-- Naive values for interpreted simulation -- Copyright (C) 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 GHDL; see the file COPYING. If not, write to the Free -- Software Foundation, 59 Temple Place - Suite 330, Boston, MA -- 02111-1307, USA. with System; with Ada.Unchecked_Conversion; with GNAT.Debug_Utilities; with Name_Table; with Debugger; use Debugger; package body Iir_Values is -- Functions for iir_value_literal function Is_Equal (Left, Right: Iir_Value_Literal_Acc) return Boolean is begin if Left.Kind /= Right.Kind then raise Internal_Error; end if; case Left.Kind is when Iir_Value_B1 => return Left.B1 = Right.B1; when Iir_Value_E32 => return Left.E32 = Right.E32; when Iir_Value_I64 => return Left.I64 = Right.I64; when Iir_Value_F64 => return Left.F64 = Right.F64; when Iir_Value_Access => return Left.Val_Access = Right.Val_Access; when Iir_Value_File => raise Internal_Error; when Iir_Value_Array => if Left.Bounds.Nbr_Dims /= Right.Bounds.Nbr_Dims then raise Internal_Error; end if; for I in Left.Bounds.D'Range loop if Left.Bounds.D (I).Length /= Right.Bounds.D (I).Length then return False; end if; end loop; for I in Left.Val_Array.V'Range loop if not Is_Equal (Left.Val_Array.V (I), Right.Val_Array.V (I)) then return False; end if; end loop; return True; when Iir_Value_Record => if Left.Val_Record.Len /= Right.Val_Record.Len then raise Constraint_Error; end if; for I in Left.Val_Record.V'Range loop if not Is_Equal (Left.Val_Record.V (I), Right.Val_Record.V (I)) then return False; end if; end loop; return True; when Iir_Value_Range => if Left.Dir /= Right.Dir then return False; end if; if not Is_Equal (Left.Left, Right.Left) then return False; end if; if not Is_Equal (Left.Right, Right.Right) then return False; end if; return True; when Iir_Value_Signal | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; end Is_Equal; function Compare_Value (Left, Right : Iir_Value_Literal_Acc) return Order is begin if Left.Kind /= Right.Kind then raise Constraint_Error; end if; case Left.Kind is when Iir_Value_B1 => if Left.B1 < Right.B1 then return Less; elsif Left.B1 = Right.B1 then return Equal; else return Greater; end if; when Iir_Value_E32 => if Left.E32 < Right.E32 then return Less; elsif Left.E32 = Right.E32 then return Equal; else return Greater; end if; when Iir_Value_I64 => if Left.I64 < Right.I64 then return Less; elsif Left.I64 = Right.I64 then return Equal; else return Greater; end if; when Iir_Value_F64 => if Left.F64 < Right.F64 then return Less; elsif Left.F64 = Right.F64 then return Equal; elsif Left.F64 > Right.F64 then return Greater; else raise Constraint_Error; end if; when Iir_Value_Array => -- LRM93 §7.2.2 -- For discrete array types, the relation < (less than) is defined -- such as the left operand is less than the right operand if -- and only if: -- * the left operand is a null array and the right operand is -- a non-null array; otherwise -- * both operands are non-null arrays, and one of the following -- conditions is satisfied: -- - the leftmost element of the left operand is less than -- that of the right; or -- - the leftmost element of the left operand is equal to -- that of the right, and the tail of the left operand is -- less than that of the right (the tail consists of the -- remaining elements to the rights of the leftmost element -- and can be null) -- The relation <= (less than or equal) for discrete array types -- is defined to be the inclusive disjunction of the results of -- the < and = operators for the same two operands. -- The relation > (greater than) and >= (greater than of equal) -- are defined to be the complements of the <= and < operators -- respectively for the same two operands. if Left.Bounds.Nbr_Dims /= 1 or Right.Bounds.Nbr_Dims /= 1 then raise Internal_Error; end if; for I in 1 .. Iir_Index32'Min (Left.Bounds.D (1).Length, Right.Bounds.D (1).Length) loop case Compare_Value (Left.Val_Array.V (I), Right.Val_Array.V (I)) is when Less => return Less; when Greater => return Greater; when Equal => null; end case; end loop; if Left.Bounds.D (1).Length < Right.Bounds.D (1).Length then return Less; elsif Left.Bounds.D (1).Length = Right.Bounds.D (1).Length then return Equal; else return Greater; end if; when Iir_Value_Signal | Iir_Value_Access | Iir_Value_Range | Iir_Value_Record | Iir_Value_File | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; end Compare_Value; function Is_Null_Range (Arange : Iir_Value_Literal_Acc) return Boolean is Cmp : Order; begin Cmp := Compare_Value (Arange.Left, Arange.Right); case Arange.Dir is when Iir_To => return Cmp = Greater; when Iir_Downto => return Cmp = Less; end case; end Is_Null_Range; procedure Increment (Val : Iir_Value_Literal_Acc) is begin case Val.Kind is when Iir_Value_B1 => if Val.B1 = False then Val.B1 := True; else raise Constraint_Error; end if; when Iir_Value_E32 => Val.E32 := Val.E32 + 1; when Iir_Value_I64 => Val.I64 := Val.I64 + 1; when Iir_Value_F64 | Iir_Value_Array | Iir_Value_Record | Iir_Value_Range | Iir_Value_File | Iir_Value_Access | Iir_Value_Signal | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; end Increment; procedure Store (Dest : Iir_Value_Literal_Acc; Src : Iir_Value_Literal_Acc) is begin if Dest.Kind /= Src.Kind then raise Constraint_Error; end if; case Dest.Kind is when Iir_Value_Array => if Dest.Val_Array.Len /= Src.Val_Array.Len then raise Constraint_Error; end if; for I in Dest.Val_Array.V'Range loop Store (Dest.Val_Array.V (I), Src.Val_Array.V (I)); end loop; when Iir_Value_Record => if Dest.Val_Record.Len /= Src.Val_Record.Len then raise Constraint_Error; end if; for I in Dest.Val_Record.V'Range loop Store (Dest.Val_Record.V (I), Src.Val_Record.V (I)); end loop; when Iir_Value_B1 => Dest.B1 := Src.B1; when Iir_Value_E32 => Dest.E32 := Src.E32; when Iir_Value_I64 => Dest.I64 := Src.I64; when Iir_Value_F64 => Dest.F64 := Src.F64; when Iir_Value_Access => Dest.Val_Access := Src.Val_Access; when Iir_Value_File => Dest.File := Src.File; when Iir_Value_Protected => Dest.Prot := Src.Prot; when Iir_Value_Signal => pragma Assert (Dest.Sig = null); Dest.Sig := Src.Sig; when Iir_Value_Range | Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; end Store; procedure Check_Bounds (Dest : Iir_Value_Literal_Acc; Src : Iir_Value_Literal_Acc; Loc : Iir) is begin case Dest.Kind is when Iir_Value_Array => if Src.Kind /= Iir_Value_Array then raise Internal_Error; end if; if Dest.Val_Array.Len /= Src.Val_Array.Len then Error_Msg_Constraint (Loc); end if; if Dest.Val_Array.Len /= 0 then Check_Bounds (Dest.Val_Array.V (1), Src.Val_Array.V (1), Loc); end if; when Iir_Value_Record => if Src.Kind /= Iir_Value_Record then raise Internal_Error; end if; if Dest.Val_Record.Len /= Src.Val_Record.Len then raise Internal_Error; end if; for I in Dest.Val_Record.V'Range loop Check_Bounds (Dest.Val_Record.V (I), Src.Val_Record.V (I), Loc); end loop; when Iir_Value_Access | Iir_Value_File | Iir_Value_Range | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => if Src.Kind /= Dest.Kind then raise Internal_Error; end if; when Iir_Value_B1 | Iir_Value_E32 | Iir_Value_I64 | Iir_Value_F64 | Iir_Value_Signal => return; end case; end Check_Bounds; function To_Iir_Value_Literal_Acc is new Ada.Unchecked_Conversion (System.Address, Iir_Value_Literal_Acc); function To_Value_Array_Acc is new Ada.Unchecked_Conversion (System.Address, Value_Array_Acc); function To_Value_Bounds_Array_Acc is new Ada.Unchecked_Conversion (System.Address, Value_Bounds_Array_Acc); function Create_Signal_Value (Sig : Ghdl_Signal_Ptr) return Iir_Value_Literal_Acc is subtype Signal_Value is Iir_Value_Literal (Iir_Value_Signal); function Alloc is new Alloc_On_Pool_Addr (Signal_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Global_Pool'Access, (Kind => Iir_Value_Signal, Sig => Sig))); end Create_Signal_Value; function Create_Terminal_Value (Terminal : Terminal_Index_Type) return Iir_Value_Literal_Acc is subtype Terminal_Value is Iir_Value_Literal (Iir_Value_Terminal); function Alloc is new Alloc_On_Pool_Addr (Terminal_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Global_Pool'Access, (Kind => Iir_Value_Terminal, Terminal => Terminal))); end Create_Terminal_Value; function Create_Quantity_Value (Quantity : Quantity_Index_Type) return Iir_Value_Literal_Acc is subtype Quantity_Value is Iir_Value_Literal (Iir_Value_Quantity); function Alloc is new Alloc_On_Pool_Addr (Quantity_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Global_Pool'Access, (Kind => Iir_Value_Quantity, Quantity => Quantity))); end Create_Quantity_Value; function Create_Protected_Value (Prot : Protected_Index_Type) return Iir_Value_Literal_Acc is subtype Protected_Value is Iir_Value_Literal (Iir_Value_Protected); function Alloc is new Alloc_On_Pool_Addr (Protected_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Global_Pool'Access, (Kind => Iir_Value_Protected, Prot => Prot))); end Create_Protected_Value; function Create_B1_Value (Val : Ghdl_B1) return Iir_Value_Literal_Acc is subtype B1_Value is Iir_Value_Literal (Iir_Value_B1); function Alloc is new Alloc_On_Pool_Addr (B1_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_B1, B1 => Val))); end Create_B1_Value; function Create_E32_Value (Val : Ghdl_E32) return Iir_Value_Literal_Acc is subtype E32_Value is Iir_Value_Literal (Iir_Value_E32); function Alloc is new Alloc_On_Pool_Addr (E32_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_E32, E32 => Val))); end Create_E32_Value; function Create_I64_Value (Val : Ghdl_I64) return Iir_Value_Literal_Acc is subtype I64_Value is Iir_Value_Literal (Iir_Value_I64); function Alloc is new Alloc_On_Pool_Addr (I64_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_I64, I64 => Val))); end Create_I64_Value; function Create_F64_Value (Val : Ghdl_F64) return Iir_Value_Literal_Acc is subtype F64_Value is Iir_Value_Literal (Iir_Value_F64); function Alloc is new Alloc_On_Pool_Addr (F64_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_F64, F64 => Val))); end Create_F64_Value; function Create_Access_Value (Val : Iir_Value_Literal_Acc) return Iir_Value_Literal_Acc is subtype Access_Value is Iir_Value_Literal (Iir_Value_Access); function Alloc is new Alloc_On_Pool_Addr (Access_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_Access, Val_Access => Val))); end Create_Access_Value; function Create_Range_Value (Left, Right : Iir_Value_Literal_Acc; Dir : Iir_Direction; Length : Iir_Index32) return Iir_Value_Literal_Acc is subtype Range_Value is Iir_Value_Literal (Iir_Value_Range); function Alloc is new Alloc_On_Pool_Addr (Range_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_Range, Left => Left, Right => Right, Dir => Dir, Length => Length))); end Create_Range_Value; function Create_File_Value (Val : Grt.Files.Ghdl_File_Index) return Iir_Value_Literal_Acc is subtype File_Value is Iir_Value_Literal (Iir_Value_File); function Alloc is new Alloc_On_Pool_Addr (File_Value); begin return To_Iir_Value_Literal_Acc (Alloc (Current_Pool, (Kind => Iir_Value_File, File => Val))); end Create_File_Value; -- Create a range_value of life LIFE. function Create_Range_Value (Left, Right : Iir_Value_Literal_Acc; Dir : Iir_Direction) return Iir_Value_Literal_Acc is Low, High : Iir_Value_Literal_Acc; Len : Iir_Index32; begin case Dir is when Iir_To => Low := Left; High := Right; when Iir_Downto => Low := Right; High := Left; end case; case (Low.Kind) is when Iir_Value_B1 => if High.B1 >= Low.B1 then Len := Ghdl_B1'Pos (High.B1) - Ghdl_B1'Pos (Low.B1) + 1; else Len := 0; end if; when Iir_Value_E32 => if High.E32 >= Low.E32 then Len := Iir_Index32 (High.E32 - Low.E32 + 1); else Len := 0; end if; when Iir_Value_I64 => declare L : Ghdl_I64; begin if High.I64 = Ghdl_I64'Last and Low.I64 = Ghdl_I64'First then -- Prevent overflow Len := Iir_Index32'Last; else L := High.I64 - Low.I64; if L >= Ghdl_I64 (Iir_Index32'Last) then -- Prevent overflow Len := Iir_Index32'Last; else L := L + 1; if L < 0 then -- null range. Len := 0; else Len := Iir_Index32 (L); end if; end if; end if; end; when Iir_Value_F64 => Len := 0; when Iir_Value_Array | Iir_Value_Record | Iir_Value_Access | Iir_Value_File | Iir_Value_Range | Iir_Value_Signal | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; return Create_Range_Value (Left, Right, Dir, Len); end Create_Range_Value; -- Return an array of length LENGTH. function Create_Array_Value (Dim : Iir_Index32; Pool : Areapool_Acc := Current_Pool) return Iir_Value_Literal_Acc is subtype Array_Value is Iir_Value_Literal (Iir_Value_Array); function Alloc_Array is new Alloc_On_Pool_Addr (Array_Value); subtype Dim_Type is Value_Bounds_Array (Dim); function Alloc_Bounds is new Alloc_On_Pool_Addr (Dim_Type); Res : Iir_Value_Literal_Acc; begin Res := To_Iir_Value_Literal_Acc (Alloc_Array (Pool, (Kind => Iir_Value_Array, Bounds => null, Val_Array => null))); Res.Bounds := To_Value_Bounds_Array_Acc (Alloc_Bounds (Pool, Dim_Type'(Nbr_Dims => Dim, D => (others => null)))); return Res; end Create_Array_Value; procedure Create_Array_Data (Arr : Iir_Value_Literal_Acc; Len : Iir_Index32; Pool : Areapool_Acc := Current_Pool) is use System; subtype Data_Type is Value_Array (Len); Res : Address; begin -- Manually allocate the array to handle large arrays without -- creating a large temporary value. Allocate (Pool.all, Res, Data_Type'Size / Storage_Unit, Data_Type'Alignment); declare -- Discard the warnings for no pragma Import as we really want -- to use the default initialization. pragma Warnings (Off); Addr1 : constant Address := Res; Init : Data_Type; for Init'Address use Addr1; pragma Warnings (On); begin null; end; Arr.Val_Array := To_Value_Array_Acc (Res); end Create_Array_Data; function Create_Array_Value (Length: Iir_Index32; Dim : Iir_Index32; Pool : Areapool_Acc := Current_Pool) return Iir_Value_Literal_Acc is Res : Iir_Value_Literal_Acc; begin Res := Create_Array_Value (Dim, Pool); Create_Array_Data (Res, Length, Pool); return Res; end Create_Array_Value; function Create_Record_Value (Nbr : Iir_Index32; Pool : Areapool_Acc := Current_Pool) return Iir_Value_Literal_Acc is subtype Record_Value is Iir_Value_Literal (Iir_Value_Record); function Alloc_Record is new Alloc_On_Pool_Addr (Record_Value); subtype Data_Type is Value_Array (Nbr); function Alloc_Data is new Alloc_On_Pool_Addr (Data_Type); Res : Iir_Value_Literal_Acc; begin Res := To_Iir_Value_Literal_Acc (Alloc_Record (Pool, (Kind => Iir_Value_Record, Val_Record => null))); Res.Val_Record := To_Value_Array_Acc (Alloc_Data (Pool, Data_Type'(Len => Nbr, V => (others => null)))); return Res; end Create_Record_Value; -- Create a copy of SRC with a specified life. function Copy (Src: in Iir_Value_Literal_Acc) return Iir_Value_Literal_Acc is Res: Iir_Value_Literal_Acc; begin case Src.Kind is when Iir_Value_E32 => return Create_E32_Value (Src.E32); when Iir_Value_I64 => return Create_I64_Value (Src.I64); when Iir_Value_F64 => return Create_F64_Value (Src.F64); when Iir_Value_B1 => return Create_B1_Value (Src.B1); when Iir_Value_Access => return Create_Access_Value (Src.Val_Access); when Iir_Value_Array => Res := Copy_Array_Bound (Src); for I in Src.Val_Array.V'Range loop Res.Val_Array.V (I) := Copy (Src.Val_Array.V (I)); end loop; return Res; when Iir_Value_Range => return Create_Range_Value (Left => Copy (Src.Left), Right => Copy (Src.Right), Dir => Src.Dir, Length => Src.Length); when Iir_Value_Record => Res := Copy_Record (Src); for I in Src.Val_Record.V'Range loop Res.Val_Record.V (I) := Copy (Src.Val_Record.V (I)); end loop; return Res; when Iir_Value_File => return Create_File_Value (Src.File); when Iir_Value_Protected => return Create_Protected_Value (Src.Prot); when Iir_Value_Signal => pragma Assert (Src.Sig = null); return Create_Signal_Value (Src.Sig); when Iir_Value_Quantity | Iir_Value_Terminal => raise Internal_Error; end case; end Copy; function Copy_Array_Bound (Src : Iir_Value_Literal_Acc) return Iir_Value_Literal_Acc is Res : Iir_Value_Literal_Acc; begin Res := Create_Array_Value (Src.Val_Array.Len, Src.Bounds.Nbr_Dims); for I in Res.Bounds.D'Range loop Res.Bounds.D (I) := Copy (Src.Bounds.D (I)); end loop; return Res; end Copy_Array_Bound; function Copy_Record (Src : Iir_Value_Literal_Acc) return Iir_Value_Literal_Acc is begin return Create_Record_Value (Src.Val_Record.Len); end Copy_Record; function Unshare (Src : Iir_Value_Literal_Acc; Pool : Areapool_Acc) return Iir_Value_Literal_Acc is Prev_Pool : constant Areapool_Acc := Current_Pool; Res : Iir_Value_Literal_Acc; begin Current_Pool := Pool; Res := Copy (Src); Current_Pool := Prev_Pool; return Res; end Unshare; function Unshare_Bounds (Src : Iir_Value_Literal_Acc; Pool : Areapool_Acc) return Iir_Value_Literal_Acc is begin if Src.Kind /= Iir_Value_Array then return Src; end if; declare Prev_Pool : constant Areapool_Acc := Current_Pool; Res : Iir_Value_Literal_Acc; begin Current_Pool := Pool; Res := Create_Array_Value (Src.Val_Array.Len, Src.Bounds.Nbr_Dims); for I in Src.Bounds.D'Range loop Res.Bounds.D (I) := Copy (Src.Bounds.D (I)); end loop; Res.Val_Array.V := Src.Val_Array.V; Current_Pool := Prev_Pool; return Res; end; end Unshare_Bounds; Heap_Pool : aliased Areapool; function Unshare_Heap (Src : Iir_Value_Literal_Acc) return Iir_Value_Literal_Acc is begin -- FIXME: this is never free. return Unshare (Src, Heap_Pool'Access); end Unshare_Heap; procedure Free_Heap_Value (Acc : Iir_Value_Literal_Acc) is begin null; end Free_Heap_Value; function Get_Nbr_Of_Scalars (Val : Iir_Value_Literal_Acc) return Natural is begin case Val.Kind is when Iir_Value_Scalars | Iir_Value_Access | Iir_Value_Signal => return 1; when Iir_Value_Record => declare Total : Natural := 0; begin for I in Val.Val_Record.V'Range loop Total := Total + Get_Nbr_Of_Scalars (Val.Val_Record.V (I)); end loop; return Total; end; when Iir_Value_Array => if Val.Val_Array.Len = 0 then -- Nul array return 0; else -- At least one element. return Natural (Val.Val_Array.Len) * Get_Nbr_Of_Scalars (Val.Val_Array.V (1)); end if; when Iir_Value_File | Iir_Value_Range | Iir_Value_Protected | Iir_Value_Terminal | Iir_Value_Quantity => raise Internal_Error; end case; end Get_Nbr_Of_Scalars; function Get_Enum_Pos (Val : Iir_Value_Literal_Acc) return Natural is begin case Val.Kind is when Iir_Value_E32 => return Ghdl_E32'Pos (Val.E32); when Iir_Value_B1 => return Ghdl_B1'Pos (Val.B1); when others => raise Internal_Error; end case; end Get_Enum_Pos; procedure Disp_Value_Tab (Value: Iir_Value_Literal_Acc; Tab: Ada.Text_IO.Count) is use Ada.Text_IO; use GNAT.Debug_Utilities; begin Set_Col (Tab); if Value = null then Put_Line ("*NULL*"); return; end if; if Boolean'(True) then Put (Image (Value.all'Address) & ' '); end if; case Value.Kind is when Iir_Value_B1 => Put_Line ("b1:" & Ghdl_B1'Image (Value.B1)); when Iir_Value_E32 => Put_Line ("e32:" & Ghdl_E32'Image (Value.E32)); when Iir_Value_I64 => Put_Line ("i64:" & Ghdl_I64'Image (Value.I64)); when Iir_Value_F64 => Put_Line ("F64:" & Ghdl_F64'Image (Value.F64)); when Iir_Value_Access => -- FIXME. if Value.Val_Access = null then Put_Line ("access: null"); else Put ("access: "); Put_Line (Image (Value.Val_Access.all'Address)); end if; when Iir_Value_Array => if Value.Val_Array = null then Put_Line ("array, without elements"); return; else Put_Line ("array, length: " & Iir_Index32'Image (Value.Val_Array.Len)); declare Ntab: constant Count := Tab + Indentation; begin Set_Col (Ntab); if Value.Bounds /= null then Put_Line ("bounds 1 .." & Iir_Index32'Image (Value.Bounds.Nbr_Dims) & ':'); for I in Value.Bounds.D'Range loop Disp_Value_Tab (Value.Bounds.D (I), Ntab); end loop; else Put_Line ("bounds = null"); end if; Set_Col (Ntab); Put_Line ("values 1 .." & Iir_Index32'Image (Value.Val_Array.Len) & ':'); for I in Value.Val_Array.V'Range loop Disp_Value_Tab (Value.Val_Array.V (I), Ntab); end loop; end; end if; when Iir_Value_Range => Put_Line ("range:"); Set_Col (Tab); Put (" direction: "); Put (Iir_Direction'Image (Value.Dir)); Put (", length:"); Put_Line (Iir_Index32'Image (Value.Length)); if Value.Left /= null then Set_Col (Tab); Put (" left bound: "); Disp_Value_Tab (Value.Left, Col); end if; if Value.Right /= null then Set_Col (Tab); Put (" right bound: "); Disp_Value_Tab (Value.Right, Col); end if; when Iir_Value_Record => Put_Line ("record:"); for I in Value.Val_Record.V'Range loop Disp_Value_Tab (Value.Val_Record.V (I), Tab + Indentation); end loop; when Iir_Value_Signal => Put ("signal: "); if Value.Sig = null then Put_Line ("(not created)"); else Put_Line (Image (Value.Sig.all'Address)); end if; when Iir_Value_File => Put_Line ("file:" & Grt.Files.Ghdl_File_Index'Image (Value.File)); when Iir_Value_Protected => Put_Line ("protected"); when Iir_Value_Quantity => Put_Line ("quantity"); when Iir_Value_Terminal => Put_Line ("terminal"); end case; end Disp_Value_Tab; procedure Disp_Value (Value: Iir_Value_Literal_Acc) is begin Disp_Value_Tab (Value, 1); end Disp_Value; -- Return TRUE if VALUE has an indirect value. function Is_Indirect (Value : Iir_Value_Literal_Acc) return Boolean is begin case Value.Kind is when Iir_Value_Scalars | Iir_Value_Access | Iir_Value_File | Iir_Value_Protected | Iir_Value_Quantity | Iir_Value_Terminal => return False; when Iir_Value_Range => return Is_Indirect (Value.Left) or else Is_Indirect (Value.Right); when Iir_Value_Array => for I in Value.Val_Array.V'Range loop if Is_Indirect (Value.Val_Array.V (I)) then return True; end if; end loop; return False; when Iir_Value_Record => for I in Value.Val_Record.V'Range loop if Is_Indirect (Value.Val_Record.V (I)) then return True; end if; end loop; return False; when Iir_Value_Signal => return True; end case; end Is_Indirect; procedure Disp_Iir_Value_Array (Value: Iir_Value_Literal_Acc; A_Type: Iir; Dim: Iir_Index32; Off : in out Iir_Index32) is use Ada.Text_IO; type Last_Enum_Type is (None, Char, Identifier); Last_Enum: Last_Enum_Type; El_Type: Iir; Enum_List: Iir_List; El_Id : Name_Id; El_Pos : Natural; begin if Dim = Value.Bounds.Nbr_Dims then -- Last dimension El_Type := Get_Base_Type (Get_Element_Subtype (A_Type)); -- Pretty print vectors of enumerated types if Get_Kind (El_Type) = Iir_Kind_Enumeration_Type_Definition and then not Is_Indirect (Value) then Last_Enum := None; Enum_List := Get_Enumeration_Literal_List (El_Type); for I in 1 .. Value.Bounds.D (Dim).Length loop El_Pos := Get_Enum_Pos (Value.Val_Array.V (Off)); Off := Off + 1; El_Id := Get_Identifier (Get_Nth_Element (Enum_List, El_Pos)); if Name_Table.Is_Character (El_Id) then case Last_Enum is when None => Put (""""); when Identifier => Put (" & """); when Char => null; end case; Put (Name_Table.Get_Character (El_Id)); Last_Enum := Char; else case Last_Enum is when None => null; when Identifier => Put (" & "); when Char => Put (""" & "); end case; Put (Name_Table.Image (El_Id)); Last_Enum := Identifier; end if; end loop; case Last_Enum is when None => Put (""""""); -- Simply "" when Identifier => null; when Char => Put (""""); end case; else Put ("("); for I in 1 .. Value.Bounds.D (Dim).Length loop if I /= 1 then Put (", "); end if; Disp_Iir_Value (Value.Val_Array.V (Off), El_Type); Off := Off + 1; end loop; Put (")"); end if; else Put ("("); for I in 1 .. Value.Bounds.D (Dim).Length loop if I /= 1 then Put (", "); end if; Disp_Iir_Value_Array (Value, A_Type, Dim + 1, Off); end loop; Put (")"); end if; end Disp_Iir_Value_Array; procedure Disp_Iir_Value_Record (Value: Iir_Value_Literal_Acc; A_Type: Iir) is use Ada.Text_IO; El : Iir_Element_Declaration; List : Iir_List; begin List := Get_Elements_Declaration_List (Get_Base_Type (A_Type)); Put ("("); for I in Value.Val_Record.V'Range loop El := Get_Nth_Element (List, Natural (I - 1)); if I /= 1 then Put (", "); end if; Put (Name_Table.Image (Get_Identifier (El))); Put (" => "); Disp_Iir_Value (Value.Val_Record.V (I), Get_Type (El)); end loop; Put (")"); end Disp_Iir_Value_Record; procedure Disp_Iir_Value (Value: Iir_Value_Literal_Acc; A_Type: Iir) is use Ada.Text_IO; begin if Value = null then Put ("!NULL!"); return; end if; case Value.Kind is when Iir_Value_I64 => Put (Ghdl_I64'Image (Value.I64)); when Iir_Value_F64 => Put (Ghdl_F64'Image (Value.F64)); when Iir_Value_E32 | Iir_Value_B1 => declare Bt : constant Iir := Get_Base_Type (A_Type); Id : Name_Id; Pos : Integer; begin if Value.Kind = Iir_Value_E32 then Pos := Ghdl_E32'Pos (Value.E32); else Pos := Ghdl_B1'Pos (Value.B1); end if; Id := Get_Identifier (Get_Nth_Element (Get_Enumeration_Literal_List (Bt), Pos)); Put (Name_Table.Image (Id)); end; when Iir_Value_Access => if Value.Val_Access = null then Put ("null"); else -- FIXME. Put ("*acc*"); end if; when Iir_Value_Array => declare Off : Iir_Index32; begin Off := 1; Disp_Iir_Value_Array (Value, A_Type, 1, Off); pragma Assert (Off = Value.Val_Array.Len + 1); end; when Iir_Value_File => raise Internal_Error; when Iir_Value_Record => Disp_Iir_Value_Record (Value, A_Type); when Iir_Value_Range => -- FIXME. raise Internal_Error; when Iir_Value_Quantity => Put ("[quantity]"); when Iir_Value_Terminal => Put ("[terminal]"); when Iir_Value_Signal => Put ("[signal]"); when Iir_Value_Protected => Put ("[protected]"); end case; end Disp_Iir_Value; end Iir_Values;