void TopazSample::initBuffer(GLenum target, GLuint& buffer, GLuint64& buffer64,
GLsizeiptr size, const GLvoid* data, bool ismutable)
{
if (buffer)
{
glDeleteBuffers(1, &buffer);
}
glGenBuffers(1, &buffer);
if (!ismutable)
{
glNamedBufferStorageEXT(buffer, size, data, 0);
}
else
{
glBindBuffer(target, buffer);
glBufferData(target, size, data, GL_DYNAMIC_DRAW);
glBindBuffer(target, 0);
}
if (bindlessVboUbo)
{
glGetNamedBufferParameterui64vNV(buffer, GL_BUFFER_GPU_ADDRESS_NV, &buffer64);
glMakeNamedBufferResidentNV(buffer, GL_READ_ONLY);
}
}
uint64_t meshVBO::getBufferAddress( vboAccess acc )
{
uint64_t address = 0;
glMakeNamedBufferResidentNV( vboID, vboAccessToGl( acc ) );
glGetNamedBufferParameterui64vNV( vboID, GL_BUFFER_GPU_ADDRESS_NV, &address );
return address;
}
JNIEXPORT void JNICALL Java_org_lwjgl_opengl_NVShaderBufferLoad_nglGetNamedBufferParameterui64vNV__IIJ(JNIEnv *__env, jclass clazz, jint buffer, jint pname, jlong paramsAddress) {
glGetNamedBufferParameterui64vNVPROC glGetNamedBufferParameterui64vNV = (glGetNamedBufferParameterui64vNVPROC)tlsGetFunction(2106);
intptr_t params = (intptr_t)paramsAddress;
UNUSED_PARAM(clazz)
glGetNamedBufferParameterui64vNV(buffer, pname, params);
}
bool CadScene::loadCSF( const char* filename, int clones, int cloneaxis)
{
CSFile* csf;
CSFileMemoryPTR mem = CSFileMemory_new();
if (CSFile_loadExt(&csf,filename,mem) != CADSCENEFILE_NOERROR || !(csf->fileFlags & CADSCENEFILE_FLAG_UNIQUENODES)){
CSFileMemory_delete(mem);
return false;
}
int copies = clones + 1;
CSFile_transform(csf);
srand(234525);
// materials
m_materials.resize( csf->numMaterials );
for (int n = 0; n < csf->numMaterials; n++ )
{
CSFMaterial* csfmaterial = &csf->materials[n];
Material& material = m_materials[n];
for (int i = 0; i < 2; i++){
material.sides[i].ambient = randomVector(0.0f,0.1f);
material.sides[i].diffuse = nv_math::vec4f(csf->materials[n].color) + randomVector(0.0f,0.07f);
material.sides[i].specular = randomVector(0.25f,0.55f);
material.sides[i].emissive = randomVector(0.0f,0.05f);
}
}
glGenBuffers(1,&m_materialsGL);
glNamedBufferStorageEXT(m_materialsGL, sizeof(Material) * m_materials.size(), &m_materials[0], 0);
//glMapNamedBufferRange(m_materialsGL, 0, sizeof(Material) * m_materials.size(), GL_MAP_PERSISTENT_BIT | GL_MAP_WRITE_BIT);
// geometry
int numGeoms = csf->numGeometries;
m_geometry.resize( csf->numGeometries * copies );
m_geometryBboxes.resize( csf->numGeometries * copies );
for (int n = 0; n < csf->numGeometries; n++ )
{
CSFGeometry* csfgeom = &csf->geometries[n];
Geometry& geom = m_geometry[n];
geom.cloneIdx = -1;
geom.numVertices = csfgeom->numVertices;
geom.numIndexSolid = csfgeom->numIndexSolid;
geom.numIndexWire = csfgeom->numIndexWire;
std::vector<Vertex> vertices( csfgeom->numVertices );
for (int i = 0; i < csfgeom->numVertices; i++){
vertices[i].position[0] = csfgeom->vertex[3*i + 0];
vertices[i].position[1] = csfgeom->vertex[3*i + 1];
vertices[i].position[2] = csfgeom->vertex[3*i + 2];
vertices[i].position[3] = 1.0f;
if (csfgeom->normal){
vertices[i].normal[0] = csfgeom->normal[3*i + 0];
vertices[i].normal[1] = csfgeom->normal[3*i + 1];
vertices[i].normal[2] = csfgeom->normal[3*i + 2];
vertices[i].normal[3] = 0.0f;
}
else{
vertices[i].normal = normalize(nv_math::vec3f(vertices[i].position));
}
m_geometryBboxes[n].merge( vertices[i].position );
}
geom.vboSize = sizeof(Vertex) * vertices.size();
glGenBuffers(1,&geom.vboGL);
glNamedBufferStorageEXT(geom.vboGL,geom.vboSize, &vertices[0], 0);
std::vector<GLuint> indices(csfgeom->numIndexSolid + csfgeom->numIndexWire);
memcpy(&indices[0],csfgeom->indexSolid, sizeof(GLuint) * csfgeom->numIndexSolid);
if (csfgeom->indexWire){
memcpy(&indices[csfgeom->numIndexSolid],csfgeom->indexWire, sizeof(GLuint) * csfgeom->numIndexWire);
}
geom.iboSize = sizeof(GLuint) * indices.size();
glGenBuffers(1,&geom.iboGL);
glNamedBufferStorageEXT(geom.iboGL, geom.iboSize, &indices[0], 0);
if (GLEW_NV_vertex_buffer_unified_memory){
glGetNamedBufferParameterui64vNV(geom.vboGL, GL_BUFFER_GPU_ADDRESS_NV, &geom.vboADDR);
glMakeNamedBufferResidentNV(geom.vboGL, GL_READ_ONLY);
glGetNamedBufferParameterui64vNV(geom.iboGL, GL_BUFFER_GPU_ADDRESS_NV, &geom.iboADDR);
glMakeNamedBufferResidentNV(geom.iboGL, GL_READ_ONLY);
}
geom.parts.resize( csfgeom->numParts );
size_t offsetSolid = 0;
size_t offsetWire = csfgeom->numIndexSolid * sizeof(GLuint);
for (int i = 0; i < csfgeom->numParts; i++){
geom.parts[i].indexWire.count = csfgeom->parts[i].indexWire;
geom.parts[i].indexSolid.count = csfgeom->parts[i].indexSolid;
geom.parts[i].indexWire.offset = offsetWire;
geom.parts[i].indexSolid.offset = offsetSolid;
offsetWire += csfgeom->parts[i].indexWire * sizeof(GLuint);
offsetSolid += csfgeom->parts[i].indexSolid * sizeof(GLuint);
}
}
for (int c = 1; c <= clones; c++){
for (int n = 0; n < numGeoms; n++ )
{
m_geometryBboxes[n + numGeoms * c] = m_geometryBboxes[n];
const Geometry& geomorig = m_geometry[n];
Geometry& geom = m_geometry[n + numGeoms * c];
geom = geomorig;
#if 1
geom.cloneIdx = n;
#else
geom.cloneIdx = -1;
glGenBuffers(1,&geom.vboGL);
glNamedBufferStorageEXT(geom.vboGL,geom.vboSize, 0, 0);
glGenBuffers(1,&geom.iboGL);
glNamedBufferStorageEXT(geom.iboGL,geom.iboSize, 0, 0);
if (GLEW_NV_vertex_buffer_unified_memory){
glGetNamedBufferParameterui64vNV(geom.vboGL, GL_BUFFER_GPU_ADDRESS_NV, &geom.vboADDR);
glMakeNamedBufferResidentNV(geom.vboGL, GL_READ_ONLY);
glGetNamedBufferParameterui64vNV(geom.iboGL, GL_BUFFER_GPU_ADDRESS_NV, &geom.iboADDR);
glMakeNamedBufferResidentNV(geom.iboGL, GL_READ_ONLY);
}
glNamedCopyBufferSubDataEXT(geomorig.vboGL, geom.vboGL, 0, 0, geom.vboSize);
glNamedCopyBufferSubDataEXT(geomorig.iboGL, geom.iboGL, 0, 0, geom.iboSize);
#endif
}
}
glGenBuffers(1,&m_geometryBboxesGL);
glNamedBufferStorageEXT(m_geometryBboxesGL,sizeof(BBox) * m_geometryBboxes.size(), &m_geometryBboxes[0], 0);
glGenTextures(1, &m_geometryBboxesTexGL);
glTextureBufferEXT(m_geometryBboxesTexGL, GL_TEXTURE_BUFFER, GL_RGBA32F, m_geometryBboxesGL);
// nodes
int numObjects = 0;
m_matrices.resize( csf->numNodes * copies );
for (int n = 0; n < csf->numNodes; n++){
CSFNode* csfnode = &csf->nodes[n];
memcpy( m_matrices[n].objectMatrix.get_value(), csfnode->objectTM, sizeof(float)*16 );
memcpy( m_matrices[n].worldMatrix.get_value(), csfnode->worldTM, sizeof(float)*16 );
m_matrices[n].objectMatrixIT = nv_math::transpose( nv_math::invert(m_matrices[n].objectMatrix) );
m_matrices[n].worldMatrixIT = nv_math::transpose( nv_math::invert(m_matrices[n].worldMatrix) );
if (csfnode->geometryIDX < 0) continue;
numObjects++;
}
// objects
m_objects.resize( numObjects * copies );
m_objectAssigns.resize( numObjects * copies );
numObjects = 0;
for (int n = 0; n < csf->numNodes; n++){
CSFNode* csfnode = &csf->nodes[n];
if (csfnode->geometryIDX < 0) continue;
Object& object = m_objects[numObjects];
object.matrixIndex = n;
object.geometryIndex = csfnode->geometryIDX;
m_objectAssigns[numObjects] = nv_math::vec2i( object.matrixIndex, object.geometryIndex );
object.parts.resize( csfnode->numParts );
for (int i = 0; i < csfnode->numParts; i++){
object.parts[i].active = 1;
object.parts[i].matrixIndex = csfnode->parts[i].nodeIDX < 0 ? object.matrixIndex : csfnode->parts[i].nodeIDX;
object.parts[i].materialIndex = csfnode->parts[i].materialIDX;
}
BBox bbox = m_geometryBboxes[object.geometryIndex].transformed( m_matrices[n].worldMatrix );
m_bbox.merge( bbox );
updateObjectDrawCache(object);
numObjects++;
}
// compute clone move delta based on m_bbox;
nv_math::vec4f dim = m_bbox.max - m_bbox.min;
int sq = 1;
int numAxis = 0;
for (int i = 0; i < 3; i++){
numAxis += (cloneaxis & (1<<i)) ? 1 : 0;
}
assert(numAxis);
switch (numAxis)
{
case 1:
sq = copies;
break;
case 2:
while (sq * sq < copies){
sq++;
}
break;
case 3:
while (sq * sq * sq < copies){
sq++;
}
break;
}
for (int c = 1; c <= clones; c++){
int numNodes = csf->numNodes;
nv_math::vec4f shift = dim * 1.05f;
float u = 0;
float v = 0;
float w = 0;
switch (numAxis)
{
case 1:
u = float(c);
break;
case 2:
u = float(c % sq);
v = float(c / sq);
break;
case 3:
u = float(c % sq);
v = float((c / sq) % sq);
w = float( c / (sq*sq));
break;
}
float use = u;
if (cloneaxis & (1<<0)){
shift.x *= -use;
if (numAxis > 1 ) use = v;
}
else {
shift.x = 0;
}
if (cloneaxis & (1<<1)){
shift.y *= use;
if (numAxis > 2 ) use = w;
else if (numAxis > 1 ) use = v;
}
else {
shift.y = 0;
}
if (cloneaxis & (1<<2)){
shift.z *= -use;
}
else {
shift.z = 0;
}
shift.w = 0;
// move all world matrices
for (int n = 0; n < numNodes; n++ )
{
MatrixNode &node = m_matrices[n + numNodes * c];
MatrixNode &nodeOrig = m_matrices[n];
node = nodeOrig;
node.worldMatrix.set_col(3,node.worldMatrix.col(3) + shift);
node.worldMatrixIT = nv_math::transpose( nv_math::invert(node.worldMatrix) );
}
{
// patch object matrix of root
MatrixNode &node = m_matrices[csf->rootIDX + numNodes * c];
node.objectMatrix.set_col(3,node.objectMatrix.col(3) + shift);
node.objectMatrixIT = nv_math::transpose( nv_math::invert(node.objectMatrix) );
}
// clone objects
for (int n = 0; n < numObjects; n++ )
{
const Object& objectorig = m_objects[n];
Object& object = m_objects[ n + numObjects * c];
object = objectorig;
object.geometryIndex += c * numGeoms;
object.matrixIndex += c * numNodes;
for (size_t i = 0; i < object.parts.size(); i++){
object.parts[i].matrixIndex += c * numNodes;
}
for (size_t i = 0; i < object.cacheSolid.state.size(); i++){
object.cacheSolid.state[i].matrixIndex += c * numNodes;
}
for (size_t i = 0; i < object.cacheWire.state.size(); i++){
object.cacheWire.state[i].matrixIndex += c * numNodes;
}
m_objectAssigns[n + numObjects * c] = nv_math::vec2i( object.matrixIndex, object.geometryIndex );
}
}
glGenBuffers(1,&m_matricesGL);
glNamedBufferStorageEXT(m_matricesGL, sizeof(MatrixNode) * m_matrices.size(), &m_matrices[0], 0);
//glMapNamedBufferRange(m_matricesGL, 0, sizeof(MatrixNode) * m_matrices.size(), GL_MAP_PERSISTENT_BIT | GL_MAP_WRITE_BIT);
glGenTextures(1,&m_matricesTexGL);
glTextureBufferEXT(m_matricesTexGL, GL_TEXTURE_BUFFER, GL_RGBA32F, m_matricesGL);
glGenBuffers(1,&m_objectAssignsGL);
glNamedBufferStorageEXT(m_objectAssignsGL,sizeof(nv_math::vec2i) * m_objectAssigns.size(), &m_objectAssigns[0], 0);
if (GLEW_NV_vertex_buffer_unified_memory){
glGetNamedBufferParameterui64vNV(m_materialsGL, GL_BUFFER_GPU_ADDRESS_NV, &m_materialsADDR);
glMakeNamedBufferResidentNV(m_materialsGL, GL_READ_ONLY);
glGetNamedBufferParameterui64vNV(m_matricesGL, GL_BUFFER_GPU_ADDRESS_NV, &m_matricesADDR);
glMakeNamedBufferResidentNV(m_matricesGL, GL_READ_ONLY);
if (GLEW_NV_bindless_texture){
m_matricesTexGLADDR = glGetTextureHandleNV(m_matricesTexGL);
glMakeTextureHandleResidentNV(m_matricesTexGLADDR);
}
}
m_nodeTree.create(copies * csf->numNodes);
for (int i = 0; i < copies; i++){
int cloneoffset = (csf->numNodes) * i;
int root = csf->rootIDX+cloneoffset;
recursiveHierarchy(m_nodeTree,csf,csf->rootIDX,cloneoffset);
m_nodeTree.setNodeParent( (NodeTree::nodeID)root, m_nodeTree.getTreeRoot() );
m_nodeTree.addToTree( (NodeTree::nodeID)root );
}
glGenBuffers(1,&m_parentIDsGL);
glNamedBufferStorageEXT(m_parentIDsGL, m_nodeTree.getTreeCompactNodes().size() * sizeof(GLuint), &m_nodeTree.getTreeCompactNodes()[0], 0);
glGenBuffers(1,&m_matricesOrigGL);
glNamedBufferStorageEXT(m_matricesOrigGL, sizeof(MatrixNode) * m_matrices.size(), &m_matrices[0], 0);
glGenTextures(1,&m_matricesOrigTexGL);
glTextureBufferEXT(m_matricesOrigTexGL, GL_TEXTURE_BUFFER, GL_RGBA32F, m_matricesOrigGL);
CSFileMemory_delete(mem);
return true;
}
