12 files changed, 186 insertions, 139 deletions

diff --git a/kernel/register.cc b/kernel/register.cc
index cdba4c36..af1cb77b 100644
--- a/kernel/register.cc
+++ b/kernel/register.cc
@@ -18,6 +18,8 @@
  */
 
 #include "kernel/yosys.h"
+#include "kernel/satgen.h"
+
 #include <string.h>
 #include <stdlib.h>
 #include <stdio.h>
@@ -691,6 +693,18 @@ struct EchoPass : public Pass {
 		log("echo %s\n", echo_mode ? "on" : "off");
 	}
 } EchoPass;
+
+SatSolver *yosys_satsolver_list;
+SatSolver *yosys_satsolver;
+
+struct MinisatSatSolver : public SatSolver {
+	MinisatSatSolver() : SatSolver("minisat") {
+		yosys_satsolver = this;
+	}
+	virtual ezSAT *create() YS_OVERRIDE {
+		return new ezMiniSAT();
+	}
+} MinisatSatSolver;
  
 YOSYS_NAMESPACE_END
 
diff --git a/kernel/satgen.h b/kernel/satgen.h
index 2f5efe67..093d248d 100644
--- a/kernel/satgen.h
+++ b/kernel/satgen.h
@@ -29,7 +29,37 @@
 
 YOSYS_NAMESPACE_BEGIN
 
-typedef ezMiniSAT ezDefaultSAT;
+// defined in kernel/register.cc
+extern struct SatSolver *yosys_satsolver_list;
+extern struct SatSolver *yosys_satsolver;
+
+struct SatSolver
+{
+	string name;
+	SatSolver *next;
+	virtual ezSAT *create() = 0;
+
+	SatSolver(string name) : name(name) {
+		next = yosys_satsolver_list;
+		yosys_satsolver_list = this;
+	}
+
+	virtual ~SatSolver() {
+		auto p = &yosys_satsolver_list;
+		while (*p) {
+			if (*p == this)
+				*p = next;
+			else
+				p = &(*p)->next;
+		}
+		if (yosys_satsolver == this)
+			yosys_satsolver = yosys_satsolver_list;
+	}
+};
+
+struct ezSatPtr : public std::unique_ptr<ezSAT> {
+	ezSatPtr() : unique_ptr<ezSAT>(yosys_satsolver->create()) { }
+};
 
 struct SatGen
 {
diff --git a/kernel/yosys.h b/kernel/yosys.h
index 47275ecd..467d2074 100644
--- a/kernel/yosys.h
+++ b/kernel/yosys.h
@@ -49,6 +49,7 @@
 #include <unordered_set>
 #include <initializer_list>
 #include <stdexcept>
+#include <memory>
 
 #include <sstream>
 #include <fstream>
diff --git a/passes/equiv/equiv_induct.cc b/passes/equiv/equiv_induct.cc
index c5b4eda7..a56730d4 100644
--- a/passes/equiv/equiv_induct.cc
+++ b/passes/equiv/equiv_induct.cc
@@ -32,7 +32,7 @@ struct EquivInductWorker
 	vector<Cell*> cells;
 	pool<Cell*> workset;
 
-	ezDefaultSAT ez;
+	ezSatPtr ez;
 	SatGen satgen;
 
 	int max_seq;
@@ -43,7 +43,8 @@ struct EquivInductWorker
 	SigPool undriven_signals;
 
 	EquivInductWorker(Module *module, const pool<Cell*> &unproven_equiv_cells, bool model_undef, int max_seq) : module(module), sigmap(module),
-			cells(module->selected_cells()), workset(unproven_equiv_cells), satgen(&ez, &sigmap), max_seq(max_seq), success_counter(0)
+			cells(module->selected_cells()), workset(unproven_equiv_cells),
+			satgen(ez.get(), &sigmap), max_seq(max_seq), success_counter(0)
 	{
 		satgen.model_undef = model_undef;
 	}
@@ -63,9 +64,9 @@ struct EquivInductWorker
 				if (bit_a != bit_b) {
 					int ez_a = satgen.importSigBit(bit_a, step);
 					int ez_b = satgen.importSigBit(bit_b, step);
-					int cond = ez.IFF(ez_a, ez_b);
+					int cond = ez->IFF(ez_a, ez_b);
 					if (satgen.model_undef)
-						cond = ez.OR(cond, satgen.importUndefSigBit(bit_a, step));
+						cond = ez->OR(cond, satgen.importUndefSigBit(bit_a, step));
 					ez_equal_terms.push_back(cond);
 				}
 			}
@@ -73,11 +74,11 @@ struct EquivInductWorker
 
 		if (satgen.model_undef) {
 			for (auto bit : undriven_signals.export_all())
-				ez.assume(ez.NOT(satgen.importUndefSigBit(bit, step)));
+				ez->assume(ez->NOT(satgen.importUndefSigBit(bit, step)));
 		}
 
 		log_assert(!ez_step_is_consistent.count(step));
-		ez_step_is_consistent[step] = ez.expression(ez.OpAnd, ez_equal_terms);
+		ez_step_is_consistent[step] = ez->expression(ez->OpAnd, ez_equal_terms);
 	}
 
 	void run()
@@ -101,27 +102,27 @@ struct EquivInductWorker
 
 		if (satgen.model_undef) {
 			for (auto bit : satgen.initial_state.export_all())
-				ez.assume(ez.NOT(satgen.importUndefSigBit(bit, 1)));
+				ez->assume(ez->NOT(satgen.importUndefSigBit(bit, 1)));
 			log("  Undef modelling: force def on %d initial reg values and %d inputs.\n",
 				GetSize(satgen.initial_state), GetSize(undriven_signals));
 		}
 
 		for (int step = 1; step <= max_seq; step++)
 		{
-			ez.assume(ez_step_is_consistent[step]);
+			ez->assume(ez_step_is_consistent[step]);
 
-			log("  Proving existence of base case for step %d. (%d clauses over %d variables)\n", step, ez.numCnfClauses(), ez.numCnfVariables());
-			if (!ez.solve()) {
+			log("  Proving existence of base case for step %d. (%d clauses over %d variables)\n", step, ez->numCnfClauses(), ez->numCnfVariables());
+			if (!ez->solve()) {
 				log("  Proof for base case failed. Circuit inherently diverges!\n");
 				return;
 			}
 
 			create_timestep(step+1);
-			int new_step_not_consistent = ez.NOT(ez_step_is_consistent[step+1]);
-			ez.bind(new_step_not_consistent);
+			int new_step_not_consistent = ez->NOT(ez_step_is_consistent[step+1]);
+			ez->bind(new_step_not_consistent);
 
-			log("  Proving induction step %d. (%d clauses over %d variables)\n", step, ez.numCnfClauses(), ez.numCnfVariables());
-			if (!ez.solve(new_step_not_consistent)) {
+			log("  Proving induction step %d. (%d clauses over %d variables)\n", step, ez->numCnfClauses(), ez->numCnfVariables());
+			if (!ez->solve(new_step_not_consistent)) {
 				log("  Proof for induction step holds. Entire workset of %d cells proven!\n", GetSize(workset));
 				for (auto cell : workset)
 					cell->setPort("\\B", cell->getPort("\\A"));
@@ -143,12 +144,12 @@ struct EquivInductWorker
 
 			int ez_a = satgen.importSigBit(bit_a, max_seq+1);
 			int ez_b = satgen.importSigBit(bit_b, max_seq+1);
-			int cond = ez.XOR(ez_a, ez_b);
+			int cond = ez->XOR(ez_a, ez_b);
 
 			if (satgen.model_undef)
-				cond = ez.AND(cond, ez.NOT(satgen.importUndefSigBit(bit_a, max_seq+1)));
+				cond = ez->AND(cond, ez->NOT(satgen.importUndefSigBit(bit_a, max_seq+1)));
 
-			if (!ez.solve(cond)) {
+			if (!ez->solve(cond)) {
 				log(" success!\n");
 				cell->setPort("\\B", cell->getPort("\\A"));
 				success_counter++;
diff --git a/passes/equiv/equiv_simple.cc b/passes/equiv/equiv_simple.cc
index 579877e6..f1b66432 100644
--- a/passes/equiv/equiv_simple.cc
+++ b/passes/equiv/equiv_simple.cc
@@ -32,7 +32,7 @@ struct EquivSimpleWorker
 	SigMap &sigmap;
 	dict<SigBit, Cell*> &bit2driver;
 
-	ezDefaultSAT ez;
+	ezSatPtr ez;
 	SatGen satgen;
 	int max_seq;
 	bool verbose;
@@ -41,7 +41,7 @@ struct EquivSimpleWorker
 
 	EquivSimpleWorker(const vector<Cell*> &equiv_cells, SigMap &sigmap, dict<SigBit, Cell*> &bit2driver, int max_seq, bool verbose, bool model_undef) :
 			module(equiv_cells.front()->module), equiv_cells(equiv_cells), equiv_cell(nullptr),
-			sigmap(sigmap), bit2driver(bit2driver), satgen(&ez, &sigmap), max_seq(max_seq), verbose(verbose)
+			sigmap(sigmap), bit2driver(bit2driver), satgen(ez.get(), &sigmap), max_seq(max_seq), verbose(verbose)
 	{
 		satgen.model_undef = model_undef;
 	}
@@ -91,7 +91,7 @@ struct EquivSimpleWorker
 	{
 		SigBit bit_a = sigmap(equiv_cell->getPort("\\A")).to_single_sigbit();
 		SigBit bit_b = sigmap(equiv_cell->getPort("\\B")).to_single_sigbit();
-		int ez_context = ez.frozen_literal();
+		int ez_context = ez->frozen_literal();
 
 		if (satgen.model_undef)
 		{
@@ -99,14 +99,14 @@ struct EquivSimpleWorker
 			int ez_b = satgen.importDefSigBit(bit_b, max_seq+1);
 			int ez_undef_a = satgen.importUndefSigBit(bit_a, max_seq+1);
 
-			ez.assume(ez.XOR(ez_a, ez_b), ez_context);
-			ez.assume(ez.NOT(ez_undef_a), ez_context);
+			ez->assume(ez->XOR(ez_a, ez_b), ez_context);
+			ez->assume(ez->NOT(ez_undef_a), ez_context);
 		}
 		else
 		{
 			int ez_a = satgen.importSigBit(bit_a, max_seq+1);
 			int ez_b = satgen.importSigBit(bit_b, max_seq+1);
-			ez.assume(ez.XOR(ez_a, ez_b), ez_context);
+			ez->assume(ez->XOR(ez_a, ez_b), ez_context);
 		}
 
 		pool<SigBit> seed_a = { bit_a };
@@ -168,16 +168,16 @@ struct EquivSimpleWorker
 
 			if (satgen.model_undef) {
 				for (auto bit : input_bits)
-					ez.assume(ez.NOT(satgen.importUndefSigBit(bit, step+1)));
+					ez->assume(ez->NOT(satgen.importUndefSigBit(bit, step+1)));
 			}
 
 			if (verbose)
-				log("    Problem size at t=%d: %d literals, %d clauses\n", step, ez.numCnfVariables(), ez.numCnfClauses());
+				log("    Problem size at t=%d: %d literals, %d clauses\n", step, ez->numCnfVariables(), ez->numCnfClauses());
 
-			if (!ez.solve(ez_context)) {
+			if (!ez->solve(ez_context)) {
 				log(verbose ? "    Proved equivalence! Marking $equiv cell as proven.\n" : " success!\n");
 				equiv_cell->setPort("\\B", equiv_cell->getPort("\\A"));
-				ez.assume(ez.NOT(ez_context));
+				ez->assume(ez->NOT(ez_context));
 				return true;
 			}
 
@@ -224,7 +224,7 @@ struct EquivSimpleWorker
 		if (!verbose)
 			log(" failed.\n");
 
-		ez.assume(ez.NOT(ez_context));
+		ez->assume(ez->NOT(ez_context));
 		return false;
 	}
 
diff --git a/passes/memory/memory_share.cc b/passes/memory/memory_share.cc
index a2f89f6d..3d241433 100644
--- a/passes/memory/memory_share.cc
+++ b/passes/memory/memory_share.cc
@@ -489,8 +489,8 @@ struct MemoryShareWorker
 		if (wr_ports.size() <= 1)
 			return;
 
-		ezDefaultSAT ez;
-		SatGen satgen(&ez, &modwalker.sigmap);
+		ezSatPtr ez;
+		SatGen satgen(ez.get(), &modwalker.sigmap);
 
 		// find list of considered ports and port pairs
 
@@ -553,7 +553,7 @@ struct MemoryShareWorker
 			if (considered_port_pairs.count(i) || considered_port_pairs.count(i+1))
 			{
 				RTLIL::SigSpec sig = modwalker.sigmap(wr_ports[i]->getPort("\\EN"));
-				port_to_sat_variable[i] = ez.expression(ez.OpOr, satgen.importSigSpec(sig));
+				port_to_sat_variable[i] = ez->expression(ez->OpOr, satgen.importSigSpec(sig));
 
 				std::vector<RTLIL::SigBit> bits = sig;
 				bits_queue.insert(bits.begin(), bits.end());
@@ -582,7 +582,7 @@ struct MemoryShareWorker
 			vector<int> ez_wire_bits = satgen.importSigSpec(wire);
 			for (int i : ez_wire_bits)
 			for (int j : ez_wire_bits)
-				if (i != j) ez.assume(ez.NOT(i), j);
+				if (i != j) ez->assume(ez->NOT(i), j);
 		}
 
 		log("  Common input cone for all EN signals: %d cells.\n", int(sat_cells.size()));
@@ -590,7 +590,7 @@ struct MemoryShareWorker
 		for (auto cell : sat_cells)
 			satgen.importCell(cell);
 
-		log("  Size of unconstrained SAT problem: %d variables, %d clauses\n", ez.numCnfVariables(), ez.numCnfClauses());
+		log("  Size of unconstrained SAT problem: %d variables, %d clauses\n", ez->numCnfVariables(), ez->numCnfClauses());
 
 		// merge subsequent ports if possible
 
@@ -599,13 +599,13 @@ struct MemoryShareWorker
 			if (!considered_port_pairs.count(i))
 				continue;
 
-			if (ez.solve(port_to_sat_variable.at(i-1), port_to_sat_variable.at(i))) {
+			if (ez->solve(port_to_sat_variable.at(i-1), port_to_sat_variable.at(i))) {
 				log("  According to SAT solver sharing of port %d with port %d is not possible.\n", i-1, i);
 				continue;
 			}
 
 			log("  Merging port %d into port %d.\n", i-1, i);
-			port_to_sat_variable.at(i) = ez.OR(port_to_sat_variable.at(i-1), port_to_sat_variable.at(i));
+			port_to_sat_variable.at(i) = ez->OR(port_to_sat_variable.at(i-1), port_to_sat_variable.at(i));
 
 			RTLIL::SigSpec last_addr = wr_ports[i-1]->getPort("\\ADDR");
 			RTLIL::SigSpec last_data = wr_ports[i-1]->getPort("\\DATA");
diff --git a/passes/opt/share.cc b/passes/opt/share.cc
index 9cd0ccc0..bf406bcd 100644
--- a/passes/opt/share.cc
+++ b/passes/opt/share.cc
@@ -1180,8 +1180,8 @@ struct ShareWorker
 				optimize_activation_patterns(filtered_cell_activation_patterns);
 				optimize_activation_patterns(filtered_other_cell_activation_patterns);
 
-				ezDefaultSAT ez;
-				SatGen satgen(&ez, &modwalker.sigmap);
+				ezSatPtr ez;
+				SatGen satgen(ez.get(), &modwalker.sigmap);
 
 				pool<RTLIL::Cell*> sat_cells;
 				std::set<RTLIL::SigBit> bits_queue;
@@ -1191,13 +1191,13 @@ struct ShareWorker
 
 				for (auto &p : filtered_cell_activation_patterns) {
 					log("      Activation pattern for cell %s: %s = %s\n", log_id(cell), log_signal(p.first), log_signal(p.second));
-					cell_active.push_back(ez.vec_eq(satgen.importSigSpec(p.first), satgen.importSigSpec(p.second)));
+					cell_active.push_back(ez->vec_eq(satgen.importSigSpec(p.first), satgen.importSigSpec(p.second)));
 					all_ctrl_signals.append(p.first);
 				}
 
 				for (auto &p : filtered_other_cell_activation_patterns) {
 					log("      Activation pattern for cell %s: %s = %s\n", log_id(other_cell), log_signal(p.first), log_signal(p.second));
-					other_cell_active.push_back(ez.vec_eq(satgen.importSigSpec(p.first), satgen.importSigSpec(p.second)));
+					other_cell_active.push_back(ez->vec_eq(satgen.importSigSpec(p.first), satgen.importSigSpec(p.second)));
 					all_ctrl_signals.append(p.first);
 				}
 
@@ -1232,36 +1232,36 @@ struct ShareWorker
 						log("      Adding exclusive control bits: %s vs. %s\n", log_signal(it.first), log_signal(it.second));
 						int sub1 = satgen.importSigBit(it.first);
 						int sub2 = satgen.importSigBit(it.second);
-						ez.assume(ez.NOT(ez.AND(sub1, sub2)));
+						ez->assume(ez->NOT(ez->AND(sub1, sub2)));
 					}
 
-				if (!ez.solve(ez.expression(ez.OpOr, cell_active))) {
+				if (!ez->solve(ez->expression(ez->OpOr, cell_active))) {
 					log("      According to the SAT solver the cell %s is never active. Sharing is pointless, we simply remove it.\n", log_id(cell));
 					cells_to_remove.insert(cell);
 					break;
 				}
 
-				if (!ez.solve(ez.expression(ez.OpOr, other_cell_active))) {
+				if (!ez->solve(ez->expression(ez->OpOr, other_cell_active))) {
 					log("      According to the SAT solver the cell %s is never active. Sharing is pointless, we simply remove it.\n", log_id(other_cell));
 					cells_to_remove.insert(other_cell);
 					shareable_cells.erase(other_cell);
 					continue;
 				}
 
-				ez.non_incremental();
+				ez->non_incremental();
 
 				all_ctrl_signals.sort_and_unify();
 				std::vector<int> sat_model = satgen.importSigSpec(all_ctrl_signals);
 				std::vector<bool> sat_model_values;
 
-				int sub1 = ez.expression(ez.OpOr, cell_active);
-				int sub2 = ez.expression(ez.OpOr, other_cell_active);
-				ez.assume(ez.AND(sub1, sub2));
+				int sub1 = ez->expression(ez->OpOr, cell_active);
+				int sub2 = ez->expression(ez->OpOr, other_cell_active);
+				ez->assume(ez->AND(sub1, sub2));
 
 				log("      Size of SAT problem: %d cells, %d variables, %d clauses\n",
-						GetSize(sat_cells), ez.numCnfVariables(), ez.numCnfClauses());
+						GetSize(sat_cells), ez->numCnfVariables(), ez->numCnfClauses());
 
-				if (ez.solve(sat_model, sat_model_values)) {
+				if (ez->solve(sat_model, sat_model_values)) {
 					log("      According to the SAT solver this pair of cells can not be shared.\n");
 					log("      Model from SAT solver: %s = %d'", log_signal(all_ctrl_signals), GetSize(sat_model_values));
 					for (int i = GetSize(sat_model_values)-1; i >= 0; i--)
diff --git a/passes/sat/eval.cc b/passes/sat/eval.cc
index 62534ec0..01d0e031 100644
--- a/passes/sat/eval.cc
+++ b/passes/sat/eval.cc
@@ -143,16 +143,16 @@ struct VlogHammerReporter
 	{
 		log("Verifying SAT model (%s)..\n", model_undef ? "with undef" : "without undef");
 
-		ezDefaultSAT ez;
+		ezSatPtr ez;
 		SigMap sigmap(module);
-		SatGen satgen(&ez, &sigmap);
+		SatGen satgen(ez.get(), &sigmap);
 		satgen.model_undef = model_undef;
 
 		for (auto &c : module->cells_)
 			if (!satgen.importCell(c.second))
 				log_error("Failed to import cell %s (type %s) to SAT database.\n", RTLIL::id2cstr(c.first), RTLIL::id2cstr(c.second->type));
 
-		ez.assume(satgen.signals_eq(recorded_set_vars, recorded_set_vals));
+		ez->assume(satgen.signals_eq(recorded_set_vars, recorded_set_vals));
 
 		std::vector<int> y_vec = satgen.importDefSigSpec(module->wires_.at("\\y"));
 		std::vector<bool> y_values;
@@ -163,9 +163,9 @@ struct VlogHammerReporter
 		}
 
 		log("  Created SAT problem with %d variables and %d clauses.\n",
-				ez.numCnfVariables(), ez.numCnfClauses());
+				ez->numCnfVariables(), ez->numCnfClauses());
 
-		if (!ez.solve(y_vec, y_values))
+		if (!ez->solve(y_vec, y_values))
 			log_error("Failed to find solution to SAT problem.\n");
 
 		for (int i = 0; i < expected_y.size(); i++) {
@@ -204,7 +204,7 @@ struct VlogHammerReporter
 				if (y_undef.at(i))
 				{
 					log("    Toggling undef bit %d to test undef gating.\n", i);
-					if (!ez.solve(y_vec, y_values, ez.IFF(y_vec.at(i), y_values.at(i) ? ez.CONST_FALSE : ez.CONST_TRUE)))
+					if (!ez->solve(y_vec, y_values, ez->IFF(y_vec.at(i), y_values.at(i) ? ez->CONST_FALSE : ez->CONST_TRUE)))
 						log_error("Failed to find solution with toggled bit!\n");
 
 					cmp_vars.push_back(y_vec.at(expected_y.size() + i));
@@ -220,15 +220,15 @@ struct VlogHammerReporter
 				}
 
 			log("    Testing if SAT solution is unique.\n");
-			ez.assume(ez.vec_ne(cmp_vars, ez.vec_const(cmp_vals)));
-			if (ez.solve(y_vec, y_values))
+			ez->assume(ez->vec_ne(cmp_vars, ez->vec_const(cmp_vals)));
+			if (ez->solve(y_vec, y_values))
 				log_error("Found two distinct solutions to SAT problem.\n");
 		}
 		else
 		{
 			log("    Testing if SAT solution is unique.\n");
-			ez.assume(ez.vec_ne(y_vec, ez.vec_const(y_values)));
-			if (ez.solve(y_vec, y_values))
+			ez->assume(ez->vec_ne(y_vec, ez->vec_const(y_values)));
+			if (ez->solve(y_vec, y_values))
 				log_error("Found two distinct solutions to SAT problem.\n");
 		}
 
diff --git a/passes/sat/freduce.cc b/passes/sat/freduce.cc
index fbca3586..8a5301ec 100644
--- a/passes/sat/freduce.cc
+++ b/passes/sat/freduce.cc
@@ -73,7 +73,7 @@ struct FindReducedInputs
 	SigMap &sigmap;
 	drivers_t &drivers;
 
-	ezDefaultSAT ez;
+	ezSatPtr ez;
 	std::set<RTLIL::Cell*> ez_cells;
 	SatGen satgen;
 
@@ -81,7 +81,7 @@ struct FindReducedInputs
 	std::vector<int> sat_pi_uniq_bitvec;
 
 	FindReducedInputs(SigMap &sigmap, drivers_t &drivers) :
-			sigmap(sigmap), drivers(drivers), satgen(&ez, &sigmap)
+			sigmap(sigmap), drivers(drivers), satgen(ez.get(), &sigmap)
 	{
 		satgen.model_undef = true;
 	}
@@ -104,30 +104,30 @@ struct FindReducedInputs
 
 		satgen.setContext(&sigmap, "A");
 		int sat_a = satgen.importSigSpec(bit).front();
-		ez.assume(ez.NOT(satgen.importUndefSigSpec(bit).front()));
+		ez->assume(ez->NOT(satgen.importUndefSigSpec(bit).front()));
 
 		satgen.setContext(&sigmap, "B");
 		int sat_b = satgen.importSigSpec(bit).front();
-		ez.assume(ez.NOT(satgen.importUndefSigSpec(bit).front()));
+		ez->assume(ez->NOT(satgen.importUndefSigSpec(bit).front()));
 
 		int idx = sat_pi.size();
 		size_t idx_bits = get_bits(idx);
 
 		if (sat_pi_uniq_bitvec.size() != idx_bits) {
-			sat_pi_uniq_bitvec.push_back(ez.frozen_literal(stringf("uniq_%d", int(idx_bits)-1)));
+			sat_pi_uniq_bitvec.push_back(ez->frozen_literal(stringf("uniq_%d", int(idx_bits)-1)));
 			for (auto &it : sat_pi)
-				ez.assume(ez.OR(ez.NOT(it.second), ez.NOT(sat_pi_uniq_bitvec.back())));
+				ez->assume(ez->OR(ez->NOT(it.second), ez->NOT(sat_pi_uniq_bitvec.back())));
 		}
 		log_assert(sat_pi_uniq_bitvec.size() == idx_bits);
 
-		sat_pi[bit] = ez.frozen_literal(stringf("p, falsei_%s", log_signal(bit)));
-		ez.assume(ez.IFF(ez.XOR(sat_a, sat_b), sat_pi[bit]));
+		sat_pi[bit] = ez->frozen_literal(stringf("p, falsei_%s", log_signal(bit)));
+		ez->assume(ez->IFF(ez->XOR(sat_a, sat_b), sat_pi[bit]));
 
 		for (size_t i = 0; i < idx_bits; i++)
 			if ((idx & (1 << i)) == 0)
-				ez.assume(ez.OR(ez.NOT(sat_pi[bit]), ez.NOT(sat_pi_uniq_bitvec[i])));
+				ez->assume(ez->OR(ez->NOT(sat_pi[bit]), ez->NOT(sat_pi_uniq_bitvec[i])));
 			else
-				ez.assume(ez.OR(ez.NOT(sat_pi[bit]), sat_pi_uniq_bitvec[i]));
+				ez->assume(ez->OR(ez->NOT(sat_pi[bit]), sat_pi_uniq_bitvec[i]));
 	}
 
 	void register_cone_worker(std::set<RTLIL::SigBit> &pi, std::set<RTLIL::SigBit> &sigdone, RTLIL::SigBit out)
@@ -201,7 +201,7 @@ struct FindReducedInputs
 					model_expr.push_back(sat_pi.at(pi[i]));
 				}
 
-			if (!ez.solve(model_expr, model, ez.expression(ezSAT::OpOr, model_expr), ez.XOR(output_a, output_b), ez.NOT(output_undef_a), ez.NOT(output_undef_b)))
+			if (!ez->solve(model_expr, model, ez->expression(ezSAT::OpOr, model_expr), ez->XOR(output_a, output_b), ez->NOT(output_undef_a), ez->NOT(output_undef_b)))
 				break;
 
 			int found_count = 0;
@@ -230,7 +230,7 @@ struct PerformReduction
 	drivers_t &drivers;
 	std::set<std::pair<RTLIL::SigBit, RTLIL::SigBit>> &inv_pairs;
 
-	ezDefaultSAT ez;
+	ezSatPtr ez;
 	SatGen satgen;
 
 	std::vector<int> sat_pi, sat_out, sat_def;
@@ -260,7 +260,7 @@ struct PerformReduction
 		} else {
 			pi_bits.push_back(out);
 			sat_pi.push_back(satgen.importSigSpec(out).front());
-			ez.assume(ez.NOT(satgen.importUndefSigSpec(out).front()));
+			ez->assume(ez->NOT(satgen.importUndefSigSpec(out).front()));
 			sigdepth[out] = 0;
 		}
 
@@ -268,7 +268,7 @@ struct PerformReduction
 	}
 
 	PerformReduction(SigMap &sigmap, drivers_t &drivers, std::set<std::pair<RTLIL::SigBit, RTLIL::SigBit>> &inv_pairs, std::vector<RTLIL::SigBit> &bits, int cone_size) :
-			sigmap(sigmap), drivers(drivers), inv_pairs(inv_pairs), satgen(&ez, &sigmap), out_bits(bits), cone_size(cone_size)
+			sigmap(sigmap), drivers(drivers), inv_pairs(inv_pairs), satgen(ez.get(), &sigmap), out_bits(bits), cone_size(cone_size)
 	{
 		satgen.model_undef = true;
 
@@ -278,15 +278,15 @@ struct PerformReduction
 		for (auto &bit : bits) {
 			out_depth.push_back(register_cone_worker(celldone, sigdepth, bit));
 			sat_out.push_back(satgen.importSigSpec(bit).front());
-			sat_def.push_back(ez.NOT(satgen.importUndefSigSpec(bit).front()));
+			sat_def.push_back(ez->NOT(satgen.importUndefSigSpec(bit).front()));
 		}
 
 		if (inv_mode && cone_size > 0) {
-			if (!ez.solve(sat_out, out_inverted, ez.expression(ezSAT::OpAnd, sat_def)))
+			if (!ez->solve(sat_out, out_inverted, ez->expression(ezSAT::OpAnd, sat_def)))
 				log_error("Solving for initial model failed!\n");
 			for (size_t i = 0; i < sat_out.size(); i++)
 				if (out_inverted.at(i))
-					sat_out[i] = ez.NOT(sat_out[i]);
+					sat_out[i] = ez->NOT(sat_out[i]);
 		} else
 			out_inverted = std::vector<bool>(sat_out.size(), false);
 	}
@@ -296,8 +296,8 @@ struct PerformReduction
 		if (verbose_level == 1)
 			log("    Finding const value for %s.\n", log_signal(out_bits[idx]));
 
-		bool can_be_set = ez.solve(ez.AND(sat_out[idx], sat_def[idx]));
-		bool can_be_clr = ez.solve(ez.AND(ez.NOT(sat_out[idx]), sat_def[idx]));
+		bool can_be_set = ez->solve(ez->AND(sat_out[idx], sat_def[idx]));
+		bool can_be_clr = ez->solve(ez->AND(ez->NOT(sat_out[idx]), sat_def[idx]));
 		log_assert(!can_be_set || !can_be_clr);
 
 		RTLIL::SigBit value(RTLIL::State::Sx);
@@ -355,8 +355,8 @@ struct PerformReduction
 
 		std::vector<int> sat_set_list, sat_clr_list;
 		for (int idx : bucket) {
-			sat_set_list.push_back(ez.AND(sat_out[idx], sat_def[idx]));
-			sat_clr_list.push_back(ez.AND(ez.NOT(sat_out[idx]), sat_def[idx]));
+			sat_set_list.push_back(ez->AND(sat_out[idx], sat_def[idx]));
+			sat_clr_list.push_back(ez->AND(ez->NOT(sat_out[idx]), sat_def[idx]));
 		}
 
 		std::vector<int> modelVars = sat_out;
@@ -366,7 +366,7 @@ struct PerformReduction
 		if (verbose_level >= 2)
 			modelVars.insert(modelVars.end(), sat_pi.begin(), sat_pi.end());
 
-		if (ez.solve(modelVars, model, ez.expression(ezSAT::OpOr, sat_set_list), ez.expression(ezSAT::OpOr, sat_clr_list)))
+		if (ez->solve(modelVars, model, ez->expression(ezSAT::OpOr, sat_set_list), ez->expression(ezSAT::OpOr, sat_clr_list)))
 		{
 			int iter_count = 1;
 
@@ -379,13 +379,13 @@ struct PerformReduction
 
 				for (int idx : bucket)
 					if (!model[sat_out.size() + idx]) {
-						sat_set_list.push_back(ez.AND(sat_out[idx], sat_def[idx]));
-						sat_clr_list.push_back(ez.AND(ez.NOT(sat_out[idx]), sat_def[idx]));
+						sat_set_list.push_back(ez->AND(sat_out[idx], sat_def[idx]));
+						sat_clr_list.push_back(ez->AND(ez->NOT(sat_out[idx]), sat_def[idx]));
 					} else {
 						sat_def_list.push_back(sat_def[idx]);
 					}
 
-				if (!ez.solve(modelVars, model, ez.expression(ezSAT::OpOr, sat_set_list), ez.expression(ezSAT::OpOr, sat_clr_list), ez.expression(ezSAT::OpAnd, sat_def_list)))
+				if (!ez->solve(modelVars, model, ez->expression(ezSAT::OpOr, sat_set_list), ez->expression(ezSAT::OpOr, sat_clr_list), ez->expression(ezSAT::OpAnd, sat_def_list)))
 					break;
 				iter_count++;
 			}
@@ -431,7 +431,7 @@ struct PerformReduction
 				for (int idx2 : bucket)
 					if (idx != idx2)
 						sat_def_list.push_back(sat_def[idx2]);
-				if (ez.solve(ez.NOT(sat_def[idx]), ez.expression(ezSAT::OpOr, sat_def_list)))
+				if (ez->solve(ez->NOT(sat_def[idx]), ez->expression(ezSAT::OpOr, sat_def_list)))
 					undef_slaves.push_back(idx);
 			}
 
@@ -505,7 +505,7 @@ struct PerformReduction
 				for (int idx2 : r)
 					if (idx != idx2)
 						sat_def_list.push_back(sat_def[idx2]);
-				if (ez.solve(ez.NOT(sat_def[idx]), ez.expression(ezSAT::OpOr, sat_def_list)))
+				if (ez->solve(ez->NOT(sat_def[idx]), ez->expression(ezSAT::OpOr, sat_def_list)))
 					undef_slaves.push_back(idx);
 			}
 
diff --git a/passes/sat/sat.cc b/passes/sat/sat.cc
index b9535f49..ad680b6a 100644
--- a/passes/sat/sat.cc
+++ b/passes/sat/sat.cc
@@ -41,9 +41,10 @@ struct SatHelper
 	RTLIL::Design *design;
 	RTLIL::Module *module;
 
-	ezDefaultSAT ez;
 	SigMap sigmap;
 	CellTypes ct;
+
+	ezSatPtr ez;
 	SatGen satgen;
 
 	// additional constraints
@@ -65,7 +66,7 @@ struct SatHelper
 	bool gotTimeout;
 
 	SatHelper(RTLIL::Design *design, RTLIL::Module *module, bool enable_undef) :
-		design(design), module(module), sigmap(module), ct(design), satgen(&ez, &sigmap)
+		design(design), module(module), sigmap(module), ct(design), satgen(ez.get(), &sigmap)
 	{
 		this->enable_undef = enable_undef;
 		satgen.model_undef = enable_undef;
@@ -155,7 +156,7 @@ struct SatHelper
 		if (set_init_def) {
 			RTLIL::SigSpec rem = satgen.initial_state.export_all();
 			std::vector<int> undef_rem = satgen.importUndefSigSpec(rem, 1);
-			ez.assume(ez.NOT(ez.expression(ezSAT::OpOr, undef_rem)));
+			ez->assume(ez->NOT(ez->expression(ezSAT::OpOr, undef_rem)));
 		}
 
 		if (set_init_undef) {
@@ -179,7 +180,7 @@ struct SatHelper
 
 		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));
+		ez->assume(satgen.signals_eq(big_lhs, big_rhs, 1));
 	}
 
 	void setup(int timestep = -1)
@@ -250,7 +251,7 @@ struct SatHelper
 
 		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));
+		ez->assume(satgen.signals_eq(big_lhs, big_rhs, timestep));
 
 		// 0 = sets_def
 		// 1 = sets_any_undef
@@ -310,11 +311,11 @@ struct SatHelper
 			log("Import %s constraint for this timestep: %s\n", t == 0 ? "def" : t == 1 ? "any_undef" : "all_undef", log_signal(sig));
 			std::vector<int> undef_sig = satgen.importUndefSigSpec(sig, timestep);
 			if (t == 0)
-				ez.assume(ez.NOT(ez.expression(ezSAT::OpOr, undef_sig)));
+				ez->assume(ez->NOT(ez->expression(ezSAT::OpOr, undef_sig)));
 			if (t == 1)
-				ez.assume(ez.expression(ezSAT::OpOr, undef_sig));
+				ez->assume(ez->expression(ezSAT::OpOr, undef_sig));
 			if (t == 2)
-				ez.assume(ez.expression(ezSAT::OpAnd, undef_sig));
+				ez->assume(ez->expression(ezSAT::OpAnd, undef_sig));
 		}
 
 		int import_cell_counter = 0;
@@ -401,7 +402,7 @@ struct SatHelper
 			std::vector<int> undef_rhs = satgen.importUndefSigSpec(big_rhs, timestep);
 
 			for (size_t i = 0; i < value_lhs.size(); i++)
-				prove_bits.push_back(ez.OR(undef_lhs.at(i), ez.AND(ez.NOT(undef_rhs.at(i)), ez.NOT(ez.XOR(value_lhs.at(i), value_rhs.at(i))))));
+				prove_bits.push_back(ez->OR(undef_lhs.at(i), ez->AND(ez->NOT(undef_rhs.at(i)), ez->NOT(ez->XOR(value_lhs.at(i), value_rhs.at(i))))));
 		}
 
 		if (prove_asserts) {
@@ -412,22 +413,22 @@ struct SatHelper
 			prove_bits.push_back(satgen.importAsserts(timestep));
 		}
 
-		return ez.expression(ezSAT::OpAnd, prove_bits);
+		return ez->expression(ezSAT::OpAnd, prove_bits);
 	}
 
 	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)));
+			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())
+		ez->setSolverTimeout(timeout);
+		bool success = ez->solve(modelExpressions, modelValues, assumptions);
+		if (ez->getSolverTimoutStatus())
 			gotTimeout = true;
 		return success;
 	}
@@ -435,9 +436,9 @@ struct SatHelper
 	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())
+		ez->setSolverTimeout(timeout);
+		bool success = ez->solve(modelExpressions, modelValues, a, b, c, d, e, f);
+		if (ez->getSolverTimoutStatus())
 			gotTimeout = true;
 		return success;
 	}
@@ -478,7 +479,7 @@ struct SatHelper
 					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)))
+			if (!solve(ez->expression(ezSAT::OpAnd, must_undef), ez->expression(ezSAT::OpOr, maybe_undef)))
 				break;
 		}
 
@@ -832,12 +833,12 @@ struct SatHelper
 				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);
+					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));
+				clause.push_back(modelValues.at(i) ? ez->NOT(modelExpressions.at(i)) : modelExpressions.at(i));
+		ez->assume(ez->expression(ezSAT::OpOr, clause));
 	}
 };
 
@@ -1319,11 +1320,11 @@ struct SatPass : public Pass {
 			inductstep.ignore_unknown_cells = ignore_unknown_cells;
 
 			inductstep.setup(1);
-			inductstep.ez.assume(inductstep.setup_proof(1));
+			inductstep.ez->assume(inductstep.setup_proof(1));
 
 			if (tempinduct_def) {
 				std::vector<int> undef_state = inductstep.satgen.importUndefSigSpec(inductstep.satgen.initial_state.export_all(), 1);
-				inductstep.ez.assume(inductstep.ez.NOT(inductstep.ez.expression(ezSAT::OpOr, undef_state)));
+				inductstep.ez->assume(inductstep.ez->NOT(inductstep.ez->expression(ezSAT::OpOr, undef_state)));
 			}
 
 			for (int inductlen = 1; inductlen <= maxsteps || maxsteps == 0; inductlen++)
@@ -1340,9 +1341,9 @@ struct SatPass : public Pass {
 					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());
+						basecase.ez->numCnfVariables(), basecase.ez->numCnfClauses());
 
-				if (basecase.solve(basecase.ez.NOT(property))) {
+				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();
@@ -1357,7 +1358,7 @@ struct SatPass : public Pass {
 					goto timeout;
 
 				log("Base case for induction length %d proven.\n", inductlen);
-				basecase.ez.assume(property);
+				basecase.ez->assume(property);
 
 				// phase 2: proving induction step
 
@@ -1371,8 +1372,8 @@ struct SatPass : public Pass {
 				if (inductlen < initsteps)
 				{
 					log("\n[induction step] Skipping problem with %d variables and %d clauses (below initsteps).\n",
-							inductstep.ez.numCnfVariables(), inductstep.ez.numCnfClauses());
-					inductstep.ez.assume(property);
+							inductstep.ez->numCnfVariables(), inductstep.ez->numCnfClauses());
+					inductstep.ez->assume(property);
 				}
 				else
 				{
@@ -1385,14 +1386,14 @@ struct SatPass : public Pass {
 						log("Dumping CNF to file `%s'.\n", cnf_file_name.c_str());
 						cnf_file_name.clear();
 
-						inductstep.ez.printDIMACS(f, false);
+						inductstep.ez->printDIMACS(f, false);
 						fclose(f);
 					}
 
 					log("\n[induction step] Solving problem with %d variables and %d clauses..\n",
-							inductstep.ez.numCnfVariables(), inductstep.ez.numCnfClauses());
+							inductstep.ez->numCnfVariables(), inductstep.ez->numCnfClauses());
 
-					if (!inductstep.solve(inductstep.ez.NOT(property))) {
+					if (!inductstep.solve(inductstep.ez->NOT(property))) {
 						if (inductstep.gotTimeout)
 							goto timeout;
 						log("Induction step proven: SUCCESS!\n");
@@ -1401,7 +1402,7 @@ struct SatPass : public Pass {
 					}
 
 					log("Induction step failed. Incrementing induction length.\n");
-					inductstep.ez.assume(property);
+					inductstep.ez->assume(property);
 					inductstep.print_model();
 				}
 			}
@@ -1457,7 +1458,7 @@ struct SatPass : public Pass {
 			if (seq_len == 0) {
 				sathelper.setup();
 				if (sathelper.prove.size() || sathelper.prove_x.size() || sathelper.prove_asserts)
-					sathelper.ez.assume(sathelper.ez.NOT(sathelper.setup_proof()));
+					sathelper.ez->assume(sathelper.ez->NOT(sathelper.setup_proof()));
 			} else {
 				std::vector<int> prove_bits;
 				for (int timestep = 1; timestep <= seq_len; timestep++) {
@@ -1467,7 +1468,7 @@ struct SatPass : public Pass {
 							prove_bits.push_back(sathelper.setup_proof(timestep));
 				}
 				if (sathelper.prove.size() || sathelper.prove_x.size() || sathelper.prove_asserts)
-					sathelper.ez.assume(sathelper.ez.NOT(sathelper.ez.expression(ezSAT::OpAnd, prove_bits)));
+					sathelper.ez->assume(sathelper.ez->NOT(sathelper.ez->expression(ezSAT::OpAnd, prove_bits)));
 				sathelper.setup_init();
 			}
 			sathelper.generate_model();
@@ -1481,7 +1482,7 @@ struct SatPass : public Pass {
 				log("Dumping CNF to file `%s'.\n", cnf_file_name.c_str());
 				cnf_file_name.clear();
 
-				sathelper.ez.printDIMACS(f, false);
+				sathelper.ez->printDIMACS(f, false);
 				fclose(f);
 			}
 
@@ -1489,7 +1490,7 @@ struct SatPass : public Pass {
 
 		rerun_solver:
 			log("\nSolving problem with %d variables and %d clauses..\n",
-					sathelper.ez.numCnfVariables(), sathelper.ez.numCnfClauses());
+					sathelper.ez->numCnfVariables(), sathelper.ez->numCnfClauses());
 
 			if (sathelper.solve())
 			{
diff --git a/passes/tests/test_abcloop.cc b/passes/tests/test_abcloop.cc
index 753fa7bf..09cb4195 100644
--- a/passes/tests/test_abcloop.cc
+++ b/passes/tests/test_abcloop.cc
@@ -127,9 +127,9 @@ static void test_abcloop()
 		module->fixup_ports();
 		Pass::call(design, "clean");
 
-		ezDefaultSAT ez;
+		ezSatPtr ez;
 		SigMap sigmap(module);
-		SatGen satgen(&ez, &sigmap);
+		SatGen satgen(ez.get(), &sigmap);
 
 		for (auto c : module->cells()) {
 			bool ok YS_ATTRIBUTE(unused) = satgen.importCell(c);
@@ -137,7 +137,7 @@ static void test_abcloop()
 		}
 
 		std::vector<int> in_vec = satgen.importSigSpec(in_sig);
-		std::vector<int> inverse_in_vec = ez.vec_not(in_vec);
+		std::vector<int> inverse_in_vec = ez->vec_not(in_vec);
 
 		std::vector<int> out_vec = satgen.importSigSpec(out_sig);
 
@@ -148,7 +148,7 @@ static void test_abcloop()
 				assumptions.push_back((i & (1 << j)) ? in_vec.at(j) : inverse_in_vec.at(j));
 
 			std::vector<bool> results;
-			if (!ez.solve(out_vec, results, assumptions)) {
+			if (!ez->solve(out_vec, results, assumptions)) {
 				log("No stable solution for input %d found -> recreate module.\n", i);
 				goto recreate_module;
 			}
@@ -156,10 +156,10 @@ static void test_abcloop()
 			for (int j = 0; j < 4; j++)
 				truthtab[i][j] = results[j];
 
-			assumptions.push_back(ez.vec_ne(out_vec, ez.vec_const(results)));
+			assumptions.push_back(ez->vec_ne(out_vec, ez->vec_const(results)));
 
 			std::vector<bool> results2;
-			if (ez.solve(out_vec, results2, assumptions)) {
+			if (ez->solve(out_vec, results2, assumptions)) {
 				log("Two stable solutions for input %d found -> recreate module.\n", i);
 				goto recreate_module;
 			}
@@ -177,9 +177,9 @@ static void test_abcloop()
 	log("\n");
 	log("Pre- and post-abc truth table:\n");
 
-	ezDefaultSAT ez;
+	ezSatPtr ez;
 	SigMap sigmap(module);
-	SatGen satgen(&ez, &sigmap);
+	SatGen satgen(ez.get(), &sigmap);
 
 	for (auto c : module->cells()) {
 		bool ok YS_ATTRIBUTE(unused) = satgen.importCell(c);
@@ -187,7 +187,7 @@ static void test_abcloop()
 	}
 
 	std::vector<int> in_vec = satgen.importSigSpec(in_sig);
-	std::vector<int> inverse_in_vec = ez.vec_not(in_vec);
+	std::vector<int> inverse_in_vec = ez->vec_not(in_vec);
 
 	std::vector<int> out_vec = satgen.importSigSpec(out_sig);
 
@@ -204,7 +204,7 @@ static void test_abcloop()
 			truthtab2[i][j] = truthtab[i][j];
 
 		std::vector<bool> results;
-		if (!ez.solve(out_vec, results, assumptions)) {
+		if (!ez->solve(out_vec, results, assumptions)) {
 			log("No stable solution for input %d found.\n", i);
 			found_error = true;
 			continue;
@@ -213,10 +213,10 @@ static void test_abcloop()
 		for (int j = 0; j < 4; j++)
 			truthtab2[i][j] = results[j];
 
-		assumptions.push_back(ez.vec_ne(out_vec, ez.vec_const(results)));
+		assumptions.push_back(ez->vec_ne(out_vec, ez->vec_const(results)));
 
 		std::vector<bool> results2;
-		if (ez.solve(out_vec, results2, assumptions)) {
+		if (ez->solve(out_vec, results2, assumptions)) {
 			log("Two stable solutions for input %d found -> recreate module.\n", i);
 			found_error = true;
 		}
diff --git a/passes/tests/test_cell.cc b/passes/tests/test_cell.cc
index ea2ab1e6..268f2559 100644
--- a/passes/tests/test_cell.cc
+++ b/passes/tests/test_cell.cc
@@ -278,10 +278,10 @@ static void run_eval_test(RTLIL::Design *design, bool verbose, bool nosat, std::
 	RTLIL::Module *gate_mod = design->module("\\gate");
 	ConstEval gold_ce(gold_mod), gate_ce(gate_mod);
 
-	ezDefaultSAT ez1, ez2;
+	ezSatPtr ez1, ez2;
 	SigMap sigmap(gold_mod);
-	SatGen satgen1(&ez1, &sigmap);
-	SatGen satgen2(&ez2, &sigmap);
+	SatGen satgen1(ez1.get(), &sigmap);
+	SatGen satgen2(ez2.get(), &sigmap);
 	satgen2.model_undef = true;
 
 	if (!nosat)
@@ -433,7 +433,7 @@ static void run_eval_test(RTLIL::Design *design, bool verbose, bool nosat, std::
 			std::vector<int> sat1_model = satgen1.importSigSpec(out_sig);
 			std::vector<bool> sat1_model_value;
 
-			if (!ez1.solve(sat1_model, sat1_model_value, ez1.vec_eq(sat1_in_sig, sat1_in_val)))
+			if (!ez1->solve(sat1_model, sat1_model_value, ez1->vec_eq(sat1_in_sig, sat1_in_val)))
 				log_error("Evaluating sat model 1 (no undef modeling) failed!\n");
 
 			if (verbose) {
@@ -468,7 +468,7 @@ static void run_eval_test(RTLIL::Design *design, bool verbose, bool nosat, std::
 
 			std::vector<bool> sat2_model_value;
 
-			if (!ez2.solve(sat2_model, sat2_model_value, ez2.vec_eq(sat2_in_def_sig, sat2_in_def_val), ez2.vec_eq(sat2_in_undef_sig, sat2_in_undef_val)))
+			if (!ez2->solve(sat2_model, sat2_model_value, ez2->vec_eq(sat2_in_def_sig, sat2_in_def_val), ez2->vec_eq(sat2_in_undef_sig, sat2_in_undef_val)))
 				log_error("Evaluating sat model 2 (undef modeling) failed!\n");
 
 			if (verbose) {