std::unique_ptr<bsp_tree_node> GenerateTreeRecursion(std::vector<pcs_polygon> &polygons, std::vector<int>&contained)
{
PCS_Model::BSP_CUR_DEPTH++;
if(PCS_Model::BSP_MAX_DEPTH < PCS_Model::BSP_CUR_DEPTH)
PCS_Model::BSP_MAX_DEPTH = PCS_Model::BSP_CUR_DEPTH;
if (PCS_Model::BSP_CUR_DEPTH > 500)
{
PCS_Model::BSP_COMPILE_ERROR = true;
return std::unique_ptr<bsp_tree_node>((bsp_tree_node*)NULL); //WHOA wtf infinite recursion!
}
std::unique_ptr<bsp_tree_node> node(new bsp_tree_node);
MakeBound(node->bound_max, node->bound_min, contained, polygons);
if (contained.size() == 1)
{
//we're a polygon.. w00t
node->Type = POLY;
node->poly_num = contained;
}
else
{
// we're a sortnorm
vector3d cmax = polygons[contained[0]].centeroid;
vector3d cmin = polygons[contained[0]].centeroid;
for (std::vector<int>::iterator it = contained.begin() + 1; it < contained.end(); ++it) {
ExpandBoundingBoxes(cmax, cmin, polygons[*it].centeroid);
}
std::vector<int> front, back;
if (!Bisect(cmax, cmin, node->point, node->normal, polygons, contained, front, back)) {
node->Type = POLY;
node->poly_num = contained;
} else {
node->Type = SPLIT;
node->front = GenerateTreeRecursion(polygons, front);
node->back = GenerateTreeRecursion(polygons, back);
}
}
PCS_Model::BSP_CUR_DEPTH--;
return node;
}
std::unique_ptr<bsp_tree_node> MakeTree(std::vector<pcs_polygon> &polygons, vector3d &Max, vector3d &Min)
{
std::vector<int> polylist(polygons.size());
for (unsigned int i = 0; i < polylist.size(); i++)
{
polylist[i] = i;
}
MakeBound(Max, Min, polylist, polygons);
// we want to give padding so as to not make the outermost bounding regions too tight
Max = Max +vector3d(0.1f, 0.1f, 0.1f);
Min = Min -vector3d(0.1f, 0.1f, 0.1f);
if (polygons.empty()) {
return std::unique_ptr<bsp_tree_node>((bsp_tree_node*)NULL);
}
wxLongLong time = wxGetLocalTimeMillis();
PCS_Model::BSP_CUR_DEPTH = 0;
std::unique_ptr<bsp_tree_node> node = GenerateTreeRecursion(polygons, polylist);
PCS_Model::BSP_TREE_TIME += (wxGetLocalTimeMillis() - time).ToLong();
return node;
}
//==================================================================
SimplePrimitiveBase::CheckSplitRes
SimplePrimitiveBase::CheckForSplit(
const Hider &hider,
int out_bound2d[4],
bool &out_uSplit,
bool &out_vSplit )
{
const Matrix44 &mtxLocalWorld = mpTransform->GetMatrix();
DASSERT( mDiceGridWd == -1 && mDiceGridHe == -1 );
Float3_ testDicePo[ MAX_MAKE_BOUND_OUT_SIZE ];
Bound bound;
bound.Reset();
MakeBound( bound, testDicePo );
float pixelArea = hider.RasterEstimate( bound, mtxLocalWorld, out_bound2d );
if ( pixelArea <= MP_GRID_MAX_SIZE )
{
if ( pixelArea < RI_EPSILON )
{
return CHECKSPLITRES_CULL;
}
float dim = DSqrt( pixelArea );
mDiceGridWd = DMT_SIMD_PADSIZE( (int)ceilf( dim ) );
mDiceGridHe = (int)ceilf( dim );
out_uSplit = false;
out_vSplit = false;
return CHECKSPLITRES_DICE; // will dice
}
else
{
#if 0
SlVec2 locUV[ TEST_DICE_SIMD_BLOCKS ];
// set last item to 0 to be safe when using the AddReduce() later on
locUV[ TEST_DICE_SIMD_BLOCKS - 1 ] = SlVec2( 0.f, 0.f );
fillUVsArray(
locUV,
1.0f / (TEST_DICE_LEN - 1),
1.0f / (TEST_DICE_LEN - 1),
TEST_DICE_LEN,
TEST_DICE_LEN );
//Float3_ avg_dPdu( 0.f, 0.f, 0.f );
//Float3_ avg_dPdv( 0.f, 0.f, 0.f );
SlScalar avg_dPdu( 0.f );
SlScalar avg_dPdv( 0.f );
for (u_int i=0; i < TEST_DICE_SIMD_BLOCKS; ++i)
{
SlVec3 posLS;
SlVec3 dPdu;
SlVec3 dPdv;
Eval_dPdu_dPdv( locUV[ i ], posLS, &dPdu, &dPdv );
avg_dPdu += dPdu.GetLengthSqr();
avg_dPdv += dPdv.GetLengthSqr();
}
// divide by the total number of elements
//avg_dPdu /= (float)TEST_DICE_SIMD_BLOCKS * DMT_SIMD_FLEN;
//avg_dPdv /= (float)TEST_DICE_SIMD_BLOCKS * DMT_SIMD_FLEN;
/*
Float3 avg_dPdu_s(
avg_dPdu.x().AddReduce(), // avg_dPdu.x()[0] + avg_dPdu.x()[1] ...
avg_dPdu.y().AddReduce(),
avg_dPdu.z().AddReduce() );
Float3 avg_dPdv_s(
avg_dPdv.x().AddReduce(), // avg_dPdv.x()[0] + avg_dPdv.x()[1] ...
avg_dPdv.y().AddReduce(),
avg_dPdv.z().AddReduce() );
*/
float lenU = avg_dPdu.AddReduce();
float lenV = avg_dPdv.AddReduce();
if ( lenU < lenV )
{
out_uSplit = false;
out_vSplit = true;
}
else
{
out_uSplit = true;
out_vSplit = false;
}
#else
out_uSplit = true;
out_vSplit = true;
#endif
return CHECKSPLITRES_SPLIT; // will split
}
}
