#ifndef IVL_vvp_net_sig_H #define IVL_vvp_net_sig_H /* * Copyright (c) 2004-2025 Stephen Williams (steve@icarus.com) * * This source code is free software; you can redistribute it * and/or modify it in source code form 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ # include "config.h" # include "vpi_user.h" # include "vvp_net.h" # include "vvp_object.h" # include # include # include # include # include # include #ifdef HAVE_IOSFWD # include #else # include #endif /* vvp_fun_signal * This node is the place holder in a vvp network for signals, * including nets of various sort. The output from a signal follows * the type of its port-0 input. If vvp_vector4_t values come in * through port-0, then vvp_vector4_t values are propagated. If * vvp_vector8_t values come in through port-0, then vvp_vector8_t * values are propagated. Thus, this node is slightly polymorphic. * * If the signal is a net (i.e. a wire or tri) then this node will * have an input that is the data source. The data source will connect * through port-0. * * If the signal is a reg, then there will be no netlist input, the * values will be written by behavioral statements. The %set and * %assign statements will write through port-0. * * In any case, behavioral code is able to read the value that this * node last propagated, by using the value() method. That is important * functionality of this node. * * Continuous assignments are made through port-1. When a value is * written here, continuous assign mode is activated, and input * through port-0 is ignored until continuous assign mode is turned * off again. Writing into this port can be done in behavioral code * using the %cassign/v instruction, or can be done by the network by * hooking the output of a vvp_net_t to this port. */ class vvp_fun_signal_base : public vvp_net_fun_t { public: vvp_fun_signal_base(); void deassign(); void deassign_pv(unsigned base, unsigned wid); public: /* The %cassign/link instruction needs a place to write the source node of the force, so that subsequent %cassign and %deassign instructions can undo the link as needed. */ class vvp_net_t*cassign_link; protected: bool continuous_assign_active_; vvp_vector2_t assign_mask_; protected: // This is true until at least one propagation happens. bool needs_init_; }; /* * Variables and wires can have their values accessed, so this base * class offers the unified concept of an accessible value. */ class vvp_signal_value { public: virtual ~vvp_signal_value() =0; virtual unsigned value_size() const =0; virtual vvp_bit4_t value(unsigned idx) const =0; virtual vvp_scalar_t scalar_value(unsigned idx) const =0; virtual void vec4_value(vvp_vector4_t&) const =0; virtual double real_value() const; virtual void get_signal_value(struct t_vpi_value*vp); }; /* * This abstract class is a little more specific than the signal_base * class, in that it adds vector access methods. */ class vvp_fun_signal_vec : public vvp_fun_signal_base { public: virtual const vvp_vector4_t& vec4_unfiltered_value() const =0; }; class automatic_signal_base : public vvp_signal_value, public vvp_net_fil_t { public: // Automatic variables cannot be forced or released. Provide // stubs that assert. virtual void release(vvp_net_ptr_t ptr, bool net_flag) override; virtual void release_pv(vvp_net_ptr_t ptr, unsigned base, unsigned wid, bool net_flag) override; virtual unsigned filter_size() const override; virtual void force_fil_vec4(const vvp_vector4_t&val, const vvp_vector2_t&mask) override; virtual void force_fil_vec8(const vvp_vector8_t&val, const vvp_vector2_t&mask) override; virtual void force_fil_real(double val, const vvp_vector2_t&mask) override; virtual void get_value(struct t_vpi_value*value) override; }; /* * Statically allocated vvp_fun_signal4. */ class vvp_fun_signal4_sa : public vvp_fun_signal_vec { public: explicit vvp_fun_signal4_sa(unsigned wid, vvp_bit4_t init=BIT4_X); void recv_vec4(vvp_net_ptr_t port, const vvp_vector4_t&bit, vvp_context_t) override; void recv_vec8(vvp_net_ptr_t port, const vvp_vector8_t&bit) override; // Part select variants of above void recv_vec4_pv(vvp_net_ptr_t port, const vvp_vector4_t&bit, unsigned base, unsigned vwid, vvp_context_t) override; void recv_vec8_pv(vvp_net_ptr_t port, const vvp_vector8_t&bit, unsigned base, unsigned vwid) override; // Get information about the vector value. const vvp_vector4_t& vec4_unfiltered_value() const override; private: vvp_vector4_t bits4_; }; /* * Automatically allocated vvp_fun_signal4. */ class vvp_fun_signal4_aa : public vvp_fun_signal_vec, public automatic_signal_base, public automatic_hooks_s { public: explicit vvp_fun_signal4_aa(unsigned wid, vvp_bit4_t init=BIT4_X); ~vvp_fun_signal4_aa(); void alloc_instance(vvp_context_t context) override; void reset_instance(vvp_context_t context) override; #ifdef CHECK_WITH_VALGRIND void free_instance(vvp_context_t context) override; #endif void recv_vec4(vvp_net_ptr_t port, const vvp_vector4_t&bit, vvp_context_t context) override; // Part select variants of above void recv_vec4_pv(vvp_net_ptr_t port, const vvp_vector4_t&bit, unsigned base, unsigned vwid, vvp_context_t) override; // Get information about the vector value. unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; const vvp_vector4_t& vec4_unfiltered_value() const override; public: // These objects are only permallocated. static void* operator new(std::size_t size) { return vvp_net_fun_t::heap_.alloc(size); } static void operator delete(void*obj); private: unsigned context_idx_; unsigned size_; vvp_bit4_t init_; }; class vvp_fun_signal_real : public vvp_fun_signal_base { public: explicit vvp_fun_signal_real() {}; // Get information about the vector value. virtual double real_unfiltered_value() const = 0; }; /* * Statically allocated vvp_fun_signal_real. */ class vvp_fun_signal_real_sa : public vvp_fun_signal_real { public: explicit vvp_fun_signal_real_sa(); void recv_real(vvp_net_ptr_t port, double bit, vvp_context_t) override; // Get information about the vector value. double real_unfiltered_value() const override; private: double bits_; }; /* * Automatically allocated vvp_fun_signal_real. */ class vvp_fun_signal_real_aa : public vvp_fun_signal_real, public automatic_signal_base, public automatic_hooks_s { public: explicit vvp_fun_signal_real_aa(); ~vvp_fun_signal_real_aa(); void alloc_instance(vvp_context_t context) override; void reset_instance(vvp_context_t context) override; #ifdef CHECK_WITH_VALGRIND void free_instance(vvp_context_t context) override; #endif void recv_real(vvp_net_ptr_t port, double bit, vvp_context_t context) override; // Get information about the vector value. double real_unfiltered_value() const override; // Get information about the vector value. unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; double real_value() const override; void get_signal_value(struct t_vpi_value*vp) override; public: // These objects are only permallocated. static void* operator new(std::size_t size); static void operator delete(void*obj); private: unsigned context_idx_; }; class vvp_fun_signal_string : public vvp_fun_signal_base { public: explicit vvp_fun_signal_string() {}; virtual const std::string& get_string() const =0; protected: std::string value_; }; /* * Statically allocated vvp_fun_signal_string. */ class vvp_fun_signal_string_sa : public vvp_fun_signal_string { public: explicit vvp_fun_signal_string_sa(); void recv_string(vvp_net_ptr_t port, const std::string&bit, vvp_context_t context) override; const std::string& get_string() const override; private: std::string value_; }; /* * Automatically allocated vvp_fun_signal_real. */ class vvp_fun_signal_string_aa : public vvp_fun_signal_string, public automatic_signal_base, public automatic_hooks_s { public: explicit vvp_fun_signal_string_aa(); ~vvp_fun_signal_string_aa(); void alloc_instance(vvp_context_t context) override; void reset_instance(vvp_context_t context) override; #ifdef CHECK_WITH_VALGRIND void free_instance(vvp_context_t context) override; #endif void recv_string(vvp_net_ptr_t port, const std::string&bit, vvp_context_t context) override; // Get information about the vector value. unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; double real_value() const override; const std::string& get_string() const override; void get_signal_value(struct t_vpi_value*vp) override; public: // These objects are only permallocated. static void* operator new(std::size_t size); static void operator delete(void*obj); private: unsigned context_idx_; }; class vvp_fun_signal_object : public vvp_fun_signal_base { public: explicit vvp_fun_signal_object(unsigned size) { size_ = size; }; unsigned size() const { return size_; } virtual vvp_object_t get_object() const =0; private: unsigned size_; }; /* * Statically allocated vvp_fun_signal_string. */ class vvp_fun_signal_object_sa : public vvp_fun_signal_object { public: explicit vvp_fun_signal_object_sa(unsigned size); void recv_object(vvp_net_ptr_t port, vvp_object_t bit, vvp_context_t context) override; vvp_object_t get_object() const override; private: vvp_object_t value_; }; /* * Automatically allocated vvp_fun_signal_real. */ class vvp_fun_signal_object_aa : public vvp_fun_signal_object, public automatic_signal_base, public automatic_hooks_s { public: explicit vvp_fun_signal_object_aa(unsigned size); ~vvp_fun_signal_object_aa(); void alloc_instance(vvp_context_t context) override; void reset_instance(vvp_context_t context) override; #ifdef CHECK_WITH_VALGRIND void free_instance(vvp_context_t context) override; #endif void recv_object(vvp_net_ptr_t port, vvp_object_t bit, vvp_context_t context) override; // Get information about the vector value. unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; //double real_value() const; //void get_signal_value(struct t_vpi_value*vp); vvp_object_t get_object() const override; public: // These objects are only permallocated. static void* operator new(std::size_t size); static void operator delete(void*obj); private: unsigned context_idx_; }; /* vvp_wire * The vvp_wire is different from vvp_variable objects in that it * exists only as a filter. The vvp_wire class tree is for * implementing Verilog wires/nets (as opposed to regs/variables). * * vvp_vpi_callback * | * | * vvp_net_fil_t vvp_signal_value * | | * \ / * \ / * \ / * vvp_wire_base */ class vvp_wire_base : public vvp_net_fil_t, public vvp_signal_value { public: vvp_wire_base(); ~vvp_wire_base(); // Support for $countdrivers virtual vvp_bit4_t driven_value(unsigned idx) const; virtual bool is_forced(unsigned idx) const; }; class vvp_wire_vec4 : public vvp_wire_base { public: vvp_wire_vec4(unsigned wid, vvp_bit4_t init); // The main filter behavior for this class. These methods take // the value that the node is driven to, and applies the force // filters. In wires, this also saves the driven value, so // that when a force is released, we can revert to the driven value. prop_t filter_vec4(const vvp_vector4_t&bit, vvp_vector4_t&rep, unsigned base, unsigned vwid) override; prop_t filter_vec8(const vvp_vector8_t&val, vvp_vector8_t&rep, unsigned base, unsigned vwid) override; // Abstract methods from vvp_vpi_callback void get_value(struct t_vpi_value*value) override; // Abstract methods from vvp_net_fit_t unsigned filter_size() const override; void force_fil_vec4(const vvp_vector4_t&val, const vvp_vector2_t&mask) override; void force_fil_vec8(const vvp_vector8_t&val, const vvp_vector2_t&mask) override; void force_fil_real(double val, const vvp_vector2_t&mask) override; void release(vvp_net_ptr_t ptr, bool net_flag) override; void release_pv(vvp_net_ptr_t ptr, unsigned base, unsigned wid, bool net_flag) override; // Implementation of vvp_signal_value methods unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; // Support for $countdrivers vvp_bit4_t driven_value(unsigned idx) const override; bool is_forced(unsigned idx) const override; private: vvp_bit4_t filtered_value_(unsigned idx) const; private: bool needs_init_; vvp_vector4_t bits4_; // The tracked driven value vvp_vector4_t force4_; // the value being forced }; class vvp_wire_vec8 : public vvp_wire_base { public: explicit vvp_wire_vec8(unsigned wid); // The main filter behavior for this class prop_t filter_vec4(const vvp_vector4_t&bit, vvp_vector4_t&rep, unsigned base, unsigned vwid) override; prop_t filter_vec8(const vvp_vector8_t&val, vvp_vector8_t&rep, unsigned base, unsigned vwid) override; // island ports use this method to filter arbitrary values // through the force filter. prop_t filter_input_vec8(const vvp_vector8_t&val, vvp_vector8_t&rep) const; // Abstract methods from vvp_vpi_callback void get_value(struct t_vpi_value*value) override; // Abstract methods from vvp_net_fit_t unsigned filter_size() const override; void force_fil_vec4(const vvp_vector4_t&val, const vvp_vector2_t&mask) override; void force_fil_vec8(const vvp_vector8_t&val, const vvp_vector2_t&mask) override; void force_fil_real(double val, const vvp_vector2_t&mask) override; void release(vvp_net_ptr_t ptr, bool net_flag) override; void release_pv(vvp_net_ptr_t ptr, unsigned base, unsigned wid, bool net_flag) override; // Implementation of vvp_signal_value methods unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; // This is new to vvp_wire_vec8 vvp_vector8_t vec8_value() const; // Support for $countdrivers vvp_bit4_t driven_value(unsigned idx) const override; bool is_forced(unsigned idx) const override; private: vvp_scalar_t filtered_value_(unsigned idx) const; private: bool needs_init_; vvp_vector8_t bits8_; vvp_vector8_t force8_; // the value being forced }; class vvp_wire_real : public vvp_wire_base { public: explicit vvp_wire_real(void); // The main filter behavior for this class prop_t filter_real(double&bit) override; // Abstract methods from vvp_vpi_callback void get_value(struct t_vpi_value*value) override; // Abstract methods from vvp_net_fit_t unsigned filter_size() const override; void force_fil_vec4(const vvp_vector4_t&val, const vvp_vector2_t&mask) override; void force_fil_vec8(const vvp_vector8_t&val, const vvp_vector2_t&mask) override; void force_fil_real(double val, const vvp_vector2_t&mask) override; void release(vvp_net_ptr_t ptr, bool net_flag) override; void release_pv(vvp_net_ptr_t ptr, unsigned base, unsigned wid, bool net_flag) override; // Implementation of vvp_signal_value methods unsigned value_size() const override; vvp_bit4_t value(unsigned idx) const override; vvp_scalar_t scalar_value(unsigned idx) const override; void vec4_value(vvp_vector4_t&) const override; double real_value() const override; void get_signal_value(struct t_vpi_value*vp) override; private: double bit_; double force_; }; #if 0 class vvp_wire_string : public vvp_wire_base { public: explicit vvp_wire_string(void); // Abstract methods from vvp_vpi_callback void get_value(struct t_vpi_value*value); // Abstract methods from vvp_net_fil_t unsigned filter_size() const; void force_fil_vec4(const vvp_vector4_t&val, const vvp_vector2_t&mask); void force_fil_vec8(const vvp_vector8_t&val, const vvp_vector2_t&mask); void force_fil_real(double val, const vvp_vector2_t&mask); void release(vvp_net_ptr_t ptr, bool net_flag); void release_pv(vvp_net_ptr_t ptr, unsigned base, unsigned wid, bool net_flag); // Implementation of vvp_signal_value methods unsigned value_size() const; vvp_bit4_t value(unsigned idx) const; vvp_scalar_t scalar_value(unsigned idx) const; void vec4_value(vvp_vector4_t&) const; double real_value() const; void get_signal_value(struct t_vpi_value*vp); private: std::string value_; }; #endif #endif /* IVL_vvp_net_sig_H */