-- GHDL Run Time (GRT) - signals management. -- 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 System; with Ada.Unchecked_Conversion; with Grt.Table; with Grt.Types; use Grt.Types; with Grt.Rtis; use Grt.Rtis; limited with Grt.Processes; pragma Elaborate_All (Grt.Table); package Grt.Signals is pragma Suppress (All_Checks); -- Kind of transaction. type Transaction_Kind is ( -- Normal transaction, with a value. Trans_Value, -- Normal transaction, with a pointer to a value (direct assignment). Trans_Direct, -- Null transaction. Trans_Null, -- Like a normal transaction, but without a value due to check error. Trans_Error ); type Transaction; type Transaction_Acc is access Transaction; type Transaction (Kind : Transaction_Kind) is record -- Line for error. Put here to compact the record. Line : Ghdl_I32; Next : Transaction_Acc; Time : Std_Time; case Kind is when Trans_Value => Val : Value_Union; when Trans_Direct => Val_Ptr : Ghdl_Value_Ptr; when Trans_Null => null; when Trans_Error => -- Filename for error. File : Ghdl_C_String; end case; end record; type Process_Acc is access Grt.Processes.Process_Type; -- A driver is bound to a process (PROC) and contains a list of -- transactions. type Driver_Type is record First_Trans : Transaction_Acc; Last_Trans : Transaction_Acc; Proc : Process_Acc; end record; type Driver_Acc is access all Driver_Type; type Driver_Fat_Array is array (Ghdl_Index_Type) of aliased Driver_Type; type Driver_Arr_Ptr is access Driver_Fat_Array; -- Function access type used to evaluate the guard expression. type Guard_Func_Acc is access function (This : System.Address) return Ghdl_B2; pragma Convention (C, Guard_Func_Acc); -- Simply linked list of processes to be resumed in case of events. type Ghdl_Signal; type Ghdl_Signal_Ptr is access Ghdl_Signal; function To_Ghdl_Signal_Ptr is new Ada.Unchecked_Conversion (Source => System.Address, Target => Ghdl_Signal_Ptr); type Signal_Fat_Array is array (Ghdl_Index_Type) of Ghdl_Signal_Ptr; type Signal_Arr_Ptr is access Signal_Fat_Array; function To_Signal_Arr_Ptr is new Ada.Unchecked_Conversion (Source => System.Address, Target => Signal_Arr_Ptr); -- List of processes to wake-up in case of event on the signal. type Action_List; type Action_List_Acc is access Action_List; type Action_List (Dynamic : Boolean) is record -- Next action for the current signal. Next : Action_List_Acc; -- Process to wake-up. Proc : Process_Acc; case Dynamic is when True => -- For a non-sensitized process. -- Previous action (to speed-up remove from the chain). Prev : Action_List_Acc; Sig : Ghdl_Signal_Ptr; -- Chain of signals for the process. Chain : Action_List_Acc; when False => null; end case; end record; -- Resolution function. -- There is a wrapper around resolution functions to simplify the call -- from GRT. -- INSTANCE is the opaque parameter given when the resolver is -- registers (RESOLV_INST). -- VAL is the signal (which may be composite). -- BOOL_VEC is an array of NBR_DRV booleans (bytes) and indicates -- non-null drivers. There are VEC_LEN non-null drivers. So the number -- of values is VEC_LEN + NBR_PORTS. This number of values is the length -- of the array for the resolution function. type Resolver_Acc is access procedure (Instance : System.Address; Val : System.Address; Bool_Vec : System.Address; Vec_Len : Ghdl_Index_Type; Nbr_Drv : Ghdl_Index_Type; Nbr_Ports : Ghdl_Index_Type); -- On some platforms, GNAT use a descriptor (instead of a trampoline) for -- nested subprograms. This descriptor contains the address of the -- subprogram and the address of the chain. An unaligned pointer to this -- descriptor (address + 1) is then used for 'Access, and every indirect -- call check for unaligned address. -- -- Disable this feature (as a resolver is never a nested subprogram), so -- code generated by ghdl is compatible with ghdl runtimes built with -- gnat. pragma Convention (C, Resolver_Acc); -- How to compute resolved signal. type Resolved_Signal_Type is record Resolv_Proc : Resolver_Acc; Resolv_Inst : System.Address; Resolv_Ptr : System.Address; Sig_Range : Sig_Table_Range; Disconnect_Time : Std_Time; end record; type Resolved_Signal_Acc is access Resolved_Signal_Type; type Conversion_Func_Acc is access procedure (Instance : System.Address); pragma Convention (C, Conversion_Func_Acc); function To_Conversion_Func_Acc is new Ada.Unchecked_Conversion (Source => System.Address, Target => Conversion_Func_Acc); -- Signal conversion data. type Sig_Conversion_Type is record -- Function which performs the conversion. Func : System.Address; Instance : System.Address; Src : Sig_Table_Range; Dest : Sig_Table_Range; end record; type Sig_Conversion_Acc is access Sig_Conversion_Type; type Forward_Build_Type is record Src : Ghdl_Signal_Ptr; Targ : Ghdl_Signal_Ptr; end record; type Forward_Build_Acc is access Forward_Build_Type; -- Used to order the signals for the propagation of signals values. type Propag_Order_Flag is ( -- The signal was not yet ordered. Propag_None, -- The signal is being ordered for driving value. -- This stage is used to catch loop (which can not occur). Propag_Being_Driving, -- The signal has been ordered for driving value. Propag_Driving, -- The signal is being ordered for effective value. Propag_Being_Effective, -- The signal has completly been ordered. Propag_Done); -- Each signal belongs to a signal_net. -- Signals on the same net must be updated in order. -- Signals on different nets have no direct relation-ship, and thus may -- be updated without order. -- Net NO_SIGNAL_NET is special: it groups all lonely signals. type Signal_Net_Type is new Integer; No_Signal_Net : constant Signal_Net_Type := 0; Net_One_Driver : constant Signal_Net_Type := -1; Net_One_Direct : constant Signal_Net_Type := -2; Net_One_Resolved : constant Signal_Net_Type := -3; -- Flush the list of active signals. procedure Flush_Active_List; type Ghdl_Signal_Data (Mode_Sig : Mode_Signal_Type := Mode_Signal) is record case Mode_Sig is when Mode_Signal_User => Nbr_Drivers : Ghdl_Index_Type; Drivers : Driver_Arr_Ptr; -- Signal which defines the effective value of this signal, -- if any. Effective : Ghdl_Signal_Ptr; -- Null if not resolved. Resolv : Resolved_Signal_Acc; when Mode_Conv_In | Mode_Conv_Out => -- Conversion paramaters for conv_in, conv_out. Conv : Sig_Conversion_Acc; when Mode_Stable | Mode_Quiet | Mode_Delayed => -- Time parameter for 'stable, 'quiet or 'delayed Time : Std_Time; Attr_Trans : Transaction_Acc; when Mode_Guard => -- Guard function and instance used to compute the -- guard expression. Guard_Func : Guard_Func_Acc; Guard_Instance : System.Address; when Mode_Transaction | Mode_End => null; end case; end record; pragma Suppress (Discriminant_Check, On => Ghdl_Signal_Data); type Ghdl_Signal_Flags is record -- Status of the ordering. Propag : Propag_Order_Flag; -- If set, the signal is dumped in a GHW file. Is_Dumped : Boolean; -- Set when an event occured. -- Only reset by GHW file dumper. Cyc_Event : Boolean; -- Set if the signal has already been visited. When outside of the -- algorithm that use it, it must be cleared. Seen : Boolean; end record; pragma Pack (Ghdl_Signal_Flags); type Ghdl_Signal is record -- Fields known by the compilers. Value : Value_Union; Driving_Value : Value_Union; Last_Value : Value_Union; Last_Event : Std_Time; Last_Active : Std_Time; Event : Boolean; Active : Boolean; -- If set, the activity of the signal is required by the user. Has_Active : Boolean; -- Internal fields. -- NOTE: keep above fields (components) in sync with translation. -- If set, the signal has an active direct driver. Is_Direct_Active : Boolean; -- Kind of the signal (none, bus or register). Sig_Kind : Kind_Signal_Type; -- Values mode of this signal. Mode : Mode_Type; -- Misc flags. Flags : Ghdl_Signal_Flags; -- Net of the signal. Net : Signal_Net_Type; -- Chain of signals that will be active in the next delta-cycle. -- (Also used to build nets). Link : Ghdl_Signal_Ptr; -- Chain of signals whose active flag was set. Used to clear the active -- flag at the end of the delta cycle. Alink : Ghdl_Signal_Ptr; -- Chain of signals that have a projected waveform in the real future. Flink : Ghdl_Signal_Ptr; -- List of processes to resume when there is an event on -- this signal. Event_List : Action_List_Acc; -- Path of the signal (with its name) in the design hierarchy. -- Used to get the type of the signal. Rti : Ghdl_Rtin_Object_Acc; -- For user signals: the sources of a signals are drivers -- and connected ports. -- For implicit signals: PORTS is used as dependence list. Nbr_Ports : Ghdl_Index_Type; Ports : Signal_Arr_Ptr; -- Mode of the signal (in, out ...) --Mode_Signal : Mode_Signal_Type; S : Ghdl_Signal_Data; end record; -- Each simple signal declared can be accessed by SIG_TABLE. package Sig_Table is new Grt.Table (Table_Component_Type => Ghdl_Signal_Ptr, Table_Index_Type => Sig_Table_Index, Table_Low_Bound => 0, Table_Initial => 128); -- Return the next time at which a driver becomes active. function Find_Next_Time return Std_Time; -- Elementary propagation computation. -- See LRM 12.6.2 and 12.6.3 type Propagation_Kind_Type is ( -- How to compute driving value: -- Default value. Drv_Error, -- One source, a driver and not resolved: -- the driving value is the driver. Drv_One_Driver, -- Same as previous, and the effective value is the driving value. Eff_One_Driver, -- One source, a port and not resolved: -- the driving value is the driving value of the port. -- Dependence. Drv_One_Port, -- Same as previous, and the effective value is the driving value. Eff_One_Port, -- Several sources or resolved: -- signal is not composite. Drv_One_Resolved, Eff_One_Resolved, -- Use the resolution function, signal is composite. Drv_Multiple, -- Same as previous, but the effective value is the previous value. Eff_Multiple, -- The effective value is the actual associated. Eff_Actual, -- Sig must be updated but does not belong to the same net. Imp_Forward, Imp_Forward_Build, -- Implicit guard signal. -- Its value must be evaluated after the effective value of its -- dependences. Imp_Guard, -- Implicit stable. -- Its value must be evaluated after the effective value of its -- dependences. Imp_Stable, -- Implicit quiet. -- Its value must be evaluated after the driving value of its -- dependences. Imp_Quiet, -- Implicit transaction. -- Its value must be evaluated after the driving value of its -- dependences. Imp_Transaction, -- Implicit delayed -- Its value must be evaluated after the driving value of its -- dependences. Imp_Delayed, -- in_conversion. -- Pseudo-signal which is set by conversion function. In_Conversion, Out_Conversion, -- End of propagation. Prop_End ); type Propagation_Type (Kind : Propagation_Kind_Type := Drv_Error) is record case Kind is when Drv_Error => null; when Drv_One_Driver | Eff_One_Driver | Drv_One_Port | Eff_One_Port | Imp_Forward | Imp_Guard | Imp_Quiet | Imp_Transaction | Imp_Stable | Imp_Delayed | Eff_Actual | Eff_One_Resolved | Drv_One_Resolved => Sig : Ghdl_Signal_Ptr; when Drv_Multiple | Eff_Multiple => Resolv : Resolved_Signal_Acc; when In_Conversion | Out_Conversion => Conv : Sig_Conversion_Acc; when Imp_Forward_Build => Forward : Forward_Build_Acc; when Prop_End => Updated : Boolean; end case; end record; package Propagation is new Grt.Table (Table_Component_Type => Propagation_Type, Table_Index_Type => Signal_Net_Type, Table_Low_Bound => 1, Table_Initial => 128); -- Get the signal index of PTR. function Signal_Ptr_To_Index (Ptr : Ghdl_Signal_Ptr) return Sig_Table_Index; -- Compute propagation order of signals. procedure Order_All_Signals; -- Initialize the package (mainly the lists). procedure Init; -- Initialize all signals. procedure Init_Signals; -- Update signals. procedure Update_Signals; -- Set the effective value of signal SIG to VAL. -- If the value is different from the previous one, resume processes. procedure Set_Effective_Value (Sig : Ghdl_Signal_Ptr; Val : Value_Union); -- Add PROC in the list of processes to be resumed in case of event on -- SIG. procedure Resume_Process_If_Event (Sig : Ghdl_Signal_Ptr; Proc : Process_Acc); -- Creating a signal: -- 1a) call Ghdl_Signal_Name_Rti (CTXT and ADDR are unused) to register -- the RTI for the whole signal (in particular the mode and the -- has_active flag) -- or -- 1b) call Ghdl_Signal_Set_Mode to register the mode and the has_active -- flag. In that case, the signal has no name. -- -- 2) call Ghdl_Create_Signal_XXX for each non-composite element procedure Ghdl_Signal_Name_Rti (Sig : Ghdl_Rti_Access; Ctxt : Ghdl_Rti_Access; Addr : System.Address); procedure Ghdl_Signal_Set_Mode (Mode : Mode_Signal_Type; Kind : Kind_Signal_Type; Has_Active : Boolean); -- FIXME: document. -- Merge RTI with SIG: adjust the has_active flag of SIG according to RTI. procedure Ghdl_Signal_Merge_Rti (Sig : Ghdl_Signal_Ptr; Rti : Ghdl_Rti_Access); -- Assigning a waveform to a signal: -- -- For simple waveform (sig <= val), the short form can be used: -- Ghdl_Signal_Simple_Assign_XX (Sig, Val); -- For all other forms -- SIG <= reject R inertial V1 after T1, V2 after T2, ...: -- Ghdl_Signal_Start_Assign_XX (SIG, R, V1, T1); -- Ghdl_Signal_Next_Assign_XX (SIG, V2, T2); -- ... -- If the delay mechanism is transport, they R = 0, -- if there is no rejection time, the mechanism is internal and R = T1. -- Performs some internal checks on signals (transaction order). -- Internal_error is called in case of error. procedure Ghdl_Signal_Internal_Checks; procedure Ghdl_Signal_Simple_Assign_Error (Sign : Ghdl_Signal_Ptr; File : Ghdl_C_String; Line : Ghdl_I32); procedure Ghdl_Signal_Start_Assign_Error (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; After : Std_Time; File : Ghdl_C_String; Line : Ghdl_I32); procedure Ghdl_Signal_Next_Assign_Error (Sign : Ghdl_Signal_Ptr; After : Std_Time; File : Ghdl_C_String; Line : Ghdl_I32); procedure Ghdl_Signal_Direct_Assign (Sign : Ghdl_Signal_Ptr); procedure Ghdl_Signal_Set_Disconnect (Sign : Ghdl_Signal_Ptr; Time : Std_Time); procedure Ghdl_Signal_Disconnect (Sign : Ghdl_Signal_Ptr); procedure Ghdl_Signal_Start_Assign_Null (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; After : Std_Time); function Ghdl_Signal_Driving (Sig : Ghdl_Signal_Ptr) return Ghdl_B2; function Ghdl_Create_Signal_B2 (Init_Val : Ghdl_B2; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_B2 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_B2); procedure Ghdl_Signal_Associate_B2 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_B2); procedure Ghdl_Signal_Simple_Assign_B2 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_B2); procedure Ghdl_Signal_Start_Assign_B2 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_B2; After : Std_Time); procedure Ghdl_Signal_Next_Assign_B2 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_B2; After : Std_Time); function Ghdl_Signal_Driving_Value_B2 (Sig : Ghdl_Signal_Ptr) return Ghdl_B2; function Ghdl_Create_Signal_E8 (Init_Val : Ghdl_E8; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_E8 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_E8); procedure Ghdl_Signal_Associate_E8 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_E8); procedure Ghdl_Signal_Simple_Assign_E8 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_E8); procedure Ghdl_Signal_Start_Assign_E8 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_E8; After : Std_Time); procedure Ghdl_Signal_Next_Assign_E8 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_E8; After : Std_Time); function Ghdl_Signal_Driving_Value_E8 (Sig : Ghdl_Signal_Ptr) return Ghdl_E8; function Ghdl_Create_Signal_E32 (Init_Val : Ghdl_E32; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_E32 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_E32); procedure Ghdl_Signal_Associate_E32 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_E32); procedure Ghdl_Signal_Simple_Assign_E32 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_E32); procedure Ghdl_Signal_Start_Assign_E32 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_E32; After : Std_Time); procedure Ghdl_Signal_Next_Assign_E32 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_E32; After : Std_Time); function Ghdl_Signal_Driving_Value_E32 (Sig : Ghdl_Signal_Ptr) return Ghdl_E32; function Ghdl_Create_Signal_I32 (Init_Val : Ghdl_I32; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_I32 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_I32); procedure Ghdl_Signal_Associate_I32 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_I32); procedure Ghdl_Signal_Simple_Assign_I32 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_I32); procedure Ghdl_Signal_Start_Assign_I32 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_I32; After : Std_Time); procedure Ghdl_Signal_Next_Assign_I32 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_I32; After : Std_Time); function Ghdl_Signal_Driving_Value_I32 (Sig : Ghdl_Signal_Ptr) return Ghdl_I32; function Ghdl_Create_Signal_I64 (Init_Val : Ghdl_I64; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_I64 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_I64); procedure Ghdl_Signal_Associate_I64 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_I64); procedure Ghdl_Signal_Simple_Assign_I64 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_I64); procedure Ghdl_Signal_Start_Assign_I64 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_I64; After : Std_Time); procedure Ghdl_Signal_Next_Assign_I64 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_I64; After : Std_Time); function Ghdl_Signal_Driving_Value_I64 (Sig : Ghdl_Signal_Ptr) return Ghdl_I64; function Ghdl_Create_Signal_F64 (Init_Val : Ghdl_F64; Resolv_Func : Resolver_Acc; Resolv_Inst : System.Address) return Ghdl_Signal_Ptr; procedure Ghdl_Signal_Init_F64 (Sig : Ghdl_Signal_Ptr; Init_Val : Ghdl_F64); procedure Ghdl_Signal_Associate_F64 (Sig : Ghdl_Signal_Ptr; Val : Ghdl_F64); procedure Ghdl_Signal_Simple_Assign_F64 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_F64); procedure Ghdl_Signal_Start_Assign_F64 (Sign : Ghdl_Signal_Ptr; Rej : Std_Time; Val : Ghdl_F64; After : Std_Time); procedure Ghdl_Signal_Next_Assign_F64 (Sign : Ghdl_Signal_Ptr; Val : Ghdl_F64; After : Std_Time); function Ghdl_Signal_Driving_Value_F64 (Sig : Ghdl_Signal_Ptr) return Ghdl_F64; -- Add a driver to SIGN for the current process. procedure Ghdl_Process_Add_Driver (Sign : Ghdl_Signal_Ptr); -- Add a direct driver for the current process. This is an optimization -- that could be used when a driver has no projected waveforms. -- -- Assignment using direct driver: -- * the driver value is set -- * put the signal on the ghdl_signal_active_chain, if the signal will -- be active and if not already on the chain. procedure Ghdl_Signal_Add_Direct_Driver (Sign : Ghdl_Signal_Ptr; Drv : Ghdl_Value_Ptr); -- Used for connexions: -- SRC is a source for TARG. procedure Ghdl_Signal_Add_Source (Targ : Ghdl_Signal_Ptr; Src : Ghdl_Signal_Ptr); -- The effective value of TARG is the effective value of SRC. procedure Ghdl_Signal_Effective_Value (Targ : Ghdl_Signal_Ptr; Src : Ghdl_Signal_Ptr); -- Conversions. In order to do conversion from A to B, an intermediate -- signal T must be created. The flow is A -> T -> B. -- The link from A -> T is a conversion, added by one of the two -- following procedures. The type of A and T is different. -- The link from T -> B is a normal connection: either an effective -- one (for in conversion) or a source (for out conversion). -- Add an in conversion (from SRC to DEST using function FUNC). -- The effective value can be read and writen directly. procedure Ghdl_Signal_In_Conversion (Func : System.Address; Instance : System.Address; Src : Ghdl_Signal_Ptr; Src_Len : Ghdl_Index_Type; Dst : Ghdl_Signal_Ptr; Dst_Len : Ghdl_Index_Type); -- Add an out conversion. -- The driving value can be read and writen directly. procedure Ghdl_Signal_Out_Conversion (Func : System.Address; Instance : System.Address; Src : Ghdl_Signal_Ptr; Src_Len : Ghdl_Index_Type; Dst : Ghdl_Signal_Ptr; Dst_Len : Ghdl_Index_Type); -- Mark the next (and not yet created) NBR_SIG signals as resolved. procedure Ghdl_Signal_Create_Resolution (Proc : Resolver_Acc; Instance : System.Address; Sig : System.Address; Nbr_Sig : Ghdl_Index_Type); -- Create a new 'stable (VAL) signal. The prefixes are set by -- ghdl_signal_attribute_register_prefix. function Ghdl_Create_Stable_Signal (Val : Std_Time) return Ghdl_Signal_Ptr; -- Create a new 'quiet (VAL) signal. The prefixes are set by -- ghdl_signal_attribute_register_prefix. function Ghdl_Create_Quiet_Signal (Val : Std_Time) return Ghdl_Signal_Ptr; -- Create a new 'transaction signal. The prefixes are set by -- ghdl_signal_attribute_register_prefix. function Ghdl_Create_Transaction_Signal return Ghdl_Signal_Ptr; -- Create a new SIG'delayed (VAL) signal. function Ghdl_Create_Delayed_Signal (Sig : Ghdl_Signal_Ptr; Val : Std_Time) return Ghdl_Signal_Ptr; -- Add SIG in the set of prefix for the last created signal. procedure Ghdl_Signal_Attribute_Register_Prefix (Sig : Ghdl_Signal_Ptr); -- Create a new implicitly defined GUARD signal. function Ghdl_Signal_Create_Guard (This : System.Address; Proc : Guard_Func_Acc) return Ghdl_Signal_Ptr; -- Add SIG to the list of referenced signals that appear in the guard -- expression. procedure Ghdl_Signal_Guard_Dependence (Sig : Ghdl_Signal_Ptr); -- Return number of ports/drivers. function Ghdl_Signal_Get_Nbr_Ports (Sig : Ghdl_Signal_Ptr) return Ghdl_Index_Type; function Ghdl_Signal_Get_Nbr_Drivers (Sig : Ghdl_Signal_Ptr) return Ghdl_Index_Type; -- Read a source (port or driver) from a signal. This is used by -- resolution functions. function Ghdl_Signal_Read_Port (Sig : Ghdl_Signal_Ptr; Index : Ghdl_Index_Type) return Ghdl_Value_Ptr; function Ghdl_Signal_Read_Driver (Sig : Ghdl_Signal_Ptr; Index : Ghdl_Index_Type) return Ghdl_Value_Ptr; Ghdl_Signal_Active_Chain : aliased Ghdl_Signal_Ptr; -- Statistics. Nbr_Active : Ghdl_I32; Nbr_Events: Ghdl_I32; function Get_Nbr_Future return Ghdl_I32; private pragma Export (C, Ghdl_Signal_Name_Rti, "__ghdl_signal_name_rti"); pragma Export (C, Ghdl_Signal_Merge_Rti, "__ghdl_signal_merge_rti"); pragma Export (C, Ghdl_Signal_Simple_Assign_Error, "__ghdl_signal_simple_assign_error"); pragma Export (C, Ghdl_Signal_Start_Assign_Error, "__ghdl_signal_start_assign_error"); pragma Export (C, Ghdl_Signal_Next_Assign_Error, "__ghdl_signal_next_assign_error"); pragma Export (C, Ghdl_Signal_Start_Assign_Null, "__ghdl_signal_start_assign_null"); pragma Export (C, Ghdl_Signal_Direct_Assign, "__ghdl_signal_direct_assign"); pragma Export (C, Ghdl_Signal_Set_Disconnect, "__ghdl_signal_set_disconnect"); pragma Export (C, Ghdl_Signal_Disconnect, "__ghdl_signal_disconnect"); pragma Export (Ada, Ghdl_Signal_Driving, "__ghdl_signal_driving"); pragma Export (Ada, Ghdl_Create_Signal_B2, "__ghdl_create_signal_b2"); pragma Export (Ada, Ghdl_Signal_Init_B2, "__ghdl_signal_init_b2"); pragma Export (Ada, Ghdl_Signal_Associate_B2, "__ghdl_signal_associate_b2"); pragma Export (Ada, Ghdl_Signal_Simple_Assign_B2, "__ghdl_signal_simple_assign_b2"); pragma Export (Ada, Ghdl_Signal_Start_Assign_B2, "__ghdl_signal_start_assign_b2"); pragma Export (Ada, Ghdl_Signal_Next_Assign_B2, "__ghdl_signal_next_assign_b2"); pragma Export (Ada, Ghdl_Signal_Driving_Value_B2, "__ghdl_signal_driving_value_b2"); pragma Export (C, Ghdl_Create_Signal_E8, "__ghdl_create_signal_e8"); pragma Export (C, Ghdl_Signal_Init_E8, "__ghdl_signal_init_e8"); pragma Export (C, Ghdl_Signal_Associate_E8, "__ghdl_signal_associate_e8"); pragma Export (C, Ghdl_Signal_Simple_Assign_E8, "__ghdl_signal_simple_assign_e8"); pragma Export (C, Ghdl_Signal_Start_Assign_E8, "__ghdl_signal_start_assign_e8"); pragma Export (C, Ghdl_Signal_Next_Assign_E8, "__ghdl_signal_next_assign_e8"); pragma Export (C, Ghdl_Signal_Driving_Value_E8, "__ghdl_signal_driving_value_e8"); pragma Export (C, Ghdl_Create_Signal_E32, "__ghdl_create_signal_e32"); pragma Export (C, Ghdl_Signal_Init_E32, "__ghdl_signal_init_e32"); pragma Export (C, Ghdl_Signal_Associate_E32, "__ghdl_signal_associate_e32"); pragma Export (C, Ghdl_Signal_Simple_Assign_E32, "__ghdl_signal_simple_assign_e32"); pragma Export (C, Ghdl_Signal_Start_Assign_E32, "__ghdl_signal_start_assign_e32"); pragma Export (C, Ghdl_Signal_Next_Assign_E32, "__ghdl_signal_next_assign_e32"); pragma Export (C, Ghdl_Signal_Driving_Value_E32, "__ghdl_signal_driving_value_e32"); pragma Export (C, Ghdl_Create_Signal_I32, "__ghdl_create_signal_i32"); pragma Export (C, Ghdl_Signal_Init_I32, "__ghdl_signal_init_i32"); pragma Export (C, Ghdl_Signal_Associate_I32, "__ghdl_signal_associate_i32"); pragma Export (C, Ghdl_Signal_Simple_Assign_I32, "__ghdl_signal_simple_assign_i32"); pragma Export (C, Ghdl_Signal_Start_Assign_I32, "__ghdl_signal_start_assign_i32"); pragma Export (C, Ghdl_Signal_Next_Assign_I32, "__ghdl_signal_next_assign_i32"); pragma Export (C, Ghdl_Signal_Driving_Value_I32, "__ghdl_signal_driving_value_i32"); pragma Export (C, Ghdl_Create_Signal_I64, "__ghdl_create_signal_i64"); pragma Export (C, Ghdl_Signal_Init_I64, "__ghdl_signal_init_i64"); pragma Export (C, Ghdl_Signal_Associate_I64, "__ghdl_signal_associate_i64"); pragma Export (C, Ghdl_Signal_Simple_Assign_I64, "__ghdl_signal_simple_assign_i64"); pragma Export (C, Ghdl_Signal_Start_Assign_I64, "__ghdl_signal_start_assign_i64"); pragma Export (C, Ghdl_Signal_Next_Assign_I64, "__ghdl_signal_next_assign_i64"); pragma Export (C, Ghdl_Signal_Driving_Value_I64, "__ghdl_signal_driving_value_i64"); pragma Export (C, Ghdl_Create_Signal_F64, "__ghdl_create_signal_f64"); pragma Export (C, Ghdl_Signal_Init_F64, "__ghdl_signal_init_f64"); pragma Export (C, Ghdl_Signal_Associate_F64, "__ghdl_signal_associate_f64"); pragma Export (C, Ghdl_Signal_Simple_Assign_F64, "__ghdl_signal_simple_assign_f64"); pragma Export (C, Ghdl_Signal_Start_Assign_F64, "__ghdl_signal_start_assign_f64"); pragma Export (C, Ghdl_Signal_Next_Assign_F64, "__ghdl_signal_next_assign_f64"); pragma Export (C, Ghdl_Signal_Driving_Value_F64, "__ghdl_signal_driving_value_f64"); pragma Export (C, Ghdl_Process_Add_Driver, "__ghdl_process_add_driver"); pragma Export (C, Ghdl_Signal_Add_Direct_Driver, "__ghdl_signal_add_direct_driver"); pragma Export (C, Ghdl_Signal_Add_Source, "__ghdl_signal_add_source"); pragma Export (C, Ghdl_Signal_Effective_Value, "__ghdl_signal_effective_value"); pragma Export (C, Ghdl_Signal_In_Conversion, "__ghdl_signal_in_conversion"); pragma Export (C, Ghdl_Signal_Out_Conversion, "__ghdl_signal_out_conversion"); pragma Export (C, Ghdl_Signal_Create_Resolution, "__ghdl_signal_create_resolution"); pragma Export (C, Ghdl_Create_Stable_Signal, "__ghdl_create_stable_signal"); pragma Export (C, Ghdl_Create_Quiet_Signal, "__ghdl_create_quiet_signal"); pragma Export (C, Ghdl_Create_Transaction_Signal, "__ghdl_create_transaction_signal"); pragma Export (C, Ghdl_Signal_Attribute_Register_Prefix, "__ghdl_signal_attribute_register_prefix"); pragma Export (C, Ghdl_Create_Delayed_Signal, "__ghdl_create_delayed_signal"); pragma Export (Ada, Ghdl_Signal_Create_Guard, "__ghdl_signal_create_guard"); pragma Export (C, Ghdl_Signal_Guard_Dependence, "__ghdl_signal_guard_dependence"); pragma Export (C, Ghdl_Signal_Get_Nbr_Ports, "__ghdl_signal_get_nbr_ports"); pragma Export (C, Ghdl_Signal_Get_Nbr_Drivers, "__ghdl_signal_get_nbr_drivers"); pragma Export (C, Ghdl_Signal_Read_Port, "__ghdl_signal_read_port"); pragma Export (C, Ghdl_Signal_Read_Driver, "__ghdl_signal_read_driver"); pragma Export (C, Ghdl_Signal_Active_Chain, "__ghdl_signal_active_chain"); end Grt.Signals;