/********************* */ /*! \file theory_bv.cpp ** \verbatim ** Top contributors (to current version): ** Liana Hadarean, Tim King, Dejan Jovanovic ** This file is part of the CVC4 project. ** Copyright (c) 2009-2016 by the authors listed in the file AUTHORS ** in the top-level source directory) and their institutional affiliations. ** All rights reserved. See the file COPYING in the top-level source ** directory for licensing information.\endverbatim ** ** [[ Add lengthier description here ]] ** \todo document this file **/ #include "theory/bv/theory_bv.h" #include "options/bv_options.h" #include "options/smt_options.h" #include "smt/smt_statistics_registry.h" #include "theory/bv/abstraction.h" #include "theory/bv/bv_eager_solver.h" #include "theory/bv/bv_subtheory_algebraic.h" #include "theory/bv/bv_subtheory_bitblast.h" #include "theory/bv/bv_subtheory_core.h" #include "theory/bv/bv_subtheory_inequality.h" #include "theory/bv/slicer.h" #include "theory/bv/theory_bv_rewrite_rules_normalization.h" #include "theory/bv/theory_bv_rewrite_rules_simplification.h" #include "theory/bv/theory_bv_rewriter.h" #include "theory/bv/theory_bv_utils.h" #include "theory/theory_model.h" #include "proof/theory_proof.h" #include "proof/proof_manager.h" #include "theory/valuation.h" using namespace CVC4::context; using namespace CVC4::theory::bv::utils; using namespace std; namespace CVC4 { namespace theory { namespace bv { TheoryBV::TheoryBV(context::Context* c, context::UserContext* u, OutputChannel& out, Valuation valuation, const LogicInfo& logicInfo) : Theory(THEORY_BV, c, u, out, valuation, logicInfo), d_context(c), d_alreadyPropagatedSet(c), d_sharedTermsSet(c), d_subtheories(), d_subtheoryMap(), d_statistics(), d_staticLearnCache(), d_lemmasAdded(c, false), d_conflict(c, false), d_invalidateModelCache(c, true), d_literalsToPropagate(c), d_literalsToPropagateIndex(c, 0), d_propagatedBy(c), d_eagerSolver(NULL), d_abstractionModule(new AbstractionModule()), d_isCoreTheory(false), d_calledPreregister(false) { if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { d_eagerSolver = new EagerBitblastSolver(this); return; } if (options::bitvectorEqualitySolver()) { SubtheorySolver* core_solver = new CoreSolver(c, this); d_subtheories.push_back(core_solver); d_subtheoryMap[SUB_CORE] = core_solver; } if (options::bitvectorInequalitySolver()) { SubtheorySolver* ineq_solver = new InequalitySolver(c, this); d_subtheories.push_back(ineq_solver); d_subtheoryMap[SUB_INEQUALITY] = ineq_solver; } if (options::bitvectorAlgebraicSolver()) { SubtheorySolver* alg_solver = new AlgebraicSolver(c, this); d_subtheories.push_back(alg_solver); d_subtheoryMap[SUB_ALGEBRAIC] = alg_solver; } BitblastSolver* bb_solver = new BitblastSolver(c, this); if (options::bvAbstraction()) { bb_solver->setAbstraction(d_abstractionModule); } d_subtheories.push_back(bb_solver); d_subtheoryMap[SUB_BITBLAST] = bb_solver; } TheoryBV::~TheoryBV() { for (unsigned i = 0; i < d_subtheories.size(); ++i) { delete d_subtheories[i]; } delete d_abstractionModule; } void TheoryBV::setMasterEqualityEngine(eq::EqualityEngine* eq) { if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { return; } if (options::bitvectorEqualitySolver()) { dynamic_cast(d_subtheoryMap[SUB_CORE])->setMasterEqualityEngine(eq); } } void TheoryBV::spendResource(unsigned ammount) throw(UnsafeInterruptException) { getOutputChannel().spendResource(ammount); } TheoryBV::Statistics::Statistics(): d_avgConflictSize("theory::bv::AvgBVConflictSize"), d_solveSubstitutions("theory::bv::NumberOfSolveSubstitutions", 0), d_solveTimer("theory::bv::solveTimer"), d_numCallsToCheckFullEffort("theory::bv::NumberOfFullCheckCalls", 0), d_numCallsToCheckStandardEffort("theory::bv::NumberOfStandardCheckCalls", 0), d_weightComputationTimer("theory::bv::weightComputationTimer"), d_numMultSlice("theory::bv::NumMultSliceApplied", 0) { smtStatisticsRegistry()->registerStat(&d_avgConflictSize); smtStatisticsRegistry()->registerStat(&d_solveSubstitutions); smtStatisticsRegistry()->registerStat(&d_solveTimer); smtStatisticsRegistry()->registerStat(&d_numCallsToCheckFullEffort); smtStatisticsRegistry()->registerStat(&d_numCallsToCheckStandardEffort); smtStatisticsRegistry()->registerStat(&d_weightComputationTimer); smtStatisticsRegistry()->registerStat(&d_numMultSlice); } TheoryBV::Statistics::~Statistics() { smtStatisticsRegistry()->unregisterStat(&d_avgConflictSize); smtStatisticsRegistry()->unregisterStat(&d_solveSubstitutions); smtStatisticsRegistry()->unregisterStat(&d_solveTimer); smtStatisticsRegistry()->unregisterStat(&d_numCallsToCheckFullEffort); smtStatisticsRegistry()->unregisterStat(&d_numCallsToCheckStandardEffort); smtStatisticsRegistry()->unregisterStat(&d_weightComputationTimer); smtStatisticsRegistry()->unregisterStat(&d_numMultSlice); } Node TheoryBV::getBVDivByZero(Kind k, unsigned width) { NodeManager* nm = NodeManager::currentNM(); if (k == kind::BITVECTOR_UDIV) { if (d_BVDivByZero.find(width) == d_BVDivByZero.end()) { // lazily create the function symbols ostringstream os; os << "BVUDivByZero_" << width; Node divByZero = nm->mkSkolem(os.str(), nm->mkFunctionType(nm->mkBitVectorType(width), nm->mkBitVectorType(width)), "partial bvudiv", NodeManager::SKOLEM_EXACT_NAME); d_BVDivByZero[width] = divByZero; } return d_BVDivByZero[width]; } else if (k == kind::BITVECTOR_UREM) { if (d_BVRemByZero.find(width) == d_BVRemByZero.end()) { ostringstream os; os << "BVURemByZero_" << width; Node divByZero = nm->mkSkolem(os.str(), nm->mkFunctionType(nm->mkBitVectorType(width), nm->mkBitVectorType(width)), "partial bvurem", NodeManager::SKOLEM_EXACT_NAME); d_BVRemByZero[width] = divByZero; } return d_BVRemByZero[width]; } Unreachable(); } void TheoryBV::collectNumerators(TNode term, TNodeSet& seen) { if (seen.find(term) != seen.end()) return; if (term.getKind() == kind::BITVECTOR_ACKERMANIZE_UDIV) { unsigned size = utils::getSize(term[0]); if (d_BVDivByZeroAckerman.find(size) == d_BVDivByZeroAckerman.end()) { d_BVDivByZeroAckerman[size] = TNodeSet(); } d_BVDivByZeroAckerman[size].insert(term[0]); seen.insert(term); } else if (term.getKind() == kind::BITVECTOR_ACKERMANIZE_UREM) { unsigned size = utils::getSize(term[0]); if (d_BVRemByZeroAckerman.find(size) == d_BVRemByZeroAckerman.end()) { d_BVRemByZeroAckerman[size] = TNodeSet(); } d_BVRemByZeroAckerman[size].insert(term[0]); seen.insert(term); } for (unsigned i = 0; i < term.getNumChildren(); ++i) { collectNumerators(term[i], seen); } seen.insert(term); } void TheoryBV::mkAckermanizationAsssertions(std::vector& assertions) { Debug("bv-ackermanize") << "TheoryBV::mkAckermanizationAsssertions\n"; Assert(options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER); AlwaysAssert(!options::incrementalSolving()); TNodeSet seen; for (unsigned i = 0; i < assertions.size(); ++i) { collectNumerators(assertions[i], seen); } // process division UF Debug("bv-ackermanize") << "Process division UF...\n"; for (WidthToNumerators::const_iterator it = d_BVDivByZeroAckerman.begin(); it != d_BVDivByZeroAckerman.end(); ++it) { const TNodeSet& numerators= it->second; for (TNodeSet::const_iterator i = numerators.begin(); i != numerators.end(); ++i) { TNodeSet::const_iterator j = i; j++; for (; j != numerators.end(); ++j) { TNode arg1 = *i; TNode arg2 = *j; TNode acker1 = utils::mkNode(kind::BITVECTOR_ACKERMANIZE_UDIV, arg1); TNode acker2 = utils::mkNode(kind::BITVECTOR_ACKERMANIZE_UDIV, arg2); Node arg_eq = utils::mkNode(kind::EQUAL, arg1, arg2); Node acker_eq = utils::mkNode(kind::EQUAL, acker1, acker2); Node lemma = utils::mkNode(kind::IMPLIES, arg_eq, acker_eq); Debug("bv-ackermanize") << " " << lemma << "\n"; assertions.push_back(lemma); } } } // process remainder UF Debug("bv-ackermanize") << "Process remainder UF...\n"; for (WidthToNumerators::const_iterator it = d_BVRemByZeroAckerman.begin(); it != d_BVRemByZeroAckerman.end(); ++it) { const TNodeSet& numerators= it->second; for (TNodeSet::const_iterator i = numerators.begin(); i != numerators.end(); ++i) { TNodeSet::const_iterator j = i; j++; for (; j != numerators.end(); ++j) { TNode arg1 = *i; TNode arg2 = *j; TNode acker1 = utils::mkNode(kind::BITVECTOR_ACKERMANIZE_UREM, arg1); TNode acker2 = utils::mkNode(kind::BITVECTOR_ACKERMANIZE_UREM, arg2); Node arg_eq = utils::mkNode(kind::EQUAL, arg1, arg2); Node acker_eq = utils::mkNode(kind::EQUAL, acker1, acker2); Node lemma = utils::mkNode(kind::IMPLIES, arg_eq, acker_eq); Debug("bv-ackermanize") << " " << lemma << "\n"; assertions.push_back(lemma); } } } } Node TheoryBV::expandDefinition(LogicRequest &logicRequest, Node node) { Debug("bitvector-expandDefinition") << "TheoryBV::expandDefinition(" << node << ")" << std::endl; switch (node.getKind()) { case kind::BITVECTOR_SDIV: case kind::BITVECTOR_SREM: case kind::BITVECTOR_SMOD: return TheoryBVRewriter::eliminateBVSDiv(node); break; case kind::BITVECTOR_UDIV: case kind::BITVECTOR_UREM: { NodeManager* nm = NodeManager::currentNM(); unsigned width = node.getType().getBitVectorSize(); if (options::bitvectorDivByZeroConst()) { Kind kind = node.getKind() == kind::BITVECTOR_UDIV ? kind::BITVECTOR_UDIV_TOTAL : kind::BITVECTOR_UREM_TOTAL; return nm->mkNode(kind, node[0], node[1]); } TNode num = node[0], den = node[1]; Node den_eq_0 = nm->mkNode(kind::EQUAL, den, nm->mkConst(BitVector(width, Integer(0)))); Node divTotalNumDen = nm->mkNode(node.getKind() == kind::BITVECTOR_UDIV ? kind::BITVECTOR_UDIV_TOTAL : kind::BITVECTOR_UREM_TOTAL, num, den); if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { // Ackermanize UF if using eager bit-blasting Node ackerman_var = nm->mkNode(node.getKind() == kind::BITVECTOR_UDIV ? kind::BITVECTOR_ACKERMANIZE_UDIV : kind::BITVECTOR_ACKERMANIZE_UREM, num); node = nm->mkNode(kind::ITE, den_eq_0, ackerman_var, divTotalNumDen); return node; } else { Node divByZero = getBVDivByZero(node.getKind(), width); Node divByZeroNum = nm->mkNode(kind::APPLY_UF, divByZero, num); node = nm->mkNode(kind::ITE, den_eq_0, divByZeroNum, divTotalNumDen); logicRequest.widenLogic(THEORY_UF); return node; } } break; default: return node; break; } Unreachable(); } void TheoryBV::preRegisterTerm(TNode node) { d_calledPreregister = true; Debug("bitvector-preregister") << "TheoryBV::preRegister(" << node << ")" << std::endl; if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { // the aig bit-blaster option is set heuristically // if bv abstraction is not used if (!d_eagerSolver->isInitialized()) { d_eagerSolver->initialize(); } if (node.getKind() == kind::BITVECTOR_EAGER_ATOM) { Node formula = node[0]; d_eagerSolver->assertFormula(formula); } // nothing to do for the other terms return; } for (unsigned i = 0; i < d_subtheories.size(); ++i) { d_subtheories[i]->preRegister(node); } } void TheoryBV::sendConflict() { Assert(d_conflict); if (d_conflictNode.isNull()) { return; } else { Debug("bitvector") << indent() << "TheoryBV::check(): conflict " << d_conflictNode; d_out->conflict(d_conflictNode); d_statistics.d_avgConflictSize.addEntry(d_conflictNode.getNumChildren()); d_conflictNode = Node::null(); } } void TheoryBV::checkForLemma(TNode fact) { if (fact.getKind() == kind::EQUAL) { if (fact[0].getKind() == kind::BITVECTOR_UREM_TOTAL) { TNode urem = fact[0]; TNode result = fact[1]; TNode divisor = urem[1]; Node result_ult_div = mkNode(kind::BITVECTOR_ULT, result, divisor); Node divisor_eq_0 = mkNode(kind::EQUAL, divisor, mkConst(BitVector(getSize(divisor), 0u))); Node split = utils::mkNode(kind::OR, divisor_eq_0, mkNode(kind::NOT, fact), result_ult_div); lemma(split); } if (fact[1].getKind() == kind::BITVECTOR_UREM_TOTAL) { TNode urem = fact[1]; TNode result = fact[0]; TNode divisor = urem[1]; Node result_ult_div = mkNode(kind::BITVECTOR_ULT, result, divisor); Node divisor_eq_0 = mkNode(kind::EQUAL, divisor, mkConst(BitVector(getSize(divisor), 0u))); Node split = utils::mkNode(kind::OR, divisor_eq_0, mkNode(kind::NOT, fact), result_ult_div); lemma(split); } } } void TheoryBV::check(Effort e) { if (done() && !fullEffort(e)) { return; } TimerStat::CodeTimer checkTimer(d_checkTime); Debug("bitvector") << "TheoryBV::check(" << e << ")" << std::endl; TimerStat::CodeTimer codeTimer(d_statistics.d_solveTimer); // we may be getting new assertions so the model cache may not be sound d_invalidateModelCache.set(true); // if we are using the eager solver if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { // this can only happen on an empty benchmark if (!d_eagerSolver->isInitialized()) { d_eagerSolver->initialize(); } if (!Theory::fullEffort(e)) return; std::vector assertions; while (!done()) { TNode fact = get().assertion; Assert (fact.getKind() == kind::BITVECTOR_EAGER_ATOM); assertions.push_back(fact); } Assert (d_eagerSolver->hasAssertions(assertions)); bool ok = d_eagerSolver->checkSat(); if (!ok) { if (assertions.size() == 1) { d_out->conflict(assertions[0]); return; } Node conflict = NodeManager::currentNM()->mkNode(kind::AND, assertions); d_out->conflict(conflict); return; } return; } if (Theory::fullEffort(e)) { ++(d_statistics.d_numCallsToCheckFullEffort); } else { ++(d_statistics.d_numCallsToCheckStandardEffort); } // if we are already in conflict just return the conflict if (inConflict()) { sendConflict(); return; } while (!done()) { TNode fact = get().assertion; checkForLemma(fact); for (unsigned i = 0; i < d_subtheories.size(); ++i) { d_subtheories[i]->assertFact(fact); } } bool ok = true; bool complete = false; for (unsigned i = 0; i < d_subtheories.size(); ++i) { Assert (!inConflict()); ok = d_subtheories[i]->check(e); complete = d_subtheories[i]->isComplete(); if (!ok) { // if we are in a conflict no need to check with other theories Assert (inConflict()); sendConflict(); return; } if (complete) { // if the last subtheory was complete we stop return; } } } void TheoryBV::collectModelInfo( TheoryModel* m, bool fullModel ){ Assert(!inConflict()); if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { d_eagerSolver->collectModelInfo(m, fullModel); } for (unsigned i = 0; i < d_subtheories.size(); ++i) { if (d_subtheories[i]->isComplete()) { d_subtheories[i]->collectModelInfo(m, fullModel); return; } } } Node TheoryBV::getModelValue(TNode var) { Assert(!inConflict()); for (unsigned i = 0; i < d_subtheories.size(); ++i) { if (d_subtheories[i]->isComplete()) { return d_subtheories[i]->getModelValue(var); } } Unreachable(); } void TheoryBV::propagate(Effort e) { Debug("bitvector") << indent() << "TheoryBV::propagate()" << std::endl; if (options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER) { return; } if (inConflict()) { return; } // go through stored propagations bool ok = true; for (; d_literalsToPropagateIndex < d_literalsToPropagate.size() && ok; d_literalsToPropagateIndex = d_literalsToPropagateIndex + 1) { TNode literal = d_literalsToPropagate[d_literalsToPropagateIndex]; // temporary fix for incremental bit-blasting if (d_valuation.isSatLiteral(literal)) { Debug("bitvector::propagate") << "TheoryBV:: propagating " << literal <<"\n"; ok = d_out->propagate(literal); } } if (!ok) { Debug("bitvector::propagate") << indent() << "TheoryBV::propagate(): conflict from theory engine" << std::endl; setConflict(); } } Theory::PPAssertStatus TheoryBV::ppAssert(TNode in, SubstitutionMap& outSubstitutions) { switch(in.getKind()) { case kind::EQUAL: { if (in[0].isVar() && !in[1].hasSubterm(in[0])) { ++(d_statistics.d_solveSubstitutions); outSubstitutions.addSubstitution(in[0], in[1]); return PP_ASSERT_STATUS_SOLVED; } if (in[1].isVar() && !in[0].hasSubterm(in[1])) { ++(d_statistics.d_solveSubstitutions); outSubstitutions.addSubstitution(in[1], in[0]); return PP_ASSERT_STATUS_SOLVED; } Node node = Rewriter::rewrite(in); if ((node[0].getKind() == kind::BITVECTOR_EXTRACT && node[1].isConst()) || (node[1].getKind() == kind::BITVECTOR_EXTRACT && node[0].isConst())) { Node extract = node[0].isConst() ? node[1] : node[0]; if (extract[0].getKind() == kind::VARIABLE) { Node c = node[0].isConst() ? node[0] : node[1]; unsigned high = utils::getExtractHigh(extract); unsigned low = utils::getExtractLow(extract); unsigned var_bitwidth = utils::getSize(extract[0]); std::vector children; if (low == 0) { Assert (high != var_bitwidth - 1); unsigned skolem_size = var_bitwidth - high - 1; Node skolem = utils::mkVar(skolem_size); children.push_back(skolem); children.push_back(c); } else if (high == var_bitwidth - 1) { unsigned skolem_size = low; Node skolem = utils::mkVar(skolem_size); children.push_back(c); children.push_back(skolem); } else { unsigned skolem1_size = low; unsigned skolem2_size = var_bitwidth - high - 1; Node skolem1 = utils::mkVar(skolem1_size); Node skolem2 = utils::mkVar(skolem2_size); children.push_back(skolem2); children.push_back(c); children.push_back(skolem1); } Node concat = utils::mkNode(kind::BITVECTOR_CONCAT, children); Assert (utils::getSize(concat) == utils::getSize(extract[0])); outSubstitutions.addSubstitution(extract[0], concat); return PP_ASSERT_STATUS_SOLVED; } } } break; case kind::BITVECTOR_ULT: case kind::BITVECTOR_SLT: case kind::BITVECTOR_ULE: case kind::BITVECTOR_SLE: default: // TODO other predicates break; } return PP_ASSERT_STATUS_UNSOLVED; } Node TheoryBV::ppRewrite(TNode t) { Debug("bv-pp-rewrite") << "TheoryBV::ppRewrite " << t << "\n"; Node res = t; if (RewriteRule::applies(t)) { Node result = RewriteRule::run(t); res = Rewriter::rewrite(result); } else if (d_isCoreTheory && t.getKind() == kind::EQUAL) { std::vector equalities; Slicer::splitEqualities(t, equalities); res = utils::mkAnd(equalities); } else if (RewriteRule::applies(t)) { Node result = RewriteRule::run(t); res = Rewriter::rewrite(result); } else if( res.getKind() == kind::EQUAL && ((res[0].getKind() == kind::BITVECTOR_PLUS && RewriteRule::applies(res[1])) || (res[1].getKind() == kind::BITVECTOR_PLUS && RewriteRule::applies(res[0])))) { Node mult = RewriteRule::applies(res[0])? RewriteRule::run(res[0]) : RewriteRule::run(res[1]); Node factor = mult[0]; Node sum = RewriteRule::applies(res[0])? res[1] : res[0]; Node new_eq =utils::mkNode(kind::EQUAL, sum, mult); Node rewr_eq = RewriteRule::run(new_eq); if (rewr_eq[0].isVar() || rewr_eq[1].isVar()){ res = Rewriter::rewrite(rewr_eq); } else { res = t; } } // if(t.getKind() == kind::EQUAL && // ((t[0].getKind() == kind::BITVECTOR_MULT && t[1].getKind() == kind::BITVECTOR_PLUS) || // (t[1].getKind() == kind::BITVECTOR_MULT && t[0].getKind() == kind::BITVECTOR_PLUS))) { // // if we have an equality between a multiplication and addition // // try to express multiplication in terms of addition // Node mult = t[0].getKind() == kind::BITVECTOR_MULT? t[0] : t[1]; // Node add = t[0].getKind() == kind::BITVECTOR_PLUS? t[0] : t[1]; // if (RewriteRule::applies(mult)) { // Node new_mult = RewriteRule::run(mult); // Node new_eq = Rewriter::rewrite(utils::mkNode(kind::EQUAL, new_mult, add)); // // the simplification can cause the formula to blow up // // only apply if formula reduced // if (d_subtheoryMap.find(SUB_BITBLAST) != d_subtheoryMap.end()) { // BitblastSolver* bv = (BitblastSolver*)d_subtheoryMap[SUB_BITBLAST]; // uint64_t old_size = bv->computeAtomWeight(t); // Assert (old_size); // uint64_t new_size = bv->computeAtomWeight(new_eq); // double ratio = ((double)new_size)/old_size; // if (ratio <= 0.4) { // ++(d_statistics.d_numMultSlice); // return new_eq; // } // } // if (new_eq.getKind() == kind::CONST_BOOLEAN) { // ++(d_statistics.d_numMultSlice); // return new_eq; // } // } // } if (options::bvAbstraction() && t.getType().isBoolean()) { d_abstractionModule->addInputAtom(res); } Debug("bv-pp-rewrite") << "to " << res << "\n"; return res; } void TheoryBV::presolve() { Debug("bitvector") << "TheoryBV::presolve" << endl; } static int prop_count = 0; bool TheoryBV::storePropagation(TNode literal, SubTheory subtheory) { Debug("bitvector::propagate") << indent() << getSatContext()->getLevel() << " " << "TheoryBV::storePropagation(" << literal << ", " << subtheory << ")" << std::endl; prop_count++; // If already in conflict, no more propagation if (d_conflict) { Debug("bitvector::propagate") << indent() << "TheoryBV::storePropagation(" << literal << ", " << subtheory << "): already in conflict" << std::endl; return false; } // If propagated already, just skip PropagatedMap::const_iterator find = d_propagatedBy.find(literal); if (find != d_propagatedBy.end()) { return true; } else { bool polarity = literal.getKind() != kind::NOT; Node negatedLiteral = polarity ? literal.notNode() : (Node) literal[0]; find = d_propagatedBy.find(negatedLiteral); if (find != d_propagatedBy.end() && (*find).second != subtheory) { // Safe to ignore this one, subtheory should produce a conflict return true; } d_propagatedBy[literal] = subtheory; } // Propagate differs depending on the subtheory // * bitblaster needs to be left alone until it's done, otherwise it doesn't know how to explain // * equality engine can propagate eagerly bool ok = true; if (subtheory == SUB_CORE) { d_out->propagate(literal); if (!ok) { setConflict(); } } else { d_literalsToPropagate.push_back(literal); } return ok; }/* TheoryBV::propagate(TNode) */ void TheoryBV::explain(TNode literal, std::vector& assumptions) { Assert (wasPropagatedBySubtheory(literal)); SubTheory sub = getPropagatingSubtheory(literal); d_subtheoryMap[sub]->explain(literal, assumptions); } Node TheoryBV::explain(TNode node) { Debug("bitvector::explain") << "TheoryBV::explain(" << node << ")" << std::endl; std::vector assumptions; // Ask for the explanation explain(node, assumptions); // this means that it is something true at level 0 if (assumptions.size() == 0) { return utils::mkTrue(); } // return the explanation Node explanation = utils::mkAnd(assumptions); Debug("bitvector::explain") << "TheoryBV::explain(" << node << ") => " << explanation << std::endl; Debug("bitvector::explain") << "TheoryBV::explain done. \n"; return explanation; } void TheoryBV::addSharedTerm(TNode t) { Debug("bitvector::sharing") << indent() << "TheoryBV::addSharedTerm(" << t << ")" << std::endl; d_sharedTermsSet.insert(t); if (options::bitvectorEqualitySolver()) { for (unsigned i = 0; i < d_subtheories.size(); ++i) { d_subtheories[i]->addSharedTerm(t); } } } EqualityStatus TheoryBV::getEqualityStatus(TNode a, TNode b) { Assert (options::bitblastMode() == theory::bv::BITBLAST_MODE_LAZY); for (unsigned i = 0; i < d_subtheories.size(); ++i) { EqualityStatus status = d_subtheories[i]->getEqualityStatus(a, b); if (status != EQUALITY_UNKNOWN) { return status; } } return EQUALITY_UNKNOWN; ; } void TheoryBV::enableCoreTheorySlicer() { Assert (!d_calledPreregister); d_isCoreTheory = true; if (d_subtheoryMap.find(SUB_CORE) != d_subtheoryMap.end()) { CoreSolver* core = (CoreSolver*)d_subtheoryMap[SUB_CORE]; core->enableSlicer(); } } void TheoryBV::ppStaticLearn(TNode in, NodeBuilder<>& learned) { if(d_staticLearnCache.find(in) != d_staticLearnCache.end()){ return; } d_staticLearnCache.insert(in); if (in.getKind() == kind::EQUAL) { if((in[0].getKind() == kind::BITVECTOR_PLUS && in[1].getKind() == kind::BITVECTOR_SHL) || (in[1].getKind() == kind::BITVECTOR_PLUS && in[0].getKind() == kind::BITVECTOR_SHL)) { TNode p = in[0].getKind() == kind::BITVECTOR_PLUS ? in[0] : in[1]; TNode s = in[0].getKind() == kind::BITVECTOR_PLUS ? in[1] : in[0]; if(p.getNumChildren() == 2 && p[0].getKind() == kind::BITVECTOR_SHL && p[1].getKind() == kind::BITVECTOR_SHL ){ unsigned size = utils::getSize(s); Node one = utils::mkConst(size, 1u); if(s[0] == one && p[0][0] == one && p[1][0] == one){ Node zero = utils::mkConst(size, 0u); TNode b = p[0]; TNode c = p[1]; // (s : 1 << S) = (b : 1 << B) + (c : 1 << C) Node b_eq_0 = b.eqNode(zero); Node c_eq_0 = c.eqNode(zero); Node b_eq_c = b.eqNode(c); Node dis = utils::mkNode(kind::OR, b_eq_0, c_eq_0, b_eq_c); Node imp = in.impNode(dis); learned << imp; } } } }else if(in.getKind() == kind::AND){ for(size_t i = 0, N = in.getNumChildren(); i < N; ++i){ ppStaticLearn(in[i], learned); } } } bool TheoryBV::applyAbstraction(const std::vector& assertions, std::vector& new_assertions) { bool changed = d_abstractionModule->applyAbstraction(assertions, new_assertions); if (changed && options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER && options::bitvectorAig()) { // disable AIG mode AlwaysAssert (!d_eagerSolver->isInitialized()); d_eagerSolver->turnOffAig(); d_eagerSolver->initialize(); } return changed; } void TheoryBV::setProofLog( BitVectorProof * bvp ) { if( options::bitblastMode() == theory::bv::BITBLAST_MODE_EAGER ){ d_eagerSolver->setProofLog( bvp ); }else{ for( unsigned i=0; i< d_subtheories.size(); i++ ){ d_subtheories[i]->setProofLog( bvp ); } } } void TheoryBV::setConflict(Node conflict) { if (options::bvAbstraction()) { Node new_conflict = d_abstractionModule->simplifyConflict(conflict); std::vector lemmas; lemmas.push_back(new_conflict); d_abstractionModule->generalizeConflict(new_conflict, lemmas); for (unsigned i = 0; i < lemmas.size(); ++i) { lemma(utils::mkNode(kind::NOT, lemmas[i])); } } d_conflict = true; d_conflictNode = conflict; } } /* namespace CVC4::theory::bv */ } /* namespace CVC4::theory */ } /* namespace CVC4 */