Iir loop Formal := Get_Formal (Assoc); if Formal /= Null_Iir then Formal := Get_Object_Prefix (Formal); end if; if Formal = Null_Iir or else Formal /= Cur_Iface then -- New formal name, analyze the current individual association -- (if any). if Iassoc /= Null_Iir then Finish_Individual_Association (Iassoc); end if; Cur_Iface := Formal; Iassoc := Null_Iir; end if; if Get_Whole_Association_Flag (Assoc) = False then -- Individual association. if Iassoc = Null_Iir then -- The first one for the interface: create a new individual -- association. Iassoc := Create_Iir (Iir_Kind_Association_Element_By_Individual); Location_Copy (Iassoc, Assoc); Set_Choice_Staticness (Iassoc, Locally); pragma Assert (Cur_Iface /= Null_Iir); Set_Formal (Iassoc, Build_Simple_Name (Cur_Iface, Get_Location (Formal))); -- Insert IASSOC. if Prev_Assoc = Null_Iir then Assoc_Chain := Iassoc; else Set_Chain (Prev_Assoc, Iassoc); end if; Set_Chain (Iassoc, Assoc); end if; -- Add this individual association to the tree. Add_Individual_Association (Iassoc, Assoc); end if; Prev_Assoc := Assoc; Assoc := Get_Chain (Assoc); end loop; -- There is maybe a remaining iassoc. if Iassoc /= Null_Iir then Finish_Individual_Association (Iassoc); end if; end Sem_Individual_Association; function Is_Conversion_Function (Assoc_Chain : Iir) return Boolean is begin -- [...] whose single parameter of the function [...] if not Is_Chain_Length_One (Assoc_Chain) then return False; end if; if Get_Kind (Assoc_Chain) /= Iir_Kind_Association_Element_By_Expression then return False; end if; -- FIXME: unfortunatly, the formal may already be set with the -- interface. -- if Get_Formal (Assoc_Chain) /= Null_Iir then -- return Null_Iir; -- end if; return True; end Is_Conversion_Function; function Is_Valid_Type_Conversion (Conv : Iir; Res_Base_Type : Iir; Param_Base_Type : Iir) return Boolean is Atype : constant Iir := Get_Type (Conv); begin return Get_Base_Type (Atype) = Res_Base_Type and then Are_Types_Closely_Related (Atype, Param_Base_Type); end Is_Valid_Type_Conversion; function Is_Valid_Function_Conversion (Call : Iir; Res_Base_Type : Iir; Param_Base_Type : Iir) return Boolean is Imp : constant Iir := Get_Implementation (Call); Res_Type : constant Iir := Get_Type (Imp); Inters : constant Iir := Get_Interface_Declaration_Chain (Imp); Param_Type : Iir; begin if Inters = Null_Iir then return False; end if; Param_Type := Get_Type (Inters); return Get_Base_Type (Res_Type) = Res_Base_Type and then Get_Base_Type (Param_Type) = Param_Base_Type; end Is_Valid_Function_Conversion; function Is_Valid_Conversion (Func : Iir; Res_Base_Type : Iir; Param_Base_Type : Iir) return Boolean is begin case Get_Kind (Func) is when Iir_Kind_Function_Call => return Is_Valid_Function_Conversion (Func, Res_Base_Type, Param_Base_Type); when Iir_Kind_Type_Conversion => return Is_Valid_Type_Conversion (Func, Res_Base_Type, Param_Base_Type); when others => Error_Kind ("is_valid_conversion", Func); end case; end Is_Valid_Conversion; function Extract_Conversion (Conv : Iir; Res_Type : Iir; Param_Type : Iir; Loc : Iir) return Iir is List : Iir_List; It : List_Iterator; Res_Base_Type : Iir; Param_Base_Type : Iir; El : Iir; Res : Iir; begin Res_Base_Type := Get_Base_Type (Res_Type); if Param_Type = Null_Iir then -- In case of error. return Null_Iir; end if; Param_Base_Type := Get_Base_Type (Param_Type); if Is_Overload_List (Conv) then List := Get_Overload_List (Conv); Res := Null_Iir; It := List_Iterate (List); while Is_Valid (It) loop El := Get_Element (It); if Is_Valid_Conversion (El, Res_Base_Type, Param_Base_Type) then if Res /= Null_Iir then raise Internal_Error; end if; Free_Iir (Conv); Res := El; end if; Next (It); end loop; else if Is_Valid_Conversion (Conv, Res_Base_Type, Param_Base_Type) then Res := Conv; else Error_Msg_Sem (+Loc, "conversion function or type does not match"); return Null_Iir; end if; end if; if Get_Kind (Res) = Iir_Kind_Function_Call then declare Imp : constant Iir := Get_Implementation (Res); Inter : constant Iir := Get_Interface_Declaration_Chain (Imp); begin if Get_Kind (Inter) /= Iir_Kind_Interface_Constant_Declaration then Error_Msg_Sem (+Loc, "interface of function must be a constant interface"); end if; if Get_Chain (Inter) /= Null_Iir then -- LRM08 6.5.7 Association lists -- In this case, the function name shall denote a function -- whose single parameter is of the type of the formal -- and [...] Error_Msg_Sem (+Loc, "conversion function must have only one parameter"); end if; end; end if; return Res; end Extract_Conversion; function Extract_In_Conversion (Conv : Iir; Res_Type : Iir; Param_Type : Iir) return Iir is Func : Iir; Assoc : Iir; begin if Conv = Null_Iir then return Null_Iir; end if; Func := Extract_Conversion (Conv, Res_Type, Param_Type, Conv); if Func = Null_Iir then return Null_Iir; end if; case Get_Kind (Func) is when Iir_Kind_Function_Call => Assoc := Get_Parameter_Association_Chain (Func); Free_Iir (Assoc); Set_Parameter_Association_Chain (Func, Null_Iir); Name_To_Method_Object (Func, Conv); return Func; when Iir_Kind_Type_Conversion => return Func; when others => Error_Kind ("extract_in_conversion", Func); end case; end Extract_In_Conversion; function Extract_Out_Conversion (Conv : Iir; Res_Type : Iir; Param_Type : Iir) return Iir is Func : Iir; begin if Conv = Null_Iir then return Null_Iir; end if; Func := Extract_Conversion (Conv, Res_Type, Param_Type, Conv); return Func; end Extract_Out_Conversion; procedure Sem_Association_Open (Assoc : Iir; Finish : Boolean; Match : out Compatibility_Level) is Formal : Iir; begin if Finish then -- LRM 4.3.3.2 Associations lists -- It is an error if an actual of open is associated with a -- formal that is associated individually. if Get_Whole_Association_Flag (Assoc) = False then Error_Msg_Sem (+Assoc, "cannot associate individually with open"); end if; Formal := Get_Formal (Assoc); if Formal /= Null_Iir then Set_Formal (Assoc, Finish_Sem_Name (Formal)); end if; end if; Match := Fully_Compatible; end Sem_Association_Open; procedure Sem_Association_Package_Type_Not_Finish (Assoc : Iir; Inter : Iir; Match : out Compatibility_Level) is Formal : constant Iir := Get_Formal (Assoc); begin if Formal = Null_Iir then -- Can be associated only once Match := Fully_Compatible; else if Kind_In (Formal, Iir_Kind_Simple_Name, Iir_Kind_Operator_Symbol) and then Get_Identifier (Formal) = Get_Identifier (Inter) then Match := Fully_Compatible; else Match := Not_Compatible; end if; end if; end Sem_Association_Package_Type_Not_Finish; procedure Sem_Association_Package_Type_Finish (Assoc : Iir; Inter : Iir) is Formal : constant Iir := Get_Formal (Assoc); begin if Formal /= Null_Iir then pragma Assert (Get_Identifier (Formal) = Get_Identifier (Inter)); pragma Assert (Get_Named_Entity (Formal) = Inter); Set_Formal (Assoc, Finish_Sem_Name (Formal)); end if; end Sem_Association_Package_Type_Finish; procedure Sem_Association_Package (Assoc : Iir; Inter : Iir; Finish : Boolean; Match : out Compatibility_Level) is Actual : Iir; Package_Inter : Iir; begin if not Finish then Sem_Association_Package_Type_Not_Finish (Assoc, Inter, Match); return; end if; Match := Not_Compatible; Sem_Association_Package_Type_Finish (Assoc, Inter); -- Analyze actual. Actual := Get_Actual (Assoc); Actual := Sem_Denoting_Name (Actual); Set_Actual (Assoc, Actual); Actual := Get_Named_Entity (Actual); if Is_Error (Actual) then return; end if; -- LRM08 6.5.7.2 Generic map aspects -- An actual associated with a formal generic package in a -- generic map aspect shall be the name that denotes an instance -- of the uninstantiated package named in the formal generic -- package declaration [...] if Get_Kind (Actual) /= Iir_Kind_Package_Instantiation_Declaration then Error_Msg_Sem (+Assoc, "actual of association is not a package instantiation"); return; end if; Package_Inter := Get_Uninstantiated_Package_Decl (Inter); if Get_Uninstantiated_Package_Decl (Actual) /= Package_Inter then Error_Msg_Sem (+Assoc, "actual package name is not an instance of interface package"); return; end if; -- LRM08 6.5.7.2 Generic map aspects -- b) If the formal generic package declaration includes an interface -- generic map aspect in the form that includes the box (<>) symbol, -- then the instantiated package denotes by the actual may be any -- instance of the uninstantiated package named in the formal -- generic package declaration. if Get_Generic_Map_Aspect_Chain (Inter) = Null_Iir then null; else -- Other cases not yet handled. raise Internal_Error; end if; Match := Fully_Compatible; return; end Sem_Association_Package; -- Create an implicit association_element_subprogram for the declaration -- of function ID for ACTUAL_Type (a type/subtype definition). function Sem_Implicit_Operator_Association (Id : Name_Id; Actual_Type : Iir; Actual_Name : Iir) return Iir is use Sem_Scopes; -- Return TRUE if DECL is a function declaration with a comparaison -- operator profile. function Has_Comparaison_Profile (Decl : Iir) return Boolean is Inter : Iir; begin -- A function declaration. if not Is_Function_Declaration (Decl) then return False; end if; -- That returns a boolean. if (Get_Base_Type (Get_Return_Type (Decl)) /= Vhdl.Std_Package.Boolean_Type_Definition) then return False; end if; -- With 2 interfaces of type ATYPE. Inter := Get_Interface_Declaration_Chain (Decl); for I in 1 .. 2 loop if Inter = Null_Iir then return False; end if; if Get_Base_Type (Get_Type (Inter)) /= Get_Base_Type (Actual_Type) then return False; end if; Inter := Get_Chain (Inter); end loop; if Inter /= Null_Iir then return False; end if; return True; end Has_Comparaison_Profile; Interp : Name_Interpretation_Type; Decl : Iir; Res : Iir; begin Interp := Get_Interpretation (Id); while Valid_Interpretation (Interp) loop Decl := Get_Declaration (Interp); if Has_Comparaison_Profile (Decl) then Res := Create_Iir (Iir_Kind_Association_Element_Subprogram); Location_Copy (Res, Actual_Name); Set_Actual (Res, Build_Simple_Name (Decl, Get_Location (Actual_Name))); Set_Use_Flag (Decl, True); return Res; end if; Interp := Get_Next_Interpretation (Interp); end loop; Error_Msg_Sem (+Actual_Name, "cannot find a %i declaration for type %i", (+Id, +Actual_Name)); return Null_Iir; end Sem_Implicit_Operator_Association; procedure Sem_Association_Type (Assoc : Iir; Inter : Iir; Finish : Boolean; Match : out Compatibility_Level) is Inter_Def : constant Iir := Get_Type (Inter); Actual : Iir; Actual_Type : Iir; Op_Eq, Op_Neq : Iir; begin if not Finish then Sem_Association_Package_Type_Not_Finish (Assoc, Inter, Match); return; end if; Match := Fully_Compatible; Sem_Association_Package_Type_Finish (Assoc, Inter); Actual := Get_Actual (Assoc); -- LRM08 6.5.7.2 Generic map aspects -- An actual associated with a formal generic type must be a subtype -- indication. -- FIXME: ghdl only supports type_mark! Actual := Sem_Types.Sem_Subtype_Indication (Actual); Set_Actual (Assoc, Actual); -- Set type association for analysis of reference to this interface. pragma Assert (Is_Null (Get_Associated_Type (Inter_Def))); if Get_Kind (Actual) in Iir_Kinds_Subtype_Definition then Actual_Type := Actual; else Actual_Type := Get_Type (Actual); end if; Set_Actual_Type (Assoc, Actual_Type); Set_Associated_Type (Inter_Def, Actual_Type); -- FIXME: it is not clear at all from the LRM how the implicit -- associations are done... Op_Eq := Sem_Implicit_Operator_Association (Std_Names.Name_Op_Equality, Actual_Type, Actual); if Op_Eq /= Null_Iir then Op_Neq := Sem_Implicit_Operator_Association (Std_Names.Name_Op_Inequality, Actual_Type, Actual); Set_Chain (Op_Eq, Op_Neq); Set_Subprogram_Association_Chain (Assoc, Op_Eq); end if; end Sem_Association_Type; function Has_Interface_Subprogram_Profile (Inter : Iir; Decl : Iir; Explain_Loc : Location_Type := No_Location) return Boolean is -- Handle previous assocation of interface type before full -- instantiation. function Get_Inter_Type (Inter : Iir) return Iir is Res : Iir; begin Res := Get_Type (Inter); if Get_Kind (Res) = Iir_Kind_Interface_Type_Definition then -- FIXME: recurse ? return Get_Associated_Type (Res); else return Res; end if; end Get_Inter_Type; Explain : constant Boolean := Explain_Loc /= No_Location; El_Inter, El_Decl : Iir; begin case Iir_Kinds_Interface_Subprogram_Declaration (Get_Kind (Inter)) is when Iir_Kind_Interface_Function_Declaration => if not Is_Function_Declaration (Decl) then if Explain then Error_Msg_Sem (Explain_Loc, " actual is not a function"); end if; return False; end if; if Get_Base_Type (Get_Inter_Type (Inter)) /= Get_Base_Type (Get_Type (Decl)) then if Explain then Error_Msg_Sem (Explain_Loc, " return type doesn't match"); end if; return False; end if; when Iir_Kind_Interface_Procedure_Declaration => if not Is_Procedure_Declaration (Decl) then if Explain then Error_Msg_Sem (Explain_Loc, " actual is not a procedure"); end if; return False; end if; end case; El_Inter := Get_Interface_Declaration_Chain (Inter); El_Decl := Get_Interface_Declaration_Chain (Decl); loop exit when Is_Null (El_Inter) and Is_Null (El_Decl); if Is_Null (El_Inter) or Is_Null (El_Decl) then if Explain then Error_Msg_Sem (Explain_Loc, " number of interfaces doesn't match"); end if; return False; end if; if Get_Base_Type (Get_Inter_Type (El_Inter)) /= Get_Base_Type (Get_Type (El_Decl)) then if Explain then Error_Msg_Sem (Explain_Loc, " type of interface %i doesn't match", +El_Inter); end if; return False; end if; El_Inter := Get_Chain (El_Inter); El_Decl := Get_Chain (El_Decl); end loop; return True; end Has_Interface_Subprogram_Profile; procedure Sem_Association_Subprogram (Assoc : Iir; Inter : Iir; Finish : Boolean; Match : out Compatibility_Level) is Discard : Boolean; pragma Unreferenced (Discard); Actual : Iir; Res : Iir; begin if not Finish then Sem_Association_Package_Type_Not_Finish (Assoc, Inter, Match); return; end if; Match := Fully_Compatible; Sem_Association_Package_Type_Finish (Assoc, Inter); Actual := Get_Actual (Assoc); -- LRM08 6.5.7.2 Generic map aspects -- An actual associated with a formal generic subprogram shall be a name -- that denotes a subprogram whose profile conforms to that of the -- formal, or the reserved word OPEN. The actual, if a predefined -- attribute name that denotes a function, shall be one of the -- predefined attributes 'IMAGE, 'VALUE, 'POS, 'VAL, 'SUCC, 'PREV, -- 'LEFTOF, or 'RIGHTOF. Sem_Name (Actual); Res := Get_Named_Entity (Actual); if Is_Error (Res) then return; end if; case Get_Kind (Res) is when Iir_Kinds_Subprogram_Declaration | Iir_Kinds_Interface_Subprogram_Declaration => if not Has_Interface_Subprogram_Profile (Inter, Res) then Error_Msg_Sem (+Assoc, "profile of %n doesn't match profile of %n", (+Actual, +Inter)); -- Explain Discard := Has_Interface_Subprogram_Profile (Inter, Res, Get_Location (Assoc)); return; end if; when Iir_Kind_Overload_List => declare Nbr_Errors : Natural; List : Iir_List; It : List_Iterator; El, R : Iir; begin Nbr_Errors := 0; R := Null_Iir; List := Get_Overload_List (Res); It := List_Iterate (List); while Is_Valid (It) loop El := Get_Element (It); if Has_Interface_Subprogram_Profile (Inter, El) then if Is_Null (R) then R := El; else if Nbr_Errors = 0 then Error_Msg_Sem (+Assoc, "many possible actual subprogram for %n:", +Inter); Error_Msg_Sem (+Assoc, " %n declared at %l", (+R, + R)); else Error_Msg_Sem (+Assoc, " %n declared at %l", (+El, +El)); end if; Nbr_Errors := Nbr_Errors + 1; end if; end if; Next (It); end loop; if Is_Null (R) then Error_Msg_Sem (+Assoc, "no matching name for %n", +Inter); if True then Error_Msg_Sem (+Assoc, " these names were incompatible:"); It := List_Iterate (List); while Is_Valid (It) loop El := Get_Element (It); Error_Msg_Sem (+Assoc, " %n declared at %l", (+El, +El)); Next (It); end loop; end if; return; elsif Nbr_Errors > 0 then return; end if; Free_Overload_List (Res); Res := R; end; when others => Error_Kind ("sem_association_subprogram", Res); end case; Set_Named_Entity (Actual, Res); Vhdl.Xrefs.Xref_Name (Actual); Sem_Decls.Mark_Subprogram_Used (Res); end Sem_Association_Subprogram; procedure Sem_Association_Terminal (Assoc : Iir; Inter : Iir; Finish : Boolean; Match : out Compatibility_Level) is Actual_Name : Iir; Actual : Iir; begin if not Finish then Sem_Association_Package_Type_Not_Finish (Assoc, Inter, Match); return; end if; Match := Not_Compatible; Sem_Association_Package_Type_Finish (Assoc, Inter); -- Analyze actual. Actual_Name := Get_Actual (Assoc); Sem_Name (Actual_Name); Actual := Get_Named_Entity (Actual_Name); if Is_Error (Actual) then return; elsif Is_Overload_List (Actual) then Error_Msg_Sem (+Actual_Name, "terminal name expected"); return; else Actual := Finish_Sem_Name (Actual_Name); case Get_Kind (Get_Object_Prefix (Actual)) is when Iir_Kind_Terminal_Declaration | Iir_Kind_Interface_Terminal_Declaration => null; when others => Error_Msg_Sem (+Actual_Name, "%n is not a terminal name", +Actual); return; end case; end if; Set_Actual (Assoc, Actual); if (Get_Base_Nature (Get_Nature (Get_Named_Entity (Actual))) /= Get_Base_Nature (Get_Nature (Inter))) then Error_Msg_Sem (+Actual, "nature of actual is not the same as formal nature"); return; end if; Match := Fully_Compatible; return; end Sem_Association_Terminal; -- Associate ASSOC with interface INTERFACE -- This sets MATCH. procedure Sem_Association_By_Expression (Assoc : Iir; Inter : Iir; Formal_Name : Iir; Formal_Conv : Iir; Finish : Boolean; Match : out Compatibility_Level) is Formal_Type : Iir; Actual: Iir; Out_Conv, In_Conv : Iir; Expr : Iir; Res_Type : Iir; begin Out_Conv := Formal_Conv; if Formal_Name /= Null_Iir then Formal_Type := Get_Type (Formal_Name); else Formal_Type := Get_Type (Inter); end if; -- If the formal type is an interface type of the same interface list, -- use the associated type of the formal type to analyze the actual. if Get_Kind (Formal_Type) = Iir_Kind_Interface_Type_Definition and then (Get_Parent (Get_Type_Declarator (Formal_Type)) = Get_Parent (Inter)) then Formal_Type := Get_Associated_Type (Formal_Type); if Formal_Type = Null_Iir then -- Interface type are only allowed within generic map aspect, -- which are analyzed in one step (so Finish is true). pragma Assert (Finish); Error_Msg_Sem (+Assoc, "expression associated before its type"); Match := Not_Compatible; return; end if; end if; -- Extract conversion from actual. -- LRM08 6.5.7.1 Association lists Actual := Get_Actual (Assoc); In_Conv := Null_Iir; if Get_Kind (Inter) /= Iir_Kind_Interface_Constant_Declaration then declare -- Actual before the extraction of the conversion. Prev_Actual : constant Iir := Actual; begin -- Extract conversion and new actual (conv_expr). case Get_Kind (Actual) is when Iir_Kind_Function_Call => Expr := Get_Parameter_Association_Chain (Actual); if Is_Conversion_Function (Expr) then In_Conv := Actual; Actual := Get_Actual (Expr); end if; when Iir_Kind_Type_Conversion => if Flags.Vhdl_Std > Vhdl_87 then In_Conv := Actual; Actual := Get_Expression (Actual); end if; when others => null; end case; if Actual = Null_Iir then Match := Fully_Compatible; return; end if; -- There could be an ambiguity between a conversion and a normal -- actual expression. Check if the new actual is an object and -- if the object is of the corresponding class. if Is_Valid (In_Conv) then if Get_Kind (Inter) = Iir_Kind_Interface_Signal_Declaration then if not Is_Signal_Object (Actual) then -- Actual is not a signal object. This is not a -- conversion but a regular association. In_Conv := Null_Iir; Actual := Prev_Actual; end if; else -- Variable: let as is. null; end if; end if; end; end if; -- 4 cases: F:out_conv, G:in_conv. -- A => B type of A = type of B -- F(A) => B type of B = type of F -- A => G(B) type of A = type of G -- F(A) => G(B) type of B = type of F, type of A = type of G if Out_Conv = Null_Iir and then In_Conv = Null_Iir then Match := Is_Expr_Compatible (Formal_Type, Actual); else Match := Fully_Compatible; if In_Conv /= Null_Iir then Match := Compatibility_Level'Min (Match, Is_Expr_Compatible (Formal_Type, In_Conv)); end if; if Out_Conv /= Null_Iir then Match := Compatibility_Level'Min (Match, Is_Expr_Compatible (Get_Type (Out_Conv), Actual)); end if; end if; if Match = Not_Compatible then if Finish and then not Is_Error (Actual) then Report_Start_Group; Error_Msg_Sem (+Assoc, "can't associate %n with %n", (+Actual, +Inter)); Error_Msg_Sem (+Assoc, "(type of %n is " & Disp_Type_Of (Actual) & ")", (1 => +Actual)); Error_Msg_Sem (+Inter, "(type of %n is " & Disp_Type_Of (Inter) & ")", +Inter); Report_End_Group; end if; return; end if; if not Finish then return; end if; -- At that point, the analysis is being finished. if Out_Conv = Null_Iir and then In_Conv = Null_Iir then Res_Type := Formal_Type; else if Out_Conv /= Null_Iir then Res_Type := Search_Compatible_Type (Get_Type (Out_Conv), Get_Type (Actual)); else Res_Type := Get_Type (Actual); end if; if In_Conv /= Null_Iir then In_Conv := Extract_In_Conversion (In_Conv, Formal_Type, Res_Type); end if; if Out_Conv /= Null_Iir then Out_Conv := Extract_Out_Conversion (Out_Conv, Res_Type, Formal_Type); end if; end if; if Res_Type = Null_Iir then -- In case of error, do not go farther. Match := Not_Compatible; return; end if; if Formal_Name /= Null_Iir then declare Formal : Iir; Conv_Assoc : Iir; begin -- Extract formal from the conversion (and unlink it from the -- conversion, as the owner of the formal is the association, not -- the conversion). Formal := Finish_Sem_Name (Get_Formal (Assoc)); case Get_Kind (Formal) is when Iir_Kind_Function_Call => pragma Assert (Formal_Conv /= Null_Iir); Set_Formal_Conversion (Assoc, Formal); Conv_Assoc := Get_Parameter_Association_Chain (Formal); Set_Parameter_Association_Chain (Formal, Null_Iir); Formal := Get_Actual (Conv_Assoc); Free_Iir (Conv_Assoc); -- Name_To_Method_Object (Func, Conv); when Iir_Kind_Type_Conversion => pragma Assert (Formal_Conv /= Null_Iir); Conv_Assoc := Formal; Set_Formal_Conversion (Assoc, Formal); Formal := Get_Expression (Formal); Set_Expression (Conv_Assoc, Null_Iir); when others => pragma Assert (Formal_Conv = Null_Iir); null; end case; Set_Formal (Assoc, Formal); -- Use the type of the formal to analyze the actual. In -- particular, the formal may be constrained while the actual is -- not. -- (but not when the formal_type is an interface type, as it -- will bring nothing more and could have been substitued by -- its associated type). Formal_Type := Get_Type (Formal); if (Out_Conv = Null_Iir and In_Conv = Null_Iir) and then Get_Kind (Formal_Type) /= Iir_Kind_Interface_Type_Definition then Res_Type := Formal_Type; end if; end; end if; -- LRM08 6.5.7 Association lists -- The formal part of a named association element may be in the form of -- a function call [...] if and only if the formal is an interface -- object, the mode of the formal is OUT, INOUT, BUFFER or LINKAGE [...] if Out_Conv /= Null_Iir and then Get_Mode (Inter) = Iir_In_Mode then Error_Msg_Sem (+Assoc, "can't use an out conversion for an in interface"); end if; -- LRM08 6.5.7 Association lists -- The actual part of an association element may be in the form of a -- function call [...] if and only if the mode of the format is IN, -- INOUT or LINKAGE [...] Set_Actual_Conversion (Assoc, In_Conv); if In_Conv /= Null_Iir and then Get_Mode (Inter) in Iir_Buffer_Mode .. Iir_Out_Mode then Error_Msg_Sem (+Assoc, "can't use an in conversion for an out/buffer interface"); end if; -- LRM08 5.3.2.2 Index constraints and discrete ranges -- e) [...] -- 3) [...] -- -- For an interface object or subelement whose mode is IN, INOUT -- or LINKAGE, if the actual part includes a conversion function -- or a type conversion, then the result type of that function -- or the type mark of the type conversion shall define a -- constraint for the index range corresponding to the index -- range of the objet, [...] -- -- For an interface object or subelement whose mode is OUT, -- BUFFER, INOUT or LINKAGE, if the formal part includes a -- conversion function or a type conversion, then the parameter -- subtype of that function or the type mark of the type -- conversion shall define a constraint for the index range -- corresponding to the index range of the object, [...] if not Is_Fully_Constrained_Type (Formal_Type) then if (Get_Mode (Inter) in Iir_In_Modes or else Get_Mode (Inter) = Iir_Linkage_Mode) and then In_Conv /= Null_Iir and then not Is_Fully_Constrained_Type (Get_Type (In_Conv)) then Error_Msg_Sem (+Assoc, "type of actual conversion must be fully constrained"); end if; if (Get_Mode (Inter) in Iir_Out_Modes or else Get_Mode (Inter) = Iir_Linkage_Mode) and then Out_Conv /= Null_Iir and then not Is_Fully_Constrained_Type (Get_Type (Out_Conv)) then Error_Msg_Sem (+Assoc, "type of formal conversion must be fully constrained"); end if; end if; -- FIXME: LRM refs -- This is somewhat wrong. A missing conversion is not an error but -- may result in a type mismatch. if Get_Mode (Inter) = Iir_Inout_Mode then if In_Conv = Null_Iir and then Out_Conv /= Null_Iir then Error_Msg_Sem (+Assoc, "out conversion without corresponding in conversion"); elsif In_Conv /= Null_Iir and then Out_Conv = Null_Iir then Error_Msg_Sem (+Assoc, "in conversion without corresponding out conversion"); end if; end if; Set_Actual (Assoc, Actual); -- Analyze actual. Expr := Sem_Expression (Actual, Res_Type); if Expr /= Null_Iir then Expr := Eval_Expr_Check_If_Static (Expr, Res_Type); Set_Actual (Assoc, Expr); if In_Conv = Null_Iir and then Out_Conv = Null_Iir then if not Eval_Is_In_Bound (Expr, Formal_Type, True) then Error_Msg_Sem (+Assoc, "actual constraints don't match formal ones"); end if; end if; end if; end Sem_Association_By_Expression; -- Associate ASSOC with interface INTERFACE -- This sets MATCH. procedure Sem_Association (Assoc : Iir; Inter : Iir; Formal : Iir; Formal_Conv : Iir; Finish : Boolean; Match : out Compatibility_Level) is begin case Iir_Kinds_Interface_Declaration (Get_Kind (Inter)) is when Iir_Kinds_Interface_Object_Declaration => if Get_Kind (Assoc) = Iir_Kind_Association_Element_Open then Sem_Association_Open (Assoc, Finish, Match); else Sem_Association_By_Expression (Assoc, Inter, Formal, Formal_Conv, Finish, Match); end if; when Iir_Kind_Interface_Terminal_Declaration => if Get_Kind (Assoc) = Iir_Kind_Association_Element_Open then Sem_Association_Open (Assoc, Finish, Match); else Sem_Association_Terminal (Assoc, Inter, Finish, Match); end if; when Iir_Kind_Interface_Package_Declaration => Sem_Association_Package (Assoc, Inter, Finish, Match); when Iir_Kind_Interface_Type_Declaration => Sem_Association_Type (Assoc, Inter, Finish, Match); when Iir_Kinds_Interface_Subprogram_Declaration => Sem_Association_Subprogram (Assoc, Inter, Finish, Match); end case; end Sem_Association; procedure Sem_Association_Chain (Interface_Chain : Iir; Assoc_Chain: in out Iir; Finish: Boolean; Missing : Missing_Type; Loc : Iir; Match : out Compatibility_Level) is Assoc : Iir; Inter : Iir; -- True if -Whide is enabled (save the state). Warn_Hide_Enabled : Boolean; type Param_Assoc_Type is (None, Open, Individual, Whole); type Assoc_Array is array (Natural range <>) of Param_Assoc_Type; Nbr_Inter : constant Natural := Get_Chain_Length (Interface_Chain); Inter_Matched : Assoc_Array (0 .. Nbr_Inter - 1) := (others => None); Last_Individual : Iir; Has_Individual : Boolean; Pos : Integer; Formal : Iir; First_Named_Assoc : Iir; Last_Named_Assoc : Iir; Formal_Name : Iir; Formal_Conv : Iir; begin Match := Fully_Compatible; First_Named_Assoc := Null_Iir; Has_Individual := False; -- Clear associated type of interface type. Inter := Interface_Chain; while Inter /= Null_Iir loop if Get_Kind (Inter) = Iir_Kind_Interface_Type_Declaration then Set_Associated_Type (Get_Type (Inter), Null_Iir); end if; Inter := Get_Chain (Inter); end loop; -- Loop on every assoc element, try to match it. Inter := Interface_Chain; Last_Individual := Null_Iir; Pos := 0; -- First positional associations Assoc := Assoc_Chain; while Assoc /= Null_Iir loop Formal := Get_Formal (Assoc); exit when Formal /= Null_Iir; -- Try to match actual of ASSOC with the interface. if Inter = Null_Iir then if Finish then Error_Msg_Sem (+Assoc, "too many actuals for %n", +Loc); end if; Match := Not_Compatible; return; end if; Set_Whole_Association_Flag (Assoc, True); Sem_Association (Assoc, Inter, Null_Iir, Null_Iir, Finish, Match); if Match = Not_Compatible then return; end if; if Get_Kind (Assoc) = Iir_Kind_Association_Element_Open then Inter_Matched (Pos) := Open; else Inter_Matched (Pos) := Whole; end if; Set_Whole_Association_Flag (Assoc, True); Inter := Get_Chain (Inter); Pos := Pos + 1; Assoc := Get_Chain (Assoc); end loop; -- Then association by name. if Assoc /= Null_Iir then -- Make interfaces visible -- -- LRM08 12.3 Visibility -- A declaration is visible by selection at places that are defined -- as follows: -- j) For a formal parameter declaration of a given subprogram -- declaration: at the place of the formal part (before the -- compound delimiter =>) of a named parameter association -- element of a corresponding subprogram call. -- k) For a local generic declaration of a given component -- declaration ... -- l) For a local port declaration of a given component declaration: -- ... -- m) For a formal generic declaration of a given entity declaration: -- ... -- n) For a formal port declaration of a given entity declaration: -- ... -- o) For a formal generic declaration or a formal port declaration -- of a given block statement: ... -- p) For a formal generic declaration of a given package -- declaration: ... -- q) For a formal generic declaration of a given subprogram -- declarations: ... -- -- At a place in which a given declaration is visible by selection, -- every declaration with the same designator as the given -- declaration and that would otherwise be directly visible is -- hidden. Sem_Scopes.Open_Declarative_Region; -- Do not warn about hidding here, way to common, way useless. Warn_Hide_Enabled := Is_Warning_Enabled (Warnid_Hide); Enable_Warning (Warnid_Hide, False); Sem_Scopes.Add_Declarations_From_Interface_Chain (Interface_Chain); Enable_Warning (Warnid_Hide, Warn_Hide_Enabled); First_Named_Assoc := Assoc; loop if Formal = Null_Iir then -- Positional after named argument. Already caught by -- Sem_Actual_Of_Association_Chain (because it is called only -- once, while sem_association_chain may be called several -- times). Match := Not_Compatible; exit; end if; -- Last assoc to be cleaned up. Last_Named_Assoc := Assoc; if Finish then Sem_Name (Formal); else Sem_Name_Soft (Formal); end if; Formal_Name := Get_Named_Entity (Formal); if Is_Error (Formal_Name) then Match := Not_Compatible; -- Continue analysis in order to catch more errors. end if; Assoc := Get_Chain (Assoc); exit when Assoc = Null_Iir; Formal := Get_Formal (Assoc); end loop; -- Remove visibility by selection of interfaces. This is needed -- to correctly analyze actuals. Sem_Scopes.Close_Declarative_Region; if Match /= Not_Compatible then Assoc := First_Named_Assoc; loop Formal := Get_Formal (Assoc); Formal_Name := Get_Named_Entity (Formal); -- Extract conversion Formal_Conv := Null_Iir; case Get_Kind (Formal_Name) is when Iir_Kind_Function_Call => -- Only one actual declare Call_Assoc : constant Iir := Get_Parameter_Association_Chain (Formal_Name); begin if (Get_Kind (Call_Assoc) /= Iir_Kind_Association_Element_By_Expression) or else Get_Chain (Call_Assoc) /= Null_Iir or else Get_Formal (Call_Assoc) /= Null_Iir or else (Get_Actual_Conversion (Call_Assoc) /= Null_Iir) then if Finish then Error_Msg_Sem (+Assoc, "ill-formed formal conversion"); end if; Match := Not_Compatible; exit; end if; Formal_Conv := Formal_Name; Formal_Name := Get_Actual (Call_Assoc); end; when Iir_Kind_Type_Conversion => Formal_Conv := Formal_Name; Formal_Name := Get_Expression (Formal_Name); when Iir_Kind_Slice_Name | Iir_Kind_Indexed_Name | Iir_Kind_Selected_Element | Iir_Kind_Simple_Name => null; when others => Formal_Name := Formal; end case; case Get_Kind (Formal_Name) is when Iir_Kind_Selected_Element | Iir_Kind_Slice_Name | Iir_Kind_Indexed_Name => Inter := Get_Base_Name (Formal_Name); Set_Whole_Association_Flag (Assoc, False); when Iir_Kind_Simple_Name | Iir_Kind_Operator_Symbol => Inter := Get_Named_Entity (Formal_Name); Formal_Name := Inter; Set_Whole_Association_Flag (Assoc, True); when others => -- Error if Finish then Error_Msg_Sem (+Assoc, "formal is not a name"); end if; Match := Not_Compatible; exit; end case; -- Simplify overload list (for interface subprogram). -- FIXME: Interface must hide previous subprogram declarations, -- so there should be no need to filter. if Is_Overload_List (Inter) then declare List : constant Iir_List := Get_Overload_List (Inter); It : List_Iterator; Filtered_Inter : Iir; El : Iir; begin Filtered_Inter := Null_Iir; It := List_Iterate (List); while Is_Valid (It) loop El := Get_Element (It); if Get_Kind (El) in Iir_Kinds_Interface_Declaration and then Get_Parent (El) = Get_Parent (Interface_Chain) then Add_Result (Filtered_Inter, El); end if; Next (It); end loop; Free_Overload_List (Inter); Inter := Filtered_Inter; pragma Assert (Get_Kind (Formal) = Iir_Kind_Simple_Name or else Get_Kind (Formal) = Iir_Kind_Operator_Symbol); Set_Named_Entity (Formal, Inter); if Inter = Null_Iir then if Finish then Error_Msg_Sem (+Assoc, "no interface %i for %n", (+Formal, +Loc)); end if; Match := Not_Compatible; exit; end if; if Is_Overload_List (Inter) then if Finish then Error_Msg_Sem (+Assoc, "ambiguous formal name"); end if; Match := Not_Compatible; exit; end if; end; end if; if Get_Kind (Inter) not in Iir_Kinds_Interface_Declaration or else Interface_Chain = Null_Iir or else Get_Parent (Inter) /= Get_Parent (Interface_Chain) then if Finish then Error_Msg_Sem (+Formal, "%n is not an interface name", +Inter); end if; Match := Not_Compatible; exit; end if; -- LRM 4.3.2.2 Association Lists -- The formal part of a named element association may be -- in the form of a function call, [...], if and only -- if the mode of the formal is OUT, INOUT, BUFFER, or -- LINKAGE, and the actual is not OPEN. if Formal_Conv /= Null_Iir and then (Get_Kind (Inter) not in Iir_Kinds_Interface_Object_Declaration or else Get_Mode (Inter) = Iir_In_Mode) then if Finish then Error_Msg_Sem (+Assoc, "formal conversion allowed only for interface object"); end if; Match := Not_Compatible; exit; end if; -- Find the Interface. declare Inter1 : Iir; begin Inter1 := Interface_Chain; Pos := 0; while Inter1 /= Null_Iir loop exit when Inter = Inter1; Inter1 := Get_Chain (Inter1); Pos := Pos + 1; end loop; if Inter1 = Null_Iir then if Finish then Error_Msg_Sem (+Assoc, "no corresponding interface for %i", +Inter); end if; Match := Not_Compatible; exit; end if; end; Sem_Association (Assoc, Inter, Formal_Name, Formal_Conv, Finish, Match); exit when Match = Not_Compatible; if Get_Whole_Association_Flag (Assoc) then -- Whole association. Last_Individual := Null_Iir; if Inter_Matched (Pos) = None then if Get_Kind (Assoc) = Iir_Kind_Association_Element_Open then Inter_Matched (Pos) := Open; else Inter_Matched (Pos) := Whole; end if; else if Finish then Error_Msg_Sem (+Assoc, "%n already associated", +Inter); end if; Match := Not_Compatible; exit; end if; else -- Individual association. Has_Individual := True; if Inter_Matched (Pos) /= Whole then if Finish and then Inter_Matched (Pos) = Individual and then Last_Individual /= Inter then Error_Msg_Sem (+Assoc, "non consecutive individual association for %n", +Inter); Match := Not_Compatible; exit; end if; Last_Individual := Inter; Inter_Matched (Pos) := Individual; else if Finish then Error_Msg_Sem (+Assoc, "%n already associated", +Inter); Match := Not_Compatible; exit; end if; end if; end if; Assoc := Get_Chain (Assoc); exit when Assoc = Null_Iir; end loop; end if; if Finish and Has_Individual and Match /= Not_Compatible then Sem_Individual_Association (Assoc_Chain); end if; if not Finish then -- Always cleanup if not finishing: there can be other tries in -- case of overloading. Assoc := First_Named_Assoc; while Assoc /= Null_Iir loop Formal := Get_Formal (Assoc); -- User may have used by position assoc after named -- assocs. if Is_Valid (Formal) then Sem_Name_Clean (Formal); end if; exit when Assoc = Last_Named_Assoc; Assoc := Get_Chain (Assoc); end loop; end if; if Match = Not_Compatible then return; end if; end if; if Missing = Missing_Allowed then -- No need to check for missing associations. return; end if; -- LRM93 8.6 Procedure Call Statement -- For each formal parameter of a procedure, a procedure call must -- specify exactly one corresponding actual parameter. -- This actual parameter is specified either explicitly, by an -- association element (other than the actual OPEN) in the association -- list, or in the absence of such an association element, by a default -- expression (see Section 4.3.3.2). -- LRM93 7.3.3 Function Calls -- For each formal parameter of a function, a function call must -- specify exactly one corresponding actual parameter. -- This actual parameter is specified either explicitly, by an -- association element (other than the actual OPEN) in the association -- list, or in the absence of such an association element, by a default -- expression (see Section 4.3.3.2). -- LRM93 1.1.1.2 / LRM08 6.5.6.3 Port clauses -- A port of mode IN may be unconnected or unassociated only if its -- declaration includes a default expression. -- A port of any mode other than IN may be unconnected or unassociated -- as long as its type is not an unconstrained array type. -- LRM08 6.5.6.2 Generic clauses -- It is an error if no such actual [instantiated package] is specified -- for a given formal generic package (either because the formal generic -- is unassociated or because the actual is OPEN). Inter := Interface_Chain; Pos := 0; while Inter /= Null_Iir loop if Inter_Matched (Pos) <= Open then if Sem_Check_Missing_Association (Inter, Missing, Finish, Inter_Matched (Pos) = Open, Loc) then Match := Not_Compatible; if not Finish then return; end if; end if; end if; Inter := Get_Chain (Inter); Pos := Pos + 1; end loop; end Sem_Association_Chain; function Sem_Check_Missing_Association (Inter : Iir; Missing : Missing_Type; Finish : Boolean; Is_Open : Boolean; Loc : Iir) return Boolean is Err : Boolean; begin -- Interface is unassociated (none or open). Err := False; case Get_Kind (Inter) is when Iir_Kinds_Interface_Object_Declaration => case Missing is when Missing_Parameter | Missing_Generic => if Get_Mode (Inter) /= Iir_In_Mode or else Get_Default_Value (Inter) = Null_Iir then Err := True; if Finish then Error_Msg_Sem (+Loc, "no actual for %n", +Inter); else return True; end if; end if; when Missing_Port => case Get_Mode (Inter) is when Iir_In_Mode => -- No overloading for components/entities. pragma Assert (Finish); if Get_Default_Value (Inter) = Null_Iir then Error_Msg_Sem (+Loc, "%n of mode IN must be connected", +Inter); Err := True; elsif not Is_Open then Warning_Msg_Sem (Warnid_No_Assoc, +Loc, "%n of mode IN is not connected", +Inter); end if; when Iir_Out_Mode | Iir_Linkage_Mode | Iir_Inout_Mode | Iir_Buffer_Mode => -- No overloading for components/entities. pragma Assert (Finish); if not Is_Fully_Constrained_Type (Get_Type (Inter)) then Error_Msg_Sem (+Loc, "unconstrained %n must be connected", +Inter); Err := True; elsif not Is_Open then Warning_Msg_Sem (Warnid_No_Assoc, +Loc, "%n of mode OUT is not connected", +Inter); end if; when Iir_Unknown_Mode => raise Internal_Error; end case; when Missing_Allowed => null; end case; when Iir_Kind_Interface_Package_Declaration => if Get_Generic_Map_Aspect_Chain (Inter) = Null_Iir then Error_Msg_Sem (+Loc, "%n must be associated", +Inter); Err := True; end if; when Iir_Kind_Interface_Function_Declaration | Iir_Kind_Interface_Procedure_Declaration => Error_Msg_Sem (+Loc, "%n must be associated", +Inter); Err := True; when others => Error_Kind ("sem_association_chain", Inter); end case; return Err; end Sem_Check_Missing_Association; end Vhdl.Sem_Assocs;