void DumpFaceInfo(const Ptex::FaceInfo& f)
{
Ptex::Res res = f.res;
std::cout << " res: " << int(res.ulog2) << ' ' << int(res.vlog2)
<< " (" << res.u() << " x " << res.v() << ")"
<< " adjface: "
<< f.adjfaces[0] << ' '
<< f.adjfaces[1] << ' '
<< f.adjfaces[2] << ' '
<< f.adjfaces[3]
<< " adjedge: "
<< f.adjedge(0) << ' '
<< f.adjedge(1) << ' '
<< f.adjedge(2) << ' '
<< f.adjedge(3)
<< " flags:";
// output flag names
if (f.flags == 0) std::cout << " (none)";
else {
if (f.isSubface()) std::cout << " subface";
if (f.isConstant()) std::cout << " constant";
if (f.isNeighborhoodConstant()) std::cout << " nbconstant";
if (f.hasEdits()) std::cout << " hasedits";
}
std::cout << std::endl;
}
void DumpData(PtexTexture* r, int faceid, bool dumpall)
{
int levels = 1;
if (dumpall) {
PtexReader* R = static_cast<PtexReader*> (r);
if (R) levels = R->header().nlevels;
}
const Ptex::FaceInfo& f = r->getFaceInfo(faceid);
int nchan = r->numChannels();
float* pixel = (float*) malloc(sizeof(float)*nchan);
Ptex::Res res = f.res;
while (levels && res.ulog2 >= 1 && res.vlog2 >= 1) {
int ures = res.u(), vres = res.v();
std::cout << " data (" << ures << " x " << vres << ")";
if (f.isConstant()) { ures = vres = 1; }
bool isconst = (ures == 1 && vres == 1);
if (isconst) std::cout << ", const: ";
else std::cout << ":";
for (int vi = 0; vi < vres; vi++) {
for (int ui = 0; ui < ures; ui++) {
if (!isconst) std::cout << "\n (" << ui << ", " << vi << "): ";
r->getPixel(faceid, ui, vi, pixel, 0, nchan, res);
for (int c=0; c < nchan; c++) {
printf(" %.3f", pixel[c]);
}
}
}
std::cout << std::endl;
res.ulog2--;
res.vlog2--;
levels--;
}
free(pixel);
}
void PtexSeparableFilter::apply(PtexSeparableKernel& k, int faceid, const Ptex::FaceInfo& f)
{
assert(k.u >= 0 && k.u + k.uw <= k.res.u());
assert(k.v >= 0 && k.v + k.vw <= k.res.v());
if (k.uw <= 0 || k.vw <= 0) return;
// downres kernel if needed
while (k.res.u() > f.res.u()) k.downresU();
while (k.res.v() > f.res.v()) k.downresV();
// get face data, and apply
PtexPtr<PtexFaceData> dh ( _tx->getData(faceid, k.res) );
if (!dh) return;
if (dh->isConstant()) {
k.applyConst(_result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan);
}
else if (dh->isTiled()) {
Ptex::Res tileres = dh->tileRes();
PtexSeparableKernel kt;
kt.res = tileres;
int tileresu = tileres.u();
int tileresv = tileres.v();
int ntilesu = k.res.u() / tileresu;
for (int v = k.v, vw = k.vw; vw > 0; vw -= kt.vw, v += kt.vw) {
int tilev = v / tileresv;
kt.v = v % tileresv;
kt.vw = PtexUtils::min(vw, tileresv - kt.v);
kt.kv = k.kv + v - k.v;
for (int u = k.u, uw = k.uw; uw > 0; uw -= kt.uw, u += kt.uw) {
int tileu = u / tileresu;
kt.u = u % tileresu;
kt.uw = PtexUtils::min(uw, tileresu - kt.u);
kt.ku = k.ku + u - k.u;
PtexPtr<PtexFaceData> th ( dh->getTile(tilev * ntilesu + tileu) );
if (th) {
if (th->isConstant())
kt.applyConst(_result, (char*)th->getData()+_firstChanOffset, _dt, _nchan);
else
kt.apply(_result, (char*)th->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
}
}
}
}
else {
k.apply(_result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
}
}
void DumpTiling(PtexFaceData* dh)
{
std::cout << " tiling: ";
if (dh->isTiled()) {
Ptex::Res res = dh->tileRes();
std::cout << "ntiles = " << dh->res().ntiles(res)
<< ", res = "
<< int(res.ulog2) << ' ' << int(res.vlog2)
<< " (" << res.u() << " x " << res.v() << ")\n";
}
else if (dh->isConstant()) {
std::cout << " (constant)" << std::endl;
}
else {
std::cout << " (untiled)" << std::endl;
}
}
void DumpData(Ptex::DataType dt, int nchan, PtexFaceData* dh, std::string prefix)
{
void* dpixel = malloc(Ptex::DataSize(dt)*nchan);
float* pixel = (float*) malloc(sizeof(float)*nchan);
uint8_t* cpixel = (uint8_t*) malloc(sizeof(uint8_t)*nchan);
Ptex::Res res = dh->res();
printf("%sdata (%d x %d)", prefix.c_str(), res.u(), res.v());
if (dh->isTiled()) {
Ptex::Res tileres = dh->tileRes();
printf(", tiled (%d x %d):\n", tileres.u(), tileres.v());
int n = res.ntiles(tileres);
for (int i = 0; i < n; i++) {
PtexFaceData* t = dh->getTile(i);
std::cout << prefix << " tile " << i;
if (!t) {
std::cout << " NULL!" << std::endl;
} else {
DumpData(dt, nchan, t, prefix + " ");
t->release();
}
}
} else {
int ures, vres;
if (dh->isConstant()) { ures = vres = 1; std::cout << ", const: "; }
else { ures = res.u(); vres = res.v(); std::cout << ":\n"; }
int vimax = vres;// if (vimax > 16) vimax = 16;
for (int vi = 0; vi < vimax; vi++) {
if (vi == 8 && vres > 16) { vi = vres-8; std::cout << prefix << " ..." << std::endl; }
std::cout << prefix << " ";
int uimax = ures;// if (uimax > 16) uimax = 16;
for (int ui = 0; ui < uimax; ui++) {
if (ui == 8 && ures > 16) { ui = ures-8; std::cout << "... "; }
dh->getPixel(ui, vi, dpixel);
Ptex::ConvertToFloat(pixel, dpixel, dt, nchan);
Ptex::ConvertFromFloat(cpixel, pixel, Ptex::dt_uint8, nchan);
for (int c=0; c < nchan; c++) {
printf("%02x", cpixel[c]);
}
printf(" ");
}
if (uimax != ures) printf(" ...");
printf("\n");
}
if (vimax != vres) std::cout << prefix << " ..." << std::endl;
}
free(cpixel);
free(pixel);
free(dpixel);
}
void PtexTriangleFilter::applyIter(PtexTriangleKernelIter& k, PtexFaceData* dh)
{
if (dh->isConstant()) {
k.applyConst(_result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan);
_weight += k.weight;
}
else if (dh->isTiled()) {
Ptex::Res tileres = dh->tileRes();
PtexTriangleKernelIter kt = k;
int tileresu = tileres.u();
int tileresv = tileres.v();
kt.rowlen = tileresu;
int ntilesu = k.rowlen / kt.rowlen;
int wOffsetBase = k.rowlen - tileresu;
for (int tilev = k.v1 / tileresv, tilevEnd = (k.v2-1) / tileresv; tilev <= tilevEnd; tilev++) {
int vOffset = tilev * tileresv;
kt.v = k.v - (float)vOffset;
kt.v1 = PtexUtils::max(0, k.v1 - vOffset);
kt.v2 = PtexUtils::min(k.v2 - vOffset, tileresv);
for (int tileu = k.u1 / tileresu, tileuEnd = (k.u2-1) / tileresu; tileu <= tileuEnd; tileu++) {
int uOffset = tileu * tileresu;
int wOffset = wOffsetBase - uOffset - vOffset;
kt.u = k.u - (float)uOffset;
kt.u1 = PtexUtils::max(0, k.u1 - uOffset);
kt.u2 = PtexUtils::min(k.u2 - uOffset, tileresu);
kt.w1 = k.w1 - wOffset;
kt.w2 = k.w2 - wOffset;
PtexPtr<PtexFaceData> th ( dh->getTile(tilev * ntilesu + tileu) );
if (th) {
kt.weight = 0;
if (th->isConstant())
kt.applyConst(_result, (char*)th->getData()+_firstChanOffset, _dt, _nchan);
else
kt.apply(_result, (char*)th->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
_weight += kt.weight;
}
}
}
}
else {
k.apply(_result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
_weight += k.weight;
}
}
void IBLWidget::loadIBL( const char* filename )
{
printf( "opening %s... ", filename );
// try and load it
Ptex::String error;
PtexTexture* tx = PtexTexture::open(filename, error);
if (!tx) {
printf( "failed\n");
return;
}
CKGL();
Ptex::DataType dataType = tx->dataType();
int numChannels = tx->numChannels();
int numFaces=tx->numFaces();
int faceWidth=0, faceHeight=0;
if( dataType != Ptex::dt_float || numChannels != 3 || numFaces != 6 )
{
printf( "not the right kind\n" );
return;
}
for( int i = 0; i < numFaces; i++ )
{
int face = i;
Ptex::Res res = tx->getFaceInfo(i).res;
if( i == 0 )
{
faceWidth = res.u();
faceHeight = res.v();
// printf( "size: %dx%d (%dx%d)\n", faceWidth, faceHeight, faceWidth*6, faceHeight );
envTex.create( faceWidth*6, faceHeight );
}
if( faceWidth != res.u() || faceHeight != res.v() )
{
printf( "error loading ptex file\n" );
return;
}
float* faceData = (float*)malloc( faceWidth*faceHeight*numChannels*sizeof(float) );
tx->getData( i, faceData, 0 );
// copy the data into the envmap texture
for( int j = 0; j < faceHeight * faceWidth; j++ )
{
color3 c( faceData[j*3+0], faceData[j*3+1], faceData[j*3+2] );
envTex.setPixel( faceWidth*face + j % faceWidth, j / faceWidth, c );
}
free( faceData );
}
tx->release();
printf( "success\n");
// allocate texture names (if we haven't before)
if( envTexID == 0 ) {
glf->glGenTextures( 1, &envTexID );
glf->glGenTextures( 1, &probTexID );
glf->glGenTextures( 1, &marginalProbTexID );
}
CKGL();
// now that the envmap tex is loaded, compute the sampling data
computeEnvMapSamplingData();
createGLSamplingTextures();
CKGL();
glf->glGenTextures(1, &envTexID);
glf->glBindTexture( GL_TEXTURE_CUBE_MAP, envTexID );
glf->glTexParameteri(GL_TEXTURE_CUBE_MAP, GL_TEXTURE_MIN_FILTER, GL_LINEAR_MIPMAP_NEAREST);
BitmapContainer<color3> flip;
flip.create(envTex.w, envTex.h);//get face flipped to match GL thinking!
for (int y=0; y < envTex.h; y++){
color3* in = &envTex.data[y*envTex.w];
color3* out = &flip.data[(envTex.h-y-1)*envTex.w];
for (int x=0; x < envTex.w; x++)
out[x] = in[x];
}
BitmapContainer<color3> tmp;
tmp.create(envTex.h, envTex.h);
CKGL();
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*0, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_POSITIVE_X , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*1, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_NEGATIVE_X , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*2, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_POSITIVE_Y , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*3, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_NEGATIVE_Y , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*4, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_POSITIVE_Z , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
CKGL();
for (int y=0; y < tmp.h; y++)
for (int x=0; x < tmp.w; x++)
tmp.setPixel(x, y,flip.getPixel(x+tmp.w*5, y));
glf->glTexImage2D( GL_TEXTURE_CUBE_MAP_NEGATIVE_Z , 0,GL_R11F_G11F_B10F, tmp.w, tmp.h, 0, GL_RGB, GL_FLOAT, tmp.getPtr() );
CKGL();
glf->glGenerateMipmap(GL_TEXTURE_CUBE_MAP);
glf->glBindTexture( GL_TEXTURE_CUBE_MAP, 0 );
CKGL();
}
OBJScene::Texture *loadPtexTexture(const FileName& filename)
{
#if defined(USE_PTEX)
std::string fn = filename.str();
Ptex::String error;
std::cout << "opening " << fn << " ... " << std::flush;
PtexTexture* tex = PtexTexture::open(fn.c_str(),error);
if (!tex) {
std::cout << "[FAILED]" << std::endl;
THROW_RUNTIME_ERROR("cannot open ptex file: "+fn);
}
PtexMetaData *metadata = tex->getMetaData();
const int32_t *vertices_per_face = nullptr;
int geom_faces = 0;
metadata->getValue("PtexFaceVertCounts", vertices_per_face, geom_faces);
OBJScene::Texture **face_textures = new OBJScene::Texture *[geom_faces];
for (size_t i=0;i<geom_faces;i++)
face_textures[i] = nullptr;
OBJScene::Texture *texture = new OBJScene::Texture();
texture->width = 0;
texture->height = 0;
texture->format = OBJScene::Texture::PTEX_RGBA8;
texture->faceTextures = geom_faces;
texture->data = face_textures;
texture->width_mask = 0;
texture->height_mask = 0;
int nchan = tex->numChannels();
if (nchan != 3 && nchan != 1)
{
std::cout << "[FAILED]" << std::endl;
THROW_RUNTIME_ERROR(fn+": ptex file with other than 1 or 3 channels found!");
}
if (nchan == 1)
texture->format = OBJScene::Texture::PTEX_FLOAT32;
float px[3];
int ptex_face_id = 0;
for (size_t geom_face_id=0;geom_face_id<geom_faces;geom_face_id++)
{
face_textures[geom_face_id] = nullptr;
const Ptex::FaceInfo &fi = tex->getFaceInfo(ptex_face_id);
int n = vertices_per_face[geom_face_id];
if (n == 4) /* ptex data only for quads */
{
Ptex::Res res = fi.res;
OBJScene::Texture *face_txt = new OBJScene::Texture();
face_txt->width = res.u();
face_txt->height = res.v();
face_txt->width_mask = 0;
face_txt->height_mask = 0;
face_txt->data = nullptr;
face_textures[geom_face_id] = face_txt;
if (nchan == 3) /* rgb color data */
{
face_txt->format = OBJScene::Texture::RGBA8;
face_txt->bytesPerTexel = 4;
unsigned char *data = new unsigned char[face_txt->bytesPerTexel*face_txt->width*face_txt->height];
face_txt->data = data;
for (int vi = 0; vi < face_txt->height; vi++) {
for (int ui = 0; ui < face_txt->width; ui++) {
tex->getPixel(ptex_face_id, ui, vi, px, 0, nchan, res);
data[(vi*face_txt->width+ui)*4+0] = (unsigned char)(px[0]*255.0f);
data[(vi*face_txt->width+ui)*4+1] = (unsigned char)(px[1]*255.0f);
data[(vi*face_txt->width+ui)*4+2] = (unsigned char)(px[2]*255.0f);
}
}
}
else if (nchan == 1) /* displacement data */
{
face_txt->format = OBJScene::Texture::FLOAT32;
face_txt->bytesPerTexel = 4;
float*data = new float[face_txt->width*face_txt->height];
face_txt->data = data;
for (int vi = 0; vi < face_txt->height; vi++) {
for (int ui = 0; ui < face_txt->width; ui++) {
tex->getPixel(ptex_face_id, ui, vi, px, 0, nchan, res);
if (!isfinite(px[0]))
px[0] = 0.0f;
data[vi*face_txt->width+ui] = px[0];
}
}
}
ptex_face_id++;
}
else
ptex_face_id += 3;
}
std::cout << "done" << std::endl << std::flush;
return texture;
#else
return nullptr;
#endif
}
void PtexSeparableFilter::apply(PtexSeparableKernel& k, int faceid, const Ptex::FaceInfo& f)
{
assert(k.u >= 0 && k.u + k.uw <= k.res.u());
assert(k.v >= 0 && k.v + k.vw <= k.res.v());
if (k.uw <= 0 || k.vw <= 0) return;
// downres kernel if needed
while (k.res.u() > f.res.u()) k.downresU();
while (k.res.v() > f.res.v()) k.downresV();
// get face data, and apply
PtexPtr<PtexFaceData> dh ( _tx->getData(faceid, k.res) );
if (!dh) return;
if (dh->isConstant()) {
k.applyConst(_result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan);
return;
}
// allocate temporary result for tanvec mode (if needed)
bool tanvecMode = (_efm == efm_tanvec) && (_nchan >= 2) && (k.rot > 0);
float* result = tanvecMode ? (float*) alloca(sizeof(float)*_nchan) : _result;
if (tanvecMode) memset(result, 0, sizeof(float)*_nchan);
if (dh->isTiled()) {
Ptex::Res tileres = dh->tileRes();
PtexSeparableKernel kt;
kt.res = tileres;
int tileresu = tileres.u();
int tileresv = tileres.v();
int ntilesu = k.res.u() / tileresu;
for (int v = k.v, vw = k.vw; vw > 0; vw -= kt.vw, v += kt.vw) {
int tilev = v / tileresv;
kt.v = v % tileresv;
kt.vw = PtexUtils::min(vw, tileresv - kt.v);
kt.kv = k.kv + v - k.v;
for (int u = k.u, uw = k.uw; uw > 0; uw -= kt.uw, u += kt.uw) {
int tileu = u / tileresu;
kt.u = u % tileresu;
kt.uw = PtexUtils::min(uw, tileresu - kt.u);
kt.ku = k.ku + u - k.u;
PtexPtr<PtexFaceData> th ( dh->getTile(tilev * ntilesu + tileu) );
if (th) {
if (th->isConstant())
kt.applyConst(result, (char*)th->getData()+_firstChanOffset, _dt, _nchan);
else
kt.apply(result, (char*)th->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
}
}
}
}
else {
k.apply(result, (char*)dh->getData()+_firstChanOffset, _dt, _nchan, _ntxchan);
}
if (tanvecMode) {
// rotate tangent-space vector data and update main result
switch (k.rot) {
case 0: // rot==0 included for completeness, but tanvecMode should be false in this case
_result[0] += result[0];
_result[1] += result[1];
break;
case 1:
_result[0] -= result[1];
_result[1] += result[0];
break;
case 2:
_result[0] -= result[0];
_result[1] -= result[1];
break;
case 3:
_result[0] += result[1];
_result[1] -= result[0];
break;
}
for (int i = 2; i < _nchan; i++) _result[i] += result[i];
}
}
