CCLib::ReferenceCloud* ccGenericPointCloud::getTheVisiblePoints()
{
    if (!m_visibilityArray || m_visibilityArray->currentSize()<size())
        return 0;

	unsigned i,count = size();
	assert(count == m_visibilityArray->currentSize());

    //we create an entity with the 'visible' vertices only
    CCLib::ReferenceCloud* rc = new CCLib::ReferenceCloud(this);

    for (i=0;i<count;++i)
        if (m_visibilityArray->getValue(i) > 0)
            rc->addPointIndex(i);

    return rc;
}
CCLib::ReferenceCloud* ccGenericPointCloud::getTheVisiblePoints() const
{
	unsigned count = size();
	assert(count == m_pointsVisibility->currentSize());

	if (!m_pointsVisibility || m_pointsVisibility->currentSize() != count)
	{
		ccLog::Warning("[ccGenericPointCloud::getTheVisiblePoints] No visibility table instantiated!");
		return 0;
	}

	//count the number of points to copy
	unsigned pointCount = 0;
	{
		for (unsigned i=0; i<count; ++i)
			if (m_pointsVisibility->getValue(i) == POINT_VISIBLE)
				++pointCount;
	}

	if (pointCount == 0)
	{
		ccLog::Warning("[ccGenericPointCloud::getTheVisiblePoints] No point in selection");
		return 0;
	}

	//we create an entity with the 'visible' vertices only
	CCLib::ReferenceCloud* rc = new CCLib::ReferenceCloud(const_cast<ccGenericPointCloud*>(this));
	if (rc->reserve(pointCount))
	{
		for (unsigned i=0; i<count; ++i)
			if (m_pointsVisibility->getValue(i) == POINT_VISIBLE)
				rc->addPointIndex(i); //can't fail (see above)
	}
	else
	{
		delete rc;
		rc = 0;
		ccLog::Error("[ccGenericPointCloud::getTheVisiblePoints] Not enough memory!");
	}

	return rc;
}
bool ccRegistrationTools::ICP(	ccHObject* data,
								ccHObject* model,
								ccGLMatrix& transMat,
								double &finalScale,
								double& finalRMS,
								unsigned& finalPointCount,
								double minRMSDecrease,
								unsigned maxIterationCount,
								unsigned randomSamplingLimit,
								bool removeFarthestPoints,
								CCLib::ICPRegistrationTools::CONVERGENCE_TYPE method,
								bool adjustScale,
								double finalOverlapRatio/*=1.0*/,
								bool useDataSFAsWeights/*=false*/,
								bool useModelSFAsWeights/*=false*/,
								int filters/*=CCLib::ICPRegistrationTools::SKIP_NONE*/,
								int maxThreadCount/*=0*/,
								QWidget* parent/*=0*/)
{
	//progress bar
	QScopedPointer<ccProgressDialog> progressDlg;
	if (parent)
	{
		progressDlg.reset(new ccProgressDialog(false, parent));
	}

	Garbage<CCLib::GenericIndexedCloudPersist> cloudGarbage;

	//if the 'model' entity is a mesh, we need to sample points on it
	CCLib::GenericIndexedCloudPersist* modelCloud = nullptr;
	ccGenericMesh* modelMesh = nullptr;
	if (model->isKindOf(CC_TYPES::MESH))
	{
		modelMesh = ccHObjectCaster::ToGenericMesh(model);
		modelCloud = modelMesh->getAssociatedCloud();
	}
	else
	{
		modelCloud = ccHObjectCaster::ToGenericPointCloud(model);
	}

	//if the 'data' entity is a mesh, we need to sample points on it
	CCLib::GenericIndexedCloudPersist* dataCloud = nullptr;
	if (data->isKindOf(CC_TYPES::MESH))
	{
		dataCloud = CCLib::MeshSamplingTools::samplePointsOnMesh(ccHObjectCaster::ToGenericMesh(data), s_defaultSampledPointsOnDataMesh, progressDlg.data());
		if (!dataCloud)
		{
			ccLog::Error("[ICP] Failed to sample points on 'data' mesh!");
			return false;
		}
		cloudGarbage.add(dataCloud);
	}
	else
	{
		dataCloud = ccHObjectCaster::ToGenericPointCloud(data);
	}

	//we activate a temporary scalar field for registration distances computation
	CCLib::ScalarField* dataDisplayedSF = nullptr;
	int oldDataSfIdx = -1, dataSfIdx = -1;

	//if the 'data' entity is a real ccPointCloud, we can even create a proper temporary SF for registration distances
	if (data->isA(CC_TYPES::POINT_CLOUD))
	{
		ccPointCloud* pc = static_cast<ccPointCloud*>(data);
		dataDisplayedSF = pc->getCurrentDisplayedScalarField();
		oldDataSfIdx = pc->getCurrentInScalarFieldIndex();
		dataSfIdx = pc->getScalarFieldIndexByName(REGISTRATION_DISTS_SF);
		if (dataSfIdx < 0)
			dataSfIdx = pc->addScalarField(REGISTRATION_DISTS_SF);
		if (dataSfIdx >= 0)
			pc->setCurrentScalarField(dataSfIdx);
		else
		{
			ccLog::Error("[ICP] Couldn't create temporary scalar field! Not enough memory?");
			return false;
		}
	}
	else
	{
		if (!dataCloud->enableScalarField())
		{
			ccLog::Error("[ICP] Couldn't create temporary scalar field! Not enough memory?");
			return false;
		}
	}

	//add a 'safety' margin to input ratio
	static double s_overlapMarginRatio = 0.2;
	finalOverlapRatio = std::max(finalOverlapRatio, 0.01); //1% minimum
	//do we need to reduce the input point cloud (so as to be close
	//to the theoretical number of overlapping points - but not too
	//low so as we are not registered yet ;)
	if (finalOverlapRatio < 1.0 - s_overlapMarginRatio)
	{
		//DGM we can now use 'approximate' distances as SAITO algorithm is exact (but with a coarse resolution)
		//level = 7 if < 1.000.000
		//level = 8 if < 10.000.000
		//level = 9 if > 10.000.000
		int gridLevel = static_cast<int>(floor(log10(static_cast<double>(std::max(dataCloud->size(), modelCloud->size()))))) + 2;
		    gridLevel = std::min(std::max(gridLevel, 7), 9);
		int result = -1;
		if (modelMesh)
		{
			CCLib::DistanceComputationTools::Cloud2MeshDistanceComputationParams c2mParams;
			c2mParams.octreeLevel = gridLevel;
			c2mParams.maxSearchDist = 0;
			c2mParams.useDistanceMap = true;
			c2mParams.signedDistances = false;
			c2mParams.flipNormals = false;
			c2mParams.multiThread = false;
			result = CCLib::DistanceComputationTools::computeCloud2MeshDistance(dataCloud, modelMesh, c2mParams, progressDlg.data());
		}
		else
		{
			result = CCLib::DistanceComputationTools::computeApproxCloud2CloudDistance(	dataCloud,
																						modelCloud,
																						gridLevel,
																						-1,
																						progressDlg.data());
		}

		if (result < 0)
		{
			ccLog::Error("Failed to determine the max (overlap) distance (not enough memory?)");
			return false;
		}

		//determine the max distance that (roughly) corresponds to the input overlap ratio
		ScalarType maxSearchDist = 0;
		{
			unsigned count = dataCloud->size();
			std::vector<ScalarType> distances;
			try
			{
				distances.resize(count);
			}
			catch (const std::bad_alloc&)
			{
				ccLog::Error("Not enough memory!");
				return false;
			}
			for (unsigned i=0; i<count; ++i)
			{
				distances[i] = dataCloud->getPointScalarValue(i);
			}
			
			ParallelSort(distances.begin(), distances.end());
			
			//now look for the max value at 'finalOverlapRatio+margin' percent
			maxSearchDist = distances[static_cast<unsigned>(std::max(1.0,count*(finalOverlapRatio+s_overlapMarginRatio)))-1];
		}

		//evntually select the points with distance below 'maxSearchDist'
		//(should roughly correspond to 'finalOverlapRatio + margin' percent)
		{
			CCLib::ReferenceCloud* refCloud = new CCLib::ReferenceCloud(dataCloud);
			cloudGarbage.add(refCloud);
			unsigned countBefore = dataCloud->size();
			unsigned baseIncrement = static_cast<unsigned>(std::max(100.0,countBefore*finalOverlapRatio*0.05));
			for (unsigned i=0; i<countBefore; ++i)
			{
				if (dataCloud->getPointScalarValue(i) <= maxSearchDist)
				{
					if (	refCloud->size() == refCloud->capacity()
						&&	!refCloud->reserve(refCloud->size() + baseIncrement) )
					{
						ccLog::Error("Not enough memory!");
						return false;
					}
					refCloud->addPointIndex(i);
				}
			}
			refCloud->resize(refCloud->size());
			dataCloud = refCloud;

			unsigned countAfter = dataCloud->size();
			double keptRatio = static_cast<double>(countAfter)/countBefore;
			ccLog::Print(QString("[ICP][Partial overlap] Selecting %1 points out of %2 (%3%) for registration").arg(countAfter).arg(countBefore).arg(static_cast<int>(100*keptRatio)));

			//update the relative 'final overlap' ratio
			finalOverlapRatio /= keptRatio;
		}
	}

	//weights
	CCLib::ScalarField* modelWeights = nullptr;
	CCLib::ScalarField* dataWeights = nullptr;
	{
		if (!modelMesh && useModelSFAsWeights)
		{
			if (modelCloud == dynamic_cast<CCLib::GenericIndexedCloudPersist*>(model) && model->isA(CC_TYPES::POINT_CLOUD))
			{
				ccPointCloud* pc = static_cast<ccPointCloud*>(model);
				modelWeights = pc->getCurrentDisplayedScalarField();
				if (!modelWeights)
					ccLog::Warning("[ICP] 'useDataSFAsWeights' is true but model has no displayed scalar field!");
			}
			else
			{
				ccLog::Warning("[ICP] 'useDataSFAsWeights' is true but only point cloud scalar fields can be used as weights!");
			}
		}

		if (useDataSFAsWeights)
		{
			if (!dataDisplayedSF)
			{
				if (dataCloud == ccHObjectCaster::ToPointCloud(data))
					ccLog::Warning("[ICP] 'useDataSFAsWeights' is true but data has no displayed scalar field!");
				else
					ccLog::Warning("[ICP] 'useDataSFAsWeights' is true but only point cloud scalar fields can be used as weights!");
			}
			else
			{
				dataWeights = dataDisplayedSF;
			}
		}
	}

	CCLib::ICPRegistrationTools::RESULT_TYPE result;
	CCLib::PointProjectionTools::Transformation transform;
	CCLib::ICPRegistrationTools::Parameters params;
	{
		params.convType = method;
		params.minRMSDecrease = minRMSDecrease;
		params.nbMaxIterations = maxIterationCount;
		params.adjustScale = adjustScale;
		params.filterOutFarthestPoints = removeFarthestPoints;
		params.samplingLimit = randomSamplingLimit;
		params.finalOverlapRatio = finalOverlapRatio;
		params.modelWeights = modelWeights;
		params.dataWeights = dataWeights;
		params.transformationFilters = filters;
		params.maxThreadCount = maxThreadCount;
	}

	result = CCLib::ICPRegistrationTools::Register(	modelCloud,
													modelMesh,
													dataCloud,
													params,
													transform,
													finalRMS,
													finalPointCount,
													static_cast<CCLib::GenericProgressCallback*>(progressDlg.data()));

	if (result >= CCLib::ICPRegistrationTools::ICP_ERROR)
	{
		ccLog::Error("Registration failed: an error occurred (code %i)",result);
	}
	else if (result == CCLib::ICPRegistrationTools::ICP_APPLY_TRANSFO)
	{
		transMat = FromCCLibMatrix<PointCoordinateType, float>(transform.R, transform.T, transform.s);
		finalScale = transform.s;
	}

	//remove temporary SF (if any)
	if (dataSfIdx >= 0)
	{
		assert(data->isA(CC_TYPES::POINT_CLOUD));
		ccPointCloud* pc = static_cast<ccPointCloud*>(data);
		pc->setCurrentScalarField(oldDataSfIdx);
		pc->deleteScalarField(dataSfIdx);
	}

	return (result < CCLib::ICPRegistrationTools::ICP_ERROR);
}
Exemple #4
0
CCLib::ReferenceCloud* qHPR::removeHiddenPoints(CCLib::GenericIndexedCloudPersist* theCloud, const CCVector3d& viewPoint, double fParam)
{
	assert(theCloud);

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

	//less than 4 points? no need for calculation, we return the whole cloud
	if (nbPoints < 4)
	{
		CCLib::ReferenceCloud* visiblePoints = new CCLib::ReferenceCloud(theCloud);
		if (!visiblePoints->addPointIndex(0,nbPoints)) //well even for less than 4 points we never know ;)
		{
			//not enough memory!
			delete visiblePoints;
			visiblePoints = 0;
		}
		return visiblePoints;
	}

	double maxRadius = 0;

	//convert point cloud to an array of double triplets (for qHull)
	coordT* pt_array = new coordT[(nbPoints+1)*3];
	{
		coordT* _pt_array = pt_array;

		for (unsigned i=0; i<nbPoints; ++i)
		{
			CCVector3d P = CCVector3d::fromArray(theCloud->getPoint(i)->u) - viewPoint;
			*_pt_array++ = static_cast<coordT>(P.x);
			*_pt_array++ = static_cast<coordT>(P.y);
			*_pt_array++ = static_cast<coordT>(P.z);

			//we keep track of the highest 'radius'
			double r2 = P.norm2();
			if (maxRadius < r2)
				maxRadius = r2;
		}
		
		//we add the view point (Cf. HPR)
		*_pt_array++ = 0;
		*_pt_array++ = 0;
		*_pt_array++ = 0;

		maxRadius = sqrt(maxRadius);
	}

	//apply spherical flipping
	{
		maxRadius *= pow(10.0,fParam) * 2;
	
		coordT* _pt_array = pt_array;
		for (unsigned i=0; i<nbPoints; ++i)
		{
			CCVector3d P = CCVector3d::fromArray(theCloud->getPoint(i)->u) - viewPoint;

			double r = (maxRadius/P.norm()) - 1.0;
			*_pt_array++ *= r;
			*_pt_array++ *= r;
			*_pt_array++ *= r;
		}
	}

	//array to flag points on the convex hull
	std::vector<bool> pointBelongsToCvxHull;

	static char qHullCommand[] = "qhull QJ Qci";
	if (!qh_new_qhull(3,nbPoints+1,pt_array,False,qHullCommand,0,stderr))
	{
		try
		{
			pointBelongsToCvxHull.resize(nbPoints+1,false);
		}
		catch (const std::bad_alloc&)
		{
			//not enough memory!
			delete[] pt_array;
			return 0;
		}

		vertexT *vertex = 0,**vertexp = 0;
		facetT *facet = 0;

		FORALLfacets
		{
			//if (!facet->simplicial)
			//	error("convhulln: non-simplicial facet"); // should never happen with QJ

			setT* vertices = qh_facet3vertex(facet);
			FOREACHvertex_(vertices)
			{
				pointBelongsToCvxHull[qh_pointid(vertex->point)] = true;
			}
			qh_settempfree(&vertices);
		}
	}

	delete[] pt_array;
	pt_array = 0;

	qh_freeqhull(!qh_ALL);
	//free long memory
	int curlong, totlong;
	qh_memfreeshort (&curlong, &totlong);
	//free short memory and memory allocator

	if (!pointBelongsToCvxHull.empty())
	{
		//compute the number of points belonging to the convex hull
		unsigned cvxHullSize = 0;
		{
			for (unsigned i=0; i<nbPoints; ++i)
				if (pointBelongsToCvxHull[i])
					++cvxHullSize;
		}

		CCLib::ReferenceCloud* visiblePoints = new CCLib::ReferenceCloud(theCloud);
		if (cvxHullSize!=0 && visiblePoints->reserve(cvxHullSize))
		{
			for (unsigned i=0; i<nbPoints; ++i)
				if (pointBelongsToCvxHull[i])
					visiblePoints->addPointIndex(i); //can't fail, see above

			return visiblePoints;

		}
		else //not enough memory
		{
			delete visiblePoints;
			visiblePoints = 0;
		}
	}

	return 0;
}
Exemple #5
0
int Cropper::compute()
{

    ccHObject::Container outcrops = vombat::theInstance()->getAllObjectsSelectedBySPCDti(&spc::VirtualOutcrop::Type);

    if (outcrops.size() > 1) {
        LOG(INFO) << "please select only one virtual outcrop on which to operate";
        return 1;
    }

    else if (outcrops.size() == 1) {
        m_root_outcrop = dynamic_cast<ccVirtualOutcrop*>(outcrops.at(0));
    }
    else
        m_root_outcrop = new ccVirtualOutcrop();

    ccHObject::Container selections = m_dialog->getSelections();

    //    ccHObject::Container clouds = m_dialog->getClouds();

    ccHObject::Container croppables = m_dialog->getCroppables();

    LOG(INFO) << "found " << selections.size() << " to be processed";
    //    LOG(INFO) << "Found " << clouds.size() << " point clouds to be analyzed";
    LOG(INFO) << "Found " << croppables.size() << " polylines";

    //    if (m_dialog->generateRegions())

    // first create selections out of regions
    for (ccHObject* obj : selections) {

        ccPlanarSelection* sel = dynamic_cast<ccPlanarSelection*>(obj);

        for (ccHObject* to_crop : croppables) {
            if (to_crop->isA(CC_TYPES::POLY_LINE)) {
//                if (to_crop->isA(CC_TYPES::POINT_CLOUD)) {
                ccPolyline* pline = ccHObjectCaster::ToPolyline(to_crop);

                ccPointCloud* vertices = dynamic_cast<ccPointCloud*>(pline->getAssociatedCloud());

                ccPointCloud* cropped_vertices = sel->crop(vertices);

                if (cropped_vertices) {
                    ccPolyline* cropped_pline = new ccPolyline(cropped_vertices);

                    cropped_pline->addPointIndex(0, cropped_vertices->size() - 1);
                    cropped_pline->setVisible(true);
                    //                    if (m_dialog->cropStrataTraces())
                    sel->addChild(cropped_pline);
                }
            }

            else if (to_crop->isA(CC_TYPES::POINT_CLOUD)) {

				LOG(INFO) << "cropping point cloud with name " << to_crop->getName().toStdString();

                ccPointCloud* cloud = ccHObjectCaster::ToPointCloud(to_crop);

                spc::PointCloudBase::Ptr asspc = spcCCPointCloud::fromccPointCloud(cloud);

                spc::SelectionExtractor<Eigen::Vector3f, int> ext;
                ext.setInputSet(asspc);
                ext.setSelection(sel->getSPCElement<spc::SelectionBase<Eigen::Vector3f> >());
                ext.compute();

                std::vector<int> inside = ext.getInsideIds();

                if (inside.size() == 0)
				{
					LOG(WARNING) << "the selection did not find anything inside it. Skipping";
                    continue;
				}

                CCLib::ReferenceCloud* ref = new CCLib::ReferenceCloud(cloud);
                for (int i : inside) {
                    ref->addPointIndex(i);
                }

                ccPointCloud* outcloud = cloud->partialClone(ref);

				LOG(INFO) << "done with cropping, calling add child on object: " << sel->getName().toStdString();
                sel->addChild(outcloud);
                newEntity(outcloud);
            }
        }
    }


    return 1;
}
Exemple #6
0
CCLib::ReferenceCloud* qHPR::removeHiddenPoints(CCLib::GenericIndexedCloudPersist* theCloud, float viewPoint[], float fParam)
{
	assert(theCloud);

	unsigned i,nbPoints = theCloud->size();

	if (nbPoints==0)
		return 0;

	CCLib::ReferenceCloud* newCloud = new CCLib::ReferenceCloud(theCloud);

	//less than 4 points ? no need for calculation, we return the whole cloud
	if (nbPoints<4)
	{
		if (!newCloud->reserve(nbPoints)) //well, we never know ;)
		{
			//not enough memory!
			delete newCloud;
			return 0;
		}
		newCloud->addPointIndex(0,nbPoints);
		return newCloud;
	}

	//view point
	coordT Cx = viewPoint[0];
	coordT Cy = viewPoint[1];
	coordT Cz = viewPoint[2];

	float* radius = new float[nbPoints];
	if (!radius)
	{
		//not enough memory!
		delete newCloud;
		return 0;
	}
	float r,maxRadius = 0.0;

	//table of points
	coordT* pt_array = new coordT[(nbPoints+1)*3];
	coordT* _pt_array = pt_array;
	theCloud->placeIteratorAtBegining();

//#define BACKUP_PROJECTED_CLOUDS
#ifdef BACKUP_PROJECTED_CLOUDS
	FILE* fp = fopen("output_centered.asc","wt");
#endif
	double x,y,z;
	for (i=0;i<nbPoints;++i)
	{
		const CCVector3* P = theCloud->getNextPoint();
		*(_pt_array++)=x=coordT(P->x)-Cx;
		*(_pt_array++)=y=coordT(P->y)-Cy;
		*(_pt_array++)=z=coordT(P->z)-Cz;
		//we pre-compute the radius ...
		r = (float)sqrt(x*x+y*y+z*z);
		//in order to determine the max radius
		if (maxRadius<r)
			maxRadius = r;
		radius[i] = r;
#ifdef BACKUP_PROJECTED_CLOUDS
		fprintf(fp,"%f %f %f %f\n",x,y,z,r);
#endif
	}
	//we add the view point (Cf. HPR)
	*(_pt_array++)=0.0;
	*(_pt_array++)=0.0;
	*(_pt_array++)=0.0;
#ifdef BACKUP_PROJECTED_CLOUDS
	fprintf(fp,"%f %f %f %f\n",0,0,0,0);
	fclose(fp);
#endif

	maxRadius *= 2.0f*pow(10.0f,fParam);

	_pt_array = pt_array;
#ifdef BACKUP_PROJECTED_CLOUDS
	fp = fopen("output_transformed.asc","wt");
#endif
	for (i=0;i<nbPoints;++i)
	{
		//Spherical flipping
		r = maxRadius/radius[i]-1.0f;
#ifndef BACKUP_PROJECTED_CLOUDS
		*(_pt_array++) *= double(r);
		*(_pt_array++) *= double(r);
		*(_pt_array++) *= double(r);
#else
		x = *_pt_array * double(r);
		*(_pt_array++) = x;
		y = *_pt_array * double(r);
		*(_pt_array++) = y;
		z = *_pt_array * double(r);
		*(_pt_array++) = z;
		fprintf(fp,"%f %f %f %f\n",x,y,z,r);
#endif
	}
#ifdef BACKUP_PROJECTED_CLOUDS
	fclose(fp);
#endif

	//we re-use the radius to record if each point belongs to the convex hull
	//delete[] radius;
	//uchar* pointBelongsToCvxHull = new uchar[nbPoints];
	uchar* pointBelongsToCvxHull = (uchar*)radius;
	memset(pointBelongsToCvxHull,0,sizeof(uchar)*(nbPoints+1));

	if (!qh_new_qhull(3,nbPoints+1,pt_array,False,(char*)"qhull QJ s Qci Tcv",0,stderr))
	{
		vertexT *vertex,**vertexp;
		facetT *facet;
		setT *vertices;

		int j, i = 0;
		FORALLfacets
		{
			/*if (!facet->simplicial)
				error("convhulln: non-simplicial facet"); // should never happen with QJ
				*/

			j = 0;
			vertices = qh_facet3vertex (facet);
			FOREACHvertex_(vertices)
			{
				pointBelongsToCvxHull[qh_pointid(vertex->point)]=1;
				++j;
			}
			qh_settempfree(&vertices);

			if (j < 3)
				printf("Warning, facet %d only has %d vertices\n",i,j); // likewise but less fatal

			i++;
		}
	}