Exemplo n.º 1
0
bool Cloud2CloudDist::Compute(	const Cloth& cloth,
								const wl::PointCloud& pc,
								double class_threshold,
								std::vector<int>& groundIndexes,
								std::vector<int>& offGroundIndexes,
								unsigned N/*=3*/)
{
	CCLib::SimpleCloud particlePoints;
	if (!particlePoints.reserve(static_cast<unsigned>(cloth.getSize())))
	{
		//not enough memory
		return false;
	}
	for (int i = 0; i < cloth.getSize(); i++)
	{
		const Particle& particle = cloth.getParticleByIndex(i);
		particlePoints.addPoint(CCVector3(static_cast<PointCoordinateType>(particle.pos.x), 0, static_cast<PointCoordinateType>(particle.pos.z)));
	}

	CCLib::SimpleCloud pcPoints;
	if (	!pcPoints.reserve(static_cast<unsigned>(pc.size()))
		||	!pcPoints.enableScalarField())
	{
		//not enough memory
		return false;
	}
	for (size_t i = 0; i < pc.size(); i++)
	{
		const wl::Point& P = pc[i];
		pcPoints.addPoint(CCVector3(P.x, 0, P.z));
	}

	try
	{
		//we spatially 'synchronize' the cloud and particles octrees
		CCLib::DgmOctree *cloudOctree = 0, *particleOctree = 0;
		CCLib::DistanceComputationTools::SOReturnCode soCode =
			CCLib::DistanceComputationTools::synchronizeOctrees
			(
			&particlePoints,
			&pcPoints,
			particleOctree,
			cloudOctree,
			0,
			0
			);

		if (soCode != CCLib::DistanceComputationTools::SYNCHRONIZED && soCode != CCLib::DistanceComputationTools::DISJOINT)
		{
			//not enough memory (or invalid input)
			return false;
		}

		//additional parameters
		void* additionalParameters[] = {(void*)(&cloth),
										(void*)(particleOctree),
										(void*)(&N)
		};

		int octreeLevel = particleOctree->findBestLevelForAGivenPopulationPerCell(std::max<unsigned>(2, N));

		int result = cloudOctree->executeFunctionForAllCellsAtLevel(
			octreeLevel,
			ComputeMeanNeighborAltitude,
			additionalParameters,
			true,
			0,
			"Rasterization",
			QThread::idealThreadCount());

		delete cloudOctree;
		cloudOctree = 0;

		delete particleOctree;
		particleOctree = 0;

		if (result == 0)
		{
			//something went wrong
			return false;
		}

		//now classify the points
		for (unsigned i = 0; i < pcPoints.size(); ++i)
		{
			if (std::fabs(pcPoints.getPointScalarValue(i) - pc[i].y) < class_threshold)
			{
				groundIndexes.push_back(i);
			}
			else
			{
				offGroundIndexes.push_back(i);
			}
		}

	}
	catch (const std::bad_alloc&)
	{
		//not enough memory
		return false;
	}

	return true;
}
int ccFastMarchingForNormsDirection::ResolveNormsDirectionByFrontPropagation(	ccPointCloud* theCloud,
																				NormsIndexesTableType* theNorms,
																				uchar octreeLevel,
																				CCLib::GenericProgressCallback* progressCb,
																				CCLib::DgmOctree* inputOctree)
{
	assert(theCloud);

	unsigned numberOfPoints = theCloud->size();
	if (numberOfPoints == 0)
		return -1;

	//we compute the octree if none is provided
	CCLib::DgmOctree* theOctree = inputOctree;
	if (!theOctree)
	{
		theOctree = new CCLib::DgmOctree(theCloud);
		if (theOctree->build(progressCb)<1)
		{
			delete theOctree;
			return -2;
		}
	}

	//temporary SF
	int oldSfIdx = theCloud->getCurrentDisplayedScalarFieldIndex();
	int sfIdx = theCloud->getScalarFieldIndexByName("FM_Propagation");
	if (sfIdx < 0)
		sfIdx = theCloud->addScalarField("FM_Propagation");
	if (sfIdx >= 0)
	{
		theCloud->setCurrentScalarField(sfIdx);
	}
	else
	{
		ccLog::Warning("[ccFastMarchingForNormsDirection] Couldn't create temporary scalar field! Not enough memory?");
		if (!inputOctree)
			delete theOctree;
		return -3;
	}

	if (!theCloud->enableScalarField())
	{
		ccLog::Warning("[ccFastMarchingForNormsDirection] Couldn't enable temporary scalar field! Not enough memory?");
		theCloud->deleteScalarField(sfIdx);
		theCloud->setCurrentScalarField(oldSfIdx);
		if (!inputOctree)
			delete theOctree;
		return -4;
	}

	//flags indicating if each point has been processed or not
	GenericChunkedArray<1,uchar>* resolved = new GenericChunkedArray<1,uchar>();
	if (!resolved->resize(numberOfPoints,true,0)) //defaultResolvedValue = 0
	{
		ccLog::Warning("[ccFastMarchingForNormsDirection] Not enough memory!");
		theCloud->deleteScalarField(sfIdx);
		theCloud->setCurrentScalarField(oldSfIdx);
		if (!inputOctree)
			delete theOctree;
		resolved->release();
		return -5;
	}

	//Fast Marching propagation
	ccFastMarchingForNormsDirection fm;

	int result = fm.init(theCloud,theNorms,theOctree,octreeLevel);
	if (result < 0)
	{
		ccLog::Error("[ccFastMarchingForNormsDirection] Something went wrong during initialization...");
		theCloud->deleteScalarField(sfIdx);
		theCloud->setCurrentScalarField(oldSfIdx);
		resolved->release();
		if (!inputOctree)
			delete theOctree;
		return -6;
	}

	//progress notification
	if (progressCb)
	{
		progressCb->reset();
		progressCb->setMethodTitle("Norms direction");
		progressCb->setInfo(qPrintable(QString("Octree level: %1\nPoints: %2").arg(octreeLevel).arg(numberOfPoints)));
		progressCb->start();
	}

	const int octreeWidth = (1<<octreeLevel)-1;

	//enable 26-connectivity
	//fm.setExtendedConnectivity(true);

	//while non-processed points remain...
	unsigned resolvedPoints = 0;
	int lastProcessedPoint = -1;
	while (true)
	{
		//find the next non-processed point
		do
		{
			++lastProcessedPoint;
		}
		while (lastProcessedPoint < static_cast<int>(numberOfPoints) && resolved->getValue(lastProcessedPoint) != 0);

		//all points have been processed? Then we can stop.
		if (lastProcessedPoint == static_cast<int>(numberOfPoints))
			break;

		//we start the propagation from this point
		//its corresponding cell in fact ;)
		const CCVector3 *thePoint = theCloud->getPoint(lastProcessedPoint);
		int pos[3];
		theOctree->getTheCellPosWhichIncludesThePoint(thePoint,pos,octreeLevel);

		//clipping (in case the octree is not 'complete')
		pos[0] = std::min(octreeWidth,pos[0]);
		pos[1] = std::min(octreeWidth,pos[1]);
		pos[2] = std::min(octreeWidth,pos[2]);

		//set corresponding FM cell as 'seed'
		fm.setSeedCell(pos);

		//launch propagation
		int propagationResult = fm.propagate();

		//if it's a success
		if (propagationResult >= 0)
		{
			//compute the number of points processed during this pass
			unsigned count = fm.updateResolvedTable(theCloud,*resolved,theNorms);

			if (count != 0)
			{
				resolvedPoints += count;
				if (progressCb)
					progressCb->update(static_cast<float>(resolvedPoints)/static_cast<float>(numberOfPoints)*100.0f);
			}

			fm.cleanLastPropagation();
		}
		else
		{
			ccLog::Error("An error occurred during front propagation! Process cancelled...");
			break;
		}
	}

	if (progressCb)
		progressCb->stop();

	resolved->release();
	resolved = 0;

	if (!inputOctree)
		delete theOctree;

	theCloud->showNormals(true);
#ifdef _DEBUG
	theCloud->setCurrentDisplayedScalarField(sfIdx);
	theCloud->getCurrentDisplayedScalarField()->computeMinAndMax();
	theCloud->showSF(true);
#else
	theCloud->deleteScalarField(sfIdx);
	theCloud->setCurrentScalarField(oldSfIdx);
#endif

	return 0;
}
bool ccMinimumSpanningTreeForNormsDirection::Process(	ccPointCloud* cloud,
														CCLib::GenericProgressCallback* progressCb/*=0*/,
														CCLib::DgmOctree* _octree/*=0*/)
{
	assert(cloud);
	if (!cloud->hasNormals())
	{
		ccLog::Warning(QString("Cloud '%1' has no normals!").arg(cloud->getName()));
		return false;
	}

	//ask for parameter
	bool ok;
#ifdef MST_USE_KNN
	unsigned kNN = static_cast<unsigned>(QInputDialog::getInt(0,"Neighborhood size", "Neighbors", 6, 1, 1000, 1, &ok));
	if (!ok)
		return false;
#else
	PointCoordinateType radius = static_cast<PointCoordinateType>(QInputDialog::getDouble(0,"Neighborhood radius", "radius", cloud->getOwnBB().getDiagNorm() * 0.01, 0, 1.0e9, 6, &ok));
	if (!ok)
		return false;
#endif

	//build octree if necessary
	CCLib::DgmOctree* octree = _octree;
	if (!octree)
	{
		octree = new CCLib::DgmOctree(cloud);
		if (octree->build(progressCb) <= 0)
		{
			ccLog::Warning(QString("Failed to compute octree on cloud '%1'").arg(cloud->getName()));
			delete octree;
			return false;
		}
	}
		
#ifdef MST_USE_KNN
	uchar level = octree->findBestLevelForAGivenPopulationPerCell(kNN*2);
#else
	uchar level = octree->findBestLevelForAGivenNeighbourhoodSizeExtraction(radius);
#endif

	bool result = true;
	try
	{
		Graph graph;
		if (!graph.reserve(cloud->size()))
		{
			//not enough memory!
			result = false;
		}

		//parameters
		void* additionalParameters[3] = {	reinterpret_cast<void*>(&graph),
											reinterpret_cast<void*>(cloud),
#ifdef MST_USE_KNN
											reinterpret_cast<void*>(&kNN)
#else
											reinterpret_cast<void*>(&radius)
#endif
										};

		if (octree->executeFunctionForAllCellsAtLevel(	level,
														&ComputeMSTGraphAtLevel,
														additionalParameters,
														false, //not compatible with parallel strategies!
														progressCb,
														"Build Spanning Tree") == 0)
		{
			//something went wrong
			ccLog::Warning(QString("Failed to compute Spanning Tree on cloud '%1'").arg(cloud->getName()));
			result = false;
		}
		else
		{
			if (!ResolveNormalsWithMST(cloud,graph,progressCb))
			{
				//something went wrong
				ccLog::Warning(QString("Failed to compute Minimum Spanning Tree on cloud '%1'").arg(cloud->getName()));
				result = false;
			}
		}
	}
	catch(...)
	{
		ccLog::Error(QString("Process failed on cloud '%1'").arg(cloud->getName()));
		result = false;
	}

	if (octree && !_octree)
	{
		delete octree;
		octree = 0;
	}

	return result;
}
int ccFastMarchingForNormsDirection::ResolveNormsDirectionByFrontPropagation(ccPointCloud* theCloud,
                                                                                NormsIndexesTableType* theNorms,
                                                                                uchar octreeLevel,
                                                                                CCLib::GenericProgressCallback* progressCb,
                                                                                CCLib::DgmOctree* _theOctree)
{
    assert(theCloud);

	int i,numberOfPoints = theCloud->size();
	if (numberOfPoints<1)
        return -2;

	//on calcule l'octree si besoin
	CCLib::DgmOctree* theOctree = _theOctree;
	if (!theOctree)
	{
		theOctree = new CCLib::DgmOctree(theCloud);
		if (theOctree->build(progressCb)<1)
		{
			delete theOctree;
			return -3;
		}
	}

	//temporaire
	int oldSfIdx = theCloud->getCurrentInScalarFieldIndex();
	int sfIdx = theCloud->getScalarFieldIndexByName("FM_Propagation");
	if (sfIdx<0)
		sfIdx=theCloud->addScalarField("FM_Propagation",true);
	if (sfIdx>=0)
		theCloud->setCurrentScalarField(sfIdx);
	else
	{
		ccConsole::Warning("[ccFastMarchingForNormsDirection] Couldn't create temporary scalar field! Not enough memory?");
		if (!_theOctree)
			delete theOctree;
		return -5;
	}
	theCloud->enableScalarField();

	//vecteur indiquant si le point a été traité
	GenericChunkedArray<1,uchar>* resolved = new GenericChunkedArray<1,uchar>();
	resolved->resize(numberOfPoints,true,0); //defaultResolvedValue=0

	//on va faire la propagation avec l'algorithme de Fast Marching
	ccFastMarchingForNormsDirection* fm = new ccFastMarchingForNormsDirection();

	int result = fm->init(theCloud,theNorms,theOctree,octreeLevel);
	if (result<0)
	{
		ccConsole::Error("[ccFastMarchingForNormsDirection] Something went wrong during initialization ...\n");
		theCloud->deleteScalarField(sfIdx);
		theCloud->setCurrentScalarField(oldSfIdx);
		if (!_theOctree)
			delete theOctree;
		delete fm;
		return -4;
	}

	int resolvedPoints=0;
	if (progressCb)
	{
		progressCb->reset();
		progressCb->setMethodTitle("Norms direction");
		char buffer[256];
		sprintf(buffer,"Octree level: %i\nNumber of points: %i",octreeLevel,numberOfPoints);
		progressCb->setInfo(buffer);
		progressCb->start();
	}

	int octreeLength = (1<<octreeLevel)-1;

	while (true)
	{
		//on cherche un point non encore traité
		resolved->placeIteratorAtBegining();
		for (i=0;i<numberOfPoints;++i)
		{
			if (resolved->getCurrentValue()==0)
				break;
			resolved->forwardIterator();
		}

		//si tous les points ont été traités, on peut arréter !
		if (i==numberOfPoints)
			break;

		//on lance la propagation à partir du point trouvé
		const CCVector3 *thePoint = theCloud->getPoint(i);

		int pos[3];
		theOctree->getTheCellPosWhichIncludesThePoint(thePoint,pos,octreeLevel);
		//clipping (important !)
		pos[0] = std::min(octreeLength,pos[0]);
		pos[1] = std::min(octreeLength,pos[1]);
		pos[2] = std::min(octreeLength,pos[2]);
		fm->setSeedCell(pos);

		int result = fm->propagate();

		//si la propagation s'est bien passée
		if (result>=0)
		{
			int count = fm->updateResolvedTable(theCloud,*resolved,theNorms);

			if (progressCb)
			{
				if (count>=0)
				{
					resolvedPoints += count;
					progressCb->update(float(resolvedPoints)/float(numberOfPoints)*100.0);
				}
			}

			fm->endPropagation();
		}
	}

	if (progressCb)
		progressCb->stop();

	delete fm;

	resolved->release();
	resolved=0;

	if (!_theOctree)
		delete theOctree;

	theCloud->deleteScalarField(sfIdx);
	theCloud->setCurrentScalarField(oldSfIdx);

	return 0;
}
int FastMarchingForFacetExtraction::ExtractPlanarFacets(	ccPointCloud* theCloud,
															unsigned char octreeLevel,
															ScalarType maxError,
															CCLib::DistanceComputationTools::ERROR_MEASURES errorMeasure,
															bool useRetroProjectionError/*=true*/,
															CCLib::GenericProgressCallback* progressCb/*=0*/,
															CCLib::DgmOctree* _theOctree/*=0*/)
{
	assert(theCloud);

	unsigned numberOfPoints = theCloud->size();
	if (numberOfPoints == 0)
		return -1;

	if (!theCloud->getCurrentOutScalarField())
		return -2;

	if (progressCb)
	{
		//just spawn the dialog so that we can see the
		//octree computation (in case the CPU charge prevents
		//the dialog from being shown)
		progressCb->start();
		QApplication::processEvents();
	}

	//we compute the octree if none is provided
	CCLib::DgmOctree* theOctree = _theOctree;
	if (!theOctree)
	{
		theOctree = new CCLib::DgmOctree(theCloud);
		if (theOctree->build(progressCb)<1)
		{
			delete theOctree;
			return -3;
		}
	}

	if (progressCb)
	{
		if (progressCb->textCanBeEdited())
		{
			progressCb->setMethodTitle("Fast Marching for facets extraction");
			progressCb->setInfo("Initializing...");
		}
		progressCb->start();
		QApplication::processEvents();
	}
	if (!theCloud->enableScalarField())
	{
		ccLog::Warning("[FastMarchingForFacetExtraction] Couldn't enable scalar field! Not enough memory?");
		if (!_theOctree)
			delete theOctree;
		return -4;
	}

	//raz SF values
	{
		for (unsigned i=0; i!=theCloud->size(); ++i)
			theCloud->setPointScalarValue(i,0);
	}

	//flags indicating if each point has been processed or not
	GenericChunkedArray<1,unsigned char>* flags = new GenericChunkedArray<1,unsigned char>();
	if (!flags->resize(numberOfPoints,true,0)) //defaultFlagValue = 0
	{
		ccLog::Warning("[FastMarchingForFacetExtraction] Not enough memory!");
		if (!_theOctree)
			delete theOctree;
		flags->release();
		return -5;
	}

	//Fast Marching propagation
	FastMarchingForFacetExtraction fm;

	int result = fm.init(	theCloud,
							theOctree,
							octreeLevel,
							maxError,
							errorMeasure,
							useRetroProjectionError,
							progressCb);
	if (result < 0)
	{
		ccLog::Error("[FastMarchingForFacetExtraction] Something went wrong during initialization...");
		flags->release();
		if (!_theOctree)
			delete theOctree;
		return -6;
	}

	//progress notification
	if (progressCb)
	{
		progressCb->update(0);
		if (progressCb->textCanBeEdited())
		{
			progressCb->setMethodTitle("Facets extraction");
			progressCb->setInfo(qPrintable(QString("Octree level: %1\nPoints: %2").arg(octreeLevel).arg(numberOfPoints)));
		}
		progressCb->start();
		QApplication::processEvents();
	}

	const int octreeWidth = (1<<octreeLevel)-1;

	//enable 26-connectivity mode
	//fm.setExtendedConnectivity(true);

	//while non-processed points remain...
	unsigned resolvedPoints = 0;
	int lastProcessedPoint = -1;
	unsigned facetIndex = 0;
	while (true)
	{
		//find the next non-processed point
		do
		{
			++lastProcessedPoint;
		}
		while (lastProcessedPoint < static_cast<int>(numberOfPoints) && flags->getValue(lastProcessedPoint) != 0);

		//all points have been processed? Then we can stop.
		if (lastProcessedPoint == static_cast<int>(numberOfPoints))
			break;

		//we start the propagation from this point
		//its corresponding cell in fact ;)
		const CCVector3 *thePoint = theCloud->getPoint(lastProcessedPoint);
		Tuple3i pos;
		theOctree->getTheCellPosWhichIncludesThePoint(thePoint, pos, octreeLevel);

		//clipping (in case the octree is not 'complete')
		pos.x = std::min(octreeWidth, pos.x);
		pos.y = std::min(octreeWidth, pos.y);
		pos.z = std::min(octreeWidth, pos.z);

		//set corresponding FM cell as 'seed'
		if (!fm.setSeedCell(pos))
		{
			//an error occurred?!
			//result = -7;
			//break;
			continue;
		}

		//launch propagation
		int propagationResult = fm.propagate();

		//compute the number of points processed during this pass
		unsigned count = fm.updateFlagsTable(theCloud,*flags,propagationResult >= 0 ? ++facetIndex : 0); //0 = invalid facet index

		if (count != 0)
		{
			resolvedPoints += count;
			if (progressCb)
			{
				if (progressCb->isCancelRequested())
				{
					result = -7;
					break;
				}
				progressCb->update(static_cast<float>(resolvedPoints)/static_cast<float>(numberOfPoints)*100.0f);
			}
		}

		fm.cleanLastPropagation();
	}

	if (progressCb)
		progressCb->stop();

	flags->release();
	flags = 0;

	if (!_theOctree)
		delete theOctree;

	return result;
}