/** * @file llvocache.cpp * @brief Cache of objects on the viewer. * * $LicenseInfo:firstyear=2003&license=viewerlgpl$ * Second Life Viewer Source Code * Copyright (C) 2010, Linden Research, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; * version 2.1 of the License only. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with this library; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * Linden Research, Inc., 945 Battery Street, San Francisco, CA 94111 USA * $/LicenseInfo$ */ #include "llviewerprecompiledheaders.h" #include "llvocache.h" #include "llerror.h" #include "llregionhandle.h" #include "llviewercontrol.h" #include "llviewerobjectlist.h" #include "lldrawable.h" #include "llviewerregion.h" #include "pipeline.h" BOOL check_read(LLAPRFile* apr_file, void* src, S32 n_bytes) { return apr_file->read(src, n_bytes) == n_bytes ; } BOOL check_write(LLAPRFile* apr_file, void* src, S32 n_bytes) { return apr_file->write(src, n_bytes) == n_bytes ; } //--------------------------------------------------------------------------- // LLVOCacheEntry //--------------------------------------------------------------------------- LLVOCacheEntry::LLVOCacheEntry(U32 local_id, U32 crc, LLDataPackerBinaryBuffer &dp) : LLViewerOctreeEntryData(LLViewerOctreeEntry::LLVOCACHEENTRY), mLocalID(local_id), mCRC(crc), mHitCount(0), mDupeCount(0), mCRCChangeCount(0), mState(INACTIVE), mRepeatedVisCounter(0), mVisFrameRange(64), mSceneContrib(0.f) { mBuffer = new U8[dp.getBufferSize()]; mDP.assignBuffer(mBuffer, dp.getBufferSize()); mDP = dp; if(dp.getBufferSize() > 0) { U32 parent_id = 0; dp.reset(); dp.unpackU32(parent_id, "ParentID"); dp.reset(); if(parent_id > 0) { mState |= CHILD; //is a child } } } LLVOCacheEntry::LLVOCacheEntry() : LLViewerOctreeEntryData(LLViewerOctreeEntry::LLVOCACHEENTRY), mLocalID(0), mCRC(0), mHitCount(0), mDupeCount(0), mCRCChangeCount(0), mBuffer(NULL), mState(INACTIVE), mRepeatedVisCounter(0), mVisFrameRange(64), mSceneContrib(0.f) { mDP.assignBuffer(mBuffer, 0); } LLVOCacheEntry::LLVOCacheEntry(LLAPRFile* apr_file) : LLViewerOctreeEntryData(LLViewerOctreeEntry::LLVOCACHEENTRY), mBuffer(NULL), mState(INACTIVE), mRepeatedVisCounter(0), mVisFrameRange(64), mSceneContrib(0.f) { S32 size = -1; BOOL success; mDP.assignBuffer(mBuffer, 0); setOctreeEntry(NULL); success = check_read(apr_file, &mLocalID, sizeof(U32)); if(success) { success = check_read(apr_file, &mCRC, sizeof(U32)); } if(success) { success = check_read(apr_file, &mHitCount, sizeof(S32)); } if(success) { success = check_read(apr_file, &mDupeCount, sizeof(S32)); } if(success) { success = check_read(apr_file, &mCRCChangeCount, sizeof(S32)); } if(success) { success = check_read(apr_file, &mState, sizeof(U32)); } if(success) { F32 ext[8]; success = check_read(apr_file, (void*)ext, sizeof(F32) * 8); LLVector4a exts[2]; exts[0].load4a(ext); exts[1].load4a(&ext[4]); setSpatialExtents(exts[0], exts[1]); } if(success) { LLVector4 pos; success = check_read(apr_file, (void*)pos.mV, sizeof(LLVector4)); LLVector4a pos_; pos_.load4a(pos.mV); setPositionGroup(pos_); } if(success) { F32 rad; success = check_read(apr_file, &rad, sizeof(F32)); setBinRadius(rad); } if(success) { success = check_read(apr_file, &size, sizeof(S32)); // Corruption in the cache entries if ((size > 10000) || (size < 1)) { // We've got a bogus size, skip reading it. // We won't bother seeking, because the rest of this file // is likely bogus, and will be tossed anyway. llwarns << "Bogus cache entry, size " << size << ", aborting!" << llendl; success = FALSE; } } if(success && size > 0) { mBuffer = new U8[size]; success = check_read(apr_file, mBuffer, size); if(success) { mDP.assignBuffer(mBuffer, size); } else { delete[] mBuffer ; mBuffer = NULL ; } } if(!success) { mLocalID = 0; mCRC = 0; mHitCount = 0; mDupeCount = 0; mCRCChangeCount = 0; mBuffer = NULL; mEntry = NULL; mState = 0; } } LLVOCacheEntry::~LLVOCacheEntry() { mDP.freeBuffer(); //llassert(mState == INACTIVE); } //virtual void LLVOCacheEntry::setOctreeEntry(LLViewerOctreeEntry* entry) { if(!entry && mDP.getBufferSize() > 0) { LLUUID fullid; mDP.reset(); mDP.unpackUUID(fullid, "ID"); mDP.reset(); LLViewerObject* obj = gObjectList.findObject(fullid); if(obj && obj->mDrawable) { entry = obj->mDrawable->getEntry(); } } LLViewerOctreeEntryData::setOctreeEntry(entry); } void LLVOCacheEntry::setBridgeChild() { mState |= BRIDGE_CHILD; } void LLVOCacheEntry::clearBridgeChild() { mState &= ~BRIDGE_CHILD; } void LLVOCacheEntry::copyTo(LLVOCacheEntry* new_entry) { //copy LLViewerOctreeEntry if(mEntry.notNull()) { new_entry->setOctreeEntry(mEntry); mEntry = NULL; } //copy children S32 num_children = getNumOfChildren(); for(S32 i = 0; i < num_children; i++) { new_entry->addChild(getChild(i)); } } void LLVOCacheEntry::setState(U32 state) { mState &= 0xffff0000; //clear the low 16 bits state &= 0x0000ffff; //clear the high 16 bits; mState |= state; if(getState() == ACTIVE) { const S32 MIN_REAVTIVE_INTERVAL = 20; U32 last_visible = getVisible(); setVisible(); if(getVisible() - last_visible < MIN_REAVTIVE_INTERVAL + mVisFrameRange) { mRepeatedVisCounter++; } else { mRepeatedVisCounter = 0; mVisFrameRange = 64; } if(mRepeatedVisCounter > 2) { //if repeatedly becomes visible immediately after invisible, enlarge the visible frame range mRepeatedVisCounter = 0; mVisFrameRange *= 2; } } } //virtual S32 LLVOCacheEntry::getMinVisFrameRange()const { return mVisFrameRange; } void LLVOCacheEntry::addChild(LLVOCacheEntry* entry) { llassert(entry != NULL); mChildrenList.push_back(entry); } LLDataPackerBinaryBuffer *LLVOCacheEntry::getDP(U32 crc) { if ( (mCRC != crc) ||(mDP.getBufferSize() == 0)) { //llinfos << "Not getting cache entry, invalid!" << llendl; return NULL; } mHitCount++; return &mDP; } LLDataPackerBinaryBuffer *LLVOCacheEntry::getDP() { if (mDP.getBufferSize() == 0) { //llinfos << "Not getting cache entry, invalid!" << llendl; return NULL; } return &mDP; } void LLVOCacheEntry::recordHit() { mHitCount++; } void LLVOCacheEntry::dump() const { llinfos << "local " << mLocalID << " crc " << mCRC << " hits " << mHitCount << " dupes " << mDupeCount << " change " << mCRCChangeCount << llendl; } BOOL LLVOCacheEntry::writeToFile(LLAPRFile* apr_file) const { if(!mEntry) { return FALSE; } BOOL success; success = check_write(apr_file, (void*)&mLocalID, sizeof(U32)); if(success) { success = check_write(apr_file, (void*)&mCRC, sizeof(U32)); } if(success) { success = check_write(apr_file, (void*)&mHitCount, sizeof(S32)); } if(success) { success = check_write(apr_file, (void*)&mDupeCount, sizeof(S32)); } if(success) { success = check_write(apr_file, (void*)&mCRCChangeCount, sizeof(S32)); } if(success) { U32 state = mState & 0xffff0000; //only store the high 16 bits. success = check_write(apr_file, (void*)&state, sizeof(U32)); } if(success) { const LLVector4a* exts = getSpatialExtents() ; LLVector4 ext(exts[0][0], exts[0][1], exts[0][2], exts[0][3]); success = check_write(apr_file, ext.mV, sizeof(LLVector4)); if(success) { ext.set(exts[1][0], exts[1][1], exts[1][2], exts[1][3]); success = check_write(apr_file, ext.mV, sizeof(LLVector4)); } } if(success) { const LLVector4a pos_ = getPositionGroup() ; LLVector4 pos(pos_[0], pos_[1], pos_[2], pos_[3]); success = check_write(apr_file, pos.mV, sizeof(LLVector4)); } if(success) { F32 rad = getBinRadius(); success = check_write(apr_file, (void*)&rad, sizeof(F32)); } if(success) { S32 size = mDP.getBufferSize(); success = check_write(apr_file, (void*)&size, sizeof(S32)); if(success) { success = check_write(apr_file, (void*)mBuffer, size); } } return success ; } void LLVOCacheEntry::calcSceneContribution(const LLVector3& camera_origin, bool needs_update, U32 last_update) { if(!needs_update && getVisible() >= last_update) { return; //no need to update } const LLVector4a& center = getPositionGroup(); LLVector4a origin; origin.load3(camera_origin.mV); LLVector4a lookAt; lookAt.setSub(center, origin); F32 squared_dist = lookAt.dot3(lookAt).getF32(); F32 rad = getBinRadius(); mSceneContrib = rad * rad / squared_dist; setVisible(); } U32 LLVOCacheEntry::getParentID() { if(!(mState & CHILD)) { return 0; //not a child } U32 parent_id = 0; LLDataPackerBinaryBuffer* dp = getDP(); if(dp) { dp->reset(); dp->unpackU32(parent_id, "ParentID"); dp->reset(); } return parent_id; } //------------------------------------------------------------------- //LLVOCachePartition //------------------------------------------------------------------- LLVOCachePartition::LLVOCachePartition(LLViewerRegion* regionp) { mRegionp = regionp; mPartitionType = LLViewerRegion::PARTITION_VO_CACHE; mVisitedTime = 0; new LLviewerOctreeGroup(mOctree); } void LLVOCachePartition::addEntry(LLViewerOctreeEntry* entry) { llassert(entry->hasVOCacheEntry()); mOctree->insert(entry); } void LLVOCachePartition::removeEntry(LLViewerOctreeEntry* entry) { entry->getVOCacheEntry()->setGroup(NULL); llassert(!entry->getGroup()); } class LLVOCacheOctreeCull : public LLViewerOctreeCull { public: LLVOCacheOctreeCull(LLCamera* camera, LLViewerRegion* regionp) : LLViewerOctreeCull(camera), mRegionp(regionp) {} virtual S32 frustumCheck(const LLviewerOctreeGroup* group) { S32 res = AABBInFrustumNoFarClipGroupBounds(group); if (res != 0) { res = llmin(res, AABBSphereIntersectGroupExtents(group)); } return res; } virtual S32 frustumCheckObjects(const LLviewerOctreeGroup* group) { S32 res = AABBInFrustumNoFarClipObjectBounds(group); if (res != 0) { res = llmin(res, AABBSphereIntersectObjectExtents(group)); } return res; } virtual void processGroup(LLviewerOctreeGroup* base_group) { mRegionp->addVisibleGroup(base_group); } private: LLViewerRegion* mRegionp; }; S32 LLVOCachePartition::cull(LLCamera &camera) { if(mVisitedTime == LLViewerOctreeEntryData::getCurrentFrame()) { return 0; //already visited. } mVisitedTime = LLViewerOctreeEntryData::getCurrentFrame(); ((LLviewerOctreeGroup*)mOctree->getListener(0))->rebound(); LLVOCacheOctreeCull culler(&camera, mRegionp); culler.traverse(mOctree); return 0; } //------------------------------------------------------------------- //LLVOCache //------------------------------------------------------------------- // Format string used to construct filename for the object cache static const char OBJECT_CACHE_FILENAME[] = "objects_%d_%d.slc"; const U32 MAX_NUM_OBJECT_ENTRIES = 128 ; const U32 MIN_ENTRIES_TO_PURGE = 16 ; const U32 INVALID_TIME = 0 ; const char* object_cache_dirname = "objectcache"; const char* header_filename = "object.cache"; LLVOCache* LLVOCache::sInstance = NULL; //static LLVOCache* LLVOCache::getInstance() { if(!sInstance) { sInstance = new LLVOCache() ; } return sInstance ; } //static BOOL LLVOCache::hasInstance() { return sInstance != NULL ; } //static void LLVOCache::destroyClass() { if(sInstance) { delete sInstance ; sInstance = NULL ; } } LLVOCache::LLVOCache(): mInitialized(FALSE), mReadOnly(TRUE), mNumEntries(0), mCacheSize(1) { mEnabled = gSavedSettings.getBOOL("ObjectCacheEnabled"); mLocalAPRFilePoolp = new LLVolatileAPRPool() ; } LLVOCache::~LLVOCache() { if(mEnabled) { writeCacheHeader(); clearCacheInMemory(); } delete mLocalAPRFilePoolp; } void LLVOCache::setDirNames(ELLPath location) { mHeaderFileName = gDirUtilp->getExpandedFilename(location, object_cache_dirname, header_filename); mObjectCacheDirName = gDirUtilp->getExpandedFilename(location, object_cache_dirname); } void LLVOCache::initCache(ELLPath location, U32 size, U32 cache_version) { if(!mEnabled) { llwarns << "Not initializing cache: Cache is currently disabled." << llendl; return ; } if(mInitialized) { llwarns << "Cache already initialized." << llendl; return ; } mInitialized = TRUE ; setDirNames(location); if (!mReadOnly) { LLFile::mkdir(mObjectCacheDirName); } mCacheSize = llclamp(size, MIN_ENTRIES_TO_PURGE, MAX_NUM_OBJECT_ENTRIES); mMetaInfo.mVersion = cache_version; readCacheHeader(); if(mMetaInfo.mVersion != cache_version) { mMetaInfo.mVersion = cache_version ; if(mReadOnly) //disable cache { clearCacheInMemory(); } else //delete the current cache if the format does not match. { removeCache(); } } } void LLVOCache::removeCache(ELLPath location) { if(mReadOnly) { llwarns << "Not removing cache at " << location << ": Cache is currently in read-only mode." << llendl; return ; } llinfos << "about to remove the object cache due to settings." << llendl ; std::string mask = "*"; std::string cache_dir = gDirUtilp->getExpandedFilename(location, object_cache_dirname); llinfos << "Removing cache at " << cache_dir << llendl; gDirUtilp->deleteFilesInDir(cache_dir, mask); //delete all files LLFile::rmdir(cache_dir); clearCacheInMemory(); mInitialized = FALSE ; } void LLVOCache::removeCache() { llassert_always(mInitialized) ; if(mReadOnly) { llwarns << "Not clearing object cache: Cache is currently in read-only mode." << llendl; return ; } llinfos << "about to remove the object cache due to some error." << llendl ; std::string mask = "*"; llinfos << "Removing cache at " << mObjectCacheDirName << llendl; gDirUtilp->deleteFilesInDir(mObjectCacheDirName, mask); clearCacheInMemory() ; writeCacheHeader(); } void LLVOCache::removeEntry(HeaderEntryInfo* entry) { llassert_always(mInitialized) ; if(mReadOnly) { return ; } if(!entry) { return ; } header_entry_queue_t::iterator iter = mHeaderEntryQueue.find(entry) ; if(iter != mHeaderEntryQueue.end()) { mHandleEntryMap.erase(entry->mHandle) ; mHeaderEntryQueue.erase(iter) ; removeFromCache(entry) ; delete entry ; mNumEntries = mHandleEntryMap.size() ; } } void LLVOCache::removeEntry(U64 handle) { handle_entry_map_t::iterator iter = mHandleEntryMap.find(handle) ; if(iter == mHandleEntryMap.end()) //no cache { return ; } HeaderEntryInfo* entry = iter->second ; removeEntry(entry) ; } void LLVOCache::clearCacheInMemory() { if(!mHeaderEntryQueue.empty()) { for(header_entry_queue_t::iterator iter = mHeaderEntryQueue.begin(); iter != mHeaderEntryQueue.end(); ++iter) { delete *iter ; } mHeaderEntryQueue.clear(); mHandleEntryMap.clear(); mNumEntries = 0 ; } } void LLVOCache::getObjectCacheFilename(U64 handle, std::string& filename) { U32 region_x, region_y; grid_from_region_handle(handle, ®ion_x, ®ion_y); filename = gDirUtilp->getExpandedFilename(LL_PATH_CACHE, object_cache_dirname, llformat(OBJECT_CACHE_FILENAME, region_x, region_y)); return ; } void LLVOCache::removeFromCache(HeaderEntryInfo* entry) { if(mReadOnly) { llwarns << "Not removing cache for handle " << entry->mHandle << ": Cache is currently in read-only mode." << llendl; return ; } std::string filename; getObjectCacheFilename(entry->mHandle, filename); LLAPRFile::remove(filename, mLocalAPRFilePoolp); entry->mTime = INVALID_TIME ; updateEntry(entry) ; //update the head file. } void LLVOCache::readCacheHeader() { if(!mEnabled) { llwarns << "Not reading cache header: Cache is currently disabled." << llendl; return; } //clear stale info. clearCacheInMemory(); bool success = true ; if (LLAPRFile::isExist(mHeaderFileName, mLocalAPRFilePoolp)) { LLAPRFile apr_file(mHeaderFileName, APR_READ|APR_BINARY, mLocalAPRFilePoolp); //read the meta element success = check_read(&apr_file, &mMetaInfo, sizeof(HeaderMetaInfo)) ; if(success) { HeaderEntryInfo* entry = NULL ; mNumEntries = 0 ; U32 num_read = 0 ; while(num_read++ < MAX_NUM_OBJECT_ENTRIES) { if(!entry) { entry = new HeaderEntryInfo() ; } success = check_read(&apr_file, entry, sizeof(HeaderEntryInfo)); if(!success) //failed { llwarns << "Error reading cache header entry. (entry_index=" << mNumEntries << ")" << llendl; delete entry ; entry = NULL ; break ; } else if(entry->mTime == INVALID_TIME) { continue ; //an empty entry } entry->mIndex = mNumEntries++ ; mHeaderEntryQueue.insert(entry) ; mHandleEntryMap[entry->mHandle] = entry ; entry = NULL ; } if(entry) { delete entry ; } } //--------- //debug code //---------- //std::string name ; //for(header_entry_queue_t::iterator iter = mHeaderEntryQueue.begin() ; success && iter != mHeaderEntryQueue.end(); ++iter) //{ // getObjectCacheFilename((*iter)->mHandle, name) ; // llinfos << name << llendl ; //} //----------- } else { writeCacheHeader() ; } if(!success) { removeCache() ; //failed to read header, clear the cache } else if(mNumEntries >= mCacheSize) { purgeEntries(mCacheSize) ; } return ; } void LLVOCache::writeCacheHeader() { if (!mEnabled) { llwarns << "Not writing cache header: Cache is currently disabled." << llendl; return; } if(mReadOnly) { llwarns << "Not writing cache header: Cache is currently in read-only mode." << llendl; return; } bool success = true ; { LLAPRFile apr_file(mHeaderFileName, APR_CREATE|APR_WRITE|APR_BINARY, mLocalAPRFilePoolp); //write the meta element success = check_write(&apr_file, &mMetaInfo, sizeof(HeaderMetaInfo)) ; mNumEntries = 0 ; for(header_entry_queue_t::iterator iter = mHeaderEntryQueue.begin() ; success && iter != mHeaderEntryQueue.end(); ++iter) { (*iter)->mIndex = mNumEntries++ ; success = check_write(&apr_file, (void*)*iter, sizeof(HeaderEntryInfo)); } mNumEntries = mHeaderEntryQueue.size() ; if(success && mNumEntries < MAX_NUM_OBJECT_ENTRIES) { HeaderEntryInfo* entry = new HeaderEntryInfo() ; entry->mTime = INVALID_TIME ; for(S32 i = mNumEntries ; success && i < MAX_NUM_OBJECT_ENTRIES ; i++) { //fill the cache with the default entry. success = check_write(&apr_file, entry, sizeof(HeaderEntryInfo)) ; } delete entry ; } } if(!success) { clearCacheInMemory() ; mReadOnly = TRUE ; //disable the cache. } return ; } BOOL LLVOCache::updateEntry(const HeaderEntryInfo* entry) { LLAPRFile apr_file(mHeaderFileName, APR_WRITE|APR_BINARY, mLocalAPRFilePoolp); apr_file.seek(APR_SET, entry->mIndex * sizeof(HeaderEntryInfo) + sizeof(HeaderMetaInfo)) ; return check_write(&apr_file, (void*)entry, sizeof(HeaderEntryInfo)) ; } void LLVOCache::readFromCache(U64 handle, const LLUUID& id, LLVOCacheEntry::vocache_entry_map_t& cache_entry_map) { if(!mEnabled) { llwarns << "Not reading cache for handle " << handle << "): Cache is currently disabled." << llendl; return ; } llassert_always(mInitialized); handle_entry_map_t::iterator iter = mHandleEntryMap.find(handle) ; if(iter == mHandleEntryMap.end()) //no cache { llwarns << "No handle map entry for " << handle << llendl; return ; } bool success = true ; { std::string filename; getObjectCacheFilename(handle, filename); LLAPRFile apr_file(filename, APR_READ|APR_BINARY, mLocalAPRFilePoolp); LLUUID cache_id ; success = check_read(&apr_file, cache_id.mData, UUID_BYTES) ; if(success) { if(cache_id != id) { llinfos << "Cache ID doesn't match for this region, discarding"<< llendl; success = false ; } if(success) { S32 num_entries; success = check_read(&apr_file, &num_entries, sizeof(S32)) ; if(success) { for (S32 i = 0; i < num_entries; i++) { LLPointer entry = new LLVOCacheEntry(&apr_file); if (!entry->getLocalID()) { llwarns << "Aborting cache file load for " << filename << ", cache file corruption!" << llendl; success = false ; break ; } cache_entry_map[entry->getLocalID()] = entry; } } } } } if(!success) { if(cache_entry_map.empty()) { removeEntry(iter->second) ; } } return ; } void LLVOCache::purgeEntries(U32 size) { while(mHeaderEntryQueue.size() > size) { header_entry_queue_t::iterator iter = mHeaderEntryQueue.begin() ; HeaderEntryInfo* entry = *iter ; mHandleEntryMap.erase(entry->mHandle); mHeaderEntryQueue.erase(iter) ; removeFromCache(entry) ; delete entry; } mNumEntries = mHandleEntryMap.size() ; } void LLVOCache::writeToCache(U64 handle, const LLUUID& id, const LLVOCacheEntry::vocache_entry_map_t& cache_entry_map, BOOL dirty_cache) { if(!mEnabled) { llwarns << "Not writing cache for handle " << handle << "): Cache is currently disabled." << llendl; return ; } llassert_always(mInitialized); if(mReadOnly) { llwarns << "Not writing cache for handle " << handle << "): Cache is currently in read-only mode." << llendl; return ; } HeaderEntryInfo* entry; handle_entry_map_t::iterator iter = mHandleEntryMap.find(handle) ; if(iter == mHandleEntryMap.end()) //new entry { if(mNumEntries >= mCacheSize - 1) { purgeEntries(mCacheSize - 1) ; } entry = new HeaderEntryInfo(); entry->mHandle = handle ; entry->mTime = time(NULL) ; entry->mIndex = mNumEntries++; mHeaderEntryQueue.insert(entry) ; mHandleEntryMap[handle] = entry ; } else { // Update access time. entry = iter->second ; //resort mHeaderEntryQueue.erase(entry) ; entry->mTime = time(NULL) ; mHeaderEntryQueue.insert(entry) ; } //update cache header if(!updateEntry(entry)) { llwarns << "Failed to update cache header index " << entry->mIndex << ". handle = " << handle << llendl; return ; //update failed. } if(!dirty_cache) { llwarns << "Skipping write to cache for handle " << handle << ": cache not dirty" << llendl; return ; //nothing changed, no need to update. } //write to cache file bool success = true ; { std::string filename; getObjectCacheFilename(handle, filename); LLAPRFile apr_file(filename, APR_CREATE|APR_WRITE|APR_BINARY, mLocalAPRFilePoolp); success = check_write(&apr_file, (void*)id.mData, UUID_BYTES) ; if(success) { S32 num_entries = cache_entry_map.size() ; success = check_write(&apr_file, &num_entries, sizeof(S32)); for (LLVOCacheEntry::vocache_entry_map_t::const_iterator iter = cache_entry_map.begin(); success && iter != cache_entry_map.end(); ++iter) { success = iter->second->writeToFile(&apr_file) ; } } } if(!success) { removeEntry(entry) ; } return ; }