-- GHDL Run Time (GRT) - VPI interface. -- Copyright (C) 2002 - 2014 Tristan Gingold & Felix Bertram -- -- This program is free software: you can redistribute it and/or modify -- it under the terms of the GNU General Public License as published by -- the Free Software Foundation, either version 2 of the License, or -- (at your option) any later version. -- -- This program is distributed in the hope that it will be useful, -- but WITHOUT ANY WARRANTY; without even the implied warranty of -- MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the -- GNU General Public License for more details. -- -- You should have received a copy of the GNU General Public License -- along with this program. If not, see . -- Description: VPI interface for GRT runtime -- the main purpose of this code is to interface with the -- Icarus Verilog Interactive (IVI) simulator GUI ------------------------------------------------------------------------------- -- TODO: ------------------------------------------------------------------------------- -- DONE: -- * The GHDL VPI implementation doesn't support time -- callbacks (cbReadOnlySynch). This is needed to support -- IVI run. Currently, the GHDL simulation runs until -- complete once a single 'run' is performed... -- * You are loading '_'-prefixed symbols when you -- load the vpi plugin. On Linux, there is no leading -- '_'. I just added code to try both '_'-prefixed and -- non-'_'-prefixed symbols. I have placed the changed -- file in the same download dir as the snapshot -- * I did find out why restart doesn't work for GHDL. -- You are passing back the leaf name of signals when the -- FullName is requested. ------------------------------------------------------------------------------- with Ada.Unchecked_Deallocation; with System.Storage_Elements; -- Work around GNAT bug. pragma Unreferenced (System.Storage_Elements); with Grt.Stdio; use Grt.Stdio; with Grt.C; use Grt.C; with Grt.Signals; use Grt.Signals; with Grt.Astdio; use Grt.Astdio; with Grt.Astdio.Vhdl; use Grt.Astdio.Vhdl; with Grt.Strings; use Grt.Strings; with Grt.Hooks; use Grt.Hooks; with Grt.Options; with Grt.Vcd; use Grt.Vcd; with Grt.Errors; use Grt.Errors; with Grt.Rtis_Types; with Grt.Std_Logic_1164; use Grt.Std_Logic_1164; with Grt.Callbacks; use Grt.Callbacks; with Grt.Vstrings; use Grt.Vstrings; with Version; package body Grt.Vpi is -- The VPI interface requires libdl (dlopen, dlsym) to be linked in. -- This is now set in Makefile, since this is target dependent. -- pragma Linker_Options ("-ldl"); --errAnyString: constant String := "grt-vcd.adb: any string" & NUL; --errNoString: constant String := "grt-vcd.adb: no string" & NUL; Product : constant String := "GHDL" & NUL; GhdlVersion : constant String := Version.Ghdl_Ver & " " & Version.Ghdl_Release & NUL; -- If true, emit traces Flag_Trace : Boolean := False; Trace_File : FILEs; Trace_Indent : Natural := 0; ------------------------------------------------------------------------------- -- * * * h e l p e r s * * * * * * * * * * * * * * * * * * * * * * * * * * ------------------------------------------------------------------------------- ------------------------------------------------------------------------ -- debugging helpers procedure dbgPut (Str : String) is S : size_t; pragma Unreferenced (S); begin S := fwrite (Str'Address, Str'Length, 1, stderr); end dbgPut; procedure dbgPut (C : Character) is R : int; pragma Unreferenced (R); begin R := fputc (Character'Pos (C), stderr); end dbgPut; procedure dbgNew_Line is begin dbgPut (Nl); end dbgNew_Line; procedure dbgPut_Line (Str : String) is begin dbgPut (Str); dbgNew_Line; end dbgPut_Line; -- procedure dbgPut_Line (Str : Ghdl_Str_Len_Type) -- is -- begin -- Put_Str_Len(stderr, Str); -- dbgNew_Line; -- end dbgPut_Line; procedure Free is new Ada.Unchecked_Deallocation (Name => vpiHandle, Object => struct_vpiHandle); ------------------------------------------------------------------------ -- NUL-terminate strings. -- note: there are several buffers -- see IEEE 1364-2001 -- tmpstring1: string(1..1024); -- function NulTerminate1 (Str : Ghdl_Str_Len_Type) return Ghdl_C_String -- is -- begin -- for i in 1..Str.Len loop -- tmpstring1(i):= Str.Str(i); -- end loop; -- tmpstring1(Str.Len+1):= NUL; -- return To_Ghdl_C_String (tmpstring1'Address); -- end NulTerminate1; -- Clear error status. procedure Reset_Error; procedure Trace_Start (Msg : String) is begin for I in 1 .. Trace_Indent loop Put (Trace_File, ' '); end loop; Put (Trace_File, Msg); end Trace_Start; procedure Trace (Msg : String) is begin Put (Trace_File, Msg); end Trace; procedure Trace (V : Integer) is begin Put_I32 (Trace_File, Ghdl_I32 (V)); end Trace; procedure Trace_Cb_Reason (V : Integer) is begin case V is when cbValueChange => Trace ("cbValueChange"); when cbReadWriteSynch => Trace ("cbReadWriteSynch"); when cbReadOnlySynch => Trace ("cbReadOnlySynch"); when cbNextSimTime => Trace ("cbNextSimTime"); when cbAfterDelay => Trace ("cbAfterDelay"); when cbEndOfCompile => Trace ("cbEndOfCompile"); when cbStartOfSimulation => Trace ("cbStartOfSimulation"); when cbEndOfSimulation => Trace ("cbEndOfSimulation"); when others => Trace (V); end case; end Trace_Cb_Reason; procedure Trace_Property (V : Integer) is begin case V is when vpiUndefined => Trace ("vpiUndefined"); when vpiType => Trace ("vpiType"); when vpiName => Trace ("vpiName"); when vpiFullName => Trace ("vpiFullName"); when vpiSize => Trace ("vpiSize"); when vpiFile => Trace ("vpiFile"); when vpiLineNo => Trace ("vpiLineNo"); when vpiDefName => Trace ("vpiDefName"); when vpiTimePrecision => Trace ("vpiTimePrecision"); when vpiDefFile => Trace ("vpiDefFile"); -- Port and net properties when vpiScalar => Trace ("vpiScalar"); when vpiVector => Trace ("vpiVector"); when vpiModule => Trace ("vpiModule"); when vpiNet => Trace ("vpiNet"); when vpiPort => Trace ("vpiPort"); when vpiParameter => Trace ("vpiParameter"); when vpiScope => Trace ("vpiScope"); when vpiInternalScope => Trace ("vpiInternalScope"); when vpiLeftRange => Trace ("vpiLeftRange"); when vpiRightRange => Trace ("vpiRightRange"); when vpiStop => Trace ("vpiStop"); when vpiFinish => Trace ("vpiFinish"); when vpiReset => Trace ("vpiReset"); when others => Trace (V); end case; end Trace_Property; procedure Trace_Format (F : Integer) is begin case F is when vpiBinStrVal => Trace ("BinStr"); when vpiOctStrVal => Trace ("OctStr"); when vpiDecStrVal => Trace ("DecStr"); when vpiHexStrVal => Trace ("HexStr"); when vpiScalarVal => Trace ("Scalar"); when vpiIntVal => Trace ("Int"); when vpiRealVal => Trace ("Real"); when vpiStringVal => Trace ("String"); when vpiVectorVal => Trace ("Vector"); when vpiStrengthVal => Trace ("Strength"); when vpiTimeVal => Trace ("Time"); when vpiObjTypeVal => Trace ("ObjType"); when vpiSuppressVal => Trace ("Suppress"); when others => Trace (F); end case; end Trace_Format; procedure Trace_Time_Tag (V : Integer) is begin case V is when vpiSimTime => Trace ("vpiSimTime"); when others => Trace (V); end case; end Trace_Time_Tag; procedure Trace (H : vpiHandle) is function To_Address is new Ada.Unchecked_Conversion (vpiHandle, System.Address); begin Put (Trace_File, To_Address (H)); end Trace; procedure Trace (Str : Ghdl_C_String) is begin if Str = null then Put (Trace_File, "null"); else Put (Trace_File, '"'); Put (Trace_File, Str); Put (Trace_File, '"'); end if; end Trace; procedure Trace_Time (V : Std_Time) is begin Put_Time (Trace_File, V); end Trace_Time; procedure Trace_Value (V : p_vpi_value) is begin case V.Format is when vpiBinStrVal | vpiOctStrVal | vpiDecStrVal | vpiHexStrVal | vpiStringVal => Trace (V.Str); when vpiScalarVal => Trace (V.Scalar); when vpiIntVal => Trace (V.Integer_m); --when vpiRealVal=> null; -- what is the equivalent to double? --when vpiTimeVal=> mTime: p_vpi_time; --when vpiVectorVal=> mVector: p_vpi_vecval; --when vpiStrengthVal=> mStrength: p_vpi_strengthval; when others => null; end case; end Trace_Value; procedure Trace_Newline is begin New_Line (Trace_File); end Trace_Newline; function Vpi_Time_To_Time (V : s_vpi_time) return Std_Time is Res : Std_Time; begin if V.mType /= vpiSimTime then raise Program_Error; end if; Res := Std_Time (Unsigned_64 (V.mHigh) * 2 ** 32 + Unsigned_64 (V.mLow)); return Res; end Vpi_Time_To_Time; ------------------------------------------------------------------------------- -- * * * V P I f u n c t i o n s * * * * * * * * * * * * * * * * * * * * ------------------------------------------------------------------------------- -- Free an handler, when it was not passed by reference. procedure Free_Copy (H : vpiHandle) is Copy : vpiHandle; begin Copy := H; Free (Copy); end Free_Copy; ------------------------------------------------------------------------ -- vpiHandle vpi_iterate(int type, vpiHandle ref) -- Obtain an iterator handle to objects with a one-to-many relationship. -- see IEEE 1364-2001, page 685 function Vpi_Iterate_Internal (aType: integer; Ref: vpiHandle) return vpiHandle is Res : vpiHandle; Rel : VhpiOneToManyT; Error : AvhpiErrorT; begin case aType is when vpiPort | vpiNet => Rel := VhpiDecls; when vpiModule => if Ref = null then Res := new struct_vpiHandle (vpiModule); Get_Root_Inst (Res.Ref); return Res; else Rel := VhpiInternalRegions; end if; when vpiInternalScope => Rel := VhpiInternalRegions; when others => return null; end case; -- find the proper start object for our scan if Ref = null then Res := null; else Res := new struct_vpiHandle (aType); Vhpi_Iterator (Rel, Ref.Ref, Res.Ref, Error); if Error /= AvhpiErrorOk then Free (Res); end if; end if; return Res; end Vpi_Iterate_Internal; function vpi_iterate (aType: integer; Ref: vpiHandle) return vpiHandle is Res : vpiHandle; begin if Flag_Trace then Trace_Start ("vpi_iterate ("); Trace_Property (aType); Trace (", "); Trace (Ref); Trace (") = "); end if; Res := Vpi_Iterate_Internal (aType, Ref); if Flag_Trace then Trace (Res); Trace_Newline; end if; return Res; end vpi_iterate; ------------------------------------------------------------------------ -- int vpi_get(int property, vpiHandle ref) -- Get the value of an integer or boolean property of an object. -- see IEEE 1364-2001, chapter 27.6, page 667 -- function ii_vpi_get_type (aRef: Ghdl_Instance_Name_Acc) return Integer -- is -- begin -- case aRef.Kind is -- when Ghdl_Name_Entity -- | Ghdl_Name_Architecture -- | Ghdl_Name_Block -- | Ghdl_Name_Generate_Iterative -- | Ghdl_Name_Generate_Conditional -- | Ghdl_Name_Instance => -- return vpiModule; -- when Ghdl_Name_Signal => -- return vpiNet; -- when others => -- return vpiUndefined; -- end case; -- end ii_vpi_get_type; function Vpi_Get_Size (Ref : vpiHandle) return Integer is Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Ref.Ref, Info); case Info.Vtype is when Vcd_Var_Vectors => return Natural (Get_Wire_Length (Info)); when Vcd_Bool | Vcd_Bit | Vcd_Stdlogic => return 1; when Vcd_Integer32 => return 32; when Vcd_Enum8 => return 8; when Vcd_Float64 => return 0; when Vcd_Bad => return 0; end case; end Vpi_Get_Size; function Vpi_Get_Vector (Ref : vpiHandle) return Boolean is Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Ref.Ref, Info); case Info.Vtype is when Vcd_Bool | Vcd_Integer32 | Vcd_Float64 | Vcd_Bit | Vcd_Stdlogic | Vcd_Enum8 => return False; when Vcd_Bitvector | Vcd_Stdlogic_Vector => return True; when Vcd_Bad => return False; end case; end Vpi_Get_Vector; function vpi_get (Property: integer; Ref: vpiHandle) return Integer is Res : Integer; begin if Flag_Trace then Trace_Start ("vpi_get ("); Trace_Property (Property); Trace (", "); Trace (Ref); Trace (") = "); end if; case Property is when vpiType => Res := Ref.mType; when vpiTimePrecision => Res := -3 * Options.Time_Resolution_Scale; when vpiSize => Res := Vpi_Get_Size (Ref); when vpiVector => Res := Boolean'Pos (Vpi_Get_Vector (Ref)); when vpiDirection => case Vhpi_Get_Mode (Ref.Ref) is when VhpiInMode => Res := vpiInput; when VhpiOutMode => Res := vpiOutput; when VhpiInoutMode => Res := vpiInout; when others => Res := vpiNoDirection; end case; when others => dbgPut_Line ("vpi_get: unknown property"); Res := 0; end case; if Flag_Trace then case Property is when vpiType => Trace_Property (Res); when others => Trace (Res); end case; Trace_Newline; end if; return Res; end vpi_get; function Vhpi_Handle_To_Vpi_Prop (Res : VhpiHandleT) return Integer is begin case Vhpi_Get_Kind (Res) is when VhpiEntityDeclK | VhpiArchBodyK | VhpiBlockStmtK | VhpiIfGenerateK | VhpiForGenerateK | VhpiCompInstStmtK => return vpiModule; when VhpiPortDeclK => declare Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Res, Info); if Info.Vtype /= Vcd_Bad then return vpiNet; end if; end; when VhpiSigDeclK => declare Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Res, Info); if Info.Vtype /= Vcd_Bad then return vpiNet; end if; end; when VhpiGenericDeclK => declare Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Res, Info); if Info.Vtype /= Vcd_Bad then return vpiParameter; end if; end; when VhpiConstDeclK => declare Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Res, Info); if Info.Vtype /= Vcd_Bad then return vpiConstant; end if; end; when others => null; end case; return vpiUndefined; end Vhpi_Handle_To_Vpi_Prop; function Build_vpiHandle (Res : VhpiHandleT; Prop : Integer) return vpiHandle is begin case Prop is when vpiModule => return new struct_vpiHandle'(mType => vpiModule, Ref => Res); when vpiNet => return new struct_vpiHandle'(mType => vpiNet, Ref => Res); when vpiPort => return new struct_vpiHandle'(mType => vpiPort, Ref => Res); when vpiParameter => return new struct_vpiHandle'(mType => vpiParameter, Ref => Res); when vpiConstant => return new struct_vpiHandle'(mType => vpiConstant, Ref => Res); when others => return null; end case; end Build_vpiHandle; ------------------------------------------------------------------------ -- vpiHandle vpi_scan(vpiHandle iter) -- Scan the Verilog HDL hierarchy for objects with a one-to-many -- relationship. -- see IEEE 1364-2001, chapter 27.36, page 709 function Vpi_Scan_Internal (Iter: vpiHandle) return vpiHandle is Res : VhpiHandleT; Error : AvhpiErrorT; R : vpiHandle; Kind, Expected_Kind : Integer; begin -- End of scan reached. Avoid a crash in case of misuse. if Iter = null then return null; end if; -- There is only one top-level module. if Iter.mType = vpiModule then case Vhpi_Get_Kind (Iter.Ref) is when VhpiRootInstK => R := new struct_vpiHandle (Iter.mType); R.Ref := Iter.Ref; Iter.Ref := Null_Handle; return R; when VhpiUndefined => -- End of iteration. return null; when others => -- Fall through. null; end case; end if; case Iter.mType is when vpiInternalScope | vpiModule => Expected_Kind := vpiModule; when vpiPort => Expected_Kind := vpiPort; when vpiNet => Expected_Kind := vpiNet; when others => Expected_Kind := vpiUndefined; end case; loop Vhpi_Scan (Iter.Ref, Res, Error); exit when Error /= AvhpiErrorOk; Kind := Vhpi_Handle_To_Vpi_Prop (Res); if Kind /= vpiUndefined and then (Kind = Expected_Kind or(Kind = vpiPort and Expected_Kind = vpiNet)) then return Build_vpiHandle (Res, Kind); end if; end loop; return null; end Vpi_Scan_Internal; function vpi_scan (Iter: vpiHandle) return vpiHandle is Res : vpiHandle; begin if Flag_Trace then Trace_Start ("vpi_scan ("); Trace (Iter); Trace (") = "); end if; Res := Vpi_Scan_Internal (Iter); if Flag_Trace then Trace (Res); Trace_Newline; end if; -- IEEE 1364-2005 27.5 vpi_free_object() -- The iterator object shall automatically be freed when vpi_scan() -- returns NULL because it has either completed an object traversal -- or encountered an error condition. -- Free the iterator. if Res = null then Free_Copy (Iter); end if; return Res; end vpi_scan; ------------------------------------------------------------------------ -- char *vpi_get_str(int property, vpiHandle ref) -- see IEEE 1364-2001, page xxx Tmpstring2 : String (1 .. 1024); function Vpi_Get_Str_Internal (Property : Integer; Ref : vpiHandle) return Ghdl_C_String is Prop : VhpiStrPropertyT; Len : Natural; Res : Ghdl_C_String; begin if Ref = null then return null; end if; case Property is when vpiFullName => Prop := VhpiFullNameP; when vpiName => Prop := VhpiNameP; when vpiType => Tmpstring2 (1 .. 4) := "???" & NUL; return To_Ghdl_C_String (Tmpstring2'Address); when others => dbgPut_Line ("vpi_get_str: unhandled property"); return null; end case; Vhpi_Get_Str (Prop, Ref.Ref, Tmpstring2, Len); Tmpstring2 (Len + 1) := NUL; if Property = vpiFullName then for I in Tmpstring2'First .. Len loop if Tmpstring2 (I) = ':' then Tmpstring2 (I) := '.'; end if; end loop; -- Remove the initial '.'. Res := To_Ghdl_C_String (Tmpstring2 (2)'Address); else Res := To_Ghdl_C_String (Tmpstring2'Address); end if; return Res; end Vpi_Get_Str_Internal; function vpi_get_str (Property : Integer; Ref : vpiHandle) return Ghdl_C_String is Res : Ghdl_C_String; begin if Flag_Trace then Trace_Start ("vpi_get_str ("); Trace_Property (Property); Trace (", "); Trace (Ref); Trace (") = "); end if; Res := Vpi_Get_Str_Internal (Property, Ref); if Flag_Trace then Trace (Res); Trace_Newline; end if; return Res; end vpi_get_str; ------------------------------------------------------------------------ -- vpiHandle vpi_handle(int type, vpiHandle ref) -- Obtain a handle to an object with a one-to-one relationship. -- see IEEE 1364-2001, chapter 27.16, page 682 function Vpi_Handle_Internal (aType : Integer; Ref : vpiHandle) return vpiHandle is Res : vpiHandle; begin if Ref = null then return null; end if; case aType is when vpiScope => case Ref.mType is when vpiModule => Res := new struct_vpiHandle (vpiScope); Res.Ref := Ref.Ref; return Res; when others => return null; end case; when vpiRightRange | vpiLeftRange => case Ref.mType is when vpiPort| vpiNet => Res := new struct_vpiHandle (aType); Res.Ref := Ref.Ref; return Res; when others => return null; end case; when others => return null; end case; end Vpi_Handle_Internal; function vpi_handle (aType : Integer; Ref : vpiHandle) return vpiHandle is Res : vpiHandle; begin if Flag_Trace then Trace_Start ("vpi_handle ("); Trace_Property (aType); Trace (", "); Trace (Ref); Trace (") = "); end if; Res := Vpi_Handle_Internal (aType, Ref); if Flag_Trace then Trace (Res); Trace_Newline; end if; return Res; end vpi_handle; ------------------------------------------------------------------------ -- void vpi_get_value(vpiHandle expr, p_vpi_value value); -- Retrieve the simulation value of an object. -- see IEEE 1364-2001, chapter 27.14, page 675 Buf_Value : Vstring; procedure Append_Bin (V : Ghdl_U64; Ndigits : Natural) is begin for I in reverse 0 .. Ndigits - 1 loop if (Shift_Right (V, I) and 1) /= 0 then Append (Buf_Value, '1'); else Append (Buf_Value, '0'); end if; end loop; end Append_Bin; type Map_Type_E8 is array (Ghdl_E8 range 0..8) of character; Map_Std_E8: constant Map_Type_E8 := "UX01ZWLH-"; type Map_Type_B1 is array (Ghdl_B1) of character; Map_Std_B1: constant Map_Type_B1 := "01"; function ii_vpi_get_value_bin_str (Obj : VhpiHandleT) return Ghdl_C_String is function E8_To_Char (Val : Ghdl_E8) return Character is begin if Val not in Map_Type_E8'range then return '?'; else return Map_Std_E8 (Val); end if; end E8_To_Char; Info : Verilog_Wire_Info; Len : Ghdl_Index_Type; begin case Vhpi_Get_Kind (Obj) is when VhpiPortDeclK | VhpiSigDeclK | VhpiGenericDeclK | VhpiConstDeclK => null; when others => return null; end case; -- Get verilog compat info. Get_Verilog_Wire (Obj, Info); if Info.Vtype = Vcd_Bad then return null; end if; Len := Get_Wire_Length (Info); Reset (Buf_Value); -- reset string buffer case Info.Vtype is when Vcd_Bad | Vcd_Float64 => return null; when Vcd_Enum8 => declare V : Ghdl_E8; begin V := Verilog_Wire_Val (Info).E8; Append_Bin (Ghdl_U64 (V), 8); end; when Vcd_Integer32 => declare V : Ghdl_U32; begin V := Verilog_Wire_Val (Info).E32; Append_Bin (Ghdl_U64 (V), 32); end; when Vcd_Bit | Vcd_Bool => Append (Buf_Value, Map_Std_B1 (Verilog_Wire_Val (Info).B1)); when Vcd_Bitvector => for J in 0 .. Len - 1 loop Append (Buf_Value, Map_Std_B1 (Verilog_Wire_Val (Info, J).B1)); end loop; when Vcd_Stdlogic => Append (Buf_Value, E8_To_Char (Verilog_Wire_Val (Info).E8)); when Vcd_Stdlogic_Vector => for J in 0 .. Len - 1 loop Append (Buf_Value, E8_To_Char (Verilog_Wire_Val (Info, J).E8)); end loop; end case; Append (Buf_Value, NUL); return Get_C_String (Buf_Value); end ii_vpi_get_value_bin_str; procedure vpi_get_value (Expr : vpiHandle; Value : p_vpi_value) is begin if Flag_Trace then Trace_Start ("vpi_get_value ("); Trace (Expr); Trace (", {format="); Trace_Format (Value.Format); Trace ("}) = "); end if; case Value.Format is when vpiObjTypeVal=> -- fill in the object type and value: -- For an integer, vpiIntVal -- For a real, vpiRealVal -- For a scalar, either vpiScalar or vpiStrength -- For a time variable, vpiTimeVal with vpiSimTime -- For a vector, vpiVectorVal dbgPut_Line ("vpi_get_value: vpiObjTypeVal"); when vpiBinStrVal=> Value.Str := ii_vpi_get_value_bin_str (Expr.Ref); --aValue.mStr := NulTerminate2(aExpr.mRef.Name.all); when vpiOctStrVal=> dbgPut_Line("vpi_get_value: vpiNet, vpiOctStrVal"); when vpiDecStrVal=> dbgPut_Line("vpi_get_value: vpiNet, vpiDecStrVal"); when vpiHexStrVal=> dbgPut_Line("vpi_get_value: vpiNet, vpiHexStrVal"); when vpiScalarVal=> dbgPut_Line("vpi_get_value: vpiNet, vpiScalarVal"); when vpiIntVal=> case Expr.mType is when vpiLeftRange | vpiRightRange=> declare Info : Verilog_Wire_Info; begin Get_Verilog_Wire (Expr.Ref, Info); if Info.Irange /= null then if Expr.mType = vpiLeftRange then Value.Integer_m := Integer (Info.Irange.I32.Left); else Value.Integer_m := Integer (Info.Irange.I32.Right); end if; else Value.Integer_m := 0; end if; end; when others=> dbgPut_Line ("vpi_get_value: vpiIntVal, unknown mType"); end case; when vpiRealVal=> dbgPut_Line("vpi_get_value: vpiRealVal"); when vpiStringVal=> dbgPut_Line("vpi_get_value: vpiStringVal"); when vpiTimeVal=> dbgPut_Line("vpi_get_value: vpiTimeVal"); when vpiVectorVal=> dbgPut_Line("vpi_get_value: vpiVectorVal"); when vpiStrengthVal=> dbgPut_Line("vpi_get_value: vpiStrengthVal"); when others=> dbgPut_Line("vpi_get_value: unknown mFormat"); end case; if Flag_Trace then Trace_Value (Value); Trace_Newline; end if; end vpi_get_value; ------------------------------------------------------------------------ -- void vpiHandle vpi_put_value(vpiHandle obj, p_vpi_value value, -- p_vpi_time when, int flags) -- Alter the simulation value of an object. -- see IEEE 1364-2001, chapter 27.14, page 675 -- FIXME type Std_Ulogic_Array is array (Ghdl_Index_Type range <>) of Std_Ulogic; procedure Ii_Vpi_Put_Value (Info : Verilog_Wire_Info; Vec : Std_Ulogic_Array) is begin case Info.Vtype is when Vcd_Bad => return; when Vcd_Bit | Vcd_Bool | Vcd_Bitvector => for J in Vec'Range loop declare V : constant Ghdl_B1 := Ghdl_B1 (Vec (J) = '1' or Vec (J) = 'H'); begin case Info.Val is when Vcd_Effective => Ghdl_Signal_Force_Effective_B1 (To_Signal_Arr_Ptr (Info.Ptr)(J), V); when Vcd_Driving => -- Force_Driving sets both the driving and the -- effective value. Ghdl_Signal_Force_Driving_B1 (To_Signal_Arr_Ptr (Info.Ptr)(J), V); when Vcd_Variable => Verilog_Wire_Val (Info, J).B1 := V; end case; end; end loop; when Vcd_Stdlogic | Vcd_Stdlogic_Vector => for J in Vec'Range loop declare V : constant Ghdl_E8 := Std_Ulogic'Pos (Vec (J)); begin case Info.Val is when Vcd_Effective => Ghdl_Signal_Force_Effective_E8 (To_Signal_Arr_Ptr (Info.Ptr)(J), V); when Vcd_Driving => Ghdl_Signal_Force_Driving_E8 (To_Signal_Arr_Ptr (Info.Ptr)(J), V); when Vcd_Variable => Verilog_Wire_Val (Info, J).E8 := V; end case; end; end loop; when Vcd_Enum8 => declare V : Ghdl_E8; begin V := 0; for I in reverse Vec'Range loop if Vec (I) = '1' then -- Ok, handles 'X', 'Z'... like '0'. V := V or Shift_Left (1, Natural (Vec'Last - I)); end if; end loop; case Info.Val is when Vcd_Effective => Ghdl_Signal_Force_Effective_E8 (To_Signal_Arr_Ptr (Info.Ptr)(0), V); when Vcd_Driving => Ghdl_Signal_Force_Driving_E8 (To_Signal_Arr_Ptr (Info.Ptr)(0), V); when Vcd_Variable => Verilog_Wire_Val (Info).E8 := V; end case; end; when Vcd_Integer32 | Vcd_Float64 => null; end case; end Ii_Vpi_Put_Value; procedure Ii_Vpi_Put_Value_Int (Info : Verilog_Wire_Info; Len : Ghdl_Index_Type; Val : Unsigned_32) is V : Unsigned_32; Vec : Std_Ulogic_Array (0 .. Len - 1); begin V := Val; for J in reverse 0 .. Len - 1 loop if (V mod 2) = 0 then Vec (J) := '0'; else Vec (J) := '1'; end if; V := Shift_Right_Arithmetic (V, 1); end loop; Ii_Vpi_Put_Value (Info, Vec); end Ii_Vpi_Put_Value_Int; procedure Ii_Vpi_Put_Value_Bin_Str (Info : Verilog_Wire_Info; Len : Ghdl_Index_Type; Str : Ghdl_C_String) is Slen : constant Natural := strlen (Str); Soff : Integer; Vec : Std_Ulogic_Array (0 .. Len - 1); V : Std_Ulogic; begin Soff := Slen; for J in reverse 0 .. Len - 1 loop Soff := Soff - 1; if Soff >= 0 then case Str (Str'First + Soff) is when 'u' | 'U' => V := 'U'; when 'x' | 'X' => V := 'X'; when '0' => V := '0'; when '1' => V := '1'; when 'z' | 'Z' => V := 'Z'; when 'w' | 'W' => V := 'W'; when 'l' | 'L' => V := 'L'; when 'h' | 'H' => V := 'H'; when '-' => V := '-'; when others => V := 'U'; end case; else V := '0'; end if; Vec (J) := V; end loop; Ii_Vpi_Put_Value (Info, Vec); end Ii_Vpi_Put_Value_Bin_Str; -- vpiHandle vpi_put_value(vpiHandle obj, p_vpi_value value, -- p_vpi_time when, int flags) function vpi_put_value (aObj : vpiHandle; aValue : p_vpi_value; aWhen : p_vpi_time; aFlags : integer) return vpiHandle is pragma Unreferenced (aWhen); pragma Unreferenced (aFlags); function To_Unsigned_32 is new Ada.Unchecked_Conversion (Integer, Unsigned_32); Info : Verilog_Wire_Info; Len : Ghdl_Index_Type; begin if Flag_Trace then Trace_Start ("vpi_put_value ("); Trace (aObj); Trace (", "); Trace_Value (aValue); Trace (")"); Trace_Newline; end if; Reset_Error; -- A very simple write procedure for VPI. -- Basically, it accepts bin_str values and converts to appropriate -- types (only std_logic and bit values and vectors). -- It'll use Set_Effective_Value procedure to update signals -- Ignoring aWhen and aFlags, for now. -- Check the Obj type. -- * The vpiHandle has a reference (field Ref) to a VhpiHandleT -- when it doesnt come from a callback. case Vhpi_Get_Kind (aObj.Ref) is when VhpiPortDeclK | VhpiSigDeclK => null; when others => return null; end case; -- The following code segment was copied from the -- ii_vpi_get_value function. -- Get verilog compat info. Get_Verilog_Wire (aObj.Ref, Info); if Info.Vtype = Vcd_Bad then return null; end if; Len := Get_Wire_Length (Info); if Len = 0 then -- No signal. return null; end if; -- Step 1: convert vpi object to internal format. -- p_vpi_handle -> Ghdl_Signal_Ptr -- To_Signal_Arr_Ptr (Info.Addr) does part of the magic -- Step 2: convert datum to appropriate type. -- Ghdl_C_String -> Value_Union -- Step 3: assigns value to object using Set_Effective_Value -- call (from grt-signals) -- Set_Effective_Value(sig_ptr, conv_value); -- Checks the format of aValue. Only vpiBinStrVal will be accepted -- for now. case aValue.Format is when vpiObjTypeVal => dbgPut_Line ("vpi_put_value: vpiObjTypeVal"); when vpiBinStrVal => -- Convert LEN (number of elements) to number of bits. case Info.Vtype is when Vcd_Bad => null; when Vcd_Bit | Vcd_Bool | Vcd_Bitvector | Vcd_Stdlogic | Vcd_Stdlogic_Vector => null; when Vcd_Enum8 => Len := Len * 8; when Vcd_Integer32 => Len := Len * 32; when Vcd_Float64 => Len := Len * 64; end case; Ii_Vpi_Put_Value_Bin_Str (Info, Len, aValue.Str); -- dbgPut_Line ("vpi_put_value: vpiBinStrVal"); when vpiOctStrVal => dbgPut_Line ("vpi_put_value: vpiNet, vpiOctStrVal"); when vpiDecStrVal => dbgPut_Line ("vpi_put_value: vpiNet, vpiDecStrVal"); when vpiHexStrVal => dbgPut_Line ("vpi_put_value: vpiNet, vpiHexStrVal"); when vpiScalarVal => dbgPut_Line ("vpi_put_value: vpiNet, vpiScalarVal"); when vpiIntVal => Ii_Vpi_Put_Value_Int (Info, Len, To_Unsigned_32 (aValue.Integer_m)); -- dbgPut_Line ("vpi_put_value: vpiIntVal"); when vpiRealVal => dbgPut_Line("vpi_put_value: vpiRealVal"); when vpiStringVal => dbgPut_Line("vpi_put_value: vpiStringVal"); when vpiTimeVal => dbgPut_Line("vpi_put_value: vpiTimeVal"); when vpiVectorVal => dbgPut_Line("vpi_put_value: vpiVectorVal"); when vpiStrengthVal => dbgPut_Line("vpi_put_value: vpiStrengthVal"); when others => dbgPut_Line("vpi_put_value: unknown mFormat"); end case; -- Must return a scheduled event caused by vpi_put_value() -- Still dont know how to do it. return null; end vpi_put_value; ------------------------------------------------------------------------ -- void vpi_get_time(vpiHandle obj, s_vpi_time*t); -- see IEEE 1364-2001, page xxx procedure vpi_get_time (Obj: vpiHandle; Time: p_vpi_time) is function To_Unsigned_64 is new Ada.Unchecked_Conversion (Std_Time, Unsigned_64); Res : Std_Time; V : Unsigned_64; begin if Flag_Trace then Trace_Start ("vpi_get_time ("); Trace (Obj); Trace (", {mtype="); Trace_Time_Tag (Time.mType); Trace ("}) = "); end if; if Obj /= null or else Time.mType /= vpiSimTime then dbgPut_Line ("vpi_get_time: unhandled"); return; end if; Res := Current_Time; V := To_Unsigned_64 (Res); Time.mHigh := Unsigned_32 (V / 2 ** 32); Time.mLow := Unsigned_32 (V mod 2 ** 32); Time.mReal := 0.0; if Flag_Trace then Trace_Time (Res); Trace_Newline; end if; end vpi_get_time; ------------------------------------------------------------------------ type Callback_List is record First, Last : vpiHandle; end record; procedure Append_Callback (List : in out Callback_List; Hand : vpiHandle) is begin if List.First = null then List.First := Hand; else List.Last.Cb_Next := Hand; Hand.Cb_Prev := List.Last; end if; List.Last := Hand; Hand.Cb_Next := null; end Append_Callback; procedure Execute_Callback (Hand : vpiHandle) is Res : Integer; pragma Unreferenced (Res); begin if Flag_Trace then Trace_Start ("vpi call callback "); Trace (Hand); Trace (" "); Trace_Cb_Reason (Hand.Cb.Reason); Trace_Newline; Trace_Indent := Trace_Indent + 1; end if; Res := Hand.Cb.Cb_Rtn (Hand.Cb'Access); if Flag_Trace then Trace_Indent := Trace_Indent - 1; Trace_Start ("vpi end callback "); Trace (Hand); Trace_Newline; end if; end Execute_Callback; procedure Execute_Callback_List (List : Callback_List) is H, Next_H : vpiHandle; begin H := List.First; while H /= null loop Next_H := H.Cb_Next; -- The callback may destroy h. Execute_Callback (H); H := Next_H; end loop; end Execute_Callback_List; -- vpiHandle vpi_register_cb(p_cb_data data) g_cbEndOfCompile : Callback_List; g_cbStartOfSimulation : Callback_List; g_cbEndOfSimulation : Callback_List; function To_Address is new Ada.Unchecked_Conversion (vpiHandle, System.Address); function To_vpiHandle is new Ada.Unchecked_Conversion (System.Address, vpiHandle); -- Wrapper procedure Call_Callback (Arg : System.Address) is Hand : vpiHandle; begin Hand := To_vpiHandle (Arg); -- Increase/decrease the reference counter as it is referenced by HAND. Hand.Cb_Refcnt := Hand.Cb_Refcnt + 1; Execute_Callback (Hand); Hand.Cb_Refcnt := Hand.Cb_Refcnt - 1; -- Free handlers if called once. case Hand.Cb.Reason is when cbEndOfCompile | cbStartOfSimulation | cbEndOfSimulation | cbReadOnlySynch | cbReadWriteSynch | cbAfterDelay | cbNextSimTime => pragma Assert (Hand.Cb_Refcnt = 1); -- The handler has been removed from the queue, so the reference -- counter has to be decremented and its value must be 0. Time -- to free it. Free (Hand); when cbValueChange => -- The handler hasn't been removed from the queue, unless the -- user did it while the callback was executed. If so, the -- reference counter must now be 0 and we can free it. if Hand.Cb_Refcnt = 0 then Free (Hand); end if; when others => null; end case; end Call_Callback; procedure Call_Valuechange_Callback (Arg : System.Address) is Hand : constant vpiHandle := To_vpiHandle (Arg); begin if Verilog_Wire_Event (Hand.Cb_Wire) then -- Note: the call may remove H from the list, or even -- destroy it. -- However, we assume it doesn't remove the next callback... Call_Callback (Arg); end if; end Call_Valuechange_Callback; procedure Resched_Callback (Arg : System.Address) is Hand : constant vpiHandle := To_vpiHandle (Arg); begin case Hand.Cb.Reason is when cbReadOnlySynch => Register_Callback (Cb_End_Of_Time_Step, Hand.Cb_Handle, Oneshot, Call_Callback'Access, Arg); when cbReadWriteSynch => Register_Callback (Cb_Last_Known_Delta, Hand.Cb_Handle, Oneshot, Call_Callback'Access, Arg); when others => raise Program_Error; end case; end Resched_Callback; function vpi_register_cb (Data : p_cb_data) return vpiHandle is Res : vpiHandle; T : Std_Time; begin if Flag_Trace then Trace_Start ("vpi_register_cb ({reason="); Trace_Cb_Reason (Data.Reason); Trace (", obj="); Trace (Data.Obj); case Data.Reason is when cbAfterDelay => Trace (", time="); Trace_Time (Vpi_Time_To_Time (Data.Time.all)); when others => null; end case; Trace ("}) = "); end if; Res := new struct_vpiHandle (vpiCallback); Res.Cb := Data.all; -- There is one reference to the callback as it is registered. Res.Cb_Refcnt := 1; case Data.Reason is when cbEndOfCompile => Append_Callback (g_cbEndOfCompile, Res); when cbStartOfSimulation => Append_Callback (g_cbStartOfSimulation, Res); when cbEndOfSimulation => Append_Callback (g_cbEndOfSimulation, Res); when cbValueChange => Get_Verilog_Wire (Data.Obj.Ref, Res.Cb_Wire); Register_Callback (Cb_Signals_Updated, Res.Cb_Handle, Repeat, Call_Valuechange_Callback'Access, To_Address (Res)); when cbReadOnlySynch | cbReadWriteSynch => T := Vpi_Time_To_Time (Data.Time.all); if T = 0 then Resched_Callback (To_Address (Res)); else Register_Callback_At (Cb_After_Delay, Res.Cb_Handle, Current_Time + T, Resched_Callback'Access, To_Address (Res)); end if; when cbAfterDelay => T := Vpi_Time_To_Time (Data.Time.all); Register_Callback_At (Cb_After_Delay, Res.Cb_Handle, Current_Time + T, Call_Callback'Access, To_Address (Res)); when cbNextSimTime => Register_Callback (Cb_Next_Time_Step, Res.Cb_Handle, Oneshot, Call_Callback'Access, To_Address (Res)); when others => dbgPut_Line ("vpi_register_cb: unknown callback reason"); Free (Res); end case; if Flag_Trace then Trace (Res); Trace_Newline; end if; return Res; end vpi_register_cb; -- int vpi_remove_cb(vpiHandle ref) function vpi_remove_cb (Ref : vpiHandle) return Integer is Ref_Copy : vpiHandle; Res : Integer; begin if Flag_Trace then Trace_Start ("vpi_remove_cb ("); Trace (Ref); Trace (") = "); end if; Res := 1; Ref_Copy := Ref; case Ref.Cb.Reason is when cbValueChange | cbReadWriteSynch | cbReadOnlySynch => Delete_Callback (Ref.Cb_Handle); Ref.Cb_Refcnt := Ref.Cb_Refcnt - 1; if Ref.Cb_Refcnt > 0 then -- Do not free REF. Ref_Copy := null; end if; when others => Res := 0; Ref_Copy := null; end case; if Flag_Trace then if Ref_Copy = null then Trace ("[not free] "); else Trace ("[free] "); end if; Trace (Res); Trace_Newline; end if; Free (Ref_Copy); return Res; end vpi_remove_cb; -- int vpi_free_object(vpiHandle ref) function vpi_free_object (aRef: vpiHandle) return integer is Ref_Copy : vpiHandle; begin if Flag_Trace then Trace_Start ("vpi_free_object ("); Trace (aRef); Trace (")"); Trace_Newline; end if; case aRef.mType is when vpiCallback => -- Callback are automatically freed. null; when others => Ref_Copy := aRef; Free (Ref_Copy); end case; return 1; end vpi_free_object; ------------------------------------------------------------------------------- -- * * * V P I d u m m i e s * * * * * * * * * * * * * * * * * * * * * * ------------------------------------------------------------------------------- -- int vpi_get_vlog_info(p_vpi_vlog_info vlog_info_p) function vpi_get_vlog_info (info : p_vpi_vlog_info) return integer is function To_Address is new Ada.Unchecked_Conversion (Source => Grt.Options.Argv_Type, Target => System.Address); begin if Flag_Trace then Trace_Start ("vpi_get_vlog_info"); Trace_Newline; end if; info.all := (Argc => Options.Argc, Argv => To_Address(Options.Argv), Product => To_Ghdl_C_String (Product'Address), Version => To_Ghdl_C_String (GhdlVersion'Address)); return 1; end vpi_get_vlog_info; -- vpiHandle vpi_handle_by_index(vpiHandle ref, int index) function vpi_handle_by_index (aRef: vpiHandle; aIndex: integer) return vpiHandle is pragma Unreferenced (aRef); pragma Unreferenced (aIndex); begin if Flag_Trace then Trace_Start ("vpi_handle_by_index UNIMPLEMENTED!"); Trace_Newline; end if; return null; end vpi_handle_by_index; -- Return True iff L and R are equal. L must not have an element set to -- NUL. R must be lower case. function Strcasecmp (L : String; R : Ghdl_C_String) return Boolean is begin if L'Last < L'First - 1 then -- Handle null string. return R (1) = NUL; end if; for I in L'Range loop if L (I) = NUL then -- NUL not allowed in L. return False; end if; if To_Lower (L (I)) /= R (I - L'First + 1) then return False; end if; end loop; -- R is NUL terminated. return R (L'Length + 1) = NUL; end Strcasecmp; procedure Find_By_Name (Scope : VhpiHandleT; Rel : VhpiOneToManyT; Name : String; Res : out VhpiHandleT; Err : out AvhpiErrorT) is It : VhpiHandleT; El_Name : Ghdl_C_String; begin Vhpi_Iterator (Rel, Scope, It, Err); if Err /= AvhpiErrorOk then return; end if; loop Vhpi_Scan (It, Res, Err); -- Either a real error or end of iterator. exit when Err /= AvhpiErrorOk; El_Name := Avhpi_Get_Base_Name (Res); exit when El_Name /= null and then Strcasecmp (Name, El_Name); end loop; end Find_By_Name; function Vpi_Handle_By_Name_Internal (Name : Ghdl_C_String; Scope : vpiHandle) return vpiHandle is B, E : Natural; Base, El : VhpiHandleT; Err : AvhpiErrorT; Prop : Integer; Res : vpiHandle; Escaped : Boolean; begin -- Extract the start point. if Scope = null then Get_Root_Scope (Base); else Base := Scope.Ref; end if; B := Name'First; -- Iterate on each part of Name. loop exit when Name (B) = NUL; -- Extract the next part of the name. declare C : Character; begin E := B; Escaped := Name (E) = '\'; loop C := Name (E + 1); -- '.' is a separator when not inside extended identifiers. exit when C = NUL or (C = '.' and not Escaped); if C = '\' then -- Start or end of extended identifiers. -- '\' within an extended identifier is doubled, so like -- if there were two extended identifiers. Escaped := not Escaped; end if; E := E + 1; end loop; end; -- Find name in Base, first as a decl, then as a sub-region. Find_By_Name (Base, VhpiDecls, Name (B .. E), El, Err); if Err /= AvhpiErrorOk then Find_By_Name (Base, VhpiInternalRegions, Name (B .. E), El, Err); end if; if Err = AvhpiErrorOk then -- Found! Base := El; else -- Not found. return null; end if; -- Next path component. B := E + 1; exit when Name (B) = NUL; pragma Assert (Name (B) = '.'); B := B + 1; end loop; Prop := Vhpi_Handle_To_Vpi_Prop (Base); if Prop /= vpiUndefined then Res := Build_vpiHandle (Base, Prop); else Res := null; end if; return Res; end Vpi_Handle_By_Name_Internal; function vpi_handle_by_name (Name : Ghdl_C_String; Scope : vpiHandle) return vpiHandle is Res : vpiHandle; begin if Flag_Trace then Trace_Start ("vpi_handle_by_name ("); Trace (Name); Trace (", "); Trace (Scope); Trace (") = "); end if; Res := Vpi_Handle_By_Name_Internal (Name, Scope); if Flag_Trace then Trace (Res); Trace_Newline; end if; return Res; end vpi_handle_by_name; -- unsigned int vpi_mcd_close(unsigned int mcd) function vpi_mcd_close (Mcd: integer) return integer is pragma Unreferenced (Mcd); begin return 0; end vpi_mcd_close; -- char *vpi_mcd_name(unsigned int mcd) function vpi_mcd_name (Mcd: integer) return integer is pragma Unreferenced (Mcd); begin return 0; end vpi_mcd_name; -- unsigned int vpi_mcd_open(char *name) function vpi_mcd_open (Name : Ghdl_C_String) return Integer is pragma Unreferenced (Name); begin return 0; end vpi_mcd_open; function vpi_register_systf (aSs: System.Address) return vpiHandle is pragma Unreferenced (aSs); begin if Flag_Trace then Trace_Start ("vpi_register_systf"); Trace_Newline; end if; return null; end vpi_register_systf; -- missing here, see grt-cvpi.c: -- vpi_mcd_open_x -- vpi_mcd_vprintf -- vpi_mcd_fputc -- vpi_mcd_fgetc -- vpi_sim_vcontrol -- vpi_chk_error -- vpi_handle_by_name Default_Message : constant String := "(no error message)" & NUL; Unknown_File : constant String := "(no file)" & NUL; Err_Message : Ghdl_C_String := To_Ghdl_C_String (Default_Message'Address); Err_Code : Ghdl_C_String := null; Err_File : Ghdl_C_String := To_Ghdl_C_String (Unknown_File'Address); Err_Line : Integer := 0; Err_Status : Integer := 0; procedure Reset_Error is begin Err_Message := To_Ghdl_C_String (Default_Message'Address); Err_Code := null; Err_File := To_Ghdl_C_String (Unknown_File'Address); Err_Line := 0; Err_Status := 0; end Reset_Error; function vpi_chk_error (Info : p_vpi_error_info) return Integer is begin if Info /= null then Info.all := (State => vpiRun, Level => vpiError, Message => Err_Message, Product => To_Ghdl_C_String (Product'Address), Code => Err_Code, File => Err_File, Line => Err_Line); end if; return Err_Status; end vpi_chk_error; function vpi_control_np (Op : Integer; Status : Integer) return Integer is begin if Flag_Trace then Trace_Start ("vpi_control ("); Trace_Property (Op); Trace (", "); Trace (Status); Trace (")"); Trace_Newline; end if; case Op is when vpiFinish | vpiStop => Options.Break_Simulation := True; return 1; when others => return 0; end case; end vpi_control_np; ------------------------------------------------------------------------------ -- * * * G H D L h o o k s * * * * * * * * * * * * * * * * * * * * * * * ------------------------------------------------------------------------------ type Lib_Cell; type Lib_Access is access Lib_Cell; type Lib_Cell is record File_Name : String_Access; Next : Lib_Access; end record; Vpi_Libraries : Lib_Access := null; ------------------------------------------------------------------------ -- Return TRUE if OPT is an option for VPI. function Vpi_Option (Opt : String) return Boolean is F : constant Natural := Opt'First; begin if Opt'Length < 5 or else Opt (F .. F + 4) /= "--vpi" then return False; end if; if Opt'Length > 6 and then Opt (F + 5) = '=' then declare Lib : Lib_Access; File : String_Access; begin -- Store library info. Lib := new Lib_Cell; -- Add an extra NUL character. File := new String (1 .. Opt'Length - 6 + 1); File (1 .. Opt'Length - 6) := Opt (F + 6 .. Opt'Last); File (File'Last) := NUL; Lib.File_Name := File; -- Add new library to the list. if Vpi_Libraries = null then Vpi_Libraries := Lib; else declare L : Lib_Access := Vpi_Libraries; begin while L.Next /= null loop L := L.Next; end loop; L.Next := Lib; end; end if; end; return True; elsif Opt'Length >= 11 and then Opt (F + 5 .. F + 10) = "-trace" then if Opt'Length > 11 and then Opt (F + 11) = '=' then declare Filename : String (1 .. Opt'Length - 11); Mode : constant String := "wt" & NUL; begin Filename (1 .. Filename'Last - 1) := Opt (F + 12 .. Opt'Last); Filename (Filename'Last) := NUL; Trace_File := fopen (Filename'Address, Mode'Address); if Trace_File = NULL_Stream then Error_S ("cannot open vpi trace file '"); Diag_C (Opt (F + 12 .. Opt'Last)); Error_E ("'"); return False; end if; end; elsif Opt'Length = 11 then Trace_File := stdout; else Error_S ("incorrect option '"); Diag_C (Opt); Error_E ("'"); return False; end if; Flag_Trace := True; return True; else return False; end if; end Vpi_Option; ------------------------------------------------------------------------ procedure Vpi_Help is begin Put_Line (" --vpi=FILENAME load VPI library"); Put_Line (" --vpi-trace[=FILE] trace vpi calls to stdout or provided FILE"); end Vpi_Help; ------------------------------------------------------------------------ -- Called before elaboration. -- void loadVpiModule(const char* modulename) function LoadVpiModule (Filename: Address) return Integer; pragma Import (C, LoadVpiModule, "loadVpiModule"); procedure Vpi_Init is Lib : Lib_Access := Vpi_Libraries; begin if Lib = null then return; end if; while Lib /= null loop if LoadVpiModule (Lib.File_Name.all'Address) /= 0 then Error_S ("cannot load VPI module '"); Diag_C (Lib.File_Name.all); Error_E ("'"); end if; Lib := Lib.Next; end loop; end Vpi_Init; ------------------------------------------------------------------------ -- Called after elaboration. procedure Vpi_Start is Res : Integer; pragma Unreferenced (Res); begin if Vpi_Libraries = null then return; end if; Grt.Rtis_Types.Search_Types_RTI; Execute_Callback_List (g_cbEndOfCompile); Execute_Callback_List (g_cbStartOfSimulation); end Vpi_Start; ------------------------------------------------------------------------ -- Called at the end of the simulation. procedure Vpi_End is Res : Integer; pragma Unreferenced (Res); begin Execute_Callback_List (g_cbEndOfSimulation); Free (Buf_Value); end Vpi_End; Vpi_Hooks : aliased constant Hooks_Type := (Desc => new String'("vpi: vpi compatible API"), Option => Vpi_Option'Access, Help => Vpi_Help'Access, Init => Vpi_Init'Access, Start => Vpi_Start'Access, Finish => Vpi_End'Access); procedure Register is begin Register_Hooks (Vpi_Hooks'Access); end Register; end Grt.Vpi;