_result_set_8cpp_source.html

 /*
  * Copyright 2017 MapD Technologies, 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 "ResultSet.h"

 #include "DataMgr/Allocators/CudaAllocator.h"
 #include "DataMgr/BufferMgr/BufferMgr.h"
 #include "Execute.h"
 #include "GpuMemUtils.h"
 #include "InPlaceSort.h"
 #include "OutputBufferInitialization.h"
 #include "RuntimeFunctions.h"
 #include "Shared/SqlTypesLayout.h"
 #include "Shared/checked_alloc.h"
 #include "Shared/likely.h"
 #include "Shared/thread_count.h"
 #include "Shared/threadpool.h"

 #include <algorithm>
 #include <bitset>
 #include <future>
 #include <numeric>

 extern bool g_use_tbb_pool;

 std::vector<int64_t> initialize_target_values_for_storage(
     const std::vector<TargetInfo>& targets) {
   std::vector<int64_t> target_init_vals;
   for (const auto& target_info : targets) {
     if (target_info.agg_kind == kCOUNT ||
         target_info.agg_kind == kAPPROX_COUNT_DISTINCT) {
       target_init_vals.push_back(0);
       continue;
     }
     if (target_info.sql_type.is_column()) {
       int64_t init_val = null_val_bit_pattern(target_info.sql_type.get_subtype(),
                                               takes_float_argument(target_info));
       target_init_vals.push_back(target_info.is_agg ? init_val : 0);
     } else if (!target_info.sql_type.get_notnull()) {
       int64_t init_val =
           null_val_bit_pattern(target_info.sql_type, takes_float_argument(target_info));
       target_init_vals.push_back(target_info.is_agg ? init_val : 0);
     } else {
       target_init_vals.push_back(target_info.is_agg ? 0xdeadbeef : 0);
     }
     if (target_info.agg_kind == kAVG) {
       target_init_vals.push_back(0);
     } else if (target_info.agg_kind == kSAMPLE && target_info.sql_type.is_geometry()) {
       for (int i = 1; i < 2 * target_info.sql_type.get_physical_coord_cols(); i++) {
         target_init_vals.push_back(0);
       }
     } else if (target_info.agg_kind == kSAMPLE && target_info.sql_type.is_varlen()) {
       target_init_vals.push_back(0);
     }
   }
   return target_init_vals;
 }

 ResultSetStorage::ResultSetStorage(const std::vector<TargetInfo>& targets,
                                    const QueryMemoryDescriptor& query_mem_desc,
                                    int8_t* buff,
                                    const bool buff_is_provided)
     : targets_(targets)
     , query_mem_desc_(query_mem_desc)
     , buff_(buff)
     , buff_is_provided_(buff_is_provided)
     , target_init_vals_(initialize_target_values_for_storage(targets)) {}

 int8_t* ResultSetStorage::getUnderlyingBuffer() const {
   return buff_;
 }

 void ResultSet::keepFirstN(const size_t n) {
   CHECK_EQ(-1, cached_row_count_);
   keep_first_ = n;
 }

 void ResultSet::dropFirstN(const size_t n) {
   CHECK_EQ(-1, cached_row_count_);
   drop_first_ = n;
 }

 ResultSet::ResultSet(const std::vector<TargetInfo>& targets,
                      const ExecutorDeviceType device_type,
                      const QueryMemoryDescriptor& query_mem_desc,
                      const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
                      const Executor* executor)
     : targets_(targets)
     , device_type_(device_type)
     , device_id_(-1)
     , query_mem_desc_(query_mem_desc)
     , crt_row_buff_idx_(0)
     , fetched_so_far_(0)
     , drop_first_(0)
     , keep_first_(0)
     , row_set_mem_owner_(row_set_mem_owner)
     , executor_(executor)
     , data_mgr_(nullptr)
     , separate_varlen_storage_valid_(false)
     , just_explain_(false)
     , cached_row_count_(-1)
     , geo_return_type_(GeoReturnType::WktString) {}

 ResultSet::ResultSet(const std::vector<TargetInfo>& targets,
                      const std::vector<ColumnLazyFetchInfo>& lazy_fetch_info,
                      const std::vector<std::vector<const int8_t*>>& col_buffers,
                      const std::vector<std::vector<int64_t>>& frag_offsets,
                      const std::vector<int64_t>& consistent_frag_sizes,
                      const ExecutorDeviceType device_type,
                      const int device_id,
                      const QueryMemoryDescriptor& query_mem_desc,
                      const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
                      const Executor* executor)
     : targets_(targets)
     , device_type_(device_type)
     , device_id_(device_id)
     , query_mem_desc_(query_mem_desc)
     , crt_row_buff_idx_(0)
     , fetched_so_far_(0)
     , drop_first_(0)
     , keep_first_(0)
     , row_set_mem_owner_(row_set_mem_owner)
     , executor_(executor)
     , lazy_fetch_info_(lazy_fetch_info)
     , col_buffers_{col_buffers}
     , frag_offsets_{frag_offsets}
     , consistent_frag_sizes_{consistent_frag_sizes}
     , data_mgr_(nullptr)
     , separate_varlen_storage_valid_(false)
     , just_explain_(false)
     , cached_row_count_(-1)
     , geo_return_type_(GeoReturnType::WktString) {}

 ResultSet::ResultSet(const std::shared_ptr<const Analyzer::Estimator> estimator,
                      const ExecutorDeviceType device_type,
                      const int device_id,
                      Data_Namespace::DataMgr* data_mgr)
     : device_type_(device_type)
     , device_id_(device_id)
     , query_mem_desc_{}
     , crt_row_buff_idx_(0)
     , estimator_(estimator)
     , data_mgr_(data_mgr)
     , separate_varlen_storage_valid_(false)
     , just_explain_(false)
     , cached_row_count_(-1)
     , geo_return_type_(GeoReturnType::WktString) {
   if (device_type == ExecutorDeviceType::GPU) {
     device_estimator_buffer_ = CudaAllocator::allocGpuAbstractBuffer(
         data_mgr_, estimator_->getBufferSize(), device_id_);
     data_mgr->getCudaMgr()->zeroDeviceMem(device_estimator_buffer_->getMemoryPtr(),
                                           estimator_->getBufferSize(),
                                           device_id_);
   } else {
     host_estimator_buffer_ =
         static_cast<int8_t*>(checked_calloc(estimator_->getBufferSize(), 1));
   }
 }

 ResultSet::ResultSet(const std::string& explanation)
     : device_type_(ExecutorDeviceType::CPU)
     , device_id_(-1)
     , fetched_so_far_(0)
     , separate_varlen_storage_valid_(false)
     , explanation_(explanation)
     , just_explain_(true)
     , cached_row_count_(-1)
     , geo_return_type_(GeoReturnType::WktString) {}

 ResultSet::ResultSet(int64_t queue_time_ms,
                      int64_t render_time_ms,
                      const std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner)
     : device_type_(ExecutorDeviceType::CPU)
     , device_id_(-1)
     , fetched_so_far_(0)
     , row_set_mem_owner_(row_set_mem_owner)
     , timings_(QueryExecutionTimings{queue_time_ms, render_time_ms, 0, 0})
     , separate_varlen_storage_valid_(false)
     , just_explain_(true)
     , cached_row_count_(-1)
     , geo_return_type_(GeoReturnType::WktString){};

 ResultSet::~ResultSet() {
   if (storage_) {
     if (!storage_->buff_is_provided_) {
       CHECK(storage_->getUnderlyingBuffer());
       free(storage_->getUnderlyingBuffer());
     }
   }
   for (auto& storage : appended_storage_) {
     if (storage && !storage->buff_is_provided_) {
       free(storage->getUnderlyingBuffer());
     }
   }
   if (host_estimator_buffer_) {
     CHECK(device_type_ == ExecutorDeviceType::CPU || device_estimator_buffer_);
     free(host_estimator_buffer_);
   }
   if (device_estimator_buffer_) {
     CHECK(data_mgr_);
     data_mgr_->free(device_estimator_buffer_);
   }
 }

 ExecutorDeviceType ResultSet::getDeviceType() const {
   return device_type_;
 }

 const ResultSetStorage* ResultSet::allocateStorage() const {
   CHECK(!storage_);
   CHECK(row_set_mem_owner_);
   auto buff =
       row_set_mem_owner_->allocate(query_mem_desc_.getBufferSizeBytes(device_type_));
   storage_.reset(
       new ResultSetStorage(targets_, query_mem_desc_, buff, /*buff_is_provided=*/true));
   return storage_.get();
 }

 const ResultSetStorage* ResultSet::allocateStorage(
     int8_t* buff,
     const std::vector<int64_t>& target_init_vals) const {
   CHECK(buff);
   CHECK(!storage_);
   storage_.reset(new ResultSetStorage(targets_, query_mem_desc_, buff, true));
   storage_->target_init_vals_ = target_init_vals;
   return storage_.get();
 }

 const ResultSetStorage* ResultSet::allocateStorage(
     const std::vector<int64_t>& target_init_vals) const {
   CHECK(!storage_);
   CHECK(row_set_mem_owner_);
   auto buff =
       row_set_mem_owner_->allocate(query_mem_desc_.getBufferSizeBytes(device_type_));
   storage_.reset(
       new ResultSetStorage(targets_, query_mem_desc_, buff, /*buff_is_provided=*/true));
   storage_->target_init_vals_ = target_init_vals;
   return storage_.get();
 }

 size_t ResultSet::getCurrentRowBufferIndex() const {
   if (crt_row_buff_idx_ == 0) {
     throw std::runtime_error("current row buffer iteration index is undefined");
   }
   return crt_row_buff_idx_ - 1;
 }

 // Note: that.appended_storage_ does not get appended to this.
 void ResultSet::append(ResultSet& that) {
   CHECK_EQ(-1, cached_row_count_);
   if (!that.storage_) {
     return;
   }
   appended_storage_.push_back(std::move(that.storage_));
   query_mem_desc_.setEntryCount(
       query_mem_desc_.getEntryCount() +
       appended_storage_.back()->query_mem_desc_.getEntryCount());
   chunks_.insert(chunks_.end(), that.chunks_.begin(), that.chunks_.end());
   col_buffers_.insert(
       col_buffers_.end(), that.col_buffers_.begin(), that.col_buffers_.end());
   frag_offsets_.insert(
       frag_offsets_.end(), that.frag_offsets_.begin(), that.frag_offsets_.end());
   consistent_frag_sizes_.insert(consistent_frag_sizes_.end(),
                                 that.consistent_frag_sizes_.begin(),
                                 that.consistent_frag_sizes_.end());
   chunk_iters_.insert(
       chunk_iters_.end(), that.chunk_iters_.begin(), that.chunk_iters_.end());
   if (separate_varlen_storage_valid_) {
     CHECK(that.separate_varlen_storage_valid_);
     serialized_varlen_buffer_.insert(serialized_varlen_buffer_.end(),
                                      that.serialized_varlen_buffer_.begin(),
                                      that.serialized_varlen_buffer_.end());
   }
   for (auto& buff : that.literal_buffers_) {
     literal_buffers_.push_back(std::move(buff));
   }
 }

 const ResultSetStorage* ResultSet::getStorage() const {
   return storage_.get();
 }

 size_t ResultSet::colCount() const {
   return just_explain_ ? 1 : targets_.size();
 }

 SQLTypeInfo ResultSet::getColType(const size_t col_idx) const {
   if (just_explain_) {
     return SQLTypeInfo(kTEXT, false);
   }
   CHECK_LT(col_idx, targets_.size());
   return targets_[col_idx].agg_kind == kAVG ? SQLTypeInfo(kDOUBLE, false)
                                             : targets_[col_idx].sql_type;
 }

 namespace {

 size_t get_truncated_row_count(size_t total_row_count, size_t limit, size_t offset) {
   if (total_row_count < offset) {
     return 0;
   }

   size_t total_truncated_row_count = total_row_count - offset;

   if (limit) {
     return std::min(total_truncated_row_count, limit);
   }

   return total_truncated_row_count;
 }

 }  // namespace

 size_t ResultSet::rowCount(const bool force_parallel) const {
   if (just_explain_) {
     return 1;
   }
   if (!permutation_.empty()) {
     if (drop_first_ > permutation_.size()) {
       return 0;
     }
     const auto limited_row_count = keep_first_ + drop_first_;
     return limited_row_count ? std::min(limited_row_count, permutation_.size())
                              : permutation_.size();
   }
   if (cached_row_count_ != -1) {
     CHECK_GE(cached_row_count_, 0);
     return cached_row_count_;
   }
   if (!storage_) {
     return 0;
   }
   if (permutation_.empty() &&
       query_mem_desc_.getQueryDescriptionType() == QueryDescriptionType::Projection) {
     return binSearchRowCount();
   }
   if (force_parallel || entryCount() > 20000) {
     return parallelRowCount();
   }
   std::lock_guard<std::mutex> lock(row_iteration_mutex_);
   moveToBegin();
   size_t row_count{0};
   while (true) {
     auto crt_row = getNextRowUnlocked(false, false);
     if (crt_row.empty()) {
       break;
     }
     ++row_count;
   }
   moveToBegin();
   return row_count;
 }

 void ResultSet::setCachedRowCount(const size_t row_count) const {
   CHECK(cached_row_count_ == -1 || cached_row_count_ == static_cast<int64_t>(row_count));
   cached_row_count_ = row_count;
 }

 size_t ResultSet::binSearchRowCount() const {
   if (!storage_) {
     return 0;
   }

   size_t row_count = storage_->binSearchRowCount();
   for (auto& s : appended_storage_) {
     row_count += s->binSearchRowCount();
   }

   return get_truncated_row_count(row_count, getLimit(), drop_first_);
 }

 size_t ResultSet::parallelRowCount() const {
   auto execute_parallel_row_count = [this](auto counter_threads) -> size_t {
     const size_t worker_count = cpu_threads();
     for (size_t i = 0,
                 start_entry = 0,
                 stride = (entryCount() + worker_count - 1) / worker_count;
          i < worker_count && start_entry < entryCount();
          ++i, start_entry += stride) {
       const auto end_entry = std::min(start_entry + stride, entryCount());
       counter_threads.spawn(
           [this](const size_t start, const size_t end) {
             size_t row_count{0};
             for (size_t i = start; i < end; ++i) {
               if (!isRowAtEmpty(i)) {
                 ++row_count;
               }
             }
             return row_count;
           },
           start_entry,
           end_entry);
     }
     const auto row_counts = counter_threads.join();
     const size_t row_count = std::accumulate(row_counts.begin(), row_counts.end(), 0);
     return row_count;
   };
   // will fall back to futures threadpool if TBB is not enabled
   const auto row_count =
       g_use_tbb_pool
           ? execute_parallel_row_count(threadpool::ThreadPool<size_t>())
           : execute_parallel_row_count(threadpool::FuturesThreadPool<size_t>());

   return get_truncated_row_count(row_count, getLimit(), drop_first_);
 }

 bool ResultSet::definitelyHasNoRows() const {
   return !storage_ && !estimator_ && !just_explain_;
 }

 const QueryMemoryDescriptor& ResultSet::getQueryMemDesc() const {
   CHECK(storage_);
   return storage_->query_mem_desc_;
 }

 const std::vector<TargetInfo>& ResultSet::getTargetInfos() const {
   return targets_;
 }

 const std::vector<int64_t>& ResultSet::getTargetInitVals() const {
   CHECK(storage_);
   return storage_->target_init_vals_;
 }

 int8_t* ResultSet::getDeviceEstimatorBuffer() const {
   CHECK(device_type_ == ExecutorDeviceType::GPU);
   CHECK(device_estimator_buffer_);
   return device_estimator_buffer_->getMemoryPtr();
 }

 int8_t* ResultSet::getHostEstimatorBuffer() const {
   return host_estimator_buffer_;
 }

 void ResultSet::syncEstimatorBuffer() const {
   CHECK(device_type_ == ExecutorDeviceType::GPU);
   CHECK(!host_estimator_buffer_);
   CHECK_EQ(size_t(0), estimator_->getBufferSize() % sizeof(int64_t));
   host_estimator_buffer_ =
       static_cast<int8_t*>(checked_calloc(estimator_->getBufferSize(), 1));
   CHECK(device_estimator_buffer_);
   auto device_buffer_ptr = device_estimator_buffer_->getMemoryPtr();
   copy_from_gpu(data_mgr_,
                 host_estimator_buffer_,
                 reinterpret_cast<CUdeviceptr>(device_buffer_ptr),
                 estimator_->getBufferSize(),
                 device_id_);
 }

 void ResultSet::setQueueTime(const int64_t queue_time) {
   timings_.executor_queue_time = queue_time;
 }

 void ResultSet::setKernelQueueTime(const int64_t kernel_queue_time) {
   timings_.kernel_queue_time = kernel_queue_time;
 }

 void ResultSet::addCompilationQueueTime(const int64_t compilation_queue_time) {
   timings_.compilation_queue_time += compilation_queue_time;
 }

 int64_t ResultSet::getQueueTime() const {
   return timings_.executor_queue_time + timings_.kernel_queue_time +
          timings_.compilation_queue_time;
 }

 int64_t ResultSet::getRenderTime() const {
   return timings_.render_time;
 }

 void ResultSet::moveToBegin() const {
   crt_row_buff_idx_ = 0;
   fetched_so_far_ = 0;
 }

 bool ResultSet::isTruncated() const {
   return keep_first_ + drop_first_;
 }

 bool ResultSet::isExplain() const {
   return just_explain_;
 }

 int ResultSet::getDeviceId() const {
   return device_id_;
 }

 QueryMemoryDescriptor ResultSet::fixupQueryMemoryDescriptor(
     const QueryMemoryDescriptor& query_mem_desc) {
   auto query_mem_desc_copy = query_mem_desc;
   query_mem_desc_copy.resetGroupColWidths(
       std::vector<int8_t>(query_mem_desc_copy.getGroupbyColCount(), 8));
   if (query_mem_desc.didOutputColumnar()) {
     return query_mem_desc_copy;
   }
   query_mem_desc_copy.alignPaddedSlots();
   return query_mem_desc_copy;
 }

 void ResultSet::sort(const std::list<Analyzer::OrderEntry>& order_entries,
                      const size_t top_n) {
   auto timer = DEBUG_TIMER(__func__);

   if (!storage_) {
     return;
   }
   CHECK_EQ(-1, cached_row_count_);
   CHECK(!targets_.empty());
 #ifdef HAVE_CUDA
   if (canUseFastBaselineSort(order_entries, top_n)) {
     baselineSort(order_entries, top_n);
     return;
   }
 #endif  // HAVE_CUDA
   if (query_mem_desc_.sortOnGpu()) {
     try {
       radixSortOnGpu(order_entries);
     } catch (const OutOfMemory&) {
       LOG(WARNING) << "Out of GPU memory during sort, finish on CPU";
       radixSortOnCpu(order_entries);
     } catch (const std::bad_alloc&) {
       LOG(WARNING) << "Out of GPU memory during sort, finish on CPU";
       radixSortOnCpu(order_entries);
     }
     return;
   }
   // This check isn't strictly required, but allows the index buffer to be 32-bit.
   if (query_mem_desc_.getEntryCount() > std::numeric_limits<uint32_t>::max()) {
     throw RowSortException("Sorting more than 4B elements not supported");
   }

   CHECK(permutation_.empty());

   const bool use_heap{order_entries.size() == 1 && top_n};
   if (use_heap && entryCount() > 100000) {
     if (g_enable_watchdog && (entryCount() > 20000000)) {
       throw WatchdogException("Sorting the result would be too slow");
     }
     parallelTop(order_entries, top_n);
     return;
   }

   if (g_enable_watchdog && (entryCount() > Executor::baseline_threshold)) {
     throw WatchdogException("Sorting the result would be too slow");
   }

   permutation_ = initPermutationBuffer(0, 1);

   auto compare = createComparator(order_entries, use_heap);

   if (use_heap) {
     topPermutation(permutation_, top_n, compare);
   } else {
     sortPermutation(compare);
   }
 }

 #ifdef HAVE_CUDA
 void ResultSet::baselineSort(const std::list<Analyzer::OrderEntry>& order_entries,
                              const size_t top_n) {
   auto timer = DEBUG_TIMER(__func__);
   // If we only have on GPU, it's usually faster to do multi-threaded radix sort on CPU
   if (getGpuCount() > 1) {
     try {
       doBaselineSort(ExecutorDeviceType::GPU, order_entries, top_n);
     } catch (...) {
       doBaselineSort(ExecutorDeviceType::CPU, order_entries, top_n);
     }
   } else {
     doBaselineSort(ExecutorDeviceType::CPU, order_entries, top_n);
   }
 }
 #endif  // HAVE_CUDA

 std::vector<uint32_t> ResultSet::initPermutationBuffer(const size_t start,
                                                        const size_t step) {
   auto timer = DEBUG_TIMER(__func__);
   CHECK_NE(size_t(0), step);
   std::vector<uint32_t> permutation;
   const auto total_entries = query_mem_desc_.getEntryCount();
   permutation.reserve(total_entries / step);
   for (size_t i = start; i < total_entries; i += step) {
     const auto storage_lookup_result = findStorage(i);
     const auto lhs_storage = storage_lookup_result.storage_ptr;
     const auto off = storage_lookup_result.fixedup_entry_idx;
     CHECK(lhs_storage);
     if (!lhs_storage->isEmptyEntry(off)) {
       permutation.emplace_back(i);
     }
   }
   return permutation;
 }

 const std::vector<uint32_t>& ResultSet::getPermutationBuffer() const {
   return permutation_;
 }

 void ResultSet::parallelTop(const std::list<Analyzer::OrderEntry>& order_entries,
                             const size_t top_n) {
   auto timer = DEBUG_TIMER(__func__);
   const size_t step = cpu_threads();
   std::vector<std::vector<uint32_t>> strided_permutations(step);
   std::vector<std::future<void>> init_futures;
   for (size_t start = 0; start < step; ++start) {
     init_futures.emplace_back(
         std::async(std::launch::async, [this, start, step, &strided_permutations] {
           strided_permutations[start] = initPermutationBuffer(start, step);
         }));
   }
   for (auto& init_future : init_futures) {
     init_future.wait();
   }
   for (auto& init_future : init_futures) {
     init_future.get();
   }
   auto compare = createComparator(order_entries, true);
   std::vector<std::future<void>> top_futures;
   for (auto& strided_permutation : strided_permutations) {
     top_futures.emplace_back(
         std::async(std::launch::async, [&strided_permutation, &compare, top_n] {
           topPermutation(strided_permutation, top_n, compare);
         }));
   }
   for (auto& top_future : top_futures) {
     top_future.wait();
   }
   for (auto& top_future : top_futures) {
     top_future.get();
   }
   permutation_.reserve(strided_permutations.size() * top_n);
   for (const auto& strided_permutation : strided_permutations) {
     permutation_.insert(
         permutation_.end(), strided_permutation.begin(), strided_permutation.end());
   }
   topPermutation(permutation_, top_n, compare);
 }

 std::pair<size_t, size_t> ResultSet::getStorageIndex(const size_t entry_idx) const {
   size_t fixedup_entry_idx = entry_idx;
   auto entry_count = storage_->query_mem_desc_.getEntryCount();
   const bool is_rowwise_layout = !storage_->query_mem_desc_.didOutputColumnar();
   if (fixedup_entry_idx < entry_count) {
     return {0, fixedup_entry_idx};
   }
   fixedup_entry_idx -= entry_count;
   for (size_t i = 0; i < appended_storage_.size(); ++i) {
     const auto& desc = appended_storage_[i]->query_mem_desc_;
     CHECK_NE(is_rowwise_layout, desc.didOutputColumnar());
     entry_count = desc.getEntryCount();
     if (fixedup_entry_idx < entry_count) {
       return {i + 1, fixedup_entry_idx};
     }
     fixedup_entry_idx -= entry_count;
   }
   UNREACHABLE() << "entry_idx = " << entry_idx << ", query_mem_desc_.getEntryCount() = "
                 << query_mem_desc_.getEntryCount();
   return {};
 }

 template struct ResultSet::ResultSetComparator<ResultSet::RowWiseTargetAccessor>;
 template struct ResultSet::ResultSetComparator<ResultSet::ColumnWiseTargetAccessor>;

 ResultSet::StorageLookupResult ResultSet::findStorage(const size_t entry_idx) const {
   auto [stg_idx, fixedup_entry_idx] = getStorageIndex(entry_idx);
   return {stg_idx ? appended_storage_[stg_idx - 1].get() : storage_.get(),
           fixedup_entry_idx,
           stg_idx};
 }

 template <typename BUFFER_ITERATOR_TYPE>
 void ResultSet::ResultSetComparator<
     BUFFER_ITERATOR_TYPE>::materializeCountDistinctColumns() {
   for (const auto& order_entry : order_entries_) {
     if (is_distinct_target(result_set_->targets_[order_entry.tle_no - 1])) {
       count_distinct_materialized_buffers_.emplace_back(
           materializeCountDistinctColumn(order_entry));
     }
   }
 }

 template <typename BUFFER_ITERATOR_TYPE>
 std::vector<int64_t>
 ResultSet::ResultSetComparator<BUFFER_ITERATOR_TYPE>::materializeCountDistinctColumn(
     const Analyzer::OrderEntry& order_entry) const {
   const size_t num_storage_entries = result_set_->query_mem_desc_.getEntryCount();
   std::vector<int64_t> count_distinct_materialized_buffer(num_storage_entries);
   const CountDistinctDescriptor count_distinct_descriptor =
       result_set_->query_mem_desc_.getCountDistinctDescriptor(order_entry.tle_no - 1);
   const size_t num_non_empty_entries = result_set_->permutation_.size();
   const size_t worker_count = cpu_threads();
   // TODO(tlm): Allow use of tbb after we determine how to easily encapsulate the choice
   // between thread pool types
   threadpool::FuturesThreadPool<void> thread_pool;
   for (size_t i = 0,
               start_entry = 0,
               stride = (num_non_empty_entries + worker_count - 1) / worker_count;
        i < worker_count && start_entry < num_non_empty_entries;
        ++i, start_entry += stride) {
     const auto end_entry = std::min(start_entry + stride, num_non_empty_entries);
     thread_pool.spawn(
         [this](const size_t start,
                const size_t end,
                const Analyzer::OrderEntry& order_entry,
                const CountDistinctDescriptor& count_distinct_descriptor,
                std::vector<int64_t>& count_distinct_materialized_buffer) {
           for (size_t i = start; i < end; ++i) {
             const uint32_t permuted_idx = result_set_->permutation_[i];
             const auto storage_lookup_result = result_set_->findStorage(permuted_idx);
             const auto storage = storage_lookup_result.storage_ptr;
             const auto off = storage_lookup_result.fixedup_entry_idx;
             const auto value = buffer_itr_.getColumnInternal(
                 storage->buff_, off, order_entry.tle_no - 1, storage_lookup_result);
             count_distinct_materialized_buffer[permuted_idx] =
                 count_distinct_set_size(value.i1, count_distinct_descriptor);
           }
         },
         start_entry,
         end_entry,
         std::cref(order_entry),
         std::cref(count_distinct_descriptor),
         std::ref(count_distinct_materialized_buffer));
   }
   thread_pool.join();
   return count_distinct_materialized_buffer;
 }

 template <typename BUFFER_ITERATOR_TYPE>
 bool ResultSet::ResultSetComparator<BUFFER_ITERATOR_TYPE>::operator()(
     const uint32_t lhs,
     const uint32_t rhs) const {
   // NB: The compare function must define a strict weak ordering, otherwise
   // std::sort will trigger a segmentation fault (or corrupt memory).
   const auto lhs_storage_lookup_result = result_set_->findStorage(lhs);
   const auto rhs_storage_lookup_result = result_set_->findStorage(rhs);
   const auto lhs_storage = lhs_storage_lookup_result.storage_ptr;
   const auto rhs_storage = rhs_storage_lookup_result.storage_ptr;
   const auto fixedup_lhs = lhs_storage_lookup_result.fixedup_entry_idx;
   const auto fixedup_rhs = rhs_storage_lookup_result.fixedup_entry_idx;
   size_t materialized_count_distinct_buffer_idx{0};

   for (const auto& order_entry : order_entries_) {
     CHECK_GE(order_entry.tle_no, 1);
     const auto& agg_info = result_set_->targets_[order_entry.tle_no - 1];
     const auto entry_ti = get_compact_type(agg_info);
     bool float_argument_input = takes_float_argument(agg_info);
     // Need to determine if the float value has been stored as float
     // or if it has been compacted to a different (often larger 8 bytes)
     // in distributed case the floats are actually 4 bytes
     // TODO the above takes_float_argument() is widely used wonder if this problem
     // exists elsewhere
     if (entry_ti.get_type() == kFLOAT) {
       const auto is_col_lazy =
           !result_set_->lazy_fetch_info_.empty() &&
           result_set_->lazy_fetch_info_[order_entry.tle_no - 1].is_lazily_fetched;
       if (result_set_->query_mem_desc_.getPaddedSlotWidthBytes(order_entry.tle_no - 1) ==
           sizeof(float)) {
         float_argument_input =
             result_set_->query_mem_desc_.didOutputColumnar() ? !is_col_lazy : true;
       }
     }

     const bool use_desc_cmp = use_heap_ ? !order_entry.is_desc : order_entry.is_desc;

     if (UNLIKELY(is_distinct_target(agg_info))) {
       CHECK_LT(materialized_count_distinct_buffer_idx,
                count_distinct_materialized_buffers_.size());
       const auto& count_distinct_materialized_buffer =
           count_distinct_materialized_buffers_[materialized_count_distinct_buffer_idx];
       const auto lhs_sz = count_distinct_materialized_buffer[lhs];
       const auto rhs_sz = count_distinct_materialized_buffer[rhs];
       ++materialized_count_distinct_buffer_idx;
       if (lhs_sz == rhs_sz) {
         continue;
       }
       return use_desc_cmp ? lhs_sz > rhs_sz : lhs_sz < rhs_sz;
     }

     const auto lhs_v = buffer_itr_.getColumnInternal(lhs_storage->buff_,
                                                      fixedup_lhs,
                                                      order_entry.tle_no - 1,
                                                      lhs_storage_lookup_result);
     const auto rhs_v = buffer_itr_.getColumnInternal(rhs_storage->buff_,
                                                      fixedup_rhs,
                                                      order_entry.tle_no - 1,
                                                      rhs_storage_lookup_result);

     if (UNLIKELY(isNull(entry_ti, lhs_v, float_argument_input) &&
                  isNull(entry_ti, rhs_v, float_argument_input))) {
       return false;
     }
     if (UNLIKELY(isNull(entry_ti, lhs_v, float_argument_input) &&
                  !isNull(entry_ti, rhs_v, float_argument_input))) {
       return use_heap_ ? !order_entry.nulls_first : order_entry.nulls_first;
     }
     if (UNLIKELY(isNull(entry_ti, rhs_v, float_argument_input) &&
                  !isNull(entry_ti, lhs_v, float_argument_input))) {
       return use_heap_ ? order_entry.nulls_first : !order_entry.nulls_first;
     }

     if (LIKELY(lhs_v.isInt())) {
       CHECK(rhs_v.isInt());
       if (UNLIKELY(entry_ti.is_string() &&
                    entry_ti.get_compression() == kENCODING_DICT)) {
         CHECK_EQ(4, entry_ti.get_logical_size());
         const auto string_dict_proxy = result_set_->executor_->getStringDictionaryProxy(
             entry_ti.get_comp_param(), result_set_->row_set_mem_owner_, false);
         auto lhs_str = string_dict_proxy->getString(lhs_v.i1);
         auto rhs_str = string_dict_proxy->getString(rhs_v.i1);
         if (lhs_str == rhs_str) {
           continue;
         }
         return use_desc_cmp ? lhs_str > rhs_str : lhs_str < rhs_str;
       }

       if (lhs_v.i1 == rhs_v.i1) {
         continue;
       }
       if (entry_ti.is_fp()) {
         if (float_argument_input) {
           const auto lhs_dval = *reinterpret_cast<const float*>(may_alias_ptr(&lhs_v.i1));
           const auto rhs_dval = *reinterpret_cast<const float*>(may_alias_ptr(&rhs_v.i1));
           return use_desc_cmp ? lhs_dval > rhs_dval : lhs_dval < rhs_dval;
         } else {
           const auto lhs_dval =
               *reinterpret_cast<const double*>(may_alias_ptr(&lhs_v.i1));
           const auto rhs_dval =
               *reinterpret_cast<const double*>(may_alias_ptr(&rhs_v.i1));
           return use_desc_cmp ? lhs_dval > rhs_dval : lhs_dval < rhs_dval;
         }
       }
       return use_desc_cmp ? lhs_v.i1 > rhs_v.i1 : lhs_v.i1 < rhs_v.i1;
     } else {
       if (lhs_v.isPair()) {
         CHECK(rhs_v.isPair());
         const auto lhs =
             pair_to_double({lhs_v.i1, lhs_v.i2}, entry_ti, float_argument_input);
         const auto rhs =
             pair_to_double({rhs_v.i1, rhs_v.i2}, entry_ti, float_argument_input);
         if (lhs == rhs) {
           continue;
         }
         return use_desc_cmp ? lhs > rhs : lhs < rhs;
       } else {
         CHECK(lhs_v.isStr() && rhs_v.isStr());
         const auto lhs = lhs_v.strVal();
         const auto rhs = rhs_v.strVal();
         if (lhs == rhs) {
           continue;
         }
         return use_desc_cmp ? lhs > rhs : lhs < rhs;
       }
     }
   }
   return false;
 }

 void ResultSet::topPermutation(
     std::vector<uint32_t>& to_sort,
     const size_t n,
     const std::function<bool(const uint32_t, const uint32_t)> compare) {
   auto timer = DEBUG_TIMER(__func__);
   std::make_heap(to_sort.begin(), to_sort.end(), compare);
   std::vector<uint32_t> permutation_top;
   permutation_top.reserve(n);
   for (size_t i = 0; i < n && !to_sort.empty(); ++i) {
     permutation_top.push_back(to_sort.front());
     std::pop_heap(to_sort.begin(), to_sort.end(), compare);
     to_sort.pop_back();
   }
   to_sort.swap(permutation_top);
 }

 void ResultSet::sortPermutation(
     const std::function<bool(const uint32_t, const uint32_t)> compare) {
   auto timer = DEBUG_TIMER(__func__);
   std::sort(permutation_.begin(), permutation_.end(), compare);
 }

 void ResultSet::radixSortOnGpu(
     const std::list<Analyzer::OrderEntry>& order_entries) const {
   auto timer = DEBUG_TIMER(__func__);
   auto data_mgr = &executor_->catalog_->getDataMgr();
   const int device_id{0};
   CudaAllocator cuda_allocator(data_mgr, device_id);
   std::vector<int64_t*> group_by_buffers(executor_->blockSize());
   group_by_buffers[0] = reinterpret_cast<int64_t*>(storage_->getUnderlyingBuffer());
   auto dev_group_by_buffers =
       create_dev_group_by_buffers(&cuda_allocator,
                                   group_by_buffers,
                                   query_mem_desc_,
                                   executor_->blockSize(),
                                   executor_->gridSize(),
                                   device_id,
                                   ExecutorDispatchMode::KernelPerFragment,
                                   -1,
                                   true,
                                   true,
                                   false,
                                   nullptr);
   inplace_sort_gpu(
       order_entries, query_mem_desc_, dev_group_by_buffers, data_mgr, device_id);
   copy_group_by_buffers_from_gpu(
       data_mgr,
       group_by_buffers,
       query_mem_desc_.getBufferSizeBytes(ExecutorDeviceType::GPU),
       dev_group_by_buffers.second,
       query_mem_desc_,
       executor_->blockSize(),
       executor_->gridSize(),
       device_id,
       false);
 }

 void ResultSet::radixSortOnCpu(
     const std::list<Analyzer::OrderEntry>& order_entries) const {
   auto timer = DEBUG_TIMER(__func__);
   CHECK(!query_mem_desc_.hasKeylessHash());
   std::vector<int64_t> tmp_buff(query_mem_desc_.getEntryCount());
   std::vector<int32_t> idx_buff(query_mem_desc_.getEntryCount());
   CHECK_EQ(size_t(1), order_entries.size());
   auto buffer_ptr = storage_->getUnderlyingBuffer();
   for (const auto& order_entry : order_entries) {
     const auto target_idx = order_entry.tle_no - 1;
     const auto sortkey_val_buff = reinterpret_cast<int64_t*>(
         buffer_ptr + query_mem_desc_.getColOffInBytes(target_idx));
     const auto chosen_bytes = query_mem_desc_.getPaddedSlotWidthBytes(target_idx);
     sort_groups_cpu(sortkey_val_buff,
                     &idx_buff[0],
                     query_mem_desc_.getEntryCount(),
                     order_entry.is_desc,
                     chosen_bytes);
     apply_permutation_cpu(reinterpret_cast<int64_t*>(buffer_ptr),
                           &idx_buff[0],
                           query_mem_desc_.getEntryCount(),
                           &tmp_buff[0],
                           sizeof(int64_t));
     for (size_t target_idx = 0; target_idx < query_mem_desc_.getSlotCount();
          ++target_idx) {
       if (static_cast<int>(target_idx) == order_entry.tle_no - 1) {
         continue;
       }
       const auto chosen_bytes = query_mem_desc_.getPaddedSlotWidthBytes(target_idx);
       const auto satellite_val_buff = reinterpret_cast<int64_t*>(
           buffer_ptr + query_mem_desc_.getColOffInBytes(target_idx));
       apply_permutation_cpu(satellite_val_buff,
                             &idx_buff[0],
                             query_mem_desc_.getEntryCount(),
                             &tmp_buff[0],
                             chosen_bytes);
     }
   }
 }

 void ResultSetStorage::addCountDistinctSetPointerMapping(const int64_t remote_ptr,
                                                          const int64_t ptr) {
   const auto it_ok = count_distinct_sets_mapping_.emplace(remote_ptr, ptr);
   CHECK(it_ok.second);
 }

 int64_t ResultSetStorage::mappedPtr(const int64_t remote_ptr) const {
   const auto it = count_distinct_sets_mapping_.find(remote_ptr);
   // Due to the removal of completely zero bitmaps in a distributed transfer there will be
   // remote ptr that do not not exists. Return 0 if no pointer found
   if (it == count_distinct_sets_mapping_.end()) {
     return int64_t(0);
   }
   return it->second;
 }

 size_t ResultSet::getLimit() const {
   return keep_first_;
 }

 std::shared_ptr<const std::vector<std::string>> ResultSet::getStringDictionaryPayloadCopy(
     const int dict_id) const {
   CHECK(executor_);
   const auto sdp =
       executor_->getStringDictionaryProxy(dict_id, row_set_mem_owner_, false);
   return sdp->getDictionary()->copyStrings();
 }

 bool can_use_parallel_algorithms(const ResultSet& rows) {
   return !rows.isTruncated();
 }

 bool use_parallel_algorithms(const ResultSet& rows) {
   return can_use_parallel_algorithms(rows) && rows.entryCount() >= 20000;
 }

 bool ResultSet::isDirectColumnarConversionPossible() const {
   if (!g_enable_direct_columnarization) {
     return false;
   } else if (query_mem_desc_.didOutputColumnar()) {
     return permutation_.empty() && (query_mem_desc_.getQueryDescriptionType() ==
                                         QueryDescriptionType::Projection ||
                                     (query_mem_desc_.getQueryDescriptionType() ==
                                          QueryDescriptionType::GroupByPerfectHash ||
                                      query_mem_desc_.getQueryDescriptionType() ==
                                          QueryDescriptionType::GroupByBaselineHash));
   } else {
     return permutation_.empty() && (query_mem_desc_.getQueryDescriptionType() ==
                                         QueryDescriptionType::GroupByPerfectHash ||
                                     query_mem_desc_.getQueryDescriptionType() ==
                                         QueryDescriptionType::GroupByBaselineHash);
   }
 }

 bool ResultSet::isZeroCopyColumnarConversionPossible(size_t column_idx) const {
   return query_mem_desc_.didOutputColumnar() &&
          query_mem_desc_.getQueryDescriptionType() == QueryDescriptionType::Projection &&
          appended_storage_.empty() && storage_ &&
          (lazy_fetch_info_.empty() || !lazy_fetch_info_[column_idx].is_lazily_fetched);
 }

 const int8_t* ResultSet::getColumnarBuffer(size_t column_idx) const {
   CHECK(isZeroCopyColumnarConversionPossible(column_idx));
   return storage_->getUnderlyingBuffer() + query_mem_desc_.getColOffInBytes(column_idx);
 }

 // returns a bitmap (and total number) of all single slot targets
 std::tuple<std::vector<bool>, size_t> ResultSet::getSingleSlotTargetBitmap() const {
   std::vector<bool> target_bitmap(targets_.size(), true);
   size_t num_single_slot_targets = 0;
   for (size_t target_idx = 0; target_idx < targets_.size(); target_idx++) {
     const auto& sql_type = targets_[target_idx].sql_type;
     if (targets_[target_idx].is_agg && targets_[target_idx].agg_kind == kAVG) {
       target_bitmap[target_idx] = false;
     } else if (sql_type.is_varlen()) {
       target_bitmap[target_idx] = false;
     } else {
       num_single_slot_targets++;
     }
   }
   return std::make_tuple(std::move(target_bitmap), num_single_slot_targets);
 }

 std::tuple<std::vector<bool>, size_t> ResultSet::getSupportedSingleSlotTargetBitmap()
     const {
   CHECK(isDirectColumnarConversionPossible());
   auto [single_slot_targets, num_single_slot_targets] = getSingleSlotTargetBitmap();

   for (size_t target_idx = 0; target_idx < single_slot_targets.size(); target_idx++) {
     const auto& target = targets_[target_idx];
     if (single_slot_targets[target_idx] &&
         (is_distinct_target(target) ||
          (target.is_agg && target.agg_kind == kSAMPLE && target.sql_type == kFLOAT))) {
       single_slot_targets[target_idx] = false;
       num_single_slot_targets--;
     }
   }
   CHECK_GE(num_single_slot_targets, size_t(0));
   return std::make_tuple(std::move(single_slot_targets), num_single_slot_targets);
 }

 // returns the starting slot index for all targets in the result set
 std::vector<size_t> ResultSet::getSlotIndicesForTargetIndices() const {
   std::vector<size_t> slot_indices(targets_.size(), 0);
   size_t slot_index = 0;
   for (size_t target_idx = 0; target_idx < targets_.size(); target_idx++) {
     slot_indices[target_idx] = slot_index;
     slot_index = advance_slot(slot_index, targets_[target_idx], false);
   }
   return slot_indices;
 }
CountDistinctDescriptor
Definition: CountDistinctDescriptor.h:43

anonymous_namespace{RelAlgExecutor.cpp}::is_agg
bool is_agg(const Analyzer::Expr *expr)
Definition: RelAlgExecutor.cpp:1325

ResultSet::row_iteration_mutex_
std::mutex row_iteration_mutex_
Definition: ResultSet.h:875

ResultSet::syncEstimatorBuffer
void syncEstimatorBuffer() const
Definition: ResultSet.cpp:456

ResultSet::baselineSort
void baselineSort(const std::list< Analyzer::OrderEntry > &order_entries, const size_t top_n)

CHECK_EQ
#define CHECK_EQ(x, y)
Definition: Logger.h:205

sort_groups_cpu
void sort_groups_cpu(int64_t *val_buff, int32_t *idx_buff, const uint64_t entry_count, const bool desc, const uint32_t chosen_bytes)
Definition: InPlaceSort.cpp:27

threadpool.h

ResultSet::QueryExecutionTimings::executor_queue_time
int64_t executor_queue_time
Definition: ResultSet.h:434

initialize_target_values_for_storage
std::vector< int64_t > initialize_target_values_for_storage(const std::vector< TargetInfo > &targets)
Definition: ResultSet.cpp:47

ResultSet::getSupportedSingleSlotTargetBitmap
std::tuple< std::vector< bool >, size_t > getSupportedSingleSlotTargetBitmap() const
Definition: ResultSet.cpp:1073

ExecutorDeviceType::GPU

InPlaceSort.h

QueryMemoryDescriptor::didOutputColumnar
bool didOutputColumnar() const
Definition: QueryMemoryDescriptor.h:264

WatchdogException
Definition: Execute.h:122

use_parallel_algorithms
bool use_parallel_algorithms(const ResultSet &rows)
Definition: ResultSet.cpp:1007

QueryMemoryDescriptor::getSlotCount
size_t getSlotCount() const
Definition: QueryMemoryDescriptor.cpp:1037

create_dev_group_by_buffers
GpuGroupByBuffers create_dev_group_by_buffers(DeviceAllocator *cuda_allocator, const std::vector< int64_t *> &group_by_buffers, const QueryMemoryDescriptor &query_mem_desc, const unsigned block_size_x, const unsigned grid_size_x, const int device_id, const ExecutorDispatchMode dispatch_mode, const int64_t num_input_rows, const bool prepend_index_buffer, const bool always_init_group_by_on_host, const bool use_bump_allocator, Allocator *insitu_allocator)
Definition: GpuMemUtils.cpp:60

ResultSetStorage::targets_
const std::vector< TargetInfo > targets_
Definition: ResultSet.h:207

OutOfMemory
Definition: BufferMgr.h:41

QueryMemoryDescriptor::setEntryCount
void setEntryCount(const size_t val)
Definition: QueryMemoryDescriptor.h:245

ResultSet::getCurrentRowBufferIndex
size_t getCurrentRowBufferIndex() const
Definition: ResultSet.cpp:262

ResultSet::getColumnarBuffer
const int8_t * getColumnarBuffer(size_t column_idx) const
Definition: ResultSet.cpp:1043

SqlTypesLayout.h

parse_ast.end
end
Definition: parse_ast.py:16

ResultSet::getRenderTime
int64_t getRenderTime() const
Definition: ResultSet.cpp:488

ResultSet::appended_storage_
AppendedStorage appended_storage_
Definition: ResultSet.h:841

g_enable_direct_columnarization
bool g_enable_direct_columnarization
Definition: Execute.cpp:106

ResultSet::geo_return_type_
GeoReturnType geo_return_type_
Definition: ResultSet.h:878

ExecutorDeviceType
ExecutorDeviceType
Definition: CompilationOptions.h:22

QueryDescriptionType::Projection

ResultSet::entryCount
size_t entryCount() const
Definition: ResultSetIteration.cpp:753

OutputBufferInitialization.h

ResultSet::GeoReturnType
GeoReturnType
Definition: ResultSet.h:499

ResultSet::radixSortOnCpu
void radixSortOnCpu(const std::list< Analyzer::OrderEntry > &order_entries) const
Definition: ResultSet.cpp:935

ResultSet::ResultSetComparator
Definition: ResultSet.h:746

ResultSet::getTargetInitVals
const std::vector< int64_t > & getTargetInitVals() const
Definition: ResultSet.cpp:441

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

CudaAllocator
Definition: CudaAllocator.h:43

QueryMemoryDescriptor
Definition: QueryMemoryDescriptor.h:68

ResultSet::getHostEstimatorBuffer
int8_t * getHostEstimatorBuffer() const
Definition: ResultSet.cpp:452

thread_count.h

threadpool::FuturesThreadPoolBase::spawn
void spawn(Function &&f, Args &&... args)
Definition: threadpool.h:33

ResultSet::colCount
size_t colCount() const
Definition: ResultSet.cpp:304

ResultSet::QueryExecutionTimings::render_time
int64_t render_time
Definition: ResultSet.h:435

ResultSet::isTruncated
bool isTruncated() const
Definition: ResultSet.cpp:497

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

Executor::baseline_threshold
static const size_t baseline_threshold
Definition: Execute.h:933

ResultSet::executor_
const Executor * executor_
Definition: ResultSet.h:850

ResultSet::isNull
static bool isNull(const SQLTypeInfo &ti, const InternalTargetValue &val, const bool float_argument_input)
Definition: ResultSetIteration.cpp:2225

ResultSet::isExplain
bool isExplain() const
Definition: ResultSet.cpp:501

Analyzer::OrderEntry::tle_no
int tle_no
Definition: Analyzer.h:1418

ResultSet::query_mem_desc_
QueryMemoryDescriptor query_mem_desc_
Definition: ResultSet.h:839

UNREACHABLE
#define UNREACHABLE()
Definition: Logger.h:241

kFLOAT
Definition: sqltypes.h:49

ResultSetStorage::addCountDistinctSetPointerMapping
void addCountDistinctSetPointerMapping(const int64_t remote_ptr, const int64_t ptr)
Definition: ResultSet.cpp:975

CHECK_GE
#define CHECK_GE(x, y)
Definition: Logger.h:210

ResultSetStorage::ResultSetStorage
ResultSetStorage(const std::vector< TargetInfo > &targets, const QueryMemoryDescriptor &query_mem_desc, int8_t *buff, const bool buff_is_provided)
Definition: ResultSet.cpp:80

ResultSet::storage_
std::unique_ptr< ResultSetStorage > storage_
Definition: ResultSet.h:840

ResultSet::isDirectColumnarConversionPossible
bool isDirectColumnarConversionPossible() const
Definition: ResultSet.cpp:1018

ResultSet::setCachedRowCount
void setCachedRowCount(const size_t row_count) const
Definition: ResultSet.cpp:375

ResultSet::setKernelQueueTime
void setKernelQueueTime(const int64_t kernel_queue_time)
Definition: ResultSet.cpp:475

ResultSet::radixSortOnGpu
void radixSortOnGpu(const std::list< Analyzer::OrderEntry > &order_entries) const
Definition: ResultSet.cpp:900

ResultSet::StorageLookupResult
Definition: ResultSet.h:657

ResultSet::getColType
SQLTypeInfo getColType(const size_t col_idx) const
Definition: ResultSet.cpp:308

ResultSet::ResultSetComparator::operator()
bool operator()(const uint32_t lhs, const uint32_t rhs) const
Definition: ResultSet.cpp:749

ResultSet::keep_first_
size_t keep_first_
Definition: ResultSet.h:845

ResultSet::keepFirstN
void keepFirstN(const size_t n)
Definition: ResultSet.cpp:94

ResultSet::chunk_iters_
std::vector< std::shared_ptr< std::list< ChunkIter > > > chunk_iters_
Definition: ResultSet.h:853

QueryDescriptionType::GroupByBaselineHash

pair_to_double
double pair_to_double(const std::pair< int64_t, int64_t > &fp_pair, const SQLTypeInfo &ti, const bool float_argument_input)
Definition: ResultSetBufferAccessors.h:197

ResultSet::addCompilationQueueTime
void addCompilationQueueTime(const int64_t compilation_queue_time)
Definition: ResultSet.cpp:479

takes_float_argument
bool takes_float_argument(const TargetInfo &target_info)
Definition: TargetInfo.h:133

ResultSet::serialized_varlen_buffer_
std::vector< SerializedVarlenBufferStorage > serialized_varlen_buffer_
Definition: ResultSet.h:870

inplace_sort_gpu
void inplace_sort_gpu(const std::list< Analyzer::OrderEntry > &order_entries, const QueryMemoryDescriptor &query_mem_desc, const GpuGroupByBuffers &group_by_buffers, Data_Namespace::DataMgr *data_mgr, const int device_id)
Definition: InPlaceSort.cpp:108

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ExecutorDeviceType getDeviceType() const
Definition: ResultSet.cpp:226

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Definition: ResultSetIteration.cpp:303

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const QueryMemoryDescriptor & getQueryMemDesc() const
Definition: ResultSet.cpp:432

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Definition: InPlaceSort.cpp:46

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Definition: ResultSetBufferAccessors.h:242

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const std::vector< uint32_t > & getPermutationBuffer() const
Definition: ResultSet.cpp:615

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Definition: ResultSet.h:873

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std::vector< uint32_t > permutation_
Definition: ResultSet.h:847

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Definition: ResultSet.h:874

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ResultSet(const std::vector< TargetInfo > &targets, const ExecutorDeviceType device_type, const QueryMemoryDescriptor &query_mem_desc, const std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner, const Executor *executor)
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Definition: ResultSet.cpp:596

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Definition: ResultSet.cpp:300

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Definition: ResultSet.h:836

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Definition: GpuMemUtils.cpp:223

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Definition: ResultSet.h:846

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Definition: CountDistinct.h:75

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Definition: ResultSet.h:849

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Definition: ResultSet.cpp:471

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Definition: Logger.h:206

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Definition: ResultSet.cpp:99

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Definition: ResultSet.h:856

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Definition: ResultSet.cpp:380

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void doBaselineSort(const ExecutorDeviceType device_type, const std::list< Analyzer::OrderEntry > &order_entries, const size_t top_n)

logger::WARNING
Definition: Logger.h:79

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copy_from_gpu
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Definition: GpuMemUtils.cpp:210

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Definition: ResultSet.cpp:684

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Definition: ResultSet.h:437

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Definition: ResultSet.h:436

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size_t getBufferSizeBytes(const RelAlgExecutionUnit &ra_exe_unit, const unsigned thread_count, const ExecutorDeviceType device_type) const
Definition: QueryMemoryDescriptor.cpp:905

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#define LIKELY(x)
Definition: likely.h:24

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void * checked_calloc(const size_t nmemb, const size_t size)
Definition: checked_alloc.h:52

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Definition: ResultSet.h:432

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bool is_distinct_target(const TargetInfo &target_info)
Definition: TargetInfo.h:129

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Definition: threadpool.h:46

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static void topPermutation(std::vector< uint32_t > &to_sort, const size_t n, const std::function< bool(const uint32_t, const uint32_t)> compare)
Definition: ResultSet.cpp:878

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Definition: ResultSet.cpp:428

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Definition: ResultSetIteration.cpp:282

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const std::vector< ColumnLazyFetchInfo > lazy_fetch_info_
Definition: ResultSet.h:857

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Definition: threadpool.h:42

BufferMgr.h

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Data_Namespace::DataMgr * data_mgr_
Definition: ResultSet.h:865

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Definition: likely.h:25

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Definition: DataMgr.h:160

ResultSet::estimator_
const std::shared_ptr< const Analyzer::Estimator > estimator_
Definition: ResultSet.h:862

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Definition: Logger.h:207

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Definition: sqltypes.h:54

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Definition: QueryMemoryDescriptor.h:261

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Definition: ResultSet.h:209

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Definition: ResultSet.cpp:894

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Definition: ResultSet.cpp:335

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Definition: QueryMemoryDescriptor.h:175

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Definition: sqldefs.h:76

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Definition: sqldefs.h:78

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std::vector< std::vector< std::vector< const int8_t * > > > col_buffers_
Definition: ResultSet.h:858

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Data_Namespace::DataMgr::getCudaMgr
CudaMgr_Namespace::CudaMgr * getCudaMgr() const
Definition: DataMgr.h:208

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size_t parallelRowCount() const
Definition: ResultSet.cpp:393

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static Data_Namespace::AbstractBuffer * allocGpuAbstractBuffer(Data_Namespace::DataMgr *data_mgr, const size_t num_bytes, const int device_id)
Definition: CudaAllocator.cpp:41

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static QueryMemoryDescriptor fixupQueryMemoryDescriptor(const QueryMemoryDescriptor &)
Definition: ResultSet.cpp:509

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Definition: ResultSet.h:80

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int getGpuCount() const

GpuMemUtils.h

likely.h

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Definition: ResultSet.cpp:270

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Definition: ResultSet.h:872

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std::tuple< std::vector< bool >, size_t > getSingleSlotTargetBitmap() const
Definition: ResultSet.cpp:1049

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std::vector< std::vector< int64_t > > consistent_frag_sizes_
Definition: ResultSet.h:860

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int8_t * host_estimator_buffer_
Definition: ResultSet.h:864

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Definition: ResultSet.cpp:1003

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Definition: ResultSet.cpp:991

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Definition: ResultSet.cpp:483

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Definition: ResultSet.h:837

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Definition: ResultSet.cpp:619

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Definition: Logger.h:197

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Definition: ResultSet.cpp:437

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Definition: Logger.h:313

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Definition: sqltypes.h:209

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Definition: ResultSet.h:843

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Definition: Execute.cpp:74

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Definition: QueryMemoryDescriptor.h:326

ResultSet.h
Basic constructors and methods of the row set interface.

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Definition: ResultSet.h:871

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Definition: QueryMemoryDescriptor.cpp:801

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Definition: ResultSet.cpp:90

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Definition: sqltypes.h:161

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Definition: ResultSet.cpp:446

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Allocate GPU memory using GpuBuffers via DataMgr.

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Definition: DataMgr.cpp:461

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Definition: ResultSet.cpp:505

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Definition: ResultSet.cpp:230

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Definition: ResultSet.h:774

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Definition: ResultSet.cpp:521

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Definition: Analyzer.h:1413

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Definition: QueryMemoryDescriptor.h:168

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Definition: thread_count.h:24

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Definition: ResultSet.h:863

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Definition: ResultSet.cpp:204

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Definition: sqldefs.h:72

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Definition: ResultSet.cpp:492

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Definition: QueryMemoryDescriptor.h:244

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Definition: ResultSet.cpp:981

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Definition: ResultSet.h:208

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Definition: ResultSet.h:838