-- Semantic analysis. -- Copyright (C) 2002, 2003, 2004, 2005 Tristan Gingold -- -- GHDL 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, or (at your option) any later -- version. -- -- GHDL 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 GHDL; see the file COPYING. If not, write to the Free -- Software Foundation, 59 Temple Place - Suite 330, Boston, MA -- 02111-1307, USA. with Errorout; use Errorout; with Types; use Types; with Std_Names; with Tokens; with Flags; use Flags; with Std_Package; use Std_Package; with Ieee.Std_Logic_1164; with Iir_Chains; with Evaluation; use Evaluation; with Name_Table; with Iirs_Utils; use Iirs_Utils; with Sem; use Sem; with Sem_Expr; use Sem_Expr; with Sem_Scopes; use Sem_Scopes; with Sem_Names; use Sem_Names; with Sem_Specs; use Sem_Specs; with Sem_Types; use Sem_Types; with Xrefs; use Xrefs; use Iir_Chains; package body Sem_Decls is -- Emit an error if the type of DECL is a file type, access type, -- protected type or if a subelement of DECL is an access type. procedure Check_Signal_Type (Decl : Iir) is Decl_Type : Iir; begin Decl_Type := Get_Type (Decl); if Get_Signal_Type_Flag (Decl_Type) = False then Error_Msg_Sem ("type of " & Disp_Node (Decl) & " cannot be " & Disp_Node (Decl_Type), Decl); case Get_Kind (Decl_Type) is when Iir_Kind_File_Type_Definition => null; when Iir_Kind_Protected_Type_Declaration => null; when Iir_Kind_Access_Type_Definition | Iir_Kind_Access_Subtype_Definition => null; when Iir_Kinds_Array_Type_Definition | Iir_Kind_Record_Type_Definition | Iir_Kind_Record_Subtype_Definition => Error_Msg_Sem ("(" & Disp_Node (Decl_Type) & " has an access subelement)", Decl); when others => Error_Kind ("check_signal_type", Decl_Type); end case; end if; end Check_Signal_Type; procedure Sem_Interface_Chain (Interface_Chain: Iir; Interface_Kind : Interface_Kind_Type) is El, A_Type: Iir; Proxy : Iir_Proxy; Default_Value: Iir; begin El := Interface_Chain; while El /= Null_Iir loop -- Avoid the reanalysed duplicated types. -- This is not an optimization, since the unanalysed type must have -- been freed. A_Type := Get_Type (El); if Get_Kind (A_Type) = Iir_Kind_Proxy then Proxy := A_Type; A_Type := Get_Type (Get_Proxy (Proxy)); Default_Value := Get_Default_Value (Get_Proxy (Proxy)); Free_Iir (Proxy); else A_Type := Sem_Subtype_Indication (A_Type); Default_Value := Get_Default_Value (El); if Default_Value /= Null_Iir and then A_Type /= Null_Iir then Deferred_Constant_Allowed := True; Default_Value := Sem_Expression (Default_Value, A_Type); Default_Value := Eval_Expr_Check_If_Static (Default_Value, A_Type); Deferred_Constant_Allowed := False; Check_Read (Default_Value); end if; end if; Set_Base_Name (El, El); Set_Name_Staticness (El, Locally); Xref_Decl (El); if A_Type /= Null_Iir then Set_Type (El, A_Type); if Get_Kind (El) = Iir_Kind_Signal_Interface_Declaration then case Get_Signal_Kind (El) is when Iir_No_Signal_Kind => null; when Iir_Bus_Kind => -- FIXME: where this test came from ? -- FIXME: from 4.3.1.2 ? if False and (Get_Kind (A_Type) not in Iir_Kinds_Subtype_Definition or else Get_Resolution_Function (A_Type) = Null_Iir) then Error_Msg_Sem (Disp_Node (A_Type) & " of guarded " & Disp_Node (El) & " is not resolved", El); end if; -- LRM 2.1.1.2 Signal parameter -- It is an error if the declaration of a formal signal -- parameter includes the reserved word BUS. if Flags.Vhdl_Std >= Vhdl_93 and then Interface_Kind in Parameter_Kind_Subtype then Error_Msg_Sem ("signal parameter can't be of kind bus", El); end if; when Iir_Register_Kind => Error_Msg_Sem ("interface signal can't be of kind register", El); end case; Set_Type_Has_Signal (A_Type); end if; case Get_Kind (El) is when Iir_Kind_Constant_Interface_Declaration | Iir_Kind_Signal_Interface_Declaration => -- LRM 4.3.2 Interface declarations -- For an interface constant declaration or an interface -- signal declaration, the subtype indication must define -- a subtype that is neither a file type, an access type, -- nor a protected type. Moreover, the subtype indication -- must not denote a composite type with a subelement that -- is a file type, an access type, or a protected type. Check_Signal_Type (El); when Iir_Kind_Variable_Interface_Declaration => case Get_Kind (Get_Base_Type (A_Type)) is when Iir_Kind_File_Type_Definition => if Flags.Vhdl_Std >= Vhdl_93 then Error_Msg_Sem ("variable formal type can't be a " & "file type (vhdl 93)", El); end if; when Iir_Kind_Protected_Type_Declaration => -- LRM 2.1.1.1 Constant and variable parameters -- It is an error if the mode of the parameter is -- other that INOUT. if Get_Mode (El) /= Iir_Inout_Mode then Error_Msg_Sem ("parameter of protected type must be inout", El); end if; when others => null; end case; when Iir_Kind_File_Interface_Declaration => if Get_Kind (Get_Base_Type (A_Type)) /= Iir_Kind_File_Type_Definition then Error_Msg_Sem ("file formal type must be a file type", El); end if; when others => -- El is not an interface. raise Internal_Error; end case; if Default_Value /= Null_Iir then Set_Default_Value (El, Default_Value); -- LRM 4.3.2 Interface declarations. -- It is an error if a default expression appears in an -- interface declaration and any of the following conditions -- hold: -- - The mode is linkage -- - The interface object is a formal signal parameter -- - The interface object is a formal variable parameter of -- mode other than in -- - The subtype indication of the interface declaration -- denotes a protected type. case Get_Kind (El) is when Iir_Kind_Constant_Interface_Declaration => null; when Iir_Kind_Signal_Interface_Declaration => if Get_Mode (El) = Iir_Linkage_Mode then Error_Msg_Sem ("default expression not allowed for linkage port", El); elsif Interface_Kind in Parameter_Kind_Subtype then Error_Msg_Sem ("default expression not allowed" & " for signal parameter", El); end if; when Iir_Kind_Variable_Interface_Declaration => if Get_Mode (El) /= Iir_In_Mode then Error_Msg_Sem ("default expression not allowed for" & " out/inout variable parameter", El); elsif Get_Kind (A_Type) = Iir_Kind_Protected_Type_Declaration then Error_Msg_Sem ("default expression not allowed for" & " variable parameter of protected type", El); end if; when Iir_Kind_File_Interface_Declaration => raise Internal_Error; when others => null; end case; end if; else Set_Type (El, Error_Type); end if; Sem_Scopes.Add_Name (El); -- By default, interface are not static. -- This may be changed just below. Set_Expr_Staticness (El, None); case Interface_Kind is when Interface_Generic => -- LRM93 1.1.1 -- The generic list in the formal generic clause defines -- generic constants whose values may be determined by the -- environment. if Get_Kind (El) /= Iir_Kind_Constant_Interface_Declaration then Error_Msg_Sem ("generic " & Disp_Node (El) & " must be a constant", El); else -- LRM93 7.4.2 (Globally static primaries) -- 3. a generic constant. Set_Expr_Staticness (El, Globally); end if; when Interface_Port => if Get_Kind (El) /= Iir_Kind_Signal_Interface_Declaration then Error_Msg_Sem ("port " & Disp_Node (El) & " must be a signal", El); end if; when Interface_Procedure | Interface_Function => if Get_Kind (El) = Iir_Kind_Variable_Interface_Declaration and then Interface_Kind = Interface_Function then Error_Msg_Sem ("variable interface parameter are not " & "allowed for a function (use a constant)", El); end if; -- By default, we suppose a subprogram read the activity of -- a signal. -- This will be adjusted when the body is analyzed. if Get_Kind (El) = Iir_Kind_Signal_Interface_Declaration and then Get_Mode (El) in Iir_In_Modes then Set_Has_Active_Flag (El, True); end if; case Get_Mode (El) is when Iir_Unknown_Mode => raise Internal_Error; when Iir_In_Mode => null; when Iir_Inout_Mode | Iir_Out_Mode => if Interface_Kind = Interface_Function and then Get_Kind (El) /= Iir_Kind_File_Interface_Declaration then Error_Msg_Sem ("mode of a function parameter cannot " & "be inout or out", El); end if; when Iir_Buffer_Mode | Iir_Linkage_Mode => Error_Msg_Sem ("buffer or linkage mode is not allowed " & "for a subprogram parameter", El); end case; end case; El := Get_Chain (El); end loop; -- LRM 10.3 Visibility -- A declaration is visible only within a certain part of its scope; -- this starts at the end of the declaration [...] -- LRM 4.3.2.1 Interface List -- A name that denotes an interface object must not appear in any -- interface declaration within the interface list containing the -- denotes interface except to declare this object. -- GHDL: this is achieved by making the interface object visible after -- having analyzed the interface list. El := Interface_Chain; while El /= Null_Iir loop Name_Visible (El); El := Get_Chain (El); end loop; end Sem_Interface_Chain; function Is_One_Dimensional (Array_Def : Iir) return Boolean is begin return Get_Nbr_Elements (Get_Index_Subtype_List (Array_Def)) = 1; end Is_One_Dimensional; -- LRM93 7.2.2 -- A discrete array is a one-dimensional array whose elements are of a -- discrete type. function Is_Discrete_Array (Def : Iir) return Boolean is begin case Get_Kind (Def) is when Iir_Kind_Array_Type_Definition | Iir_Kind_Array_Subtype_Definition => null; when others => raise Internal_Error; -- return False; end case; if not Is_One_Dimensional (Def) then return False; end if; if Get_Kind (Get_Element_Subtype (Def)) not in Iir_Kinds_Discrete_Type_Definition then return False; end if; return True; end Is_Discrete_Array; procedure Create_Implicit_File_Primitives (Decl : Iir_Type_Declaration; Type_Definition : Iir_File_Type_Definition) is use Iir_Chains.Interface_Declaration_Chain_Handling; Type_Mark: Iir; Proc: Iir_Implicit_Procedure_Declaration; Func: Iir_Implicit_Function_Declaration; Inter: Iir; Loc : Location_Type; File_Interface_Kind : Iir_Kind; Last_Interface : Iir; Last : Iir; begin Last := Decl; Type_Mark := Get_Type_Mark (Type_Definition); Loc := Get_Location (Decl); if Flags.Vhdl_Std >= Vhdl_93c then for I in 1 .. 2 loop -- Create the implicit file_open (form 1) declaration. -- Create the implicit file_open (form 2) declaration. Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Location (Proc, Loc); Set_Parent (Proc, Get_Parent (Decl)); Set_Identifier (Proc, Std_Names.Name_File_Open); Set_Type_Reference (Proc, Decl); Set_Visible_Flag (Proc, True); Build_Init (Last_Interface); case I is when 1 => Set_Implicit_Definition (Proc, Iir_Predefined_File_Open); when 2 => Set_Implicit_Definition (Proc, Iir_Predefined_File_Open_Status); -- status : out file_open_status. Inter := Create_Iir (Iir_Kind_Variable_Interface_Declaration); Set_Location (Inter, Loc); Set_Identifier (Inter, Std_Names.Name_Status); Set_Type (Inter, Std_Package.File_Open_Status_Type_Definition); Set_Mode (Inter, Iir_Out_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); end case; -- File F : FT Inter := Create_Iir (Iir_Kind_File_Interface_Declaration); Set_Location (Inter, Loc); Set_Identifier (Inter, Std_Names.Name_F); Set_Type (Inter, Type_Definition); Set_Mode (Inter, Iir_Inout_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); -- External_Name : in STRING Inter := Create_Iir (Iir_Kind_Constant_Interface_Declaration); Set_Location (Inter, Loc); Set_Identifier (Inter, Std_Names.Name_External_Name); Set_Type (Inter, Std_Package.String_Type_Definition); Set_Mode (Inter, Iir_In_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); -- Open_Kind : in File_Open_Kind := Read_Mode. Inter := Create_Iir (Iir_Kind_Constant_Interface_Declaration); Set_Location (Inter, Loc); Set_Identifier (Inter, Std_Names.Name_Open_Kind); Set_Type (Inter, Std_Package.File_Open_Kind_Type_Definition); Set_Mode (Inter, Iir_In_Mode); Set_Base_Name (Inter, Inter); Set_Default_Value (Inter, Std_Package.File_Open_Kind_Read_Mode); Append (Last_Interface, Proc, Inter); Compute_Subprogram_Hash (Proc); -- Add it to the list. Insert_Incr (Last, Proc); end loop; -- Create the implicit file_close declaration. Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Identifier (Proc, Std_Names.Name_File_Close); Set_Location (Proc, Loc); Set_Parent (Proc, Get_Parent (Decl)); Set_Implicit_Definition (Proc, Iir_Predefined_File_Close); Set_Type_Reference (Proc, Decl); Set_Visible_Flag (Proc, True); Build_Init (Last_Interface); Inter := Create_Iir (Iir_Kind_File_Interface_Declaration); Set_Identifier (Inter, Std_Names.Name_F); Set_Location (Inter, Loc); Set_Type (Inter, Type_Definition); Set_Mode (Inter, Iir_Inout_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); Compute_Subprogram_Hash (Proc); -- Add it to the list. Insert_Incr (Last, Proc); end if; if Flags.Vhdl_Std = Vhdl_87 then File_Interface_Kind := Iir_Kind_Variable_Interface_Declaration; else File_Interface_Kind := Iir_Kind_File_Interface_Declaration; end if; -- Create the implicit procedure read declaration. Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Identifier (Proc, Std_Names.Name_Read); Set_Location (Proc, Loc); Set_Parent (Proc, Get_Parent (Decl)); Set_Type_Reference (Proc, Decl); Set_Visible_Flag (Proc, True); Build_Init (Last_Interface); Inter := Create_Iir (File_Interface_Kind); Set_Identifier (Inter, Std_Names.Name_F); Set_Location (Inter, Loc); Set_Type (Inter, Type_Definition); Set_Mode (Inter, Iir_In_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); Inter := Create_Iir (Iir_Kind_Variable_Interface_Declaration); Set_Identifier (Inter, Std_Names.Name_Value); Set_Location (Inter, Loc); Set_Type (Inter, Type_Mark); Set_Mode (Inter, Iir_Out_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); if Get_Kind (Type_Mark) in Iir_Kinds_Array_Type_Definition and then Get_Constraint_State (Type_Mark) /= Fully_Constrained then Inter := Create_Iir (Iir_Kind_Variable_Interface_Declaration); Set_Identifier (Inter, Std_Names.Name_Length); Set_Location (Inter, Loc); Set_Type (Inter, Std_Package.Natural_Subtype_Definition); Set_Mode (Inter, Iir_Out_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); Set_Implicit_Definition (Proc, Iir_Predefined_Read_Length); else Set_Implicit_Definition (Proc, Iir_Predefined_Read); end if; Compute_Subprogram_Hash (Proc); -- Add it to the list. Insert_Incr (Last, Proc); -- Create the implicit procedure write declaration. Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Identifier (Proc, Std_Names.Name_Write); Set_Location (Proc, Loc); Set_Parent (Proc, Get_Parent (Decl)); Set_Type_Reference (Proc, Decl); Set_Visible_Flag (Proc, True); Build_Init (Last_Interface); Inter := Create_Iir (File_Interface_Kind); Set_Identifier (Inter, Std_Names.Name_F); Set_Location (Inter, Loc); Set_Type (Inter, Type_Definition); Set_Mode (Inter, Iir_Out_Mode); Set_Base_Name (Inter, Inter); Set_Name_Staticness (Inter, Locally); Set_Expr_Staticness (Inter, None); Append (Last_Interface, Proc, Inter); Inter := Create_Iir (Iir_Kind_Constant_Interface_Declaration); Set_Identifier (Inter, Std_Names.Name_Value); Set_Location (Inter, Loc); Set_Type (Inter, Type_Mark); Set_Mode (Inter, Iir_In_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Proc, Inter); Set_Implicit_Definition (Proc, Iir_Predefined_Write); Compute_Subprogram_Hash (Proc); -- Add it to the list. Insert_Incr (Last, Proc); -- Create the implicit procedure flush declaration if Flags.Vhdl_Std >= Vhdl_08 then Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Identifier (Proc, Std_Names.Name_Flush); Set_Location (Proc, Loc); Set_Parent (Proc, Get_Parent (Decl)); Set_Type_Reference (Proc, Decl); Set_Visible_Flag (Proc, True); Build_Init (Last_Interface); Inter := Create_Iir (File_Interface_Kind); Set_Identifier (Inter, Std_Names.Name_F); Set_Location (Inter, Loc); Set_Type (Inter, Type_Definition); Set_Base_Name (Inter, Inter); Set_Name_Staticness (Inter, Locally); Set_Expr_Staticness (Inter, None); Append (Last_Interface, Proc, Inter); Set_Implicit_Definition (Proc, Iir_Predefined_Flush); Compute_Subprogram_Hash (Proc); -- Add it to the list. Insert_Incr (Last, Proc); end if; -- Create the implicit function endfile declaration. Func := Create_Iir (Iir_Kind_Implicit_Function_Declaration); Set_Identifier (Func, Std_Names.Name_Endfile); Set_Location (Func, Loc); Set_Parent (Func, Get_Parent (Decl)); Set_Type_Reference (Func, Decl); Set_Visible_Flag (Func, True); Build_Init (Last_Interface); Inter := Create_Iir (File_Interface_Kind); Set_Identifier (Inter, Std_Names.Name_F); Set_Location (Inter, Loc); Set_Type (Inter, Type_Definition); Set_Mode (Inter, Iir_In_Mode); Set_Base_Name (Inter, Inter); Append (Last_Interface, Func, Inter); Set_Return_Type (Func, Std_Package.Boolean_Type_Definition); Set_Implicit_Definition (Func, Iir_Predefined_Endfile); Compute_Subprogram_Hash (Func); -- Add it to the list. Insert_Incr (Last, Func); end Create_Implicit_File_Primitives; function Create_Anonymous_Interface (Atype : Iir) return Iir_Constant_Interface_Declaration is Inter : Iir_Constant_Interface_Declaration; begin Inter := Create_Iir (Iir_Kind_Constant_Interface_Declaration); Location_Copy (Inter, Atype); Set_Identifier (Inter, Null_Identifier); Set_Mode (Inter, Iir_In_Mode); Set_Type (Inter, Atype); Set_Base_Name (Inter, Inter); return Inter; end Create_Anonymous_Interface; procedure Create_Implicit_Operations (Decl : Iir; Is_Std_Standard : Boolean := False) is use Std_Names; Binary_Chain : Iir; Unary_Chain : Iir; Type_Definition : Iir; Last : Iir; procedure Add_Operation (Name : Name_Id; Def : Iir_Predefined_Functions; Interface_Chain : Iir; Return_Type : Iir) is Operation : Iir_Implicit_Function_Declaration; begin Operation := Create_Iir (Iir_Kind_Implicit_Function_Declaration); Location_Copy (Operation, Decl); Set_Parent (Operation, Get_Parent (Decl)); Set_Interface_Declaration_Chain (Operation, Interface_Chain); Set_Type_Reference (Operation, Decl); Set_Return_Type (Operation, Return_Type); Set_Implicit_Definition (Operation, Def); Set_Identifier (Operation, Name); Set_Visible_Flag (Operation, True); Compute_Subprogram_Hash (Operation); Insert_Incr (Last, Operation); end Add_Operation; procedure Add_Relational (Name : Name_Id; Def : Iir_Predefined_Functions) is begin Add_Operation (Name, Def, Binary_Chain, Std_Package.Boolean_Type_Definition); end Add_Relational; procedure Add_Binary (Name : Name_Id; Def : Iir_Predefined_Functions) is begin Add_Operation (Name, Def, Binary_Chain, Type_Definition); end Add_Binary; procedure Add_Unary (Name : Name_Id; Def : Iir_Predefined_Functions) is begin Add_Operation (Name, Def, Unary_Chain, Type_Definition); end Add_Unary; procedure Add_To_String (Def : Iir_Predefined_Functions) is begin Add_Operation (Name_To_String, Def, Unary_Chain, String_Type_Definition); end Add_To_String; procedure Add_Min_Max (Name : Name_Id; Def : Iir_Predefined_Functions) is Left, Right : Iir; begin Left := Create_Anonymous_Interface (Type_Definition); Set_Identifier (Left, Name_L); Right := Create_Anonymous_Interface (Type_Definition); Set_Identifier (Right, Name_R); Set_Chain (Left, Right); Add_Operation (Name, Def, Left, Type_Definition); end Add_Min_Max; procedure Add_Vector_Min_Max (Name : Name_Id; Def : Iir_Predefined_Functions) is Left : Iir; begin Left := Create_Anonymous_Interface (Type_Definition); Set_Identifier (Left, Name_L); Add_Operation (Name, Def, Left, Get_Element_Subtype (Type_Definition)); end Add_Vector_Min_Max; procedure Add_Shift_Operators is Inter_Chain : Iir_Constant_Interface_Declaration; Inter_Int : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Inter_Int := Create_Iir (Iir_Kind_Constant_Interface_Declaration); Location_Copy (Inter_Int, Decl); Set_Identifier (Inter_Int, Null_Identifier); Set_Mode (Inter_Int, Iir_In_Mode); Set_Type (Inter_Int, Std_Package.Integer_Subtype_Definition); Set_Base_Name (Inter_Int, Inter_Int); Set_Chain (Inter_Chain, Inter_Int); Add_Operation (Name_Sll, Iir_Predefined_Array_Sll, Inter_Chain, Type_Definition); Add_Operation (Name_Srl, Iir_Predefined_Array_Srl, Inter_Chain, Type_Definition); Add_Operation (Name_Sla, Iir_Predefined_Array_Sla, Inter_Chain, Type_Definition); Add_Operation (Name_Sra, Iir_Predefined_Array_Sra, Inter_Chain, Type_Definition); Add_Operation (Name_Rol, Iir_Predefined_Array_Rol, Inter_Chain, Type_Definition); Add_Operation (Name_Ror, Iir_Predefined_Array_Ror, Inter_Chain, Type_Definition); end Add_Shift_Operators; begin Last := Decl; Type_Definition := Get_Base_Type (Get_Type_Definition (Decl)); if Get_Kind (Type_Definition) /= Iir_Kind_File_Type_Definition then Unary_Chain := Create_Anonymous_Interface (Type_Definition); Binary_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Binary_Chain, Unary_Chain); end if; case Get_Kind (Type_Definition) is when Iir_Kind_Enumeration_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Enum_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Enum_Inequality); Add_Relational (Name_Op_Greater, Iir_Predefined_Enum_Greater); Add_Relational (Name_Op_Greater_Equal, Iir_Predefined_Enum_Greater_Equal); Add_Relational (Name_Op_Less, Iir_Predefined_Enum_Less); Add_Relational (Name_Op_Less_Equal, Iir_Predefined_Enum_Less_Equal); if Flags.Vhdl_Std >= Vhdl_08 then -- LRM08 5.2.6 Predefined operations on scalar types -- Given a type declaration that declares a scalar type T, the -- following operations are implicitely declared immediately -- following the type declaration (except for the TO_STRING -- operations in package STANDARD [...]) Add_Min_Max (Name_Minimum, Iir_Predefined_Enum_Minimum); Add_Min_Max (Name_Maximum, Iir_Predefined_Enum_Maximum); if not Is_Std_Standard then Add_To_String (Iir_Predefined_Enum_To_String); end if; -- LRM08 9.2.3 Relational operators -- The matching relational operators are predefined for the -- [predefined type BIT and for the] type STD_ULOGIC defined -- in package STD_LOGIC_1164. if Type_Definition = Ieee.Std_Logic_1164.Std_Ulogic_Type then Add_Binary (Name_Op_Match_Equality, Iir_Predefined_Std_Ulogic_Match_Equality); Add_Binary (Name_Op_Match_Inequality, Iir_Predefined_Std_Ulogic_Match_Inequality); Add_Binary (Name_Op_Match_Less, Iir_Predefined_Std_Ulogic_Match_Less); Add_Binary (Name_Op_Match_Less_Equal, Iir_Predefined_Std_Ulogic_Match_Less_Equal); Add_Binary (Name_Op_Match_Greater, Iir_Predefined_Std_Ulogic_Match_Greater); Add_Binary (Name_Op_Match_Greater_Equal, Iir_Predefined_Std_Ulogic_Match_Greater_Equal); end if; end if; when Iir_Kind_Array_Type_Definition | Iir_Kind_Array_Subtype_Definition => declare Element_Type : Iir; Element_Array_Inter_Chain : Iir; Array_Element_Inter_Chain : Iir; Element_Element_Inter_Chain : Iir; begin Add_Relational (Name_Op_Equality, Iir_Predefined_Array_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Array_Inequality); if Is_Discrete_Array (Type_Definition) then Add_Relational (Name_Op_Greater, Iir_Predefined_Array_Greater); Add_Relational (Name_Op_Greater_Equal, Iir_Predefined_Array_Greater_Equal); Add_Relational (Name_Op_Less, Iir_Predefined_Array_Less); Add_Relational (Name_Op_Less_Equal, Iir_Predefined_Array_Less_Equal); -- LRM08 5.3.2.4 Predefined operations on array types -- Given a type declaration that declares a discrete array -- type T, the following operatons are implicitly declared -- immediately following the type declaration: -- function MINIMUM (L, R : T) return T; -- function MAXIMUM (L, R : T) return T; if Vhdl_Std >= Vhdl_08 then Add_Min_Max (Name_Maximum, Iir_Predefined_Array_Maximum); Add_Min_Max (Name_Minimum, Iir_Predefined_Array_Minimum); end if; end if; Element_Type := Get_Element_Subtype (Type_Definition); if Is_One_Dimensional (Type_Definition) then -- LRM93 7.2.4 Adding operators -- The concatenation operator & is predefined for any -- one-dimensional array type. Add_Operation (Name_Op_Concatenation, Iir_Predefined_Array_Array_Concat, Binary_Chain, Type_Definition); Element_Array_Inter_Chain := Create_Anonymous_Interface (Element_Type); Set_Chain (Element_Array_Inter_Chain, Unary_Chain); Add_Operation (Name_Op_Concatenation, Iir_Predefined_Element_Array_Concat, Element_Array_Inter_Chain, Type_Definition); Array_Element_Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Array_Element_Inter_Chain, Create_Anonymous_Interface (Element_Type)); Add_Operation (Name_Op_Concatenation, Iir_Predefined_Array_Element_Concat, Array_Element_Inter_Chain, Type_Definition); Element_Element_Inter_Chain := Create_Anonymous_Interface (Element_Type); Set_Chain (Element_Element_Inter_Chain, Create_Anonymous_Interface (Element_Type)); Add_Operation (Name_Op_Concatenation, Iir_Predefined_Element_Element_Concat, Element_Element_Inter_Chain, Type_Definition); -- LRM08 5.3.2.4 Predefined operations on array types -- In addition, given a type declaration that declares a -- one-dimensional array type T whose elements are of a -- sclar type E, the following operations are implicitly -- declared immediately following the type declaration: -- function MINIMUM (L : T) return E; -- function MAXIMUM (L : T) return E; if Vhdl_Std >= Vhdl_08 and then (Get_Kind (Element_Type) in Iir_Kinds_Scalar_Type_Definition) then Add_Vector_Min_Max (Name_Maximum, Iir_Predefined_Vector_Maximum); Add_Vector_Min_Max (Name_Minimum, Iir_Predefined_Vector_Minimum); end if; if Element_Type = Std_Package.Boolean_Type_Definition or else Element_Type = Std_Package.Bit_Type_Definition then -- LRM93 7.2.1 Logical operators -- LRM08 9.2.2 Logical operators -- The binary logical operators AND, OR, NAND, NOR, XOR, -- and XNOR, and the unary logical operator NOT are -- defined for predefined types BIT and BOOLEAN. They -- are also defined for any one-dimensional array type -- whose element type is BIT or BOOLEAN. Add_Unary (Name_Not, Iir_Predefined_TF_Array_Not); Add_Binary (Name_And, Iir_Predefined_TF_Array_And); Add_Binary (Name_Or, Iir_Predefined_TF_Array_Or); Add_Binary (Name_Nand, Iir_Predefined_TF_Array_Nand); Add_Binary (Name_Nor, Iir_Predefined_TF_Array_Nor); Add_Binary (Name_Xor, Iir_Predefined_TF_Array_Xor); if Flags.Vhdl_Std > Vhdl_87 then Add_Binary (Name_Xnor, Iir_Predefined_TF_Array_Xnor); -- LRM93 7.2.3 Shift operators -- The shift operators SLL, SRL, SLA, SRA, ROL and -- ROR are defined for any one-dimensional array type -- whose element type is either of the predefined -- types BIT or BOOLEAN. Add_Shift_Operators; end if; -- LRM08 9.2.2 Logical operators -- For the binary operators AND, OR, NAND, NOR, XOR and -- XNOR, the operands shall both be [of the same base -- type,] or one operand shall be of a scalar type and -- the other operand shall be a one-dimensional array -- whose element type is the scalar type. The result -- type is the same as the base type of the operands if -- [both operands are scalars of the same base type or] -- both operands are arrays, or the same as the base type -- of the array operand if one operand is a scalar and -- the other operand is an array. if Flags.Vhdl_Std >= Vhdl_08 then Add_Operation (Name_And, Iir_Predefined_TF_Element_Array_And, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_And, Iir_Predefined_TF_Array_Element_And, Array_Element_Inter_Chain, Type_Definition); Add_Operation (Name_Or, Iir_Predefined_TF_Element_Array_Or, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_Or, Iir_Predefined_TF_Array_Element_Or, Array_Element_Inter_Chain, Type_Definition); Add_Operation (Name_Nand, Iir_Predefined_TF_Element_Array_Nand, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_Nand, Iir_Predefined_TF_Array_Element_Nand, Array_Element_Inter_Chain, Type_Definition); Add_Operation (Name_Nor, Iir_Predefined_TF_Element_Array_Nor, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_Nor, Iir_Predefined_TF_Array_Element_Nor, Array_Element_Inter_Chain, Type_Definition); Add_Operation (Name_Xor, Iir_Predefined_TF_Element_Array_Xor, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_Xor, Iir_Predefined_TF_Array_Element_Xor, Array_Element_Inter_Chain, Type_Definition); Add_Operation (Name_Xnor, Iir_Predefined_TF_Element_Array_Xnor, Element_Array_Inter_Chain, Type_Definition); Add_Operation (Name_Xnor, Iir_Predefined_TF_Array_Element_Xnor, Array_Element_Inter_Chain, Type_Definition); end if; if Flags.Vhdl_Std >= Vhdl_08 then -- LRM08 9.2.2 Logical operations -- The unary logical operators AND, OR, NAND, NOR, -- XOR, and XNOR are referred to as logical reduction -- operators. The logical reduction operators are -- predefined for any one-dimensional array type whose -- element type is BIT or BOOLEAN. The result type -- for the logical reduction operators is the same as -- the element type of the operand. Add_Operation (Name_And, Iir_Predefined_TF_Reduction_And, Unary_Chain, Element_Type); Add_Operation (Name_Or, Iir_Predefined_TF_Reduction_Or, Unary_Chain, Element_Type); Add_Operation (Name_Nand, Iir_Predefined_TF_Reduction_Nand, Unary_Chain, Element_Type); Add_Operation (Name_Nor, Iir_Predefined_TF_Reduction_Nor, Unary_Chain, Element_Type); Add_Operation (Name_Xor, Iir_Predefined_TF_Reduction_Xor, Unary_Chain, Element_Type); Add_Operation (Name_Xnor, Iir_Predefined_TF_Reduction_Xnor, Unary_Chain, Element_Type); end if; end if; -- LRM08 9.2.3 Relational operators -- The matching equality and matching inequality operatotrs -- are also defined for any one-dimensional array type -- whose element type is BIT or STD_ULOGIC. if Flags.Vhdl_Std >= Vhdl_08 then if Element_Type = Std_Package.Bit_Type_Definition then Add_Operation (Name_Op_Match_Equality, Iir_Predefined_Bit_Array_Match_Equality, Binary_Chain, Element_Type); Add_Operation (Name_Op_Match_Inequality, Iir_Predefined_Bit_Array_Match_Inequality, Binary_Chain, Element_Type); elsif Element_Type = Ieee.Std_Logic_1164.Std_Ulogic_Type then Add_Operation (Name_Op_Match_Equality, Iir_Predefined_Std_Ulogic_Array_Match_Equality, Binary_Chain, Element_Type); Add_Operation (Name_Op_Match_Inequality, Iir_Predefined_Std_Ulogic_Array_Match_Inequality, Binary_Chain, Element_Type); end if; end if; -- LRM08 5.3.2.4 Predefined operations on array type -- -- Given a type declaration that declares a one-dimensional -- array type T whose element type is a character type that -- contains only character literals, the following operation -- is implicitely declared immediately following the type -- declaration if Vhdl_Std >= Vhdl_08 and then String_Type_Definition /= Null_Iir and then (Get_Kind (Element_Type) = Iir_Kind_Enumeration_Type_Definition) and then Get_Only_Characters_Flag (Element_Type) then Add_Operation (Name_To_String, Iir_Predefined_Array_Char_To_String, Unary_Chain, String_Type_Definition); end if; end if; end; when Iir_Kind_Access_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Access_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Access_Inequality); declare Deallocate_Proc: Iir_Implicit_Procedure_Declaration; Var_Interface: Iir_Variable_Interface_Declaration; begin Deallocate_Proc := Create_Iir (Iir_Kind_Implicit_Procedure_Declaration); Set_Identifier (Deallocate_Proc, Std_Names.Name_Deallocate); Set_Implicit_Definition (Deallocate_Proc, Iir_Predefined_Deallocate); Var_Interface := Create_Iir (Iir_Kind_Variable_Interface_Declaration); Set_Identifier (Var_Interface, Std_Names.Name_P); Set_Type (Var_Interface, Type_Definition); Set_Mode (Var_Interface, Iir_Inout_Mode); Set_Base_Name (Var_Interface, Var_Interface); --Set_Purity_State (Deallocate_Proc, Impure); Set_Wait_State (Deallocate_Proc, False); Set_Type_Reference (Deallocate_Proc, Decl); Set_Visible_Flag (Deallocate_Proc, True); Set_Interface_Declaration_Chain (Deallocate_Proc, Var_Interface); Compute_Subprogram_Hash (Deallocate_Proc); Insert_Incr (Last, Deallocate_Proc); end; when Iir_Kind_Record_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Record_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Record_Inequality); when Iir_Kind_Integer_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Integer_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Integer_Inequality); Add_Relational (Name_Op_Greater, Iir_Predefined_Integer_Greater); Add_Relational (Name_Op_Greater_Equal, Iir_Predefined_Integer_Greater_Equal); Add_Relational (Name_Op_Less, Iir_Predefined_Integer_Less); Add_Relational (Name_Op_Less_Equal, Iir_Predefined_Integer_Less_Equal); Add_Binary (Name_Op_Plus, Iir_Predefined_Integer_Plus); Add_Binary (Name_Op_Minus, Iir_Predefined_Integer_Minus); Add_Unary (Name_Op_Minus, Iir_Predefined_Integer_Negation); Add_Unary (Name_Op_Plus, Iir_Predefined_Integer_Identity); Add_Binary (Name_Op_Mul, Iir_Predefined_Integer_Mul); Add_Binary (Name_Op_Div, Iir_Predefined_Integer_Div); Add_Binary (Name_Mod, Iir_Predefined_Integer_Mod); Add_Binary (Name_Rem, Iir_Predefined_Integer_Rem); Add_Unary (Name_Abs, Iir_Predefined_Integer_Absolute); declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Inter_Chain, Create_Anonymous_Interface (Integer_Type_Definition)); Add_Operation (Name_Op_Exp, Iir_Predefined_Integer_Exp, Inter_Chain, Type_Definition); end; if Vhdl_Std >= Vhdl_08 then -- LRM08 5.2.6 Predefined operations on scalar types -- Given a type declaration that declares a scalar type T, the -- following operations are implicitely declared immediately -- following the type declaration (except for the TO_STRING -- operations in package STANDARD [...]) Add_Min_Max (Name_Minimum, Iir_Predefined_Integer_Minimum); Add_Min_Max (Name_Maximum, Iir_Predefined_Integer_Maximum); if not Is_Std_Standard then Add_To_String (Iir_Predefined_Integer_To_String); end if; end if; when Iir_Kind_Floating_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Floating_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Floating_Inequality); Add_Relational (Name_Op_Greater, Iir_Predefined_Floating_Greater); Add_Relational (Name_Op_Greater_Equal, Iir_Predefined_Floating_Greater_Equal); Add_Relational (Name_Op_Less, Iir_Predefined_Floating_Less); Add_Relational (Name_Op_Less_Equal, Iir_Predefined_Floating_Less_Equal); Add_Binary (Name_Op_Plus, Iir_Predefined_Floating_Plus); Add_Binary (Name_Op_Minus, Iir_Predefined_Floating_Minus); Add_Unary (Name_Op_Minus, Iir_Predefined_Floating_Negation); Add_Unary (Name_Op_Plus, Iir_Predefined_Floating_Identity); Add_Binary (Name_Op_Mul, Iir_Predefined_Floating_Mul); Add_Binary (Name_Op_Div, Iir_Predefined_Floating_Div); Add_Unary (Name_Abs, Iir_Predefined_Floating_Absolute); declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Inter_Chain, Create_Anonymous_Interface (Integer_Type_Definition)); Add_Operation (Name_Op_Exp, Iir_Predefined_Floating_Exp, Inter_Chain, Type_Definition); end; if Vhdl_Std >= Vhdl_08 then -- LRM08 5.2.6 Predefined operations on scalar types -- Given a type declaration that declares a scalar type T, the -- following operations are implicitely declared immediately -- following the type declaration (except for the TO_STRING -- operations in package STANDARD [...]) Add_Min_Max (Name_Minimum, Iir_Predefined_Floating_Minimum); Add_Min_Max (Name_Maximum, Iir_Predefined_Floating_Maximum); if not Is_Std_Standard then Add_To_String (Iir_Predefined_Floating_To_String); end if; end if; when Iir_Kind_Physical_Type_Definition => Add_Relational (Name_Op_Equality, Iir_Predefined_Physical_Equality); Add_Relational (Name_Op_Inequality, Iir_Predefined_Physical_Inequality); Add_Relational (Name_Op_Greater, Iir_Predefined_Physical_Greater); Add_Relational (Name_Op_Greater_Equal, Iir_Predefined_Physical_Greater_Equal); Add_Relational (Name_Op_Less, Iir_Predefined_Physical_Less); Add_Relational (Name_Op_Less_Equal, Iir_Predefined_Physical_Less_Equal); Add_Binary (Name_Op_Plus, Iir_Predefined_Physical_Plus); Add_Binary (Name_Op_Minus, Iir_Predefined_Physical_Minus); Add_Unary (Name_Op_Minus, Iir_Predefined_Physical_Negation); Add_Unary (Name_Op_Plus, Iir_Predefined_Physical_Identity); declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Inter_Chain, Create_Anonymous_Interface (Integer_Type_Definition)); Add_Operation (Name_Op_Mul, Iir_Predefined_Physical_Integer_Mul, Inter_Chain, Type_Definition); Add_Operation (Name_Op_Div, Iir_Predefined_Physical_Integer_Div, Inter_Chain, Type_Definition); end; declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Integer_Type_Definition); Set_Chain (Inter_Chain, Unary_Chain); Add_Operation (Name_Op_Mul, Iir_Predefined_Integer_Physical_Mul, Inter_Chain, Type_Definition); end; declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Inter_Chain, Create_Anonymous_Interface (Real_Type_Definition)); Add_Operation (Name_Op_Mul, Iir_Predefined_Physical_Real_Mul, Inter_Chain, Type_Definition); Add_Operation (Name_Op_Div, Iir_Predefined_Physical_Real_Div, Inter_Chain, Type_Definition); end; declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Real_Type_Definition); Set_Chain (Inter_Chain, Unary_Chain); Add_Operation (Name_Op_Mul, Iir_Predefined_Real_Physical_Mul, Inter_Chain, Type_Definition); end; Add_Operation (Name_Op_Div, Iir_Predefined_Physical_Physical_Div, Binary_Chain, Std_Package.Convertible_Integer_Type_Definition); Add_Unary (Name_Abs, Iir_Predefined_Physical_Absolute); if Vhdl_Std >= Vhdl_08 then -- LRM08 5.2.6 Predefined operations on scalar types -- Given a type declaration that declares a scalar type T, the -- following operations are implicitely declared immediately -- following the type declaration (except for the TO_STRING -- operations in package STANDARD [...]) Add_Min_Max (Name_Minimum, Iir_Predefined_Physical_Minimum); Add_Min_Max (Name_Maximum, Iir_Predefined_Physical_Maximum); if not Is_Std_Standard then Add_To_String (Iir_Predefined_Physical_To_String); end if; end if; when Iir_Kind_File_Type_Definition => Create_Implicit_File_Primitives (Decl, Type_Definition); when Iir_Kind_Protected_Type_Declaration => null; when others => Error_Kind ("create_predefined_operations", Type_Definition); end case; if not Is_Std_Standard then return; end if; if Decl = Std_Package.Boolean_Type then Add_Binary (Name_And, Iir_Predefined_Boolean_And); Add_Binary (Name_Or, Iir_Predefined_Boolean_Or); Add_Binary (Name_Nand, Iir_Predefined_Boolean_Nand); Add_Binary (Name_Nor, Iir_Predefined_Boolean_Nor); Add_Binary (Name_Xor, Iir_Predefined_Boolean_Xor); if Flags.Vhdl_Std > Vhdl_87 then Add_Binary (Name_Xnor, Iir_Predefined_Boolean_Xnor); end if; Add_Unary (Name_Not, Iir_Predefined_Boolean_Not); elsif Decl = Std_Package.Bit_Type then Add_Binary (Name_And, Iir_Predefined_Bit_And); Add_Binary (Name_Or, Iir_Predefined_Bit_Or); Add_Binary (Name_Nand, Iir_Predefined_Bit_Nand); Add_Binary (Name_Nor, Iir_Predefined_Bit_Nor); Add_Binary (Name_Xor, Iir_Predefined_Bit_Xor); if Flags.Vhdl_Std > Vhdl_87 then Add_Binary (Name_Xnor, Iir_Predefined_Bit_Xnor); end if; Add_Unary (Name_Not, Iir_Predefined_Bit_Not); if Flags.Vhdl_Std >= Vhdl_08 then Add_Binary (Name_Op_Match_Equality, Iir_Predefined_Bit_Match_Equality); Add_Binary (Name_Op_Match_Inequality, Iir_Predefined_Bit_Match_Inequality); Add_Binary (Name_Op_Match_Less, Iir_Predefined_Bit_Match_Less); Add_Binary (Name_Op_Match_Less_Equal, Iir_Predefined_Bit_Match_Less_Equal); Add_Binary (Name_Op_Match_Greater, Iir_Predefined_Bit_Match_Greater); Add_Binary (Name_Op_Match_Greater_Equal, Iir_Predefined_Bit_Match_Greater_Equal); -- LRM08 9.2.9 Condition operator -- The unary operator ?? is predefined for type BIT defined in -- package STANDARD. Add_Operation (Name_Op_Condition, Iir_Predefined_Bit_Condition, Unary_Chain, Std_Package.Boolean_Type_Definition); end if; elsif Decl = Std_Package.Universal_Real_Type then declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Type_Definition); Set_Chain (Inter_Chain, Create_Anonymous_Interface (Universal_Integer_Type_Definition)); Add_Operation (Name_Op_Mul, Iir_Predefined_Universal_R_I_Mul, Inter_Chain, Type_Definition); Add_Operation (Name_Op_Div, Iir_Predefined_Universal_R_I_Div, Inter_Chain, Type_Definition); end; declare Inter_Chain : Iir; begin Inter_Chain := Create_Anonymous_Interface (Universal_Integer_Type_Definition); Set_Chain (Inter_Chain, Unary_Chain); Add_Operation (Name_Op_Mul, Iir_Predefined_Universal_I_R_Mul, Inter_Chain, Type_Definition); end; end if; end Create_Implicit_Operations; procedure Sem_Type_Declaration (Decl: Iir; Is_Global : Boolean) is Def: Iir; Inter : Name_Interpretation_Type; Old_Decl : Iir; St_Decl : Iir_Subtype_Declaration; Bt_Def : Iir; begin -- Check if DECL complete a previous incomplete type declaration. Inter := Get_Interpretation (Get_Identifier (Decl)); if Valid_Interpretation (Inter) and then Is_In_Current_Declarative_Region (Inter) then Old_Decl := Get_Declaration (Inter); if Get_Kind (Old_Decl) /= Iir_Kind_Type_Declaration or else (Get_Kind (Get_Type_Definition (Old_Decl)) /= Iir_Kind_Incomplete_Type_Definition) then Old_Decl := Null_Iir; end if; else Old_Decl := Null_Iir; end if; if Old_Decl = Null_Iir then if Get_Kind (Decl) = Iir_Kind_Type_Declaration then -- This is necessary at least for enumeration type definition. Sem_Scopes.Add_Name (Decl); end if; else -- This is a way to prevent: -- type a; -- type a is access a; -- which is non-sense. Set_Visible_Flag (Old_Decl, False); end if; -- Check the definition of the type. Def := Get_Type_Definition (Decl); if Def = Null_Iir then -- Incomplete type declaration Def := Create_Iir (Iir_Kind_Incomplete_Type_Definition); Location_Copy (Def, Decl); Set_Type_Definition (Decl, Def); Set_Base_Type (Def, Def); Set_Signal_Type_Flag (Def, True); Set_Type_Declarator (Def, Decl); Set_Visible_Flag (Decl, True); Set_Incomplete_Type_List (Def, Create_Iir_List); Xref_Decl (Decl); else if Old_Decl = Null_Iir then Xref_Decl (Decl); else Xref_Body (Decl, Old_Decl); end if; Def := Sem_Type_Definition (Def, Decl); if Def /= Null_Iir then case Get_Kind (Def) is when Iir_Kind_Integer_Subtype_Definition | Iir_Kind_Floating_Subtype_Definition | Iir_Kind_Physical_Subtype_Definition | Iir_Kind_Array_Subtype_Definition => -- Some type declaration are in fact subtype declarations. St_Decl := Create_Iir (Iir_Kind_Subtype_Declaration); Location_Copy (St_Decl, Decl); Set_Identifier (St_Decl, Get_Identifier (Decl)); Set_Type (St_Decl, Def); Set_Type_Declarator (Def, St_Decl); Set_Chain (St_Decl, Get_Chain (Decl)); Set_Chain (Decl, St_Decl); -- The type declaration declares the base type. Bt_Def := Get_Base_Type (Def); Set_Type_Definition (Decl, Bt_Def); Set_Type_Declarator (Bt_Def, Decl); Set_Subtype_Definition (Decl, Def); if Old_Decl = Null_Iir then Sem_Scopes.Add_Name (St_Decl); else Replace_Name (Get_Identifier (Decl), Old_Decl, St_Decl); Set_Type_Declarator (Get_Type_Definition (Old_Decl), St_Decl); end if; Sem_Scopes.Name_Visible (St_Decl); -- The implicit subprogram will be added in the -- scope just after. Create_Implicit_Operations (Decl, False); when Iir_Kind_Enumeration_Type_Definition | Iir_Kind_Array_Type_Definition | Iir_Kind_Record_Type_Definition | Iir_Kind_Access_Type_Definition | Iir_Kind_File_Type_Definition => St_Decl := Null_Iir; Set_Type_Declarator (Def, Decl); Sem_Scopes.Name_Visible (Decl); -- The implicit subprogram will be added in the -- scope just after. Create_Implicit_Operations (Decl, False); when Iir_Kind_Protected_Type_Declaration => Set_Type_Declarator (Def, Decl); St_Decl := Null_Iir; -- No implicit subprograms. when others => Error_Kind ("sem_type_declaration", Def); end case; if Old_Decl /= Null_Iir then -- Complete the type definition. declare List : Iir_List; El : Iir; Old_Def : Iir; begin Old_Def := Get_Type_Definition (Old_Decl); Set_Signal_Type_Flag (Old_Def, Get_Signal_Type_Flag (Def)); List := Get_Incomplete_Type_List (Old_Def); for I in Natural loop El := Get_Nth_Element (List, I); exit when El = Null_Iir; Set_Designated_Type (El, Def); end loop; -- Complete the incomplete_type_definition node -- (set type_declarator and base_type). Set_Base_Type (Old_Def, Get_Base_Type (Def)); if St_Decl = Null_Iir then Set_Type_Declarator (Old_Def, Decl); Replace_Name (Get_Identifier (Decl), Old_Decl, Decl); end if; end; end if; if Is_Global then Set_Type_Has_Signal (Def); end if; end if; end if; end Sem_Type_Declaration; procedure Sem_Subtype_Declaration (Decl: Iir; Is_Global : Boolean) is Def: Iir; begin -- Real hack to skip subtype declarations of anonymous type decls. if Get_Visible_Flag (Decl) then return; end if; Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); -- Check the definition of the type. Def := Sem_Subtype_Indication (Get_Type (Decl)); if Def = Null_Iir then return; end if; if not Is_Anonymous_Type_Definition (Def) then -- There is no added constraints and therefore the subtype -- declaration is in fact an alias of the type. Def := Copy_Subtype_Indication (Def); Location_Copy (Def, Decl); end if; Set_Type (Decl, Def); Set_Type_Declarator (Def, Decl); Name_Visible (Decl); if Is_Global then Set_Type_Has_Signal (Def); end if; end Sem_Subtype_Declaration; -- If DECL is a constant declaration, and there is already a constant -- declaration in the current scope with the same name, then return it. -- Otherwise, return NULL. function Get_Deferred_Constant (Decl : Iir) return Iir is Deferred_Const : Iir; Interp : Name_Interpretation_Type; begin if Get_Kind (Decl) /= Iir_Kind_Constant_Declaration then return Null_Iir; end if; Interp := Get_Interpretation (Get_Identifier (Decl)); if not Valid_Interpretation (Interp) then return Null_Iir; end if; if not Is_In_Current_Declarative_Region (Interp) or else Is_Potentially_Visible (Interp) then -- Deferred and full declarations must be declared in the same -- declarative region. return Null_Iir; end if; Deferred_Const := Get_Declaration (Interp); if Get_Kind (Deferred_Const) /= Iir_Kind_Constant_Declaration then return Null_Iir; end if; -- LRM93 4.3.1.1 -- The corresponding full constant declaration, which defines the value -- of the constant, must appear in the body of the package. if Get_Kind (Get_Library_Unit (Get_Current_Design_Unit)) /= Iir_Kind_Package_Body then Error_Msg_Sem ("full constant declaration must appear in package body", Decl); end if; return Deferred_Const; end Get_Deferred_Constant; procedure Sem_Object_Declaration (Decl: Iir; Parent : Iir) is Atype: Iir; Default_Value : Iir; Proxy : Iir; Deferred_Const : Iir; Staticness : Iir_Staticness; begin Deferred_Const := Get_Deferred_Constant (Decl); -- Semantize type and default value: Atype := Get_Type (Decl); if Get_Kind (Atype) /= Iir_Kind_Proxy then Atype := Sem_Subtype_Indication (Atype); if Atype = Null_Iir then Atype := Create_Error_Type (Get_Type (Decl)); end if; end if; if Deferred_Const = Null_Iir then Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); else Xref_Ref (Decl, Deferred_Const); end if; if Get_Kind (Atype) = Iir_Kind_Proxy then Proxy := Get_Proxy (Atype); Default_Value := Get_Default_Value (Proxy); Atype := Get_Type (Proxy); if Atype = Null_Iir then return; end if; Proxy := Get_Type (Decl); Free_Iir (Proxy); else Default_Value := Get_Default_Value (Decl); if Default_Value /= Null_Iir then Default_Value := Sem_Expression (Default_Value, Atype); if Default_Value = Null_Iir then Default_Value := Create_Error_Expr (Get_Default_Value (Decl), Atype); end if; Check_Read (Default_Value); end if; end if; Set_Type (Decl, Atype); Default_Value := Eval_Expr_Check_If_Static (Default_Value, Atype); Set_Default_Value (Decl, Default_Value); Set_Base_Name (Decl, Decl); Set_Name_Staticness (Decl, Locally); Set_Visible_Flag (Decl, True); -- LRM93 2.6 -- The subtype indication given in the full declaration of the deferred -- constant must conform to that given in the deferred constant -- declaration. if Deferred_Const /= Null_Iir and then not Are_Trees_Equal (Get_Type (Decl), Get_Type (Deferred_Const)) then Error_Msg_Sem ("subtype indication doesn't conform with the deferred constant", Decl); end if; -- LRM 4.3.1.3 -- It is an error if a variable declaration declares a variable that is -- of a file type. -- -- LRM 4.3.1.1 -- It is an error if a constant declaration declares a constant that is -- of a file type, or an access type, or a composite type which has -- subelement that is a file type of an access type. -- -- LRM 4.3.1.2 -- It is an error if a signal declaration declares a signal that is of -- a file type [or an access type]. case Get_Kind (Atype) is when Iir_Kind_File_Type_Definition => Error_Msg_Sem (Disp_Node (Decl) & " cannot be of type file", Decl); when others => if Get_Kind (Decl) /= Iir_Kind_Variable_Declaration then Check_Signal_Type (Decl); end if; end case; if not Check_Implicit_Conversion (Atype, Default_Value) then Error_Msg_Sem ("default value length does not match object type length", Decl); end if; case Get_Kind (Decl) is when Iir_Kind_Constant_Declaration => -- LRM93 4.3.1.1 -- If the assignment symbol ":=" followed by an expression is not -- present in a constant declaration, then the declaration -- declares a deferred constant. -- Such a constant declaration may only appear in a package -- declaration. if Deferred_Const /= Null_Iir then Set_Deferred_Declaration (Decl, Deferred_Const); Set_Deferred_Declaration (Deferred_Const, Decl); end if; if Default_Value = Null_Iir then if Deferred_Const /= Null_Iir then Error_Msg_Sem ("full constant declaration must have a default value", Decl); else Set_Deferred_Declaration_Flag (Decl, True); end if; if Get_Kind (Parent) /= Iir_Kind_Package_Declaration then Error_Msg_Sem ("a constant must have a default value", Decl); end if; Set_Expr_Staticness (Decl, Globally); else -- LRM93 7.4.1: a locally static primary is defined: -- A constant (other than deferred constant) explicitly -- declared by a constant declaration and initialized -- with a locally static expression. -- Note: the staticness of the full declaration may be locally. if False and Deferred_Const /= Null_Iir then -- This is a deferred constant. Staticness := Globally; else Staticness := Min (Get_Expr_Staticness (Default_Value), Get_Type_Staticness (Atype)); -- What about expr staticness of c in: -- constant c : bit_vector (a to b) := "01"; -- where a and b are not locally static ? --Staticness := Get_Expr_Staticness (Default_Value); -- LRM 7.4.2 (Globally static primaries) -- 5. a constant if Staticness < Globally then Staticness := Globally; end if; end if; Set_Expr_Staticness (Decl, Staticness); end if; when Iir_Kind_Signal_Declaration => -- LRM93 4.3.1.2 -- It is also an error if a guarded signal of a -- scalar type is neither a resolved signal nor a -- subelement of a resolved signal. if Get_Signal_Kind (Decl) /= Iir_No_Signal_Kind and then not Get_Resolved_Flag (Atype) then Error_Msg_Sem ("guarded " & Disp_Node (Decl) & " must be resolved", Decl); end if; Set_Expr_Staticness (Decl, None); Set_Has_Disconnect_Flag (Decl, False); Set_Type_Has_Signal (Atype); when Iir_Kind_Variable_Declaration => -- LRM93 4.3.1.3 Variable declarations -- Variable declared immediatly within entity declarations, -- architectures bodies, packages, packages bodies, and blocks -- must be shared variable. -- Variables declared immediatly within subprograms and -- processes must not be shared variables. -- Variables may appear in proteted type bodies; such -- variables, which must not be shared variables, represent -- shared data. case Get_Kind (Parent) is when Iir_Kind_Entity_Declaration | Iir_Kind_Architecture_Body | Iir_Kind_Package_Declaration | Iir_Kind_Package_Body | Iir_Kind_Block_Statement | Iir_Kind_Generate_Statement => if not Get_Shared_Flag (Decl) then Error_Msg_Sem ("non shared variable declaration not allowed here", Decl); end if; when Iir_Kinds_Process_Statement | Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => if Get_Shared_Flag (Decl) then Error_Msg_Sem ("shared variable declaration not allowed here", Decl); end if; when Iir_Kind_Protected_Type_Body => if Get_Shared_Flag (Decl) then Error_Msg_Sem ("variable of protected type body must not be shared", Decl); end if; when Iir_Kind_Protected_Type_Declaration => -- This is not allowed, but caught -- in sem_protected_type_declaration. null; when others => Error_Kind ("sem_object_declaration(2)", Parent); end case; if Flags.Vhdl_Std >= Vhdl_00 then declare Base_Type : Iir; Is_Protected : Boolean; begin Base_Type := Get_Base_Type (Atype); Is_Protected := Get_Kind (Base_Type) = Iir_Kind_Protected_Type_Declaration; -- LRM00 4.3.1.3 -- The base type of the subtype indication of a -- shared variable declaration must be a protected type. if Get_Shared_Flag (Decl) and not Is_Protected then Error_Msg_Sem ("type of a shared variable must be a protected type", Decl); end if; -- LRM00 4.3.1.3 Variable declarations -- If a given variable appears (directly or indirectly) -- within a protected type body, then the base type -- denoted by the subtype indication of the variable -- declarations must not be a protected type defined by -- the protected type body. -- FIXME: indirectly ? if Is_Protected and then Get_Kind (Parent) = Iir_Kind_Protected_Type_Body and then Base_Type = Get_Protected_Type_Declaration (Parent) then Error_Msg_Sem ("variable type must not be of the protected type body", Decl); end if; end; end if; Set_Expr_Staticness (Decl, None); when others => Error_Kind ("sem_object_declaration", Decl); end case; case Get_Kind (Decl) is when Iir_Kind_Constant_Declaration => -- LRM93 §3.2.1.1 -- For a constant declared by an object declaration, the index -- ranges are defined by the initial value, if the subtype of the -- constant is unconstrained; otherwise they are defined by this -- subtype. --if Default_Value = Null_Iir -- and then not Sem_Is_Constrained (Atype) --then -- Error_Msg_Sem ("constant declaration of unconstrained " -- & Disp_Node (Atype) & " is not allowed", Decl); --end if; null; --if Deferred_Const = Null_Iir then -- Name_Visible (Decl); --end if; when Iir_Kind_Variable_Declaration | Iir_Kind_Signal_Declaration => -- LRM93 3.2.1.1 / LRM08 5.3.2.2 -- For a variable or signal declared by an object declaration, the -- subtype indication of the corressponding object declaration -- must define a constrained array subtype. if not Is_Fully_Constrained_Type (Atype) then Error_Msg_Sem ("declaration of " & Disp_Node (Decl) & " with unconstrained " & Disp_Node (Atype) & " is not allowed", Decl); if Default_Value /= Null_Iir then Error_Msg_Sem ("(even with a default value)", Decl); end if; end if; when others => Error_Kind ("sem_object_declaration(2)", Decl); end case; end Sem_Object_Declaration; procedure Sem_File_Declaration (Decl: Iir_File_Declaration) is Atype: Iir; Logical_Name: Iir; Open_Kind : Iir; begin Sem_Scopes.Add_Name (Decl); Set_Expr_Staticness (Decl, None); Set_Base_Name (Decl, Decl); Xref_Decl (Decl); -- Try to find a type. Atype := Get_Type (Decl); if Get_Kind (Atype) = Iir_Kind_Proxy then Atype := Get_Type (Get_Proxy (Atype)); Free_Iir (Get_Type (Decl)); else Atype := Sem_Subtype_Indication (Get_Type (Decl)); if Atype = Null_Iir then return; end if; end if; Set_Type (Decl, Atype); -- LRM93 4.3.1.4 -- The subtype indication of a file declaration must define a file -- subtype. if Get_Kind (Atype) /= Iir_Kind_File_Type_Definition then Error_Msg_Sem ("file subtype expected for a file declaration", Decl); return; end if; Logical_Name := Get_File_Logical_Name (Decl); -- LRM93 4.3.1.4 -- The file logical name must be an expression of predefined type -- STRING. if Logical_Name /= Null_Iir then Logical_Name := Sem_Expression (Logical_Name, String_Type_Definition); if Logical_Name /= Null_Iir then Check_Read (Logical_Name); Set_File_Logical_Name (Decl, Logical_Name); end if; end if; Open_Kind := Get_File_Open_Kind (Decl); if Open_Kind /= Null_Iir then Open_Kind := Sem_Expression (Open_Kind, File_Open_Kind_Type_Definition); if Open_Kind /= Null_Iir then Check_Read (Open_Kind); Set_File_Open_Kind (Decl, Open_Kind); end if; else -- LRM93 4.3.1.4 -- If a file open kind expression is not included in the file open -- information of a given file declaration, then the default value -- of READ_MODE is used during elaboration of the file declaration. -- -- LRM87 4.3.1.4 -- The default mode is IN, if no mode is specified. if Get_Mode (Decl) = Iir_Unknown_Mode then if Flags.Vhdl_Std = Vhdl_87 then Set_Mode (Decl, Iir_In_Mode); else Set_File_Open_Kind (Decl, File_Open_Kind_Read_Mode); end if; end if; end if; Name_Visible (Decl); -- LRM 93 2.2 -- If a pure function is the parent of a given procedure, then -- that procedure must not contain a reference to an explicitly -- declared file object [...] -- -- A pure function must not contain a reference to an explicitly -- declared file. -- Note: this check is also performed when a file is referenced. -- But a file can be declared without being explicitly referenced. if Flags.Vhdl_Std > Vhdl_93c then declare Parent : Iir; Spec : Iir; begin Parent := Get_Parent (Decl); case Get_Kind (Parent) is when Iir_Kind_Function_Body => Spec := Get_Subprogram_Specification (Parent); if Get_Pure_Flag (Spec) then Error_Msg_Sem ("cannot declare a file in a pure function", Decl); end if; when Iir_Kind_Procedure_Body => Spec := Get_Subprogram_Specification (Parent); Set_Purity_State (Spec, Impure); Set_Impure_Depth (Parent, Iir_Depth_Impure); when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => Error_Kind ("sem_file_declaration", Parent); when others => null; end case; end; end if; end Sem_File_Declaration; procedure Sem_Attribute_Declaration (Decl: Iir_Attribute_Declaration) is A_Type : Iir; Ident : Name_Id; begin -- LRM93 4.4 -- The identifier is said to be the designator of the attribute. Ident := Get_Identifier (Decl); if Ident in Std_Names.Name_Id_Attributes or else (Flags.Vhdl_Std = Vhdl_87 and then Ident in Std_Names.Name_Id_Vhdl87_Attributes) or else (Flags.Vhdl_Std > Vhdl_87 and then Ident in Std_Names.Name_Id_Vhdl93_Attributes) then Error_Msg_Sem ("predefined attribute """ & Name_Table.Image (Ident) & """ overriden", Decl); end if; Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); A_Type := Sem_Subtype_Indication (Get_Type (Decl)); if A_Type = Null_Iir then return; end if; Set_Type (Decl, A_Type); -- LRM93 4.4 Attribute declarations. -- It is an error if the type mark denotes an access type, a file type, -- a protected type, or a composite type with a subelement that is -- an access type, a file type, or a protected type. -- The subtype need not be constrained. Check_Signal_Type (Decl); Name_Visible (Decl); end Sem_Attribute_Declaration; procedure Sem_Component_Declaration (Component: Iir_Component_Declaration) is begin Sem_Scopes.Add_Name (Component); Xref_Decl (Component); -- LRM 10.1 Declarative region -- 6. A component declaration. Open_Declarative_Region; Sem_Interface_Chain (Get_Generic_Chain (Component), Interface_Generic); Sem_Interface_Chain (Get_Port_Chain (Component), Interface_Port); Close_Declarative_Region; Name_Visible (Component); end Sem_Component_Declaration; procedure Sem_Object_Alias_Declaration (Alias: Iir_Object_Alias_Declaration) is N_Type: Iir; N_Name: constant Iir := Get_Name (Alias); Name_Type : Iir; begin Set_Base_Name (Alias, Alias); -- Get_Base_Name (N_Name)); -- LRM93 4.3.3.1 Object Aliases. -- 1. A signature may not appear in a declaration of an object alias. -- FIXME: todo. -- -- 2. The name must be a static name that denotes an object. if Get_Name_Staticness (N_Name) < Globally then Error_Msg_Sem ("aliased name must be a static name", Alias); end if; -- LRM93 4.3.3.1 -- The base type of the name specified in an alias declaration must be -- the same as the base type of the type mark in the subtype indication -- (if the subtype indication is present); Name_Type := Get_Type (N_Name); N_Type := Get_Type (Alias); if N_Type = Null_Iir then Set_Type (Alias, Name_Type); N_Type := Name_Type; else -- FIXME: must be analyzed before calling Name_Visibility. N_Type := Sem_Subtype_Indication (N_Type); if N_Type /= Null_Iir then Set_Type (Alias, N_Type); if Get_Base_Type (N_Type) /= Get_Base_Type (Name_Type) then Error_Msg_Sem ("base type of aliased name and name mismatch", Alias); end if; end if; end if; -- LRM93 4.3.3.1 -- This type must not be a multi-dimensional array type. if Get_Kind (N_Type) in Iir_Kinds_Array_Type_Definition then if not Is_Unidim_Array_Type (N_Type) then Error_Msg_Sem ("aliased name must not be a multi-dimensional array type", Alias); end if; if Get_Type_Staticness (N_Type) = Locally and then Get_Type_Staticness (Name_Type) = Locally and then Eval_Discrete_Type_Length (Get_Nth_Element (Get_Index_Subtype_List (N_Type), 0)) /= Eval_Discrete_Type_Length (Get_Nth_Element (Get_Index_Subtype_List (Name_Type), 0)) then Error_Msg_Sem ("number of elements not matching in type and name", Alias); end if; end if; Set_Name_Staticness (Alias, Get_Name_Staticness (N_Name)); Set_Expr_Staticness (Alias, Get_Expr_Staticness (N_Name)); if Is_Signal_Object (N_Name) then Set_Type_Has_Signal (N_Type); end if; end Sem_Object_Alias_Declaration; function Signature_Match (N_Entity : Iir; Sig : Iir_Signature) return Boolean is List : Iir_List; Inter : Iir; El : Iir; begin List := Get_Type_Marks_List (Sig); case Get_Kind (N_Entity) is when Iir_Kind_Enumeration_Literal => -- LRM93 2.3.2 Signatures -- * Similarly, a signature is said to match the parameter and -- result type profile of a given enumeration literal if -- the signature matches the parameter and result type profile -- of the subprogram equivalent to the enumeration literal, -- defined in Section 3.1.1 return List = Null_Iir_List and then Get_Type (N_Entity) = Get_Return_Type (Sig); when Iir_Kind_Function_Declaration | Iir_Kind_Implicit_Function_Declaration => -- LRM93 2.3.2 Signatures -- * if the reserved word RETURN is present, the subprogram is -- a function and the base type of the type mark following -- the reserved word in the signature is the same as the base -- type of the return type of the function, [...] if Get_Return_Type (Sig) /= Get_Base_Type (Get_Return_Type (N_Entity)) then return False; end if; when Iir_Kind_Procedure_Declaration | Iir_Kind_Implicit_Procedure_Declaration => -- LRM93 2.3.2 Signatures -- * [...] or the reserved word RETURN is absent and the -- subprogram is a procedure. if Get_Return_Type (Sig) /= Null_Iir then return False; end if; when others => -- LRM93 2.3.2 Signatures -- A signature distinguishes between overloaded subprograms and -- overloaded enumeration literals based on their parameter -- and result type profiles. return False; end case; -- LRM93 2.3.2 Signature -- * the number of type marks prior the reserved word RETURN, if any, -- matches the number of formal parameters of the subprogram; -- * at each parameter position, the base type denoted by the type -- mark of the signature is the same as the base type of the -- corresponding formal parameter of the subprogram; [and finally, ] Inter := Get_Interface_Declaration_Chain (N_Entity); if List = Null_Iir_List then return Inter = Null_Iir; end if; for I in Natural loop El := Get_Nth_Element (List, I); if El = Null_Iir and Inter = Null_Iir then return True; end if; if El = Null_Iir or Inter = Null_Iir then return False; end if; if Get_Base_Type (Get_Type (Inter)) /= El then return False; end if; Inter := Get_Chain (Inter); end loop; -- Avoid a spurious warning. return False; end Signature_Match; -- Extract from NAME the named entity whose profile matches with SIG. function Sem_Signature (Name : Iir; Sig : Iir_Signature) return Iir is Res : Iir; El : Iir; List : Iir_List; Error : Boolean; begin -- Sem signature. List := Get_Type_Marks_List (Sig); if List /= Null_Iir_List then for I in Natural loop El := Get_Nth_Element (List, I); exit when El = Null_Iir; El := Find_Declaration (El, Decl_Type); if El /= Null_Iir then Replace_Nth_Element (List, I, Get_Base_Type (El)); end if; end loop; end if; El := Get_Return_Type (Sig); if El /= Null_Iir then El := Find_Declaration (El, Decl_Type); if El /= Null_Iir then Set_Return_Type (Sig, Get_Base_Type (El)); end if; end if; Res := Null_Iir; Error := False; if Is_Overload_List (Name) then for I in Natural loop El := Get_Nth_Element (Get_Overload_List (Name), I); exit when El = Null_Iir; if Signature_Match (El, Sig) then if Res = Null_Iir then Res := El; else Error := True; Error_Msg_Sem ("cannot resolve signature, many matching subprograms:", Sig); Error_Msg_Sem ("found: " & Disp_Node (Res), Res); end if; if Error then Error_Msg_Sem ("found: " & Disp_Node (El), El); end if; end if; end loop; else if Signature_Match (Name, Sig) then Res := Name; end if; end if; if Error then return Null_Iir; end if; if Res = Null_Iir then Error_Msg_Sem ("cannot resolve signature, no matching subprogram", Sig); end if; return Res; end Sem_Signature; -- Create implicit aliases for an alias ALIAS of a type or of a subtype. procedure Add_Aliases_For_Type_Alias (Alias : Iir) is N_Entity : constant Iir := Get_Name (Alias); Def : constant Iir := Get_Base_Type (Get_Type_Of_Type_Mark (N_Entity)); Type_Decl : constant Iir := Get_Type_Declarator (Def); Last : Iir; El : Iir; Enum_List : Iir_Enumeration_Literal_List; -- Append an implicit alias procedure Add_Implicit_Alias (Decl : Iir) is N_Alias : constant Iir_Non_Object_Alias_Declaration := Create_Iir (Iir_Kind_Non_Object_Alias_Declaration); begin Location_Copy (N_Alias, Alias); Set_Identifier (N_Alias, Get_Identifier (Decl)); Set_Name (N_Alias, Decl); Set_Parent (N_Alias, Get_Parent (Alias)); Set_Implicit_Alias_Flag (N_Alias, True); Sem_Scopes.Add_Name (N_Alias); Set_Visible_Flag (N_Alias, True); -- Append in the declaration chain. Set_Chain (N_Alias, Get_Chain (Last)); Set_Chain (Last, N_Alias); Last := N_Alias; end Add_Implicit_Alias; begin Last := Alias; if Get_Kind (Def) = Iir_Kind_Enumeration_Type_Definition then -- LRM93 4.3.3.2 Non-Object Aliases -- 3. If the name denotes an enumeration type, then one -- implicit alias declaration for each of the -- literals of the type immediatly follows the alias -- declaration for the enumeration type; [...] -- -- LRM08 6.6.3 Nonobject aliases -- c) If the name denotes an enumeration type of a subtype of an -- enumeration type, then one implicit alias declaration for each -- of the litereals of the base type immediately follows the -- alias declaration for the enumeration type; [...] Enum_List := Get_Enumeration_Literal_List (Def); for I in Natural loop El := Get_Nth_Element (Enum_List, I); exit when El = Null_Iir; -- LRM93 4.3.3.2 Non-Object Aliases -- [...] each such implicit declaration has, as its alias -- designator, the simple name or character literal of the -- literal, and has, as its name, a name constructed by taking -- the name of the alias for the enumeration type and -- substituting the simple name or character literal being -- aliased for the simple name of the type. Each implicit -- alias has a signature that matches the parameter and result -- type profile of the literal being aliased. -- -- LRM08 6.6.3 Nonobject aliases -- [...] each such implicit declaration has, as its alias -- designator, the simple name or character literal of the -- literal and has, as its name, a name constructed by taking -- the name of the alias for the enumeration type or subtype -- and substituing the simple name or character literal being -- aliased for the simple name of the type or subtype. Each -- implicit alias has a signature that matches the parameter -- and result type profile of the literal being aliased. Add_Implicit_Alias (El); end loop; end if; -- LRM93 4.3.3.2 Non-Object Aliases -- 4. Alternatively, if the name denotes a physical type -- [...] -- GHDL: this is not possible, since a physical type is -- anonymous (LRM93 is buggy on this point). -- -- LRM08 6.6.3 Nonobject aliases -- d) Alternatively, if the name denotes a subtype of a physical type, -- [...] if Get_Kind (Def) = Iir_Kind_Physical_Type_Definition then -- LRM08 6.3.3 Nonobject aliases -- [...] then one implicit alias declaration for each of the -- units of the base type immediately follows the alias -- declaration for the physical type; each such implicit -- declaration has, as its alias designator, the simple name of -- the unit and has, as its name, a name constructed by taking -- the name of the alias for the subtype of the physical type -- and substituting the simple name of the unit being aliased for -- the simple name of the subtype. El := Get_Unit_Chain (Def); while El /= Null_Iir loop Add_Implicit_Alias (El); El := Get_Chain (El); end loop; end if; -- LRM93 4.3.3.2 Non-Object Aliases -- 5. Finally, if the name denotes a type, then implicit -- alias declarations for each predefined operator -- for the type immediatly follow the explicit alias -- declaration for the type, and if present, any -- implicit alias declarations for literals or units -- of the type. -- Each implicit alias has a signature that matches the -- parameter and result type profule of the implicit -- operator being aliased. -- -- LRM08 6.6.3 Nonobject aliases -- e) Finally, if the name denotes a type of a subtype, then implicit -- alias declarations for each predefined operation for the type -- immediately follow the explicit alias declaration for the type or -- subtype and, if present, any implicit alias declarations for -- literals or units of the type. Each implicit alias has a -- signature that matches the parameter and result type profile of -- the implicit operation being aliased. El := Get_Chain (Type_Decl); while El /= Null_Iir loop case Get_Kind (El) is when Iir_Kind_Implicit_Function_Declaration | Iir_Kind_Implicit_Procedure_Declaration => exit when Get_Type_Reference (El) /= Type_Decl; when others => exit; end case; Add_Implicit_Alias (El); El := Get_Chain (El); end loop; end Add_Aliases_For_Type_Alias; procedure Sem_Non_Object_Alias_Declaration (Alias : Iir_Non_Object_Alias_Declaration) is use Std_Names; N_Entity : constant Iir := Get_Name (Alias); Id : Name_Id; begin case Get_Kind (N_Entity) is when Iir_Kind_Function_Declaration | Iir_Kind_Implicit_Function_Declaration | Iir_Kind_Procedure_Declaration | Iir_Kind_Implicit_Procedure_Declaration => -- LRM93 4.3.3.2 Non-Object Aliases -- 2. A signature is required if the name denotes a subprogram -- (including an operator) or enumeration literal. if Get_Signature (Alias) = Null_Iir then Error_Msg_Sem ("signature required for subprogram", Alias); end if; when Iir_Kind_Enumeration_Literal => if Get_Signature (Alias) = Null_Iir then Error_Msg_Sem ("signature required for enumeration literal", Alias); end if; when Iir_Kind_Type_Declaration => Add_Aliases_For_Type_Alias (Alias); when Iir_Kind_Subtype_Declaration => -- LRM08 6.6.3 Nonobject aliases -- ... or a subtype ... if Flags.Vhdl_Std >= Vhdl_08 then Add_Aliases_For_Type_Alias (Alias); end if; when Iir_Kinds_Object_Declaration => raise Internal_Error; when Iir_Kind_Attribute_Declaration | Iir_Kind_Component_Declaration => null; when Iir_Kind_Terminal_Declaration => null; when others => Error_Kind ("sem_non_object_alias_declaration", N_Entity); end case; Id := Get_Identifier (Alias); case Id is when Name_Characters => -- LRM 4.3.3 Alias declarations -- If the alias designator is a character literal, the -- name must denote an enumeration literal. if Get_Kind (N_Entity) /= Iir_Kind_Enumeration_Literal then Error_Msg_Sem ("alias of a character must denote an enumeration literal", Alias); return; end if; when Name_Id_Operators | Name_Shift_Operators | Name_Word_Operators => -- LRM 4.3.3 Alias declarations -- If the alias designator is an operator symbol, the -- name must denote a function, and that function then -- overloads the operator symbol. In this latter case, -- the operator symbol and the function both must meet the -- requirements of 2.3.1. if Get_Kind (N_Entity) not in Iir_Kinds_Function_Declaration then Error_Msg_Sem ("alias of an operator must denote a function", Alias); return; end if; Check_Operator_Requirements (Id, N_Entity); when others => null; end case; end Sem_Non_Object_Alias_Declaration; function Sem_Alias_Declaration (Alias : Iir) return Iir is use Std_Names; Name : Iir; Sig : Iir_Signature; N_Entity : Iir; Res : Iir; begin Xref_Decl (Alias); Name := Get_Name (Alias); if Get_Kind (Name) = Iir_Kind_Signature then Sig := Name; Name := Get_Prefix (Name); else Sig := Null_Iir; end if; Sem_Name (Name, False); N_Entity := Get_Named_Entity (Name); if N_Entity = Error_Mark then return Alias; end if; if Is_Overload_List (N_Entity) then if Sig = Null_Iir then Error_Msg_Sem ("signature required for alias of a subprogram", Alias); return Alias; end if; end if; if Sig /= Null_Iir then N_Entity := Sem_Signature (N_Entity, Sig); end if; if N_Entity = Null_Iir then return Alias; end if; Set_Named_Entity (Name, N_Entity); Xref_Name (Name); if Is_Object_Name (N_Entity) then Sem_Scopes.Add_Name (Alias); Name_Visible (Alias); if Sig /= Null_Iir then Error_Msg_Sem ("signature not allowed for object alias", Sig); end if; Set_Name (Alias, N_Entity); Sem_Object_Alias_Declaration (Alias); return Alias; else if Get_Type (Alias) /= Null_Iir then Error_Msg_Sem ("subtype indication not allowed for non-object alias", Alias); end if; Res := Create_Iir (Iir_Kind_Non_Object_Alias_Declaration); Location_Copy (Res, Alias); Set_Parent (Res, Get_Parent (Alias)); Set_Chain (Res, Get_Chain (Alias)); Set_Identifier (Res, Get_Identifier (Alias)); Set_Name (Res, N_Entity); Set_Signature (Res, Sig); Sem_Scopes.Add_Name (Res); Name_Visible (Res); Free_Iir (Alias); Sem_Non_Object_Alias_Declaration (Res); return Res; end if; end Sem_Alias_Declaration; procedure Sem_Group_Template_Declaration (Decl : Iir_Group_Template_Declaration) is begin Sem_Scopes.Add_Name (Decl); Sem_Scopes.Name_Visible (Decl); Xref_Decl (Decl); end Sem_Group_Template_Declaration; procedure Sem_Group_Declaration (Group : Iir_Group_Declaration) is use Tokens; Constituent_List : Iir_Group_Constituent_List; Template : Iir_Group_Template_Declaration; Class, Prev_Class : Token_Type; El : Iir; El_Name : Iir; El_Entity : Iir_Entity_Class; begin Sem_Scopes.Add_Name (Group); Xref_Decl (Group); Template := Find_Declaration (Get_Group_Template_Name (Group), Decl_Group_Template); if Template = Null_Iir then return; end if; Set_Group_Template_Name (Group, Template); Constituent_List := Get_Group_Constituent_List (Group); El_Entity := Get_Entity_Class_Entry_Chain (Template); Prev_Class := Tok_Eof; for I in Natural loop El := Get_Nth_Element (Constituent_List, I); exit when El = Null_Iir; if El_Entity = Null_Iir then Error_Msg_Sem ("too many elements in group constituent list", Group); exit; end if; Class := Get_Entity_Class (El_Entity); if Class = Tok_Box then -- LRM93 4.6 -- An entity class entry that includes a box (<>) allows zero -- or more group constituents to appear in this position in the -- corresponding group declaration. Class := Prev_Class; else Prev_Class := Class; El_Entity := Get_Chain (El_Entity); end if; Sem_Name (El, False); El_Name := Get_Named_Entity (El); if El_Name /= Error_Mark then -- LRM93 4.7 -- It is an error if the class of any group constituent in the -- group constituent list is not the same as the class specified -- by the corresponding entity class entry in the entity class -- entry list of the group template. if Get_Entity_Class_Kind (El_Name) /= Class then Error_Msg_Sem ("constituent not of class '" & Tokens.Image (Class) & ''', El); end if; Xref_Name (El); end if; end loop; -- End of entity_class list reached or zero or more constituent allowed. if not (El_Entity = Null_Iir or else Get_Entity_Class (El_Entity) = Tok_Box) then Error_Msg_Sem ("not enough elements in group constituent list", Group); end if; Set_Visible_Flag (Group, True); end Sem_Group_Declaration; function Sem_Scalar_Nature_Definition (Def : Iir; Decl : Iir) return Iir is function Sem_Scalar_Nature_Typemark (T : Iir; Name : String) return Iir is Res : Iir; begin Res := Find_Declaration (T, Decl_Type); if Res = Null_Iir then return Real_Type_Definition; end if; -- LRM93 3.5.1 -- The type marks must denote floating point types case Get_Kind (Res) is when Iir_Kind_Floating_Subtype_Definition | Iir_Kind_Floating_Type_Definition => return Res; when others => Error_Msg_Sem (Name & "type must be a floating point type", T); return Real_Type_Definition; end case; end Sem_Scalar_Nature_Typemark; Tm : Iir; Ref : Iir; begin Tm := Get_Across_Type (Def); Tm := Sem_Scalar_Nature_Typemark (Tm, "across"); Set_Across_Type (Def, Tm); Tm := Get_Through_Type (Def); Tm := Sem_Scalar_Nature_Typemark (Tm, "through"); Set_Through_Type (Def, Tm); -- Declare the reference Ref := Get_Reference (Def); Set_Nature (Ref, Def); Set_Chain (Ref, Get_Chain (Decl)); Set_Chain (Decl, Ref); return Def; end Sem_Scalar_Nature_Definition; function Sem_Nature_Definition (Def : Iir; Decl : Iir) return Iir is begin case Get_Kind (Def) is when Iir_Kind_Scalar_Nature_Definition => return Sem_Scalar_Nature_Definition (Def, Decl); when others => Error_Kind ("sem_nature_definition", Def); return Null_Iir; end case; end Sem_Nature_Definition; procedure Sem_Nature_Declaration (Decl : Iir) is Def : Iir; begin Def := Get_Nature (Decl); if Def /= Null_Iir then Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); Def := Sem_Nature_Definition (Def, Decl); if Def /= Null_Iir then Set_Nature_Declarator (Def, Decl); Sem_Scopes.Name_Visible (Decl); end if; end if; end Sem_Nature_Declaration; procedure Sem_Terminal_Declaration (Decl : Iir) is Def, Nature : Iir; begin Def := Get_Nature (Decl); if Def /= Null_Iir then Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); if Get_Kind (Def) = Iir_Kind_Proxy then Nature := Get_Nature (Get_Proxy (Def)); Free_Iir (Def); else Nature := Sem_Subnature_Indication (Def); end if; if Nature /= Null_Iir then Set_Nature (Decl, Nature); Sem_Scopes.Name_Visible (Decl); end if; end if; end Sem_Terminal_Declaration; procedure Sem_Branch_Quantity_Declaration (Decl : Iir) is Plus : Iir; Minus : Iir; Branch_Type : Iir; Value : Iir; Proxy : Iir; begin Plus := Get_Plus_Terminal (Decl); if Get_Kind (Plus) = Iir_Kind_Proxy then Proxy := Get_Proxy (Plus); Free_Iir (Plus); Plus := Get_Plus_Terminal (Proxy); Minus := Get_Minus_Terminal (Proxy); Value := Get_Default_Value (Proxy); else Plus := Find_Declaration (Plus, Decl_Terminal); Minus := Get_Minus_Terminal (Decl); if Minus /= Null_Iir then Minus := Find_Declaration (Minus, Decl_Terminal); end if; Proxy := Null_Iir; end if; Set_Plus_Terminal (Decl, Plus); Set_Minus_Terminal (Decl, Minus); case Get_Kind (Decl) is when Iir_Kind_Across_Quantity_Declaration => Branch_Type := Get_Across_Type (Get_Nature (Plus)); when Iir_Kind_Through_Quantity_Declaration => Branch_Type := Get_Through_Type (Get_Nature (Plus)); when others => raise Program_Error; end case; Set_Type (Decl, Branch_Type); Set_Base_Name (Decl, Decl); if Proxy = Null_Iir then Value := Get_Default_Value (Decl); if Value /= Null_Iir then Value := Sem_Expression (Value, Branch_Type); end if; else Value := Get_Default_Value (Proxy); end if; Set_Default_Value (Decl, Value); -- TODO: tolerance Sem_Scopes.Add_Name (Decl); Xref_Decl (Decl); Sem_Scopes.Name_Visible (Decl); end Sem_Branch_Quantity_Declaration; procedure Sem_Declaration_Chain (Parent : Iir) is Decl: Iir; Last_Decl : Iir; Attr_Spec_Chain : Iir; Kind : Iir_Kind; -- If IS_GLOBAL is set, then declarations may be seen outside of unit. -- This must be set for entities and packages (except when -- Flags.Flag_Whole_Analyze is set). Is_Global : Boolean; begin case Get_Kind (Parent) is when Iir_Kind_Entity_Declaration | Iir_Kind_Package_Declaration => Is_Global := not Flags.Flag_Whole_Analyze; when others => Is_Global := False; end case; -- Due to implicit declarations, the list can grow during sem. Decl := Get_Declaration_Chain (Parent); Last_Decl := Null_Iir; Attr_Spec_Chain := Null_Iir; loop << Again >> exit when Decl = Null_Iir; Kind := Get_Kind (Decl); case Kind is when Iir_Kind_Type_Declaration | Iir_Kind_Anonymous_Type_Declaration => Sem_Type_Declaration (Decl, Is_Global); when Iir_Kind_Subtype_Declaration => Sem_Subtype_Declaration (Decl, Is_Global); when Iir_Kind_Signal_Declaration => Sem_Object_Declaration (Decl, Parent); when Iir_Kind_Constant_Declaration => Sem_Object_Declaration (Decl, Parent); when Iir_Kind_Variable_Declaration => Sem_Object_Declaration (Decl, Parent); when Iir_Kind_Attribute_Declaration => Sem_Attribute_Declaration (Decl); when Iir_Kind_Attribute_Specification => Sem_Attribute_Specification (Decl, Parent); if Get_Entity_Name_List (Decl) in Iir_Lists_All_Others then Set_Attribute_Specification_Chain (Decl, Attr_Spec_Chain); Attr_Spec_Chain := Decl; end if; when Iir_Kind_Component_Declaration => Sem_Component_Declaration (Decl); when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => declare Res : Iir; begin Res := Sem_Subprogram_Declaration (Decl); if Res /= Decl then -- Replace DECL with RES. if Last_Decl = Null_Iir then Set_Declaration_Chain (Parent, Res); else Set_Chain (Last_Decl, Res); end if; Decl := Res; -- Since RES is a body, no need to check for post -- attribute specification. goto Again; end if; if Is_Global and then Kind = Iir_Kind_Function_Declaration and then Is_A_Resolution_Function (Res, Null_Iir) then Set_Resolution_Function_Flag (Res, True); end if; end; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body => Sem_Subprogram_Body (Decl); when Iir_Kind_Implicit_Function_Declaration | Iir_Kind_Implicit_Procedure_Declaration => Sem_Scopes.Add_Name (Decl); -- Implicit subprogram are already visible. when Iir_Kind_Non_Object_Alias_Declaration => -- Added by Sem_Alias_Declaration. Need to check that no -- existing attribute specification apply to them. null; when Iir_Kind_Object_Alias_Declaration => declare Res : Iir; begin Res := Sem_Alias_Declaration (Decl); if Res /= Decl then -- Replace DECL with RES. if Last_Decl = Null_Iir then Set_Declaration_Chain (Parent, Res); else Set_Chain (Last_Decl, Res); end if; Decl := Res; -- An alias may add new alias declarations. Do not skip -- them: check that no existing attribute specifications -- apply to them. end if; end; when Iir_Kind_File_Declaration => Sem_File_Declaration (Decl); when Iir_Kind_Use_Clause => Sem_Use_Clause (Decl); when Iir_Kind_Configuration_Specification => null; when Iir_Kind_Disconnection_Specification => Sem_Disconnect_Specification (Decl); when Iir_Kind_Group_Template_Declaration => Sem_Group_Template_Declaration (Decl); when Iir_Kind_Group_Declaration => Sem_Group_Declaration (Decl); when Iir_Kinds_Signal_Attribute => -- Added by sem, so nothing to do. null; when Iir_Kind_Protected_Type_Body => Sem_Protected_Type_Body (Decl); when Iir_Kind_Nature_Declaration => Sem_Nature_Declaration (Decl); when Iir_Kind_Terminal_Declaration => Sem_Terminal_Declaration (Decl); when Iir_Kind_Across_Quantity_Declaration | Iir_Kind_Through_Quantity_Declaration => Sem_Branch_Quantity_Declaration (Decl); when others => Error_Kind ("sem_declaration_chain", Decl); end case; if Attr_Spec_Chain /= Null_Iir then Check_Post_Attribute_Specification (Attr_Spec_Chain, Decl); end if; Last_Decl := Decl; Decl := Get_Chain (Decl); end loop; end Sem_Declaration_Chain; procedure Check_Full_Declaration (Decls_Parent : Iir; Decl: Iir) is El: Iir; -- If set, emit a warning if a declaration is not used. Check_Unused : Boolean; begin -- LRM 3.5 Protected types. -- Each protected type declaration appearing immediatly within a given -- declaration region must have exactly one corresponding protected type -- body appearing immediatly within the same declarative region and -- textually subsequent to the protected type declaration. -- LRM 3.3.1 Incomplete type declarations -- For each incomplete type declaration, there must be a corresponding -- full type declaration with the same identifier. This full type -- declaration must occur later and immediatly within the same -- declarative part as the incomplete type declaration to which it -- correspinds. -- LRM 4.3.1.1 Constant declarations -- If the assignment symbol ":=" followed by an expression is not -- present in a constant declaration, then the declaration declares a -- deferred constant. Such a constant declaration must appear in a -- package declaration. The corresponding full constant declaration, -- which defines the value of the constant, must appear in the body of -- the package (see 2.6). -- LRM 2.2 Subprogram bodies -- If both a declaration and a body are given, [...]. Furthermore, -- both the declaration and the body must occur immediatly within the -- same declaration region. -- Set Check_Unused. Check_Unused := False; if Flags.Warn_Unused then case Get_Kind (Decl) is when Iir_Kind_Entity_Declaration => -- May be used in architecture. null; when Iir_Kind_Architecture_Body | Iir_Kind_Block_Statement | Iir_Kind_Generate_Statement => -- Might be used in a configuration. -- FIXME: create a second level of warning. null; when Iir_Kind_Package_Body | Iir_Kind_Protected_Type_Body => -- Check only for declarations of the body. if Decls_Parent = Decl then Check_Unused := True; end if; when Iir_Kind_Function_Body | Iir_Kind_Procedure_Body | Iir_Kind_Process_Statement | Iir_Kind_Sensitized_Process_Statement => Check_Unused := True; when others => -- Note: Check_Full_Declaration is not called -- for package declarations or protected type declarations. Error_Kind ("check_full_declaration", Decl); end case; end if; El := Get_Declaration_Chain (Decls_Parent); while El /= Null_Iir loop case Get_Kind (El) is when Iir_Kind_Constant_Declaration => if Get_Deferred_Declaration_Flag (El) then if Get_Deferred_Declaration (El) = Null_Iir then Error_Msg_Sem ("missing value for constant declared at " & Disp_Location (El), Decl); else -- Remove from visibility the full declaration of the -- constant. -- FIXME: this is not a check! Set_Deferred_Declaration (El, Null_Iir); end if; end if; when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => if Get_Subprogram_Body (El) = Null_Iir then Error_Msg_Sem ("missing body for " & Disp_Node (El) & " declared at " & Disp_Location (El), Decl); end if; when Iir_Kind_Type_Declaration => declare Def : Iir; begin Def := Get_Type_Definition (El); if Get_Kind (Def) = Iir_Kind_Incomplete_Type_Definition and then Get_Type_Declarator (Def) = El then Error_Msg_Sem ("missing full type declaration for " & Disp_Node (El), El); elsif Get_Kind (Def) = Iir_Kind_Protected_Type_Declaration and then Get_Protected_Type_Body (Def) = Null_Iir then Error_Msg_Sem ("missing protected type body for " & Disp_Node (El), El); end if; end; when others => null; end case; if Check_Unused then -- All subprograms declared in the specification (package or -- protected type) have only their *body* in the body. -- Therefore, they don't appear as declaration in body. -- Only private subprograms appears as declarations. case Get_Kind (El) is when Iir_Kind_Function_Declaration | Iir_Kind_Procedure_Declaration => if not Get_Use_Flag (El) then Warning_Msg_Sem (Disp_Node (El) & " is never referenced", El); end if; when others => null; end case; end if; El := Get_Chain (El); end loop; end Check_Full_Declaration; procedure Sem_Iterator (Iterator : Iir_Iterator_Declaration; Staticness : Iir_Staticness) is It_Type: Iir; A_Range: Iir; Range_Type : Iir; begin Xref_Decl (Iterator); It_Type := Get_Type (Iterator); A_Range := Sem_Discrete_Range_Integer (It_Type); if A_Range = Null_Iir then Set_Type (Iterator, Create_Error_Type (Iterator)); return; end if; if Get_Kind (A_Range) in Iir_Kinds_Type_And_Subtype_Definition then Range_Type := A_Range; else Range_Type := Get_Type (A_Range); end if; case Get_Kind (Range_Type) is when Iir_Kinds_Discrete_Type_Definition => null; when others => Error_Msg_Sem ("iterator is not of discrete type", A_Range); Set_Type (Iterator, Null_Iir); return; end case; Set_Type (Iterator, Range_To_Subtype_Definition (A_Range)); Set_Base_Name (Iterator, Iterator); Set_Expr_Staticness (Iterator, Staticness); end Sem_Iterator; end Sem_Decls;