public static Dictionary <long, BuildStats> FindBuildStatsPerPlayer()
{
Dictionary <long, BuildStats> stats = new Dictionary <long, BuildStats>();
foreach (MyEntity entity in MyEntities.GetEntities())
{
if (!(entity is MyCubeGrid grid))
{
continue;
}
foreach (var block in grid.GetBlocks())
{
long buildBy = block.BuiltBy;
if (!stats.TryGetValue(buildBy, out BuildStats statsForPlayer))
{
statsForPlayer = new BuildStats();
stats.Add(buildBy, statsForPlayer);
}
statsForPlayer.BlockCount++;
statsForPlayer.PcuCount += BlockUtils.GetPcu(block);
}
}
return(stats);
}
public void build <T>(List <T> primitives, uint leafSize = 3, bool printStats = false) where T : IModel
{
if (primitives.Count == 0)
{
init_empty();
return;
}
buildData dat;
dat.maxPrims = (int)leafSize;
dat.numPrims = (uint)primitives.Count;
dat.indices = new uint[dat.numPrims];
dat.primBound = new AxisAlignedBox[dat.numPrims];
bounds = primitives[0].getBounds();
for (int i = 0; i < dat.numPrims; ++i)
{
dat.indices[i] = (uint)i;
dat.primBound[i] = primitives[i].getBounds();
bounds.merge(dat.primBound[i]);
}
List <uint> tempTree = new List <uint>();
BuildStats stats = new BuildStats();
buildHierarchy(tempTree, dat, stats);
objects = new uint[dat.numPrims];
for (int i = 0; i < dat.numPrims; ++i)
{
objects[i] = dat.indices[i];
}
tree = tempTree.ToArray();
}
public async Task <ActionResult> Stats(bool pr = false)
{
var util = Factory.Create <BuildCounterEntity>(_storageAccount.CreateCloudTableClient(), TableNames.CounterBuilds);
var map = new Dictionary <DateTimeKey, BuildStats>();
var endDate = DateTimeOffset.UtcNow;
var startDate = endDate.AddDays(-7);
foreach (var entity in await util.QueryAsync(startDate: startDate, endDate: endDate))
{
BuildStats stats;
var date = util.GetDateTimeKey(entity);
if (!map.TryGetValue(date, out stats))
{
stats = new BuildStats(date.DateTime);
map[date] = stats;
}
stats.BuildSucceededCount += entity.CommitSucceededCount;
stats.BuildFailedCount += entity.CommitFailedCount;
if (pr)
{
stats.BuildSucceededCount += entity.PullRequestSucceededCount;
stats.BuildFailedCount += entity.PullRequestFailedCount;
}
}
var model = new BuildStatsModel(map.Values.OrderBy(x => x.Date).ToList(), pr);
return(View(viewName: "Stats", model: model));
}
public void build <T>(List <T> primitives, GetBounds <T> getBounds, uint leafSize = 3, bool printStats = false)
{
if (primitives.Count == 0)
{
init_empty();
return;
}
buildData dat;
dat.maxPrims = (int)leafSize;
dat.numPrims = (uint)primitives.Count;
dat.indices = new uint[dat.numPrims];
dat.primBound = new AxisAlignedBox[dat.numPrims];
getBounds(primitives[0], out bounds);
for (int i = 0; i < dat.numPrims; ++i)
{
dat.primBound[i] = AxisAlignedBox.NaN;
dat.indices[i] = (uint)i;
getBounds(primitives[i], out dat.primBound[i]);
bounds.merge(dat.primBound[i]);
}
List <uint> tempTree = new List <uint>();
BuildStats stats = new BuildStats();
buildHierarchy(tempTree, dat, stats);
for (int i = 0; i < dat.numPrims; ++i)
{
objects.Add(dat.indices[i]);
}
tree = tempTree;
}
public void build(PrimitiveList primitives)
{
this.primitives = primitives;
int n = primitives.getNumPrimitives();
UI.printDetailed(UI.Module.ACCEL, "Getting bounding box ...");
bounds = primitives.getWorldBounds(null);
objects = new int[n];
for (int i = 0; i < n; i++)
{
objects[i] = i;
}
UI.printDetailed(UI.Module.ACCEL, "Creating tree ...");
int initialSize = 3 * (2 * 6 * n + 1);
List <int> tempTree = new List <int>((initialSize + 3) / 4);
BuildStats stats = new BuildStats();
Timer t = new Timer();
t.start();
buildHierarchy(tempTree, objects, stats);
t.end();
UI.printDetailed(UI.Module.ACCEL, "Trimming tree ...");
tree = tempTree.ToArray();
// display stats
stats.printStats();
UI.printDetailed(UI.Module.ACCEL, " * Creation time: {0}", t);
UI.printDetailed(UI.Module.ACCEL, " * Usage of init: {0,9:0.00}%", (double)(100 * tree.Length) / initialSize);
UI.printDetailed(UI.Module.ACCEL, " * Tree memory: {0}", Memory.SizeOf(tree));
UI.printDetailed(UI.Module.ACCEL, " * Indices memory: {0}", Memory.SizeOf(objects));
}
public void build(PrimitiveList primitives)
{
this.primitives = primitives;
int n = primitives.getNumPrimitives();
UI.printDetailed(UI.Module.ACCEL, "Getting bounding box ...");
bounds = primitives.getWorldBounds(null);
objects = new int[n];
for (int i = 0; i < n; i++)
objects[i] = i;
UI.printDetailed(UI.Module.ACCEL, "Creating tree ...");
int initialSize = 3 * (2 * 6 * n + 1);
List<int> tempTree = new List<int>((initialSize + 3) / 4);
BuildStats stats = new BuildStats();
Timer t = new Timer();
t.start();
buildHierarchy(tempTree, objects, stats);
t.end();
UI.printDetailed(UI.Module.ACCEL, "Trimming tree ...");
tree = tempTree.ToArray();
// display stats
stats.printStats();
UI.printDetailed(UI.Module.ACCEL, " * Creation time: %s", t);
UI.printDetailed(UI.Module.ACCEL, " * Usage of init: %3d%%", 100 * tree.Length / initialSize);
UI.printDetailed(UI.Module.ACCEL, " * Tree memory: %s", Memory.SizeOf(tree));
UI.printDetailed(UI.Module.ACCEL, " * Indices memory: %s", Memory.SizeOf(objects));
}
void BuildHierarchy(List <uint> tempTree, buildData dat, BuildStats stats)
{
// create space for the first node
tempTree.Add(3u << 30); // dummy leaf
tempTree.Add(0);
tempTree.Add(0);
// seed bbox
AABound gridBox = new();
gridBox.lo = bounds.Lo;
gridBox.hi = bounds.Hi;
AABound nodeBox = gridBox;
// seed subdivide function
Subdivide(0, (int)(dat.numPrims - 1), tempTree, dat, gridBox, nodeBox, 0, 1, stats);
}
private void buildHierarchy(List <int> tempTree, int[] indices, BuildStats stats)
{
// create space for the first node
tempTree.Add(3 << 30); // dummy leaf
tempTree.Add(0);
tempTree.Add(0);
if (objects.Length == 0)
{
return;
}
// seed bbox
float[] gridBox = { bounds.getMinimum().x, bounds.getMaximum().x,
bounds.getMinimum().y, bounds.getMaximum().y,
bounds.getMinimum().z, bounds.getMaximum().z };
float[] nodeBox = { bounds.getMinimum().x, bounds.getMaximum().x,
bounds.getMinimum().y, bounds.getMaximum().y,
bounds.getMinimum().z, bounds.getMaximum().z };
// seed subdivide function
subdivide(0, objects.Length - 1, tempTree, indices, gridBox, nodeBox, 0, 1, stats);
}
public BuildContext()
{
Stats = new BuildStats();
Env = new BuildEnvironment(this);
ProbedPaths = new ConcurrentBag<string>();
}
private void buildTree(float minx, float maxx, float miny, float maxy, float minz, float maxz, BuildTask task, int depth, List <int> tempTree, int offset, List <int> tempList, BuildStats stats)
{
// get node bounding box extents
if (task.numObjects > maxPrims && depth < MAX_DEPTH)
{
float dx = maxx - minx;
float dy = maxy - miny;
float dz = maxz - minz;
// search for best possible split
float bestCost = INTERSECT_COST * task.numObjects;
int bestAxis = -1;
int bestOffsetStart = -1;
int bestOffsetEnd = -1;
float bestSplit = 0;
bool bestPlanarLeft = false;
int bnl = 0, bnr = 0;
// inverse area of the bounding box (factor of 2 ommitted)
float area = (dx * dy + dy * dz + dz * dx);
float ISECT_COST = INTERSECT_COST / area;
// setup counts for each axis
int[] nl = { 0, 0, 0 };
int[] nr = { task.numObjects, task.numObjects, task.numObjects };
// setup bounds for each axis
float[] dp = { dy *dz, dz *dx, dx *dy };
float[] ds = { dy + dz, dz + dx, dx + dy };
float[] nodeMin = { minx, miny, minz };
float[] nodeMax = { maxx, maxy, maxz };
// search for best cost
int nSplits = task.n;
long[] splits = task.splits;
byte[] lrtable = task.leftRightTable;
for (int i = 0; i < nSplits;)
{
// extract current split
long ptr = splits[i];
float split = unpackSplit(ptr);
int axis = unpackAxis(ptr);
// mark current position
int currentOffset = i;
// count number of primitives start/stopping/lying on the
// current plane
int pClosed = 0, pPlanar = 0, pOpened = 0;
long ptrMasked = (long)((ulong)ptr & (~((ulong)TYPE_MASK) & 0xFFFFFFFFF0000000L));
long ptrClosed = ptrMasked | CLOSED;
long ptrPlanar = ptrMasked | PLANAR;
long ptrOpened = ptrMasked | OPENED;
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrClosed)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pClosed++;
i++;
}
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrPlanar)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pPlanar++;
i++;
}
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrOpened)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pOpened++;
i++;
}
// now we have summed all contributions from this plane
nr[axis] -= pPlanar + pClosed;
// compute cost
if (split >= nodeMin[axis] && split <= nodeMax[axis])
{
// left and right surface area (factor of 2 ommitted)
float dl = split - nodeMin[axis];
float dr = nodeMax[axis] - split;
float lp = dp[axis] + dl * ds[axis];
float rp = dp[axis] + dr * ds[axis];
// planar prims go to smallest cell always
bool planarLeft = dl < dr;
int numLeft = nl[axis] + (planarLeft ? pPlanar : 0);
int numRight = nr[axis] + (planarLeft ? 0 : pPlanar);
float eb = ((numLeft == 0 && dl > 0) || (numRight == 0 && dr > 0)) ? EMPTY_BONUS : 0;
float cost = TRAVERSAL_COST + ISECT_COST * (1 - eb) * (lp * numLeft + rp * numRight);
if (cost < bestCost)
{
bestCost = cost;
bestAxis = axis;
bestSplit = split;
bestOffsetStart = currentOffset;
bestOffsetEnd = i;
bnl = numLeft;
bnr = numRight;
bestPlanarLeft = planarLeft;
}
}
// move objects left
nl[axis] += pOpened + pPlanar;
}
// debug check for correctness of the scan
for (int axis = 0; axis < 3; axis++)
{
int numLeft = nl[axis];
int numRight = nr[axis];
if (numLeft != task.numObjects || numRight != 0)
{
UI.printError(UI.Module.ACCEL, "Didn't scan full range of objects @depth={0}. Left overs for axis {1}: [L: {2}] [R: {3}]", depth, axis, numLeft, numRight);
}
}
// found best split?
if (bestAxis != -1)
{
// allocate space for child nodes
BuildTask taskL = new BuildTask(bnl, task);
BuildTask taskR = new BuildTask(bnr, task);
int lk = 0, rk = 0;
for (int i = 0; i < bestOffsetStart; i++)
{
long ptr = splits[i];
if (unpackAxis(ptr) == bestAxis)
{
if (unpackSplitType(ptr) != CLOSED)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(1 << ((obj & 3) << 1));//>>>
lk++;
}
}
}
for (int i = bestOffsetStart; i < bestOffsetEnd; i++)
{
long ptr = splits[i];
Debug.Assert(unpackAxis(ptr) == bestAxis);
if (unpackSplitType(ptr) == PLANAR)
{
if (bestPlanarLeft)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(1 << ((obj & 3) << 1));//>>>
lk++;
}
else
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(2 << ((obj & 3) << 1));//>>>
rk++;
}
}
}
for (int i = bestOffsetEnd; i < nSplits; i++)
{
long ptr = splits[i];
if (unpackAxis(ptr) == bestAxis)
{
if (unpackSplitType(ptr) != OPENED)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(2 << ((obj & 3) << 1));//>>>
rk++;
}
}
}
// output new splits while maintaining order
long[] splitsL = taskL.splits;
long[] splitsR = taskR.splits;
int nsl = 0, nsr = 0;
for (int i = 0; i < nSplits; i++)
{
long ptr = splits[i];
int obj = unpackObject(ptr);
int idx = (int)((uint)obj >> 2);//>>>
int mask = 1 << ((obj & 3) << 1);
if ((lrtable[idx] & mask) != 0)
{
splitsL[nsl] = ptr;
nsl++;
}
if ((lrtable[idx] & (mask << 1)) != 0)
{
splitsR[nsr] = ptr;
nsr++;
}
}
taskL.n = nsl;
taskR.n = nsr;
// free more memory
task.splits = splits = splitsL = splitsR = null;
task = null;
// allocate child nodes
int nextOffset = tempTree.Count;
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
// create current node
tempTree[offset + 0] = (bestAxis << 30) | nextOffset;
tempTree[offset + 1] = ByteUtil.floatToRawIntBits(bestSplit);
// recurse for child nodes - free object arrays after each step
stats.updateInner();
switch (bestAxis)
{
case 0:
buildTree(minx, bestSplit, miny, maxy, minz, maxz, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(bestSplit, maxx, miny, maxy, minz, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
case 1:
buildTree(minx, maxx, miny, bestSplit, minz, maxz, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(minx, maxx, bestSplit, maxy, minz, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
case 2:
buildTree(minx, maxx, miny, maxy, minz, bestSplit, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(minx, maxx, miny, maxy, bestSplit, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
default:
Debug.Assert(false);
break;
}
}
}
// create leaf node
int listOffset = tempList.Count;
int n = 0;
for (int i = 0; i < task.n; i++)
{
long ptr = task.splits[i];
if (unpackAxis(ptr) == 0 && unpackSplitType(ptr) != CLOSED)
{
tempList.Add(unpackObject(ptr));
n++;
}
}
stats.updateLeaf(depth, n);
if (n != task.numObjects)
{
UI.printError(UI.Module.ACCEL, "Error creating leaf node - expecting {0} found {1}", task.numObjects, n);
}
tempTree[offset + 0] = (3 << 30) | listOffset;
tempTree[offset + 1] = task.numObjects;
// free some memory
task.splits = null;
}
public void build(PrimitiveList primitives)
{
UI.printDetailed(UI.Module.ACCEL, "KDTree settings");
UI.printDetailed(UI.Module.ACCEL, " * Max Leaf Size: {0}", maxPrims);
UI.printDetailed(UI.Module.ACCEL, " * Max Depth: {0}", MAX_DEPTH);
UI.printDetailed(UI.Module.ACCEL, " * Traversal cost: {0}", TRAVERSAL_COST);
UI.printDetailed(UI.Module.ACCEL, " * Intersect cost: {0}", INTERSECT_COST);
UI.printDetailed(UI.Module.ACCEL, " * Empty bonus: {0}", EMPTY_BONUS);
UI.printDetailed(UI.Module.ACCEL, " * Dump leaves: {0}", dump ? "enabled" : "disabled");
Timer total = new Timer();
total.start();
this.primitiveList = primitives;
// get the object space bounds
bounds = primitives.getWorldBounds(null);
int nPrim = primitiveList.getNumPrimitives(), nSplits = 0;
BuildTask task = new BuildTask(nPrim);
Timer prepare = new Timer();
prepare.start();
for (int i = 0; i < nPrim; i++)
{
for (int axis = 0; axis < 3; axis++)
{
float ls = primitiveList.getPrimitiveBound(i, 2 * axis + 0);
float rs = primitiveList.getPrimitiveBound(i, 2 * axis + 1);
if (ls == rs)
{
// flat in this dimension
task.splits[nSplits] = pack(ls, PLANAR, axis, i);
nSplits++;
}
else
{
task.splits[nSplits + 0] = pack(ls, OPENED, axis, i);
task.splits[nSplits + 1] = pack(rs, CLOSED, axis, i);
nSplits += 2;
}
}
}
task.n = nSplits;
prepare.end();
Timer t = new Timer();
List <int> tempTree = new List <int>();
List <int> tempList = new List <int>();
tempTree.Add(0);
tempTree.Add(1);
t.start();
// sort it
Timer sorting = new Timer();
sorting.start();
radix12(task.splits, task.n);
sorting.end();
// build the actual tree
BuildStats stats = new BuildStats();
buildTree(bounds.getMinimum().x, bounds.getMaximum().x, bounds.getMinimum().y, bounds.getMaximum().y, bounds.getMinimum().z, bounds.getMaximum().z, task, 1, tempTree, 0, tempList, stats);
t.end();
// write out arrays
// free some memory
task = null;
tree = tempTree.ToArray();
tempTree = null;
this.primitives = tempList.ToArray();
tempList = null;
total.end();
// display some extra info
stats.printStats();
UI.printDetailed(UI.Module.ACCEL, " * Node memory: {0}", Memory.SizeOf(tree));
UI.printDetailed(UI.Module.ACCEL, " * Object memory: {0}", Memory.SizeOf(this.primitives));
UI.printDetailed(UI.Module.ACCEL, " * Prepare time: {0}", prepare);
UI.printDetailed(UI.Module.ACCEL, " * Sorting time: {0}", sorting);
UI.printDetailed(UI.Module.ACCEL, " * Tree creation: {0}", t);
UI.printDetailed(UI.Module.ACCEL, " * Build time: {0}", total);
if (dump)
{
try
{
UI.printInfo(UI.Module.ACCEL, "Dumping mtls to {0}.mtl ...", dumpPrefix);
StreamWriter mtlFile = new StreamWriter(dumpPrefix + ".mtl");
int maxN = stats.maxObjects;
for (int n = 0; n <= maxN; n++)
{
float blend = (float)n / (float)maxN;
Color nc;
if (blend < 0.25)
{
nc = Color.blend(Color.BLUE, Color.GREEN, blend / 0.25f);
}
else if (blend < 0.5)
{
nc = Color.blend(Color.GREEN, Color.YELLOW, (blend - 0.25f) / 0.25f);
}
else if (blend < 0.75)
{
nc = Color.blend(Color.YELLOW, Color.RED, (blend - 0.50f) / 0.25f);
}
else
{
nc = Color.MAGENTA;
}
mtlFile.WriteLine(string.Format("newmtl mtl{0}", n));
float[] rgb = nc.getRGB();
mtlFile.WriteLine("Ka 0.1 0.1 0.1");
mtlFile.WriteLine(string.Format("Kd {0}g {1}g {2}g", rgb[0], rgb[1], rgb[2]));
mtlFile.WriteLine("illum 1\n");
}
StreamWriter objFile = new StreamWriter(dumpPrefix + ".obj");
UI.printInfo(UI.Module.ACCEL, "Dumping tree to {0}.obj ...", dumpPrefix);
dumpObj(0, 0, maxN, new BoundingBox(bounds), objFile, mtlFile);
objFile.Close();
mtlFile.Close();
}
catch (Exception e)
{
Console.WriteLine(e);
}
}
}
public void build(PrimitiveList primitives)
{
UI.printDetailed(UI.Module.ACCEL, "KDTree settings");
UI.printDetailed(UI.Module.ACCEL, " * Max Leaf Size: {0}", maxPrims);
UI.printDetailed(UI.Module.ACCEL, " * Max Depth: {0}", MAX_DEPTH);
UI.printDetailed(UI.Module.ACCEL, " * Traversal cost: {0}", TRAVERSAL_COST);
UI.printDetailed(UI.Module.ACCEL, " * Intersect cost: {0}", INTERSECT_COST);
UI.printDetailed(UI.Module.ACCEL, " * Empty bonus: {0}", EMPTY_BONUS);
UI.printDetailed(UI.Module.ACCEL, " * Dump leaves: {0}", dump ? "enabled" : "disabled");
Timer total = new Timer();
total.start();
primitiveList = primitives;
// get the object space bounds
bounds = primitives.getWorldBounds(null);
int nPrim = primitiveList.getNumPrimitives(), nSplits = 0;
BuildTask task = new BuildTask(nPrim);
Timer prepare = new Timer();
prepare.start();
for (int i = 0; i < nPrim; i++)
{
for (int axis = 0; axis < 3; axis++)
{
float ls = primitiveList.getPrimitiveBound(i, 2 * axis + 0);
float rs = primitiveList.getPrimitiveBound(i, 2 * axis + 1);
if (ls == rs)
{
// flat in this dimension
task.splits[nSplits] = pack(ls, PLANAR, axis, i);
nSplits++;
}
else
{
task.splits[nSplits + 0] = pack(ls, OPENED, axis, i);
task.splits[nSplits + 1] = pack(rs, CLOSED, axis, i);
nSplits += 2;
}
}
}
task.n = nSplits;
prepare.end();
Timer t = new Timer();
List<int> tempTree = new List<int>();
List<int> tempList = new List<int>();
tempTree.Add(0);
tempTree.Add(1);
t.start();
// sort it
Timer sorting = new Timer();
sorting.start();
radix12(task.splits, task.n);
sorting.end();
// build the actual tree
BuildStats stats = new BuildStats();
buildTree(bounds.getMinimum().x, bounds.getMaximum().x, bounds.getMinimum().y, bounds.getMaximum().y, bounds.getMinimum().z, bounds.getMaximum().z, task, 1, tempTree, 0, tempList, stats);
t.end();
// write out arrays
// free some memory
task = null;
tree = tempTree.ToArray();
tempTree = null;
this.primitives = tempList.ToArray();
tempList = null;
total.end();
// display some extra info
stats.printStats();
UI.printDetailed(UI.Module.ACCEL, " * Node memory: {0}", Memory.SizeOf(tree));
UI.printDetailed(UI.Module.ACCEL, " * Object memory: {0}", Memory.SizeOf(this.primitives));
UI.printDetailed(UI.Module.ACCEL, " * Prepare time: {0}", prepare);
UI.printDetailed(UI.Module.ACCEL, " * Sorting time: {0}", sorting);
UI.printDetailed(UI.Module.ACCEL, " * Tree creation: {0}", t);
UI.printDetailed(UI.Module.ACCEL, " * Build time: {0}", total);
if (dump)
{
try
{
UI.printInfo(UI.Module.ACCEL, "Dumping mtls to {0}.mtl ...", dumpPrefix);
StreamWriter mtlFile = new StreamWriter(dumpPrefix + ".mtl");
int maxN = stats.maxObjects;
for (int n = 0; n <= maxN; n++)
{
float blend = (float)n / (float)maxN;
Color nc;
if (blend < 0.25)
nc = Color.blend(Color.BLUE, Color.GREEN, blend / 0.25f);
else if (blend < 0.5)
nc = Color.blend(Color.GREEN, Color.YELLOW, (blend - 0.25f) / 0.25f);
else if (blend < 0.75)
nc = Color.blend(Color.YELLOW, Color.RED, (blend - 0.50f) / 0.25f);
else
nc = Color.MAGENTA;
mtlFile.WriteLine(string.Format("newmtl mtl{0}", n));
float[] rgb = nc.getRGB();
mtlFile.WriteLine("Ka 0.1 0.1 0.1");
mtlFile.WriteLine(string.Format("Kd {0}g {1}g {2}g", rgb[0], rgb[1], rgb[2]));
mtlFile.WriteLine("illum 1\n");
}
StreamWriter objFile = new StreamWriter(dumpPrefix + ".obj");
UI.printInfo(UI.Module.ACCEL, "Dumping tree to {0}.obj ...", dumpPrefix);
dumpObj(0, 0, maxN, new BoundingBox(bounds), objFile, mtlFile);
objFile.Close();
mtlFile.Close();
}
catch (Exception e)
{
Console.WriteLine(e);
}
}
}
private void buildHierarchy(List<int> tempTree, int[] indices, BuildStats stats)
{
// create space for the first node
tempTree.Add(3 << 30); // dummy leaf
tempTree.Add(0);
tempTree.Add(0);
if (objects.Length == 0)
return;
// seed bbox
float[] gridBox = { bounds.getMinimum().x, bounds.getMaximum().x,
bounds.getMinimum().y, bounds.getMaximum().y,
bounds.getMinimum().z, bounds.getMaximum().z };
float[] nodeBox = { bounds.getMinimum().x, bounds.getMaximum().x,
bounds.getMinimum().y, bounds.getMaximum().y,
bounds.getMinimum().z, bounds.getMaximum().z };
// seed subdivide function
subdivide(0, objects.Length - 1, tempTree, indices, gridBox, nodeBox, 0, 1, stats);
}
private void subdivide(int left, int right, List <int> tempTree, int[] indices, float[] gridBox, float[] nodeBox, int nodeIndex, int depth, BuildStats stats)
{
if ((right - left + 1) <= maxPrims || depth >= 64)
{
// write leaf node
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
// calculate extents
int axis = -1, prevAxis, rightOrig;
float clipL = float.NaN, clipR = float.NaN, prevClip = float.NaN;
float split = float.NaN, prevSplit;
bool wasLeft = true;
while (true)
{
prevAxis = axis;
prevSplit = split;
// perform quick consistency checks
float[] d = { gridBox[1] - gridBox[0], gridBox[3] - gridBox[2],
gridBox[5] - gridBox[4] };
if (d[0] < 0 || d[1] < 0 || d[2] < 0)
{
throw new Exception("negative node extents");
}
for (int i = 0; i < 3; i++)
{
if (nodeBox[2 * i + 1] < gridBox[2 * i] || nodeBox[2 * i] > gridBox[2 * i + 1])
{
UI.printError(UI.Module.ACCEL, "Reached tree area in error - discarding node with: {0} objects", right - left + 1);
throw new Exception("invalid node overlap");
}
}
// find longest axis
if (d[0] > d[1] && d[0] > d[2])
{
axis = 0;
}
else if (d[1] > d[2])
{
axis = 1;
}
else
{
axis = 2;
}
split = 0.5f * (gridBox[2 * axis] + gridBox[2 * axis + 1]);
// partition L/R subsets
clipL = float.NegativeInfinity;
clipR = float.PositiveInfinity;
rightOrig = right; // save this for later
float nodeL = float.PositiveInfinity;
float nodeR = float.NegativeInfinity;
for (int i = left; i <= right;)
{
int obj = indices[i];
float minb = primitives.getPrimitiveBound(obj, 2 * axis + 0);
float maxb = primitives.getPrimitiveBound(obj, 2 * axis + 1);
float center = (minb + maxb) * 0.5f;
if (center <= split)
{
// stay left
i++;
if (clipL < maxb)
{
clipL = maxb;
}
}
else
{
// move to the right most
int t = indices[i];
indices[i] = indices[right];
indices[right] = t;
right--;
if (clipR > minb)
{
clipR = minb;
}
}
if (nodeL > minb)
{
nodeL = minb;
}
if (nodeR < maxb)
{
nodeR = maxb;
}
}
// check for empty space
if (nodeL > nodeBox[2 * axis + 0] && nodeR < nodeBox[2 * axis + 1])
{
float nodeBoxW = nodeBox[2 * axis + 1] - nodeBox[2 * axis + 0];
float nodeNewW = nodeR - nodeL;
// node box is too big compare to space occupied by primitives?
if (1.3f * nodeNewW < nodeBoxW)
{
stats.updateBVH2();
int nextIndex = tempTree.Count;
// allocate child
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
// write bvh2 clip node
stats.updateInner();
tempTree[nodeIndex + 0] = (axis << 30) | (1 << 29) | nextIndex;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(nodeL);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(nodeR);
// update nodebox and recurse
nodeBox[2 * axis + 0] = nodeL;
nodeBox[2 * axis + 1] = nodeR;
subdivide(left, rightOrig, tempTree, indices, gridBox, nodeBox, nextIndex, depth + 1, stats);
return;
}
}
// ensure we are making progress in the subdivision
if (right == rightOrig)
{
// all left
if (clipL <= split)
{
// keep looping on left half
gridBox[2 * axis + 1] = split;
prevClip = clipL;
wasLeft = true;
continue;
}
if (prevAxis == axis && prevSplit == split)
{
// we are stuck here - create a leaf
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
gridBox[2 * axis + 1] = split;
prevClip = float.NaN;
}
else if (left > right)
{
// all right
right = rightOrig;
if (clipR >= split)
{
// keep looping on right half
gridBox[2 * axis + 0] = split;
prevClip = clipR;
wasLeft = false;
continue;
}
if (prevAxis == axis && prevSplit == split)
{
// we are stuck here - create a leaf
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
gridBox[2 * axis + 0] = split;
prevClip = float.NaN;
}
else
{
// we are actually splitting stuff
if (prevAxis != -1 && !float.IsNaN(prevClip))
{
// second time through - lets create the previous split
// since it produced empty space
int nextIndex = tempTree.Count;
// allocate child node
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
if (wasLeft)
{
// create a node with a left child
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (prevAxis << 30) | nextIndex;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(prevClip);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(float.PositiveInfinity);
}
else
{
// create a node with a right child
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (prevAxis << 30) | (nextIndex - 3);
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(float.NegativeInfinity);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(prevClip);
}
// count stats for the unused leaf
depth++;
stats.updateLeaf(depth, 0);
// now we keep going as we are, with a new nodeIndex:
nodeIndex = nextIndex;
}
break;
}
}
// compute index of child nodes
int nextIndex1 = tempTree.Count;
// allocate left node
int nl = right - left + 1;
int nr = rightOrig - (right + 1) + 1;
if (nl > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
else
{
nextIndex1 -= 3;
}
// allocate right node
if (nr > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (axis << 30) | nextIndex1;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(clipL);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(clipR);
// prepare L/R child boxes
float[] gridBoxL = new float[6];
float[] gridBoxR = new float[6];
float[] nodeBoxL = new float[6];
float[] nodeBoxR = new float[6];
for (int i = 0; i < 6; i++)
{
gridBoxL[i] = gridBoxR[i] = gridBox[i];
nodeBoxL[i] = nodeBoxR[i] = nodeBox[i];
}
gridBoxL[2 * axis + 1] = gridBoxR[2 * axis] = split;
nodeBoxL[2 * axis + 1] = clipL;
nodeBoxR[2 * axis + 0] = clipR;
// free memory
gridBox = nodeBox = null;
// recurse
if (nl > 0)
{
subdivide(left, right, tempTree, indices, gridBoxL, nodeBoxL, nextIndex1, depth + 1, stats);
}
else
{
stats.updateLeaf(depth + 1, 0);
}
if (nr > 0)
{
subdivide(right + 1, rightOrig, tempTree, indices, gridBoxR, nodeBoxR, nextIndex1 + 3, depth + 1, stats);
}
else
{
stats.updateLeaf(depth + 1, 0);
}
}
private void subdivide(int left, int right, List<int> tempTree, int[] indices, float[] gridBox, float[] nodeBox, int nodeIndex, int depth, BuildStats stats)
{
if ((right - left + 1) <= maxPrims || depth >= 64)
{
// write leaf node
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
// calculate extents
int axis = -1, prevAxis, rightOrig;
float clipL = float.NaN, clipR = float.NaN, prevClip = float.NaN;
float split = float.NaN, prevSplit;
bool wasLeft = true;
while (true)
{
prevAxis = axis;
prevSplit = split;
// perform quick consistency checks
float[] d = { gridBox[1] - gridBox[0], gridBox[3] - gridBox[2],
gridBox[5] - gridBox[4] };
if (d[0] < 0 || d[1] < 0 || d[2] < 0)
throw new Exception("negative node extents");
for (int i = 0; i < 3; i++)
{
if (nodeBox[2 * i + 1] < gridBox[2 * i] || nodeBox[2 * i] > gridBox[2 * i + 1])
{
UI.printError(UI.Module.ACCEL, "Reached tree area in error - discarding node with: {0} objects", right - left + 1);
throw new Exception("invalid node overlap");
}
}
// find longest axis
if (d[0] > d[1] && d[0] > d[2])
axis = 0;
else if (d[1] > d[2])
axis = 1;
else
axis = 2;
split = 0.5f * (gridBox[2 * axis] + gridBox[2 * axis + 1]);
// partition L/R subsets
clipL = float.NegativeInfinity;
clipR = float.PositiveInfinity;
rightOrig = right; // save this for later
float nodeL = float.PositiveInfinity;
float nodeR = float.NegativeInfinity;
for (int i = left; i <= right; )
{
int obj = indices[i];
float minb = primitives.getPrimitiveBound(obj, 2 * axis + 0);
float maxb = primitives.getPrimitiveBound(obj, 2 * axis + 1);
float center = (minb + maxb) * 0.5f;
if (center <= split)
{
// stay left
i++;
if (clipL < maxb)
clipL = maxb;
}
else
{
// move to the right most
int t = indices[i];
indices[i] = indices[right];
indices[right] = t;
right--;
if (clipR > minb)
clipR = minb;
}
if (nodeL > minb)
nodeL = minb;
if (nodeR < maxb)
nodeR = maxb;
}
// check for empty space
if (nodeL > nodeBox[2 * axis + 0] && nodeR < nodeBox[2 * axis + 1])
{
float nodeBoxW = nodeBox[2 * axis + 1] - nodeBox[2 * axis + 0];
float nodeNewW = nodeR - nodeL;
// node box is too big compare to space occupied by primitives?
if (1.3f * nodeNewW < nodeBoxW)
{
stats.updateBVH2();
int nextIndex = tempTree.Count;
// allocate child
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
// write bvh2 clip node
stats.updateInner();
tempTree[nodeIndex + 0] = (axis << 30) | (1 << 29) | nextIndex;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(nodeL);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(nodeR);
// update nodebox and recurse
nodeBox[2 * axis + 0] = nodeL;
nodeBox[2 * axis + 1] = nodeR;
subdivide(left, rightOrig, tempTree, indices, gridBox, nodeBox, nextIndex, depth + 1, stats);
return;
}
}
// ensure we are making progress in the subdivision
if (right == rightOrig)
{
// all left
if (clipL <= split)
{
// keep looping on left half
gridBox[2 * axis + 1] = split;
prevClip = clipL;
wasLeft = true;
continue;
}
if (prevAxis == axis && prevSplit == split)
{
// we are stuck here - create a leaf
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
gridBox[2 * axis + 1] = split;
prevClip = float.NaN;
}
else if (left > right)
{
// all right
right = rightOrig;
if (clipR >= split)
{
// keep looping on right half
gridBox[2 * axis + 0] = split;
prevClip = clipR;
wasLeft = false;
continue;
}
if (prevAxis == axis && prevSplit == split)
{
// we are stuck here - create a leaf
stats.updateLeaf(depth, right - left + 1);
createNode(tempTree, nodeIndex, left, right);
return;
}
gridBox[2 * axis + 0] = split;
prevClip = float.NaN;
}
else
{
// we are actually splitting stuff
if (prevAxis != -1 && !float.IsNaN(prevClip))
{
// second time through - lets create the previous split
// since it produced empty space
int nextIndex = tempTree.Count;
// allocate child node
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
if (wasLeft)
{
// create a node with a left child
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (prevAxis << 30) | nextIndex;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(prevClip);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(float.PositiveInfinity);
}
else
{
// create a node with a right child
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (prevAxis << 30) | (nextIndex - 3);
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(float.NegativeInfinity);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(prevClip);
}
// count stats for the unused leaf
depth++;
stats.updateLeaf(depth, 0);
// now we keep going as we are, with a new nodeIndex:
nodeIndex = nextIndex;
}
break;
}
}
// compute index of child nodes
int nextIndex1 = tempTree.Count;
// allocate left node
int nl = right - left + 1;
int nr = rightOrig - (right + 1) + 1;
if (nl > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
else
nextIndex1 -= 3;
// allocate right node
if (nr > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
// write leaf node
stats.updateInner();
tempTree[nodeIndex + 0] = (axis << 30) | nextIndex1;
tempTree[nodeIndex + 1] = ByteUtil.floatToRawIntBits(clipL);
tempTree[nodeIndex + 2] = ByteUtil.floatToRawIntBits(clipR);
// prepare L/R child boxes
float[] gridBoxL = new float[6];
float[] gridBoxR = new float[6];
float[] nodeBoxL = new float[6];
float[] nodeBoxR = new float[6];
for (int i = 0; i < 6; i++)
{
gridBoxL[i] = gridBoxR[i] = gridBox[i];
nodeBoxL[i] = nodeBoxR[i] = nodeBox[i];
}
gridBoxL[2 * axis + 1] = gridBoxR[2 * axis] = split;
nodeBoxL[2 * axis + 1] = clipL;
nodeBoxR[2 * axis + 0] = clipR;
// free memory
gridBox = nodeBox = null;
// recurse
if (nl > 0)
subdivide(left, right, tempTree, indices, gridBoxL, nodeBoxL, nextIndex1, depth + 1, stats);
else
stats.updateLeaf(depth + 1, 0);
if (nr > 0)
subdivide(right + 1, rightOrig, tempTree, indices, gridBoxR, nodeBoxR, nextIndex1 + 3, depth + 1, stats);
else
stats.updateLeaf(depth + 1, 0);
}
void Subdivide(int left, int right, List <uint> tempTree, buildData dat, AABound gridBox, AABound nodeBox, int nodeIndex, int depth, BuildStats stats)
{
if ((right - left + 1) <= dat.maxPrims || depth >= 64)
{
// write leaf node
stats.UpdateLeaf(depth, right - left + 1);
CreateNode(tempTree, nodeIndex, left, right);
return;
}
// calculate extents
int axis = -1, prevAxis, rightOrig;
float clipL = float.NaN, clipR = float.NaN, prevClip = float.NaN;
float split = float.NaN, prevSplit;
bool wasLeft = true;
while (true)
{
prevAxis = axis;
prevSplit = split;
// perform quick consistency checks
Vector3 d = gridBox.hi - gridBox.lo;
for (int i = 0; i < 3; i++)
{
if (nodeBox.hi[i] < gridBox.lo[i] || nodeBox.lo[i] > gridBox.hi[i])
{
Log.outError(LogFilter.Server, "Reached tree area in error - discarding node with: {0} objects", right - left + 1);
}
}
// find longest axis
axis = (int)d.primaryAxis();
split = 0.5f * (gridBox.lo[axis] + gridBox.hi[axis]);
// partition L/R subsets
clipL = float.NegativeInfinity;
clipR = float.PositiveInfinity;
rightOrig = right; // save this for later
float nodeL = float.PositiveInfinity;
float nodeR = float.NegativeInfinity;
for (int i = left; i <= right;)
{
int obj = (int)dat.indices[i];
float minb = dat.primBound[obj].Lo[axis];
float maxb = dat.primBound[obj].Hi[axis];
float center = (minb + maxb) * 0.5f;
if (center <= split)
{
// stay left
i++;
if (clipL < maxb)
{
clipL = maxb;
}
}
else
{
// move to the right most
int t = (int)dat.indices[i];
dat.indices[i] = dat.indices[right];
dat.indices[right] = (uint)t;
right--;
if (clipR > minb)
{
clipR = minb;
}
}
nodeL = Math.Min(nodeL, minb);
nodeR = Math.Max(nodeR, maxb);
}
// check for empty space
if (nodeL > nodeBox.lo[axis] && nodeR < nodeBox.hi[axis])
{
float nodeBoxW = nodeBox.hi[axis] - nodeBox.lo[axis];
float nodeNewW = nodeR - nodeL;
// node box is too big compare to space occupied by primitives?
if (1.3f * nodeNewW < nodeBoxW)
{
stats.UpdateBVH2();
int nextIndex1 = tempTree.Count;
// allocate child
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
// write bvh2 clip node
stats.UpdateInner();
tempTree[nodeIndex + 0] = (uint)((axis << 30) | (1 << 29) | nextIndex1);
tempTree[nodeIndex + 1] = FloatToRawIntBits(nodeL);
tempTree[nodeIndex + 2] = FloatToRawIntBits(nodeR);
// update nodebox and recurse
nodeBox.lo[axis] = nodeL;
nodeBox.hi[axis] = nodeR;
Subdivide(left, rightOrig, tempTree, dat, gridBox, nodeBox, nextIndex1, depth + 1, stats);
return;
}
}
// ensure we are making progress in the subdivision
if (right == rightOrig)
{
// all left
if (prevAxis == axis && MathFunctions.fuzzyEq(prevSplit, split))
{
// we are stuck here - create a leaf
stats.UpdateLeaf(depth, right - left + 1);
CreateNode(tempTree, nodeIndex, left, right);
return;
}
if (clipL <= split)
{
// keep looping on left half
gridBox.hi[axis] = split;
prevClip = clipL;
wasLeft = true;
continue;
}
gridBox.hi[axis] = split;
prevClip = float.NaN;
}
else if (left > right)
{
// all right
right = rightOrig;
if (prevAxis == axis && MathFunctions.fuzzyEq(prevSplit, split))
{
// we are stuck here - create a leaf
stats.UpdateLeaf(depth, right - left + 1);
CreateNode(tempTree, nodeIndex, left, right);
return;
}
if (clipR >= split)
{
// keep looping on right half
gridBox.lo[axis] = split;
prevClip = clipR;
wasLeft = false;
continue;
}
gridBox.lo[axis] = split;
prevClip = float.NaN;
}
else
{
// we are actually splitting stuff
if (prevAxis != -1 && !float.IsNaN(prevClip))
{
// second time through - lets create the previous split
// since it produced empty space
int nextIndex0 = tempTree.Count;
// allocate child node
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
if (wasLeft)
{
// create a node with a left child
// write leaf node
stats.UpdateInner();
tempTree[nodeIndex + 0] = (uint)((prevAxis << 30) | nextIndex0);
tempTree[nodeIndex + 1] = FloatToRawIntBits(prevClip);
tempTree[nodeIndex + 2] = FloatToRawIntBits(float.PositiveInfinity);
}
else
{
// create a node with a right child
// write leaf node
stats.UpdateInner();
tempTree[nodeIndex + 0] = (uint)((prevAxis << 30) | (nextIndex0 - 3));
tempTree[nodeIndex + 1] = FloatToRawIntBits(float.NegativeInfinity);
tempTree[nodeIndex + 2] = FloatToRawIntBits(prevClip);
}
// count stats for the unused leaf
depth++;
stats.UpdateLeaf(depth, 0);
// now we keep going as we are, with a new nodeIndex:
nodeIndex = nextIndex0;
}
break;
}
}
// compute index of child nodes
int nextIndex = tempTree.Count;
// allocate left node
int nl = right - left + 1;
int nr = rightOrig - (right + 1) + 1;
if (nl > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
else
{
nextIndex -= 3;
}
// allocate right node
if (nr > 0)
{
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
}
// write leaf node
stats.UpdateInner();
tempTree[nodeIndex + 0] = (uint)((axis << 30) | nextIndex);
tempTree[nodeIndex + 1] = FloatToRawIntBits(clipL);
tempTree[nodeIndex + 2] = FloatToRawIntBits(clipR);
// prepare L/R child boxes
AABound gridBoxL = gridBox;
AABound gridBoxR = gridBox;
AABound nodeBoxL = nodeBox;
AABound nodeBoxR = nodeBox;
gridBoxL.hi[axis] = gridBoxR.lo[axis] = split;
nodeBoxL.hi[axis] = clipL;
nodeBoxR.lo[axis] = clipR;
// recurse
if (nl > 0)
{
Subdivide(left, right, tempTree, dat, gridBoxL, nodeBoxL, nextIndex, depth + 1, stats);
}
else
{
stats.UpdateLeaf(depth + 1, 0);
}
if (nr > 0)
{
Subdivide(right + 1, rightOrig, tempTree, dat, gridBoxR, nodeBoxR, nextIndex + 3, depth + 1, stats);
}
else
{
stats.UpdateLeaf(depth + 1, 0);
}
}
private void buildTree(float minx, float maxx, float miny, float maxy, float minz, float maxz, BuildTask task, int depth, List<int> tempTree, int offset, List<int> tempList, BuildStats stats)
{
// get node bounding box extents
if (task.numObjects > maxPrims && depth < MAX_DEPTH)
{
float dx = maxx - minx;
float dy = maxy - miny;
float dz = maxz - minz;
// search for best possible split
float bestCost = INTERSECT_COST * task.numObjects;
int bestAxis = -1;
int bestOffsetStart = -1;
int bestOffsetEnd = -1;
float bestSplit = 0;
bool bestPlanarLeft = false;
int bnl = 0, bnr = 0;
// inverse area of the bounding box (factor of 2 ommitted)
float area = (dx * dy + dy * dz + dz * dx);
float ISECT_COST = INTERSECT_COST / area;
// setup counts for each axis
int[] nl = { 0, 0, 0 };
int[] nr = { task.numObjects, task.numObjects, task.numObjects };
// setup bounds for each axis
float[] dp = { dy * dz, dz * dx, dx * dy };
float[] ds = { dy + dz, dz + dx, dx + dy };
float[] nodeMin = { minx, miny, minz };
float[] nodeMax = { maxx, maxy, maxz };
// search for best cost
int nSplits = task.n;
long[] splits = task.splits;
byte[] lrtable = task.leftRightTable;
for (int i = 0; i < nSplits; )
{
// extract current split
long ptr = splits[i];
float split = unpackSplit(ptr);
int axis = unpackAxis(ptr);
// mark current position
int currentOffset = i;
// count number of primitives start/stopping/lying on the
// current plane
int pClosed = 0, pPlanar = 0, pOpened = 0;
long ptrMasked = (long)((ulong)ptr & (~((ulong)TYPE_MASK) & 0xFFFFFFFFF0000000L));
long ptrClosed = ptrMasked | CLOSED;
long ptrPlanar = ptrMasked | PLANAR;
long ptrOpened = ptrMasked | OPENED;
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrClosed)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pClosed++;
i++;
}
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrPlanar)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pPlanar++;
i++;
}
while (i < nSplits && ((ulong)splits[i] & 0xFFFFFFFFF0000000L) == (ulong)ptrOpened)
{
int obj = unpackObject(splits[i]);
lrtable[(uint)obj >> 2] = 0;//>>>
pOpened++;
i++;
}
// now we have summed all contributions from this plane
nr[axis] -= pPlanar + pClosed;
// compute cost
if (split >= nodeMin[axis] && split <= nodeMax[axis])
{
// left and right surface area (factor of 2 ommitted)
float dl = split - nodeMin[axis];
float dr = nodeMax[axis] - split;
float lp = dp[axis] + dl * ds[axis];
float rp = dp[axis] + dr * ds[axis];
// planar prims go to smallest cell always
bool planarLeft = dl < dr;
int numLeft = nl[axis] + (planarLeft ? pPlanar : 0);
int numRight = nr[axis] + (planarLeft ? 0 : pPlanar);
float eb = ((numLeft == 0 && dl > 0) || (numRight == 0 && dr > 0)) ? EMPTY_BONUS : 0;
float cost = TRAVERSAL_COST + ISECT_COST * (1 - eb) * (lp * numLeft + rp * numRight);
if (cost < bestCost)
{
bestCost = cost;
bestAxis = axis;
bestSplit = split;
bestOffsetStart = currentOffset;
bestOffsetEnd = i;
bnl = numLeft;
bnr = numRight;
bestPlanarLeft = planarLeft;
}
}
// move objects left
nl[axis] += pOpened + pPlanar;
}
// debug check for correctness of the scan
for (int axis = 0; axis < 3; axis++)
{
int numLeft = nl[axis];
int numRight = nr[axis];
if (numLeft != task.numObjects || numRight != 0)
UI.printError(UI.Module.ACCEL, "Didn't scan full range of objects @depth={0}. Left overs for axis {1}: [L: {2}] [R: {3}]", depth, axis, numLeft, numRight);
}
// found best split?
if (bestAxis != -1)
{
// allocate space for child nodes
BuildTask taskL = new BuildTask(bnl, task);
BuildTask taskR = new BuildTask(bnr, task);
int lk = 0, rk = 0;
for (int i = 0; i < bestOffsetStart; i++)
{
long ptr = splits[i];
if (unpackAxis(ptr) == bestAxis)
{
if (unpackSplitType(ptr) != CLOSED)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(1 << ((obj & 3) << 1));//>>>
lk++;
}
}
}
for (int i = bestOffsetStart; i < bestOffsetEnd; i++)
{
long ptr = splits[i];
Debug.Assert(unpackAxis(ptr) == bestAxis);
if (unpackSplitType(ptr) == PLANAR)
{
if (bestPlanarLeft)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(1 << ((obj & 3) << 1));//>>>
lk++;
}
else
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(2 << ((obj & 3) << 1));//>>>
rk++;
}
}
}
for (int i = bestOffsetEnd; i < nSplits; i++)
{
long ptr = splits[i];
if (unpackAxis(ptr) == bestAxis)
{
if (unpackSplitType(ptr) != OPENED)
{
int obj = unpackObject(ptr);
lrtable[(uint)obj >> 2] |= (byte)(2 << ((obj & 3) << 1));//>>>
rk++;
}
}
}
// output new splits while maintaining order
long[] splitsL = taskL.splits;
long[] splitsR = taskR.splits;
int nsl = 0, nsr = 0;
for (int i = 0; i < nSplits; i++)
{
long ptr = splits[i];
int obj = unpackObject(ptr);
int idx = (int)((uint)obj >> 2);//>>>
int mask = 1 << ((obj & 3) << 1);
if ((lrtable[idx] & mask) != 0)
{
splitsL[nsl] = ptr;
nsl++;
}
if ((lrtable[idx] & (mask << 1)) != 0)
{
splitsR[nsr] = ptr;
nsr++;
}
}
taskL.n = nsl;
taskR.n = nsr;
// free more memory
task.splits = splits = splitsL = splitsR = null;
task = null;
// allocate child nodes
int nextOffset = tempTree.Count;
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
tempTree.Add(0);
// create current node
tempTree[offset + 0] = (bestAxis << 30) | nextOffset;
tempTree[offset + 1] = ByteUtil.floatToRawIntBits(bestSplit);
// recurse for child nodes - free object arrays after each step
stats.updateInner();
switch (bestAxis)
{
case 0:
buildTree(minx, bestSplit, miny, maxy, minz, maxz, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(bestSplit, maxx, miny, maxy, minz, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
case 1:
buildTree(minx, maxx, miny, bestSplit, minz, maxz, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(minx, maxx, bestSplit, maxy, minz, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
case 2:
buildTree(minx, maxx, miny, maxy, minz, bestSplit, taskL, depth + 1, tempTree, nextOffset, tempList, stats);
taskL = null;
buildTree(minx, maxx, miny, maxy, bestSplit, maxz, taskR, depth + 1, tempTree, nextOffset + 2, tempList, stats);
taskR = null;
return;
default:
Debug.Assert(false);
break;
}
}
}
// create leaf node
int listOffset = tempList.Count;
int n = 0;
for (int i = 0; i < task.n; i++)
{
long ptr = task.splits[i];
if (unpackAxis(ptr) == 0 && unpackSplitType(ptr) != CLOSED)
{
tempList.Add(unpackObject(ptr));
n++;
}
}
stats.updateLeaf(depth, n);
if (n != task.numObjects)
UI.printError(UI.Module.ACCEL, "Error creating leaf node - expecting {0} found {1}", task.numObjects, n);
tempTree[offset + 0] = (3 << 30) | listOffset;
tempTree[offset + 1] = task.numObjects;
// free some memory
task.splits = null;
}
