Exemplo n.º 1
0
Node ModelPostprocessor::rewriteAs(TNode n, TypeNode asType) {
  if(n.getType().isSubtypeOf(asType)) {
    // good to go, we have the right type
    return n;
  }
  if(!n.isConst()) {
    // we don't handle non-const right now
    return n;
  }
  if(asType.isBoolean()) {
    if(n.getType().isBitVector(1u)) {
      // type mismatch: should only happen for Boolean-term conversion under
      // datatype constructor applications; rewrite from BV(1) back to Boolean
      bool tf = (n.getConst<BitVector>().getValue() == 1);
      return NodeManager::currentNM()->mkConst(tf);
    }
    if(n.getType().isDatatype() && n.getType().hasAttribute(BooleanTermAttr())) {
      // type mismatch: should only happen for Boolean-term conversion under
      // datatype constructor applications; rewrite from datatype back to Boolean
      Assert(n.getKind() == kind::APPLY_CONSTRUCTOR);
      Assert(n.getNumChildren() == 0);
      // we assume (by construction) false is first; see boolean_terms.cpp
      bool tf = (Datatype::indexOf(n.getOperator().toExpr()) == 1);
      Debug("boolean-terms") << "+++ rewriteAs " << n << " : " << asType << " ==> " << tf << endl;
      return NodeManager::currentNM()->mkConst(tf);
    }
  }
  if(n.getType().isBoolean()) {
    bool tf = n.getConst<bool>();
    if(asType.isBitVector(1u)) {
      return NodeManager::currentNM()->mkConst(BitVector(1u, tf ? 1u : 0u));
    }
    if(asType.isDatatype() && asType.hasAttribute(BooleanTermAttr())) {
      const Datatype& asDatatype = asType.getConst<Datatype>();
      return NodeManager::currentNM()->mkNode(kind::APPLY_CONSTRUCTOR, (tf ? asDatatype[0] : asDatatype[1]).getConstructor());
    }
  }
  if(n.getType().isRecord() && asType.isRecord()) {
    Debug("boolean-terms") << "+++ got a record - rewriteAs " << n << " : " << asType << endl;
    const Record& rec CVC4_UNUSED = n.getType().getConst<Record>();
    const Record& asRec = asType.getConst<Record>();
    Assert(rec.getNumFields() == asRec.getNumFields());
    Assert(n.getNumChildren() == asRec.getNumFields());
    NodeBuilder<> b(n.getKind());
    b << asType;
    for(size_t i = 0; i < n.getNumChildren(); ++i) {
      b << rewriteAs(n[i], TypeNode::fromType(asRec[i].second));
    }
    Node out = b;
    Debug("boolean-terms") << "+++ returning record " << out << endl;
    return out;
  }
Exemplo n.º 2
0
Kind SymmetryBreaker::getOrderKind(Node node)
{
  TypeNode tn = node.getType();
  if (tn.isBoolean())
  {
    return IMPLIES;
  }
  else if (tn.isReal())
  {
    return LEQ;
  }
  else if (tn.isBitVector())
  {
    return BITVECTOR_ULE;
  }
  if (tn.isFirstClass())
  {
    return EQUAL;
  }
  return UNDEFINED_KIND;
}
Exemplo n.º 3
0
  Node removeToFPGeneric (TNode node) {
    Assert(node.getKind() == kind::FLOATINGPOINT_TO_FP_GENERIC);
    
    FloatingPointToFPGeneric info = node.getOperator().getConst<FloatingPointToFPGeneric>();
    
    size_t children = node.getNumChildren();
    
    Node op;
    
    if (children == 1) {
      op = NodeManager::currentNM()->mkConst(FloatingPointToFPIEEEBitVector(info.t.exponent(),
									    info.t.significand()));
      return NodeManager::currentNM()->mkNode(op, node[0]);
      
    } else {
      Assert(children == 2);
      Assert(node[0].getType().isRoundingMode());
      
      TypeNode t = node[1].getType();
      
      if (t.isFloatingPoint()) {
	op = NodeManager::currentNM()->mkConst(FloatingPointToFPFloatingPoint(info.t.exponent(),
									      info.t.significand()));
      } else if (t.isReal()) {
	op = NodeManager::currentNM()->mkConst(FloatingPointToFPReal(info.t.exponent(),
								     info.t.significand()));
      } else if (t.isBitVector()) {
	op = NodeManager::currentNM()->mkConst(FloatingPointToFPSignedBitVector(info.t.exponent(),
										info.t.significand()));
	
      } else {
	throw TypeCheckingExceptionPrivate(node, "cannot rewrite to_fp generic due to incorrect type of second argument");
      }
      
      return NodeManager::currentNM()->mkNode(op, node[0], node[1]);
    }
    
    Unreachable("to_fp generic not rewritten");
  }
Exemplo n.º 4
0
void CoreSolver::buildModel() {
  Debug("bv-core") << "CoreSolver::buildModel() \n";
  d_modelValues.clear();
  TNodeSet constants;
  TNodeSet constants_in_eq_engine;
  // collect constants in equality engine
  eq::EqClassesIterator eqcs_i = eq::EqClassesIterator(&d_equalityEngine);
  while (!eqcs_i.isFinished()) {
    TNode repr = *eqcs_i;
    if  (repr.getKind() == kind::CONST_BITVECTOR) {
      // must check if it's just the constant
      eq::EqClassIterator it(repr, &d_equalityEngine);
      if (!(++it).isFinished() || true) {
        constants.insert(repr);
        constants_in_eq_engine.insert(repr);
      }
    }
    ++eqcs_i;
  }

  // build repr to value map

  eqcs_i = eq::EqClassesIterator(&d_equalityEngine);
  while (!eqcs_i.isFinished()) {
    TNode repr = *eqcs_i;
    ++eqcs_i;

    if (repr.getKind() != kind::VARIABLE &&
        repr.getKind() != kind::SKOLEM &&
        repr.getKind() != kind::CONST_BITVECTOR &&
        !d_bv->isSharedTerm(repr)) {
      continue;
    }

    TypeNode type = repr.getType();
    if (type.isBitVector() && repr.getKind()!= kind::CONST_BITVECTOR) {
      Debug("bv-core-model") << "   processing " << repr <<"\n";
      // we need to assign a value for it
      TypeEnumerator te(type);
      Node val;
      do {
        val = *te;
        ++te;
        // Debug("bv-core-model") << "  trying value " << val << "\n";
        // Debug("bv-core-model") << "  is in set? " << constants.count(val) << "\n";
        // Debug("bv-core-model") << "  enumerator done? " << te.isFinished() << "\n";
      } while (constants.count(val) != 0 && !(te.isFinished()));

      if (te.isFinished() && constants.count(val) != 0) {
        // if we cannot enumerate anymore values we just return the lemma stating that
        // at least two of the representatives are equal.
        std::vector<TNode> representatives;
        representatives.push_back(repr);

        for (TNodeSet::const_iterator it = constants_in_eq_engine.begin();
             it != constants_in_eq_engine.end(); ++it) {
          TNode constant = *it;
          if (utils::getSize(constant) == utils::getSize(repr)) {
            representatives.push_back(constant);
          }
        }
        for (ModelValue::const_iterator it = d_modelValues.begin(); it != d_modelValues.end(); ++it) {
          representatives.push_back(it->first);
        }
        std::vector<Node> equalities;
        for (unsigned i = 0; i < representatives.size(); ++i) {
          for (unsigned j = i + 1; j < representatives.size(); ++j) {
            TNode a = representatives[i];
            TNode b = representatives[j];
            if (a.getKind() == kind::CONST_BITVECTOR &&
                b.getKind() == kind::CONST_BITVECTOR) {
              Assert (a != b);
              continue;
            }
            if (utils::getSize(a) == utils::getSize(b)) {
              equalities.push_back(utils::mkNode(kind::EQUAL, a, b));
            }
          }
        }
        // better off letting the SAT solver split on values
        if (equalities.size() > d_lemmaThreshold) {
          d_isComplete = false;
          return;
        }

        Node lemma = utils::mkOr(equalities);
        d_bv->lemma(lemma);
        Debug("bv-core") << "  lemma: " << lemma << "\n";
        return;
      }
    
      Debug("bv-core-model") << "   " << repr << " => " << val <<"\n" ;
      constants.insert(val);
      d_modelValues[repr] = val;
    }
  }
}