passes/equiv/equiv_make.cc - third_party/yosys - Git at Google

 /*
  *  yosys -- Yosys Open SYnthesis Suite
  *
  *  Copyright (C) 2012  Clifford Wolf <clifford@clifford.at>
  *
  *  Permission to use, copy, modify, and/or distribute this software for any
  *  purpose with or without fee is hereby granted, provided that the above
  *  copyright notice and this permission notice appear in all copies.
  *
  *  THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
  *  WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
  *  MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
  *  ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
  *  WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
  *  ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
  *  OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
  *
  */

 #include "kernel/yosys.h"
 #include "kernel/sigtools.h"
 #include "kernel/celltypes.h"

 USING_YOSYS_NAMESPACE
 PRIVATE_NAMESPACE_BEGIN

 struct EquivMakeWorker
 {
 	Module *gold_mod, *gate_mod, *equiv_mod;
 	pool<IdString> wire_names, cell_names;
 	CellTypes ct;

 	bool inames;
 	vector<string> blacklists;
 	vector<string> encfiles;

 	pool<IdString> blacklist_names;
 	dict<IdString, dict<Const, Const>> encdata;

 	pool<SigBit> undriven_bits;
 	SigMap assign_map;

 	dict<SigBit, pool<Cell*>> bit2driven; // map: bit <--> and its driven cells

 	CellTypes comb_ct;

 	EquivMakeWorker()
 	{
 		comb_ct.setup_internals();
 		comb_ct.setup_stdcells();
 	}

 	void read_blacklists()
 	{
 		for (auto fn : blacklists)
 		{
 			std::ifstream f(fn);
 			if (f.fail())
 				log_cmd_error("Can't open blacklist file '%s'!\n", fn.c_str());

 			string line, token;
 			while (std::getline(f, line)) {
 				while (1) {
 					token = next_token(line);
 					if (token.empty())
 						break;
 					blacklist_names.insert(RTLIL::escape_id(token));
 				}
 			}
 		}
 	}

 	void read_encfiles()
 	{
 		for (auto fn : encfiles)
 		{
 			std::ifstream f(fn);
 			if (f.fail())
 				log_cmd_error("Can't open encfile '%s'!\n", fn.c_str());

 			dict<Const, Const> *ed = nullptr;
 			string line, token;
 			while (std::getline(f, line))
 			{
 				token = next_token(line);
 				if (token.empty() || token[0] == '#')
 					continue;

 				if (token == ".fsm") {
 					IdString modname = RTLIL::escape_id(next_token(line));
 					IdString signame = RTLIL::escape_id(next_token(line));
 					if (encdata.count(signame))
 						log_cmd_error("Re-definition of signal '%s' in encfile '%s'!\n", signame.c_str(), fn.c_str());
 					encdata[signame] = dict<Const, Const>();
 					ed = &encdata[signame];
 					continue;
 				}

 				if (token == ".map") {
 					Const gold_bits = Const::from_string(next_token(line));
 					Const gate_bits = Const::from_string(next_token(line));
 					(*ed)[gold_bits] = gate_bits;
 					continue;
 				}

 				log_cmd_error("Syntax error in encfile '%s'!\n", fn.c_str());
 			}
 		}
 	}

 	void copy_to_equiv()
 	{
 		Module *gold_clone = gold_mod->clone();
 		Module *gate_clone = gate_mod->clone();

 		for (auto it : gold_clone->wires().to_vector()) {
 			if ((it->name[0] == '\\' || inames) && blacklist_names.count(it->name) == 0)
 				wire_names.insert(it->name);
 			gold_clone->rename(it, it->name.str() + "_gold");
 		}

 		for (auto it : gold_clone->cells().to_vector()) {
 			if ((it->name[0] == '\\' || inames) && blacklist_names.count(it->name) == 0)
 				cell_names.insert(it->name);
 			gold_clone->rename(it, it->name.str() + "_gold");
 		}

 		for (auto it : gate_clone->wires().to_vector()) {
 			if ((it->name[0] == '\\' || inames) && blacklist_names.count(it->name) == 0)
 				wire_names.insert(it->name);
 			gate_clone->rename(it, it->name.str() + "_gate");
 		}

 		for (auto it : gate_clone->cells().to_vector()) {
 			if ((it->name[0] == '\\' || inames) && blacklist_names.count(it->name) == 0)
 				cell_names.insert(it->name);
 			gate_clone->rename(it, it->name.str() + "_gate");
 		}

 		gold_clone->cloneInto(equiv_mod);
 		gate_clone->cloneInto(equiv_mod);
 		delete gold_clone;
 		delete gate_clone;
 	}

 	void find_same_wires()
 	{
 		SigMap assign_map(equiv_mod);
 		SigMap rd_signal_map;

 		// list of cells without added $equiv cells
 		auto cells_list = equiv_mod->cells().to_vector();

 		for (auto id : wire_names)
 		{
 			IdString gold_id = id.str() + "_gold";
 			IdString gate_id = id.str() + "_gate";

 			Wire *gold_wire = equiv_mod->wire(gold_id);
 			Wire *gate_wire = equiv_mod->wire(gate_id);

 			if (encdata.count(id))
 			{
 				log("Creating encoder/decoder for signal %s.\n", log_id(id));

 				Wire *dec_wire = equiv_mod->addWire(id.str() + "_decoded", gold_wire->width);
 				Wire *enc_wire = equiv_mod->addWire(id.str() + "_encoded", gate_wire->width);

 				SigSpec dec_a, dec_b, dec_s;
 				SigSpec enc_a, enc_b, enc_s;

 				dec_a = SigSpec(State::Sx, dec_wire->width);
 				enc_a = SigSpec(State::Sx, enc_wire->width);

 				for (auto &it : encdata.at(id))
 				{
 					SigSpec dec_sig = gate_wire, dec_pat = it.second;
 					SigSpec enc_sig = dec_wire, enc_pat = it.first;

 					if (GetSize(dec_sig) != GetSize(dec_pat))
 						log_error("Invalid pattern %s for signal %s of size %d!\n",
 								log_signal(dec_pat), log_signal(dec_sig), GetSize(dec_sig));

 					if (GetSize(enc_sig) != GetSize(enc_pat))
 						log_error("Invalid pattern %s for signal %s of size %d!\n",
 								log_signal(enc_pat), log_signal(enc_sig), GetSize(enc_sig));

 					SigSpec reduced_dec_sig, reduced_dec_pat;
 					for (int i = 0; i < GetSize(dec_sig); i++)
 						if (dec_pat[i] == State::S0 || dec_pat[i] == State::S1) {
 							reduced_dec_sig.append(dec_sig[i]);
 							reduced_dec_pat.append(dec_pat[i]);
 						}

 					SigSpec reduced_enc_sig, reduced_enc_pat;
 					for (int i = 0; i < GetSize(enc_sig); i++)
 						if (enc_pat[i] == State::S0 || enc_pat[i] == State::S1) {
 							reduced_enc_sig.append(enc_sig[i]);
 							reduced_enc_pat.append(enc_pat[i]);
 						}

 					SigSpec dec_result = it.first;
 					for (auto &bit : dec_result)
 						if (bit != State::S1) bit = State::S0;

 					SigSpec enc_result = it.second;
 					for (auto &bit : enc_result)
 						if (bit != State::S1) bit = State::S0;

 					SigSpec dec_eq = equiv_mod->addWire(NEW_ID);
 					SigSpec enc_eq = equiv_mod->addWire(NEW_ID);

 					equiv_mod->addEq(NEW_ID, reduced_dec_sig, reduced_dec_pat, dec_eq);
 					cells_list.push_back(equiv_mod->addEq(NEW_ID, reduced_enc_sig, reduced_enc_pat, enc_eq));

 					dec_s.append(dec_eq);
 					enc_s.append(enc_eq);
 					dec_b.append(dec_result);
 					enc_b.append(enc_result);
 				}

 				equiv_mod->addPmux(NEW_ID, dec_a, dec_b, dec_s, dec_wire);
 				equiv_mod->addPmux(NEW_ID, enc_a, enc_b, enc_s, enc_wire);

 				rd_signal_map.add(assign_map(gate_wire), enc_wire);
 				gate_wire = dec_wire;
 			}

 			if (gold_wire == nullptr || gate_wire == nullptr || gold_wire->width != gate_wire->width) {
 				if (gold_wire && gold_wire->port_id)
 					log_error("Can't match gold port `%s' to a gate port.\n", log_id(gold_wire));
 				if (gate_wire && gate_wire->port_id)
 					log_error("Can't match gate port `%s' to a gold port.\n", log_id(gate_wire));
 				continue;
 			}

 			log("Presumably equivalent wires: %s (%s), %s (%s) -> %s\n",
 					log_id(gold_wire), log_signal(assign_map(gold_wire)),
 					log_id(gate_wire), log_signal(assign_map(gate_wire)), log_id(id));

 			if (gold_wire->port_output || gate_wire->port_output)
 			{
 				Wire *wire = equiv_mod->addWire(id, gold_wire->width);
 				wire->port_output = true;
 				gold_wire->port_input = false;
 				gate_wire->port_input = false;
 				gold_wire->port_output = false;
 				gate_wire->port_output = false;

 				for (int i = 0; i < wire->width; i++)
 					equiv_mod->addEquiv(NEW_ID, SigSpec(gold_wire, i), SigSpec(gate_wire, i), SigSpec(wire, i));

 				rd_signal_map.add(assign_map(gold_wire), wire);
 				rd_signal_map.add(assign_map(gate_wire), wire);
 			}
 			else
 			if (gold_wire->port_input || gate_wire->port_input)
 			{
 				Wire *wire = equiv_mod->addWire(id, gold_wire->width);
 				wire->port_input = true;
 				gold_wire->port_input = false;
 				gate_wire->port_input = false;
 				equiv_mod->connect(gold_wire, wire);
 				equiv_mod->connect(gate_wire, wire);
 			}
 			else
 			{
 				Wire *wire = equiv_mod->addWire(id, gold_wire->width);
 				SigSpec rdmap_gold, rdmap_gate, rdmap_equiv;

 				for (int i = 0; i < wire->width; i++) {
 					if (undriven_bits.count(assign_map(SigBit(gold_wire, i)))) {
 						log("  Skipping signal bit %s [%d]: undriven on gold side.\n", id2cstr(gold_wire->name), i);
 						continue;
 					}
 					if (undriven_bits.count(assign_map(SigBit(gate_wire, i)))) {
 						log("  Skipping signal bit %s [%d]: undriven on gate side.\n", id2cstr(gate_wire->name), i);
 						continue;
 					}
 					equiv_mod->addEquiv(NEW_ID, SigSpec(gold_wire, i), SigSpec(gate_wire, i), SigSpec(wire, i));
 					rdmap_gold.append(SigBit(gold_wire, i));
 					rdmap_gate.append(SigBit(gate_wire, i));
 					rdmap_equiv.append(SigBit(wire, i));
 				}

 				rd_signal_map.add(rdmap_gold, rdmap_equiv);
 				rd_signal_map.add(rdmap_gate, rdmap_equiv);
 			}
 		}

 		init_bit2driven();

 		pool<Cell*> visited_cells;
 		for (auto c : cells_list)
 		for (auto &conn : c->connections())
 			if (!ct.cell_output(c->type, conn.first)) {
 				SigSpec old_sig = assign_map(conn.second);
 				SigSpec new_sig = rd_signal_map(old_sig);

 				if(old_sig != new_sig) {
 					SigSpec tmp_sig = old_sig;
 					for (int i = 0; i < GetSize(old_sig); i++) {
 						SigBit old_bit = old_sig[i], new_bit = new_sig[i];

 						visited_cells.clear();
 						if (check_signal_in_fanout(visited_cells, old_bit, new_bit))
 							continue;

 						log("Changing input %s of cell %s (%s): %s -> %s\n",
 								log_id(conn.first), log_id(c), log_id(c->type),
 								log_signal(old_bit), log_signal(new_bit));

 						tmp_sig[i] = new_bit;
 					}
 					c->setPort(conn.first, tmp_sig);
 				}
 			}

 		equiv_mod->fixup_ports();
 	}

 	void find_same_cells()
 	{
 		SigMap assign_map(equiv_mod);

 		for (auto id : cell_names)
 		{
 			IdString gold_id = id.str() + "_gold";
 			IdString gate_id = id.str() + "_gate";

 			Cell *gold_cell = equiv_mod->cell(gold_id);
 			Cell *gate_cell = equiv_mod->cell(gate_id);

 			if (gold_cell == nullptr || gate_cell == nullptr || gold_cell->type != gate_cell->type || !ct.cell_known(gold_cell->type) ||
 					gold_cell->parameters != gate_cell->parameters || GetSize(gold_cell->connections()) != GetSize(gate_cell->connections()))
 		try_next_cell_name:
 				continue;

 			for (auto gold_conn : gold_cell->connections())
 				if (!gate_cell->connections().count(gold_conn.first))
 					goto try_next_cell_name;

 			log("Presumably equivalent cells: %s %s (%s) -> %s\n",
 					log_id(gold_cell), log_id(gate_cell), log_id(gold_cell->type), log_id(id));

 			for (auto gold_conn : gold_cell->connections())
 			{
 				SigSpec gold_sig = assign_map(gold_conn.second);
 				SigSpec gate_sig = assign_map(gate_cell->getPort(gold_conn.first));

 				if (ct.cell_output(gold_cell->type, gold_conn.first)) {
 					equiv_mod->connect(gate_sig, gold_sig);
 					continue;
 				}

 				for (int i = 0; i < GetSize(gold_sig); i++)
 					if (gold_sig[i] != gate_sig[i]) {
 						Wire *w = equiv_mod->addWire(NEW_ID);
 						equiv_mod->addEquiv(NEW_ID, gold_sig[i], gate_sig[i], w);
 						gold_sig[i] = w;
 					}

 				gold_cell->setPort(gold_conn.first, gold_sig);
 			}

 			equiv_mod->remove(gate_cell);
 			equiv_mod->rename(gold_cell, id);
 		}
 	}

 	void find_undriven_nets(bool mark)
 	{
 		undriven_bits.clear();
 		assign_map.set(equiv_mod);

 		for (auto wire : equiv_mod->wires()) {
 			for (auto bit : assign_map(wire))
 				if (bit.wire)
 					undriven_bits.insert(bit);
 		}

 		for (auto wire : equiv_mod->wires()) {
 			if (wire->port_input)
 				for (auto bit : assign_map(wire))
 					undriven_bits.erase(bit);
 		}

 		for (auto cell : equiv_mod->cells()) {
 			for (auto &conn : cell->connections())
 				if (!ct.cell_known(cell->type) || ct.cell_output(cell->type, conn.first))
 					for (auto bit : assign_map(conn.second))
 						undriven_bits.erase(bit);
 		}

 		if (mark) {
 			SigSpec undriven_sig(undriven_bits);
 			undriven_sig.sort_and_unify();

 			for (auto chunk : undriven_sig.chunks()) {
 				log("Setting undriven nets to undef: %s\n", log_signal(chunk));
 				equiv_mod->connect(chunk, SigSpec(State::Sx, chunk.width));
 			}
 		}
 	}

 	void init_bit2driven()
 	{
 		for (auto cell : equiv_mod->cells()) {
 			if (!ct.cell_known(cell->type) && !cell->type.in("$dff", "$_DFF_P_", "$_DFF_N_", "$ff", "$_FF_"))
 				continue;
 			for (auto &conn : cell->connections())
 			{
 				if (yosys_celltypes.cell_input(cell->type, conn.first))
 					for (auto bit : assign_map(conn.second))
 					{
 						bit2driven[bit].insert(cell);
 					}
 			}
 		}
 	}

 	bool check_signal_in_fanout(pool<Cell*> & visited_cells, SigBit source_bit, SigBit target_bit)
 	{
 		if (source_bit == target_bit)
 			return true;

 		if (bit2driven.count(source_bit) == 0)
 			return false;

 		auto driven_cells = bit2driven.at(source_bit);
 		for (auto driven_cell: driven_cells)
 		{
 			bool is_comb = comb_ct.cell_known(driven_cell->type);
 			if (!is_comb)
 				continue;

 			if (visited_cells.count(driven_cell) > 0)
 				continue;
 			visited_cells.insert(driven_cell);

 			for (auto &conn: driven_cell->connections())
 			{
 				if (yosys_celltypes.cell_input(driven_cell->type, conn.first))
 					continue;

 				for (auto bit: conn.second) {
 					bool is_in_fanout = check_signal_in_fanout(visited_cells, bit, target_bit);
 					if (is_in_fanout == true)
 						return true;
 				}
 			}
 		}

 		return false;
 	}

 	void run()
 	{
 		copy_to_equiv();
 		find_undriven_nets(false);
 		find_same_wires();
 		find_same_cells();
 		find_undriven_nets(true);
 	}
 };

 struct EquivMakePass : public Pass {
 	EquivMakePass() : Pass("equiv_make", "prepare a circuit for equivalence checking") { }
 	void help() YS_OVERRIDE
 	{
 		//   |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
 		log("\n");
 		log("    equiv_make [options] gold_module gate_module equiv_module\n");
 		log("\n");
 		log("This creates a module annotated with $equiv cells from two presumably\n");
 		log("equivalent modules. Use commands such as 'equiv_simple' and 'equiv_status'\n");
 		log("to work with the created equivalent checking module.\n");
 		log("\n");
 		log("    -inames\n");
 		log("        Also match cells and wires with $... names.\n");
 		log("\n");
 		log("    -blacklist <file>\n");
 		log("        Do not match cells or signals that match the names in the file.\n");
 		log("\n");
 		log("    -encfile <file>\n");
 		log("        Match FSM encodings using the description from the file.\n");
 		log("        See 'help fsm_recode' for details.\n");
 		log("\n");
 		log("Note: The circuit created by this command is not a miter (with something like\n");
 		log("a trigger output), but instead uses $equiv cells to encode the equivalence\n");
 		log("checking problem. Use 'miter -equiv' if you want to create a miter circuit.\n");
 		log("\n");
 	}
 	void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
 	{
 		EquivMakeWorker worker;
 		worker.ct.setup(design);
 		worker.inames = false;

 		size_t argidx;
 		for (argidx = 1; argidx < args.size(); argidx++)
 		{
 			if (args[argidx] == "-inames") {
 				worker.inames = true;
 				continue;
 			}
 			if (args[argidx] == "-blacklist" && argidx+1 < args.size()) {
 				worker.blacklists.push_back(args[++argidx]);
 				continue;
 			}
 			if (args[argidx] == "-encfile" && argidx+1 < args.size()) {
 				worker.encfiles.push_back(args[++argidx]);
 				continue;
 			}
 			break;
 		}

 		if (argidx+3 != args.size())
 			log_cmd_error("Invalid number of arguments.\n");

 		worker.gold_mod = design->module(RTLIL::escape_id(args[argidx]));
 		worker.gate_mod = design->module(RTLIL::escape_id(args[argidx+1]));
 		worker.equiv_mod = design->module(RTLIL::escape_id(args[argidx+2]));

 		if (worker.gold_mod == nullptr)
 			log_cmd_error("Can't find gold module %s.\n", args[argidx].c_str());

 		if (worker.gate_mod == nullptr)
 			log_cmd_error("Can't find gate module %s.\n", args[argidx+1].c_str());

 		if (worker.equiv_mod != nullptr)
 			log_cmd_error("Equiv module %s already exists.\n", args[argidx+2].c_str());

 		if (worker.gold_mod->has_memories() || worker.gold_mod->has_processes())
 			log_cmd_error("Gold module contains memories or processes. Run 'memory' or 'proc' respectively.\n");

 		if (worker.gate_mod->has_memories() || worker.gate_mod->has_processes())
 			log_cmd_error("Gate module contains memories or processes. Run 'memory' or 'proc' respectively.\n");

 		worker.read_blacklists();
 		worker.read_encfiles();

 		log_header(design, "Executing EQUIV_MAKE pass (creating equiv checking module).\n");

 		worker.equiv_mod = design->addModule(RTLIL::escape_id(args[argidx+2]));
 		worker.run();
 	}
 } EquivMakePass;

 PRIVATE_NAMESPACE_END
	/*
	* yosys -- Yosys Open SYnthesis Suite
	*
	* Copyright (C) 2012 Clifford Wolf <clifford@clifford.at>
	*
	* Permission to use, copy, modify, and/or distribute this software for any
	* purpose with or without fee is hereby granted, provided that the above
	* copyright notice and this permission notice appear in all copies.
	*
	* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
	* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
	* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
	* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
	* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
	* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
	* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
	*
	*/

	#include "kernel/yosys.h"
	#include "kernel/sigtools.h"
	#include "kernel/celltypes.h"

	USING_YOSYS_NAMESPACE
	PRIVATE_NAMESPACE_BEGIN

	struct EquivMakeWorker
	{
	Module gold_mod, gate_mod, *equiv_mod;
	pool<IdString> wire_names, cell_names;
	CellTypes ct;

	bool inames;
	vector<string> blacklists;
	vector<string> encfiles;

	pool<IdString> blacklist_names;
	dict<IdString, dict<Const, Const>> encdata;

	pool<SigBit> undriven_bits;
	SigMap assign_map;

	dict<SigBit, pool<Cell*>> bit2driven; // map: bit <--> and its driven cells

	CellTypes comb_ct;

	EquivMakeWorker()
	{
	comb_ct.setup_internals();
	comb_ct.setup_stdcells();
	}

	void read_blacklists()
	{
	for (auto fn : blacklists)
	{
	std::ifstream f(fn);
	if (f.fail())
	log_cmd_error("Can't open blacklist file '%s'!\n", fn.c_str());

	string line, token;
	while (std::getline(f, line)) {
	while (1) {
	token = next_token(line);
	if (token.empty())
	break;
	blacklist_names.insert(RTLIL::escape_id(token));
	}
	}
	}
	}

	void read_encfiles()
	{
	for (auto fn : encfiles)
	{
	std::ifstream f(fn);
	if (f.fail())
	log_cmd_error("Can't open encfile '%s'!\n", fn.c_str());

	dict<Const, Const> *ed = nullptr;
	string line, token;
	while (std::getline(f, line))
	{
	token = next_token(line);
	if (token.empty() \|\| token[0] == '#')
	continue;

	if (token == ".fsm") {
	IdString modname = RTLIL::escape_id(next_token(line));
	IdString signame = RTLIL::escape_id(next_token(line));
	if (encdata.count(signame))
	log_cmd_error("Re-definition of signal '%s' in encfile '%s'!\n", signame.c_str(), fn.c_str());
	encdata[signame] = dict<Const, Const>();
	ed = &encdata[signame];
	continue;
	}

	if (token == ".map") {
	Const gold_bits = Const::from_string(next_token(line));
	Const gate_bits = Const::from_string(next_token(line));
	(*ed)[gold_bits] = gate_bits;
	continue;
	}

	log_cmd_error("Syntax error in encfile '%s'!\n", fn.c_str());
	}
	}
	}

	void copy_to_equiv()
	{
	Module *gold_clone = gold_mod->clone();
	Module *gate_clone = gate_mod->clone();

	for (auto it : gold_clone->wires().to_vector()) {
	if ((it->name[0] == '\\' \|\| inames) && blacklist_names.count(it->name) == 0)
	wire_names.insert(it->name);
	gold_clone->rename(it, it->name.str() + "_gold");
	}

	for (auto it : gold_clone->cells().to_vector()) {
	if ((it->name[0] == '\\' \|\| inames) && blacklist_names.count(it->name) == 0)
	cell_names.insert(it->name);
	gold_clone->rename(it, it->name.str() + "_gold");
	}

	for (auto it : gate_clone->wires().to_vector()) {
	if ((it->name[0] == '\\' \|\| inames) && blacklist_names.count(it->name) == 0)
	wire_names.insert(it->name);
	gate_clone->rename(it, it->name.str() + "_gate");
	}

	for (auto it : gate_clone->cells().to_vector()) {
	if ((it->name[0] == '\\' \|\| inames) && blacklist_names.count(it->name) == 0)
	cell_names.insert(it->name);
	gate_clone->rename(it, it->name.str() + "_gate");
	}

	gold_clone->cloneInto(equiv_mod);
	gate_clone->cloneInto(equiv_mod);
	delete gold_clone;
	delete gate_clone;
	}

	void find_same_wires()
	{
	SigMap assign_map(equiv_mod);
	SigMap rd_signal_map;

	// list of cells without added $equiv cells
	auto cells_list = equiv_mod->cells().to_vector();

	for (auto id : wire_names)
	{
	IdString gold_id = id.str() + "_gold";
	IdString gate_id = id.str() + "_gate";

	Wire *gold_wire = equiv_mod->wire(gold_id);
	Wire *gate_wire = equiv_mod->wire(gate_id);

	if (encdata.count(id))
	{
	log("Creating encoder/decoder for signal %s.\n", log_id(id));

	Wire *dec_wire = equiv_mod->addWire(id.str() + "_decoded", gold_wire->width);
	Wire *enc_wire = equiv_mod->addWire(id.str() + "_encoded", gate_wire->width);

	SigSpec dec_a, dec_b, dec_s;
	SigSpec enc_a, enc_b, enc_s;

	dec_a = SigSpec(State::Sx, dec_wire->width);
	enc_a = SigSpec(State::Sx, enc_wire->width);

	for (auto &it : encdata.at(id))
	{
	SigSpec dec_sig = gate_wire, dec_pat = it.second;
	SigSpec enc_sig = dec_wire, enc_pat = it.first;

	if (GetSize(dec_sig) != GetSize(dec_pat))
	log_error("Invalid pattern %s for signal %s of size %d!\n",
	log_signal(dec_pat), log_signal(dec_sig), GetSize(dec_sig));

	if (GetSize(enc_sig) != GetSize(enc_pat))
	log_error("Invalid pattern %s for signal %s of size %d!\n",
	log_signal(enc_pat), log_signal(enc_sig), GetSize(enc_sig));

	SigSpec reduced_dec_sig, reduced_dec_pat;
	for (int i = 0; i < GetSize(dec_sig); i++)
	if (dec_pat[i] == State::S0 \|\| dec_pat[i] == State::S1) {
	reduced_dec_sig.append(dec_sig[i]);
	reduced_dec_pat.append(dec_pat[i]);
	}

	SigSpec reduced_enc_sig, reduced_enc_pat;
	for (int i = 0; i < GetSize(enc_sig); i++)
	if (enc_pat[i] == State::S0 \|\| enc_pat[i] == State::S1) {
	reduced_enc_sig.append(enc_sig[i]);
	reduced_enc_pat.append(enc_pat[i]);
	}

	SigSpec dec_result = it.first;
	for (auto &bit : dec_result)
	if (bit != State::S1) bit = State::S0;

	SigSpec enc_result = it.second;
	for (auto &bit : enc_result)
	if (bit != State::S1) bit = State::S0;

	SigSpec dec_eq = equiv_mod->addWire(NEW_ID);
	SigSpec enc_eq = equiv_mod->addWire(NEW_ID);

	equiv_mod->addEq(NEW_ID, reduced_dec_sig, reduced_dec_pat, dec_eq);
	cells_list.push_back(equiv_mod->addEq(NEW_ID, reduced_enc_sig, reduced_enc_pat, enc_eq));

	dec_s.append(dec_eq);
	enc_s.append(enc_eq);
	dec_b.append(dec_result);
	enc_b.append(enc_result);
	}

	equiv_mod->addPmux(NEW_ID, dec_a, dec_b, dec_s, dec_wire);
	equiv_mod->addPmux(NEW_ID, enc_a, enc_b, enc_s, enc_wire);

	rd_signal_map.add(assign_map(gate_wire), enc_wire);
	gate_wire = dec_wire;
	}

	if (gold_wire == nullptr \|\| gate_wire == nullptr \|\| gold_wire->width != gate_wire->width) {
	if (gold_wire && gold_wire->port_id)
	log_error("Can't match gold port `%s' to a gate port.\n", log_id(gold_wire));
	if (gate_wire && gate_wire->port_id)
	log_error("Can't match gate port `%s' to a gold port.\n", log_id(gate_wire));
	continue;
	}

	log("Presumably equivalent wires: %s (%s), %s (%s) -> %s\n",
	log_id(gold_wire), log_signal(assign_map(gold_wire)),
	log_id(gate_wire), log_signal(assign_map(gate_wire)), log_id(id));

	if (gold_wire->port_output \|\| gate_wire->port_output)
	{
	Wire *wire = equiv_mod->addWire(id, gold_wire->width);
	wire->port_output = true;
	gold_wire->port_input = false;
	gate_wire->port_input = false;
	gold_wire->port_output = false;
	gate_wire->port_output = false;

	for (int i = 0; i < wire->width; i++)
	equiv_mod->addEquiv(NEW_ID, SigSpec(gold_wire, i), SigSpec(gate_wire, i), SigSpec(wire, i));

	rd_signal_map.add(assign_map(gold_wire), wire);
	rd_signal_map.add(assign_map(gate_wire), wire);
	}
	else
	if (gold_wire->port_input \|\| gate_wire->port_input)
	{
	Wire *wire = equiv_mod->addWire(id, gold_wire->width);
	wire->port_input = true;
	gold_wire->port_input = false;
	gate_wire->port_input = false;
	equiv_mod->connect(gold_wire, wire);
	equiv_mod->connect(gate_wire, wire);
	}
	else
	{
	Wire *wire = equiv_mod->addWire(id, gold_wire->width);
	SigSpec rdmap_gold, rdmap_gate, rdmap_equiv;

	for (int i = 0; i < wire->width; i++) {
	if (undriven_bits.count(assign_map(SigBit(gold_wire, i)))) {
	log(" Skipping signal bit %s [%d]: undriven on gold side.\n", id2cstr(gold_wire->name), i);
	continue;
	}
	if (undriven_bits.count(assign_map(SigBit(gate_wire, i)))) {
	log(" Skipping signal bit %s [%d]: undriven on gate side.\n", id2cstr(gate_wire->name), i);
	continue;
	}
	equiv_mod->addEquiv(NEW_ID, SigSpec(gold_wire, i), SigSpec(gate_wire, i), SigSpec(wire, i));
	rdmap_gold.append(SigBit(gold_wire, i));
	rdmap_gate.append(SigBit(gate_wire, i));
	rdmap_equiv.append(SigBit(wire, i));
	}

	rd_signal_map.add(rdmap_gold, rdmap_equiv);
	rd_signal_map.add(rdmap_gate, rdmap_equiv);
	}
	}

	init_bit2driven();

	pool<Cell*> visited_cells;
	for (auto c : cells_list)
	for (auto &conn : c->connections())
	if (!ct.cell_output(c->type, conn.first)) {
	SigSpec old_sig = assign_map(conn.second);
	SigSpec new_sig = rd_signal_map(old_sig);

	if(old_sig != new_sig) {
	SigSpec tmp_sig = old_sig;
	for (int i = 0; i < GetSize(old_sig); i++) {
	SigBit old_bit = old_sig[i], new_bit = new_sig[i];

	visited_cells.clear();
	if (check_signal_in_fanout(visited_cells, old_bit, new_bit))
	continue;

	log("Changing input %s of cell %s (%s): %s -> %s\n",
	log_id(conn.first), log_id(c), log_id(c->type),
	log_signal(old_bit), log_signal(new_bit));

	tmp_sig[i] = new_bit;
	}
	c->setPort(conn.first, tmp_sig);
	}
	}

	equiv_mod->fixup_ports();
	}

	void find_same_cells()
	{
	SigMap assign_map(equiv_mod);

	for (auto id : cell_names)
	{
	IdString gold_id = id.str() + "_gold";
	IdString gate_id = id.str() + "_gate";

	Cell *gold_cell = equiv_mod->cell(gold_id);
	Cell *gate_cell = equiv_mod->cell(gate_id);

	if (gold_cell == nullptr \|\| gate_cell == nullptr \|\| gold_cell->type != gate_cell->type \|\| !ct.cell_known(gold_cell->type) \|\|
	gold_cell->parameters != gate_cell->parameters \|\| GetSize(gold_cell->connections()) != GetSize(gate_cell->connections()))
	try_next_cell_name:
	continue;

	for (auto gold_conn : gold_cell->connections())
	if (!gate_cell->connections().count(gold_conn.first))
	goto try_next_cell_name;

	log("Presumably equivalent cells: %s %s (%s) -> %s\n",
	log_id(gold_cell), log_id(gate_cell), log_id(gold_cell->type), log_id(id));

	for (auto gold_conn : gold_cell->connections())
	{
	SigSpec gold_sig = assign_map(gold_conn.second);
	SigSpec gate_sig = assign_map(gate_cell->getPort(gold_conn.first));

	if (ct.cell_output(gold_cell->type, gold_conn.first)) {
	equiv_mod->connect(gate_sig, gold_sig);
	continue;
	}

	for (int i = 0; i < GetSize(gold_sig); i++)
	if (gold_sig[i] != gate_sig[i]) {
	Wire *w = equiv_mod->addWire(NEW_ID);
	equiv_mod->addEquiv(NEW_ID, gold_sig[i], gate_sig[i], w);
	gold_sig[i] = w;
	}

	gold_cell->setPort(gold_conn.first, gold_sig);
	}

	equiv_mod->remove(gate_cell);
	equiv_mod->rename(gold_cell, id);
	}
	}

	void find_undriven_nets(bool mark)
	{
	undriven_bits.clear();
	assign_map.set(equiv_mod);

	for (auto wire : equiv_mod->wires()) {
	for (auto bit : assign_map(wire))
	if (bit.wire)
	undriven_bits.insert(bit);
	}

	for (auto wire : equiv_mod->wires()) {
	if (wire->port_input)
	for (auto bit : assign_map(wire))
	undriven_bits.erase(bit);
	}

	for (auto cell : equiv_mod->cells()) {
	for (auto &conn : cell->connections())
	if (!ct.cell_known(cell->type) \|\| ct.cell_output(cell->type, conn.first))
	for (auto bit : assign_map(conn.second))
	undriven_bits.erase(bit);
	}

	if (mark) {
	SigSpec undriven_sig(undriven_bits);
	undriven_sig.sort_and_unify();

	for (auto chunk : undriven_sig.chunks()) {
	log("Setting undriven nets to undef: %s\n", log_signal(chunk));
	equiv_mod->connect(chunk, SigSpec(State::Sx, chunk.width));
	}
	}
	}

	void init_bit2driven()
	{
	for (auto cell : equiv_mod->cells()) {
	if (!ct.cell_known(cell->type) && !cell->type.in("$dff", "$_DFF_P_", "$_DFF_N_", "$ff", "$_FF_"))
	continue;
	for (auto &conn : cell->connections())
	{
	if (yosys_celltypes.cell_input(cell->type, conn.first))
	for (auto bit : assign_map(conn.second))
	{
	bit2driven[bit].insert(cell);
	}
	}
	}
	}

	bool check_signal_in_fanout(pool<Cell*> & visited_cells, SigBit source_bit, SigBit target_bit)
	{
	if (source_bit == target_bit)
	return true;

	if (bit2driven.count(source_bit) == 0)
	return false;

	auto driven_cells = bit2driven.at(source_bit);
	for (auto driven_cell: driven_cells)
	{
	bool is_comb = comb_ct.cell_known(driven_cell->type);
	if (!is_comb)
	continue;

	if (visited_cells.count(driven_cell) > 0)
	continue;
	visited_cells.insert(driven_cell);

	for (auto &conn: driven_cell->connections())
	{
	if (yosys_celltypes.cell_input(driven_cell->type, conn.first))
	continue;

	for (auto bit: conn.second) {
	bool is_in_fanout = check_signal_in_fanout(visited_cells, bit, target_bit);
	if (is_in_fanout == true)
	return true;
	}
	}
	}

	return false;
	}

	void run()
	{
	copy_to_equiv();
	find_undriven_nets(false);
	find_same_wires();
	find_same_cells();
	find_undriven_nets(true);
	}
	};

	struct EquivMakePass : public Pass {
	EquivMakePass() : Pass("equiv_make", "prepare a circuit for equivalence checking") { }
	void help() YS_OVERRIDE
	{
	// \|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|---v---\|
	log("\n");
	log(" equiv_make [options] gold_module gate_module equiv_module\n");
	log("\n");
	log("This creates a module annotated with $equiv cells from two presumably\n");
	log("equivalent modules. Use commands such as 'equiv_simple' and 'equiv_status'\n");
	log("to work with the created equivalent checking module.\n");
	log("\n");
	log(" -inames\n");
	log(" Also match cells and wires with $... names.\n");
	log("\n");
	log(" -blacklist <file>\n");
	log(" Do not match cells or signals that match the names in the file.\n");
	log("\n");
	log(" -encfile <file>\n");
	log(" Match FSM encodings using the description from the file.\n");
	log(" See 'help fsm_recode' for details.\n");
	log("\n");
	log("Note: The circuit created by this command is not a miter (with something like\n");
	log("a trigger output), but instead uses $equiv cells to encode the equivalence\n");
	log("checking problem. Use 'miter -equiv' if you want to create a miter circuit.\n");
	log("\n");
	}
	void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
	{
	EquivMakeWorker worker;
	worker.ct.setup(design);
	worker.inames = false;

	size_t argidx;
	for (argidx = 1; argidx < args.size(); argidx++)
	{
	if (args[argidx] == "-inames") {
	worker.inames = true;
	continue;
	}
	if (args[argidx] == "-blacklist" && argidx+1 < args.size()) {
	worker.blacklists.push_back(args[++argidx]);
	continue;
	}
	if (args[argidx] == "-encfile" && argidx+1 < args.size()) {
	worker.encfiles.push_back(args[++argidx]);
	continue;
	}
	break;
	}

	if (argidx+3 != args.size())
	log_cmd_error("Invalid number of arguments.\n");

	worker.gold_mod = design->module(RTLIL::escape_id(args[argidx]));
	worker.gate_mod = design->module(RTLIL::escape_id(args[argidx+1]));
	worker.equiv_mod = design->module(RTLIL::escape_id(args[argidx+2]));

	if (worker.gold_mod == nullptr)
	log_cmd_error("Can't find gold module %s.\n", args[argidx].c_str());

	if (worker.gate_mod == nullptr)
	log_cmd_error("Can't find gate module %s.\n", args[argidx+1].c_str());

	if (worker.equiv_mod != nullptr)
	log_cmd_error("Equiv module %s already exists.\n", args[argidx+2].c_str());

	if (worker.gold_mod->has_memories() \|\| worker.gold_mod->has_processes())
	log_cmd_error("Gold module contains memories or processes. Run 'memory' or 'proc' respectively.\n");

	if (worker.gate_mod->has_memories() \|\| worker.gate_mod->has_processes())
	log_cmd_error("Gate module contains memories or processes. Run 'memory' or 'proc' respectively.\n");

	worker.read_blacklists();
	worker.read_encfiles();

	log_header(design, "Executing EQUIV_MAKE pass (creating equiv checking module).\n");

	worker.equiv_mod = design->addModule(RTLIL::escape_id(args[argidx+2]));
	worker.run();
	}
	} EquivMakePass;

	PRIVATE_NAMESPACE_END