Ejemplo n.º 1
0
// The function front scans the frontier of nodePtr. It returns the keys
// of the leaves found in the frontier of nodePtr in a SListPure.
// These keys include keys of direction indicators detected in the frontier.
//
// No direction is assigned to the direction indicators.
//
void EmbedPQTree::getFront(
	PQNode<edge,IndInfo*,bool>* nodePtr,
	SListPure<PQBasicKey<edge,IndInfo*,bool>*> &keys)
{
	ArrayBuffer<PQNode<edge,IndInfo*,bool>*> S;
	S.push(nodePtr);

	while (!S.empty())
	{
		PQNode<edge,IndInfo*,bool> *checkNode = S.popRet();

		if (checkNode->type() == PQNodeRoot::PQNodeType::Leaf)
			keys.pushBack((PQBasicKey<edge,IndInfo*,bool>*) checkNode->getKey());
		else
		{
			PQNode<edge,IndInfo*,bool>* firstSon  = nullptr;
			if (checkNode->type() == PQNodeRoot::PQNodeType::PNode)
			{
				firstSon = checkNode->referenceChild();
			}
			else if (checkNode->type() == PQNodeRoot::PQNodeType::QNode)
			{
				firstSon = checkNode->getEndmost(PQNodeRoot::SibDirection::Right);
				// By this, we make sure that we start on the left side
				// since the left endmost child will be on top of the stack
			}

			if (firstSon->status() == PQNodeRoot::PQNodeStatus::Indicator)
			{
				keys.pushBack((PQBasicKey<edge,IndInfo*,bool>*) firstSon->getNodeInfo());
			}
			else
				S.push(firstSon);

			PQNode<edge,IndInfo*,bool> *nextSon = firstSon->getNextSib(nullptr);
			PQNode<edge,IndInfo*,bool> *oldSib = firstSon;
			while (nextSon && nextSon != firstSon)
			{
				if (nextSon->status() == PQNodeRoot::PQNodeStatus::Indicator)
					keys.pushBack((PQBasicKey<edge,IndInfo*,bool>*) nextSon->getNodeInfo());
				else
					S.push(nextSon);

				PQNode<edge,IndInfo*,bool> *holdSib = nextSon->getNextSib(oldSib);
				oldSib = nextSon;
				nextSon = holdSib;
			}
		}
	}
}
Ejemplo n.º 2
0
// The function front scans the frontier of nodePtr. It returns the keys 
// of the leaves found in the frontier of nodePtr in a SListPure. 
// These keys include keys of direction indicators detected in the frontier.
//
// No direction is assigned to the direction indicators.
//
void EmbedPQTree::getFront(
	PQNode<edge,indInfo*,bool>* nodePtr,
	SListPure<PQBasicKey<edge,indInfo*,bool>*> &keys)
{   
	Stack<PQNode<edge,indInfo*,bool>*> S;
	S.push(nodePtr);
  
	while (!S.empty())
	{
		PQNode<edge,indInfo*,bool> *checkNode = S.pop();

		if (checkNode->type() == PQNodeRoot::leaf)
			keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) checkNode->getKey());      
		else
		{
			PQNode<edge,indInfo*,bool>* firstSon  = 0;
			if (checkNode->type() == PQNodeRoot::PNode)
			{  
				firstSon = checkNode->referenceChild();
			}
 			else if (checkNode->type() == PQNodeRoot::QNode)
			{
				firstSon = checkNode->getEndmost(RIGHT);
				// By this, we make sure that we start on the left side
				// since the left endmost child will be on top of the stack
			}

			if (firstSon->status() == INDICATOR)
			{
				keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) firstSon->getNodeInfo());
			}
			else
				S.push(firstSon);

			PQNode<edge,indInfo*,bool> *nextSon = firstSon->getNextSib(0);
			PQNode<edge,indInfo*,bool> *oldSib = firstSon;
			while (nextSon && nextSon != firstSon)
			{
				if (nextSon->status() == INDICATOR)
					keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) nextSon->getNodeInfo());
				else
					S.push(nextSon);

				PQNode<edge,indInfo*,bool> *holdSib = nextSon->getNextSib(oldSib);
				oldSib = nextSon;
				nextSon = holdSib;
			}
		}
	}
}
Ejemplo n.º 3
0
// Overloads virtual function of base class PQTree
// Allows ignoring the virtual direction indicators during 
// the template matching algorithm.
PQNode<edge,indInfo*,bool>* EmbedPQTree::clientRightEndmost(
	PQNode<edge,indInfo*,bool> *nodePtr) const 
{
	PQNode<edge,indInfo*,bool> *right = PQTree<edge,indInfo*,bool>::clientRightEndmost(nodePtr);

	if (!right || right->status() != INDICATOR) 
		return right;
	else 
		return clientNextSib(right,NULL);
}
Ejemplo n.º 4
0
// Overloads virtual function of base class PQTree
// Allows ignoring the virtual direction indicators during 
// the template matching algorithm.
PQNode<edge,indInfo*,bool>* EmbedPQTree::clientLeftEndmost(
	PQNode<edge,indInfo*,bool> *nodePtr) const 
{
	PQNode<edge,indInfo*,bool> *left = PQTree<edge,indInfo*,bool>::clientLeftEndmost(nodePtr);
  
	if (!left || left->status() != INDICATOR) 
		return left;
	else 
		return clientNextSib(left,NULL);
}
Ejemplo n.º 5
0
// Overloads virtual function of base class PQTree
// Allows ignoring the virtual direction indicators during
// the template matching algorithm.
PQNode<edge,IndInfo*,bool>* EmbedPQTree::clientRightEndmost(
	PQNode<edge,IndInfo*,bool> *nodePtr) const
{
	PQNode<edge,IndInfo*,bool> *right = PQTree<edge,IndInfo*,bool>::clientRightEndmost(nodePtr);

	if (!right || right->status() != PQNodeRoot::PQNodeStatus::Indicator)
		return right;
	else
		return clientNextSib(right,nullptr);
}
Ejemplo n.º 6
0
// Overloads virtual function of base class PQTree
// Allows ignoring the virtual direction indicators during
// the template matching algorithm.
PQNode<edge,IndInfo*,bool>* EmbedPQTree::clientLeftEndmost(
	PQNode<edge,IndInfo*,bool> *nodePtr) const
{
	PQNode<edge,IndInfo*,bool> *left = PQTree<edge,IndInfo*,bool>::clientLeftEndmost(nodePtr);

	if (!left || left->status() != PQNodeRoot::PQNodeStatus::Indicator)
		return left;
	else
		return clientNextSib(left,nullptr);
}
Ejemplo n.º 7
0
// The function [[emptyAllPertinentNodes]] has to be called after a reduction
// has been processed. This overloaded function first destroys all full nodes
// by marking them as TO_BE_DELETED and then calling the base class function
// [[emptyAllPertinentNodes]].
void PlanarPQTree::emptyAllPertinentNodes()
{
	ListIterator<PQNode<edge,indInfo*,bool>*> it;
	for (it = m_pertinentNodes->begin(); it.valid(); it++)
	{
		PQNode<edge,indInfo*,bool>* nodePtr = (*it);
		if (nodePtr->status() == FULL)
			destroyNode(nodePtr);
	}
	if (m_pertinentRoot)
		m_pertinentRoot->status(FULL);

	PQTree<edge,indInfo*,bool>::emptyAllPertinentNodes();
}
void PlanarSubgraphPQTree::
removeEliminatedLeaves(SList<PQLeafKey<edge,whaInfo*,bool>*> &eliminatedKeys)
{
	PQNode<edge,whaInfo*,bool>*  nodePtr = 0;
	PQNode<edge,whaInfo*,bool>*  parent  = 0;
	PQNode<edge,whaInfo*,bool>*  sibling = 0;

	SListIterator<PQLeafKey<edge,whaInfo*,bool>*> it;
	for (it = eliminatedKeys.begin(); it.valid(); it++)
	{
		nodePtr = (*it)->nodePointer();
		parent = nodePtr->parent();
		sibling = nodePtr->getNextSib(NULL);

		removeNodeFromTree(parent,nodePtr);
		checkIfOnlyChild(sibling,parent);
		if (parent->status() == TO_BE_DELETED)
		{
			parent->status(WHA_DELETE);
		}
		nodePtr->status(WHA_DELETE);
	}
}
Ejemplo n.º 9
0
// The function [[emptyAllPertinentNodes]] has to be called after a reduction
// has been processed. This overloaded function first destroys all full nodes
// by marking them as TO_BE_DELETED and then calling the base class function
// [[emptyAllPertinentNodes]].
void EmbedPQTree::emptyAllPertinentNodes()
{
	ListIterator<PQNode<edge,indInfo*,bool>*> it;

	for (it = m_pertinentNodes->begin(); it.valid(); it++)
	{
		PQNode<edge,indInfo*,bool>* nodePtr = (*it);
		if (nodePtr->status() == FULL)
			destroyNode(nodePtr);
	}
	if (m_pertinentRoot) // Node was kept in the tree. Do not free it.
		m_pertinentRoot->status(FULL);

	PQTree<edge,indInfo*,bool>::emptyAllPertinentNodes();
}
Ejemplo n.º 10
0
// The function front scans the frontier of nodePtr. It returns the keys 
// of the leaves found in the frontier of nodePtr in a SListPure. 
// These keys include keys of direction indicators detected in the frontier.
//
// CAREFUL: Funktion marks all full nodes for destruction. 
//			Only to be used in connection with replaceRoot. 
//
void EmbedPQTree::front(
	PQNode<edge,indInfo*,bool>* nodePtr,
	SListPure<PQBasicKey<edge,indInfo*,bool>*> &keys)
{   
	Stack<PQNode<edge,indInfo*,bool>*> S;
	S.push(nodePtr);
  
	while (!S.empty())
	{
		PQNode<edge,indInfo*,bool> *checkNode = S.pop();

		if (checkNode->type() == PQNodeRoot::leaf)
			keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) checkNode->getKey());      
		else
		{
			PQNode<edge,indInfo*,bool>* firstSon = 0;
			if (checkNode->type() == PQNodeRoot::PNode)
			{  
				firstSon = checkNode->referenceChild();
			}
 			else if (checkNode->type() == PQNodeRoot::QNode)
			{
				firstSon = checkNode->getEndmost(RIGHT);
				// By this, we make sure that we start on the left side
				// since the left endmost child will be on top of the stack
			}

			if (firstSon->status() == INDICATOR)
			{
				keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) firstSon->getNodeInfo());
				m_pertinentNodes->pushBack(firstSon);
				destroyNode(firstSon);
			}
			else
				S.push(firstSon);

			PQNode<edge,indInfo*,bool> *nextSon = firstSon->getNextSib(0);
			PQNode<edge,indInfo*,bool> *oldSib = firstSon;
			while (nextSon && nextSon != firstSon)
			{
				if (nextSon->status() == INDICATOR)
				{
					// Direction indicators point with their left sibling pointer
					// in the direction of their sequence. If an indicator is scanned
					// from the opposite direction, coming from its right sibling
					// the corresponding sequence must be reversed.
					if (oldSib == nextSon->getSib(LEFT)) //Direction changed
						nextSon->getNodeInfo()->userStructInfo()->changeDir = true;
					keys.pushBack((PQBasicKey<edge,indInfo*,bool>*) nextSon->getNodeInfo());
					m_pertinentNodes->pushBack(nextSon);
				}
				else
					S.push(nextSon);

				PQNode<edge,indInfo*,bool> *holdSib = nextSon->getNextSib(oldSib);
				oldSib = nextSon;
				nextSon = holdSib;
			}
		}
	}
}