/*
 *  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.
 *
 */

// [[CITE]] Temporal Induction by Incremental SAT Solving
// Niklas Een and Niklas Sörensson (2003)
// http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.4.8161

#include "kernel/register.h"
#include "kernel/celltypes.h"
#include "kernel/consteval.h"
#include "kernel/sigtools.h"
#include "kernel/log.h"
#include "kernel/satgen.h"
#include <stdlib.h>
#include <stdio.h>
#include <algorithm>

namespace {

struct SatHelper
{
	RTLIL::Design *design;
	RTLIL::Module *module;

	ezDefaultSAT ez;
	SigMap sigmap;
	CellTypes ct;
	SatGen satgen;

	// additional constraints
	std::vector<std::pair<std::string, std::string>> sets, prove, sets_init;
	std::map<int, std::vector<std::pair<std::string, std::string>>> sets_at;
	std::map<int, std::vector<std::string>> unsets_at;

	// undef constraints
	bool enable_undef, set_init_undef;
	std::vector<std::string> sets_def, sets_any_undef, sets_all_undef;
	std::map<int, std::vector<std::string>> sets_def_at, sets_any_undef_at, sets_all_undef_at;

	// model variables
	std::vector<std::string> shows;
	SigPool show_signal_pool;
	SigSet<RTLIL::Cell*> show_drivers;
	int max_timestep, timeout;
	bool gotTimeout;

	SatHelper(RTLIL::Design *design, RTLIL::Module *module, bool enable_undef) :
		design(design), module(module), sigmap(module), ct(design), satgen(&ez, design, &sigmap)
	{
		this->enable_undef = enable_undef;
		satgen.model_undef = enable_undef;
		set_init_undef = false;
		max_timestep = -1;
		timeout = 0;
		gotTimeout = false;
	}

	void check_undef_enabled(const RTLIL::SigSpec &sig)
	{
		if (enable_undef)
			return;

		std::vector<RTLIL::SigBit> sigbits = sig.to_sigbit_vector();
		for (size_t i = 0; i < sigbits.size(); i++)
			if (sigbits[i].wire == NULL && sigbits[i].data == RTLIL::State::Sx)
				log_cmd_error("Bit %d of %s is undef but option -enable_undef is missing!\n", int(i), log_signal(sig));
	}

	void setup_init()
	{
		log ("\nSetting up initial state:\n");

		RTLIL::SigSpec big_lhs, big_rhs;

		for (auto &s : sets_init)
		{
			RTLIL::SigSpec lhs, rhs;

			if (!RTLIL::SigSpec::parse(lhs, module, s.first))
				log_cmd_error("Failed to parse lhs set expression `%s'.\n", s.first.c_str());
			if (!RTLIL::SigSpec::parse_rhs(lhs, rhs, module, s.second))
				log_cmd_error("Failed to parse rhs set expression `%s'.\n", s.second.c_str());
			show_signal_pool.add(sigmap(lhs));
			show_signal_pool.add(sigmap(rhs));

			if (lhs.width != rhs.width)
				log_cmd_error("Set expression with different lhs and rhs sizes: %s (%s, %d bits) vs. %s (%s, %d bits)\n",
					s.first.c_str(), log_signal(lhs), lhs.width, s.second.c_str(), log_signal(rhs), rhs.width);

			log("Import set-constraint: %s = %s\n", log_signal(lhs), log_signal(rhs));
			big_lhs.remove2(lhs, &big_rhs);
			big_lhs.append(lhs);
			big_rhs.append(rhs);
		}

		if (!satgen.initial_state.check_all(big_lhs)) {
			RTLIL::SigSpec rem = satgen.initial_state.remove(big_lhs);
			rem.optimize();
			log_cmd_error("Found -set-init bits that are not part of the initial_state: %s\n", log_signal(rem));
		}

		if (set_init_undef) {
			RTLIL::SigSpec rem = satgen.initial_state.export_all();
			rem.remove(big_lhs);
			big_lhs.append(rem);
			big_rhs.append(RTLIL::SigSpec(RTLIL::State::Sx, rem.width));
		}

		if (big_lhs.width == 0) {
			log("No constraints for initial state found.\n\n");
			return;
		}

		log("Final constraint equation: %s = %s\n\n", log_signal(big_lhs), log_signal(big_rhs));
		check_undef_enabled(big_lhs), check_undef_enabled(big_rhs);
		ez.assume(satgen.signals_eq(big_lhs, big_rhs, 1));
	}

	void setup(int timestep = -1)
	{
		if (timestep > 0)
			log ("\nSetting up time step %d:\n", timestep);
		else
			log ("\nSetting up SAT problem:\n");

		if (timestep > max_timestep)
			max_timestep = timestep;

		RTLIL::SigSpec big_lhs, big_rhs;

		for (auto &s : sets)
		{
			RTLIL::SigSpec lhs, rhs;

			if (!RTLIL::SigSpec::parse(lhs, module, s.first))
				log_cmd_error("Failed to parse lhs set expression `%s'.\n", s.first.c_str());
			if (!RTLIL::SigSpec::parse_rhs(lhs, rhs, module, s.second))
				log_cmd_error("Failed to parse rhs set expression `%s'.\n", s.second.c_str());
			show_signal_pool.add(sigmap(lhs));
			show_signal_pool.add(sigmap(rhs));

			if (lhs.width != rhs.width)
				log_cmd_error("Set expression with different lhs and rhs sizes: %s (%s, %d bits) vs. %s (%s, %d bits)\n",
					s.first.c_str(), log_signal(lhs), lhs.width, s.second.c_str(), log_signal(rhs), rhs.width);

			log("Import set-constraint: %s = %s\n", log_signal(lhs), log_signal(rhs));
			big_lhs.remove2(lhs, &big_rhs);
			big_lhs.append(lhs);
			big_rhs.append(rhs);
		}

		for (auto &s : sets_at[timestep])
		{
			RTLIL::SigSpec lhs, rhs;

			if (!RTLIL::SigSpec::parse(lhs, module, s.first))
				log_cmd_error("Failed to parse lhs set expression `%s'.\n", s.first.c_str());
			if (!RTLIL::SigSpec::parse_rhs(lhs, rhs, module, s.second))
				log_cmd_error("Failed to parse rhs set expression `%s'.\n", s.second.c_str());
			show_signal_pool.add(sigmap(lhs));
			show_signal_pool.add(sigmap(rhs));

			if (lhs.width != rhs.width)
				log_cmd_error("Set expression with different lhs and rhs sizes: %s (%s, %d bits) vs. %s (%s, %d bits)\n",
					s.first.c_str(), log_signal(lhs), lhs.width, s.second.c_str(), log_signal(rhs), rhs.width);

			log("Import set-constraint for timestep: %s = %s\n", log_signal(lhs), log_signal(rhs));
			big_lhs.remove2(lhs, &big_rhs);
			big_lhs.append(lhs);
			big_rhs.append(rhs);
		}

		for (auto &s : unsets_at[timestep])
		{
			RTLIL::SigSpec lhs;

			if (!RTLIL::SigSpec::parse(lhs, module, s))
				log_cmd_error("Failed to parse lhs set expression `%s'.\n", s.c_str());
			show_signal_pool.add(sigmap(lhs));

			log("Import unset-constraint for timestep: %s\n", log_signal(lhs));
			big_lhs.remove2(lhs, &big_rhs);
		}

		log("Final constraint equation: %s = %s\n", log_signal(big_lhs), log_signal(big_rhs));
		check_undef_enabled(big_lhs), check_undef_enabled(big_rhs);
		ez.assume(satgen.signals_eq(big_lhs, big_rhs, timestep));

		int import_cell_counter = 0;
		for (auto &c : module->cells)
			if (design->selected(module, c.second)) {
				// log("Import cell: %s\n", RTLIL::id2cstr(c.first));
				if (satgen.importCell(c.second, timestep)) {
					for (auto &p : c.second->connections)
						if (ct.cell_output(c.second->type, p.first))
							show_drivers.insert(sigmap(p.second), c.second);
					import_cell_counter++;
				} else
					log("Warning: failed to import cell %s (type %s) to SAT database.\n", RTLIL::id2cstr(c.first), RTLIL::id2cstr(c.second->type));
		}
		log("Imported %d cells to SAT database.\n", import_cell_counter);
	}

	int setup_proof(int timestep = -1)
	{
		assert(prove.size() > 0);

		RTLIL::SigSpec big_lhs, big_rhs;

		for (auto &s : prove)
		{
			RTLIL::SigSpec lhs, rhs;

			if (!RTLIL::SigSpec::parse(lhs, module, s.first))
				log_cmd_error("Failed to parse lhs proof expression `%s'.\n", s.first.c_str());
			if (!RTLIL::SigSpec::parse_rhs(lhs, rhs, module, s.second))
				log_cmd_error("Failed to parse rhs proof expression `%s'.\n", s.second.c_str());
			show_signal_pool.add(sigmap(lhs));
			show_signal_pool.add(sigmap(rhs));

			if (lhs.width != rhs.width)
				log_cmd_error("Proof expression with different lhs and rhs sizes: %s (%s, %d bits) vs. %s (%s, %d bits)\n",
					s.first.c_str(), log_signal(lhs), lhs.width, s.second.c_str(), log_signal(rhs), rhs.width);

			log("Import proof-constraint: %s = %s\n", log_signal(lhs), log_signal(rhs));
			big_lhs.remove2(lhs, &big_rhs);
			big_lhs.append(lhs);
			big_rhs.append(rhs);
		}

		log("Final proof equation: %s = %s\n", log_signal(big_lhs), log_signal(big_rhs));
		check_undef_enabled(big_lhs), check_undef_enabled(big_rhs);
		return satgen.signals_eq(big_lhs, big_rhs, timestep);
	}

	void force_unique_state(int timestep_from, int timestep_to)
	{
		RTLIL::SigSpec state_signals = satgen.initial_state.export_all();
		for (int i = timestep_from; i < timestep_to; i++)
			ez.assume(ez.NOT(satgen.signals_eq(state_signals, state_signals, i, timestep_to)));
	}

	bool solve(const std::vector<int> &assumptions)
	{
		log_assert(gotTimeout == false);
		ez.setSolverTimeout(timeout);
		bool success = ez.solve(modelExpressions, modelValues, assumptions);
		if (ez.getSolverTimoutStatus())
			gotTimeout = true;
		return success;
	}

	bool solve(int a = 0, int b = 0, int c = 0, int d = 0, int e = 0, int f = 0)
	{
		log_assert(gotTimeout == false);
		ez.setSolverTimeout(timeout);
		bool success = ez.solve(modelExpressions, modelValues, a, b, c, d, e, f);
		if (ez.getSolverTimoutStatus())
			gotTimeout = true;
		return success;
	}

	struct ModelBlockInfo {
		int timestep, offset, width;
		std::string description;
		bool operator < (const ModelBlockInfo &other) const {
			if (timestep != other.timestep)
				return timestep < other.timestep;
			if (description != other.description)
				return description < other.description;
			if (offset != other.offset)
				return offset < other.offset;
			if (width != other.width)
				return width < other.width;
			return false;
		}
	};

	std::vector<int> modelExpressions;
	std::vector<bool> modelValues;
	std::set<ModelBlockInfo> modelInfo;

	void maximize_undefs()
	{
		log_assert(enable_undef);
		std::vector<bool> backupValues;

		while (1)
		{
			std::vector<int> must_undef, maybe_undef;

			for (size_t i = 0; i < modelExpressions.size()/2; i++)
				if (modelValues.at(modelExpressions.size()/2 + i))
					must_undef.push_back(modelExpressions.at(modelExpressions.size()/2 + i));
				else
					maybe_undef.push_back(modelExpressions.at(modelExpressions.size()/2 + i));

			backupValues.swap(modelValues);
			if (!solve(ez.expression(ezSAT::OpAnd, must_undef), ez.expression(ezSAT::OpOr, maybe_undef)))
				break;
		}

		backupValues.swap(modelValues);
	}

	void generate_model()
	{
		RTLIL::SigSpec modelSig;
		modelExpressions.clear();
		modelInfo.clear();

		// Add "show" signals or alternatively the leaves on the input cone on all set and prove signals

		if (shows.size() == 0)
		{
			SigPool queued_signals, handled_signals, final_signals;
			queued_signals = show_signal_pool;
			while (queued_signals.size() > 0) {
				RTLIL::SigSpec sig = queued_signals.export_one();
				queued_signals.del(sig);
				handled_signals.add(sig);
				std::set<RTLIL::Cell*> drivers = show_drivers.find(sig);
				if (drivers.size() == 0) {
					final_signals.add(sig);
				} else {
					for (auto &d : drivers)
					for (auto &p : d->connections) {
						if (d->type == "$dff" && p.first == "\\CLK")
							continue;
						if (d->type.substr(0, 6) == "$_DFF_" && p.first == "\\C")
							continue;
						queued_signals.add(handled_signals.remove(sigmap(p.second)));
					}
				}
			}
			modelSig = final_signals.export_all();

			// additionally add all set and prove signals directly
			// (it improves user confidence if we write the constraints back ;-)
			modelSig.append(show_signal_pool.export_all());
		}
		else
		{
			for (auto &s : shows) {
				RTLIL::SigSpec sig;
				if (!RTLIL::SigSpec::parse(sig, module, s))
					log_cmd_error("Failed to parse show expression `%s'.\n", s.c_str());
				log("Import show expression: %s\n", log_signal(sig));
				modelSig.append(sig);
			}
		}

		modelSig.sort_and_unify();
		// log("Model signals: %s\n", log_signal(modelSig));

		std::vector<int> modelUndefExpressions;

		for (auto &c : modelSig.chunks)
			if (c.wire != NULL)
			{
				ModelBlockInfo info;
				RTLIL::SigSpec chunksig = c;
				info.width = chunksig.width;
				info.description = log_signal(chunksig);

				for (int timestep = -1; timestep <= max_timestep; timestep++)
				{
					if ((timestep == -1 && max_timestep > 0) || timestep == 0)
						continue;

					info.timestep = timestep;
					info.offset = modelExpressions.size();
					modelInfo.insert(info);

					std::vector<int> vec = satgen.importSigSpec(chunksig, timestep);
					modelExpressions.insert(modelExpressions.end(), vec.begin(), vec.end());

					if (enable_undef) {
						std::vector<int> undef_vec = satgen.importUndefSigSpec(chunksig, timestep);
						modelUndefExpressions.insert(modelUndefExpressions.end(), undef_vec.begin(), undef_vec.end());
					}
				}
			}

		// Add initial state signals as collected by satgen
		//
		modelSig = satgen.initial_state.export_all();
		for (auto &c : modelSig.chunks)
			if (c.wire != NULL)
			{
				ModelBlockInfo info;
				RTLIL::SigSpec chunksig = c;

				info.timestep = 0;
				info.offset = modelExpressions.size();
				info.width = chunksig.width;
				info.description = log_signal(chunksig);
				modelInfo.insert(info);

				std::vector<int> vec = satgen.importSigSpec(chunksig, 1);
				modelExpressions.insert(modelExpressions.end(), vec.begin(), vec.end());

				if (enable_undef) {
					std::vector<int> undef_vec = satgen.importUndefSigSpec(chunksig, 1);
					modelUndefExpressions.insert(modelUndefExpressions.end(), undef_vec.begin(), undef_vec.end());
				}
			}

		modelExpressions.insert(modelExpressions.end(), modelUndefExpressions.begin(), modelUndefExpressions.end());
	}

	void print_model()
	{
		int maxModelName = 10;
		int maxModelWidth = 10;

		for (auto &info : modelInfo) {
			maxModelName = std::max(maxModelName, int(info.description.size()));
			maxModelWidth = std::max(maxModelWidth, info.width);
		}

		log("\n");

		int last_timestep = -2;
		for (auto &info : modelInfo)
		{
			RTLIL::Const value;
			bool found_undef = false;

			for (int i = 0; i < info.width; i++) {
				value.bits.push_back(modelValues.at(info.offset+i) ? RTLIL::State::S1 : RTLIL::State::S0);
				if (enable_undef && modelValues.at(modelExpressions.size()/2 + info.offset + i))
					value.bits.back() = RTLIL::State::Sx, found_undef = true;
			}

			if (info.timestep != last_timestep) {
				const char *hline = "---------------------------------------------------------------------------------------------------"
						    "---------------------------------------------------------------------------------------------------"
						    "---------------------------------------------------------------------------------------------------";
				if (last_timestep == -2) {
					log(max_timestep > 0 ? "  Time " : "  ");
					log("%-*s %10s %10s %*s\n", maxModelName+10, "Signal Name", "Dec", "Hex", maxModelWidth+5, "Bin");
				}
				log(max_timestep > 0 ? "  ---- " : "  ");
				log("%*.*s %10.10s %10.10s %*.*s\n", maxModelName+10, maxModelName+10,
						hline, hline, hline, maxModelWidth+5, maxModelWidth+5, hline);
				last_timestep = info.timestep;
			}

			if (max_timestep > 0) {
				if (info.timestep > 0)
					log("  %4d ", info.timestep);
				else
					log("  init ");
			} else
				log("  ");

			if (info.width <= 32 && !found_undef)
				log("%-*s %10d %10x %*s\n", maxModelName+10, info.description.c_str(), value.as_int(), value.as_int(), maxModelWidth+5, value.as_string().c_str());
			else
				log("%-*s %10s %10s %*s\n", maxModelName+10, info.description.c_str(), "--", "--", maxModelWidth+5, value.as_string().c_str());
		}

		if (last_timestep == -2)
			log("  no model variables selected for display.\n");
	}

	void invalidate_model(bool max_undef)
	{
		std::vector<int> clause;
		if (enable_undef) {
			for (size_t i = 0; i < modelExpressions.size()/2; i++) {
				int bit = modelExpressions.at(i), bit_undef = modelExpressions.at(modelExpressions.size()/2 + i);
				bool val = modelValues.at(i), val_undef = modelValues.at(modelExpressions.size()/2 + i);
				if (!max_undef || !val_undef)
					clause.push_back(val_undef ? ez.NOT(bit_undef) : val ? ez.NOT(bit) : bit);
			}
		} else
			for (size_t i = 0; i < modelExpressions.size(); i++)
				clause.push_back(modelValues.at(i) ? ez.NOT(modelExpressions.at(i)) : modelExpressions.at(i));
		ez.assume(ez.expression(ezSAT::OpOr, clause));
	}
};

} /* namespace */

static void print_proof_failed()
{
	log("\n");
	log("   ______                   ___       ___       _ _            _ _ \n");
	log("  (_____ \\                 / __)     / __)     (_) |          | | |\n");
	log("   _____) )___ ___   ___ _| |__    _| |__ _____ _| | _____  __| | |\n");
	log("  |  ____/ ___) _ \\ / _ (_   __)  (_   __|____ | | || ___ |/ _  |_|\n");
	log("  | |   | |  | |_| | |_| || |       | |  / ___ | | || ____( (_| |_ \n");
	log("  |_|   |_|   \\___/ \\___/ |_|       |_|  \\_____|_|\\_)_____)\\____|_|\n");
	log("\n");
}

static void print_timeout()
{
	log("\n");
	log("        _____  _  _      _____ ____  _     _____\n");
	log("       /__ __\\/ \\/ \\__/|/  __//  _ \\/ \\ /\\/__ __\\\n");
	log("         / \\  | || |\\/|||  \\  | / \\|| | ||  / \\\n");
	log("         | |  | || |  |||  /_ | \\_/|| \\_/|  | |\n");
	log("         \\_/  \\_/\\_/  \\|\\____\\\\____/\\____/  \\_/\n");
	log("\n");
}

static void print_qed()
{
	log("\n");
	log("                  /$$$$$$      /$$$$$$$$     /$$$$$$$    \n");
	log("                 /$$__  $$    | $$_____/    | $$__  $$   \n");
	log("                | $$  \\ $$    | $$          | $$  \\ $$   \n");
	log("                | $$  | $$    | $$$$$       | $$  | $$   \n");
	log("                | $$  | $$    | $$__/       | $$  | $$   \n");
	log("                | $$/$$ $$    | $$          | $$  | $$   \n");
	log("                |  $$$$$$/ /$$| $$$$$$$$ /$$| $$$$$$$//$$\n");
	log("                 \\____ $$$|__/|________/|__/|_______/|__/\n");
	log("                       \\__/                              \n");
	log("\n");
}

struct SatPass : public Pass {
	SatPass() : Pass("sat", "solve a SAT problem in the circuit") { }
	virtual void help()
	{
		//   |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
		log("\n");
		log("    sat [options] [selection]\n");
		log("\n");
		log("This command solves a SAT problem defined over the currently selected circuit\n");
		log("and additional constraints passed as parameters.\n");
		log("\n");
		log("    -all\n");
		log("        show all solutions to the problem (this can grow exponentially, use\n");
		log("        -max <N> instead to get <N> solutions)\n");
		log("\n");
		log("    -max <N>\n");
		log("        like -all, but limit number of solutions to <N>\n");
		log("\n");
		log("    -enable_undef\n");
		log("        enable modeling of undef value (aka 'x-bits')\n");
		log("        this option is implied by -set-def, -set-undef et. cetera\n");
		log("\n");
		log("    -max_undef\n");
		log("        maximize the number of undef bits in solutions, giving a better\n");
		log("        picture of which input bits are actually vital to the solution.\n");
		log("\n");
		log("    -set <signal> <value>\n");
		log("        set the specified signal to the specified value.\n");
		log("\n");
	#if 0
		log("    -set-def <signal>\n");
		log("        add a constraint that all bits of the given signal must be defined\n");
		log("\n");
		log("    -set-any-undef <signal>\n");
		log("        add a constraint that at least one bit of the given signal is undefined\n");
		log("\n");
		log("    -set-all-undef <signal>\n");
		log("        add a constraint that all bits of the given signal are undefined\n");
		log("\n");
	#endif
		log("    -show <signal>\n");
		log("        show the model for the specified signal. if no -show option is\n");
		log("        passed then a set of signals to be shown is automatically selected.\n");
		log("\n");
		log("    -ignore_div_by_zero\n");
		log("        ignore all solutions that involve a division by zero\n");
		log("\n");
		log("The following options can be used to set up a sequential problem:\n");
		log("\n");
		log("    -seq <N>\n");
		log("        set up a sequential problem with <N> time steps. The steps will\n");
		log("        be numbered from 1 to N.\n");
		log("\n");
		log("    -set-at <N> <signal> <value>\n");
		log("    -unset-at <N> <signal>\n");
		log("        set or unset the specified signal to the specified value in the\n");
		log("        given timestep. this has priority over a -set for the same signal.\n");
		log("\n");
	#if 0
		log("    -set-def-at <N> <signal>\n");
		log("    -set-any-undef-at <N> <signal>\n");
		log("    -set-all-undef-at <N> <signal>\n");
		log("        add undef contraints in the given timestep.\n");
		log("\n");
	#endif
		log("    -set-init <signal> <value>\n");
		log("        set the initial value for the register driving the signal to the value\n");
		log("\n");
		log("    -set-init-undef\n");
		log("        set all initial states (not set using -set-init) to undef\n");
		log("\n");
		log("The following additional options can be used to set up a proof. If also -seq\n");
		log("is passed, a temporal induction proof is performed.\n");
		log("\n");
		log("    -prove <signal> <value>\n");
		log("        Attempt to proof that <signal> is always <value>. In a temporal\n");
		log("        induction proof it is proven that the condition holds forever after\n");
		log("        the number of time steps passed using -seq.\n");
		log("\n");
		log("    -maxsteps <N>\n");
		log("        Set a maximum length for the induction.\n");
		log("\n");
		log("    -timeout <N>\n");
		log("        Maximum number of seconds a single SAT instance may take.\n");
		log("\n");
		log("    -verify\n");
		log("        Return an error and stop the synthesis script if the proof fails.\n");
		log("\n");
		log("    -verify-no-timeout\n");
		log("        Like -verify but do not return an error for timeouts.\n");
		log("\n");
	}
	virtual void execute(std::vector<std::string> args, RTLIL::Design *design)
	{
		std::vector<std::pair<std::string, std::string>> sets, sets_init, prove;
		std::map<int, std::vector<std::pair<std::string, std::string>>> sets_at;
		std::map<int, std::vector<std::string>> unsets_at, sets_def_at, sets_any_undef_at, sets_all_undef_at;
		std::vector<std::string> shows, sets_def, sets_any_undef, sets_all_undef;
		int loopcount = 0, seq_len = 0, maxsteps = 0, timeout = 0;
		bool verify = false, fail_on_timeout = false, enable_undef = false;
		bool ignore_div_by_zero = false, set_init_undef = false, max_undef = true;

		log_header("Executing SAT pass (solving SAT problems in the circuit).\n");

		size_t argidx;
		for (argidx = 1; argidx < args.size(); argidx++) {
			if (args[argidx] == "-all") {
				loopcount = -1;
				continue;
			}
			if (args[argidx] == "-verify") {
				fail_on_timeout = true;
				verify = true;
				continue;
			}
			if (args[argidx] == "-verify-no-timeout") {
				verify = true;
				continue;
			}
			if (args[argidx] == "-timeout" && argidx+1 < args.size()) {
				timeout = atoi(args[++argidx].c_str());
				continue;
			}
			if (args[argidx] == "-max" && argidx+1 < args.size()) {
				loopcount = atoi(args[++argidx].c_str());
				continue;
			}
			if (args[argidx] == "-maxsteps" && argidx+1 < args.size()) {
				maxsteps = atoi(args[++argidx].c_str());
				continue;
			}
			if (args[argidx] == "-ignore_div_by_zero") {
				ignore_div_by_zero = true;
				continue;
			}
			if (args[argidx] == "-enable_undef") {
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-max_undef") {
				enable_undef = true;
				max_undef = true;
				continue;
			}
			if (args[argidx] == "-set" && argidx+2 < args.size()) {
				std::string lhs = args[++argidx];
				std::string rhs = args[++argidx];
				sets.push_back(std::pair<std::string, std::string>(lhs, rhs));
				continue;
			}
			if (args[argidx] == "-set-def" && argidx+1 < args.size()) {
				sets_def.push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-set-any-undef" && argidx+1 < args.size()) {
				sets_any_undef.push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-set-all-undef" && argidx+1 < args.size()) {
				sets_all_undef.push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-prove" && argidx+2 < args.size()) {
				std::string lhs = args[++argidx];
				std::string rhs = args[++argidx];
				prove.push_back(std::pair<std::string, std::string>(lhs, rhs));
				continue;
			}
			if (args[argidx] == "-seq" && argidx+1 < args.size()) {
				seq_len = atoi(args[++argidx].c_str());
				continue;
			}
			if (args[argidx] == "-set-at" && argidx+3 < args.size()) {
				int timestep = atoi(args[++argidx].c_str());
				std::string lhs = args[++argidx];
				std::string rhs = args[++argidx];
				sets_at[timestep].push_back(std::pair<std::string, std::string>(lhs, rhs));
				continue;
			}
			if (args[argidx] == "-unset-at" && argidx+2 < args.size()) {
				int timestep = atoi(args[++argidx].c_str());
				unsets_at[timestep].push_back(args[++argidx]);
				continue;
			}
			if (args[argidx] == "-set-def-at" && argidx+2 < args.size()) {
				int timestep = atoi(args[++argidx].c_str());
				sets_def_at[timestep].push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-set-any-undef-at" && argidx+2 < args.size()) {
				int timestep = atoi(args[++argidx].c_str());
				sets_any_undef_at[timestep].push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-set-all-undef-at" && argidx+2 < args.size()) {
				int timestep = atoi(args[++argidx].c_str());
				sets_all_undef_at[timestep].push_back(args[++argidx]);
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-set-init" && argidx+2 < args.size()) {
				std::string lhs = args[++argidx];
				std::string rhs = args[++argidx];
				sets_init.push_back(std::pair<std::string, std::string>(lhs, rhs));
				continue;
			}
			if (args[argidx] == "-set-init-undef") {
				set_init_undef = true;
				enable_undef = true;
				continue;
			}
			if (args[argidx] == "-show" && argidx+1 < args.size()) {
				shows.push_back(args[++argidx]);
				continue;
			}
			break;
		}
		extra_args(args, argidx, design);

		RTLIL::Module *module = NULL;
		for (auto &mod_it : design->modules)
			if (design->selected(mod_it.second)) {
				if (module)
					log_cmd_error("Only one module must be selected for the SAT pass! (selected: %s and %s)\n",
							RTLIL::id2cstr(module->name), RTLIL::id2cstr(mod_it.first));
				module = mod_it.second;
			}
		if (module == NULL) 
			log_cmd_error("Can't perform SAT on an empty selection!\n");

		if (prove.size() == 0 && verify)
			log_cmd_error("Got -verify but nothing to prove!\n");

		if (prove.size() > 0 && seq_len > 0)
		{
			if (loopcount > 0 || max_undef)
				log_cmd_error("The options -max, -all, and -max_undef are not supported for temporal induction proofs!\n");

			SatHelper basecase(design, module, enable_undef);
			SatHelper inductstep(design, module, enable_undef);

			basecase.sets = sets;
			basecase.prove = prove;
			basecase.sets_at = sets_at;
			basecase.unsets_at = unsets_at;
			basecase.shows = shows;
			basecase.timeout = timeout;
			basecase.sets_def = sets_def;
			basecase.sets_any_undef = sets_any_undef;
			basecase.sets_all_undef = sets_all_undef;
			basecase.sets_def_at = sets_def_at;
			basecase.sets_any_undef_at = sets_any_undef_at;
			basecase.sets_all_undef_at = sets_all_undef_at;
			basecase.sets_init = sets_init;
			basecase.set_init_undef = set_init_undef;
			basecase.satgen.ignore_div_by_zero = ignore_div_by_zero;

			for (int timestep = 1; timestep <= seq_len; timestep++)
				basecase.setup(timestep);
			basecase.setup_init();

			inductstep.sets = sets;
			inductstep.prove = prove;
			inductstep.shows = shows;
			inductstep.timeout = timeout;
			inductstep.sets_def = sets_def;
			inductstep.sets_any_undef = sets_any_undef;
			inductstep.sets_all_undef = sets_all_undef;
			inductstep.sets_def_at = sets_def_at;
			inductstep.sets_any_undef_at = sets_any_undef_at;
			inductstep.sets_all_undef_at = sets_all_undef_at;
			inductstep.sets_init = sets_init;
			inductstep.set_init_undef = set_init_undef;
			inductstep.satgen.ignore_div_by_zero = ignore_div_by_zero;

			inductstep.setup(1);
			inductstep.ez.assume(inductstep.setup_proof(1));

			for (int inductlen = 1; inductlen <= maxsteps || maxsteps == 0; inductlen++)
			{
				log("\n** Trying induction with length %d **\n", inductlen);

				// phase 1: proving base case

				basecase.setup(seq_len + inductlen);
				int property = basecase.setup_proof(seq_len + inductlen);
				basecase.generate_model();

				if (inductlen > 1)
					basecase.force_unique_state(seq_len + 1, seq_len + inductlen);

				log("\n[base case] Solving problem with %d variables and %d clauses..\n",
						basecase.ez.numCnfVariables(), basecase.ez.numCnfClauses());

				if (basecase.solve(basecase.ez.NOT(property))) {
					log("SAT temporal induction proof finished - model found for base case: FAIL!\n");
					print_proof_failed();
					basecase.print_model();
					goto tip_failed;
				}

				if (basecase.gotTimeout)
					goto timeout;

				log("Base case for induction length %d proven.\n", inductlen);
				basecase.ez.assume(property);

				// phase 2: proving induction step

				inductstep.setup(inductlen + 1);
				property = inductstep.setup_proof(inductlen + 1);
				inductstep.generate_model();

				if (inductlen > 1)
					inductstep.force_unique_state(1, inductlen + 1);

				log("\n[induction step] Solving problem with %d variables and %d clauses..\n",
						inductstep.ez.numCnfVariables(), inductstep.ez.numCnfClauses());

				if (!inductstep.solve(inductstep.ez.NOT(property))) {
					if (inductstep.gotTimeout)
						goto timeout;
					log("Induction step proven: SUCCESS!\n");
					print_qed();
					goto tip_success;
				}

				log("Induction step failed. Incrementing induction length.\n");
				inductstep.ez.assume(property);

				inductstep.print_model();
			}

			log("\nReached maximum number of time steps -> proof failed.\n");
			print_proof_failed();

		tip_failed:
			if (verify) {
				log("\n");
				log_error("Called with -verify and proof did fail!\n");
			}

		tip_success:;
		}
		else
		{
			if (maxsteps > 0)
				log_cmd_error("The options -maxsteps is only supported for temporal induction proofs!\n");

			SatHelper sathelper(design, module, enable_undef);

			sathelper.sets = sets;
			sathelper.prove = prove;
			sathelper.sets_at = sets_at;
			sathelper.unsets_at = unsets_at;
			sathelper.shows = shows;
			sathelper.timeout = timeout;
			sathelper.sets_def = sets_def;
			sathelper.sets_any_undef = sets_any_undef;
			sathelper.sets_all_undef = sets_all_undef;
			sathelper.sets_def_at = sets_def_at;
			sathelper.sets_any_undef_at = sets_any_undef_at;
			sathelper.sets_all_undef_at = sets_all_undef_at;
			sathelper.sets_init = sets_init;
			sathelper.set_init_undef = set_init_undef;
			sathelper.satgen.ignore_div_by_zero = ignore_div_by_zero;

			if (seq_len == 0) {
				sathelper.setup();
				if (sathelper.prove.size() > 0)
					sathelper.ez.assume(sathelper.ez.NOT(sathelper.setup_proof()));
			} else {
				for (int timestep = 1; timestep <= seq_len; timestep++)
					sathelper.setup(timestep);
				sathelper.setup_init();
			}
			sathelper.generate_model();

#if 0
			// print CNF for debugging
			sathelper.ez.printDIMACS(stdout, true);
#endif

			int rerun_counter = 0;

		rerun_solver:
			log("\nSolving problem with %d variables and %d clauses..\n",
					sathelper.ez.numCnfVariables(), sathelper.ez.numCnfClauses());

			if (sathelper.solve())
			{
				if (max_undef) {
					log("SAT model found. maximizing number of undefs.\n");
					sathelper.maximize_undefs();
				}

				if (prove.size() == 0) {
					log("SAT solving finished - model found:\n");
				} else {
					log("SAT proof finished - model found: FAIL!\n");
					print_proof_failed();
				}

				sathelper.print_model();

				if (loopcount != 0) {
					loopcount--, rerun_counter++;
					sathelper.invalidate_model(max_undef);
					goto rerun_solver;
				}

				if (verify) {
					log("\n");
					log_error("Called with -verify and proof did fail!\n");
				}
			}
			else
			{
				if (sathelper.gotTimeout)
					goto timeout;
				if (rerun_counter)
					log("SAT solving finished - no more models found (after %d distinct solutions).\n", rerun_counter);
				else if (prove.size() == 0)
					log("SAT solving finished - no model found.\n");
				else {
					log("SAT proof finished - no model found: SUCCESS!\n");
					print_qed();
				}
			}

			if (verify && rerun_counter) {
				log("\n");
				log_error("Called with -verify and proof did fail!\n");
			}
		}

		if (0) {
	timeout:
			log("Interrupted SAT solver: TIMEOUT!\n");
			print_timeout();
			if (fail_on_timeout)
				log_error("Called with -verify and proof did time out!\n");
		}
	}
} SatPass;