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|
-- GHDL Run Time (GRT) - VCD generator.
-- 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.
--
-- As a special exception, if other files instantiate generics from this
-- unit, or you link this unit with other files to produce an executable,
-- this unit does not by itself cause the resulting executable to be
-- covered by the GNU General Public License. This exception does not
-- however invalidate any other reasons why the executable file might be
-- covered by the GNU Public License.
with Interfaces;
with Grt.Stdio; use Grt.Stdio;
with System.Storage_Elements; -- Work around GNAT bug.
pragma Unreferenced (System.Storage_Elements);
with Grt.Errors; use Grt.Errors;
with Grt.Signals; use Grt.Signals;
with Grt.Table;
with Grt.Astdio; use Grt.Astdio;
with Grt.C; use Grt.C;
with Grt.Hooks; use Grt.Hooks;
with Grt.Rtis; use Grt.Rtis;
with Grt.Rtis_Addr; use Grt.Rtis_Addr;
with Grt.Rtis_Types; use Grt.Rtis_Types;
with Grt.Vstrings;
pragma Elaborate_All (Grt.Table);
package body Grt.Vcd is
-- If TRUE, put $date in vcd file.
-- Can be set to FALSE to make vcd comparaison easier.
Flag_Vcd_Date : Boolean := True;
Stream : FILEs;
procedure My_Vcd_Put (Str : String)
is
R : size_t;
pragma Unreferenced (R);
begin
R := fwrite (Str'Address, Str'Length, 1, Stream);
end My_Vcd_Put;
procedure My_Vcd_Putc (C : Character)
is
R : int;
pragma Unreferenced (R);
begin
R := fputc (Character'Pos (C), Stream);
end My_Vcd_Putc;
procedure My_Vcd_Close is
begin
fclose (Stream);
Stream := NULL_Stream;
end My_Vcd_Close;
-- VCD filename.
-- Stream corresponding to the VCD filename.
--Vcd_Stream : FILEs;
-- Index type of the table of vcd variables to dump.
type Vcd_Index_Type is new Integer;
-- Return TRUE if OPT is an option for VCD.
function Vcd_Option (Opt : String) return Boolean
is
F : constant Natural := Opt'First;
Mode : constant String := "wt" & NUL;
Vcd_Filename : String_Access;
begin
if Opt'Length < 5 or else Opt (F .. F + 4) /= "--vcd" then
return False;
end if;
if Opt'Length = 12 and then Opt (F + 5 .. F + 11) = "-nodate" then
Flag_Vcd_Date := False;
return True;
end if;
if Opt'Length > 6 and then Opt (F + 5) = '=' then
if Vcd_Close /= null then
Error ("--vcd: file already set");
return True;
end if;
-- Add an extra NUL character.
Vcd_Filename := new String (1 .. Opt'Length - 6 + 1);
Vcd_Filename (1 .. Opt'Length - 6) := Opt (F + 6 .. Opt'Last);
Vcd_Filename (Vcd_Filename'Last) := NUL;
if Vcd_Filename.all = "-" & NUL then
Stream := stdout;
else
Stream := fopen (Vcd_Filename.all'Address, Mode'Address);
if Stream = NULL_Stream then
Error_C ("cannot open ");
Error_E (Vcd_Filename (Vcd_Filename'First
.. Vcd_Filename'Last - 1));
return True;
end if;
end if;
Vcd_Putc := My_Vcd_Putc'Access;
Vcd_Put := My_Vcd_Put'Access;
Vcd_Close := My_Vcd_Close'Access;
return True;
else
return False;
end if;
end Vcd_Option;
procedure Vcd_Help is
begin
Put_Line (" --vcd=FILENAME dump signal values into a VCD file");
Put_Line (" --vcd-nodate do not write date in VCD file");
end Vcd_Help;
procedure Vcd_Newline is
begin
Vcd_Putc (Nl);
end Vcd_Newline;
procedure Vcd_Putline (Str : String) is
begin
Vcd_Put (Str);
Vcd_Newline;
end Vcd_Putline;
-- procedure Vcd_Put (Str : Ghdl_Str_Len_Type)
-- is
-- begin
-- Put_Str_Len (Vcd_Stream, Str);
-- end Vcd_Put;
procedure Vcd_Put_I32 (V : Ghdl_I32)
is
Str : String (1 .. 11);
First : Natural;
begin
Vstrings.To_String (Str, First, V);
Vcd_Put (Str (First .. Str'Last));
end Vcd_Put_I32;
procedure Vcd_Put_Idcode (N : Vcd_Index_Type)
is
Str : String (1 .. 8);
V, R : Vcd_Index_Type;
L : Natural;
begin
L := 0;
V := N;
loop
R := V mod 93;
V := V / 93;
L := L + 1;
Str (L) := Character'Val (33 + R);
exit when V = 0;
end loop;
Vcd_Put (Str (1 .. L));
end Vcd_Put_Idcode;
procedure Vcd_Put_Name (Obj : VhpiHandleT)
is
Name : String (1 .. 128);
Name_Len : Integer;
begin
Vhpi_Get_Str (VhpiNameP, Obj, Name, Name_Len);
if Name_Len <= Name'Last then
Vcd_Put (Name (1 .. Name_Len));
else
-- Truncate.
Vcd_Put (Name);
end if;
end Vcd_Put_Name;
procedure Vcd_Put_End is
begin
Vcd_Putline ("$end");
end Vcd_Put_End;
-- Called before elaboration.
procedure Vcd_Init
is
begin
if Vcd_Close = null then
return;
end if;
if Flag_Vcd_Date then
Vcd_Putline ("$date");
Vcd_Put (" ");
declare
type time_t is new Interfaces.Integer_64;
Cur_Time : time_t;
function time (Addr : Address) return time_t;
pragma Import (C, time);
function ctime (Timep: Address) return Ghdl_C_String;
pragma Import (C, ctime);
Ct : Ghdl_C_String;
begin
Cur_Time := time (Null_Address);
Ct := ctime (Cur_Time'Address);
for I in Positive loop
exit when Ct (I) = NUL;
Vcd_Putc (Ct (I));
end loop;
-- Note: ctime already append a LF.
end;
Vcd_Put_End;
end if;
Vcd_Putline ("$version");
Vcd_Putline (" GHDL v0");
Vcd_Put_End;
Vcd_Putline ("$timescale");
Vcd_Putline (" 1 fs");
Vcd_Put_End;
end Vcd_Init;
package Vcd_Table is new Grt.Table
(Table_Component_Type => Verilog_Wire_Info,
Table_Index_Type => Vcd_Index_Type,
Table_Low_Bound => 0,
Table_Initial => 32);
procedure Avhpi_Error (Err : AvhpiErrorT)
is
pragma Unreferenced (Err);
begin
Put_Line ("Vcd.Avhpi_Error!");
null;
end Avhpi_Error;
function Rti_To_Vcd_Kind (Rti : Ghdl_Rti_Access) return Vcd_Var_Kind
is
Rti1 : Ghdl_Rti_Access;
begin
if Rti.Kind = Ghdl_Rtik_Subtype_Scalar then
Rti1 := To_Ghdl_Rtin_Subtype_Scalar_Acc (Rti).Basetype;
else
Rti1 := Rti;
end if;
if Rti1 = Std_Standard_Boolean_RTI_Ptr then
return Vcd_Bool;
end if;
if Rti1 = Std_Standard_Bit_RTI_Ptr then
return Vcd_Bit;
end if;
if Rti1 = Ieee_Std_Logic_1164_Std_Ulogic_RTI_Ptr then
return Vcd_Stdlogic;
end if;
if Rti1.Kind = Ghdl_Rtik_Type_I32 then
return Vcd_Integer32;
end if;
if Rti1.Kind = Ghdl_Rtik_Type_F64 then
return Vcd_Float64;
end if;
return Vcd_Bad;
end Rti_To_Vcd_Kind;
function Rti_To_Vcd_Kind (Rti : Ghdl_Rtin_Type_Array_Acc)
return Vcd_Var_Kind
is
It : Ghdl_Rti_Access;
begin
if Rti.Nbr_Dim /= 1 then
return Vcd_Bad;
end if;
It := Rti.Indexes (0);
if It.Kind /= Ghdl_Rtik_Subtype_Scalar then
return Vcd_Bad;
end if;
if To_Ghdl_Rtin_Subtype_Scalar_Acc (It).Basetype.Kind
/= Ghdl_Rtik_Type_I32
then
return Vcd_Bad;
end if;
case Rti_To_Vcd_Kind (Rti.Element) is
when Vcd_Bit =>
return Vcd_Bitvector;
when Vcd_Stdlogic =>
return Vcd_Stdlogic_Vector;
when others =>
return Vcd_Bad;
end case;
end Rti_To_Vcd_Kind;
procedure Get_Verilog_Wire (Sig : VhpiHandleT; Info : out Verilog_Wire_Info)
is
Sig_Type : VhpiHandleT;
Rti : Ghdl_Rti_Access;
Error : AvhpiErrorT;
Sig_Addr : Address;
begin
-- Extract type of the signal.
Vhpi_Handle (VhpiSubtype, Sig, Sig_Type, Error);
if Error /= AvhpiErrorOk then
Avhpi_Error (Error);
return;
end if;
Rti := Avhpi_Get_Rti (Sig_Type);
Sig_Addr := Avhpi_Get_Address (Sig);
Info.Kind := Vcd_Bad;
case Rti.Kind is
when Ghdl_Rtik_Type_B1
| Ghdl_Rtik_Type_E8
| Ghdl_Rtik_Subtype_Scalar =>
Info.Kind := Rti_To_Vcd_Kind (Rti);
Info.Addr := Sig_Addr;
Info.Irange := null;
when Ghdl_Rtik_Subtype_Array =>
declare
St : Ghdl_Rtin_Subtype_Array_Acc;
begin
St := To_Ghdl_Rtin_Subtype_Array_Acc (Rti);
Info.Kind := Rti_To_Vcd_Kind (St.Basetype);
Info.Addr := Sig_Addr;
Info.Irange := To_Ghdl_Range_Ptr
(Loc_To_Addr (St.Common.Depth, St.Bounds,
Avhpi_Get_Context (Sig)));
end;
when Ghdl_Rtik_Type_Array =>
declare
Uc : Ghdl_Uc_Array_Acc;
begin
Info.Kind := Rti_To_Vcd_Kind
(To_Ghdl_Rtin_Type_Array_Acc (Rti));
Uc := To_Ghdl_Uc_Array_Acc (Sig_Addr);
Info.Addr := Uc.Base;
Info.Irange := To_Ghdl_Range_Ptr (Uc.Bounds);
end;
when others =>
Info.Irange := null;
end case;
-- Do not allow null-array.
if Info.Irange /= null and then Info.Irange.I32.Len = 0 then
Info.Kind := Vcd_Bad;
Info.Irange := null;
return;
end if;
if Vhpi_Get_Kind (Sig) = VhpiPortDeclK then
case Vhpi_Get_Mode (Sig) is
when VhpiInMode
| VhpiInoutMode
| VhpiBufferMode
| VhpiLinkageMode =>
Info.Val := Vcd_Effective;
when VhpiOutMode =>
Info.Val := Vcd_Driving;
when VhpiErrorMode =>
Info.Kind := Vcd_Bad;
end case;
else
Info.Val := Vcd_Effective;
end if;
end Get_Verilog_Wire;
procedure Add_Signal (Sig : VhpiHandleT)
is
N : Vcd_Index_Type;
Vcd_El : Verilog_Wire_Info;
begin
Get_Verilog_Wire (Sig, Vcd_El);
if Vcd_El.Kind = Vcd_Bad then
Vcd_Put ("$comment ");
Vcd_Put_Name (Sig);
Vcd_Put (" is not handled");
--Vcd_Put (Ghdl_Type_Kind'Image (Desc.Kind));
Vcd_Putc (' ');
Vcd_Put_End;
return;
else
Vcd_Table.Increment_Last;
N := Vcd_Table.Last;
Vcd_Table.Table (N) := Vcd_El;
Vcd_Put ("$var ");
case Vcd_El.Kind is
when Vcd_Integer32 =>
Vcd_Put ("integer 32");
when Vcd_Float64 =>
Vcd_Put ("real 64");
when Vcd_Bool
| Vcd_Bit
| Vcd_Stdlogic =>
Vcd_Put ("reg 1");
when Vcd_Bitvector
| Vcd_Stdlogic_Vector =>
Vcd_Put ("reg ");
Vcd_Put_I32 (Ghdl_I32 (Vcd_El.Irange.I32.Len));
when Vcd_Bad =>
null;
end case;
Vcd_Putc (' ');
Vcd_Put_Idcode (N);
Vcd_Putc (' ');
Vcd_Put_Name (Sig);
if Vcd_El.Irange /= null then
Vcd_Putc ('[');
Vcd_Put_I32 (Vcd_El.Irange.I32.Left);
Vcd_Putc (':');
Vcd_Put_I32 (Vcd_El.Irange.I32.Right);
Vcd_Putc (']');
end if;
Vcd_Putc (' ');
Vcd_Put_End;
if Boolean'(False) then
Vcd_Put ("$comment ");
Vcd_Put_Name (Sig);
Vcd_Put (" is ");
case Vcd_El.Val is
when Vcd_Effective =>
Vcd_Put ("effective ");
when Vcd_Driving =>
Vcd_Put ("driving ");
end case;
Vcd_Put_End;
end if;
end if;
end Add_Signal;
procedure Vcd_Put_Hierarchy (Inst : VhpiHandleT)
is
Decl_It : VhpiHandleT;
Decl : VhpiHandleT;
Error : AvhpiErrorT;
begin
Vhpi_Iterator (VhpiDecls, Inst, Decl_It, Error);
if Error /= AvhpiErrorOk then
Avhpi_Error (Error);
return;
end if;
-- Extract signals.
loop
Vhpi_Scan (Decl_It, Decl, Error);
exit when Error = AvhpiErrorIteratorEnd;
if Error /= AvhpiErrorOk then
Avhpi_Error (Error);
return;
end if;
case Vhpi_Get_Kind (Decl) is
when VhpiPortDeclK
| VhpiSigDeclK =>
Add_Signal (Decl);
when others =>
null;
end case;
end loop;
-- Extract sub-scopes.
Vhpi_Iterator (VhpiInternalRegions, Inst, Decl_It, Error);
if Error /= AvhpiErrorOk then
Avhpi_Error (Error);
return;
end if;
loop
Vhpi_Scan (Decl_It, Decl, Error);
exit when Error = AvhpiErrorIteratorEnd;
if Error /= AvhpiErrorOk then
Avhpi_Error (Error);
return;
end if;
case Vhpi_Get_Kind (Decl) is
when VhpiIfGenerateK
| VhpiForGenerateK
| VhpiBlockStmtK
| VhpiCompInstStmtK =>
Vcd_Put ("$scope module ");
Vcd_Put_Name (Decl);
Vcd_Putc (' ');
Vcd_Put_End;
Vcd_Put_Hierarchy (Decl);
Vcd_Put ("$upscope ");
Vcd_Put_End;
when others =>
null;
end case;
end loop;
end Vcd_Put_Hierarchy;
procedure Vcd_Put_Bit (V : Ghdl_B1)
is
C : Character;
begin
if V then
C := '1';
else
C := '0';
end if;
Vcd_Putc (C);
end Vcd_Put_Bit;
procedure Vcd_Put_Stdlogic (V : Ghdl_E8)
is
type Map_Type is array (Ghdl_E8 range 0 .. 8) of Character;
-- "UX01ZWLH-"
-- Map_Vlg : constant Map_Type := "xx01zz01x";
Map_Std : constant Map_Type := "UX01ZWLH-";
begin
if V not in Map_Type'Range then
Vcd_Putc ('?');
else
Vcd_Putc (Map_Std (V));
end if;
end Vcd_Put_Stdlogic;
procedure Vcd_Put_Integer32 (V : Ghdl_U32)
is
Val : Ghdl_U32;
N : Natural;
begin
Val := V;
N := 32;
while N > 1 loop
exit when (Val and 16#8000_0000#) /= 0;
Val := Val * 2;
N := N - 1;
end loop;
while N > 0 loop
if (Val and 16#8000_0000#) /= 0 then
Vcd_Putc ('1');
else
Vcd_Putc ('0');
end if;
Val := Val * 2;
N := N - 1;
end loop;
end Vcd_Put_Integer32;
-- Using the floor attribute of Ghdl_F64 will result on a link error while
-- trying to simulate a design. So it was needed to create a floor function
function Digit_Floor (V : Ghdl_F64) return Ghdl_I32
is
Var : Ghdl_I32;
begin
-- V is always positive here and only of interest when it is a digit
if V > 10.0 then
return -1;
else
Var := Ghdl_I32(V-0.5); --Ghdl_I32 rounds to the nearest integer
-- The rounding made by Ghdl_I32 is asymetric :
-- 0.5 will be rounded to 1, but -0.5 to -1 instead of 0
if Var > 0 then
return Var;
else
return 0;
end if;
end if;
end Digit_Floor;
procedure Vcd_Put_Float64 (V : Ghdl_F64)
is
Val_tmp, Fact : Ghdl_F64;
Digit, Exp, Delta_Exp, N_Exp : Ghdl_I32;
--
begin
Exp := 0;
if V /= V then
Vcd_Put("NaN");
return;
end if;
if V < 0.0 then
Vcd_Putc ('-');
Val_tmp := -V;
elsif V = 0.0 then
Vcd_Put("0.0");
return;
else
Val_tmp := V;
end if;
if Val_tmp > Ghdl_F64'Last then
Vcd_Put("Inf");
return;
elsif Val_tmp < 1.0 then
Fact := 10.0;
Delta_Exp := -1;
else
Fact := 0.1;
Delta_Exp := 1;
end if;
-- Seek the first digit
loop
Digit := Digit_Floor(Val_tmp);
if Digit > 0 then
exit;
end if;
Exp := Exp + Delta_Exp;
Val_tmp := Val_tmp * Fact;
end loop;
Vcd_Putc(Character'Val(Digit + 48));
Vcd_Putc('.');
for i in 0..4 loop -- 5 digits displayed after the point
Val_tmp := abs(Val_tmp - Ghdl_F64(Digit))*10.0;
Digit := Digit_Floor(Val_tmp);
Vcd_Putc(Character'Val(Digit + 48));
end loop;
Vcd_Putc('E');
if Exp < 0 then
Vcd_Putc('-');
Exp := -Exp;
end if;
N_Exp := 100;
while N_Exp > 0 loop
Vcd_Putc(Character'Val(Exp/N_Exp + 48));
Exp := Exp mod N_Exp;
N_Exp := N_Exp/10;
end loop;
end Vcd_Put_Float64;
procedure Vcd_Put_Var (I : Vcd_Index_Type)
is
Addr : Address;
V : Verilog_Wire_Info renames Vcd_Table.Table (I);
Len : Ghdl_Index_Type;
begin
Addr := V.Addr;
if V.Irange = null then
Len := 1;
else
Len := V.Irange.I32.Len;
end if;
case V.Val is
when Vcd_Effective =>
case V.Kind is
when Vcd_Bit
| Vcd_Bool =>
Vcd_Put_Bit (To_Signal_Arr_Ptr (Addr)(0).Value.B1);
when Vcd_Stdlogic =>
Vcd_Put_Stdlogic (To_Signal_Arr_Ptr (Addr)(0).Value.E8);
when Vcd_Integer32 =>
Vcd_Putc ('b');
Vcd_Put_Integer32 (To_Signal_Arr_Ptr (Addr)(0).Value.E32);
Vcd_Putc (' ');
when Vcd_Float64 =>
Vcd_Putc ('r');
Vcd_Put_Float64 (To_Signal_Arr_Ptr (Addr)(0).Value.F64);
Vcd_Putc (' ');
when Vcd_Bitvector =>
Vcd_Putc ('b');
for J in 0 .. Len - 1 loop
Vcd_Put_Bit (To_Signal_Arr_Ptr (Addr)(J).Value.B1);
end loop;
Vcd_Putc (' ');
when Vcd_Stdlogic_Vector =>
Vcd_Putc ('b');
for J in 0 .. Len - 1 loop
Vcd_Put_Stdlogic (To_Signal_Arr_Ptr (Addr)(J).Value.E8);
end loop;
Vcd_Putc (' ');
when Vcd_Bad =>
null;
end case;
when Vcd_Driving =>
case V.Kind is
when Vcd_Bit
| Vcd_Bool =>
Vcd_Put_Bit
(To_Signal_Arr_Ptr (Addr)(0).Driving_Value.B1);
when Vcd_Stdlogic =>
Vcd_Put_Stdlogic
(To_Signal_Arr_Ptr (Addr)(0).Driving_Value.E8);
when Vcd_Integer32 =>
Vcd_Putc ('b');
Vcd_Put_Integer32
(To_Signal_Arr_Ptr (Addr)(0).Driving_Value.E32);
Vcd_Putc (' ');
when Vcd_Float64 =>
Vcd_Putc ('r');
Vcd_Put_Float64 (To_Signal_Arr_Ptr (Addr)(0)
.Driving_Value.F64);
Vcd_Putc (' ');
when Vcd_Bitvector =>
Vcd_Putc ('b');
for J in 0 .. Len - 1 loop
Vcd_Put_Bit
(To_Signal_Arr_Ptr (Addr)(J).Driving_Value.B1);
end loop;
Vcd_Putc (' ');
when Vcd_Stdlogic_Vector =>
Vcd_Putc ('b');
for J in 0 .. Len - 1 loop
Vcd_Put_Stdlogic
(To_Signal_Arr_Ptr (Addr)(J).Driving_Value.E8);
end loop;
Vcd_Putc (' ');
when Vcd_Bad =>
null;
end case;
end case;
Vcd_Put_Idcode (I);
Vcd_Newline;
end Vcd_Put_Var;
function Verilog_Wire_Changed (Info : Verilog_Wire_Info;
Last : Std_Time)
return Boolean
is
Len : Ghdl_Index_Type;
begin
if Info.Irange = null then
Len := 1;
else
Len := Info.Irange.I32.Len;
end if;
case Info.Val is
when Vcd_Effective =>
case Info.Kind is
when Vcd_Bit
| Vcd_Bool
| Vcd_Stdlogic
| Vcd_Bitvector
| Vcd_Stdlogic_Vector
| Vcd_Integer32
| Vcd_Float64 =>
for J in 0 .. Len - 1 loop
if To_Signal_Arr_Ptr (Info.Addr)(J).Last_Event = Last then
return True;
end if;
end loop;
when Vcd_Bad =>
null;
end case;
when Vcd_Driving =>
case Info.Kind is
when Vcd_Bit
| Vcd_Bool
| Vcd_Stdlogic
| Vcd_Bitvector
| Vcd_Stdlogic_Vector
| Vcd_Integer32
| Vcd_Float64 =>
for J in 0 .. Len - 1 loop
if To_Signal_Arr_Ptr (Info.Addr)(J).Last_Active = Last
then
return True;
end if;
end loop;
when Vcd_Bad =>
null;
end case;
end case;
return False;
end Verilog_Wire_Changed;
procedure Vcd_Put_Time
is
Str : String (1 .. 21);
First : Natural;
begin
Vcd_Putc ('#');
Vstrings.To_String (Str, First, Ghdl_I64 (Cycle_Time));
Vcd_Put (Str (First .. Str'Last));
Vcd_Newline;
end Vcd_Put_Time;
procedure Vcd_Cycle;
-- Called after elaboration.
procedure Vcd_Start
is
Root : VhpiHandleT;
begin
-- Do nothing if there is no VCD file to generate.
if Vcd_Close = null then
return;
end if;
-- Be sure the RTI of std_ulogic is set.
Search_Types_RTI;
-- Put hierarchy.
Get_Root_Inst (Root);
Vcd_Put_Hierarchy (Root);
-- End of header.
Vcd_Put ("$enddefinitions ");
Vcd_Put_End;
Register_Cycle_Hook (Vcd_Cycle'Access);
end Vcd_Start;
-- Called before each non delta cycle.
procedure Vcd_Cycle is
begin
-- Disp values.
Vcd_Put_Time;
if Cycle_Time = 0 then
-- Disp all values.
for I in Vcd_Table.First .. Vcd_Table.Last loop
Vcd_Put_Var (I);
end loop;
else
-- Disp only values changed.
for I in Vcd_Table.First .. Vcd_Table.Last loop
if Verilog_Wire_Changed (Vcd_Table.Table (I), Cycle_Time) then
Vcd_Put_Var (I);
end if;
end loop;
end if;
end Vcd_Cycle;
-- Called at the end of the simulation.
procedure Vcd_End is
begin
if Vcd_Close /= null then
Vcd_Close.all;
end if;
end Vcd_End;
Vcd_Hooks : aliased constant Hooks_Type :=
(Option => Vcd_Option'Access,
Help => Vcd_Help'Access,
Init => Vcd_Init'Access,
Start => Vcd_Start'Access,
Finish => Vcd_End'Access);
procedure Register is
begin
Register_Hooks (Vcd_Hooks'Access);
end Register;
end Grt.Vcd;
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