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OspTree.cpp @ 2542

Revision 2542, 60.6 KB checked in by mattausch, 17 years ago (diff)

Rev	Line
[1237]	1	#include <stack>
	2	#include <time.h>
	3	#include <iomanip>
	4
	5	#include "ViewCell.h"
	6	#include "Plane3.h"
	7	#include "OspTree.h"
	8	#include "Mesh.h"
	9	#include "common.h"
	10	#include "Environment.h"
	11	#include "Polygon3.h"
	12	#include "Ray.h"
	13	#include "AxisAlignedBox3.h"
	14	#include "Exporter.h"
	15	#include "Plane3.h"
	16	#include "ViewCellsManager.h"
	17	#include "Beam.h"
	18	#include "KdTree.h"
[1315]	19	#include "IntersectableWrapper.h"
[1237]	20	#include "VspTree.h"
	21
[2176]	22	using namespace std;
[1237]	23
[2176]	24
[1237]	25	namespace GtpVisibilityPreprocessor {
	26
	27
	28	#define USE_FIXEDPOINT_T 0
	29
	30
[2116]	31	int MailablePvsData::sMailId = 1;
	32	int MailablePvsData::sReservedMailboxes = 1;
	33
	34
[1570]	35	////////////
[1237]	36	//-- static members
	37
	38	OspTree *OspTree::OspSubdivisionCandidate::sOspTree = NULL;
	39
	40	// variable for debugging volume contribution for heuristics
	41	static float debugVol;
	42
	43	static bool ViewCellHasMultipleReferences(Intersectable *obj,
	44	ViewCell *vc,
	45	bool checkOnlyMailed)
	46	{
[1736]	47	// no view cell pvs!!
	48	/* MailablePvsData *vdata = obj->mViewCellPvs.Find(vc);
[1570]	49
[1237]	50	if (vdata)
	51	{
	52	// more than one view cell sees this object inside different kd cells
	53	if (!checkOnlyMailed \|\| !vdata->Mailed())
	54	{
	55	if (checkOnlyMailed)
	56	vdata->Mail();
	57	//Debug << "sumpdf: " << vdata->mSumPdf << endl;
	58	if (vdata->mSumPdf > 1.5f)
	59	return true;
	60	}
[1736]	61	}*/
[1237]	62
	63	return false;
	64	}
	65
	66
	67	void OspTreeStatistics::Print(ostream &app) const
	68	{
	69	app << "=========== OspTree statistics ===============\n";
	70
	71	app << setprecision(4);
	72
	73	app << "#N_CTIME ( Construction time [s] )\n" << Time() << " \n";
	74
	75	app << "#N_NODES ( Number of nodes )\n" << nodes << "\n";
	76
	77	app << "#N_INTERIORS ( Number of interior nodes )\n" << Interior() << "\n";
	78
	79	app << "#N_LEAVES ( Number of leaves )\n" << Leaves() << "\n";
	80
	81	app << "#AXIS_ALIGNED_SPLITS (number of axis aligned splits)\n" << splits[0] + splits[1] + splits[2] << endl;
	82
	83	app << "#N_SPLITS ( Number of splits in axes x y z)\n";
	84
	85	for (int i = 0; i < 3; ++ i)
	86	app << splits[i] << " ";
	87	app << endl;
	88
	89	app << "#N_PMAXDEPTHLEAVES ( Percentage of leaves at maximum depth )\n"
	90	<< maxDepthNodes * 100 / (double)Leaves() << endl;
	91
	92	app << "#N_PMINPVSLEAVES ( Percentage of leaves with mininimal PVS )\n"
	93	<< minPvsNodes * 100 / (double)Leaves() << endl;
	94
	95	//app << "#N_PMINOBJECTREFLEAVES ( Percentage of leaves with minimal number of object ref)\n"
	96	//<< minObjectNodes * 100 / (double)Leaves() << endl;
	97
	98	app << "#N_MAXCOSTNODES ( Percentage of leaves with terminated because of max cost ratio )\n"
	99	<< maxCostNodes * 100 / (double)Leaves() << endl;
	100
	101	app << "#N_PMINPROBABILITYLEAVES ( Percentage of leaves with mininum probability )\n"
	102	<< minProbabilityNodes * 100 / (double)Leaves() << endl;
	103
	104	app << "#N_PMAXDEPTH ( Maximal reached depth )\n" << maxDepth << endl;
	105
	106	app << "#N_PMINDEPTH ( Minimal reached depth )\n" << minDepth << endl;
	107
	108	app << "#AVGDEPTH ( average depth )\n" << AvgDepth() << endl;
	109
	110	app << "#N_INVALIDLEAVES (number of invalid leaves )\n" << invalidLeaves << endl;
	111
	112	app << "#N_MAXOBJECTREFS ( Max number of object refs / leaf )\n" <<
	113	maxObjectRefs << "\n";
	114
	115	// app << "#N_RAYS (number of rays / leaf)\n" << AvgRays() << endl;
	116	//app << "#N_PVS: " << pvs << endl;
	117
	118	app << "========== END OF VspTree statistics ==========\n";
	119	}
	120
	121
	122	/******************************************************************/
	123	/* class VspNode implementation */
	124	/******************************************************************/
	125
	126
	127	/*******************************************************************/
	128	/* class OspTree implementation */
	129	/*******************************************************************/
	130
	131
	132	OspTree::OspTree():
	133	mRoot(NULL),
	134	mTimeStamp(1),
	135	mCopyFromKdTree(false)
	136	{
	137	ReadEnvironment();
	138	mSubdivisionCandidates = new vector<SortableEntry>;
	139	}
	140
	141
	142	OspTree::OspTree(const KdTree &kdTree)
	143	{
	144	ReadEnvironment();
	145
	146	// copy values from kd tree
	147	mCopyFromKdTree = true;
	148	mBoundingBox = kdTree.GetBox();
	149	mRoot = kdTree.GetRoot();
	150
	151	mSubdivisionCandidates = new vector<SortableEntry>;
	152	}
	153
	154
	155	OspTree::~OspTree()
	156	{
	157	// delete kd intersectables
	158	KdIntersectableMap::iterator it, it_end = mKdIntersectables.end();
	159
	160	for (it = mKdIntersectables.begin(); it != mKdIntersectables.end(); ++ it)
	161	{
	162	DEL_PTR((*it).second);
	163	}
	164
[1415]	165	// delete hierarchy only if not using the hierarchy from
	166	// some other kd tree (otherwise the other kd tree has to do the job)
[1237]	167	if (!mCopyFromKdTree)
	168	DEL_PTR(mRoot);
	169
	170	DEL_PTR(mSubdivisionCandidates);
	171	mSubdivisionStats.close();
	172	}
	173
	174
	175	void OspTree::ReadEnvironment()
	176	{
	177	bool randomize = false;
	178	Environment::GetSingleton()->GetBoolValue("VspTree.Construction.randomize", randomize);
	179	if (randomize)
	180	Randomize(); // initialise random generator for heuristics
	181
	182	//-- termination criteria for autopartition
	183	Environment::GetSingleton()->GetIntValue("OspTree.Termination.maxDepth", mTermMaxDepth);
	184	Environment::GetSingleton()->GetIntValue("OspTree.Termination.maxLeaves", mTermMaxLeaves);
	185	Environment::GetSingleton()->GetIntValue("OspTree.Termination.minObjects", mTermMinObjects);
	186	Environment::GetSingleton()->GetFloatValue("OspTree.Termination.minProbability", mTermMinProbability);
	187
	188	Environment::GetSingleton()->GetIntValue("OspTree.Termination.missTolerance", mTermMissTolerance);
	189
	190	//-- max cost ratio for early tree termination
	191	Environment::GetSingleton()->GetFloatValue("OspTree.Termination.maxCostRatio", mTermMaxCostRatio);
	192
	193	Environment::GetSingleton()->GetFloatValue("OspTree.Termination.minGlobalCostRatio",
	194	mTermMinGlobalCostRatio);
	195
	196
	197	//-- factors for bsp tree split plane heuristics
	198	Environment::GetSingleton()->GetFloatValue("OspTree.Termination.ct_div_ci", mCtDivCi);
	199
	200	//-- partition criteria
	201	Environment::GetSingleton()->GetFloatValue("OspTree.Construction.epsilon", mEpsilon);
	202
	203	// if only the driving axis is used for axis aligned split
	204	Environment::GetSingleton()->GetBoolValue("OspTree.splitUseOnlyDrivingAxis", mOnlyDrivingAxis);
	205	Environment::GetSingleton()->GetFloatValue("OspTree.maxStaticMemory", mMaxMemory);
	206	Environment::GetSingleton()->GetBoolValue("OspTree.useCostHeuristics", mUseCostHeuristics);
	207
	208
	209	char subdivisionStatsLog[100];
	210	Environment::GetSingleton()->GetStringValue("OspTree.subdivisionStats", subdivisionStatsLog);
	211	mSubdivisionStats.open(subdivisionStatsLog);
	212
	213	Environment::GetSingleton()->GetFloatValue("OspTree.Construction.splitBorder", mSplitBorder);
[1288]	214	Environment::GetSingleton()->GetFloatValue(
	215	"OspTree.Construction.renderCostDecreaseWeight", mRenderCostDecreaseWeight);
[1237]	216
	217
	218	//-- debug output
	219
	220	Debug << "***** OSP tree options ****** " << endl;
	221
	222	Debug << "max depth: " << mTermMaxDepth << endl;
	223	Debug << "min probabiliy: " << mTermMinProbability << endl;
	224	Debug << "min objects: " << mTermMinObjects << endl;
	225	Debug << "max cost ratio: " << mTermMaxCostRatio << endl;
	226	Debug << "miss tolerance: " << mTermMissTolerance << endl;
	227	Debug << "max leaves: " << mTermMaxLeaves << endl;
	228
	229	Debug << "randomize: " << randomize << endl;
	230
	231	Debug << "min global cost ratio: " << mTermMinGlobalCostRatio << endl;
	232	Debug << "global cost miss tolerance: " << mTermGlobalCostMissTolerance << endl;
	233	Debug << "only driving axis: " << mOnlyDrivingAxis << endl;
	234	Debug << "max memory: " << mMaxMemory << endl;
	235	Debug << "use cost heuristics: " << mUseCostHeuristics << endl;
	236	Debug << "subdivision stats log: " << subdivisionStatsLog << endl;
	237
	238	Debug << "split borders: " << mSplitBorder << endl;
	239	Debug << "render cost decrease weight: " << mRenderCostDecreaseWeight << endl;
	240	Debug << endl;
	241	}
	242
	243
	244	void OspTree::SplitObjects(KdLeaf *parent,
	245	const AxisAlignedPlane& splitPlane,
	246	const ObjectContainer &objects,
	247	ObjectContainer &front,
	248	ObjectContainer &back)
	249	{
	250	ObjectContainer::const_iterator oit, oit_end = objects.end();
	251
	252	for (oit = objects.begin(); oit != oit_end; ++ oit)
	253	{
	254	Intersectable object = oit;
	255
	256	// initialise leaf references of objects
	257	if (parent->IsRoot())
	258	{
[1736]	259	// matt: no more parent ref
	260	//object->mReferences = 1;
[1237]	261	}
	262
	263	// remove parent ref
[1736]	264	// matt: no more parent ref
	265	//-- object->mReferences;
[1237]	266
	267	// determine the side of this ray with respect to the plane
	268	const AxisAlignedBox3 box = object->GetBox();
	269
	270	if (box.Max(splitPlane.mAxis) >= splitPlane.mPosition)
	271	{
	272	front.push_back(object);
[1736]	273	// matt: no more ref
	274	//++ object->mReferences;
[1237]	275	}
	276
	277	if (box.Min(splitPlane.mAxis) < splitPlane.mPosition)
	278	{
	279	back.push_back(object);
[1736]	280	// matt: no more ref
	281	//++ object->mReferences;
[1237]	282	}
	283	}
	284
	285	mOspStats.objectRefs -= (int)objects.size();
	286	mOspStats.objectRefs += (int)(back.size() + front.size());
	287	}
	288
	289
	290	KdInterior *OspTree::SubdivideNode(
	291	const AxisAlignedPlane &splitPlane,
	292	const OspTraversalData &tData,
	293	OspTraversalData &frontData,
	294	OspTraversalData &backData
	295	)
	296	{
	297	KdLeaf *leaf = tData.mNode;
	298
	299	// two new leaves
	300	mOspStats.nodes += 2;
	301
	302	// add the new nodes to the tree
	303	KdInterior *node = new KdInterior(leaf->mParent);
	304
	305	const int axis = splitPlane.mAxis;
	306	const float position = splitPlane.mPosition;
	307
	308	node->mAxis = axis;
	309	node->mPosition = position;
	310	node->mBox = tData.mBoundingBox;
	311
	312
	313	//-- the front and back traversal data is filled with the new values
	314
	315	// bounding boxes: split front and back node geometry
	316	tData.mBoundingBox.Split(splitPlane.mAxis, splitPlane.mPosition,
	317	frontData.mBoundingBox, backData.mBoundingBox);
	318
	319	frontData.mDepth = backData.mDepth = tData.mDepth + 1;
	320
	321	//-- subdivide rays
	322	frontData.mRays = new RayInfoContainer();
	323	backData.mRays = new RayInfoContainer();
	324
	325	/* SplitRays(splitPlane,
	326	*tData.mRays,
	327	*frontData.mRays,
	328	*backData.mRays);
	329	*/
	330
	331	//-- classify objects
	332
	333	int objectsBack = 0;
	334	int objectsFront = 0;
	335
	336	ObjectContainer::const_iterator mi, mi_end = leaf->mObjects.end();
	337
	338	for ( mi = leaf->mObjects.begin(); mi != mi_end; ++ mi)
	339	{
	340	// determine the side of this ray with respect to the plane
	341	const AxisAlignedBox3 box = (*mi)->GetBox();
	342
	343	if (box.Max(axis) >= position)
	344	++ objectsFront;
	345
	346	if (box.Min(axis) < position)
	347	++ objectsBack;
	348	}
	349
	350
	351	// TODO matt: compute pvs
	352	//frontData.mPvs = objectsFront;
	353	//backData.mPvs = objectsBack;
	354
	355	//CheckViewCellsPvs(leaf, *tData.mRays);
	356	RemoveParentViewCellsPvs(leaf, *tData.mRays);
	357
	358
	359	/////////////
	360	//-- create front and back leaf
	361
	362	KdLeaf *back = new KdLeaf(node, objectsBack);
	363	KdLeaf *front = new KdLeaf(node, objectsFront);
	364
	365	KdInterior *parent = leaf->mParent;
	366
	367	// replace a link from node's parent
	368	if (parent)
	369	{
	370	parent->ReplaceChildLink(leaf, node);
	371	node->mParent = parent;
	372	}
	373	else // new root
	374	{
	375	mRoot = node;
	376	}
	377
	378	// and setup child links
	379	node->SetupChildLinks(back, front);
	380
	381	SplitObjects(leaf, splitPlane, leaf->mObjects, front->mObjects, back->mObjects);
	382
	383	FilterRays(front, tData.mRays, frontData.mRays);
	384	FilterRays(back, tData.mRays, backData.mRays);
	385
	386	++ mOspStats.splits[splitPlane.mAxis];
	387
	388	//-- eval view cells pvs
	389
	390	// remove parent pvs update pvs of left and right leaves
	391	// Note: It is necessary to update first left and then right pvs.
	392	// We need to store the view cells seen by each object,
	393	// but also if the view cells are seen as part of two different
	394	// kd leaves, which is stored in the pdf component of the pvs entry.
	395	// Because if an object is part of a view cell more than once,
	396	// it cannot be removed from the pvs by splitting a kd node where
	397	// the view cell sees only the other child of the node.
	398	// This is important during the subdivision
	399
[2100]	400	//MailablePvsData::NewMail();
[1237]	401	UpdateViewCellsPvs(front, *frontData.mRays);
	402	UpdateViewCellsPvs(back, *backData.mRays);
	403
	404	////////////////////////////////////
	405
	406
	407	ProcessMultipleRefs(front);
	408	ProcessMultipleRefs(back);
	409
	410	frontData.mNode = front;
	411	backData.mNode = back;
	412
	413	// compute probability, i.e., volume of seen view cells
	414	frontData.mProbability = EvalViewCellsVolume(front, *frontData.mRays);
	415	backData.mProbability = EvalViewCellsVolume(back, *backData.mRays);
	416
	417	//delete leaf;
	418	return node;
	419	}
	420
	421
	422	KdNode *OspTree::Subdivide(SplitQueue &tQueue,
	423	SubdivisionCandidate *splitCandidate,
	424	const bool globalCriteriaMet)
	425	{
[2017]	426	OspSubdivisionCandidate sc = static_cast<OspSubdivisionCandidate >(splitCandidate);
[1237]	427	OspTraversalData &tData = sc->mParentData;
	428
	429	KdNode *newNode = tData.mNode;
	430
	431	if (!LocalTerminationCriteriaMet(tData) && !globalCriteriaMet)
	432	{
	433	OspTraversalData tFrontData;
	434	OspTraversalData tBackData;
	435
	436	//-- continue subdivision
	437
	438	// create new interior node and two leaf node
	439	const AxisAlignedPlane splitPlane = sc->mSplitPlane;
	440
	441	newNode = SubdivideNode(splitPlane,
	442	tData,
	443	tFrontData,
	444	tBackData);
	445
[1576]	446	const int maxCostMisses = sc->GetMaxCostMisses();
[1237]	447
	448	// how often was max cost ratio missed in this branch?
	449	tFrontData.mMaxCostMisses = maxCostMisses;
	450	tBackData.mMaxCostMisses = maxCostMisses;
	451
	452	mTotalCost -= sc->GetRenderCostDecrease();
	453
	454	// subdivision statistics
	455	if (1) EvalSubdivisionStats(*sc);
	456
	457	//-- push the new split candidates on the queue
	458
	459	OspSubdivisionCandidate *frontCandidate = new OspSubdivisionCandidate(tFrontData);
	460	OspSubdivisionCandidate *backCandidate = new OspSubdivisionCandidate(tBackData);
	461
	462	EvalSubdivisionCandidate(*frontCandidate);
	463	EvalSubdivisionCandidate(*backCandidate);
	464
	465	tQueue.Push(frontCandidate);
	466	tQueue.Push(backCandidate);
	467
	468	// delete old leaf node
	469	DEL_PTR(tData.mNode);
	470	}
	471
	472
	473	//-- terminate traversal
	474	if (newNode->IsLeaf())
	475	{
	476	EvaluateLeafStats(tData);
	477
	478	const bool mStoreRays= true;
	479
	480	//-- store additional info
	481	if (mStoreRays)
	482	{
[2017]	483	KdLeaf leaf = static_cast<KdLeaf >(newNode);
[1237]	484
	485	RayInfoContainer::const_iterator it, it_end = tData.mRays->end();
	486
	487	for (it = tData.mRays->begin(); it != it_end; ++ it)
	488	{
	489	(*it).mRay->Ref();
	490	leaf->mVssRays.push_back((*it).mRay);
	491	}
	492	}
	493	}
	494
	495	//-- cleanup
	496	tData.Clear();
	497
	498	return newNode;
	499	}
	500
	501
	502	void OspTree::EvalSubdivisionCandidate(OspSubdivisionCandidate &splitCandidate)
	503	{
	504	// compute locally best split plane
	505	const float ratio = SelectSplitPlane(splitCandidate.mParentData,
[1251]	506	splitCandidate.mSplitPlane);
[1237]	507
	508	const bool success = ratio < mTermMaxCostRatio;
	509	float oldRenderCost;
	510
	511	// compute global decrease in render cost
	512	const float renderCostDecr = EvalRenderCostDecrease(splitCandidate.mSplitPlane,
	513	splitCandidate.mParentData,
	514	oldRenderCost);
	515
	516	splitCandidate.SetRenderCostDecrease(renderCostDecr);
	517
[1576]	518	const float pvsSizeIncr = 0; // todo
[1237]	519	#if 0
	520	const float priority = (float)-data.mDepth;
	521	#else
	522	// take render cost of node into account
	523	// otherwise danger of being stuck in a local minimum!!
	524	const float factor = mRenderCostDecreaseWeight;
	525	const float priority = factor * renderCostDecr + (1.0f - factor) * oldRenderCost;
	526
	527	#endif
	528
	529	// compute global decrease in render cost
	530	splitCandidate.SetPriority(priority);
	531
[1576]	532	splitCandidate.SetMaxCostMisses(success ?
	533	splitCandidate.mParentData.mMaxCostMisses :
	534	splitCandidate.mParentData.mMaxCostMisses + 1);
[1237]	535	}
	536
	537
[1251]	538	inline bool OspTree::LocalTerminationCriteriaMet(const OspTraversalData &data) const
[1237]	539	{
	540	// matt: TODO
	541	return (
	542	//(data.mNode->mObjects.size() < mTermMinObjects) \|\|
	543	//(data.mProbability <= mTermMinProbability) \|\|
	544	(data.mDepth >= mTermMaxDepth)
	545	);
	546	}
	547
	548
[1251]	549	inline bool OspTree::GlobalTerminationCriteriaMet(const OspTraversalData &data) const
[1237]	550	{
	551	// matt: TODO
[1444]	552	return (0
	553	\|\| (mOspStats.Leaves() >= mTermMaxLeaves)
	554	//\|\| mOutOfMemory
	555	\|\| (mGlobalCostMisses >= mTermGlobalCostMissTolerance)
[1237]	556	);
	557	}
	558
	559
	560	void OspTree::EvaluateLeafStats(const OspTraversalData &data)
	561	{
	562	// the node became a leaf -> evaluate stats for leafs
	563	KdLeaf *leaf = data.mNode;
	564
	565	++ mCreatedLeaves;
	566
	567	/*if (data.mPvs > mOspStats.maxPvs)
	568	{
	569	mOspStats.maxPvs = data.mPvs;
	570	}
	571
	572	mOspStats.pvs += data.mPvs;
	573
	574	if (data.mDepth < mOspStats.minDepth)
	575	{
	576	mOspStats.minDepth = data.mDepth;
	577	}*/
	578
	579	if (data.mDepth >= mTermMaxDepth)
	580	{
	581	++ mOspStats.maxDepthNodes;
	582	//Debug << "new max depth: " << mVspStats.maxDepthNodes << endl;
	583	}
	584
	585	if (data.mProbability <= mTermMinProbability)
	586	++ mOspStats.minProbabilityNodes;
	587
	588	// accumulate depth to compute average depth
	589	mOspStats.accumDepth += data.mDepth;
	590
	591	// if ((int)(leaf->mObjects.size()) < mTermMinCost)
	592	// ++ mOspStats.minCostNodes;
	593
	594	if ((int)(leaf->mObjects.size()) > mOspStats.maxObjectRefs)
	595	mOspStats.maxObjectRefs = (int)leaf->mObjects.size();
	596
[1715]	597	#ifdef GTP_DEBUG
[1237]	598	Debug << "BSP stats: "
	599	<< "Depth: " << data.mDepth << " (max: " << mTermMaxDepth << "), "
	600	<< "Prob: " << data.mProbability << " (min: " << mTermMinProbability << ")\n";
	601	#endif
	602	}
	603
	604
	605	float OspTree::EvalLocalCostHeuristics(const OspTraversalData &tData,
	606	const AxisAlignedBox3 &box,
	607	const int axis,
	608	float &position,
	609	int &objectsFront,
	610	int &objectsBack)
	611	{
	612	RayInfoContainer usedRays;
	613	int mMaxTests = 500000; // HACK
	614
	615	if (mMaxTests < (int)tData.mRays->size())
	616	{
	617	GetRayInfoSets(*tData.mRays, mMaxTests, usedRays);
	618	}
	619	else
	620	{
	621	usedRays = *tData.mRays;
	622	}
	623
	624	// go through the lists, count the number of objects left and right
	625	// and evaluate the following cost funcion:
	626	// C = ct_div_ci + (ol + or)/queries
	627
	628	const float minBox = box.Min(axis);
	629	const float maxBox = box.Max(axis);
	630	Debug << "min: " << minBox << " max: " << maxBox << endl;
	631
	632	const float sizeBox = maxBox - minBox;
	633
	634	float minBand = minBox + mSplitBorder * (maxBox - minBox);
	635	float maxBand = minBox + (1.0f - mSplitBorder) * (maxBox - minBox);
	636
	637	const float viewSpaceVol = mVspTree->GetBoundingBox().GetVolume();
	638
	639	//-- sort so we can use a sweep
	640	SortSubdivisionCandidates(tData, axis, minBand, maxBand);
	641
	642	float totalVol = 0;
	643	float voll = 0;
	644	float volr = totalVol;
	645
	646	ViewCellContainer touchedViewCells;
	647
	648	const float totalRenderCost = PrepareHeuristics(tData, touchedViewCells);
	649	float renderCost = totalRenderCost;
	650
	651	/// this is kind of a reverse pvs
	652	const int totalPvs = (int)tData.mNode->mObjects.size();
	653
	654	int pvsl = 0;
	655	int pvsr = totalPvs;
	656
	657	float sum = (float)totalVol * sizeBox;
	658
[1297]	659	Debug << "total render cost: " << renderCost / viewSpaceVol << endl;
[1237]	660
	661	/////////////////////////////////
	662
	663	// note: initialised to take mid split
	664	// if no good split can be found,
	665	position = minBox + 0.5f * sizeBox;
	666
	667	// the relative cost ratio
	668	float ratio = 99999999.0f;
	669	bool splitPlaneFound = false;
	670
	671	float volBack = voll;
	672	float volFront = volr;
	673
	674	int pvsBack = pvsl;
	675	int pvsFront = pvsr;
	676
	677	float minRenderCost = 1e20f;
	678
	679	debugVol = 0;
	680
	681
	682
	683	/////////////////////////////
	684	// the sweep heuristics
	685
	686
	687	//-- traverse through events and find best split plane
	688
	689	vector<SortableEntry>::const_iterator ci, ci_end = mSubdivisionCandidates->end();
	690	//minRenderCost = RandomValue(0,viewSpaceVol);
	691
	692	for (ci = mSubdivisionCandidates->begin(); ci != ci_end; ++ ci)
	693	{
	694	Intersectable object = (ci).mObject;
	695
	696	EvalHeuristicsContribution(tData.mNode,
	697	*ci,
	698	renderCost,
	699	touchedViewCells
	700	);
	701
	702	// Note: sufficient to compare size of bounding boxes of front and back side?
	703	if (((ci).mPos >= minBand) && ((ci).mPos <= maxBand))
	704	{
	705	float currentPos;
[1297]	706	Debug << "current min: " << minRenderCost / viewSpaceVol << endl;
[1237]	707
	708	// HACK: current positition is BETWEEN visibility events
	709	if (1 && /((ci).mType == SortableEntry::BOX_INTERSECT) &&*/ ((ci + 1) != ci_end))
	710	currentPos = ((ci).mPos + ((ci + 1)).mPos) * 0.5f;
	711	else
	712	currentPos = (*ci).mPos;
	713
	714	if (renderCost < minRenderCost)
	715	{
	716	splitPlaneFound = true;
	717	minRenderCost = renderCost;
	718	position = currentPos;
	719	Debug << "pos: " << position << endl;
	720	}
	721	}
	722	}
	723	//splitPlaneFound = true;
	724	if (splitPlaneFound)
	725	{
	726	ratio = minRenderCost / totalRenderCost;
	727	}
[1715]	728	#if GTP_DEBUG
[1237]	729	Debug << "\n§§§§ eval local cost §§§§" << endl
	730	<< "old rc: " << totalRenderCost / viewSpaceVol << " new rc: " << minRenderCost / viewSpaceVol << endl
	731	<< "render cost decrease: " << (totalRenderCost - minRenderCost) / viewSpaceVol << endl;
[1654]	732	#endif
[1237]	733	return ratio;
	734	}
	735
	736
	737	void OspTree::SortSubdivisionCandidates(const OspTraversalData &tData,
	738	const int axis,
	739	float minBand,
	740	float maxBand)
	741
	742	{
	743	mSubdivisionCandidates->clear();
	744
	745	RayInfoContainer *rays = tData.mRays;
	746	KdLeaf *leaf = tData.mNode;
	747
	748	int requestedSize = 2 * (int)rays->size() + 2 * (int)leaf->mObjects.size();
	749
	750	// creates a sorted split candidates array
	751	if (mSubdivisionCandidates->capacity() > 500000 &&
	752	requestedSize < (int)(mSubdivisionCandidates->capacity() / 10) )
	753	{
	754	delete mSubdivisionCandidates;
	755	mSubdivisionCandidates = new vector<SortableEntry>;
	756	}
	757
	758	mSubdivisionCandidates->reserve(requestedSize);
	759
	760	float pos;
	761
	762	//-- insert ray queries
	763	//-- we are intersested only in rays which intersect an object that
	764	//-- is part of the kd node because they can induce a change in view cell
	765	//-- volume on the left and the right part.
	766	//-- Note that they cannot induce a change in pvs size!!
	767
	768	RayInfoContainer::const_iterator rit, rit_end = rays->end();
	769
	770	for (rit = rays->begin(); rit < rit_end; ++ rit)
	771	{
	772	VssRay ray = (rit).mRay;
	773
	774	const bool positive = ray->HasPosDir(axis);
	775
	776	if (EndPointInsideNode(leaf, *ray, true))
	777	{
	778	pos = ray->mTermination[axis];
	779
	780	mSubdivisionCandidates->push_back(
	781	SortableEntry(SortableEntry::BOX_INTERSECT,
	782	pos,
	783	ray->mTerminationObject,
	784	ray)
	785	);
	786	}
	787
	788	// if hitpoint with object is inside this node
	789	if (EndPointInsideNode(leaf, *ray, false))
	790	{
	791	pos = ray->mOrigin[axis];
	792
	793	mSubdivisionCandidates->push_back(
	794	SortableEntry(SortableEntry::BOX_INTERSECT,
	795	pos,
	796	ray->mOriginObject,
	797	ray)
	798	);
	799	}
	800	}
	801
	802
	803	//-- insert object queries
	804	//-- These queries can induce a change in pvs size.
	805	//-- Note that they cannot induce a change in view cell volume, as
	806	//-- there is no ray associated with these events!!
	807
	808	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	809
	810	for (oit = leaf->mObjects.begin(); oit != leaf->mObjects.end(); ++ oit )
	811	{
	812	Intersectable object = oit;
	813	const AxisAlignedBox3 box = object->GetBox();
	814
	815	mSubdivisionCandidates->push_back(
	816	SortableEntry(SortableEntry::BOX_MIN,
	817	box.Min(axis),
	818	object,
	819	NULL)
	820	);
	821
	822
	823	mSubdivisionCandidates->push_back(
	824	SortableEntry(SortableEntry::BOX_MAX,
	825	box.Max(axis),
	826	object,
	827	NULL)
	828	);
	829	}
	830
	831	stable_sort(mSubdivisionCandidates->begin(), mSubdivisionCandidates->end());
	832	}
	833
	834
	835	const OspTreeStatistics &OspTree::GetStatistics() const
	836	{
	837	return mOspStats;
	838	}
	839
	840
	841	void OspTree::PrepareHeuristics(const VssRay &ray,
	842	ViewCellContainer &touchedViewCells)
	843	{
	844	// collect view cells and set mail + counter
	845	ViewCellContainer viewCells;
	846	mVspTree->GetViewCells(ray, viewCells);
	847
	848	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	849
	850	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	851	{
	852	ViewCell vc = (vit);
	853
	854	if (!vc->Mailed())
	855	{
	856	vc->Mail(); // set as belonging to front leaf
	857	vc->mCounter = 0;
	858	touchedViewCells.push_back(vc);
	859	}
	860
	861	// view cell volume already added => just increase counter
	862	++ vc->mCounter;
	863	}
	864	}
	865
	866
	867	float OspTree::PrepareHeuristics(const OspTraversalData &tData,
	868	ViewCellContainer &touchedViewCells)
	869	{
	870	float renderCost = 0;
	871
	872	Intersectable::NewMail(3);
	873	ViewCell::NewMail(3);
	874	MailablePvsData::NewMail();
	875
	876	KdLeaf *leaf = tData.mNode;
	877
	878	RayInfoContainer::const_iterator rit, rit_end = tData.mRays->end();
	879
	880	for (rit = tData.mRays->begin(); rit < rit_end; ++ rit)
	881	{
	882	VssRay ray = (rit).mRay;
	883	PrepareHeuristics(*ray, touchedViewCells);
	884	}
	885
	886	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	887
	888	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	889	{
	890	Intersectable obj = oit;
	891	obj->Mail(); // set as belonging to front leaf
	892
	893	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	894
	895	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	896	{
	897	ViewCell vc = vit;
[1736]	898	// no view cel pvs!!
	899	/MailablePvsData vdata = obj->mViewCellPvs.Find(vc);
[1237]	900
	901	if (!vdata) // should never happen
	902	continue;
	903
	904	if (!vdata->Mailed())
	905	{
	906	vdata->Mail();
	907	renderCost += vc->GetVolume();
[1736]	908	}*/
[1237]	909	}
	910	}
	911
	912	return renderCost;
	913	}
	914
	915
	916	void OspTree::AddObjectContribution(KdLeaf *leaf,
	917	Intersectable *obj,
	918	ViewCellContainer &touchedViewCells,
	919	float &renderCost)
	920	{
	921	//Debug << "add contri to obj: " << obj->mMailbox - Intersectable::sMailId << endl;
	922	obj->Mail(2); // set as belonging to both leafs
	923
	924	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	925
	926	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	927	{
	928	ViewCell vc = vit;
[1251]	929
[1237]	930	// if obj not previously associated with this view cell => increase render cost
	931	if (vc->Mailed(1) && !ViewCellHasMultipleReferences(obj, vc, false))
	932	{
	933	//Debug << "add to rendercost: " << vc->GetVolume() / mVspTree->GetBoundingBox().GetVolume() << endl;
	934	renderCost += vc->GetVolume();
	935	}
	936	}
	937	}
	938
	939
	940	void OspTree::SubtractObjectContribution(KdLeaf *leaf,
	941	Intersectable * obj,
	942	ViewCellContainer &touchedViewCells,
	943	float &renderCost)
	944	{
	945	//Debug << "subtract contri from obj: " << obj->mMailbox - Intersectable::sMailId << endl;
	946	obj->Mail(1); // set as belonging to back leaf
	947	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	948
	949	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	950	{
	951	ViewCell vc = vit;
	952
	953	// if obj was previously associated with this view cell but is not now
	954	// => decrease render cost
	955	if (vc->Mailed() && !ViewCellHasMultipleReferences(obj, vc, false))
	956	{
	957	//Debug << "subtract from rendercost: " << vc->GetVolume() / mVspTree->GetBoundingBox().GetVolume() << endl;
	958	renderCost -= vc->GetVolume();
	959	}
	960	}
	961	}
	962
	963
	964	void OspTree::EvalRayContribution(KdLeaf *leaf,
	965	const VssRay &ray,
	966	float &renderCost)
	967	{
	968	ViewCellContainer viewCells;
	969
	970	mVspTree->GetViewCells(ray, viewCells);
	971
	972	// classify view cells and compute volume contri accordingly
	973	// possible view cell classifications:
	974	// view cell mailed => view cell can be seen from left child node
	975	// view cell counter > 0 view cell can be seen from right child node
	976	// combined: view cell volume belongs to both nodes
	977	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	978
	979	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	980	{
	981	EvalViewCellContribution(leaf, *vit, renderCost);
	982	}
	983	}
	984
	985
	986	void OspTree::EvalViewCellContribution(KdLeaf *leaf,
	987	ViewCell *viewCell,
	988	float &renderCost)
	989	{
	990	//Debug << "**************" << endl;
	991	//Debug << "vc contri: " << renderCost / mVspTree->GetBoundingBox().GetVolume() << " " << viewCell->mMailbox - ViewCell::sMailId << " counter: " << viewCell->mCounter << endl;
	992
	993	const float vol = viewCell->GetVolume();
	994
	995	if (viewCell->Mailed())
	996	{
	997	viewCell->Mail(2); // view cell can be seen from both nodes
	998
	999	// we now see view cell from both nodes => add contri
	1000	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1001
	1002	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1003	{
	1004	Intersectable obj = oit;
	1005
	1006	// was render cost already added?
	1007	if (!ViewCellHasMultipleReferences(obj, viewCell, false) &&
	1008	obj->Mailed(1))
	1009	{
	1010	//Debug << "obj mail 1!! " << vol / mVspTree->GetBoundingBox().GetVolume() << endl;
	1011	renderCost += vol;
	1012	}
	1013	}
	1014	}
	1015
	1016	if (-- viewCell->mCounter == 0)
	1017	{
	1018	viewCell->Mail(1); // view cell can be seen from back node only
	1019
	1020	//MailablePvsData::NewMail();
	1021	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1022
	1023	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1024	{
	1025	Intersectable obj = oit;
	1026
	1027	// can render cost be be reduced?
	1028	if (!ViewCellHasMultipleReferences(obj, viewCell, false) && obj->Mailed())
	1029	{
	1030	renderCost -= vol;
	1031	}
	1032	}
	1033	}
	1034	//Debug << "new rc: " << renderCost / mVspTree->GetBoundingBox().GetVolume() << " counter2: " << viewCell->mCounter << endl;
	1035	//Debug << "**************"<<endl;
	1036	}
	1037
	1038
	1039	void OspTree::EvalHeuristicsContribution(KdLeaf *leaf,
	1040	const SortableEntry &ci,
	1041	float &renderCost,
	1042	ViewCellContainer &touchedViewCells)
	1043	{
	1044	Intersectable *obj = ci.mObject;
	1045	VssRay *ray = ci.mRay;
	1046
	1047	// switch between different types of events
	1048	switch (ci.mType)
	1049	{
	1050	case SortableEntry::BOX_MIN:
	1051	cout << "<";
	1052	AddObjectContribution(leaf, ci.mObject, touchedViewCells, renderCost);
	1053	break;
	1054
	1055	case SortableEntry::BOX_MAX:
	1056	cout << ">";
	1057	SubtractObjectContribution(leaf, ci.mObject, touchedViewCells, renderCost);
	1058	break;
	1059
	1060	// compute volume contribution from view cells
	1061	case SortableEntry::BOX_INTERSECT:
	1062	cout << "i";
	1063	// process ray if the hit point with termination / origin object
	1064	// is inside this kd leaf
	1065	EvalRayContribution(leaf, *ray, renderCost);
	1066	break;
	1067
	1068	default:
	1069	cout << "should not come here" << endl;
	1070	break;
	1071	}
	1072
	1073	//cout << "vol left: " << volLeft << " vol right " << volRight << endl;
	1074	}
	1075
	1076
	1077	void OspTree::SetViewCellsManager(ViewCellsManager *vcm)
	1078	{
	1079	mViewCellsManager = vcm;
	1080	}
	1081
	1082
	1083	AxisAlignedBox3 OspTree::GetBoundingBox() const
	1084	{
	1085	return mBoundingBox;
	1086	}
	1087
	1088
	1089	float OspTree::SelectSplitPlane(const OspTraversalData &tData,
[1251]	1090	AxisAlignedPlane &plane)
[1237]	1091	{
	1092	float nPosition[3];
	1093	float nCostRatio[3];
	1094
	1095	// create bounding box of node geometry
	1096	AxisAlignedBox3 box = tData.mBoundingBox;
	1097
	1098	int sAxis = 0;
	1099	int bestAxis = -1;
	1100
	1101	if (mOnlyDrivingAxis)
	1102	{
	1103	sAxis = box.Size().DrivingAxis();
	1104	}
	1105
	1106
	1107	// -- evaluate split cost for all three axis
	1108	for (int axis = 0; axis < 3; ++ axis)
	1109	{
	1110	if (!mOnlyDrivingAxis \|\| (axis == sAxis))
	1111	{
	1112	if (1 \|\| mUseCostHeuristics)
	1113	{
	1114	//-- place split plane using heuristics
	1115	int objectsFront, objectsBack;
	1116
	1117	nCostRatio[axis] =
	1118	EvalLocalCostHeuristics(tData,
	1119	tData.mBoundingBox,
	1120	axis,
	1121	nPosition[axis],
	1122	objectsFront,
	1123	objectsBack);
	1124	}
	1125	/* else
	1126	{
	1127	//-- split plane position is spatial median
	1128
	1129	nPosition[axis] = (box.Min()[axis] + box.Max()[axis]) * 0.5f;
	1130
	1131	nCostRatio[axis] = EvalLocalSplitCost(tData,
	1132	box,
	1133	axis,
	1134	nPosition[axis],
	1135	nProbFront[axis],
	1136	nProbBack[axis]);
	1137	}*/
	1138
	1139	if (bestAxis == -1)
	1140	{
	1141	bestAxis = axis;
	1142	}
	1143	else if (nCostRatio[axis] < nCostRatio[bestAxis])
	1144	{
	1145	bestAxis = axis;
	1146	}
	1147	}
	1148	}
	1149
	1150	//-- assign values
	1151
	1152	plane.mAxis = bestAxis;
	1153	// split plane position
	1154	plane.mPosition = nPosition[bestAxis];
	1155
	1156	Debug << "val: " << nCostRatio[bestAxis] << " axis: " << bestAxis << endl;
	1157	return nCostRatio[bestAxis];
	1158	}
	1159
	1160
	1161	bool OspTree::EndPointInsideNode(KdLeaf *leaf,
	1162	VssRay &ray,
	1163	bool isTermination) const
	1164	{
	1165	// test if the leaf where the hitpoint is located is the current leaf
	1166	if (isTermination)
	1167	{
	1168	return ray.mTerminationObject && (GetLeaf(ray.mTermination, ray.mTerminationNode) == leaf);
	1169	}
	1170	else
	1171	{
	1172	return false; // no origin object!
	1173	return ray.mOriginObject && (GetLeaf(ray.mOrigin, ray.mOriginNode) == leaf);
	1174	}
	1175	}
	1176
	1177
	1178	void OspTree::EvalSubdivisionStats(const SubdivisionCandidate &sc)
	1179	{
	1180	const float costDecr = sc.GetRenderCostDecrease();
	1181
	1182	AddSubdivisionStats(mOspStats.Leaves(),
	1183	costDecr,
	1184	mTotalCost
	1185	);
	1186	}
	1187
	1188
	1189	void OspTree::AddSubdivisionStats(const int leaves,
	1190	const float renderCostDecr,
	1191	const float totalRenderCost)
	1192	{
	1193	mSubdivisionStats
	1194	<< "#Leaves\n" << leaves << endl
	1195	<< "#RenderCostDecrease\n" << renderCostDecr << endl
	1196	<< "#TotalRenderCost\n" << totalRenderCost << endl;
	1197	//<< "#AvgRenderCost\n" << avgRenderCost << endl;
	1198	}
	1199
	1200
	1201	int OspTree::ClassifyRay(VssRay *ray,
	1202	KdLeaf *leaf,
	1203	const AxisAlignedPlane &plane) const
	1204	{
	1205	const bool originInside = EndPointInsideNode(leaf, *ray, false);
	1206	const bool terminationInside = EndPointInsideNode(leaf, *ray, true);
	1207
	1208	const bool originGt = (ray->mOrigin[plane.mAxis] >= plane.mPosition);
	1209	const bool originLt = (ray->mOrigin[plane.mAxis] <= plane.mPosition);
	1210
	1211	const bool terminationGt = (ray->mTermination[plane.mAxis] >= plane.mPosition);
	1212	const bool terminationLt = (ray->mTermination[plane.mAxis] <= plane.mPosition);
	1213
	1214	// add view cell volume to front volume
	1215	const bool addToFront =
	1216	((originInside && originGt) \|\| (terminationInside && terminationGt));
	1217
	1218	// add view cell volume to back volume
	1219	const bool addToBack =
	1220	((originInside && originLt/!originGt/) \|\| (terminationInside && terminationLt/terminationGt/));
	1221
	1222	// classify ray with respect to the child nodes the view cells contribute
	1223	if (addToFront && addToBack)
	1224	return 0;
	1225	else if (addToBack)
	1226	return -1;
	1227	else if (addToFront)
	1228	return 1;
	1229
	1230	return -2;
	1231	}
	1232
	1233
	1234	int OspTree::ClassifyRays(const RayInfoContainer &rays,
	1235	KdLeaf *leaf,
	1236	const AxisAlignedPlane &plane,
	1237	RayInfoContainer &frontRays,
	1238	RayInfoContainer &backRays) const
	1239	{
	1240	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	1241
	1242	for (rit = rays.begin(); rit < rit_end; ++ rit)
	1243	{
	1244	VssRay ray = (rit).mRay;
	1245
	1246	bool originGt = false;
	1247	bool terminationGt = false;
	1248
	1249	Intersectable *obj = ray->mOriginObject;
	1250
	1251	if (0 && obj)
	1252	{
	1253	originGt = ray->mOrigin[plane.mAxis] >= plane.mPosition;
	1254	}
	1255
	1256	obj = ray->mTerminationObject;
	1257
	1258	if (obj)
	1259	{
	1260	terminationGt = ray->mTermination[plane.mAxis] >= plane.mPosition;
	1261	}
	1262
	1263	// either begin or end point on front side
	1264	const bool addToFront = originGt \|\| terminationGt;
	1265
	1266	// add view cell volume to back volume
	1267	const bool addToBack = !originGt \|\| !terminationGt;
	1268
	1269	// classify ray with respect to the child nodes the view cells contribute
	1270	if (addToFront)
	1271	frontRays.push_back(*rit);
	1272	if (addToBack)
	1273	backRays.push_back(*rit);
	1274	}
	1275
	1276	return 0;
	1277	}
	1278
	1279
	1280	float OspTree::EvalRenderCostDecrease(const AxisAlignedPlane &candidatePlane,
	1281	const OspTraversalData &tData,
	1282	float &normalizedOldRenderCost) const
	1283	{
	1284	float pvsFront = 0;
	1285	float pvsBack = 0;
	1286
	1287	// probability that view point lies in back / front node
[1291]	1288	float pOverall = 0;
[1237]	1289	float pFront = 0;
	1290	float pBack = 0;
	1291	float pFrontAndBack = 0;
	1292
	1293	Intersectable::NewMail(3);
	1294	KdLeaf *leaf = tData.mNode;
	1295
	1296	const float viewSpaceVol = mVspTree->GetBoundingBox().GetVolume();
	1297	const int totalPvs = (int)leaf->mObjects.size();
	1298
	1299	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1300
	1301	// evaluate reverse pvs and view cell volume on left and right cell
	1302	// note: should I take all leaf objects or rather the objects hit by rays?
	1303	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1304	{
	1305	int pvsContri = 0;
	1306
	1307	Intersectable obj = oit;
	1308	const AxisAlignedBox3 box = obj->GetBox();
	1309
	1310	// test if box falls in left / right child node
	1311	if (box.Max(candidatePlane.mAxis) >= candidatePlane.mPosition)
	1312	{
	1313	++ pvsFront;
	1314	obj->Mail();
	1315	}
	1316
	1317	if (box.Min(candidatePlane.mAxis) < candidatePlane.mPosition)
	1318	{
	1319	++ pvsBack;
	1320
	1321	if (obj->Mailed())
	1322	obj->Mail(2);
	1323	else
	1324	obj->Mail(1);
	1325	}
	1326	}
	1327
	1328	ViewCellContainer touchedViewCells;
	1329
	1330	// sum up volume seen from the objects of left and right children
	1331	// => the volume is the weight for the render cost equation
	1332	ViewCell::NewMail(3);
	1333
	1334	RayInfoContainer::const_iterator rit, rit_end = tData.mRays->end();
	1335	//map<Intersectable *, ViewCellContainer> objectsMap;
	1336
	1337	for (rit = tData.mRays->begin(); rit < rit_end; ++ rit)
	1338	{
	1339	VssRay ray = (rit).mRay;
	1340
	1341	// add volume to volumes of left and / or right children
	1342	// if one of the ray end points is inside
	1343	const int classification = ClassifyRay(ray, leaf, candidatePlane);
	1344
	1345	ViewCellContainer viewCells;
	1346	mVspTree->GetViewCells(*ray, viewCells);
	1347
	1348	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	1349
	1350	// traverse through view cells and classify them according
	1351	// to them being seen from to back / front / front and back node
	1352	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	1353	{
	1354	ViewCell vc = vit;
	1355
	1356	// if not previously mailed
	1357	if (!vc->Mailed() && !vc->Mailed(1) && !vc->Mailed(2))
	1358	{
	1359	touchedViewCells.push_back(vc);
	1360	}
	1361
	1362	// classify / mail the view cell
	1363	MailViewCell(vc, classification);
	1364	}
	1365	}
	1366
	1367	// evaluate view cells volume contribution
	1368	// with respect to the mail box classification
	1369	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	1370
	1371	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	1372	{
	1373	AddViewCellVolumeContri(*vit, pFront, pBack, pFrontAndBack);
	1374	}
	1375
	1376	//////////////////////////////////////////////
	1377	//
	1378	// evaluate contribution of objects which are part of other kd nodes
	1379	// which are seen by the same view cell
	1380	// These contributions cannot be reduced by splitting, because
	1381	// the object would still be part of the pvs
	1382
	1383	float newRc = 0;
	1384	float rc = 0;
	1385
	1386	MailablePvsData::NewMail();
	1387	//ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1388
	1389	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1390	{
	1391	Intersectable obj = oit;
	1392	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	1393
	1394	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	1395	{
	1396	ViewCell vc = vit;
[1736]	1397	// no more view cell pvs!!
	1398	/MailablePvsData vdata = obj->mViewCellPvs.Find(vc);
[1237]	1399	if (!vdata)
	1400	{
[1528]	1401	Debug << "error! should not come here" << endl;
[1237]	1402	continue;
	1403	}
	1404
	1405	if (!vdata->Mailed())
	1406	{
	1407	vdata->Mail();
	1408	rc += vc->GetVolume();
	1409
	1410	if ((vdata->mSumPdf > 1.5) \|\|
	1411	vc->Mailed(2) \|\|
	1412	obj->Mailed(2) \|\|
	1413	(obj->Mailed() && vc->Mailed()) \|\|
	1414	(obj->Mailed(1) && vc->Mailed(1))
	1415	)
	1416	{
	1417	newRc += vc->GetVolume();
	1418	}
[1736]	1419	}*/
[1237]	1420	}
	1421	}
	1422
	1423
	1424	/////////////////////////////
	1425	//-- pvs rendering heuristics
	1426
[1291]	1427	const float oldRenderCost = rc;
[1237]	1428
	1429	// sum up the terms:
	1430	// the view cells seeing
	1431	// a) the left node are weighted by the #left node objects
	1432	// b) the right node are weighted by the #right node objects
	1433	// c) both nodes are weighted by the #parent node objects
[1291]	1434	const float newRenderCost = newRc;
[1237]	1435
[1291]	1436
[1237]	1437	// normalize volume with view space volume
	1438	const float renderCostDecrease = (oldRenderCost - newRenderCost) / viewSpaceVol;
	1439
[1291]	1440	Debug << "\nrender cost decrease: " << endl
[1237]	1441	<< "old rc: " << oldRenderCost / viewSpaceVol << " new rc: " << newRenderCost / viewSpaceVol << endl
	1442	<< "render cost decrease: " << renderCostDecrease << endl;
	1443
	1444	normalizedOldRenderCost = oldRenderCost / viewSpaceVol;
	1445
	1446
	1447	return renderCostDecrease;
	1448	}
	1449
	1450
[1287]	1451	void OspTree::ComputeBoundingBox(const ObjectContainer &objects)
[1237]	1452	{
[1287]	1453	mBoundingBox.Initialize();
[1237]	1454
[1287]	1455	ObjectContainer::const_iterator oit, oit_end = objects.end();
[1237]	1456
[1287]	1457	//-- compute bounding box
	1458	for (oit = objects.begin(); oit != oit_end; ++ oit)
	1459	{
	1460	Intersectable obj = oit;
[1237]	1461
[1287]	1462	// compute bounding box of view space
	1463	mBoundingBox.Include(obj->GetBox());
[1237]	1464	}
	1465	}
	1466
	1467
	1468	void OspTree::ProcessMultipleRefs(KdLeaf *leaf) const
	1469	{
	1470	// find objects from multiple kd-leaves
	1471	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1472
	1473	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1474	{
	1475	Intersectable object = oit;
	1476
[1736]	1477	// matt: no more ref
	1478	/*if (object->mReferences > 1)
[1237]	1479	{
	1480	leaf->mMultipleObjects.push_back(object);
[1736]	1481	}*/
[1237]	1482	}
	1483	}
	1484
	1485
	1486	void OspTree::CollectLeaves(vector<KdLeaf *> &leaves) const
	1487	{
	1488	stack<KdNode *> nodeStack;
	1489	nodeStack.push(mRoot);
	1490
	1491	while (!nodeStack.empty())
	1492	{
	1493	KdNode *node = nodeStack.top();
	1494	nodeStack.pop();
	1495	if (node->IsLeaf())
	1496	{
	1497	KdLeaf leaf = (KdLeaf )node;
	1498	leaves.push_back(leaf);
	1499	}
	1500	else
	1501	{
	1502	KdInterior interior = (KdInterior )node;
	1503	nodeStack.push(interior->mBack);
	1504	nodeStack.push(interior->mFront);
	1505	}
	1506	}
	1507	}
	1508
	1509
	1510	AxisAlignedBox3 OspTree::GetBoundingBox(KdNode *node) const
	1511	{
	1512	if (!node->mParent)
	1513	return mBoundingBox;
	1514
	1515	if (!node->IsLeaf())
	1516	{
[2017]	1517	return (static_cast<KdInterior *>(node))->mBox;
[1237]	1518	}
	1519
[2017]	1520	KdInterior parent = static_cast<KdInterior >(node->mParent);
[1237]	1521
	1522	AxisAlignedBox3 box(parent->mBox);
	1523
	1524	if (parent->mFront == node)
	1525	box.SetMin(parent->mAxis, parent->mPosition);
	1526	else
	1527	box.SetMax(parent->mAxis, parent->mPosition);
	1528
	1529	return box;
	1530	}
	1531
	1532
	1533	void OspTree::CollectViewCells(KdLeaf *leaf, ViewCellContainer &viewCells)
	1534	{
	1535	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	1536
	1537	ViewCell::NewMail();
	1538
	1539	// loop through all object and collect view cell pvs of this node
	1540	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	1541	{
	1542	Intersectable obj = oit;
[1736]	1543	// no more view cell pvs!!
	1544	/*ViewCellPvsMap::const_iterator vit, vit_end = obj->mViewCellPvs.mEntries.end();
[1237]	1545
	1546	for (vit = obj->mViewCellPvs.mEntries.begin(); vit != vit_end; ++ vit)
	1547	{
	1548	ViewCell vc = (vit).first;
	1549
	1550	if (!vc->Mailed())
	1551	{
	1552	vc->Mail();
	1553	viewCells.push_back(vc);
	1554	}
[1736]	1555	}*/
[1237]	1556	}
	1557	}
	1558
	1559
	1560	void OspTree::CollectDirtyCandidates(OspSubdivisionCandidate *sc,
[1633]	1561	vector<SubdivisionCandidate *> &dirtyList,
	1562	const bool onlyUnmailed)
[1237]	1563	{
	1564	OspTraversalData &tData = sc->mParentData;
	1565	KdLeaf *node = tData.mNode;
	1566
	1567	ViewCell::NewMail();
	1568	ViewCellContainer viewCells;
	1569	ViewCellContainer tmpViewCells;
	1570
	1571	RayInfoContainer::const_iterator rit, rit_end = tData.mRays->end();
	1572
	1573	// find all view cells associated with the rays, add them to view cells
	1574	for (rit = tData.mRays->begin(); rit != rit_end; ++ rit)
	1575	{
	1576	VssRay ray = (rit).mRay;
	1577	mVspTree->GetViewCells(*ray, tmpViewCells);
	1578
	1579	ViewCellContainer::const_iterator vit, vit_end = tmpViewCells.end();
	1580
	1581	for (vit = tmpViewCells.begin(); vit != vit_end; ++ vit)
	1582	{
[2017]	1583	VspViewCell vc = static_cast<VspViewCell >(*vit);
[1237]	1584
	1585	if (!vc->Mailed())
	1586	{
	1587	vc->Mail();
	1588	viewCells.push_back(vc);
	1589	}
	1590	}
	1591	}
	1592
[2542]	1593	// candidates that contain this view cells are thrown into dirty list
[1237]	1594	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	1595
	1596	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	1597	{
[2017]	1598	VspViewCell vc = static_cast<VspViewCell >(*vit);
[1237]	1599
[1551]	1600	VspLeaf *leaf = vc->mLeaves[0];
[1633]	1601
	1602	SubdivisionCandidate *dsc = leaf->GetSubdivisionCandidate();
	1603	if (dsc && (!onlyUnmailed \|\| !dsc->Mailed()))
	1604	{
	1605	dsc->Mail();
	1606	dirtyList.push_back(dsc);
	1607	}
[1237]	1608	}
	1609	}
	1610
	1611
	1612	KdNode *OspTree::GetRoot() const
	1613	{
	1614	return mRoot;
	1615	}
	1616
	1617
	1618	KdLeaf OspTree::GetLeaf(const Vector3 &pt, KdNode node) const
	1619	{
	1620	// start from root of tree
	1621	if (node == NULL)
	1622	{
	1623	node = mRoot;
	1624	}
	1625
	1626	stack<KdNode *> nodeStack;
	1627	nodeStack.push(node);
	1628
	1629	KdLeaf *leaf = NULL;
	1630
	1631	while (!nodeStack.empty())
	1632	{
	1633	KdNode *node = nodeStack.top();
	1634	nodeStack.pop();
	1635
	1636	if (node->IsLeaf())
	1637	{
[2017]	1638	leaf = static_cast<KdLeaf *>(node);
[1237]	1639	}
	1640	else
	1641	{
	1642	// find point
[2017]	1643	KdInterior interior = static_cast<KdInterior >(node);
[1237]	1644
	1645	if (interior->mPosition > pt[interior->mAxis])
	1646	{
	1647	nodeStack.push(interior->mBack);
	1648	}
	1649	else
	1650	{
	1651	nodeStack.push(interior->mFront);
	1652	}
	1653	}
	1654	}
	1655
	1656	return leaf;
	1657	}
	1658
	1659
	1660	void OspTree::PreprocessRays(KdLeaf *root,
	1661	const VssRayContainer &sampleRays,
	1662	RayInfoContainer &rays)
	1663	{
	1664	VssRayContainer::const_iterator rit, rit_end = sampleRays.end();
	1665	RayInfoContainer clippedRays;
	1666
	1667	long startTime = GetTime();
	1668
	1669	cout << "storing rays ... ";
	1670
	1671	Intersectable::NewMail();
	1672
	1673	//-- store rays and objects
	1674	for (rit = sampleRays.begin(); rit != rit_end; ++ rit)
	1675	{
	1676	VssRay ray = rit;
	1677
	1678	float minT, maxT;
	1679	static Ray hray;
	1680
	1681	hray.Init(*ray);
	1682
	1683	// TODO: not very efficient to implictly cast between rays types
	1684	if (GetBoundingBox().GetRaySegment(hray, minT, maxT))
	1685	{
	1686	float len = ray->Length();
	1687	if (!len)
	1688	len = Limits::Small;
	1689
	1690	clippedRays.push_back(RayInfo(ray, minT / len, maxT / len));
	1691
	1692	// HACK: reset nodes for the case we have used object kd tree for
	1693	// tree building.
	1694	ray->mOriginNode = NULL;
	1695	ray->mTerminationNode = NULL;
	1696	}
	1697	}
	1698
	1699	FilterRays(root, clippedRays, rays);
	1700
	1701	cout << "finished in " << TimeDiff(startTime, GetTime()) * 1e-3 << " secs" << endl;
	1702	}
	1703
	1704
	1705
	1706	int OspTree::SplitRays(const AxisAlignedPlane &plane,
	1707	RayInfoContainer &rays,
	1708	RayInfoContainer &frontRays,
	1709	RayInfoContainer &backRays) const
	1710	{
	1711	int splits = 0;
	1712
	1713	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	1714
	1715	for (rit = rays.begin(); rit != rit_end; ++ rit)
	1716	{
	1717	RayInfo bRay = *rit;
	1718
	1719	VssRay *ray = bRay.mRay;
	1720	float t;
	1721
	1722	// get classification and receive new t
	1723	//-- test if start point behind or in front of plane
	1724	const int side = bRay.ComputeRayIntersection(plane.mAxis, plane.mPosition, t);
	1725
	1726	if (side == 0)
	1727	{
	1728	++ splits;
	1729
	1730	if (ray->HasPosDir(plane.mAxis))
	1731	{
	1732	backRays.push_back(RayInfo(ray, bRay.GetMinT(), t));
	1733	frontRays.push_back(RayInfo(ray, t, bRay.GetMaxT()));
	1734	}
	1735	else
	1736	{
	1737	frontRays.push_back(RayInfo(ray, bRay.GetMinT(), t));
	1738	backRays.push_back(RayInfo(ray, t, bRay.GetMaxT()));
	1739	}
	1740	}
	1741	else if (side == 1)
	1742	{
	1743	frontRays.push_back(bRay);
	1744	}
	1745	else
	1746	{
	1747	backRays.push_back(bRay);
	1748	}
	1749	}
	1750
	1751	return splits;
	1752	}
	1753
	1754
	1755	int OspTree::FilterRays(KdLeaf *leaf,
	1756	const RayInfoContainer &rays,
	1757	RayInfoContainer &filteredRays)
	1758	{
	1759	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	1760
	1761	for (rit = rays.begin(); rit != rit_end; ++ rit)
	1762	{
	1763	VssRay ray = (rit).mRay;
	1764
	1765	// test if intersection point with one of the objects is inside this node
	1766	const bool originInside = EndPointInsideNode(leaf, *ray, false);
	1767	const bool terminationInside = EndPointInsideNode(leaf, *ray, true);
	1768
	1769	if (originInside \|\| terminationInside)
	1770	{
	1771	filteredRays.push_back(ray);
	1772	}
	1773	}
	1774
	1775	return 0;
	1776	}
	1777
	1778
	1779	int OspTree::CheckViewCellsPvs(KdLeaf *leaf,
	1780	const RayInfoContainer &rays) const
	1781	{
	1782	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	1783
	1784	Intersectable::NewMail();
	1785	ObjectContainer touchedObjects;
	1786
	1787
	1788	for (rit = rays.begin(); rit < rit_end; ++ rit)
	1789	{
	1790	VssRay ray = (rit).mRay;
	1791
	1792	if (ray->mTerminationObject)
	1793	{
	1794	Intersectable *obj = ray->mTerminationObject;
	1795
	1796	if (!obj->Mailed())
	1797	{
	1798	obj->Mail();
	1799	touchedObjects.push_back(obj);
	1800	}
	1801	}
	1802
	1803	if (ray->mOriginObject)
	1804	{
	1805	Intersectable *obj = ray->mOriginObject;
	1806
	1807	if (!obj->Mailed())
	1808	{
	1809	obj->Mail();
	1810	touchedObjects.push_back(obj);
	1811	}
	1812	}
	1813	}
[1297]	1814	Debug << "touched view cells: " << (int)touchedObjects.size() << endl;
[1237]	1815	ObjectContainer::const_iterator it, it_end = touchedObjects.end();
	1816	for (it = touchedObjects.begin(); it != it_end; ++ it)
	1817	{
[1736]	1818	// no more view cell pvs!!
	1819	/Debug << "\nobj: " << (it) << " vc pvs size: " << (*it)->mViewCellPvs.GetSize() << endl << endl;
[1237]	1820	ViewCellPvsMap::const_iterator mit, mit_end = (*it)->mViewCellPvs.mEntries.end();
	1821
	1822	for (mit = (*it)->mViewCellPvs.mEntries.begin(); mit != mit_end; ++ mit)
	1823	{
[1297]	1824	Debug << "new sumpdf: " << (*mit).second.mSumPdf << endl;
[1736]	1825	}*/
[1237]	1826	}
	1827
	1828	return 0;
	1829	}
	1830
	1831
	1832	KdIntersectable OspTree::GetOrCreateKdIntersectable(KdNode node)
	1833	{
[1615]	1834	//if (!node) return NULL;
	1835
[1237]	1836	// search nodes
[1615]	1837	std::map<KdNode , KdIntersectable >::const_iterator it = mKdIntersectables.find(node);
[1237]	1838
	1839	if (it != mKdIntersectables.end())
	1840	{
	1841	return (*it).second;
	1842	}
	1843
	1844	// not in map => create new entry
[1694]	1845	KdIntersectable *kdObj = new KdIntersectable(node, GetBoundingBox(node));
[1237]	1846	mKdIntersectables[node] = kdObj;
	1847
	1848	return kdObj;
	1849	}
	1850
	1851
	1852	/*
	1853	void OspTree::AddViewCellVolume(ViewCell *vc,
	1854	const int cf,
	1855	float &frontVol,
	1856	float &backVol,
	1857	float &totalVol) const
	1858	{
	1859	//const float renderCost = mViewCellsManager->SimpleRay &raynderCost(obj);
	1860	const float vol = vc->GetVolume();
	1861
	1862	// view cell not found yet => new
	1863	if (!vc->Mailed() && !vc->Mailed(1) && !vc->Mailed(2))
	1864	{
	1865	totalVol += vol;
	1866	}
	1867
	1868	if (cf >= 0) // front volume
	1869	{
	1870	if (!vc->Mailed() && !vc->Mailed(2))
	1871	{
	1872	frontVol += vol;
	1873
	1874	// already in back volume => in both volumes
	1875	if (vc->Mailed(1))
	1876	vc->Mail(2);
	1877	else
	1878	vc->Mail();
	1879	}
	1880	}
	1881
	1882	if (cf <= 0) // back volume
	1883	{
	1884	if (!vc->Mailed(1) && !vc->Mailed(2))
	1885	{
	1886	backVol += vol;
	1887
	1888	// already in front volume => in both volume
	1889	if (vc->Mailed())
	1890	vc->Mail(2);
	1891	else
	1892	vc->Mail(1);
	1893	}
	1894	}
	1895	}
	1896	*/
	1897
	1898
	1899	void OspTree::MailViewCell(ViewCell *vc, const int cf) const
	1900	{
	1901	if (vc->Mailed(2)) // already classified
	1902	return;
	1903
	1904	if (cf >= 0) // front volume
	1905	{
	1906	// already in back volume => in both volumes
	1907	if (vc->Mailed(1))
	1908	{
	1909	vc->Mail(2);
	1910	}
	1911	else
	1912	{
	1913	vc->Mail();
	1914	}
	1915	}
	1916
	1917	if (cf <= 0) // back volume
	1918	{
	1919	// already in front volume => in both volume
	1920	if (vc->Mailed())
	1921	{
	1922	vc->Mail(2);
	1923	}
	1924	else
	1925	{
	1926	vc->Mail(1);
	1927	}
	1928	}
	1929	}
	1930
	1931
	1932	void OspTree::AddViewCellVolumeContri(ViewCell *vc,
	1933	float &frontVol,
	1934	float &backVol,
	1935	float &frontAndBackVol) const
	1936	{
	1937	if (vc->Mailed())
	1938	{
	1939	frontVol += vc->GetVolume();
	1940	}
	1941	else if (vc->Mailed(1))
	1942	{
	1943	backVol += vc->GetVolume();
	1944	}
	1945	else if (vc->Mailed(2))
	1946	{
	1947	frontAndBackVol += vc->GetVolume();
	1948	}
	1949	}
	1950
	1951
	1952	float OspTree::EvalViewCellsVolume(KdLeaf *leaf,
	1953	const RayInfoContainer &rays) const
	1954	{
	1955	float vol = 0;
	1956	ViewCell::NewMail();
	1957
	1958	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	1959
	1960	for (rit = rays.begin(); rit != rays.end(); ++ rit)
	1961	{
	1962	VssRay ray = (rit).mRay;
	1963
	1964	ViewCellContainer viewCells;
	1965	mVspTree->GetViewCells(*ray, viewCells);
	1966
	1967	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	1968
	1969	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	1970	{
	1971	ViewCell vc = vit;
	1972
	1973	if (!vc->Mailed())
	1974	{
	1975	vc->Mail();
	1976	vol += vc->GetVolume();
	1977	}
	1978	}
	1979	}
	1980
	1981	return vol;
	1982	}
	1983
	1984
	1985	bool OspTree::AddViewCellToObjectPvs(Intersectable *obj,
	1986	ViewCell *vc,
	1987	float &contribution,
[1633]	1988	bool onlyUnmailed) const
[1237]	1989	{
	1990	contribution = 0; // todo
[1736]	1991
	1992	// no more view cell pvs!!
	1993	/MailablePvsData vdata = obj->mViewCellPvs.Find(vc);
[1237]	1994	if (!vdata)
	1995	{
	1996	vdata = obj->mViewCellPvs.AddSample2(vc, 1);
	1997	}
[1633]	1998	else if (!onlyUnmailed \|\| !vdata->Mailed())
[1237]	1999	{
	2000	obj->mViewCellPvs.AddSample(vc, 1);
	2001	}
[1736]	2002
[1237]	2003	vdata->Mail();
[1736]	2004	*/
[1237]	2005
	2006	return true;
	2007	}
	2008
	2009
	2010	void OspTree::CollectTouchedViewCells(const RayInfoContainer &rays,
	2011	ViewCellContainer &touchedViewCells) const
	2012	{
	2013	ViewCell::NewMail();
	2014
	2015	RayInfoContainer::const_iterator rit, rit_end = rays.end();
	2016
	2017	for (rit = rays.begin(); rit != rit_end; ++ rit)
	2018	{
	2019	VssRay ray = (rit).mRay;
	2020
	2021	ViewCellContainer viewCells;
	2022	mVspTree->GetViewCells(*ray, viewCells);
	2023
	2024	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	2025
	2026	// traverse through view cells and classify them according
	2027	// to them being seen from to back / front / front and back node
	2028	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	2029	{
	2030	ViewCell vc = vit;
	2031	if (!vc->Mailed())
	2032	{
	2033	vc->Mail();
	2034	touchedViewCells.push_back(vc);
	2035	}
	2036	}
	2037	}
	2038	}
	2039
	2040
	2041	int OspTree::UpdateViewCellsPvs(KdLeaf *leaf,
	2042	const RayInfoContainer &rays) const
	2043
	2044	{
	2045	MailablePvsData::NewMail();
	2046
	2047	ViewCellContainer touchedViewCells;
	2048	CollectTouchedViewCells(rays, touchedViewCells);
	2049
	2050	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	2051
	2052	for (oit = leaf->mObjects.begin(); oit < oit_end; ++ oit)
	2053	{
	2054	Intersectable obj = oit;
	2055	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	2056
	2057	// traverse through view cells and classify them according
	2058	// to them being seen from to back / front / front and back node
	2059	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	2060	{
	2061	ViewCell vc = vit;
	2062	float contri;
	2063	AddViewCellToObjectPvs(obj, vc, contri, true);
	2064	}
	2065	}
	2066
	2067	return 0;
	2068	}
	2069
	2070
	2071	int OspTree::RemoveParentViewCellsPvs(KdLeaf *leaf,
	2072	const RayInfoContainer &rays
	2073	) const
	2074
	2075	{
	2076	MailablePvsData::NewMail();
	2077
	2078	ViewCellContainer touchedViewCells;
	2079	CollectTouchedViewCells(rays, touchedViewCells);
	2080
	2081	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	2082
	2083	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	2084	{
	2085	Intersectable obj = oit;
	2086
	2087	// traverse through view cells and classify them according
	2088	// to them being seen from to back / front / front and back node
	2089	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	2090
	2091	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	2092	{
	2093	ViewCell vc = vit;
	2094
[1736]	2095	/MailablePvsData vdata = obj->mViewCellPvs.Find(vc);
[1237]	2096
	2097	if (vdata && !vdata->Mailed())
	2098	{
	2099	vdata->Mail();
	2100	obj->mViewCellPvs.RemoveSample(vc, 1);
[1736]	2101	}*/
[1237]	2102	}
	2103	}
	2104
	2105	return 0;
	2106	}
	2107
	2108
	2109	float OspTree::EvalRenderCost(const VssRayContainer &myrays)
	2110	{
	2111	float rc = 0;
	2112	float prop = mVspTree->GetBoundingBox().GetVolume();
	2113
	2114	KdLeafContainer leaves;
	2115	CollectLeaves(leaves);
	2116
	2117	ViewCellContainer vcleaves;
	2118	mVspTree->CollectViewCells(vcleaves, false);
	2119
	2120
	2121	ViewCellContainer::const_iterator vit, vit_end = vcleaves.end();
	2122
	2123	for (vit = vcleaves.begin(); vit != vit_end; ++ vit)
	2124	{
	2125	ViewCell vc = vit;
	2126	vc->GetPvs().Clear();
	2127	}
	2128
	2129	KdLeafContainer::const_iterator kit, kit_end = leaves.end();
	2130
	2131	MailablePvsData::NewMail();
	2132
	2133	for (kit = leaves.begin(); kit != kit_end; ++ kit)
	2134	{
	2135	KdLeaf leaf = kit;
	2136	float newCost = 0;
	2137	float vol = 0;
	2138
	2139	ViewCell::NewMail();
	2140	VssRayContainer::const_iterator rit, rit_end = leaf->mVssRays.end();
	2141	ViewCellContainer touchedViewCells;
	2142
	2143	for (rit = leaf->mVssRays.begin(); rit != rit_end; ++ rit)
	2144	{
	2145	VssRay ray = rit;
	2146
	2147	// test if intersection point with one of the objects is inside this node
	2148	const bool originInside = EndPointInsideNode(leaf, *ray, false);
	2149	const bool terminationInside = EndPointInsideNode(leaf, *ray, true);
	2150
	2151	if (originInside \|\| terminationInside)
	2152	{
	2153	ViewCellContainer viewCells;
	2154	mVspTree->GetViewCells(*ray, viewCells);
	2155
	2156	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	2157
	2158	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	2159	{
	2160	ViewCell vc = vit;
	2161
	2162	// if not previously mailed
	2163	if (!vc->Mailed())
	2164	{
	2165	vc->Mail();
	2166	touchedViewCells.push_back(vc);
	2167	}
	2168
	2169	}
	2170	}
	2171	}
	2172
	2173	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	2174
	2175	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	2176	{
	2177	Intersectable obj = oit;
	2178	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	2179
	2180	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	2181	{
	2182	ViewCell vc = vit;
[1740]	2183	/PvsData vdata = vc->GetPvs().Find(obj);
[1237]	2184
	2185	if (!vdata)
	2186	{
	2187	vc->GetPvs().AddSample(obj, 1);
	2188	newCost += vc->GetVolume();
	2189	}
	2190
[1740]	2191	MailablePvsData *vdata = obj->mViewCellPvs.Find(vc);
[1237]	2192
	2193	if (!vdata \|\| !vdata->Mailed())
	2194	{
	2195	newCost += vc->GetVolume();
	2196	if (!vdata)
	2197	vdata = obj->mViewCellPvs.AddSample2(vc, 1);
	2198	vdata->Mail();
	2199	}*/
	2200	}
	2201	}
	2202
	2203	rc += newCost;
	2204	}
	2205
	2206	return rc / prop;
	2207	}
	2208
	2209
	2210	float OspTree::EvalLeafCost(const OspTraversalData &tData)
	2211	{
	2212	KdLeaf *leaf = tData.mNode;
	2213
	2214	float rc = 0;
	2215	//float prop = mVspTree->GetBoundingBox().GetVolume();
	2216	//float vol = 0;
	2217	//ViewCell::NewMail();
	2218
	2219	RayInfoContainer::const_iterator rit, rit_end = tData.mRays->end();
	2220	ViewCellContainer touchedViewCells;
	2221
	2222	for (rit = tData.mRays->begin(); rit != rit_end; ++ rit)
	2223	{
	2224	VssRay ray = (rit).mRay;
	2225
	2226	// test if intersection point with one of the objects is inside this node
	2227
	2228	ViewCellContainer viewCells;
	2229	mVspTree->GetViewCells(*ray, viewCells);
	2230
	2231	ViewCellContainer::const_iterator vit, vit_end = viewCells.end();
	2232
	2233	for (vit = viewCells.begin(); vit != vit_end; ++ vit)
	2234	{
	2235	ViewCell vc = vit;
	2236
	2237	// if not previously mailed
	2238	if (!vc->Mailed())
	2239	{
	2240	vc->Mail();
	2241	touchedViewCells.push_back(vc);
	2242	}
	2243	}
	2244	}
	2245
	2246	// clear pvs of involved view cells
	2247	ViewCellContainer::const_iterator vit, vit_end = touchedViewCells.end();
	2248
	2249	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	2250	{
	2251	ViewCell vc = vit;
	2252	vc->GetPvs().Clear();
	2253	}
	2254
	2255	ObjectContainer::const_iterator oit, oit_end = leaf->mObjects.end();
	2256
	2257	for (oit = leaf->mObjects.begin(); oit != oit_end; ++ oit)
	2258	{
	2259	Intersectable obj = oit;
	2260
	2261	for (vit = touchedViewCells.begin(); vit != vit_end; ++ vit)
	2262	{
	2263	ViewCell vc = vit;
[1740]	2264	/PvsData vdata = vc->GetPvs().Find(obj);
[1237]	2265
	2266	if (!vdata)
	2267	{
	2268	vc->GetPvs().AddSample(obj, 1);
	2269	rc += vc->GetVolume();
	2270	}
[1740]	2271	*/
[1237]	2272	}
	2273	}
	2274
	2275	return rc;
	2276	}
	2277
	2278
	2279	bool OspTree::Export(OUT_STREAM &stream)
	2280	{
	2281	ExportNode(mRoot, stream);
	2282
	2283	return true;
	2284	}
	2285
	2286
	2287	void OspTree::ExportNode(KdNode *node, OUT_STREAM &stream)
	2288	{
	2289	if (node->IsLeaf())
	2290	{
[2017]	2291	KdLeaf leaf = static_cast<KdLeaf >(node);
[1237]	2292
	2293	stream << "<Leaf ";
	2294	stream << "objects=\"";
	2295
[1286]	2296	// export objects in kd leaves
[1237]	2297	//if (mExportObjects) ExportObjects(leaf, stream);
	2298
	2299	stream << "\" />" << endl;
	2300	}
	2301	else
	2302	{
[2017]	2303	KdInterior interior = static_cast<KdInterior >(node);
[1237]	2304
	2305	stream << "<Interior plane=\"" << interior->mPosition << " "
	2306	<< interior->mAxis << "\">" << endl;
	2307
	2308	ExportNode(interior->mBack, stream);
	2309	ExportNode(interior->mFront, stream);
	2310
	2311	stream << "</Interior>" << endl;
	2312	}
	2313	}
	2314
	2315
	2316	struct KdObjectsTraversalData
	2317	{
	2318	KdNode *node;
	2319	ObjectContainer *objects;
	2320	};
	2321
	2322
	2323	void OspTree::InsertObjects(KdNode *node, const ObjectContainer &objects)
	2324	{
	2325	stack<KdObjectsTraversalData> tStack;
	2326
	2327	while (!tStack.empty())
	2328	{
	2329	KdObjectsTraversalData tData = tStack.top();
	2330	tStack.pop();
	2331
	2332	KdNode *node = tData.node;
	2333
	2334	if (node->IsLeaf())
	2335	{
[2017]	2336	KdLeaf leaf = static_cast<KdLeaf >(node);
[1237]	2337
	2338	ObjectContainer::const_iterator oit, oit_end = tData.objects->end();
	2339
	2340	for (oit = tData.objects->begin(); oit != oit_end; ++ oit)
	2341	{
	2342	leaf->mObjects.push_back(*oit);
	2343	}
	2344	}
	2345	else // interior
	2346	{
	2347	KdObjectsTraversalData frontData, backData;
[2017]	2348	KdInterior interior = static_cast<KdInterior >(node);
[1237]	2349
	2350	frontData.objects = new ObjectContainer();
	2351	backData.objects = new ObjectContainer();
	2352
	2353	ObjectContainer::const_iterator oit, oit_end = tData.objects->end();
	2354
	2355	for (oit = tData.objects->begin(); oit != oit_end; ++ oit)
	2356	{
	2357	Intersectable object = oit;
	2358
	2359	// determine the side of this ray with respect to the plane
	2360	const AxisAlignedBox3 box = object->GetBox();
	2361
	2362	if (box.Max(interior->mAxis) >= interior->mPosition)
	2363	{
	2364	frontData.objects->push_back(object);
	2365	}
	2366
	2367	if (box.Min(interior->mAxis) < interior->mPosition)
	2368	{
	2369	backData.objects->push_back(object);
	2370	}
	2371	}
	2372
	2373	tStack.push(backData);
	2374	tStack.push(frontData);
	2375	}
	2376
	2377	DEL_PTR(tData.objects);
	2378	}
	2379	}
	2380
	2381
[1779]	2382	void OspTree::PrepareConstruction(SplitQueue &tQueue,
	2383	const VssRayContainer &sampleRays,
	2384	const ObjectContainer &objects,
	2385	RayInfoContainer &rays)
[1237]	2386	{
	2387	// store pointer to this tree
	2388	OspSubdivisionCandidate::sOspTree = this;
	2389	mOspStats.nodes = 1;
	2390
	2391	// compute bounding box from objects
[1287]	2392	ComputeBoundingBox(objects);
[1237]	2393
	2394	mTermMinProbability *= mBoundingBox.GetVolume();
	2395	mGlobalCostMisses = 0;
	2396
	2397	//-- create new root
	2398	KdLeaf *kdleaf = new KdLeaf(NULL, 0);
	2399	kdleaf->mObjects = objects;
	2400	mRoot = kdleaf;
	2401
	2402	// get clipped rays
	2403	PreprocessRays(kdleaf, sampleRays, rays);
	2404
	2405	// probabilty is voume of all "seen" view cells
	2406	#if 1
	2407	const float prop = EvalViewCellsVolume(kdleaf, rays);
	2408	#else
	2409	const float prop = GetBoundingBox().GetVolume();
	2410	#endif
	2411
	2412	//-- add first candidate for object space partition
	2413
	2414	// create osp traversal data
	2415	OspTraversalData oData(kdleaf, 0, &rays, 0, prop, mBoundingBox);
	2416
	2417	//-- first split candidate
	2418	OspSubdivisionCandidate *oSubdivisionCandidate =
	2419	new OspSubdivisionCandidate(oData);
	2420
	2421	UpdateViewCellsPvs(kdleaf, rays);
	2422
	2423	EvalSubdivisionCandidate(*oSubdivisionCandidate);
	2424
	2425	mTotalCost = (float)objects.size() * prop /
	2426	mVspTree->GetBoundingBox().GetVolume();
	2427
	2428	EvalSubdivisionStats(*oSubdivisionCandidate);
	2429
[1779]	2430	tQueue.Push(oSubdivisionCandidate);
[1237]	2431	}
	2432
	2433
[1259]	2434	bool OspTree::AddLeafToPvs(KdLeaf *leaf,
	2435	ViewCell *vc,
	2436	const float pdf,
	2437	float &contribution)
	2438	{
	2439	// add kd intersecable to pvs
	2440	KdIntersectable *kdObj = GetOrCreateKdIntersectable(leaf);
	2441
	2442	return vc->AddPvsSample(kdObj, pdf, contribution);
	2443	}
	2444
	2445
[1694]	2446	}

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source: GTP/trunk/Lib/Vis/Preprocessing/src/OspTree.cpp @ 2542

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