-- Iir to ortho translator. -- Copyright (C) 2002 - 2014 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 GCC; see the file COPYING. If not, write to the Free -- Software Foundation, 59 Temple Place - Suite 330, Boston, MA -- 02111-1307, USA. with Evaluation; use Evaluation; with Std_Package; use Std_Package; with Errorout; use Errorout; with Iirs_Utils; use Iirs_Utils; with Trans_Decls; use Trans_Decls; with Trans.Chap3; with Trans.Chap6; with Trans.Chap7; with Trans.Rtis; with Trans.Helpers2; use Trans.Helpers2; with Trans.Foreach_Non_Composite; package body Trans.Chap14 is use Trans.Helpers; function Translate_Array_Attribute_To_Range (Expr : Iir) return Mnode is Prefix : constant Iir := Get_Prefix (Expr); Type_Name : constant Iir := Is_Type_Name (Prefix); Arr : Mnode; Dim : Natural; begin if Type_Name /= Null_Iir then -- Prefix denotes a type name Arr := T2M (Type_Name, Mode_Value); else -- Prefix is an object. Arr := Chap6.Translate_Name (Prefix, Mode_Value); end if; Dim := Natural (Get_Value (Get_Parameter (Expr))); return Chap3.Get_Array_Range (Arr, Get_Type (Prefix), Dim); end Translate_Array_Attribute_To_Range; function Translate_Range_Array_Attribute (Expr : Iir) return O_Lnode is begin return M2Lv (Translate_Array_Attribute_To_Range (Expr)); end Translate_Range_Array_Attribute; function Translate_Length_Array_Attribute (Expr : Iir; Rtype : Iir) return O_Enode is Rng : Mnode; Val : O_Enode; begin Rng := Translate_Array_Attribute_To_Range (Expr); Val := M2E (Chap3.Range_To_Length (Rng)); if Rtype /= Null_Iir then Val := New_Convert_Ov (Val, Get_Ortho_Type (Rtype, Mode_Value)); end if; return Val; end Translate_Length_Array_Attribute; -- Extract high or low bound of RANGE_VAR. function Range_To_High_Low (Range_Var : Mnode; Range_Type : Iir; Is_High : Boolean) return Mnode is Op : ON_Op_Kind; If_Blk : O_If_Block; Range_Svar : constant Mnode := Stabilize (Range_Var); Res : O_Dnode; Tinfo : constant Ortho_Info_Acc := Get_Info (Get_Base_Type (Range_Type)); begin Res := Create_Temp (Tinfo.Ortho_Type (Mode_Value)); Open_Temp; if Is_High then Op := ON_Neq; else Op := ON_Eq; end if; Start_If_Stmt (If_Blk, New_Compare_Op (Op, M2E (Chap3.Range_To_Dir (Range_Svar)), New_Lit (Ghdl_Dir_To_Node), Ghdl_Bool_Type)); New_Assign_Stmt (New_Obj (Res), M2E (Chap3.Range_To_Left (Range_Svar))); New_Else_Stmt (If_Blk); New_Assign_Stmt (New_Obj (Res), M2E (Chap3.Range_To_Right (Range_Svar))); Finish_If_Stmt (If_Blk); Close_Temp; return Dv2M (Res, Tinfo, Mode_Value); end Range_To_High_Low; function Translate_High_Low_Type_Attribute (Atype : Iir; Is_High : Boolean) return O_Enode is Cons : constant Iir := Get_Range_Constraint (Atype); begin -- FIXME: improve code if constraint is a range expression. if Get_Type_Staticness (Atype) = Locally then if Get_Direction (Cons) = Iir_To xor Is_High then return New_Lit (Chap7.Translate_Static_Range_Left (Cons, Atype)); else return New_Lit (Chap7.Translate_Static_Range_Right (Cons, Atype)); end if; else return M2E (Range_To_High_Low (Chap3.Type_To_Range (Atype), Atype, Is_High)); end if; end Translate_High_Low_Type_Attribute; function Translate_High_Low_Array_Attribute (Expr : Iir; Is_High : Boolean) return O_Enode is begin -- FIXME: improve code if index is a range expression. return M2E (Range_To_High_Low (Translate_Array_Attribute_To_Range (Expr), Get_Type (Expr), Is_High)); end Translate_High_Low_Array_Attribute; function Translate_Low_Array_Attribute (Expr : Iir) return O_Enode is begin return Translate_High_Low_Array_Attribute (Expr, False); end Translate_Low_Array_Attribute; function Translate_High_Array_Attribute (Expr : Iir) return O_Enode is begin return Translate_High_Low_Array_Attribute (Expr, True); end Translate_High_Array_Attribute; function Translate_Left_Array_Attribute (Expr : Iir) return O_Enode is Rng : Mnode; begin Rng := Translate_Array_Attribute_To_Range (Expr); return M2E (Chap3.Range_To_Left (Rng)); end Translate_Left_Array_Attribute; function Translate_Right_Array_Attribute (Expr : Iir) return O_Enode is Rng : Mnode; begin Rng := Translate_Array_Attribute_To_Range (Expr); return M2E (Chap3.Range_To_Right (Rng)); end Translate_Right_Array_Attribute; function Translate_Ascending_Array_Attribute (Expr : Iir) return O_Enode is Rng : Mnode; begin Rng := Translate_Array_Attribute_To_Range (Expr); return New_Compare_Op (ON_Eq, M2E (Chap3.Range_To_Dir (Rng)), New_Lit (Ghdl_Dir_To_Node), Std_Boolean_Type_Node); end Translate_Ascending_Array_Attribute; function Translate_Left_Type_Attribute (Atype : Iir) return O_Enode is begin if Get_Type_Staticness (Atype) = Locally then return New_Lit (Chap7.Translate_Static_Range_Left (Get_Range_Constraint (Atype), Atype)); else return M2E (Chap3.Range_To_Left (Chap3.Type_To_Range (Atype))); end if; end Translate_Left_Type_Attribute; function Translate_Right_Type_Attribute (Atype : Iir) return O_Enode is begin if Get_Type_Staticness (Atype) = Locally then return New_Lit (Chap7.Translate_Static_Range_Right (Get_Range_Constraint (Atype), Atype)); else return M2E (Chap3.Range_To_Right (Chap3.Type_To_Range (Atype))); end if; end Translate_Right_Type_Attribute; function Translate_Dir_Type_Attribute (Atype : Iir) return O_Enode is Info : Type_Info_Acc; begin if Get_Type_Staticness (Atype) = Locally then return New_Lit (Chap7.Translate_Static_Range_Dir (Get_Range_Constraint (Atype))); else Info := Get_Info (Atype); return New_Value (New_Selected_Element (Get_Var (Info.T.Range_Var), Info.T.Range_Dir)); end if; end Translate_Dir_Type_Attribute; function Translate_Val_Attribute (Attr : Iir) return O_Enode is Val : O_Enode; Attr_Type : Iir; Res_Var : O_Dnode; Res_Type : O_Tnode; begin Attr_Type := Get_Type (Attr); Res_Type := Get_Ortho_Type (Attr_Type, Mode_Value); Res_Var := Create_Temp (Res_Type); Val := Chap7.Translate_Expression (Get_Parameter (Attr)); case Get_Kind (Attr_Type) is when Iir_Kind_Enumeration_Type_Definition | Iir_Kind_Enumeration_Subtype_Definition => -- For enumeration, always check the value is in the enum -- range. declare Val_Type : O_Tnode; Val_Var : O_Dnode; If_Blk : O_If_Block; begin Val_Type := Get_Ortho_Type (Get_Type (Get_Parameter (Attr)), Mode_Value); Val_Var := Create_Temp_Init (Val_Type, Val); Start_If_Stmt (If_Blk, New_Dyadic_Op (ON_Or, New_Compare_Op (ON_Lt, New_Obj_Value (Val_Var), New_Lit (New_Signed_Literal (Val_Type, 0)), Ghdl_Bool_Type), New_Compare_Op (ON_Ge, New_Obj_Value (Val_Var), New_Lit (New_Signed_Literal (Val_Type, Integer_64 (Get_Nbr_Elements (Get_Enumeration_Literal_List (Attr_Type))))), Ghdl_Bool_Type))); Chap6.Gen_Bound_Error (Attr); Finish_If_Stmt (If_Blk); Val := New_Obj_Value (Val_Var); end; when others => null; end case; New_Assign_Stmt (New_Obj (Res_Var), New_Convert_Ov (Val, Res_Type)); Chap3.Check_Range (Res_Var, Attr, Get_Type (Get_Prefix (Attr)), Attr); return New_Obj_Value (Res_Var); end Translate_Val_Attribute; function Translate_Pos_Attribute (Attr : Iir; Res_Type : Iir) return O_Enode is T : O_Dnode; Ttype : O_Tnode; begin Ttype := Get_Ortho_Type (Res_Type, Mode_Value); T := Create_Temp (Ttype); New_Assign_Stmt (New_Obj (T), New_Convert_Ov (Chap7.Translate_Expression (Get_Parameter (Attr)), Ttype)); Chap3.Check_Range (T, Attr, Res_Type, Attr); return New_Obj_Value (T); end Translate_Pos_Attribute; function Translate_Succ_Pred_Attribute (Attr : Iir) return O_Enode is Expr_Type : constant Iir := Get_Type (Attr); Tinfo : constant Type_Info_Acc := Get_Info (Expr_Type); Ttype : O_Tnode; Expr : O_Enode; Is_Inc : Boolean; Op : ON_Op_Kind; begin -- FIXME: should check bounds. Expr := Chap7.Translate_Expression (Get_Parameter (Attr), Expr_Type); Ttype := Tinfo.Ortho_Type (Mode_Value); case Get_Kind (Attr) is when Iir_Kind_Succ_Attribute => Is_Inc := True; when Iir_Kind_Pred_Attribute => Is_Inc := False; when Iir_Kind_Leftof_Attribute => Is_Inc := Get_Direction (Get_Range_Constraint (Expr_Type)) = Iir_Downto; when Iir_Kind_Rightof_Attribute => Is_Inc := Get_Direction (Get_Range_Constraint (Expr_Type)) = Iir_To; when others => Error_Kind ("translate_succ_pred_attribute", Attr); end case; if Is_Inc then Op := ON_Add_Ov; else Op := ON_Sub_Ov; end if; case Tinfo.Type_Mode is when Type_Mode_B1 | Type_Mode_E8 | Type_Mode_E32 => -- Should check it is not the last. declare List : constant Iir_List := Get_Enumeration_Literal_List (Get_Base_Type (Expr_Type)); Limit : Iir; L : O_Dnode; begin L := Create_Temp_Init (Ttype, Expr); if Is_Inc then Limit := Get_Last_Element (List); else Limit := Get_First_Element (List); end if; Chap6.Check_Bound_Error (New_Compare_Op (ON_Eq, New_Obj_Value (L), New_Lit (Get_Ortho_Expr (Limit)), Ghdl_Bool_Type), Attr, 0); return New_Convert_Ov (New_Dyadic_Op (Op, New_Convert_Ov (New_Obj_Value (L), Ghdl_I32_Type), New_Lit (New_Signed_Literal (Ghdl_I32_Type, 1))), Ttype); end; when Type_Mode_I32 | Type_Mode_P64 => return New_Dyadic_Op (Op, Expr, New_Lit (New_Signed_Literal (Ttype, 1))); when others => raise Internal_Error; end case; end Translate_Succ_Pred_Attribute; type Bool_Sigattr_Data_Type is record Label : O_Snode; Field : O_Fnode; end record; procedure Bool_Sigattr_Non_Composite_Signal (Targ : Mnode; Targ_Type : Iir; Data : Bool_Sigattr_Data_Type) is pragma Unreferenced (Targ_Type); begin Gen_Exit_When (Data.Label, New_Value (Get_Signal_Field (Targ, Data.Field))); end Bool_Sigattr_Non_Composite_Signal; function Bool_Sigattr_Prepare_Data_Composite (Targ : Mnode; Targ_Type : Iir; Data : Bool_Sigattr_Data_Type) return Bool_Sigattr_Data_Type is pragma Unreferenced (Targ, Targ_Type); begin return Data; end Bool_Sigattr_Prepare_Data_Composite; function Bool_Sigattr_Update_Data_Array (Data : Bool_Sigattr_Data_Type; Targ_Type : Iir; Index : O_Dnode) return Bool_Sigattr_Data_Type is pragma Unreferenced (Targ_Type, Index); begin return Data; end Bool_Sigattr_Update_Data_Array; function Bool_Sigattr_Update_Data_Record (Data : Bool_Sigattr_Data_Type; Targ_Type : Iir; El : Iir_Element_Declaration) return Bool_Sigattr_Data_Type is pragma Unreferenced (Targ_Type, El); begin return Data; end Bool_Sigattr_Update_Data_Record; procedure Bool_Sigattr_Finish_Data_Composite (Data : in out Bool_Sigattr_Data_Type) is pragma Unreferenced (Data); begin null; end Bool_Sigattr_Finish_Data_Composite; procedure Bool_Sigattr_Foreach is new Foreach_Non_Composite (Data_Type => Bool_Sigattr_Data_Type, Composite_Data_Type => Bool_Sigattr_Data_Type, Do_Non_Composite => Bool_Sigattr_Non_Composite_Signal, Prepare_Data_Array => Bool_Sigattr_Prepare_Data_Composite, Update_Data_Array => Bool_Sigattr_Update_Data_Array, Finish_Data_Array => Bool_Sigattr_Finish_Data_Composite, Prepare_Data_Record => Bool_Sigattr_Prepare_Data_Composite, Update_Data_Record => Bool_Sigattr_Update_Data_Record, Finish_Data_Record => Bool_Sigattr_Finish_Data_Composite); function Translate_Bool_Signal_Attribute (Attr : Iir; Field : O_Fnode) return O_Enode is Data : Bool_Sigattr_Data_Type; Res : O_Dnode; Name : Mnode; Prefix : constant Iir := Get_Prefix (Attr); Prefix_Type : constant Iir := Get_Type (Prefix); begin if Get_Kind (Prefix_Type) in Iir_Kinds_Scalar_Type_Definition then -- Effecient handling for a scalar signal. Name := Chap6.Translate_Name (Prefix, Mode_Signal); return New_Value (Get_Signal_Field (Name, Field)); else -- Element per element handling for composite signals. Res := Create_Temp (Std_Boolean_Type_Node); Open_Temp; New_Assign_Stmt (New_Obj (Res), New_Lit (Std_Boolean_True_Node)); Name := Chap6.Translate_Name (Prefix, Mode_Signal); Start_Loop_Stmt (Data.Label); Data.Field := Field; Bool_Sigattr_Foreach (Name, Prefix_Type, Data); New_Assign_Stmt (New_Obj (Res), New_Lit (Std_Boolean_False_Node)); New_Exit_Stmt (Data.Label); Finish_Loop_Stmt (Data.Label); Close_Temp; return New_Obj_Value (Res); end if; end Translate_Bool_Signal_Attribute; function Translate_Event_Attribute (Attr : Iir) return O_Enode is begin return Translate_Bool_Signal_Attribute (Attr, Ghdl_Signal_Event_Field); end Translate_Event_Attribute; function Translate_Active_Attribute (Attr : Iir) return O_Enode is begin return Translate_Bool_Signal_Attribute (Attr, Ghdl_Signal_Active_Field); end Translate_Active_Attribute; -- Read signal value FIELD of signal SIG. function Get_Signal_Value_Field (Sig : O_Enode; Sig_Type : Iir; Field : O_Fnode) return O_Lnode is Tinfo : constant Type_Info_Acc := Get_Info (Sig_Type); S_Type : constant O_Tnode := Tinfo.Ortho_Ptr_Type (Mode_Value); T : O_Lnode; begin T := New_Access_Element (Sig); return New_Access_Element (New_Unchecked_Address (New_Selected_Element (T, Field), S_Type)); end Get_Signal_Value_Field; function Get_Signal_Field (Sig : Mnode; Field : O_Fnode) return O_Lnode is S : O_Enode; begin S := New_Convert_Ov (New_Value (M2Lv (Sig)), Ghdl_Signal_Ptr); return New_Selected_Element (New_Access_Element (S), Field); end Get_Signal_Field; function Read_Last_Value (Sig : O_Enode; Sig_Type : Iir) return O_Enode is begin return New_Value (Get_Signal_Value_Field (Sig, Sig_Type, Ghdl_Signal_Last_Value_Field)); end Read_Last_Value; function Translate_Last_Value is new Chap7.Translate_Signal_Value (Read_Value => Read_Last_Value); function Translate_Last_Value_Attribute (Attr : Iir) return O_Enode is Prefix : constant Iir := Get_Prefix (Attr); Prefix_Type : constant Iir := Get_Type (Prefix); Name : Mnode; begin Name := Chap6.Translate_Name (Prefix, Mode_Signal); return Translate_Last_Value (M2E (Name), Prefix_Type); end Translate_Last_Value_Attribute; function Read_Last_Time (Sig : O_Enode; Field : O_Fnode) return O_Enode is T : O_Lnode; begin T := New_Access_Element (New_Convert_Ov (Sig, Ghdl_Signal_Ptr)); return New_Value (New_Selected_Element (T, Field)); end Read_Last_Time; type Last_Time_Data is record Var : O_Dnode; Field : O_Fnode; end record; procedure Translate_Last_Time_Non_Composite (Targ : Mnode; Targ_Type : Iir; Data : Last_Time_Data) is pragma Unreferenced (Targ_Type); Val : O_Dnode; If_Blk : O_If_Block; begin Open_Temp; Val := Create_Temp_Init (Std_Time_Otype, Read_Last_Time (New_Value (M2Lv (Targ)), Data.Field)); Start_If_Stmt (If_Blk, New_Compare_Op (ON_Gt, New_Obj_Value (Val), New_Obj_Value (Data.Var), Ghdl_Bool_Type)); New_Assign_Stmt (New_Obj (Data.Var), New_Obj_Value (Val)); Finish_If_Stmt (If_Blk); Close_Temp; end Translate_Last_Time_Non_Composite; function Last_Time_Prepare_Data_Composite (Targ : Mnode; Targ_Type : Iir; Data : Last_Time_Data) return Last_Time_Data is pragma Unreferenced (Targ, Targ_Type); begin return Data; end Last_Time_Prepare_Data_Composite; function Last_Time_Update_Data_Array (Data : Last_Time_Data; Targ_Type : Iir; Index : O_Dnode) return Last_Time_Data is pragma Unreferenced (Targ_Type, Index); begin return Data; end Last_Time_Update_Data_Array; function Last_Time_Update_Data_Record (Data : Last_Time_Data; Targ_Type : Iir; El : Iir_Element_Declaration) return Last_Time_Data is pragma Unreferenced (Targ_Type, El); begin return Data; end Last_Time_Update_Data_Record; procedure Last_Time_Finish_Data_Composite (Data : in out Last_Time_Data) is pragma Unreferenced (Data); begin null; end Last_Time_Finish_Data_Composite; procedure Translate_Last_Time is new Foreach_Non_Composite (Data_Type => Last_Time_Data, Composite_Data_Type => Last_Time_Data, Do_Non_Composite => Translate_Last_Time_Non_Composite, Prepare_Data_Array => Last_Time_Prepare_Data_Composite, Update_Data_Array => Last_Time_Update_Data_Array, Finish_Data_Array => Last_Time_Finish_Data_Composite, Prepare_Data_Record => Last_Time_Prepare_Data_Composite, Update_Data_Record => Last_Time_Update_Data_Record, Finish_Data_Record => Last_Time_Finish_Data_Composite); function Translate_Last_Time_Attribute (Prefix : Iir; Field : O_Fnode) return O_Enode is Prefix_Type : constant Iir := Get_Type (Prefix); Name : Mnode; Info : Type_Info_Acc; Var : O_Dnode; Data : Last_Time_Data; Right_Bound : Iir_Int64; If_Blk : O_If_Block; begin Name := Chap6.Translate_Name (Prefix, Mode_Signal); Info := Get_Info (Prefix_Type); Var := Create_Temp (Std_Time_Otype); if Info.Type_Mode in Type_Mode_Scalar then New_Assign_Stmt (New_Obj (Var), Read_Last_Time (M2E (Name), Field)); else -- Init with a negative value. New_Assign_Stmt (New_Obj (Var), New_Lit (New_Signed_Literal (Std_Time_Otype, -1))); Data := Last_Time_Data'(Var => Var, Field => Field); Translate_Last_Time (Name, Prefix_Type, Data); end if; Right_Bound := Get_Value (Get_Right_Limit (Get_Range_Constraint (Time_Subtype_Definition))); -- VAR < 0 ? Start_If_Stmt (If_Blk, New_Compare_Op (ON_Lt, New_Obj_Value (Var), New_Lit (New_Signed_Literal (Std_Time_Otype, 0)), Ghdl_Bool_Type)); -- LRM 14.1 Predefined attributes -- [...]; otherwise, it returns TIME'HIGH. New_Assign_Stmt (New_Obj (Var), New_Lit (New_Signed_Literal (Std_Time_Otype, Integer_64 (Right_Bound)))); New_Else_Stmt (If_Blk); -- Returns NOW - Var. New_Assign_Stmt (New_Obj (Var), New_Dyadic_Op (ON_Sub_Ov, New_Obj_Value (Ghdl_Now), New_Obj_Value (Var))); Finish_If_Stmt (If_Blk); return New_Obj_Value (Var); end Translate_Last_Time_Attribute; -- Return TRUE if the scalar signal SIG is being driven. function Read_Driving_Attribute (Sig : O_Enode) return O_Enode is Assoc : O_Assoc_List; begin Start_Association (Assoc, Ghdl_Signal_Driving); New_Association (Assoc, New_Convert_Ov (Sig, Ghdl_Signal_Ptr)); return New_Function_Call (Assoc); end Read_Driving_Attribute; procedure Driving_Non_Composite_Signal (Targ : Mnode; Targ_Type : Iir; Label : O_Snode) is pragma Unreferenced (Targ_Type); begin Gen_Exit_When (Label, New_Monadic_Op (ON_Not, Read_Driving_Attribute (New_Value (M2Lv (Targ))))); end Driving_Non_Composite_Signal; function Driving_Prepare_Data_Composite (Targ : Mnode; Targ_Type : Iir; Label : O_Snode) return O_Snode is pragma Unreferenced (Targ, Targ_Type); begin return Label; end Driving_Prepare_Data_Composite; function Driving_Update_Data_Array (Label : O_Snode; Targ_Type : Iir; Index : O_Dnode) return O_Snode is pragma Unreferenced (Targ_Type, Index); begin return Label; end Driving_Update_Data_Array; function Driving_Update_Data_Record (Label : O_Snode; Targ_Type : Iir; El : Iir_Element_Declaration) return O_Snode is pragma Unreferenced (Targ_Type, El); begin return Label; end Driving_Update_Data_Record; procedure Driving_Finish_Data_Composite (Label : in out O_Snode) is pragma Unreferenced (Label); begin null; end Driving_Finish_Data_Composite; procedure Driving_Foreach is new Foreach_Non_Composite (Data_Type => O_Snode, Composite_Data_Type => O_Snode, Do_Non_Composite => Driving_Non_Composite_Signal, Prepare_Data_Array => Driving_Prepare_Data_Composite, Update_Data_Array => Driving_Update_Data_Array, Finish_Data_Array => Driving_Finish_Data_Composite, Prepare_Data_Record => Driving_Prepare_Data_Composite, Update_Data_Record => Driving_Update_Data_Record, Finish_Data_Record => Driving_Finish_Data_Composite); function Translate_Driving_Attribute (Attr : Iir) return O_Enode is Label : O_Snode; Res : O_Dnode; Name : Mnode; Prefix : Iir; Prefix_Type : Iir; begin Prefix := Get_Prefix (Attr); Prefix_Type := Get_Type (Prefix); if Get_Kind (Prefix_Type) in Iir_Kinds_Scalar_Type_Definition then -- Effecient handling for a scalar signal. Name := Chap6.Translate_Name (Prefix, Mode_Signal); return Read_Driving_Attribute (New_Value (M2Lv (Name))); else -- Element per element handling for composite signals. Res := Create_Temp (Std_Boolean_Type_Node); Open_Temp; New_Assign_Stmt (New_Obj (Res), New_Lit (Std_Boolean_False_Node)); Name := Chap6.Translate_Name (Prefix, Mode_Signal); Start_Loop_Stmt (Label); Driving_Foreach (Name, Prefix_Type, Label); New_Assign_Stmt (New_Obj (Res), New_Lit (Std_Boolean_True_Node)); New_Exit_Stmt (Label); Finish_Loop_Stmt (Label); Close_Temp; return New_Obj_Value (Res); end if; end Translate_Driving_Attribute; function Read_Driving_Value (Sig : O_Enode; Sig_Type : Iir) return O_Enode is Tinfo : Type_Info_Acc; Subprg : O_Dnode; Assoc : O_Assoc_List; begin Tinfo := Get_Info (Sig_Type); case Tinfo.Type_Mode is when Type_Mode_B1 => Subprg := Ghdl_Signal_Driving_Value_B1; when Type_Mode_E8 => Subprg := Ghdl_Signal_Driving_Value_E8; when Type_Mode_E32 => Subprg := Ghdl_Signal_Driving_Value_E32; when Type_Mode_I32 | Type_Mode_P32 => Subprg := Ghdl_Signal_Driving_Value_I32; when Type_Mode_P64 | Type_Mode_I64 => Subprg := Ghdl_Signal_Driving_Value_I64; when Type_Mode_F64 => Subprg := Ghdl_Signal_Driving_Value_F64; when others => raise Internal_Error; end case; Start_Association (Assoc, Subprg); New_Association (Assoc, New_Convert_Ov (Sig, Ghdl_Signal_Ptr)); return New_Convert_Ov (New_Function_Call (Assoc), Tinfo.Ortho_Type (Mode_Value)); end Read_Driving_Value; function Translate_Driving_Value is new Chap7.Translate_Signal_Value (Read_Value => Read_Driving_Value); function Translate_Driving_Value_Attribute (Attr : Iir) return O_Enode is Prefix : constant Iir := Get_Prefix (Attr); Name : Mnode; begin Name := Chap6.Translate_Name (Prefix, Mode_Signal); return Translate_Driving_Value (M2E (Name), Get_Type (Prefix)); end Translate_Driving_Value_Attribute; function Translate_Image_Attribute (Attr : Iir) return O_Enode is Prefix_Type : constant Iir := Get_Base_Type (Get_Type (Get_Prefix (Attr))); Pinfo : constant Type_Info_Acc := Get_Info (Prefix_Type); Res : O_Dnode; Subprg : O_Dnode; Assoc : O_Assoc_List; Conv : O_Tnode; begin Res := Create_Temp (Std_String_Node); Create_Temp_Stack2_Mark; case Pinfo.Type_Mode is when Type_Mode_B1 => Subprg := Ghdl_Image_B1; Conv := Ghdl_Bool_Type; when Type_Mode_E8 => Subprg := Ghdl_Image_E8; Conv := Ghdl_I32_Type; when Type_Mode_E32 => Subprg := Ghdl_Image_E32; Conv := Ghdl_I32_Type; when Type_Mode_I32 => Subprg := Ghdl_Image_I32; Conv := Ghdl_I32_Type; when Type_Mode_P32 => Subprg := Ghdl_Image_P32; Conv := Ghdl_I32_Type; when Type_Mode_P64 => Subprg := Ghdl_Image_P64; Conv := Ghdl_I64_Type; when Type_Mode_F64 => Subprg := Ghdl_Image_F64; Conv := Ghdl_Real_Type; when others => raise Internal_Error; end case; Start_Association (Assoc, Subprg); New_Association (Assoc, New_Address (New_Obj (Res), Std_String_Ptr_Node)); New_Association (Assoc, New_Convert_Ov (Chap7.Translate_Expression (Get_Parameter (Attr), Prefix_Type), Conv)); case Pinfo.Type_Mode is when Type_Mode_B1 | Type_Mode_E8 | Type_Mode_E32 | Type_Mode_P32 | Type_Mode_P64 => New_Association (Assoc, New_Lit (Rtis.New_Rti_Address (Pinfo.Type_Rti))); when Type_Mode_I32 | Type_Mode_F64 => null; when others => raise Internal_Error; end case; New_Procedure_Call (Assoc); return New_Address (New_Obj (Res), Std_String_Ptr_Node); end Translate_Image_Attribute; function Translate_Value_Attribute (Attr : Iir) return O_Enode is Prefix_Type : constant Iir := Get_Base_Type (Get_Type (Get_Prefix (Attr))); Pinfo : constant Type_Info_Acc := Get_Info (Prefix_Type); Subprg : O_Dnode; Assoc : O_Assoc_List; begin case Pinfo.Type_Mode is when Type_Mode_B1 => Subprg := Ghdl_Value_B1; when Type_Mode_E8 => Subprg := Ghdl_Value_E8; when Type_Mode_E32 => Subprg := Ghdl_Value_E32; when Type_Mode_I32 => Subprg := Ghdl_Value_I32; when Type_Mode_P32 => Subprg := Ghdl_Value_P32; when Type_Mode_P64 => Subprg := Ghdl_Value_P64; when Type_Mode_F64 => Subprg := Ghdl_Value_F64; when others => raise Internal_Error; end case; Start_Association (Assoc, Subprg); New_Association (Assoc, Chap7.Translate_Expression (Get_Parameter (Attr), String_Type_Definition)); case Pinfo.Type_Mode is when Type_Mode_B1 | Type_Mode_E8 | Type_Mode_E32 | Type_Mode_P32 | Type_Mode_P64 => New_Association (Assoc, New_Lit (Rtis.New_Rti_Address (Pinfo.Type_Rti))); when Type_Mode_I32 | Type_Mode_F64 => null; when others => raise Internal_Error; end case; return New_Convert_Ov (New_Function_Call (Assoc), Pinfo.Ortho_Type (Mode_Value)); end Translate_Value_Attribute; function Translate_Path_Instance_Name_Attribute (Attr : Iir) return O_Enode is Name : constant Path_Instance_Name_Type := Get_Path_Instance_Name_Suffix (Attr); Res : O_Dnode; Name_Cst : O_Dnode; Str_Cst : O_Cnode; Constr : O_Assoc_List; Is_Instance : constant Boolean := Get_Kind (Attr) = Iir_Kind_Instance_Name_Attribute; begin Create_Temp_Stack2_Mark; Res := Create_Temp (Std_String_Node); Str_Cst := Create_String_Len (Name.Suffix, Create_Uniq_Identifier); New_Const_Decl (Name_Cst, Create_Uniq_Identifier, O_Storage_Private, Ghdl_Str_Len_Type_Node); Start_Init_Value (Name_Cst); Finish_Init_Value (Name_Cst, Str_Cst); if Is_Instance then Start_Association (Constr, Ghdl_Get_Instance_Name); else Start_Association (Constr, Ghdl_Get_Path_Name); end if; New_Association (Constr, New_Address (New_Obj (Res), Std_String_Ptr_Node)); if Name.Path_Instance = Null_Iir then Rtis.Associate_Null_Rti_Context (Constr); else Rtis.Associate_Rti_Context (Constr, Name.Path_Instance); end if; New_Association (Constr, New_Address (New_Obj (Name_Cst), Ghdl_Str_Len_Ptr_Node)); New_Procedure_Call (Constr); return New_Address (New_Obj (Res), Std_String_Ptr_Node); end Translate_Path_Instance_Name_Attribute; end Trans.Chap14;