/*++ Copyright (c) 2012 Microsoft Corporation Module Name: rel_context.cpp Abstract: context for relational datalog engine. Author: Nikolaj Bjorner (nbjorner) 2012-12-3. Revision History: Extracted from dl_context --*/ #include"rel_context.h" #include"dl_context.h" #include"dl_compiler.h" #include"dl_instruction.h" #include"dl_mk_explanations.h" #include"dl_mk_magic_sets.h" #include"dl_product_relation.h" #include"dl_bound_relation.h" #include"dl_interval_relation.h" #include"dl_mk_karr_invariants.h" #include"dl_finite_product_relation.h" #include"dl_sparse_table.h" #include"dl_table.h" #include"dl_table_relation.h" #include"aig_exporter.h" namespace datalog { class rel_context::scoped_query { context& m_ctx; rule_set m_rules; decl_set m_preds; bool m_was_closed; public: scoped_query(context& ctx): m_ctx(ctx), m_rules(ctx.get_rules()), m_preds(ctx.get_predicates()), m_was_closed(ctx.is_closed()) { if (m_was_closed) { ctx.reopen(); } } ~scoped_query() { m_ctx.reopen(); m_ctx.restrict_predicates(m_preds); m_ctx.replace_rules(m_rules); if (m_was_closed) { m_ctx.close(); } } void reset() { m_ctx.reopen(); m_ctx.restrict_predicates(m_preds); m_ctx.replace_rules(m_rules); m_ctx.close(); } }; rel_context::rel_context(context& ctx) : engine_base(ctx.get_manager(), "datalog"), m_context(ctx), m(ctx.get_manager()), m_rmanager(ctx), m_answer(m), m_last_result_relation(0), m_ectx(ctx) { // register plugins for builtin tables get_rmanager().register_plugin(alloc(sparse_table_plugin, get_rmanager())); get_rmanager().register_plugin(alloc(hashtable_table_plugin, get_rmanager())); get_rmanager().register_plugin(alloc(bitvector_table_plugin, get_rmanager())); get_rmanager().register_plugin(alloc(equivalence_table_plugin, get_rmanager())); // register plugins for builtin relations get_rmanager().register_plugin(alloc(bound_relation_plugin, get_rmanager())); get_rmanager().register_plugin(alloc(interval_relation_plugin, get_rmanager())); get_rmanager().register_plugin(alloc(karr_relation_plugin, get_rmanager())); } rel_context::~rel_context() { if (m_last_result_relation) { m_last_result_relation->deallocate(); m_last_result_relation = 0; } } lbool rel_context::saturate() { scoped_query sq(m_context); return saturate(sq); } lbool rel_context::saturate(scoped_query& sq) { m_context.ensure_closed(); bool time_limit = m_context.soft_timeout()!=0; unsigned remaining_time_limit = m_context.soft_timeout(); unsigned restart_time = m_context.initial_restart_timeout(); instruction_block termination_code; lbool result; TRACE("dl", m_context.display(tout);); while (true) { m_ectx.reset(); m_code.reset(); termination_code.reset(); m_context.ensure_closed(); m_context.transform_rules(); if (m_context.canceled()) { result = l_undef; break; } TRACE("dl", m_context.display(tout);); if (m_context.get_params().dump_aig().size()) { const char *filename = static_cast(m_context.get_params().dump_aig().c_ptr()); aig_exporter aig(m_context.get_rules(), get_context(), &m_table_facts); std::ofstream strm(filename, std::ios_base::binary); aig(strm); exit(0); } compiler::compile(m_context, m_context.get_rules(), m_code, termination_code); TRACE("dl", m_code.display(*this, tout); ); bool timeout_after_this_round = time_limit && (restart_time==0 || remaining_time_limit<=restart_time); if (time_limit || restart_time!=0) { unsigned timeout = time_limit ? (restart_time!=0) ? std::min(remaining_time_limit, restart_time) : remaining_time_limit : restart_time; m_ectx.set_timelimit(timeout); } bool early_termination = !m_code.perform(m_ectx); m_ectx.reset_timelimit(); VERIFY( termination_code.perform(m_ectx) || m_context.canceled()); m_code.process_all_costs(); IF_VERBOSE(10, m_ectx.report_big_relations(1000, verbose_stream());); if (m_context.canceled()) { result = l_undef; break; } if (!early_termination) { m_context.set_status(OK); result = l_true; break; } if (memory::above_high_watermark()) { m_context.set_status(MEMOUT); result = l_undef; break; } if (timeout_after_this_round) { m_context.set_status(TIMEOUT); result = l_undef; break; } SASSERT(restart_time != 0); if (time_limit) { SASSERT(remaining_time_limit>restart_time); remaining_time_limit -= restart_time; } uint64 new_restart_time = static_cast(restart_time)*m_context.initial_restart_timeout(); if (new_restart_time > UINT_MAX) { restart_time = UINT_MAX; } else { restart_time = static_cast(new_restart_time); } sq.reset(); } m_context.record_transformed_rules(); TRACE("dl", display_profile(tout);); return result; } lbool rel_context::query(unsigned num_rels, func_decl * const* rels) { get_rmanager().reset_saturated_marks(); scoped_query _scoped_query(m_context); for (unsigned i = 0; i < num_rels; ++i) { m_context.set_output_predicate(rels[i]); } m_context.close(); reset_negated_tables(); lbool res = saturate(_scoped_query); switch(res) { case l_true: { expr_ref_vector ans(m); expr_ref e(m); bool some_non_empty = num_rels == 0; bool is_approx = false; for (unsigned i = 0; i < num_rels; ++i) { func_decl* q = m_context.get_rules().get_pred(rels[i]); relation_base& rel = get_relation(q); if (!rel.empty()) { some_non_empty = true; } if (!rel.is_precise()) { is_approx = true; } rel.to_formula(e); ans.push_back(e); } SASSERT(!m_last_result_relation); if (some_non_empty) { m_answer = m.mk_and(ans.size(), ans.c_ptr()); if (is_approx) { res = l_undef; m_context.set_status(APPROX); } } else { m_answer = m.mk_false(); res = l_false; } break; } case l_false: m_answer = m.mk_false(); break; case l_undef: break; } return res; } lbool rel_context::query(expr* query) { get_rmanager().reset_saturated_marks(); scoped_query _scoped_query(m_context); rule_manager& rm = m_context.get_rule_manager(); func_decl_ref query_pred(m); try { query_pred = rm.mk_query(query, m_context.get_rules()); } catch (default_exception& exn) { m_context.set_status(INPUT_ERROR); throw exn; } m_context.close(); reset_negated_tables(); if (m_context.generate_explanations()) { m_context.transform_rules(alloc(mk_explanations, m_context)); } query_pred = m_context.get_rules().get_pred(query_pred); if (m_context.magic_sets_for_queries()) { m_context.transform_rules(alloc(mk_magic_sets, m_context, query_pred)); query_pred = m_context.get_rules().get_pred(query_pred); } lbool res = saturate(_scoped_query); query_pred = m_context.get_rules().get_pred(query_pred); if (res != l_undef) { m_last_result_relation = get_relation(query_pred).clone(); if (m_last_result_relation->empty()) { res = l_false; m_answer = m.mk_false(); } else { m_last_result_relation->to_formula(m_answer); if (!m_last_result_relation->is_precise()) { m_context.set_status(APPROX); res = l_undef; } } } return res; } void rel_context::reset_negated_tables() { rule_set::pred_set_vector const & pred_sets = m_context.get_rules().get_strats(); bool non_empty = false; for (unsigned i = 1; i < pred_sets.size(); ++i) { func_decl_set::iterator it = pred_sets[i]->begin(), end = pred_sets[i]->end(); for (; it != end; ++it) { func_decl* pred = *it; relation_base & rel = get_relation(pred); if (!rel.empty()) { non_empty = true; break; } } } if (!non_empty) { return; } // collect predicates that depend on negation. func_decl_set depends_on_negation; for (unsigned i = 1; i < pred_sets.size(); ++i) { bool change = true; while (change) { change = false; func_decl_set::iterator it = pred_sets[i]->begin(), end = pred_sets[i]->end(); for (; it != end; ++it) { func_decl* pred = *it; if (depends_on_negation.contains(pred)) { continue; } rule_vector const& rules = m_context.get_rules().get_predicate_rules(pred); bool inserted = false; for (unsigned j = 0; !inserted && j < rules.size(); ++j) { rule* r = rules[j]; unsigned psz = r->get_positive_tail_size(); unsigned tsz = r->get_uninterpreted_tail_size(); if (psz < tsz) { depends_on_negation.insert(pred); change = true; inserted = true; } for (unsigned k = 0; !inserted && k < tsz; ++k) { func_decl* tail_decl = r->get_tail(k)->get_decl(); if (depends_on_negation.contains(tail_decl)) { depends_on_negation.insert(pred); change = true; inserted = true; } } } } } } func_decl_set::iterator it = depends_on_negation.begin(), end = depends_on_negation.end(); for (; it != end; ++it) { func_decl* pred = *it; relation_base & rel = get_relation(pred); if (!rel.empty()) { TRACE("dl", tout << "Resetting: " << mk_ismt2_pp(pred, m) << "\n";); rel.reset(); } } } void rel_context::restrict_predicates(func_decl_set const& predicates) { get_rmanager().restrict_predicates(predicates); } relation_base & rel_context::get_relation(func_decl * pred) { return get_rmanager().get_relation(pred); } relation_base * rel_context::try_get_relation(func_decl * pred) const { return get_rmanager().try_get_relation(pred); } relation_manager & rel_context::get_rmanager() { return m_rmanager; } const relation_manager & rel_context::get_rmanager() const { return m_rmanager; } bool rel_context::output_profile() const { return m_context.output_profile(); } void rel_context::set_predicate_representation(func_decl * pred, unsigned relation_name_cnt, symbol const * relation_names) { TRACE("dl", tout << pred->get_name() << ": "; for (unsigned i = 0; i < relation_name_cnt; ++i) { tout << relation_names[i] << " "; } tout << "\n"; ); relation_manager & rmgr = get_rmanager(); family_id target_kind = null_family_id; switch (relation_name_cnt) { case 0: return; case 1: target_kind = get_ordinary_relation_plugin(relation_names[0]).get_kind(); break; default: { svector rel_kinds; // kinds of plugins that are not table plugins family_id rel_kind; // the aggregate kind of non-table plugins for (unsigned i = 0; i < relation_name_cnt; i++) { relation_plugin & p = get_ordinary_relation_plugin(relation_names[i]); rel_kinds.push_back(p.get_kind()); } if (rel_kinds.size() == 1) { rel_kind = rel_kinds[0]; } else { relation_signature rel_sig; rmgr.from_predicate(pred, rel_sig); product_relation_plugin & prod_plugin = product_relation_plugin::get_plugin(rmgr); rel_kind = prod_plugin.get_relation_kind(rel_sig, rel_kinds); } target_kind = rel_kind; break; } } SASSERT(target_kind != null_family_id); get_rmanager().set_predicate_kind(pred, target_kind); } void rel_context::set_cancel(bool f) { get_rmanager().set_cancel(f); } relation_plugin & rel_context::get_ordinary_relation_plugin(symbol relation_name) { relation_plugin * plugin = get_rmanager().get_relation_plugin(relation_name); if (!plugin) { std::stringstream sstm; sstm << "relation plugin " << relation_name << " does not exist"; throw default_exception(sstm.str()); } if (plugin->is_product_relation()) { throw default_exception("cannot request product relation directly"); } if (plugin->is_sieve_relation()) { throw default_exception("cannot request sieve relation directly"); } if (plugin->is_finite_product_relation()) { throw default_exception("cannot request finite product relation directly"); } return *plugin; } bool rel_context::result_contains_fact(relation_fact const& f) { SASSERT(m_last_result_relation); return m_last_result_relation->contains_fact(f); } void rel_context::reset_tables() { get_rmanager().reset_saturated_marks(); rule_set::decl2rules::iterator it = m_context.get_rules().begin_grouped_rules(); rule_set::decl2rules::iterator end = m_context.get_rules().end_grouped_rules(); for (; it != end; ++it) { func_decl* p = it->m_key; relation_base & rel = get_relation(p); rel.reset(); } for (unsigned i = 0; i < m_table_facts.size(); ++i) { func_decl* pred = m_table_facts[i].first; relation_fact const& fact = m_table_facts[i].second; get_relation(pred).add_fact(fact); } } void rel_context::add_fact(func_decl* pred, relation_fact const& fact) { get_rmanager().reset_saturated_marks(); get_relation(pred).add_fact(fact); m_table_facts.push_back(std::make_pair(pred, fact)); } void rel_context::add_fact(func_decl* pred, table_fact const& fact) { get_rmanager().reset_saturated_marks(); relation_base & rel0 = get_relation(pred); if (rel0.from_table()) { table_relation & rel = static_cast(rel0); rel.add_table_fact(fact); // TODO: table facts? } else { relation_fact rfact(m); for (unsigned i = 0; i < fact.size(); ++i) { rfact.push_back(m_context.get_decl_util().mk_numeral(fact[i], pred->get_domain()[i])); } add_fact(pred, rfact); } } bool rel_context::has_facts(func_decl * pred) const { relation_base* r = try_get_relation(pred); return r && !r->empty(); } void rel_context::store_relation(func_decl * pred, relation_base * rel) { get_rmanager().store_relation(pred, rel); } void rel_context::inherit_predicate_kind(func_decl* new_pred, func_decl* orig_pred) { if (orig_pred) { family_id target_kind = get_rmanager().get_requested_predicate_kind(orig_pred); if (target_kind != null_family_id) { get_rmanager().set_predicate_kind(new_pred, target_kind); } } } void rel_context::display_output_facts(rule_set const& rules, std::ostream & out) const { get_rmanager().display_output_tables(rules, out); } void rel_context::display_facts(std::ostream& out) const { get_rmanager().display(out); } void rel_context::display_profile(std::ostream& out) { m_code.make_annotations(m_ectx); m_code.process_all_costs(); out << "\n--------------\n"; out << "Instructions\n"; m_code.display(*this, out); out << "\n--------------\n"; out << "Big relations\n"; m_ectx.report_big_relations(1000, out); get_rmanager().display_relation_sizes(out); } };