_data_mgr_8cpp_source.html

 /*
  * Copyright 2020 OmniSci, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "DataMgr/DataMgr.h"
 #include "BufferMgr/CpuBufferMgr/CpuBufferMgr.h"
 #include "BufferMgr/GpuCudaBufferMgr/GpuCudaBufferMgr.h"
 #include "CudaMgr/CudaMgr.h"
 #include "FileMgr/GlobalFileMgr.h"
 #include "PersistentStorageMgr/PersistentStorageMgr.h"

 #ifdef __APPLE__
 #include <sys/sysctl.h>
 #include <sys/types.h>
 #else
 #include <unistd.h>
 #endif

 #include <boost/filesystem.hpp>

 #include <algorithm>
 #include <limits>

 using namespace std;
 using namespace Buffer_Namespace;
 using namespace File_Namespace;

 extern bool g_enable_fsi;

 namespace Data_Namespace {

 DataMgr::DataMgr(const string& dataDir,
                  const SystemParameters& system_parameters,
                  const bool useGpus,
                  const int numGpus,
                  const int startGpu,
                  const size_t reservedGpuMem,
                  const size_t numReaderThreads,
                  const DiskCacheConfig cache_config)
     : dataDir_(dataDir) {
   if (useGpus) {
     try {
       cudaMgr_ = std::make_unique<CudaMgr_Namespace::CudaMgr>(numGpus, startGpu);
       reservedGpuMem_ = reservedGpuMem;
       hasGpus_ = true;
     } catch (const std::exception& e) {
       LOG(ERROR) << "Unable to instantiate CudaMgr, falling back to CPU-only mode. "
                  << e.what();
       hasGpus_ = false;
     }
   } else {
     hasGpus_ = false;
   }

   populateMgrs(system_parameters, numReaderThreads, cache_config);
   createTopLevelMetadata();
 }

 DataMgr::~DataMgr() {
   int numLevels = bufferMgrs_.size();
   for (int level = numLevels - 1; level >= 0; --level) {
     for (size_t device = 0; device < bufferMgrs_[level].size(); device++) {
       delete bufferMgrs_[level][device];
     }
   }
 }

 DataMgr::SystemMemoryUsage DataMgr::getSystemMemoryUsage() const {
   SystemMemoryUsage usage;

 #ifdef __linux__

   // Determine Linux available memory and total memory.
   // Available memory is different from free memory because
   // when Linux sees free memory, it tries to use it for
   // stuff like disk caching. However, the memory is not
   // reserved and is still available to be allocated by
   // user processes.
   // Parsing /proc/meminfo for this info isn't very elegant
   // but as a virtual file it should be reasonably fast.
   // See also:
   //   https://github.com/torvalds/linux/commit/34e431b0ae398fc54ea69ff85ec700722c9da773
   ProcMeminfoParser mi;
   usage.free = mi["MemAvailable"];
   usage.total = mi["MemTotal"];

   // Determine process memory in use.
   // See also:
   //   https://stackoverflow.com/questions/669438/how-to-get-memory-usage-at-runtime-using-c
   //   http://man7.org/linux/man-pages/man5/proc.5.html
   int64_t size = 0;
   int64_t resident = 0;
   int64_t shared = 0;

   std::ifstream fstatm("/proc/self/statm");
   fstatm >> size >> resident >> shared;
   fstatm.close();

   long page_size =
       sysconf(_SC_PAGE_SIZE);  // in case x86-64 is configured to use 2MB pages

   usage.resident = resident * page_size;
   usage.vtotal = size * page_size;
   usage.regular = (resident - shared) * page_size;
   usage.shared = shared * page_size;

   ProcBuddyinfoParser bi;
   usage.frag = bi.getFragmentationPercent();

 #else

   usage.total = 0;
   usage.free = 0;
   usage.resident = 0;
   usage.vtotal = 0;
   usage.regular = 0;
   usage.shared = 0;
   usage.frag = 0;

 #endif

   return usage;
 }

 size_t DataMgr::getTotalSystemMemory() {
 #ifdef __APPLE__
   int mib[2];
   size_t physical_memory;
   size_t length;
   // Get the Physical memory size
   mib[0] = CTL_HW;
   mib[1] = HW_MEMSIZE;
   length = sizeof(size_t);
   sysctl(mib, 2, &physical_memory, &length, NULL, 0);
   return physical_memory;

 #else  // Linux
   long pages = sysconf(_SC_PHYS_PAGES);
   long page_size = sysconf(_SC_PAGE_SIZE);
   return pages * page_size;
 #endif
 }

 // This function exists for testing purposes so that we can test a reset of the cache.
 void DataMgr::resetPersistentStorage(const DiskCacheConfig& cache_config,
                                      const size_t num_reader_threads,
                                      const SystemParameters& sys_params) {
   int numLevels = bufferMgrs_.size();
   for (int level = numLevels - 1; level >= 0; --level) {
     for (size_t device = 0; device < bufferMgrs_[level].size(); device++) {
       delete bufferMgrs_[level][device];
     }
   }
   bufferMgrs_.clear();
   populateMgrs(sys_params, num_reader_threads, cache_config);
   createTopLevelMetadata();
 }

 void DataMgr::populateMgrs(const SystemParameters& system_parameters,
                            const size_t userSpecifiedNumReaderThreads,
                            const DiskCacheConfig& cache_config) {
   // no need for locking, as this is only called in the constructor
   bufferMgrs_.resize(2);
   if (g_enable_fsi) {
     bufferMgrs_[0].push_back(
         new PersistentStorageMgr(dataDir_, userSpecifiedNumReaderThreads, cache_config));
   } else {
     bufferMgrs_[0].push_back(
         new GlobalFileMgr(0, dataDir_, userSpecifiedNumReaderThreads));
   }
   levelSizes_.push_back(1);
   size_t page_size{512};
   size_t cpuBufferSize = system_parameters.cpu_buffer_mem_bytes;
   if (cpuBufferSize == 0) {  // if size is not specified
     const auto total_system_memory = getTotalSystemMemory();
     VLOG(1) << "Detected " << (float)total_system_memory / (1024 * 1024)
             << "M of total system memory.";
     cpuBufferSize = total_system_memory *
                     0.8;  // should get free memory instead of this ugly heuristic
   }
   size_t minCpuSlabSize = std::min(system_parameters.min_cpu_slab_size, cpuBufferSize);
   minCpuSlabSize = (minCpuSlabSize / page_size) * page_size;
   size_t maxCpuSlabSize = std::min(system_parameters.max_cpu_slab_size, cpuBufferSize);
   maxCpuSlabSize = (maxCpuSlabSize / page_size) * page_size;
   LOG(INFO) << "Min CPU Slab Size is " << (float)minCpuSlabSize / (1024 * 1024) << "MB";
   LOG(INFO) << "Max CPU Slab Size is " << (float)maxCpuSlabSize / (1024 * 1024) << "MB";
   LOG(INFO) << "Max memory pool size for CPU is " << (float)cpuBufferSize / (1024 * 1024)
             << "MB";
   if (hasGpus_) {
     LOG(INFO) << "Reserved GPU memory is " << (float)reservedGpuMem_ / (1024 * 1024)
               << "MB includes render buffer allocation";
     bufferMgrs_.resize(3);
     bufferMgrs_[1].push_back(new CpuBufferMgr(0,
                                               cpuBufferSize,
                                               cudaMgr_.get(),
                                               minCpuSlabSize,
                                               maxCpuSlabSize,
                                               page_size,
                                               bufferMgrs_[0][0]));
     levelSizes_.push_back(1);
     int numGpus = cudaMgr_->getDeviceCount();
     for (int gpuNum = 0; gpuNum < numGpus; ++gpuNum) {
       size_t gpuMaxMemSize =
           system_parameters.gpu_buffer_mem_bytes != 0
               ? system_parameters.gpu_buffer_mem_bytes
               : (cudaMgr_->getDeviceProperties(gpuNum)->globalMem) - (reservedGpuMem_);
       size_t minGpuSlabSize =
           std::min(system_parameters.min_gpu_slab_size, gpuMaxMemSize);
       minGpuSlabSize = (minGpuSlabSize / page_size) * page_size;
       size_t maxGpuSlabSize =
           std::min(system_parameters.max_gpu_slab_size, gpuMaxMemSize);
       maxGpuSlabSize = (maxGpuSlabSize / page_size) * page_size;
       LOG(INFO) << "Min GPU Slab size for GPU " << gpuNum << " is "
                 << (float)minGpuSlabSize / (1024 * 1024) << "MB";
       LOG(INFO) << "Max GPU Slab size for GPU " << gpuNum << " is "
                 << (float)maxGpuSlabSize / (1024 * 1024) << "MB";
       LOG(INFO) << "Max memory pool size for GPU " << gpuNum << " is "
                 << (float)gpuMaxMemSize / (1024 * 1024) << "MB";
       bufferMgrs_[2].push_back(new GpuCudaBufferMgr(gpuNum,
                                                     gpuMaxMemSize,
                                                     cudaMgr_.get(),
                                                     minGpuSlabSize,
                                                     maxGpuSlabSize,
                                                     page_size,
                                                     bufferMgrs_[1][0]));
     }
     levelSizes_.push_back(numGpus);
   } else {
     bufferMgrs_[1].push_back(new CpuBufferMgr(0,
                                               cpuBufferSize,
                                               cudaMgr_.get(),
                                               minCpuSlabSize,
                                               maxCpuSlabSize,
                                               page_size,
                                               bufferMgrs_[0][0]));
     levelSizes_.push_back(1);
   }
 }

 void DataMgr::convertDB(const std::string basePath) {
   // no need for locking, as this is only called in the constructor

   /* check that "mapd_data" directory exists and it's empty */
   std::string mapdDataPath(basePath + "/../mapd_data/");
   boost::filesystem::path path(mapdDataPath);
   if (boost::filesystem::exists(path)) {
     if (!boost::filesystem::is_directory(path)) {
       LOG(FATAL) << "Path to directory mapd_data to convert DB is not a directory.";
     }
   } else {  // data directory does not exist
     LOG(FATAL) << "Path to directory mapd_data to convert DB does not exist.";
   }

   GlobalFileMgr* gfm;
   if (g_enable_fsi) {
     gfm = dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getGlobalFileMgr();
   } else {
     gfm = dynamic_cast<GlobalFileMgr*>(bufferMgrs_[0][0]);
   }
   size_t defaultPageSize = gfm->getDefaultPageSize();
   LOG(INFO) << "Database conversion started.";
   FileMgr* fm_base_db =
       new FileMgr(gfm,
                   defaultPageSize,
                   basePath);  // this call also copies data into new DB structure
   delete fm_base_db;

   /* write content of DB into newly created/converted DB structure & location */
   checkpoint();  // outputs data files as well as metadata files
   LOG(INFO) << "Database conversion completed.";
 }

 void DataMgr::createTopLevelMetadata()
     const {  // create metadata shared by all tables of all DBs
   ChunkKey chunkKey(2);
   chunkKey[0] = 0;  // top level db_id
   chunkKey[1] = 0;  // top level tb_id

   GlobalFileMgr* gfm;
   if (g_enable_fsi) {
     gfm = dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getGlobalFileMgr();
   } else {
     gfm = dynamic_cast<GlobalFileMgr*>(bufferMgrs_[0][0]);
   }
   auto fm_top = gfm->getFileMgr(chunkKey);
   if (dynamic_cast<File_Namespace::FileMgr*>(fm_top)) {
     static_cast<File_Namespace::FileMgr*>(fm_top)->createTopLevelMetadata();
   }
 }

 std::vector<MemoryInfo> DataMgr::getMemoryInfo(const MemoryLevel memLevel) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);

   std::vector<MemoryInfo> mem_info;
   if (memLevel == MemoryLevel::CPU_LEVEL) {
     CpuBufferMgr* cpu_buffer =
         dynamic_cast<CpuBufferMgr*>(bufferMgrs_[MemoryLevel::CPU_LEVEL][0]);
     CHECK(cpu_buffer);
     MemoryInfo mi;

     mi.pageSize = cpu_buffer->getPageSize();
     mi.maxNumPages = cpu_buffer->getMaxSize() / mi.pageSize;
     mi.isAllocationCapped = cpu_buffer->isAllocationCapped();
     mi.numPageAllocated = cpu_buffer->getAllocated() / mi.pageSize;

     const auto& slab_segments = cpu_buffer->getSlabSegments();
     for (size_t slab_num = 0; slab_num < slab_segments.size(); ++slab_num) {
       for (auto segment : slab_segments[slab_num]) {
         MemoryData md;
         md.slabNum = slab_num;
         md.startPage = segment.start_page;
         md.numPages = segment.num_pages;
         md.touch = segment.last_touched;
         md.memStatus = segment.mem_status;
         md.chunk_key.insert(
             md.chunk_key.end(), segment.chunk_key.begin(), segment.chunk_key.end());
         mi.nodeMemoryData.push_back(md);
       }
     }
     mem_info.push_back(mi);
   } else if (hasGpus_) {
     int numGpus = cudaMgr_->getDeviceCount();
     for (int gpuNum = 0; gpuNum < numGpus; ++gpuNum) {
       GpuCudaBufferMgr* gpu_buffer =
           dynamic_cast<GpuCudaBufferMgr*>(bufferMgrs_[MemoryLevel::GPU_LEVEL][gpuNum]);
       CHECK(gpu_buffer);
       MemoryInfo mi;

       mi.pageSize = gpu_buffer->getPageSize();
       mi.maxNumPages = gpu_buffer->getMaxSize() / mi.pageSize;
       mi.isAllocationCapped = gpu_buffer->isAllocationCapped();
       mi.numPageAllocated = gpu_buffer->getAllocated() / mi.pageSize;

       const auto& slab_segments = gpu_buffer->getSlabSegments();
       for (size_t slab_num = 0; slab_num < slab_segments.size(); ++slab_num) {
         for (auto segment : slab_segments[slab_num]) {
           MemoryData md;
           md.slabNum = slab_num;
           md.startPage = segment.start_page;
           md.numPages = segment.num_pages;
           md.touch = segment.last_touched;
           md.chunk_key.insert(
               md.chunk_key.end(), segment.chunk_key.begin(), segment.chunk_key.end());
           md.memStatus = segment.mem_status;
           mi.nodeMemoryData.push_back(md);
         }
       }
       mem_info.push_back(mi);
     }
   }
   return mem_info;
 }

 std::string DataMgr::dumpLevel(const MemoryLevel memLevel) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);

   // if gpu we need to iterate through all the buffermanagers for each card
   if (memLevel == MemoryLevel::GPU_LEVEL) {
     int numGpus = cudaMgr_->getDeviceCount();
     std::ostringstream tss;
     for (int gpuNum = 0; gpuNum < numGpus; ++gpuNum) {
       tss << bufferMgrs_[memLevel][gpuNum]->printSlabs();
     }
     return tss.str();
   } else {
     return bufferMgrs_[memLevel][0]->printSlabs();
   }
 }

 void DataMgr::clearMemory(const MemoryLevel memLevel) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);

   // if gpu we need to iterate through all the buffermanagers for each card
   if (memLevel == MemoryLevel::GPU_LEVEL) {
     if (cudaMgr_) {
       int numGpus = cudaMgr_->getDeviceCount();
       for (int gpuNum = 0; gpuNum < numGpus; ++gpuNum) {
         LOG(INFO) << "clear slabs on gpu " << gpuNum;
         bufferMgrs_[memLevel][gpuNum]->clearSlabs();
       }
     } else {
       throw std::runtime_error("Unable to clear GPU memory: No GPUs detected");
     }
   } else {
     bufferMgrs_[memLevel][0]->clearSlabs();
   }
 }

 bool DataMgr::isBufferOnDevice(const ChunkKey& key,
                                const MemoryLevel memLevel,
                                const int deviceId) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   return bufferMgrs_[memLevel][deviceId]->isBufferOnDevice(key);
 }

 void DataMgr::getChunkMetadataVec(ChunkMetadataVector& chunkMetadataVec) {
   // Can we always assume this will just be at the disklevel bc we just
   // started?
   // access to this object is locked by the file mgr
   bufferMgrs_[0][0]->getChunkMetadataVec(chunkMetadataVec);
 }

 void DataMgr::getChunkMetadataVecForKeyPrefix(ChunkMetadataVector& chunkMetadataVec,
                                               const ChunkKey& keyPrefix) {
   bufferMgrs_[0][0]->getChunkMetadataVecForKeyPrefix(chunkMetadataVec, keyPrefix);
 }

 AbstractBuffer* DataMgr::createChunkBuffer(const ChunkKey& key,
                                            const MemoryLevel memoryLevel,
                                            const int deviceId,
                                            const size_t page_size) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   int level = static_cast<int>(memoryLevel);
   return bufferMgrs_[level][deviceId]->createBuffer(key, page_size);
 }

 AbstractBuffer* DataMgr::getChunkBuffer(const ChunkKey& key,
                                         const MemoryLevel memoryLevel,
                                         const int deviceId,
                                         const size_t numBytes) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   const auto level = static_cast<size_t>(memoryLevel);
   CHECK_LT(level, levelSizes_.size());     // make sure we have a legit buffermgr
   CHECK_LT(deviceId, levelSizes_[level]);  // make sure we have a legit buffermgr
   return bufferMgrs_[level][deviceId]->getBuffer(key, numBytes);
 }

 void DataMgr::deleteChunksWithPrefix(const ChunkKey& keyPrefix) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);

   int numLevels = bufferMgrs_.size();
   for (int level = numLevels - 1; level >= 0; --level) {
     for (int device = 0; device < levelSizes_[level]; ++device) {
       bufferMgrs_[level][device]->deleteBuffersWithPrefix(keyPrefix);
     }
   }
 }

 // only deletes the chunks at the given memory level
 void DataMgr::deleteChunksWithPrefix(const ChunkKey& keyPrefix,
                                      const MemoryLevel memLevel) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);

   if (bufferMgrs_.size() <= memLevel) {
     return;
   }
   for (int device = 0; device < levelSizes_[memLevel]; ++device) {
     bufferMgrs_[memLevel][device]->deleteBuffersWithPrefix(keyPrefix);
   }
 }

 AbstractBuffer* DataMgr::alloc(const MemoryLevel memoryLevel,
                                const int deviceId,
                                const size_t numBytes) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   const auto level = static_cast<int>(memoryLevel);
   CHECK_LT(deviceId, levelSizes_[level]);
   return bufferMgrs_[level][deviceId]->alloc(numBytes);
 }

 void DataMgr::free(AbstractBuffer* buffer) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   int level = static_cast<int>(buffer->getType());
   bufferMgrs_[level][buffer->getDeviceId()]->free(buffer);
 }

 void DataMgr::copy(AbstractBuffer* destBuffer, AbstractBuffer* srcBuffer) {
   destBuffer->write(srcBuffer->getMemoryPtr(),
                     srcBuffer->size(),
                     0,
                     srcBuffer->getType(),
                     srcBuffer->getDeviceId());
 }

 // could add function below to do arbitrary copies between buffers

 // void DataMgr::copy(AbstractBuffer *destBuffer, const AbstractBuffer *srcBuffer, const
 // size_t numBytes, const size_t destOffset, const size_t srcOffset) {
 //} /

 void DataMgr::checkpoint(const int db_id, const int tb_id) {
   // TODO(adb): do we need a buffer mgr lock here?
   for (auto levelIt = bufferMgrs_.rbegin(); levelIt != bufferMgrs_.rend(); ++levelIt) {
     // use reverse iterator so we start at GPU level, then CPU then DISK
     for (auto deviceIt = levelIt->begin(); deviceIt != levelIt->end(); ++deviceIt) {
       (*deviceIt)->checkpoint(db_id, tb_id);
     }
   }
 }

 void DataMgr::checkpoint() {
   // TODO(adb): SAA
   for (auto levelIt = bufferMgrs_.rbegin(); levelIt != bufferMgrs_.rend(); ++levelIt) {
     // use reverse iterator so we start at GPU level, then CPU then DISK
     for (auto deviceIt = levelIt->begin(); deviceIt != levelIt->end(); ++deviceIt) {
       (*deviceIt)->checkpoint();
     }
   }
 }

 void DataMgr::removeTableRelatedDS(const int db_id, const int tb_id) {
   std::lock_guard<std::mutex> buffer_lock(buffer_access_mutex_);
   bufferMgrs_[0][0]->removeTableRelatedDS(db_id, tb_id);
 }

 void DataMgr::setTableEpoch(const int db_id, const int tb_id, const int start_epoch) {
   GlobalFileMgr* gfm;
   if (g_enable_fsi) {
     gfm = dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getGlobalFileMgr();
   } else {
     gfm = dynamic_cast<GlobalFileMgr*>(bufferMgrs_[0][0]);
   }
   gfm->setTableEpoch(db_id, tb_id, start_epoch);
 }

 size_t DataMgr::getTableEpoch(const int db_id, const int tb_id) {
   GlobalFileMgr* gfm;
   if (g_enable_fsi) {
     gfm = dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getGlobalFileMgr();
   } else {
     gfm = dynamic_cast<GlobalFileMgr*>(bufferMgrs_[0][0]);
   }
   return gfm->getTableEpoch(db_id, tb_id);
 }

 GlobalFileMgr* DataMgr::getGlobalFileMgr() const {
   GlobalFileMgr* global_file_mgr;
   if (g_enable_fsi) {
     global_file_mgr =
         dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getGlobalFileMgr();
   } else {
     global_file_mgr = dynamic_cast<GlobalFileMgr*>(bufferMgrs_[0][0]);
   }
   CHECK(global_file_mgr);
   return global_file_mgr;
 }

 std::ostream& operator<<(std::ostream& os, const DataMgr::SystemMemoryUsage& mem_info) {
   os << "jsonlog ";
   os << "{";
   os << " \"name\": \"CPU Memory Info\",";
   os << " \"TotalMB\": " << mem_info.total / (1024. * 1024.) << ",";
   os << " \"FreeMB\": " << mem_info.free / (1024. * 1024.) << ",";
   os << " \"ProcessMB\": " << mem_info.resident / (1024. * 1024.) << ",";
   os << " \"VirtualMB\": " << mem_info.vtotal / (1024. * 1024.) << ",";
   os << " \"ProcessPlusSwapMB\": " << mem_info.regular / (1024. * 1024.) << ",";
   os << " \"ProcessSharedMB\": " << mem_info.shared / (1024. * 1024.) << ",";
   os << " \"FragmentationPercent\": " << mem_info.frag;
   os << " }";
   return os;
 }

 foreign_storage::ForeignStorageMgr* DataMgr::getForeignStorageMgr() const {
   if (g_enable_fsi) {
     return dynamic_cast<PersistentStorageMgr*>(bufferMgrs_[0][0])->getForeignStorageMgr();
   }
   return nullptr;
 }

 }  // namespace Data_Namespace
Buffer_Namespace::BufferMgr::getAllocated
size_t getAllocated() override
Definition: BufferMgr.cpp:493

Data_Namespace::DataMgr::buffer_access_mutex_
std::mutex buffer_access_mutex_
Definition: DataMgr.h:246

Data_Namespace::DataMgr::SystemMemoryUsage::resident
size_t resident
Definition: DataMgr.h:218

Data_Namespace::MemoryInfo::nodeMemoryData
std::vector< MemoryData > nodeMemoryData
Definition: DataMgr.h:65

Data_Namespace::MemoryData::memStatus
Buffer_Namespace::MemStatus memStatus
Definition: DataMgr.h:57

CpuBufferMgr.h

Buffer_Namespace::BufferMgr::getMaxSize
size_t getMaxSize() override
Definition: BufferMgr.cpp:488

Data_Namespace::MemoryData::numPages
size_t numPages
Definition: DataMgr.h:54

Data_Namespace::DataMgr::bufferMgrs_
std::vector< std::vector< AbstractBufferMgr * > > bufferMgrs_
Definition: DataMgr.h:241

GlobalFileMgr.h

Data_Namespace::DataMgr::levelSizes_
std::vector< int > levelSizes_
Definition: DataMgr.h:213

GpuCudaBufferMgr.h

CudaMgr.h

Data_Namespace::operator<<
std::ostream & operator<<(std::ostream &os, const DataMgr::SystemMemoryUsage &mem_info)
Definition: DataMgr.cpp:555

LOG
#define LOG(tag)
Definition: Logger.h:188

Data_Namespace::MemoryInfo
Definition: DataMgr.h:60

Data_Namespace::DataMgr::populateMgrs
void populateMgrs(const SystemParameters &system_parameters, const size_t userSpecifiedNumReaderThreads, const DiskCacheConfig &cache_config)
Definition: DataMgr.cpp:176

Data_Namespace::DataMgr::SystemMemoryUsage::regular
size_t regular
Definition: DataMgr.h:220

SystemParameters
Definition: SystemParameters.h:28

Data_Namespace::AbstractBuffer::size
virtual size_t size() const =0

Data_Namespace::DataMgr::getChunkMetadataVec
void getChunkMetadataVec(ChunkMetadataVector &chunkMetadataVec)
Definition: DataMgr.cpp:413

foreign_storage::ForeignStorageMgr
Definition: ForeignStorageMgr.h:29

SystemParameters::cpu_buffer_mem_bytes
size_t cpu_buffer_mem_bytes
Definition: SystemParameters.h:39

Data_Namespace::AbstractBuffer::getMemoryPtr
virtual int8_t * getMemoryPtr()=0

Data_Namespace::AbstractBuffer::getType
virtual MemoryLevel getType() const =0

Data_Namespace::DataMgr::clearMemory
void clearMemory(const MemoryLevel memLevel)
Definition: DataMgr.cpp:387

Buffer_Namespace::CpuBufferMgr
Definition: CpuBufferMgr.h:29

logger::FATAL
Definition: Logger.h:81

SystemParameters::min_cpu_slab_size
size_t min_cpu_slab_size
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