/** * @file llvovolume.cpp * @brief LLVOVolume class implementation * * Copyright (c) 2001-$CurrentYear$, Linden Research, Inc. * $License$ */ // A "volume" is a box, cylinder, sphere, or other primitive shape. #include "llviewerprecompiledheaders.h" #include "llvovolume.h" #include "llviewercontrol.h" #include "lldir.h" #include "llflexibleobject.h" #include "llmaterialtable.h" #include "llprimitive.h" #include "llvolume.h" #include "llvolumemgr.h" #include "llvolumemessage.h" #include "material_codes.h" #include "message.h" #include "object_flags.h" #include "llagent.h" #include "lldrawable.h" #include "lldrawpoolsimple.h" #include "lldrawpoolbump.h" #include "llface.h" // TEMP HACK ventrella #include "llhudmanager.h" #include "llflexibleobject.h" #include "llanimalcontrols.h" #include "llsky.h" #include "llviewercamera.h" #include "llviewerimagelist.h" #include "llviewerregion.h" #include "llviewertextureanim.h" #include "llworld.h" #include "llselectmgr.h" #include "pipeline.h" const S32 MIN_QUIET_FRAMES_COALESCE = 30; const F32 FORCE_SIMPLE_RENDER_AREA = 512.f; const F32 FORCE_CULL_AREA = 8.f; BOOL gAnimateTextures = TRUE; extern BOOL gHideSelectedObjects; F32 LLVOVolume::sLODFactor = 1.f; F32 LLVOVolume::sLODSlopDistanceFactor = 0.5f; //Changing this to zero, effectively disables the LOD transition slop F32 LLVOVolume::sDistanceFactor = 1.0f; S32 LLVOVolume::sNumLODChanges = 0; LLVOVolume::LLVOVolume(const LLUUID &id, const LLPCode pcode, LLViewerRegion *regionp) : LLViewerObject(id, pcode, regionp), mVolumeImpl(NULL) { mTexAnimMode = 0; mRelativeXform.identity(); mRelativeXformInvTrans.identity(); mLOD = MIN_LOD; mInited = FALSE; mTextureAnimp = NULL; mGlobalVolume = FALSE; mVObjRadius = LLVector3(1,1,0.5f).magVec(); mNumFaces = 0; } LLVOVolume::~LLVOVolume() { delete mTextureAnimp; mTextureAnimp = NULL; delete mVolumeImpl; mVolumeImpl = NULL; } // static void LLVOVolume::initClass() { } U32 LLVOVolume::processUpdateMessage(LLMessageSystem *mesgsys, void **user_data, U32 block_num, EObjectUpdateType update_type, LLDataPacker *dp) { LLColor4U color; // Do base class updates... U32 retval = LLViewerObject::processUpdateMessage(mesgsys, user_data, block_num, update_type, dp); if (!dp) { if (update_type == OUT_FULL) { //////////////////////////////// // // Unpack texture animation data // // if (mesgsys->getSizeFast(_PREHASH_ObjectData, block_num, _PREHASH_TextureAnim)) { if (!mTextureAnimp) { mTextureAnimp = new LLViewerTextureAnim(); } else { if (!(mTextureAnimp->mMode & LLTextureAnim::SMOOTH)) { mTextureAnimp->reset(); } } mTexAnimMode = 0; mTextureAnimp->unpackTAMessage(mesgsys, block_num); } else { if (mTextureAnimp) { delete mTextureAnimp; mTextureAnimp = NULL; gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; mTexAnimMode = 0; } } // Unpack volume data LLVolumeParams volume_params; LLVolumeMessage::unpackVolumeParams(&volume_params, mesgsys, _PREHASH_ObjectData, block_num); if (setVolume(volume_params, 0)) { markForUpdate(TRUE); } } // Sigh, this needs to be done AFTER the volume is set as well, otherwise bad stuff happens... //////////////////////////// // // Unpack texture entry data // if (unpackTEMessage(mesgsys, _PREHASH_ObjectData, block_num) & (TEM_CHANGE_TEXTURE|TEM_CHANGE_COLOR)) { updateTEData(); } } else { // CORY TO DO: Figure out how to get the value here if (update_type != OUT_TERSE_IMPROVED) { LLVolumeParams volume_params; BOOL res = LLVolumeMessage::unpackVolumeParams(&volume_params, *dp); if (!res) { llwarns << "Bogus volume parameters in object " << getID() << llendl; llwarns << getRegion()->getOriginGlobal() << llendl; } if (setVolume(volume_params, 0)) { markForUpdate(TRUE); } S32 res2 = unpackTEMessage(*dp); if (TEM_INVALID == res2) { // Well, crap, there's something bogus in the data that we're unpacking. dp->dumpBufferToLog(); llwarns << "Flushing cache files" << llendl; char mask[LL_MAX_PATH]; /* Flawfinder: ignore */ snprintf(mask, LL_MAX_PATH, "%s*.slc", gDirUtilp->getDirDelimiter().c_str()); /* Flawfinder: ignore */ gDirUtilp->deleteFilesInDir(gDirUtilp->getExpandedFilename(LL_PATH_CACHE,"").c_str(),mask); // llerrs << "Bogus TE data in " << getID() << ", crashing!" << llendl; llwarns << "Bogus TE data in " << getID() << llendl; } else if (res2 & (TEM_CHANGE_TEXTURE|TEM_CHANGE_COLOR)) { updateTEData(); } U32 value = dp->getPassFlags(); if (value & 0x40) { if (!mTextureAnimp) { mTextureAnimp = new LLViewerTextureAnim(); } else { if (!(mTextureAnimp->mMode & LLTextureAnim::SMOOTH)) { mTextureAnimp->reset(); } } mTexAnimMode = 0; mTextureAnimp->unpackTAMessage(*dp); } else if (mTextureAnimp) { delete mTextureAnimp; mTextureAnimp = NULL; gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; mTexAnimMode = 0; } } else { S32 texture_length = mesgsys->getSizeFast(_PREHASH_ObjectData, block_num, _PREHASH_TextureEntry); if (texture_length) { U8 tdpbuffer[1024]; LLDataPackerBinaryBuffer tdp(tdpbuffer, 1024); mesgsys->getBinaryDataFast(_PREHASH_ObjectData, _PREHASH_TextureEntry, tdpbuffer, 0, block_num); if ( unpackTEMessage(tdp) & (TEM_CHANGE_TEXTURE|TEM_CHANGE_COLOR)) { updateTEData(); } } } } return retval; } void LLVOVolume::animateTextures() { F32 off_s = 0.f, off_t = 0.f, scale_s = 1.f, scale_t = 1.f, rot = 0.f; S32 result; if (result = mTextureAnimp->animateTextures(off_s, off_t, scale_s, scale_t, rot)) { if (!mTexAnimMode) { mFaceMappingChanged = TRUE; gPipeline.markTextured(mDrawable); } mTexAnimMode = result | mTextureAnimp->mMode; S32 start=0, end=mDrawable->getNumFaces()-1; if (mTextureAnimp->mFace >= 0 && mTextureAnimp->mFace <= end) { start = end = mTextureAnimp->mFace; } for (S32 i = start; i <= end; i++) { LLQuaternion quat; LLVector3 scale(1,1,1); LLFace* facep = mDrawable->getFace(i); const LLTextureEntry* te = facep->getTextureEntry(); LLMatrix4& tex_mat = facep->mTextureMatrix; if (!te) { continue; } if (!(result & LLViewerTextureAnim::ROTATE)) { te->getRotation(&rot); } { F32 axis = -1; F32 s,t; te->getScale(&s,&t); if (s < 0) { axis = -axis; } if (t < 0) { axis = -axis; } quat.setQuat(rot, 0, 0, axis); } if (!(result & LLViewerTextureAnim::TRANSLATE)) { te->getOffset(&off_s,&off_t); } LLVector3 trans(off_s+0.5f, off_t+0.5f, 0.f); tex_mat.identity(); tex_mat.translate(LLVector3(-0.5f, -0.5f, 0.f)); tex_mat.rotate(quat); if (!(result & LLViewerTextureAnim::SCALE)) { te->getScale(&scale_s, &scale_t); } { scale.setVec(scale_s, scale_t, 1.f); LLMatrix4 mat; mat.initAll(scale, LLQuaternion(), LLVector3()); tex_mat *= mat; } tex_mat.translate(trans); } } else { if (mTexAnimMode && mTextureAnimp->mRate == 0) { U8 start, count; if (mTextureAnimp->mFace == -1) { start = 0; count = getNumTEs(); } else { start = (U8) mTextureAnimp->mFace; count = 1; } for (S32 i = start; i < start + count; i++) { if (mTexAnimMode & LLViewerTextureAnim::TRANSLATE) { setTEOffset(i, mTextureAnimp->mOffS, mTextureAnimp->mOffT); } if (mTexAnimMode & LLViewerTextureAnim::SCALE) { setTEScale(i, mTextureAnimp->mScaleS, mTextureAnimp->mScaleT); } if (mTexAnimMode & LLViewerTextureAnim::ROTATE) { setTERotation(i, mTextureAnimp->mRot); } } gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; mTexAnimMode = 0; } } } BOOL LLVOVolume::idleUpdate(LLAgent &agent, LLWorld &world, const F64 &time) { LLViewerObject::idleUpdate(agent, world, time); if (mDead || mDrawable.isNull()) { return TRUE; } /////////////////////// // // Do texture animation stuff // if (mTextureAnimp && gAnimateTextures) { animateTextures(); } // Dispatch to implementation if (mVolumeImpl) { mVolumeImpl->doIdleUpdate(agent, world, time); } return TRUE; } void LLVOVolume::updateTextures(LLAgent &agent) { // LLFastTimer t(LLFastTimer::FTM_TEMP6); const F32 TEXTURE_AREA_REFRESH_TIME = 5.f; // seconds if (mTextureUpdateTimer.getElapsedTimeF32() > TEXTURE_AREA_REFRESH_TIME) { if (mDrawable->isVisible()) { updateTextures(); } } } void LLVOVolume::updateTextures() { // Update the pixel area of all faces if (!gPipeline.hasRenderType(LLPipeline::RENDER_TYPE_SIMPLE)) { return; } if (LLViewerImage::sDontLoadVolumeTextures || mDrawable.isNull()) // || !mDrawable->isVisible()) { return; } mTextureUpdateTimer.reset(); F32 old_area = mPixelArea; mPixelArea = 0.f; const S32 num_faces = mDrawable->getNumFaces(); F32 min_vsize=999999999.f, max_vsize=0.f; for (S32 i = 0; i < num_faces; i++) { LLFace* face = mDrawable->getFace(i); const LLTextureEntry *te = face->getTextureEntry(); LLViewerImage *imagep = face->getTexture(); if (!imagep || !te || face->mExtents[0] == face->mExtents[1]) { continue; } F32 vsize; if (isHUDAttachment()) { F32 area = (F32) gCamera->getScreenPixelArea(); vsize = area; imagep->setBoostLevel(LLViewerImage::BOOST_HUD); face->setPixelArea(area); // treat as full screen } else { vsize = getTextureVirtualSize(face); } mPixelArea = llmax(mPixelArea, face->getPixelArea()); face->setVirtualSize(vsize); imagep->addTextureStats(vsize); if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_TEXTURE_AREA)) { if (vsize < min_vsize) min_vsize = vsize; if (vsize > max_vsize) max_vsize = vsize; } else if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_TEXTURE_PRIORITY)) { F32 pri = imagep->getDecodePriority(); if (pri < min_vsize) min_vsize = pri; if (pri > max_vsize) max_vsize = pri; } else if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_FACE_AREA)) { F32 pri = mPixelArea; if (pri < min_vsize) min_vsize = pri; if (pri > max_vsize) max_vsize = pri; } } if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_TEXTURE_AREA)) { setDebugText(llformat("%.0f:%.0f", fsqrtf(min_vsize),fsqrtf(max_vsize))); } else if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_TEXTURE_PRIORITY)) { setDebugText(llformat("%.0f:%.0f", fsqrtf(min_vsize),fsqrtf(max_vsize))); } else if (gPipeline.hasRenderDebugMask(LLPipeline::RENDER_DEBUG_FACE_AREA)) { setDebugText(llformat("%.0f:%.0f", fsqrtf(min_vsize),fsqrtf(max_vsize))); } if (mPixelArea == 0) { //flexi phasing issues make this happen mPixelArea = old_area; } } F32 LLVOVolume::getTextureVirtualSize(LLFace* face) { //get area of circle around face LLVector3 center = face->getPositionAgent(); LLVector3 size = (face->mExtents[1] - face->mExtents[0]) * 0.5f; F32 face_area = LLPipeline::calcPixelArea(center, size, *gCamera); face->setPixelArea(face_area); if (face_area <= 0) { return 0.f; } //get area of circle in texture space LLVector2 tdim = face->mTexExtents[1] - face->mTexExtents[0]; F32 texel_area = (tdim * 0.5f).magVecSquared()*3.14159f; if (texel_area <= 0) { // Probably animated, use default texel_area = 1.f; } //apply texel area to face area to get accurate ratio face_area /= llclamp(texel_area, 1.f/64.f, 16.f); return face_area; } BOOL LLVOVolume::isActive() const { return !mStatic || mTextureAnimp || isAttachment() || (mVolumeImpl && mVolumeImpl->isActive()); } BOOL LLVOVolume::setMaterial(const U8 material) { BOOL res = LLViewerObject::setMaterial(material); if (res) { // for deprecated LL_MCODE_LIGHT if (mDrawable.notNull()) { gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_LIGHTING, TRUE); } } return res; } void LLVOVolume::setTexture(const S32 face) { llassert(face < getNumTEs()); LLViewerImage::bindTexture(getTEImage(face)); } void LLVOVolume::setScale(const LLVector3 &scale, BOOL damped) { if (scale != getScale()) { // store local radius LLViewerObject::setScale(scale); if (mVolumeImpl) { mVolumeImpl->onSetScale(scale, damped); } updateRadius(); //since drawable transforms do not include scale, changing volume scale //requires an immediate rebuild of volume verts. gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_POSITION, TRUE); } } LLFace* LLVOVolume::addFace(S32 f) { const LLTextureEntry* te = getTE(f); LLViewerImage* imagep = getTEImage(f); return mDrawable->addFace(te, imagep); } LLDrawable *LLVOVolume::createDrawable(LLPipeline *pipeline) { pipeline->allocDrawable(this); mDrawable->setRenderType(LLPipeline::RENDER_TYPE_VOLUME); S32 max_tes_to_set = getNumTEs(); for (S32 i = 0; i < max_tes_to_set; i++) { LLFace* face = addFace(i); // JC - should there be a setViewerObject(this) call here? face->setTEOffset(i); } mNumFaces = max_tes_to_set; if (isAttachment()) { mDrawable->makeActive(); } if (getIsLight()) { // Add it to the pipeline mLightSet gPipeline.setLight(mDrawable, TRUE); } updateRadius(); mDrawable->updateDistance(*gCamera); return mDrawable; } BOOL LLVOVolume::setVolume(const LLVolumeParams &volume_params, const S32 detail, bool unique_volume) { // Check if we need to change implementations bool is_flexible = (volume_params.getPathParams().getCurveType() == LL_PCODE_PATH_FLEXIBLE); if (is_flexible) { setParameterEntryInUse(LLNetworkData::PARAMS_FLEXIBLE, TRUE, false); if (!mVolumeImpl) { LLFlexibleObjectData* data = (LLFlexibleObjectData*)getParameterEntry(LLNetworkData::PARAMS_FLEXIBLE); mVolumeImpl = new LLVolumeImplFlexible(this, data); } } else { // Mark the parameter not in use setParameterEntryInUse(LLNetworkData::PARAMS_FLEXIBLE, FALSE, false); if (mVolumeImpl) { delete mVolumeImpl; mVolumeImpl = NULL; if (mDrawable.notNull()) { // Undo the damage we did to this matrix mDrawable->updateXform(FALSE); } } } mGlobalVolume = (mVolumeImpl && mVolumeImpl->isVolumeGlobal()); if (LLPrimitive::setVolume(volume_params, mLOD, (mVolumeImpl && mVolumeImpl->isVolumeUnique()))) { mFaceMappingChanged = TRUE; if (mVolumeImpl) { mVolumeImpl->onSetVolume(volume_params, detail); } return TRUE; } return FALSE; } S32 LLVOVolume::computeLODDetail(F32 distance, F32 radius) { S32 cur_detail; // We've got LOD in the profile, and in the twist. Use radius. F32 tan_angle = (LLVOVolume::sLODFactor*radius)/distance; cur_detail = LLVolumeLODGroup::getDetailFromTan(llround(tan_angle, 0.01f)); return cur_detail; } BOOL LLVOVolume::calcLOD() { if (mDrawable.isNull()) { return FALSE; } S32 cur_detail = 0; F32 radius = mVolumep->mLODScaleBias.scaledVec(getScale()).magVec(); F32 distance = mDrawable->mDistanceWRTCamera; distance *= sDistanceFactor; F32 rampDist = LLVOVolume::sLODFactor * 2; if (distance < rampDist) { // Boost LOD when you're REALLY close distance *= 1.0f/rampDist; distance *= distance; distance *= rampDist; } // DON'T Compensate for field of view changing on FOV zoom. distance *= 3.14159f/3.f; cur_detail = computeLODDetail(llround(distance, 0.01f), llround(radius, 0.01f)); if (cur_detail != mLOD) { mAppAngle = llround((F32) atan2( mDrawable->getRadius(), mDrawable->mDistanceWRTCamera) * RAD_TO_DEG, 0.01f); mLOD = cur_detail; return TRUE; } else { return FALSE; } } BOOL LLVOVolume::updateLOD() { if (mDrawable.isNull()) { return FALSE; } BOOL lod_changed = calcLOD(); if (lod_changed) { gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_VOLUME, FALSE); mLODChanged = TRUE; } return lod_changed; } BOOL LLVOVolume::setDrawableParent(LLDrawable* parentp) { if (!LLViewerObject::setDrawableParent(parentp)) { // no change in drawable parent return FALSE; } if (!mDrawable->isRoot()) { // rebuild vertices in parent relative space gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_VOLUME, TRUE); if (mDrawable->isActive() && !parentp->isActive()) { parentp->makeActive(); } else if (mDrawable->isStatic() && parentp->isActive()) { mDrawable->makeActive(); } } return TRUE; } void LLVOVolume::updateFaceFlags() { for (S32 i = 0; i < getVolume()->getNumFaces(); i++) { LLFace *face = mDrawable->getFace(i); BOOL fullbright = getTE(i)->getFullbright(); face->clearState(LLFace::FULLBRIGHT | LLFace::HUD_RENDER | LLFace::LIGHT); if (fullbright || (mMaterial == LL_MCODE_LIGHT)) { face->setState(LLFace::FULLBRIGHT); } if (mDrawable->isLight()) { face->setState(LLFace::LIGHT); } if (isHUDAttachment()) { face->setState(LLFace::HUD_RENDER); } } } void LLVOVolume::setParent(LLViewerObject* parent) { LLViewerObject::setParent(parent); if (mDrawable) { gPipeline.markMoved(mDrawable); mVolumeChanged = TRUE; gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_VOLUME, TRUE); } } // NOTE: regenFaces() MUST be followed by genTriangles()! void LLVOVolume::regenFaces() { // remove existing faces BOOL count_changed = mNumFaces != getNumTEs(); if (count_changed) { deleteFaces(); // add new faces mNumFaces = getNumTEs(); } for (S32 i = 0; i < mNumFaces; i++) { LLFace* facep = count_changed ? addFace(i) : mDrawable->getFace(i); facep->setTEOffset(i); facep->setTexture(getTEImage(i)); facep->setViewerObject(this); } if (!count_changed) { updateFaceFlags(); } } BOOL LLVOVolume::genBBoxes(BOOL force_global) { BOOL res = TRUE; LLVector3 min,max; BOOL rebuild = mDrawable->isState(LLDrawable::REBUILD_VOLUME | LLDrawable::REBUILD_POSITION); for (S32 i = 0; i < getVolume()->getNumFaces(); i++) { LLFace *face = mDrawable->getFace(i); res &= face->genVolumeBBoxes(*getVolume(), i, mRelativeXform, mRelativeXformInvTrans, mGlobalVolume | force_global); if (rebuild) { if (i == 0) { min = face->mExtents[0]; max = face->mExtents[1]; } else { for (U32 i = 0; i < 3; i++) { if (face->mExtents[0].mV[i] < min.mV[i]) { min.mV[i] = face->mExtents[0].mV[i]; } if (face->mExtents[1].mV[i] > max.mV[i]) { max.mV[i] = face->mExtents[1].mV[i]; } } } } } if (rebuild) { mDrawable->setSpatialExtents(min,max); mDrawable->setPositionGroup((min+max)*0.5f); //bounding boxes changed, update texture priorities updateTextures(); } updateRadius(); mDrawable->movePartition(); return res; } void LLVOVolume::updateRelativeXform() { if (mVolumeImpl) { mVolumeImpl->updateRelativeXform(); return; } LLDrawable* drawable = mDrawable; if (drawable->isActive()) { // setup relative transforms LLQuaternion delta_rot; LLVector3 delta_pos, delta_scale; //matrix from local space to parent relative/global space delta_rot = drawable->isSpatialRoot() ? LLQuaternion() : mDrawable->getRotation(); delta_pos = drawable->isSpatialRoot() ? LLVector3(0,0,0) : mDrawable->getPosition(); delta_scale = mDrawable->getScale(); // Vertex transform (4x4) LLVector3 x_axis = LLVector3(delta_scale.mV[VX], 0.f, 0.f) * delta_rot; LLVector3 y_axis = LLVector3(0.f, delta_scale.mV[VY], 0.f) * delta_rot; LLVector3 z_axis = LLVector3(0.f, 0.f, delta_scale.mV[VZ]) * delta_rot; mRelativeXform.initRows(LLVector4(x_axis, 0.f), LLVector4(y_axis, 0.f), LLVector4(z_axis, 0.f), LLVector4(delta_pos, 1.f)); // compute inverse transpose for normals // mRelativeXformInvTrans.setRows(x_axis, y_axis, z_axis); // mRelativeXformInvTrans.invert(); // mRelativeXformInvTrans.setRows(x_axis, y_axis, z_axis); // grumble - invert is NOT a matrix invert, so we do it by hand: LLMatrix3 rot_inverse = LLMatrix3(~delta_rot); LLMatrix3 scale_inverse; scale_inverse.setRows(LLVector3(1.0, 0.0, 0.0) / delta_scale.mV[VX], LLVector3(0.0, 1.0, 0.0) / delta_scale.mV[VY], LLVector3(0.0, 0.0, 1.0) / delta_scale.mV[VZ]); mRelativeXformInvTrans = rot_inverse * scale_inverse; mRelativeXformInvTrans.transpose(); } else { LLVector3 pos = getPosition(); LLVector3 scale = getScale(); LLQuaternion rot = getRotation(); if (mParent) { pos *= mParent->getRotation(); pos += mParent->getPosition(); rot *= mParent->getRotation(); } LLViewerRegion* region = getRegion(); pos += region->getOriginAgent(); LLVector3 x_axis = LLVector3(scale.mV[VX], 0.f, 0.f) * rot; LLVector3 y_axis = LLVector3(0.f, scale.mV[VY], 0.f) * rot; LLVector3 z_axis = LLVector3(0.f, 0.f, scale.mV[VZ]) * rot; mRelativeXform.initRows(LLVector4(x_axis, 0.f), LLVector4(y_axis, 0.f), LLVector4(z_axis, 0.f), LLVector4(pos, 1.f)); // compute inverse transpose for normals LLMatrix3 rot_inverse = LLMatrix3(~rot); LLMatrix3 scale_inverse; scale_inverse.setRows(LLVector3(1.0, 0.0, 0.0) / scale.mV[VX], LLVector3(0.0, 1.0, 0.0) / scale.mV[VY], LLVector3(0.0, 0.0, 1.0) / scale.mV[VZ]); mRelativeXformInvTrans = rot_inverse * scale_inverse; mRelativeXformInvTrans.transpose(); } } BOOL LLVOVolume::updateGeometry(LLDrawable *drawable) { LLFastTimer t(LLFastTimer::FTM_UPDATE_PRIMITIVES); if (mVolumeImpl != NULL) { LLFastTimer t(LLFastTimer::FTM_GEN_FLEX); BOOL res = mVolumeImpl->doUpdateGeometry(drawable); updateFaceFlags(); return res; } BOOL compiled = FALSE; updateRelativeXform(); if (mDrawable.isNull()) // Not sure why this is happening, but it is... { return TRUE; // No update to complete } if (mVolumeChanged || mFaceMappingChanged ) { compiled = TRUE; mInited = TRUE; if (mVolumeChanged) { LLFastTimer ftm(LLFastTimer::FTM_GEN_VOLUME); LLVolumeParams volume_params = getVolume()->getParams(); setVolume(volume_params, 0); drawable->setState(LLDrawable::REBUILD_VOLUME); } { LLFastTimer t(LLFastTimer::FTM_GEN_TRIANGLES); regenFaces(); genBBoxes(FALSE); } } else if (mLODChanged) { LLPointer old_volumep, new_volumep; F32 old_lod, new_lod; old_volumep = getVolume(); old_lod = old_volumep->getDetail(); { LLFastTimer ftm(LLFastTimer::FTM_GEN_VOLUME); LLVolumeParams volume_params = getVolume()->getParams(); setVolume(volume_params, 0); } new_volumep = getVolume(); new_lod = new_volumep->getDetail(); if (new_lod != old_lod) { compiled = TRUE; sNumLODChanges += getVolume()->getNumFaces(); drawable->setState(LLDrawable::REBUILD_VOLUME); // for face->genVolumeTriangles() { LLFastTimer t(LLFastTimer::FTM_GEN_TRIANGLES); if (new_volumep->getNumFaces() != old_volumep->getNumFaces()) { regenFaces(); } genBBoxes(FALSE); } } } // it has its own drawable (it's moved) or it has changed UVs or it has changed xforms from global<->local else { compiled = TRUE; // All it did was move or we changed the texture coordinate offset LLFastTimer t(LLFastTimer::FTM_GEN_TRIANGLES); genBBoxes(FALSE); } // Update face flags updateFaceFlags(); if(compiled) { LLPipeline::sCompiles++; } mVolumeChanged = FALSE; mLODChanged = FALSE; mFaceMappingChanged = FALSE; return TRUE; } void LLVOVolume::updateFaceSize(S32 idx) { const LLVolumeFace& vol_face = getVolume()->getVolumeFace(idx); LLFace* facep = mDrawable->getFace(idx); facep->setSize(vol_face.mVertices.size(), vol_face.mIndices.size()); } BOOL LLVOVolume::isRootEdit() const { if (mParent && !((LLViewerObject*)mParent)->isAvatar()) { return FALSE; } return TRUE; } void LLVOVolume::setTEImage(const U8 te, LLViewerImage *imagep) { BOOL changed = (mTEImages[te] != imagep); LLViewerObject::setTEImage(te, imagep); if (changed) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } } S32 LLVOVolume::setTETexture(const U8 te, const LLUUID &uuid) { S32 res = LLViewerObject::setTETexture(te, uuid); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEColor(const U8 te, const LLColor4 &color) { S32 res = LLViewerObject::setTEColor(te, color); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEBumpmap(const U8 te, const U8 bumpmap) { S32 res = LLViewerObject::setTEBumpmap(te, bumpmap); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTETexGen(const U8 te, const U8 texgen) { S32 res = LLViewerObject::setTETexGen(te, texgen); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEShiny(const U8 te, const U8 shiny) { S32 res = LLViewerObject::setTEShiny(te, shiny); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEFullbright(const U8 te, const U8 fullbright) { S32 res = LLViewerObject::setTEFullbright(te, fullbright); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEMediaFlags(const U8 te, const U8 media_flags) { S32 res = LLViewerObject::setTEMediaFlags(te, media_flags); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEScale(const U8 te, const F32 s, const F32 t) { S32 res = LLViewerObject::setTEScale(te, s, t); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEScaleS(const U8 te, const F32 s) { S32 res = LLViewerObject::setTEScaleS(te, s); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } S32 LLVOVolume::setTEScaleT(const U8 te, const F32 t) { S32 res = LLViewerObject::setTEScaleT(te, t); if (res) { gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } return res; } void LLVOVolume::updateTEData() { if (mDrawable.notNull()) { mFaceMappingChanged = TRUE; gPipeline.markRebuild(mDrawable, LLDrawable::REBUILD_MATERIAL, TRUE); } } //---------------------------------------------------------------------------- void LLVOVolume::setIsLight(BOOL is_light) { if (is_light != getIsLight()) { if (is_light) { setParameterEntryInUse(LLNetworkData::PARAMS_LIGHT, TRUE, true); } else { setParameterEntryInUse(LLNetworkData::PARAMS_LIGHT, FALSE, true); } if (is_light) { // Add it to the pipeline mLightSet gPipeline.setLight(mDrawable, TRUE); } else { // Not a light. Remove it from the pipeline's light set. gPipeline.setLight(mDrawable, FALSE); // Remove this object from any object which has it as a light if (mDrawable) { mDrawable->clearLightSet(); } } } } void LLVOVolume::setLightColor(const LLColor3& color) { LLLightParams *param_block = (LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { if (param_block->getColor() != color) { param_block->setColor(LLColor4(color, param_block->getColor().mV[3])); parameterChanged(LLNetworkData::PARAMS_LIGHT, true); gPipeline.markTextured(mDrawable); mFaceMappingChanged = TRUE; } } } void LLVOVolume::setLightIntensity(F32 intensity) { LLLightParams *param_block = (LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { if (param_block->getColor().mV[3] != intensity) { param_block->setColor(LLColor4(LLColor3(param_block->getColor()), intensity)); parameterChanged(LLNetworkData::PARAMS_LIGHT, true); } } } void LLVOVolume::setLightRadius(F32 radius) { LLLightParams *param_block = (LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { if (param_block->getRadius() != radius) { param_block->setRadius(radius); parameterChanged(LLNetworkData::PARAMS_LIGHT, true); } } } void LLVOVolume::setLightFalloff(F32 falloff) { LLLightParams *param_block = (LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { if (param_block->getFalloff() != falloff) { param_block->setFalloff(falloff); parameterChanged(LLNetworkData::PARAMS_LIGHT, true); } } } void LLVOVolume::setLightCutoff(F32 cutoff) { LLLightParams *param_block = (LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { if (param_block->getCutoff() != cutoff) { param_block->setCutoff(cutoff); parameterChanged(LLNetworkData::PARAMS_LIGHT, true); } } } //---------------------------------------------------------------------------- BOOL LLVOVolume::getIsLight() const { return getParameterEntryInUse(LLNetworkData::PARAMS_LIGHT); } LLColor3 LLVOVolume::getLightBaseColor() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return LLColor3(param_block->getColor()); } else { return LLColor3(1,1,1); } } LLColor3 LLVOVolume::getLightColor() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return LLColor3(param_block->getColor()) * param_block->getColor().mV[3]; } else { return LLColor3(1,1,1); } } F32 LLVOVolume::getLightIntensity() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return param_block->getColor().mV[3]; } else { return 1.f; } } F32 LLVOVolume::getLightRadius() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return param_block->getRadius(); } else { return 0.f; } } F32 LLVOVolume::getLightFalloff() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return param_block->getFalloff(); } else { return 0.f; } } F32 LLVOVolume::getLightCutoff() const { const LLLightParams *param_block = (const LLLightParams *)getParameterEntry(LLNetworkData::PARAMS_LIGHT); if (param_block) { return param_block->getCutoff(); } else { return 0.f; } } //---------------------------------------------------------------------------- // returns < 0 if inside radius F32 LLVOVolume::getLightDistance(const LLVector3& pos) const { LLVector3 dpos = getRenderPosition() - pos; F32 dist = dpos.magVec() - getLightRadius(); return dist; } // returns intensity, modifies color in result F32 LLVOVolume::calcLightAtPoint(const LLVector3& pos, const LLVector3& norm, LLColor4& result) { if (!getIsLight()) { return 0.0f; } F32 light_radius = getLightRadius(); LLVector3 light_pos = getRenderPosition(); LLVector3 light_dir = light_pos - pos; F32 dist = light_dir.normVec(); F32 dp = norm * light_dir; if ((gPipeline.getLightingDetail() > 2)) { if (dp <= 0) { result *= 0; return 0; } if (dist >= light_radius) { result *= 0; return 0; } F32 mag = 1.0f-(dist/light_radius); mag = powf(mag, 0.75f); mag *= dp; result = getLightColor() * mag; return mag; } else { F32 light_radius = getLightRadius(); LLVector3 light_pos = getRenderPosition(); LLVector3 light_dir = light_pos - pos; F32 dist = light_dir.normVec(); F32 dp = norm * light_dir; F32 atten = (1.f/.2f) / (light_radius); // 20% of brightness at radius F32 falloff = 1.f / (dist * atten); F32 mag = falloff * dp; mag = llmax(mag, 0.0f); result = getLightColor() * mag; return mag; } } BOOL LLVOVolume::updateLighting(BOOL do_lighting) { LLMemType mt1(LLMemType::MTYPE_DRAWABLE); #if 0 if (mDrawable->isStatic()) { do_lighting = FALSE; } const LLMatrix4& mat_vert = mDrawable->getWorldMatrix(); const LLMatrix3& mat_normal = LLMatrix3(mDrawable->getWorldRotation()); LLVolume* volume = getVolume(); for (S32 i = 0; i < volume->getNumFaces(); i++) { LLFace *face = mDrawable->getFace(i); if (face && face->getGeomCount()) { face->genLighting(volume, mDrawable, i, i, mat_vert, mat_normal, do_lighting); } } #endif return TRUE; } //---------------------------------------------------------------------------- U32 LLVOVolume::getVolumeInterfaceID() const { if (mVolumeImpl) { return mVolumeImpl->getID(); } return 0; } BOOL LLVOVolume::isFlexible() const { if (getParameterEntryInUse(LLNetworkData::PARAMS_FLEXIBLE)) { if (getVolume()->getParams().getPathParams().getCurveType() != LL_PCODE_PATH_FLEXIBLE) { llwarns << "wtf" << llendl; LLVolumeParams volume_params = getVolume()->getParams(); U8 profile_and_hole = volume_params.getProfileParams().getCurveType(); volume_params.setType(profile_and_hole, LL_PCODE_PATH_FLEXIBLE); } return TRUE; } else { return FALSE; } } BOOL LLVOVolume::isVolumeGlobal() const { if (mVolumeImpl) { return mVolumeImpl->isVolumeGlobal() ? TRUE : FALSE; } return FALSE; } BOOL LLVOVolume::canBeFlexible() const { U8 path = getVolume()->getParams().getPathParams().getCurveType(); return (path == LL_PCODE_PATH_FLEXIBLE || path == LL_PCODE_PATH_LINE); } BOOL LLVOVolume::setIsFlexible(BOOL is_flexible) { BOOL res = FALSE; BOOL was_flexible = isFlexible(); LLVolumeParams volume_params; if (is_flexible) { if (!was_flexible) { volume_params = getVolume()->getParams(); U8 profile_and_hole = volume_params.getProfileParams().getCurveType(); volume_params.setType(profile_and_hole, LL_PCODE_PATH_FLEXIBLE); res = TRUE; setFlags(FLAGS_USE_PHYSICS, FALSE); setFlags(FLAGS_PHANTOM, TRUE); setParameterEntryInUse(LLNetworkData::PARAMS_FLEXIBLE, TRUE, true); if (mDrawable) { mDrawable->makeActive(); } } } else { if (was_flexible) { volume_params = getVolume()->getParams(); U8 profile_and_hole = volume_params.getProfileParams().getCurveType(); volume_params.setType(profile_and_hole, LL_PCODE_PATH_LINE); res = TRUE; setFlags(FLAGS_PHANTOM, FALSE); setParameterEntryInUse(LLNetworkData::PARAMS_FLEXIBLE, FALSE, true); } } if (res) { res = setVolume(volume_params, 1); if (res) { markForUpdate(TRUE); } } return res; } //---------------------------------------------------------------------------- void LLVOVolume::generateSilhouette(LLSelectNode* nodep, const LLVector3& view_point) { LLVolume *volume = getVolume(); if (volume) { LLVector3 view_vector; view_vector = view_point; //transform view vector into volume space view_vector -= getRenderPosition(); mDrawable->mDistanceWRTCamera = view_vector.magVec(); LLQuaternion worldRot = getRenderRotation(); view_vector = view_vector * ~worldRot; if (!isVolumeGlobal()) { LLVector3 objScale = getScale(); LLVector3 invObjScale(1.f / objScale.mV[VX], 1.f / objScale.mV[VY], 1.f / objScale.mV[VZ]); view_vector.scaleVec(invObjScale); } updateRelativeXform(); volume->generateSilhouetteVertices(nodep->mSilhouetteVertices, nodep->mSilhouetteNormals, nodep->mSilhouetteSegments, view_vector, mRelativeXform, mRelativeXformInvTrans); nodep->mSilhouetteExists = TRUE; } } void LLVOVolume::deleteFaces() { S32 face_count = mNumFaces; if (mDrawable.notNull()) { mDrawable->deleteFaces(0, face_count); } mNumFaces = 0; } void LLVOVolume::updateRadius() { if (mDrawable.isNull()) { return; } mVObjRadius = getScale().magVec(); mDrawable->setRadius(mVObjRadius); } BOOL LLVOVolume::isAttachment() const { if (mState == 0) { return FALSE; } else { return TRUE; } } BOOL LLVOVolume::isHUDAttachment() const { // *NOTE: we assume hud attachment points are in defined range // since this range is constant for backwards compatibility // reasons this is probably a reasonable assumption to make S32 attachment_id = ATTACHMENT_ID_FROM_STATE(mState); return ( attachment_id >= 31 && attachment_id <= 38 ); } const LLMatrix4 LLVOVolume::getRenderMatrix() const { if (mDrawable->isActive() && !mDrawable->isRoot()) { return mDrawable->getParent()->getWorldMatrix(); } return mDrawable->getWorldMatrix(); } void LLVOVolume::writeCAL3D(apr_file_t* fp, std::string& path, std::string& file_base, S32 joint_num, LLVector3& pos, LLQuaternion& rot, S32& material_index, S32& texture_index, std::multimap& material_map) { #if 0 LLImageTGA tga_image; if (mDrawable.isNull()) { return; } LLVector3 final_pos = getPosition(); final_pos *= 100.f; final_pos = final_pos * rot; final_pos += pos; LLQuaternion final_rot; final_rot = getRotation() * rot; LLMatrix4 transform; transform.initAll(getScale(), final_rot, final_pos); LLMatrix4 int_transpose_transform; int_transpose_transform.initAll(LLVector3(1.f / getScale().mV[VX], 1.f / getScale().mV[VY], 1.f / getScale().mV[VZ]), final_rot, LLVector3::zero); for (S32 i = 0; i < mDrawable->getNumFaces(); i++) { S32 vert_num = 0; LLFace* facep = mDrawable->getFace(i); LLDrawPool* poolp = facep->getPool(); const LLTextureEntry* tep = facep->getTextureEntry(); if (!tep) { continue; } S32 my_material = -1; S32 my_texture = -1; LLColor4 face_color = tep->getColor(); typedef std::multimap::iterator material_it_t; std::pair found_range = material_map.equal_range(tep->getID()); material_it_t material_it = found_range.first; LLMaterialExportInfo* material_info = NULL; while(material_it != material_map.end() && material_it != found_range.second) { // we've at least found a matching texture, so reuse it my_texture = material_it->second->mTextureIndex; if (material_it->second->mColor == face_color) { // we've found a matching material material_info = material_it->second; } ++material_it; } if (material_info) { // material already exported, just reuse it my_material = material_info->mMaterialIndex; my_texture = material_info->mTextureIndex; } else { // reserve new material number my_material = material_index++; // if we didn't already find a matching texture... if (my_texture == -1) { //...use the next available slot... my_texture = texture_index++; //...and export texture as image file char filename[MAX_PATH]; /* Flawfinder: ignore */ snprintf(filename, MAX_PATH, "%s\\%s_material_tex_%d.tga", path.c_str(), file_base.c_str(), my_texture); /* Flawfinder: ignore */ LLViewerImage* imagep = facep->getTexture(); if (imagep->getTexName() == 0) { llinfos << "No image data available for " << filename << llendl; continue; } LLImageRaw raw_image; imagep->readBackRaw(-1, raw_image); BOOL success = tga_image.encode(raw_image); success = tga_image.save(filename); } material_info = new LLMaterialExportInfo(my_material, my_texture, face_color); material_map.insert(std::make_pair(tep->getID(), material_info)); } apr_file_printf(fp, "\t\n", facep->getGeomCount(), facep->getIndicesCount() / 3, my_material); for (S32 vert_index = 0; vert_index < facep->getGeomCount(); vert_index++) { LLVector3 vert_pos = poolp->getVertex(facep->getGeomStart() + vert_index); vert_pos *= 100.f; vert_pos = vert_pos * transform; LLVector3 vert_norm = poolp->getNormal(facep->getGeomStart() + vert_index); vert_norm = vert_norm * int_transpose_transform; LLVector2 vert_tc = poolp->getTexCoord(facep->getGeomStart() + vert_index, 0); apr_file_printf(fp, " \n", vert_num++); apr_file_printf(fp, " %.4f %.4f %.4f\n", vert_pos.mV[VX], vert_pos.mV[VY], vert_pos.mV[VZ]); apr_file_printf(fp, " %.6f %.6f %.6f\n", vert_norm.mV[VX], vert_norm.mV[VY], vert_norm.mV[VZ]); apr_file_printf(fp, " %.6f %.6f\n", vert_tc.mV[VX], 1.f - vert_tc.mV[VY]); apr_file_printf(fp, " 1.0\n", joint_num + 1); apr_file_printf(fp, " \n"); } for (U32 index_i = 0; index_i < facep->getIndicesCount(); index_i += 3) { U32 index_a = poolp->getIndex(facep->getIndicesStart() + index_i) - facep->getGeomStart(); U32 index_b = poolp->getIndex(facep->getIndicesStart() + index_i + 1) - facep->getGeomStart(); U32 index_c = poolp->getIndex(facep->getIndicesStart() + index_i + 2) - facep->getGeomStart(); apr_file_printf(fp, " \n", index_a, index_b, index_c); } apr_file_printf(fp, " \n"); } for (U32 i = 0; i < mChildList.size(); i++) { ((LLVOVolume*)(LLViewerObject*)mChildList[i])->writeCAL3D(fp, path, file_base, joint_num, final_pos, final_rot, material_index, texture_index, material_map); } #endif } //static void LLVOVolume::preUpdateGeom() { sNumLODChanges = 0; } void LLVOVolume::parameterChanged(U16 param_type, bool local_origin) { LLViewerObject::parameterChanged(param_type, local_origin); } void LLVOVolume::parameterChanged(U16 param_type, LLNetworkData* data, BOOL in_use, bool local_origin) { LLViewerObject::parameterChanged(param_type, data, in_use, local_origin); if (mVolumeImpl) { mVolumeImpl->onParameterChanged(param_type, data, in_use, local_origin); } if (mDrawable.notNull()) { BOOL is_light = getIsLight(); if (is_light != mDrawable->isState(LLDrawable::LIGHT)) { gPipeline.setLight(mDrawable, is_light); } } } void LLVOVolume::setSelected(BOOL sel) { LLViewerObject::setSelected(sel); if (mDrawable.notNull()) { mDrawable->movePartition(); } } void LLVOVolume::updateSpatialExtents(LLVector3& newMin, LLVector3& newMax) { } F32 LLVOVolume::getBinRadius() { F32 radius; const LLVector3* ext = mDrawable->getSpatialExtents(); BOOL shrink_wrap = mDrawable->isAnimating(); BOOL alpha_wrap = FALSE; if (!isHUDAttachment()) { for (S32 i = 0; i < mDrawable->getNumFaces(); i++) { if (mDrawable->getFace(i)->getPoolType() == LLDrawPool::POOL_ALPHA) { alpha_wrap = TRUE; break; } } } else { shrink_wrap = FALSE; } if (alpha_wrap) { LLVector3 bounds = getScale(); radius = llmin(bounds.mV[1], bounds.mV[2]); radius = llmin(radius, bounds.mV[0]); radius *= 0.5f; } else if (shrink_wrap) { radius = (ext[1]-ext[0]).magVec()*0.5f; } else if (mDrawable->isStatic()) { radius = 32.f; } else { radius = 8.f; } return llclamp(radius, 0.5f, 256.f); } const LLVector3 LLVOVolume::getPivotPositionAgent() const { if (mVolumeImpl) { return mVolumeImpl->getPivotPosition(); } return LLViewerObject::getPivotPositionAgent(); } void LLVOVolume::onShift(const LLVector3 &shift_vector) { if (mVolumeImpl) { mVolumeImpl->onShift(shift_vector); } updateRelativeXform(); } const LLMatrix4& LLVOVolume::getWorldMatrix(LLXformMatrix* xform) const { if (mVolumeImpl) { return mVolumeImpl->getWorldMatrix(xform); } return xform->getWorldMatrix(); } LLVector3 LLVOVolume::agentPositionToVolume(const LLVector3& pos) const { LLVector3 ret = pos - getRenderPosition(); ret = ret * ~getRenderRotation(); LLVector3 objScale = isVolumeGlobal() ? LLVector3(1,1,1) : getScale(); LLVector3 invObjScale(1.f / objScale.mV[VX], 1.f / objScale.mV[VY], 1.f / objScale.mV[VZ]); ret.scaleVec(invObjScale); return ret; } LLVector3 LLVOVolume::agentDirectionToVolume(const LLVector3& dir) const { return dir * ~getRenderRotation(); } LLVector3 LLVOVolume::volumePositionToAgent(const LLVector3& dir) const { LLVector3 ret = dir; ret.scaleVec(getScale()); ret = ret * getRenderRotation(); ret += getRenderPosition(); return ret; } BOOL LLVOVolume::lineSegmentIntersect(const LLVector3& start, LLVector3& end) const { return FALSE; #if 0 // needs to be rewritten to use face extents instead of volume bounds LLVolume* volume = getVolume(); BOOL ret = FALSE; if (volume) { LLVector3 v_start, v_end, v_dir; v_start = agentPositionToVolume(start); v_end = agentPositionToVolume(end); if (LLLineSegmentAABB(v_start, v_end, volume->mBounds[0], volume->mBounds[1])) { if (volume->lineSegmentIntersect(v_start, v_end) >= 0) { end = volumePositionToAgent(v_end); ret = TRUE; } } } return ret; #endif } U32 LLVOVolume::getPartitionType() const { if (isHUDAttachment()) { return LLPipeline::PARTITION_HUD; } return LLPipeline::PARTITION_VOLUME; } LLVolumePartition::LLVolumePartition() : LLSpatialPartition(LLVOVolume::VERTEX_DATA_MASK, FALSE) { mLODPeriod = 16; mDepthMask = FALSE; mDrawableType = LLPipeline::RENDER_TYPE_VOLUME; mPartitionType = LLPipeline::PARTITION_VOLUME; mSlopRatio = 0.25f; mBufferUsage = GL_DYNAMIC_DRAW_ARB; mImageEnabled = TRUE; } LLVolumeBridge::LLVolumeBridge(LLDrawable* drawablep) : LLSpatialBridge(drawablep, LLVOVolume::VERTEX_DATA_MASK) { mDepthMask = FALSE; mLODPeriod = 16; mDrawableType = LLPipeline::RENDER_TYPE_VOLUME; mPartitionType = LLPipeline::PARTITION_BRIDGE; mBufferUsage = GL_DYNAMIC_DRAW_ARB; mSlopRatio = 0.25f; } void LLVolumeGeometryManager::registerFace(LLSpatialGroup* group, LLFace* facep, U32 type) { LLMemType mt(LLMemType::MTYPE_SPACE_PARTITION); if (facep->getViewerObject()->isSelected() && gHideSelectedObjects) { return; } //add face to drawmap std::vector& draw_vec = group->mDrawMap[type]; S32 idx = draw_vec.size()-1; BOOL fullbright = (type == LLRenderPass::PASS_FULLBRIGHT || type == LLRenderPass::PASS_ALPHA) ? facep->isState(LLFace::FULLBRIGHT) : FALSE; const LLMatrix4* tex_mat = NULL; if (type != LLRenderPass::PASS_SHINY && facep->isState(LLFace::TEXTURE_ANIM)) { tex_mat = &(facep->mTextureMatrix); } U8 bump = (type == LLRenderPass::PASS_BUMP ? facep->getTextureEntry()->getBumpmap() : 0); //LLViewerImage* tex = facep->mAppAngle < FORCE_SIMPLE_RENDER_ANGLE ? NULL : facep->getTexture(); LLViewerImage* tex = facep->getTexture(); if (type == LLRenderPass::PASS_GLOW) { U32 start = facep->getGeomIndex(); U32 end = start + facep->getGeomCount()-1; U32 offset = facep->getIndicesStart(); U32 count = facep->getIndicesCount(); LLDrawInfo* draw_info = new LLDrawInfo(start,end,count,offset,tex, facep->mVertexBuffer, fullbright, bump); draw_info->mVSize = facep->getVirtualSize(); draw_vec.push_back(draw_info); LLVOVolume* volume = (LLVOVolume*) facep->getViewerObject(); BOOL is_light = volume->mDrawable->isLight(); U8 alpha = is_light ? 196 : 160; LLColor3 col = is_light ? volume->getLightColor() : LLColor3(0,0,0); LLColor4 col2 = facep->getRenderColor(); draw_info->mGlowColor.setVec((U8) (col.mV[0]*col2.mV[0]*255), (U8) (col.mV[1]*col2.mV[1]*255), (U8) (col.mV[2]*col2.mV[2]*255), alpha); draw_info->mTextureMatrix = tex_mat; validate_draw_info(*draw_info); } else if (idx >= 0 && draw_vec[idx]->mVertexBuffer == facep->mVertexBuffer && draw_vec[idx]->mEnd == facep->getGeomIndex()-1 && draw_vec[idx]->mTexture == tex && #if LL_DARWIN draw_vec[idx]->mEnd - draw_vec[idx]->mStart + facep->getGeomCount() <= (U32) gGLManager.mGLMaxVertexRange && draw_vec[idx]->mCount + facep->getIndicesCount() <= (U32) gGLManager.mGLMaxIndexRange && #endif draw_vec[idx]->mFullbright == fullbright && draw_vec[idx]->mBump == bump && draw_vec[idx]->mTextureMatrix == tex_mat) { draw_vec[idx]->mCount += facep->getIndicesCount(); draw_vec[idx]->mEnd += facep->getGeomCount(); draw_vec[idx]->mVSize = llmax(draw_vec[idx]->mVSize, facep->getVirtualSize()); validate_draw_info(*draw_vec[idx]); } else { U32 start = facep->getGeomIndex(); U32 end = start + facep->getGeomCount()-1; U32 offset = facep->getIndicesStart(); U32 count = facep->getIndicesCount(); LLDrawInfo* draw_info = new LLDrawInfo(start,end,count,offset,tex, facep->mVertexBuffer, fullbright, bump); draw_info->mVSize = facep->getVirtualSize(); draw_vec.push_back(draw_info); draw_info->mReflectionMap = group->mReflectionMap; draw_info->mTextureMatrix = tex_mat; validate_draw_info(*draw_info); } } void LLVolumeGeometryManager::getGeometry(LLSpatialGroup* group) { } void LLVolumeGeometryManager::rebuildGeom(LLSpatialGroup* group) { if (group->changeLOD()) { group->mLastUpdateDistance = group->mDistance; } group->mLastUpdateViewAngle = group->mViewAngle; if (!group->isState(LLSpatialGroup::GEOM_DIRTY | LLSpatialGroup::ALPHA_DIRTY)) { return; } group->mBuilt = 1.f; LLFastTimer ftm(LLFastTimer::FTM_REBUILD_VBO); LLFastTimer ftm2(LLFastTimer::FTM_REBUILD_VOLUME_VB); //find reflection map if (group->mSpatialPartition->mImageEnabled) { if (group->mReflectionMap.isNull()) { LLSpatialGroup* parent = group->getParent(); while (parent && group->mReflectionMap.isNull()) { group->mReflectionMap = parent->mReflectionMap; parent = parent->getParent(); } } } group->clearDrawMap(); mFaceList.clear(); std::vector alpha_faces; U32 vertex_count = 0; U32 index_count = 0; U32 useage = group->mSpatialPartition->mBufferUsage; //get all the faces into a list, putting alpha faces in their own list for (LLSpatialGroup::element_iter drawable_iter = group->getData().begin(); drawable_iter != group->getData().end(); ++drawable_iter) { LLDrawable* drawablep = *drawable_iter; if (drawablep->isDead()) { continue; } if (drawablep->isAnimating()) { //fall back to stream draw for animating verts useage = GL_STREAM_DRAW_ARB; } LLVOVolume* vobj = drawablep->getVOVolume(); //for each face for (S32 i = 0; i < drawablep->getNumFaces(); i++) { //sum up face verts and indices drawablep->updateFaceSize(i); LLFace* facep = drawablep->getFace(i); if (facep->hasGeometry() && facep->mPixelArea > FORCE_CULL_AREA) { const LLTextureEntry* te = facep->getTextureEntry(); LLViewerImage* tex = facep->getTexture(); BOOL force_simple = (facep->mPixelArea < FORCE_SIMPLE_RENDER_AREA); U32 type = gPipeline.getPoolTypeFromTE(te, tex); if (type != LLDrawPool::POOL_ALPHA && force_simple) { type = LLDrawPool::POOL_SIMPLE; } facep->setPoolType(type); if (vobj->isHUDAttachment()) { facep->setState(LLFace::FULLBRIGHT); } if (vobj->mTextureAnimp && vobj->mTexAnimMode) { if (vobj->mTextureAnimp->mFace <= -1) { S32 face; for (face = 0; face < vobj->getNumTEs(); face++) { drawablep->getFace(face)->setState(LLFace::TEXTURE_ANIM); } } else if (vobj->mTextureAnimp->mFace < vobj->getNumTEs()) { drawablep->getFace(vobj->mTextureAnimp->mFace)->setState(LLFace::TEXTURE_ANIM); } } if (type == LLDrawPool::POOL_ALPHA) { vertex_count += facep->getGeomCount(); index_count += facep->getIndicesCount(); alpha_faces.push_back(facep); } else { if (drawablep->isState(LLDrawable::REBUILD_VOLUME)) { facep->mLastUpdateTime = gFrameTimeSeconds; } mFaceList.push_back(facep); } } else { //face has no renderable geometry facep->mVertexBuffer = NULL; facep->mLastVertexBuffer = NULL; //don't alpha wrap drawables that have only tiny tiny alpha faces facep->setPoolType(LLDrawPool::POOL_SIMPLE); } vobj->updateTextures(); } } group->mVertexCount = vertex_count; group->mIndexCount = index_count; group->mBufferUsage = useage; LLStrider vertices; LLStrider normals; LLStrider texcoords2; LLStrider texcoords; LLStrider colors; LLStrider indices; //PROCESS NON-ALPHA FACES { //sort faces by texture std::sort(mFaceList.begin(), mFaceList.end(), LLFace::CompareTextureAndTime()); std::vector::iterator face_iter = mFaceList.begin(); LLSpatialGroup::buffer_map_t buffer_map; while (face_iter != mFaceList.end()) { //pull off next face LLFace* facep = *face_iter; LLViewerImage* tex = facep->getTexture(); U32 index_count = facep->getIndicesCount(); U32 geom_count = facep->getGeomCount(); //sum up vertices needed for this texture std::vector::iterator i = face_iter; ++i; while (i != mFaceList.end() && (*i)->getTexture() == tex) { facep = *i; ++i; index_count += facep->getIndicesCount(); geom_count += facep->getGeomCount(); } //create/delete/resize vertex buffer if needed LLVertexBuffer* buffer = NULL; LLSpatialGroup::buffer_map_t::iterator found_iter = group->mBufferMap.find(tex); if (found_iter != group->mBufferMap.end()) { buffer = found_iter->second; } if (!buffer) { //create new buffer if needed buffer = createVertexBuffer(group->mSpatialPartition->mVertexDataMask, group->mBufferUsage); buffer->allocateBuffer(geom_count, index_count, TRUE); } else { if (LLVertexBuffer::sEnableVBOs && buffer->getUsage() != group->mBufferUsage) { buffer = createVertexBuffer(group->mSpatialPartition->mVertexDataMask, group->mBufferUsage); buffer->allocateBuffer(geom_count, index_count, TRUE); } else { buffer->resizeBuffer(geom_count, index_count); } } BOOL clean = TRUE; buffer_map[tex] = buffer; //add face geometry //get vertex buffer striders buffer->getVertexStrider(vertices); buffer->getNormalStrider(normals); buffer->getTexCoordStrider(texcoords); buffer->getTexCoord2Strider(texcoords2); buffer->getColorStrider(colors); buffer->getIndexStrider(indices); U32 indices_index = 0; U32 index_offset = 0; while (face_iter < i) { facep = *face_iter; LLDrawable* drawablep = facep->getDrawable(); LLVOVolume* vobj = drawablep->getVOVolume(); LLVolume* volume = vobj->getVolume(); U32 te_idx = facep->getTEOffset(); facep->mIndicesIndex = indices_index; facep->mGeomIndex = index_offset; facep->mVertexBuffer = buffer; { if (facep->getGeometryVolume(*volume, te_idx, vertices, normals, texcoords, texcoords2, colors, indices, vobj->getRelativeXform(), vobj->getRelativeXformInvTrans(), index_offset)) { clean = FALSE; buffer->markDirty(facep->getGeomIndex(), facep->getGeomCount(), facep->getIndicesStart(), facep->getIndicesCount()); } } indices_index += facep->mIndicesCount; BOOL force_simple = facep->mPixelArea < FORCE_SIMPLE_RENDER_AREA; BOOL fullbright = facep->isState(LLFace::FULLBRIGHT); const LLTextureEntry* te = facep->getTextureEntry(); if (tex->getPrimaryFormat() == GL_ALPHA) { registerFace(group, facep, LLRenderPass::PASS_INVISIBLE); } else if (fullbright) { registerFace(group, facep, LLRenderPass::PASS_FULLBRIGHT); } else { registerFace(group, facep, LLRenderPass::PASS_SIMPLE); } facep->setPoolType(LLDrawPool::POOL_SIMPLE); if (te->getShiny()) { registerFace(group, facep, LLRenderPass::PASS_SHINY); } if (!force_simple && te->getBumpmap()) { registerFace(group, facep, LLRenderPass::PASS_BUMP); } if (vobj->getIsLight() || (LLPipeline::sRenderGlow && facep->isState(LLFace::FULLBRIGHT))) { registerFace(group, facep, LLRenderPass::PASS_GLOW); } ++face_iter; } if (clean) { buffer->markClean(); } } group->mBufferMap.clear(); for (LLSpatialGroup::buffer_map_t::iterator i = buffer_map.begin(); i != buffer_map.end(); ++i) { group->mBufferMap[i->first] = i->second; } } //PROCESS ALPHA FACES if (!alpha_faces.empty()) { //sort alpha faces by distance std::sort(alpha_faces.begin(), alpha_faces.end(), LLFace::CompareDistanceGreater()); //store alpha faces in root vertex buffer if (group->mVertexBuffer.isNull() || (LLVertexBuffer::sEnableVBOs && group->mBufferUsage != group->mVertexBuffer->getUsage())) { group->mVertexBuffer = createVertexBuffer(group->mSpatialPartition->mVertexDataMask, group->mBufferUsage); group->mVertexBuffer->allocateBuffer(group->mVertexCount, group->mIndexCount, true); stop_glerror(); } else { group->mVertexBuffer->resizeBuffer(group->mVertexCount, group->mIndexCount); stop_glerror(); } //get vertex buffer striders LLVertexBuffer* buffer = group->mVertexBuffer; BOOL clean = TRUE; buffer->getVertexStrider(vertices); buffer->getNormalStrider(normals); buffer->getTexCoordStrider(texcoords); buffer->getTexCoord2Strider(texcoords2); buffer->getColorStrider(colors); buffer->getIndexStrider(indices); U32 index_offset = 0; U32 indices_index = 0; for (std::vector::iterator i = alpha_faces.begin(); i != alpha_faces.end(); ++i) { LLFace* facep = *i; LLDrawable* drawablep = facep->getDrawable(); LLVOVolume* vobj = drawablep->getVOVolume(); LLVolume* volume = vobj->getVolume(); U32 te_idx = facep->getTEOffset(); facep->mIndicesIndex = indices_index; facep->mGeomIndex = index_offset; facep->mVertexBuffer = group->mVertexBuffer; if (facep->getGeometryVolume(*volume, te_idx, vertices, normals, texcoords, texcoords2, colors, indices, vobj->getRelativeXform(), vobj->getRelativeXformInvTrans(), index_offset)) { clean = FALSE; buffer->markDirty(facep->getGeomIndex(), facep->getGeomCount(), facep->getIndicesStart(), facep->getIndicesCount()); } indices_index += facep->mIndicesCount; registerFace(group, facep, LLRenderPass::PASS_ALPHA); } if (clean) { buffer->markClean(); } } else { group->mVertexBuffer = NULL; } //get all the faces into a list, putting alpha faces in their own list for (LLSpatialGroup::element_iter drawable_iter = group->getData().begin(); drawable_iter != group->getData().end(); ++drawable_iter) { LLDrawable* drawablep = *drawable_iter; drawablep->clearState(LLDrawable::REBUILD_ALL); } group->mLastUpdateTime = gFrameTimeSeconds; group->clearState(LLSpatialGroup::GEOM_DIRTY | LLSpatialGroup::MATRIX_DIRTY | LLSpatialGroup::ALPHA_DIRTY); mFaceList.clear(); } void LLGeometryManager::addGeometryCount(LLSpatialGroup* group, U32 &vertex_count, U32 &index_count) { //initialize to default usage for this partition U32 usage = group->mSpatialPartition->mBufferUsage; //clear off any old faces mFaceList.clear(); //for each drawable for (LLSpatialGroup::element_iter drawable_iter = group->getData().begin(); drawable_iter != group->getData().end(); ++drawable_iter) { LLDrawable* drawablep = *drawable_iter; if (drawablep->isDead()) { continue; } if (drawablep->isAnimating()) { //fall back to stream draw for animating verts usage = GL_STREAM_DRAW_ARB; } //for each face for (S32 i = 0; i < drawablep->getNumFaces(); i++) { //sum up face verts and indices drawablep->updateFaceSize(i); LLFace* facep = drawablep->getFace(i); if (facep->hasGeometry() && facep->mPixelArea > FORCE_CULL_AREA) { vertex_count += facep->getGeomCount(); index_count += facep->getIndicesCount(); //remember face (for sorting) mFaceList.push_back(facep); } else { facep->mVertexBuffer = NULL; facep->mLastVertexBuffer = NULL; } } } group->mBufferUsage = usage; } LLHUDPartition::LLHUDPartition() { mPartitionType = LLPipeline::PARTITION_HUD; mDrawableType = LLPipeline::RENDER_TYPE_HUD; mSlopRatio = 0.f; mLODPeriod = 16; } void LLHUDPartition::shift(const LLVector3 &offset) { //HUD objects don't shift with region crossing. That would be silly. }