// static void LLViewerJointMesh::updateGeometry(LLFace *mFace, LLPolyMesh *mMesh) { LLStrider<LLVector3> o_vertices; LLStrider<LLVector3> o_normals; //get vertex and normal striders LLVertexBuffer* buffer = mFace->getVertexBuffer(); buffer->getVertexStrider(o_vertices, 0); buffer->getNormalStrider(o_normals, 0); F32* __restrict vert = o_vertices[0].mV; F32* __restrict norm = o_normals[0].mV; const F32* __restrict weights = mMesh->getWeights(); const LLVector4a* __restrict coords = (LLVector4a*) mMesh->getCoords(); const LLVector4a* __restrict normals = (LLVector4a*) mMesh->getNormals(); U32 offset = mMesh->mFaceVertexOffset*4; vert += offset; norm += offset; for (U32 index = 0; index < mMesh->getNumVertices(); index++) { // equivalent to joint = floorf(weights[index]); S32 joint = _mm_cvtt_ss2si(_mm_load_ss(weights+index)); F32 w = weights[index] - joint; LLMatrix4a gBlendMat; if (w != 0.f) { // blend between matrices and apply gBlendMat.setLerp(gJointMatAligned[joint+0], gJointMatAligned[joint+1], w); LLVector4a res; gBlendMat.affineTransform(coords[index], res); res.store4a(vert+index*4); gBlendMat.rotate(normals[index], res); res.store4a(norm+index*4); } else { // No lerp required in this case. LLVector4a res; gJointMatAligned[joint].affineTransform(coords[index], res); res.store4a(vert+index*4); gJointMatAligned[joint].rotate(normals[index], res); res.store4a(norm+index*4); } } buffer->flush(); }
void create_vertex_buffers_from_model(LLModel* model, std::vector<LLPointer <LLVertexBuffer> >& vertex_buffers) { #if 0 //VECTORIZE THIS ? vertex_buffers.clear(); for (S32 i = 0; i < model->getNumVolumeFaces(); ++i) { const LLVolumeFace &vf = model->getVolumeFace(i); U32 num_vertices = vf.mNumVertices; U32 num_indices = vf.mNumIndices; if (!num_vertices || ! num_indices) { continue; } LLVertexBuffer* vb = new LLVertexBuffer(LLVertexBuffer::MAP_VERTEX | LLVertexBuffer::MAP_NORMAL | LLVertexBuffer::MAP_TEXCOORD0, 0); vb->allocateBuffer(num_vertices, num_indices, TRUE); LLStrider<LLVector3> vertex_strider; LLStrider<LLVector3> normal_strider; LLStrider<LLVector2> tc_strider; LLStrider<U16> index_strider; vb->getVertexStrider(vertex_strider); vb->getNormalStrider(normal_strider); vb->getTexCoord0Strider(tc_strider); vb->getIndexStrider(index_strider); // build vertices and normals for (U32 i = 0; (S32)i < num_vertices; i++) { *(vertex_strider++) = vf.mVertices[i].mPosition; *(tc_strider++) = vf.mVertices[i].mTexCoord; LLVector3 normal = vf.mVertices[i].mNormal; normal.normalize(); *(normal_strider++) = normal; } // build indices for (U32 i = 0; i < num_indices; i++) { *(index_strider++) = vf.mIndices[i]; } vertex_buffers.push_back(vb); } #endif }
// static void LLViewerJointMesh::updateGeometryVectorized(LLFace *face, LLPolyMesh *mesh) { static LLV4Matrix4 sJointMat[32]; LLDynamicArray<LLJointRenderData*>& joint_data = mesh->getReferenceMesh()->mJointRenderData; S32 j, joint_num, joint_end = joint_data.count(); LLV4Vector3 pivot; //upload joint pivots/matrices for(j = joint_num = 0; joint_num < joint_end ; ++joint_num ) { LLSkinJoint *sj; const LLMatrix4 * wm = joint_data[joint_num]->mWorldMatrix; if (NULL == (sj = joint_data[joint_num]->mSkinJoint)) { sj = joint_data[++joint_num]->mSkinJoint; ((LLV4Matrix3)(sJointMat[j] = *wm)).multiply(sj->mRootToParentJointSkinOffset, pivot); sJointMat[j++].translate(pivot); wm = joint_data[joint_num]->mWorldMatrix; } ((LLV4Matrix3)(sJointMat[j] = *wm)).multiply(sj->mRootToJointSkinOffset, pivot); sJointMat[j++].translate(pivot); } F32 weight = F32_MAX; LLV4Matrix4 blend_mat; LLStrider<LLVector3> o_vertices; LLStrider<LLVector3> o_normals; LLVertexBuffer *buffer = face->mVertexBuffer; buffer->getVertexStrider(o_vertices, mesh->mFaceVertexOffset); buffer->getNormalStrider(o_normals, mesh->mFaceVertexOffset); const F32* weights = mesh->getWeights(); const LLVector3* coords = mesh->getCoords(); const LLVector3* normals = mesh->getNormals(); for (U32 index = 0, index_end = mesh->getNumVertices(); index < index_end; ++index) { if( weight != weights[index]) { S32 joint = llfloor(weight = weights[index]); blend_mat.lerp(sJointMat[joint], sJointMat[joint+1], weight - joint); } blend_mat.multiply(coords[index], o_vertices[index]); ((LLV4Matrix3)blend_mat).multiply(normals[index], o_normals[index]); } buffer->setBuffer(0); }
// static void LLViewerJointMesh::updateGeometrySSE2(LLFace *face, LLPolyMesh *mesh) { // This cannot be a file-level static because it will be initialized // before main() using SSE code, which will crash on non-SSE processors. static LLV4Matrix4 sJointMat[32]; LLDynamicArray<LLJointRenderData*>& joint_data = mesh->getReferenceMesh()->mJointRenderData; //upload joint pivots/matrices for(S32 j = 0, jend = joint_data.count(); j < jend ; ++j ) { matrix_translate(sJointMat[j], joint_data[j]->mWorldMatrix, joint_data[j]->mSkinJoint ? joint_data[j]->mSkinJoint->mRootToJointSkinOffset : joint_data[j+1]->mSkinJoint->mRootToParentJointSkinOffset); } F32 weight = F32_MAX; LLV4Matrix4 blend_mat; LLStrider<LLVector3> o_vertices; LLStrider<LLVector3> o_normals; LLVertexBuffer *buffer = face->mVertexBuffer; buffer->getVertexStrider(o_vertices, mesh->mFaceVertexOffset); buffer->getNormalStrider(o_normals, mesh->mFaceVertexOffset); const F32* weights = mesh->getWeights(); const LLVector3* coords = mesh->getCoords(); const LLVector3* normals = mesh->getNormals(); for (U32 index = 0, index_end = mesh->getNumVertices(); index < index_end; ++index) { if( weight != weights[index]) { S32 joint = llfloor(weight = weights[index]); blend_mat.lerp(sJointMat[joint], sJointMat[joint+1], weight - joint); } blend_mat.multiply(coords[index], o_vertices[index]); ((LLV4Matrix3)blend_mat).multiply(normals[index], o_normals[index]); } //setBuffer(0) called in LLVOAvatar::renderSkinned }
void LLTerrainPartition::getGeometry(LLSpatialGroup* group) { LLFastTimer ftm(FTM_REBUILD_TERRAIN_VB); LLVertexBuffer* buffer = group->mVertexBuffer; //get vertex buffer striders LLStrider<LLVector3> vertices; LLStrider<LLVector3> normals; LLStrider<LLVector2> texcoords2; LLStrider<LLVector2> texcoords; LLStrider<U16> indices; llassert_always(buffer->getVertexStrider(vertices)); llassert_always(buffer->getNormalStrider(normals)); llassert_always(buffer->getTexCoord0Strider(texcoords)); llassert_always(buffer->getTexCoord1Strider(texcoords2)); llassert_always(buffer->getIndexStrider(indices)); U32 indices_index = 0; U32 index_offset = 0; for (std::vector<LLFace*>::iterator i = mFaceList.begin(); i != mFaceList.end(); ++i) { LLFace* facep = *i; facep->setIndicesIndex(indices_index); facep->setGeomIndex(index_offset); facep->setVertexBuffer(buffer); LLVOSurfacePatch* patchp = (LLVOSurfacePatch*) facep->getViewerObject(); patchp->getGeometry(vertices, normals, texcoords, texcoords2, indices); indices_index += facep->getIndicesCount(); index_offset += facep->getGeomCount(); } buffer->flush(); mFaceList.clear(); }
void LLParticlePartition::getGeometry(LLSpatialGroup* group) { LLFastTimer ftm(FTM_REBUILD_PARTICLE_GEOM); std::sort(mFaceList.begin(), mFaceList.end(), LLFace::CompareDistanceGreater()); U32 index_count = 0; U32 vertex_count = 0; group->clearDrawMap(); LLVertexBuffer* buffer = group->mVertexBuffer; LLStrider<U16> indicesp; LLStrider<LLVector4a> verticesp; LLStrider<LLVector3> normalsp; LLStrider<LLVector2> texcoordsp; LLStrider<LLColor4U> colorsp; LLStrider<LLColor4U> emissivep; buffer->getVertexStrider(verticesp); buffer->getNormalStrider(normalsp); buffer->getColorStrider(colorsp); buffer->getEmissiveStrider(emissivep); LLSpatialGroup::drawmap_elem_t& draw_vec = group->mDrawMap[mRenderPass]; for (std::vector<LLFace*>::iterator i = mFaceList.begin(); i != mFaceList.end(); ++i) { LLFace* facep = *i; LLAlphaObject* object = (LLAlphaObject*) facep->getViewerObject(); if (!facep->isState(LLFace::PARTICLE)) { //set the indices of this face S32 idx = LLVOPartGroup::findAvailableVBSlot(); if (idx >= 0) { facep->setGeomIndex(idx*4); facep->setIndicesIndex(idx*6); facep->setVertexBuffer(LLVOPartGroup::sVB); facep->setPoolType(LLDrawPool::POOL_ALPHA); facep->setState(LLFace::PARTICLE); } else { continue; //out of space in particle buffer } } S32 geom_idx = (S32) facep->getGeomIndex(); LLStrider<U16> cur_idx = indicesp + facep->getIndicesStart(); LLStrider<LLVector4a> cur_vert = verticesp + geom_idx; LLStrider<LLVector3> cur_norm = normalsp + geom_idx; LLStrider<LLVector2> cur_tc = texcoordsp + geom_idx; LLStrider<LLColor4U> cur_col = colorsp + geom_idx; LLStrider<LLColor4U> cur_glow = emissivep + geom_idx; LLColor4U* start_glow = cur_glow.get(); object->getGeometry(facep->getTEOffset(), cur_vert, cur_norm, cur_tc, cur_col, cur_glow, cur_idx); BOOL has_glow = FALSE; if (cur_glow.get() != start_glow) { has_glow = TRUE; } llassert(facep->getGeomCount() == 4); llassert(facep->getIndicesCount() == 6); vertex_count += facep->getGeomCount(); index_count += facep->getIndicesCount(); S32 idx = draw_vec.size()-1; BOOL fullbright = facep->isState(LLFace::FULLBRIGHT); F32 vsize = facep->getVirtualSize(); bool batched = false; U32 bf_src = LLRender::BF_SOURCE_ALPHA; U32 bf_dst = LLRender::BF_ONE_MINUS_SOURCE_ALPHA; object->getBlendFunc(facep->getTEOffset(), bf_src, bf_dst); if (idx >= 0) { LLDrawInfo* info = draw_vec[idx]; if (info->mTexture == facep->getTexture() && info->mHasGlow == has_glow && info->mFullbright == fullbright && info->mBlendFuncDst == bf_dst && info->mBlendFuncSrc == bf_src) { if (draw_vec[idx]->mEnd == facep->getGeomIndex()-1) { batched = true; info->mCount += facep->getIndicesCount(); info->mEnd += facep->getGeomCount(); info->mVSize = llmax(draw_vec[idx]->mVSize, vsize); } else if (draw_vec[idx]->mStart == facep->getGeomIndex()+facep->getGeomCount()+1) { batched = true; info->mCount += facep->getIndicesCount(); info->mStart -= facep->getGeomCount(); info->mOffset = facep->getIndicesStart(); info->mVSize = llmax(draw_vec[idx]->mVSize, vsize); } } } if (!batched) { U32 start = facep->getGeomIndex(); U32 end = start + facep->getGeomCount()-1; U32 offset = facep->getIndicesStart(); U32 count = facep->getIndicesCount(); LLDrawInfo* info = new LLDrawInfo(start,end,count,offset,facep->getTexture(), //facep->getTexture(), buffer, fullbright); const LLVector4a* bounds = group->getBounds(); info->mExtents[0] = bounds[0]; info->mExtents[1] = bounds[1]; info->mVSize = vsize; info->mBlendFuncDst = bf_dst; info->mBlendFuncSrc = bf_src; info->mHasGlow = has_glow; info->mParticle = TRUE; draw_vec.push_back(info); //for alpha sorting facep->setDrawInfo(info); } if(facep->getGeomCount() > 0) { buffer->validateRange(facep->getGeomIndex(), facep->getGeomIndex() + facep->getGeomCount() - 1, facep->getIndicesCount(), facep->getIndicesStart()); } } mFaceList.clear(); }
void LLParticlePartition::getGeometry(LLSpatialGroup* group) { LLMemType mt(LLMemType::MTYPE_SPACE_PARTITION); LLFastTimer ftm(mDrawableType == LLPipeline::RENDER_TYPE_GRASS ? LLFastTimer::FTM_REBUILD_GRASS_VB : LLFastTimer::FTM_REBUILD_PARTICLE_VB); std::sort(mFaceList.begin(), mFaceList.end(), LLFace::CompareDistanceGreater()); U32 index_count = 0; U32 vertex_count = 0; group->clearDrawMap(); LLVertexBuffer* buffer = group->mVertexBuffer; LLStrider<U16> indicesp; LLStrider<LLVector3> verticesp; LLStrider<LLVector3> normalsp; LLStrider<LLVector2> texcoordsp; LLStrider<LLColor4U> colorsp; buffer->getVertexStrider(verticesp); buffer->getNormalStrider(normalsp); buffer->getColorStrider(colorsp); buffer->getTexCoord0Strider(texcoordsp); buffer->getIndexStrider(indicesp); LLSpatialGroup::drawmap_elem_t& draw_vec = group->mDrawMap[mRenderPass]; for (std::vector<LLFace*>::iterator i = mFaceList.begin(); i != mFaceList.end(); ++i) { LLFace* facep = *i; LLAlphaObject* object = (LLAlphaObject*) facep->getViewerObject(); facep->setGeomIndex(vertex_count); facep->setIndicesIndex(index_count); facep->mVertexBuffer = buffer; facep->setPoolType(LLDrawPool::POOL_ALPHA); object->getGeometry(facep->getTEOffset(), verticesp, normalsp, texcoordsp, colorsp, indicesp); vertex_count += facep->getGeomCount(); index_count += facep->getIndicesCount(); S32 idx = draw_vec.size()-1; BOOL fullbright = facep->isState(LLFace::FULLBRIGHT); F32 vsize = facep->getVirtualSize(); if (idx >= 0 && draw_vec[idx]->mEnd == facep->getGeomIndex()-1 && draw_vec[idx]->mTexture == facep->getTexture() && (U16) (draw_vec[idx]->mEnd - draw_vec[idx]->mStart + facep->getGeomCount()) <= (U32) gGLManager.mGLMaxVertexRange && //draw_vec[idx]->mCount + facep->getIndicesCount() <= (U32) gGLManager.mGLMaxIndexRange && draw_vec[idx]->mEnd - draw_vec[idx]->mStart + facep->getGeomCount() < 4096 && draw_vec[idx]->mFullbright == fullbright) { draw_vec[idx]->mCount += facep->getIndicesCount(); draw_vec[idx]->mEnd += facep->getGeomCount(); draw_vec[idx]->mVSize = llmax(draw_vec[idx]->mVSize, vsize); } else { U32 start = facep->getGeomIndex(); U32 end = start + facep->getGeomCount()-1; U32 offset = facep->getIndicesStart(); U32 count = facep->getIndicesCount(); LLDrawInfo* info = new LLDrawInfo(start,end,count,offset,facep->getTexture(), buffer, fullbright); info->mExtents[0] = group->mObjectExtents[0]; info->mExtents[1] = group->mObjectExtents[1]; info->mVSize = vsize; draw_vec.push_back(info); //for alpha sorting facep->setDrawInfo(info); } } buffer->setBuffer(0); mFaceList.clear(); }
void LLVOTree::updateMesh() { LLMatrix4 matrix; // Translate to tree base HACK - adjustment in Z plants tree underground const LLVector3 &pos_agent = getPositionAgent(); //gGL.translatef(pos_agent.mV[VX], pos_agent.mV[VY], pos_agent.mV[VZ] - 0.1f); LLMatrix4 trans_mat; trans_mat.setTranslation(pos_agent.mV[VX], pos_agent.mV[VY], pos_agent.mV[VZ] - 0.1f); trans_mat *= matrix; // Rotate to tree position and bend for current trunk/wind // Note that trunk stiffness controls the amount of bend at the trunk as // opposed to the crown of the tree // const F32 TRUNK_STIFF = 22.f; LLQuaternion rot = LLQuaternion(mTrunkBend.magVec()*TRUNK_STIFF*DEG_TO_RAD, LLVector4(mTrunkBend.mV[VX], mTrunkBend.mV[VY], 0)) * LLQuaternion(90.f*DEG_TO_RAD, LLVector4(0,0,1)) * getRotation(); LLMatrix4 rot_mat(rot); rot_mat *= trans_mat; F32 radius = getScale().magVec()*0.05f; LLMatrix4 scale_mat; scale_mat.mMatrix[0][0] = scale_mat.mMatrix[1][1] = scale_mat.mMatrix[2][2] = radius; scale_mat *= rot_mat; // const F32 THRESH_ANGLE_FOR_BILLBOARD = 15.f; // const F32 BLEND_RANGE_FOR_BILLBOARD = 3.f; F32 droop = mDroop + 25.f*(1.f - mTrunkBend.magVec()); S32 stop_depth = 0; F32 alpha = 1.0; U32 vert_count = 0; U32 index_count = 0; calcNumVerts(vert_count, index_count, mTrunkLOD, stop_depth, mDepth, mTrunkDepth, mBranches); LLFace* facep = mDrawable->getFace(0); LLVertexBuffer* buff = new LLVertexBuffer(LLDrawPoolTree::VERTEX_DATA_MASK, GL_STATIC_DRAW_ARB); buff->allocateBuffer(vert_count, index_count, TRUE); facep->setVertexBuffer(buff); LLStrider<LLVector3> vertices; LLStrider<LLVector3> normals; LLStrider<LLVector2> tex_coords; LLStrider<U16> indices; U16 idx_offset = 0; buff->getVertexStrider(vertices); buff->getNormalStrider(normals); buff->getTexCoord0Strider(tex_coords); buff->getIndexStrider(indices); genBranchPipeline(vertices, normals, tex_coords, indices, idx_offset, scale_mat, mTrunkLOD, stop_depth, mDepth, mTrunkDepth, 1.0, mTwist, droop, mBranches, alpha); mReferenceBuffer->flush(); buff->flush(); }
void LLViewerJointMesh::updateGeometry() { if (!(mValid && mMesh && mFace && mMesh->hasWeights() && mFace->mVertexBuffer.notNull() && LLShaderMgr::getVertexShaderLevel(LLShaderMgr::SHADER_AVATAR) == 0)) { return; } uploadJointMatrices(); LLStrider<LLVector3> o_vertices; LLStrider<LLVector3> o_normals; //get vertex and normal striders LLVertexBuffer *buffer = mFace->mVertexBuffer; buffer->getVertexStrider(o_vertices, 0); buffer->getNormalStrider(o_normals, 0); F32 last_weight = F32_MAX; LLMatrix4 gBlendMat; LLMatrix3 gBlendRotMat; const F32* weights = mMesh->getWeights(); const LLVector3* coords = mMesh->getCoords(); const LLVector3* normals = mMesh->getNormals(); for (U32 index = 0; index < mMesh->getNumVertices(); index++) { U32 bidx = index + mMesh->mFaceVertexOffset; // blend by first matrix F32 w = weights[index]; // Maybe we don't have to change gBlendMat. // Profiles of a single-avatar scene on a Mac show this to be a very // common case. JC if (w == last_weight) { o_vertices[bidx] = coords[index] * gBlendMat; o_normals[bidx] = normals[index] * gBlendRotMat; continue; } last_weight = w; S32 joint = llfloor(w); w -= joint; // No lerp required in this case. if (w == 1.0f) { gBlendMat = gJointMat[joint+1]; o_vertices[bidx] = coords[index] * gBlendMat; gBlendRotMat = gJointRot[joint+1]; o_normals[bidx] = normals[index] * gBlendRotMat; continue; } // Try to keep all the accesses to the matrix data as close // together as possible. This function is a hot spot on the // Mac. JC LLMatrix4 &m0 = gJointMat[joint+1]; LLMatrix4 &m1 = gJointMat[joint+0]; gBlendMat.mMatrix[VX][VX] = lerp(m1.mMatrix[VX][VX], m0.mMatrix[VX][VX], w); gBlendMat.mMatrix[VX][VY] = lerp(m1.mMatrix[VX][VY], m0.mMatrix[VX][VY], w); gBlendMat.mMatrix[VX][VZ] = lerp(m1.mMatrix[VX][VZ], m0.mMatrix[VX][VZ], w); gBlendMat.mMatrix[VY][VX] = lerp(m1.mMatrix[VY][VX], m0.mMatrix[VY][VX], w); gBlendMat.mMatrix[VY][VY] = lerp(m1.mMatrix[VY][VY], m0.mMatrix[VY][VY], w); gBlendMat.mMatrix[VY][VZ] = lerp(m1.mMatrix[VY][VZ], m0.mMatrix[VY][VZ], w); gBlendMat.mMatrix[VZ][VX] = lerp(m1.mMatrix[VZ][VX], m0.mMatrix[VZ][VX], w); gBlendMat.mMatrix[VZ][VY] = lerp(m1.mMatrix[VZ][VY], m0.mMatrix[VZ][VY], w); gBlendMat.mMatrix[VZ][VZ] = lerp(m1.mMatrix[VZ][VZ], m0.mMatrix[VZ][VZ], w); gBlendMat.mMatrix[VW][VX] = lerp(m1.mMatrix[VW][VX], m0.mMatrix[VW][VX], w); gBlendMat.mMatrix[VW][VY] = lerp(m1.mMatrix[VW][VY], m0.mMatrix[VW][VY], w); gBlendMat.mMatrix[VW][VZ] = lerp(m1.mMatrix[VW][VZ], m0.mMatrix[VW][VZ], w); o_vertices[bidx] = coords[index] * gBlendMat; LLMatrix3 &n0 = gJointRot[joint+1]; LLMatrix3 &n1 = gJointRot[joint+0]; gBlendRotMat.mMatrix[VX][VX] = lerp(n1.mMatrix[VX][VX], n0.mMatrix[VX][VX], w); gBlendRotMat.mMatrix[VX][VY] = lerp(n1.mMatrix[VX][VY], n0.mMatrix[VX][VY], w); gBlendRotMat.mMatrix[VX][VZ] = lerp(n1.mMatrix[VX][VZ], n0.mMatrix[VX][VZ], w); gBlendRotMat.mMatrix[VY][VX] = lerp(n1.mMatrix[VY][VX], n0.mMatrix[VY][VX], w); gBlendRotMat.mMatrix[VY][VY] = lerp(n1.mMatrix[VY][VY], n0.mMatrix[VY][VY], w); gBlendRotMat.mMatrix[VY][VZ] = lerp(n1.mMatrix[VY][VZ], n0.mMatrix[VY][VZ], w); gBlendRotMat.mMatrix[VZ][VX] = lerp(n1.mMatrix[VZ][VX], n0.mMatrix[VZ][VX], w); gBlendRotMat.mMatrix[VZ][VY] = lerp(n1.mMatrix[VZ][VY], n0.mMatrix[VZ][VY], w); gBlendRotMat.mMatrix[VZ][VZ] = lerp(n1.mMatrix[VZ][VZ], n0.mMatrix[VZ][VZ], w); o_normals[bidx] = normals[index] * gBlendRotMat; } }
void LLParticlePartition::getGeometry(LLSpatialGroup* group) { LLMemType mt(LLMemType::MTYPE_SPACE_PARTITION); LLFastTimer ftm(FTM_REBUILD_PARTICLE_GEOM); std::sort(mFaceList.begin(), mFaceList.end(), LLFace::CompareDistanceGreater()); U32 index_count = 0; U32 vertex_count = 0; group->clearDrawMap(); LLVertexBuffer* buffer = group->mVertexBuffer; LLStrider<U16> indicesp; LLStrider<LLVector4a> verticesp; LLStrider<LLVector3> normalsp; LLStrider<LLVector2> texcoordsp; LLStrider<LLColor4U> colorsp; buffer->getVertexStrider(verticesp); buffer->getNormalStrider(normalsp); buffer->getColorStrider(colorsp); LLSpatialGroup::drawmap_elem_t& draw_vec = group->mDrawMap[mRenderPass]; for (std::vector<LLFace*>::iterator i = mFaceList.begin(); i != mFaceList.end(); ++i) { LLFace* facep = *i; LLAlphaObject* object = (LLAlphaObject*) facep->getViewerObject(); if (!facep->isState(LLFace::PARTICLE)) { //set the indices of this face S32 idx = LLVOPartGroup::findAvailableVBSlot(); if (idx >= 0) { facep->setGeomIndex(idx*4); facep->setIndicesIndex(idx*6); facep->setVertexBuffer(LLVOPartGroup::sVB); facep->setPoolType(LLDrawPool::POOL_ALPHA); facep->setState(LLFace::PARTICLE); } else { continue; //out of space in particle buffer } } S32 geom_idx = (S32) facep->getGeomIndex(); LLStrider<U16> cur_idx = indicesp + facep->getIndicesStart(); LLStrider<LLVector4a> cur_vert = verticesp + geom_idx; LLStrider<LLVector3> cur_norm = normalsp + geom_idx; LLStrider<LLVector2> cur_tc = texcoordsp + geom_idx; LLStrider<LLColor4U> cur_col = colorsp + geom_idx; object->getGeometry(facep->getTEOffset(), cur_vert, cur_norm, cur_tc, cur_col, cur_idx); llassert(facep->getGeomCount() == 4); llassert(facep->getIndicesCount() == 6); vertex_count += facep->getGeomCount(); index_count += facep->getIndicesCount(); S32 idx = draw_vec.size()-1; BOOL fullbright = facep->isState(LLFace::FULLBRIGHT); F32 vsize = facep->getVirtualSize(); bool batched = false; if (idx >= 0 && draw_vec[idx]->mTexture == facep->getTexture() && draw_vec[idx]->mFullbright == fullbright) { if (draw_vec[idx]->mEnd == facep->getGeomIndex()-1) { batched = true; draw_vec[idx]->mCount += facep->getIndicesCount(); draw_vec[idx]->mEnd += facep->getGeomCount(); draw_vec[idx]->mVSize = llmax(draw_vec[idx]->mVSize, vsize); } else if (draw_vec[idx]->mStart == facep->getGeomIndex()+facep->getGeomCount()+1) { batched = true; draw_vec[idx]->mCount += facep->getIndicesCount(); draw_vec[idx]->mStart -= facep->getGeomCount(); draw_vec[idx]->mOffset = facep->getIndicesStart(); draw_vec[idx]->mVSize = llmax(draw_vec[idx]->mVSize, vsize); } } if (!batched) { U32 start = facep->getGeomIndex(); U32 end = start + facep->getGeomCount()-1; U32 offset = facep->getIndicesStart(); U32 count = facep->getIndicesCount(); LLDrawInfo* info = new LLDrawInfo(start,end,count,offset,facep->getTexture(), //facep->getTexture(), buffer, fullbright); info->mExtents[0] = group->mObjectExtents[0]; info->mExtents[1] = group->mObjectExtents[1]; info->mVSize = vsize; draw_vec.push_back(info); //for alpha sorting facep->setDrawInfo(info); } } mFaceList.clear(); }