/*++ Copyright (c) 2011 Microsoft Corporation Module Name: sat_tactic.cpp Abstract: Tactic for using the SAT solver and its preprocessing capabilities. Author: Leonardo (leonardo) 2011-10-25 Notes: --*/ #include"tactical.h" #include"goal2sat.h" #include"sat_solver.h" #include"filter_model_converter.h" #include"ast_smt2_pp.h" #include"model_v2_pp.h" class sat_tactic : public tactic { struct imp { ast_manager & m; goal2sat m_goal2sat; sat2goal m_sat2goal; sat::solver m_solver; params_ref m_params; imp(ast_manager & _m, params_ref const & p): m(_m), m_solver(p, 0), m_params(p) { SASSERT(!m.proofs_enabled()); } void operator()(goal_ref const & g, goal_ref_buffer & result, model_converter_ref & mc, proof_converter_ref & pc, expr_dependency_ref & core) { mc = 0; pc = 0; core = 0; fail_if_proof_generation("sat", g); fail_if_unsat_core_generation("sat", g); bool produce_models = g->models_enabled(); TRACE("before_sat_solver", g->display(tout);); g->elim_redundancies(); atom2bool_var map(m); m_goal2sat(*g, m_params, m_solver, map); TRACE("sat_solver_unknown", tout << "interpreted_atoms: " << map.interpreted_atoms() << "\n"; atom2bool_var::iterator it = map.begin(); atom2bool_var::iterator end = map.end(); for (; it != end; ++it) { if (!is_uninterp_const(it->m_key)) tout << mk_ismt2_pp(it->m_key, m) << "\n"; }); g->reset(); g->m().compact_memory(); CASSERT("sat_solver", m_solver.check_invariant()); IF_VERBOSE(TACTIC_VERBOSITY_LVL, m_solver.display_status(verbose_stream());); TRACE("sat_dimacs", m_solver.display_dimacs(tout);); lbool r = m_solver.check(); if (r == l_false) { g->assert_expr(m.mk_false(), 0, 0); } else if (r == l_true && !map.interpreted_atoms()) { // register model if (produce_models) { model_ref md = alloc(model, m); sat::model const & ll_m = m_solver.get_model(); TRACE("sat_tactic", for (unsigned i = 0; i < ll_m.size(); i++) tout << i << ":" << ll_m[i] << " "; tout << "\n";); atom2bool_var::iterator it = map.begin(); atom2bool_var::iterator end = map.end(); for (; it != end; ++it) { expr * n = it->m_key; sat::bool_var v = it->m_value; TRACE("sat_tactic", tout << "extracting value of " << mk_ismt2_pp(n, m) << "\nvar: " << v << "\n";); switch (sat::value_at(v, ll_m)) { case l_true: md->register_decl(to_app(n)->get_decl(), m.mk_true()); break; case l_false: md->register_decl(to_app(n)->get_decl(), m.mk_false()); break; default: break; } } TRACE("sat_tactic", model_v2_pp(tout, *md);); mc = model2model_converter(md.get()); } } else { // get simplified problem. #if 0 IF_VERBOSE(TACTIC_VERBOSITY_LVL, verbose_stream() << "\"formula constains interpreted atoms, recovering formula from sat solver...\"\n";); #endif m_solver.pop(m_solver.scope_lvl()); m_sat2goal(m_solver, map, m_params, *(g.get()), mc); } g->inc_depth(); result.push_back(g.get()); } void set_cancel(bool f) { m_goal2sat.set_cancel(f); m_sat2goal.set_cancel(f); m_solver.set_cancel(f); } }; struct scoped_set_imp { sat_tactic * m_owner; scoped_set_imp(sat_tactic * o, imp * i):m_owner(o) { #pragma omp critical (sat_tactic) { m_owner->m_imp = i; } } ~scoped_set_imp() { #pragma omp critical (sat_tactic) { m_owner->m_imp = 0; } } }; imp * m_imp; params_ref m_params; statistics m_stats; public: sat_tactic(ast_manager & m, params_ref const & p): m_imp(0), m_params(p) { } virtual tactic * translate(ast_manager & m) { return alloc(sat_tactic, m, m_params); } virtual ~sat_tactic() { SASSERT(m_imp == 0); } virtual void updt_params(params_ref const & p) { m_params = p; } virtual void collect_param_descrs(param_descrs & r) { goal2sat::collect_param_descrs(r); sat2goal::collect_param_descrs(r); sat::solver::collect_param_descrs(r); } void operator()(goal_ref const & g, goal_ref_buffer & result, model_converter_ref & mc, proof_converter_ref & pc, expr_dependency_ref & core) { imp proc(g->m(), m_params); scoped_set_imp set(this, &proc); try { proc(g, result, mc, pc, core); proc.m_solver.collect_statistics(m_stats); } catch (sat::solver_exception & ex) { proc.m_solver.collect_statistics(m_stats); throw tactic_exception(ex.msg()); } TRACE("sat_stats", m_stats.display_smt2(tout);); } virtual void cleanup() { SASSERT(m_imp == 0); } virtual void collect_statistics(statistics & st) const { st.copy(m_stats); } virtual void reset_statistics() { m_stats.reset(); } protected: virtual void set_cancel(bool f) { #pragma omp critical (sat_tactic) { if (m_imp) m_imp->set_cancel(f); } } }; tactic * mk_sat_tactic(ast_manager & m, params_ref const & p) { return clean(alloc(sat_tactic, m, p)); } tactic * mk_sat_preprocessor_tactic(ast_manager & m, params_ref const & p) { params_ref p_aux; p_aux.set_uint(":max-conflicts", 0); tactic * t = clean(using_params(mk_sat_tactic(m, p), p_aux)); t->updt_params(p); return t; }