_result_set_8cpp_source.html

 /*

  * Copyright 2021 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 "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/Intervals.h"

 #include "Shared/SqlTypesLayout.h"

 #include "Shared/checked_alloc.h"

 #include "Shared/likely.h"

 #include "Shared/thread_count.h"

 #include "Shared/threading.h"


 #include <algorithm>

 #include <atomic>

 #include <bitset>

 #include <future>

 #include <numeric>


 size_t g_parallel_top_min = 100e3;

 size_t g_parallel_top_max = 20e6;  // In effect only with g_enable_watchdog.


 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 Catalog_Namespace::Catalog* catalog,

                      const unsigned block_size,

                      const unsigned grid_size)

     : 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)

     , catalog_(catalog)

     , block_size_(block_size)

     , grid_size_(grid_size)

     , data_mgr_(nullptr)

     , separate_varlen_storage_valid_(false)

     , just_explain_(false)

     , for_validation_only_(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 Catalog_Namespace::Catalog* catalog,

                      const unsigned block_size,

                      const unsigned grid_size)

     : 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)

     , catalog_(catalog)

     , block_size_(block_size)

     , grid_size_(grid_size)

     , 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)

     , for_validation_only_(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)

     , for_validation_only_(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)

     , for_validation_only_(false)

     , 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)

     , for_validation_only_(false)

     , 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_), /*thread_idx=*/0);

   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,

     std::shared_ptr<VarlenOutputInfo> varlen_output_info) const {

   CHECK(buff);

   CHECK(!storage_);

   storage_.reset(new ResultSetStorage(targets_, query_mem_desc_, buff, true));

   // TODO: add both to the constructor

   storage_->target_init_vals_ = target_init_vals;

   if (varlen_output_info) {

     storage_->varlen_output_info_ = varlen_output_info;

   }

   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_), /*thread_idx=*/0);

   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 {

   using namespace threading;

   auto execute_parallel_row_count = [this, query_id = logger::query_id()](

                                         const blocked_range<size_t>& r,

                                         size_t row_count) {

     auto qid_scope_guard = logger::set_thread_local_query_id(query_id);

     for (size_t i = r.begin(); i < r.end(); ++i) {

       if (!isRowAtEmpty(i)) {

         ++row_count;

       }

     }

     return row_count;

   };

   const auto row_count = parallel_reduce(blocked_range<size_t>(0, entryCount()),

                                          size_t(0),

                                          execute_parallel_row_count,

                                          std::plus<int>());

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

 }


 bool ResultSet::isEmpty() const {

   if (entryCount() == 0) {

     return true;

   }

   if (!storage_) {

     return true;

   }


   std::lock_guard<std::mutex> lock(row_iteration_mutex_);

   moveToBegin();

   while (true) {

     auto crt_row = getNextRowUnlocked(false, false);

     if (!crt_row.empty()) {

       return false;

     }

   }

   moveToBegin();

   return true;

 }


 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();

   auto allocator = data_mgr_->createGpuAllocator(device_id_);

   allocator->copyFromDevice(

       host_estimator_buffer_, device_buffer_ptr, estimator_->getBufferSize());

 }


 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_;

 }


 void ResultSet::setValidationOnlyRes() {

   for_validation_only_ = true;

 }


 bool ResultSet::isValidationOnlyRes() const {

   return for_validation_only_;

 }


 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,

                      size_t top_n,

                      const Executor* executor) {

   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, executor);

     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());


   if (top_n && g_parallel_top_min < entryCount()) {

     if (g_enable_watchdog && g_parallel_top_max < entryCount()) {

       throw WatchdogException("Sorting the result would be too slow");

     }

     parallelTop(order_entries, top_n, executor);

   } else {

     if (g_enable_watchdog && Executor::baseline_threshold < entryCount()) {

       throw WatchdogException("Sorting the result would be too slow");

     }

     permutation_.resize(query_mem_desc_.getEntryCount());

     // PermutationView is used to share common API with parallelTop().

     PermutationView pv(permutation_.data(), 0, permutation_.size());

     pv = initPermutationBuffer(pv, 0, permutation_.size());

     if (top_n == 0) {

       top_n = pv.size();  // top_n == 0 implies a full sort

     }

     pv = topPermutation(pv, top_n, createComparator(order_entries, pv, executor, false));

     if (pv.size() < permutation_.size()) {

       permutation_.resize(pv.size());

       permutation_.shrink_to_fit();

     }

   }

 }


 #ifdef HAVE_CUDA

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

                              const size_t top_n,

                              const Executor* executor) {

   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, executor);

     } catch (...) {

       doBaselineSort(ExecutorDeviceType::CPU, order_entries, top_n, executor);

     }

   } else {

     doBaselineSort(ExecutorDeviceType::CPU, order_entries, top_n, executor);

   }

 }

 #endif  // HAVE_CUDA


 // Append non-empty indexes i in [begin,end) from findStorage(i) to permutation.

 PermutationView ResultSet::initPermutationBuffer(PermutationView permutation,

                                                  PermutationIdx const begin,

                                                  PermutationIdx const end) const {

   auto timer = DEBUG_TIMER(__func__);

   for (PermutationIdx i = begin; i < end; ++i) {

     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.push_back(i);

     }

   }

   return permutation;

 }


 const Permutation& ResultSet::getPermutationBuffer() const {

   return permutation_;

 }


 void ResultSet::parallelTop(const std::list<Analyzer::OrderEntry>& order_entries,

                             const size_t top_n,

                             const Executor* executor) {

   auto timer = DEBUG_TIMER(__func__);

   const size_t nthreads = cpu_threads();


   // Split permutation_ into nthreads subranges and top-sort in-place.

   permutation_.resize(query_mem_desc_.getEntryCount());

   std::vector<PermutationView> permutation_views(nthreads);

   threading::task_group top_sort_threads;

   for (auto interval : makeIntervals<PermutationIdx>(0, permutation_.size(), nthreads)) {

     top_sort_threads.run([this,

                           &order_entries,

                           &permutation_views,

                           top_n,

                           executor,

                           query_id = logger::query_id(),

                           interval] {

       auto qid_scope_guard = logger::set_thread_local_query_id(query_id);

       PermutationView pv(permutation_.data() + interval.begin, 0, interval.size());

       pv = initPermutationBuffer(pv, interval.begin, interval.end);

       const auto compare = createComparator(order_entries, pv, executor, true);

       permutation_views[interval.index] = topPermutation(pv, top_n, compare);

     });

   }

   top_sort_threads.wait();


   // In case you are considering implementing a parallel reduction, note that the

   // ResultSetComparator constructor is O(N) in order to materialize some of the aggregate

   // columns as necessary to perform a comparison. This cost is why reduction is chosen to

   // be serial instead; only one more Comparator is needed below.


   // Left-copy disjoint top-sorted subranges into one contiguous range.

   // ++++....+++.....+++++...  ->  ++++++++++++............

   auto end = permutation_.begin() + permutation_views.front().size();

   for (size_t i = 1; i < nthreads; ++i) {

     std::copy(permutation_views[i].begin(), permutation_views[i].end(), end);

     end += permutation_views[i].size();

   }


   // Top sort final range.

   PermutationView pv(permutation_.data(), end - permutation_.begin());

   const auto compare = createComparator(order_entries, pv, executor, false);

   pv = topPermutation(pv, top_n, compare);

   permutation_.resize(pv.size());

   permutation_.shrink_to_fit();

 }


 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>

 ResultSet::ApproxQuantileBuffers ResultSet::ResultSetComparator<

     BUFFER_ITERATOR_TYPE>::materializeApproxQuantileColumns() const {

   ResultSet::ApproxQuantileBuffers approx_quantile_materialized_buffers;

   for (const auto& order_entry : order_entries_) {

     if (result_set_->targets_[order_entry.tle_no - 1].agg_kind == kAPPROX_QUANTILE) {

       approx_quantile_materialized_buffers.emplace_back(

           materializeApproxQuantileColumn(order_entry));

     }

   }

   return approx_quantile_materialized_buffers;

 }


 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 = permutation_.size();


   const auto work = [&, query_id = logger::query_id()](const size_t start,

                                                        const size_t end) {

     auto qid_scope_guard = logger::set_thread_local_query_id(query_id);

     for (size_t i = start; i < end; ++i) {

       const PermutationIdx permuted_idx = 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);

     }

   };

   // TODO(tlm): Allow use of tbb after we determine how to easily encapsulate the choice

   // between thread pool types

   if (single_threaded_) {

     work(0, num_non_empty_entries);

   } else {

     threading::task_group thread_pool;

     for (auto interval : makeIntervals<size_t>(0, num_non_empty_entries, cpu_threads())) {

       thread_pool.run([=] { work(interval.begin, interval.end); });

     }

     thread_pool.wait();

   }

   return count_distinct_materialized_buffer;

 }


 double ResultSet::calculateQuantile(quantile::TDigest* const t_digest) {

   static_assert(sizeof(int64_t) == sizeof(quantile::TDigest*));

   CHECK(t_digest);

   t_digest->mergeBuffer();

   double const quantile = t_digest->quantile();

   return boost::math::isnan(quantile) ? NULL_DOUBLE : quantile;

 }


 template <typename BUFFER_ITERATOR_TYPE>

 ResultSet::ApproxQuantileBuffers::value_type

 ResultSet::ResultSetComparator<BUFFER_ITERATOR_TYPE>::materializeApproxQuantileColumn(

     const Analyzer::OrderEntry& order_entry) const {

   ResultSet::ApproxQuantileBuffers::value_type materialized_buffer(

       result_set_->query_mem_desc_.getEntryCount());

   const size_t size = permutation_.size();

   const auto work = [&, query_id = logger::query_id()](const size_t start,

                                                        const size_t end) {

     auto qid_scope_guard = logger::set_thread_local_query_id(query_id);

     for (size_t i = start; i < end; ++i) {

       const PermutationIdx permuted_idx = 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);

       materialized_buffer[permuted_idx] =

           value.i1 ? calculateQuantile(reinterpret_cast<quantile::TDigest*>(value.i1))

                    : NULL_DOUBLE;

     }

   };

   if (single_threaded_) {

     work(0, size);

   } else {

     threading::task_group thread_pool;

     for (auto interval : makeIntervals<size_t>(0, size, cpu_threads())) {

       thread_pool.run([=] { work(interval.begin, interval.end); });

     }

     thread_pool.wait();

   }

   return materialized_buffer;

 }


 template <typename BUFFER_ITERATOR_TYPE>

 bool ResultSet::ResultSetComparator<BUFFER_ITERATOR_TYPE>::operator()(

     const PermutationIdx lhs,

     const PermutationIdx 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};

   size_t materialized_approx_quantile_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;

       }

     }


     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 (lhs_sz < rhs_sz) != order_entry.is_desc;

     } else if (UNLIKELY(agg_info.agg_kind == kAPPROX_QUANTILE)) {

       CHECK_LT(materialized_approx_quantile_buffer_idx,

                approx_quantile_materialized_buffers_.size());

       const auto& approx_quantile_materialized_buffer =

           approx_quantile_materialized_buffers_[materialized_approx_quantile_buffer_idx];

       const auto lhs_value = approx_quantile_materialized_buffer[lhs];

       const auto rhs_value = approx_quantile_materialized_buffer[rhs];

       ++materialized_approx_quantile_buffer_idx;

       if (lhs_value == rhs_value) {

         continue;

       } else if (!entry_ti.get_notnull()) {

         if (lhs_value == NULL_DOUBLE) {

           return order_entry.nulls_first;

         } else if (rhs_value == NULL_DOUBLE) {

           return !order_entry.nulls_first;

         }

       }

       return (lhs_value < rhs_value) != order_entry.is_desc;

     }


     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))) {

       continue;

     }

     if (UNLIKELY(isNull(entry_ti, lhs_v, float_argument_input) &&

                  !isNull(entry_ti, rhs_v, float_argument_input))) {

       return order_entry.nulls_first;

     }

     if (UNLIKELY(isNull(entry_ti, rhs_v, float_argument_input) &&

                  !isNull(entry_ti, lhs_v, float_argument_input))) {

       return !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());

         CHECK(executor_);

         const auto string_dict_proxy = 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 (lhs_str < rhs_str) != order_entry.is_desc;

       }


       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 (lhs_dval < rhs_dval) != order_entry.is_desc;

         } 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 (lhs_dval < rhs_dval) != order_entry.is_desc;

         }

       }

       return (lhs_v.i1 < rhs_v.i1) != order_entry.is_desc;

     } 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 (lhs < rhs) != order_entry.is_desc;

       } 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 (lhs < rhs) != order_entry.is_desc;

       }

     }

   }

   return false;

 }


 // Partial sort permutation into top(least by compare) n elements.

 // If permutation.size() <= n then sort entire permutation by compare.

 // Return PermutationView with new size() = min(n, permutation.size()).

 PermutationView ResultSet::topPermutation(PermutationView permutation,

                                           const size_t n,

                                           const Comparator& compare) {

   auto timer = DEBUG_TIMER(__func__);

   if (n < permutation.size()) {

     std::partial_sort(

         permutation.begin(), permutation.begin() + n, permutation.end(), compare);

     permutation.resize(n);

   } else {

     std::sort(permutation.begin(), permutation.end(), compare);

   }

   return permutation;

 }


 void ResultSet::radixSortOnGpu(

     const std::list<Analyzer::OrderEntry>& order_entries) const {

   auto timer = DEBUG_TIMER(__func__);

   auto data_mgr = &catalog_->getDataMgr();

   const int device_id{0};

   auto allocator = data_mgr->createGpuAllocator(device_id);

   CHECK_GT(block_size_, 0);

   CHECK_GT(grid_size_, 0);

   std::vector<int64_t*> group_by_buffers(block_size_);

   group_by_buffers[0] = reinterpret_cast<int64_t*>(storage_->getUnderlyingBuffer());

   auto dev_group_by_buffers =

       create_dev_group_by_buffers(allocator.get(),

                                   group_by_buffers,

                                   query_mem_desc_,

                                   block_size_,

                                   grid_size_,

                                   device_id,

                                   ExecutorDispatchMode::KernelPerFragment,

                                   /*num_input_rows=*/-1,

                                   /*prepend_index_buffer=*/true,

                                   /*always_init_group_by_on_host=*/true,

                                   /*use_bump_allocator=*/false,

                                   /*has_varlen_output=*/false,

                                   /*insitu_allocator*=*/nullptr);

   inplace_sort_gpu(

       order_entries, query_mem_desc_, dev_group_by_buffers, data_mgr, device_id);

   copy_group_by_buffers_from_gpu(

       *allocator,

       group_by_buffers,

       query_mem_desc_.getBufferSizeBytes(ExecutorDeviceType::GPU),

       dev_group_by_buffers.data,

       query_mem_desc_,

       block_size_,

       grid_size_,

       device_id,

       /*use_bump_allocator=*/false,

       /*has_varlen_output=*/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);

     }

   }

 }


 size_t ResultSet::getLimit() const {

   return keep_first_;

 }


 std::shared_ptr<const std::vector<std::string>> ResultSet::getStringDictionaryPayloadCopy(

     const int dict_id) const {

   const auto sdp = row_set_mem_owner_->getOrAddStringDictProxy(

       dict_id, /*with_generation=*/false, catalog_);

   CHECK(sdp);

   return sdp->getDictionary()->copyStrings();

 }


 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.agg_kind == kAPPROX_QUANTILE ||

          (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;

 }


 // namespace result_set


 bool result_set::can_use_parallel_algorithms(const ResultSet& rows) {

   return !rows.isTruncated();

 }


 bool result_set::use_parallel_algorithms(const ResultSet& rows) {

   return result_set::can_use_parallel_algorithms(rows) && rows.entryCount() >= 20000;

 }

logger::set_thread_local_query_id
QidScopeGuard set_thread_local_query_id(QueryId const query_id)
Definition: Logger.cpp:468

CountDistinctDescriptor
Definition: CountDistinctDescriptor.h:43

anonymous_namespace{RelAlgExecutor.cpp}::is_agg
bool is_agg(const Analyzer::Expr *expr)
Definition: RelAlgExecutor.cpp:1563

catalog_
catalog_(nullptr)

ResultSet::syncEstimatorBuffer
void syncEstimatorBuffer() const
Definition: ResultSet.cpp:432

threading_std::task_group::run
void run(F &&f)
Definition: threading_std.h:114

CHECK_EQ
#define CHECK_EQ(x, y)
Definition: Logger.h:217

ResultSet::getQueryMemDesc
const QueryMemoryDescriptor & getQueryMemDesc() const
Definition: ResultSet.cpp:408

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

create_dev_group_by_buffers
GpuGroupByBuffers create_dev_group_by_buffers(DeviceAllocator *device_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, const bool has_varlen_output, Allocator *insitu_allocator)
Definition: GpuMemUtils.cpp:60

g_parallel_top_max
size_t g_parallel_top_max
Definition: ResultSet.cpp:45

ResultSet::getStorageIndex
std::pair< size_t, size_t > getStorageIndex(const size_t entry_idx) const
Definition: ResultSet.cpp:649

NULL_DOUBLE
#define NULL_DOUBLE
Definition: InlineNullValues.h:35

VectorView::push_back
DEVICE void push_back(T const &value)
Definition: VectorView.h:74

ResultSet::isValidationOnlyRes
bool isValidationOnlyRes() const
Definition: ResultSet.cpp:483

ExecutorDeviceType::GPU

InPlaceSort.h

g_enable_watchdog
bool g_enable_watchdog

kAPPROX_QUANTILE
Definition: sqldefs.h:78

ResultSet::setValidationOnlyRes
void setValidationOnlyRes()
Definition: ResultSet.cpp:479

ResultSet::initPermutationBuffer
PermutationView initPermutationBuffer(PermutationView permutation, PermutationIdx const begin, PermutationIdx const end) const
Definition: ResultSet.cpp:581

WatchdogException
Definition: Execute.h:157

Catalog_Namespace::Catalog
class for a per-database catalog. also includes metadata for the current database and the current use...
Definition: Catalog.h:111

OutOfMemory
Definition: BufferMgr.h:40

SqlTypesLayout.h

g_enable_direct_columnarization
bool g_enable_direct_columnarization
Definition: Execute.cpp:115

ExecutorDeviceType
ExecutorDeviceType
Definition: CompilationOptions.h:22

QueryDescriptionType::Projection

ResultSet::moveToBegin
void moveToBegin() const
Definition: ResultSet.cpp:466

OutputBufferInitialization.h

ResultSet::GeoReturnType
GeoReturnType
Definition: ResultSet.h:389

ResultSet::ResultSetComparator
Definition: ResultSet.h:636

LOG
#define LOG(tag)
Definition: Logger.h:203

QueryMemoryDescriptor
Definition: QueryMemoryDescriptor.h:68

thread_count.h

threading_std::task_group
Definition: threading_std.h:109

Executor::baseline_threshold
static const size_t baseline_threshold
Definition: Execute.h:1091

ResultSet::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 Catalog_Namespace::Catalog *catalog, const unsigned block_size, const unsigned grid_size)
Definition: ResultSet.cpp:57

Analyzer::OrderEntry::tle_no
int tle_no
Definition: Analyzer.h:1578

UNREACHABLE
#define UNREACHABLE()
Definition: Logger.h:253

gpu_enabled::sort
DEVICE void sort(ARGS &&...args)
Definition: gpu_enabled.h:105

ResultSet::getTargetInfos
const std::vector< TargetInfo > & getTargetInfos() const
Definition: ResultSet.cpp:413

kFLOAT
Definition: sqltypes.h:47

CHECK_GE
#define CHECK_GE(x, y)
Definition: Logger.h:222

ResultSet::setKernelQueueTime
void setKernelQueueTime(const int64_t kernel_queue_time)
Definition: ResultSet.cpp:449

ResultSet::StorageLookupResult
Definition: ResultSet.h:549

ResultSet::rowCount
size_t rowCount(const bool force_parallel=false) const
Definition: ResultSet.cpp:306

quantile::detail::TDigest::mergeBuffer
DEVICE void mergeBuffer()
Definition: quantile.h:629

quantile::detail::TDigest
Definition: quantile.h:184

ResultSet::keepFirstN
void keepFirstN(const size_t n)
Definition: ResultSet.cpp:47

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:199

ResultSet::addCompilationQueueTime
void addCompilationQueueTime(const int64_t compilation_queue_time)
Definition: ResultSet.cpp:453

ResultSet::ApproxQuantileBuffers
std::vector< std::vector< double >> ApproxQuantileBuffers
Definition: ResultSet.h:633

takes_float_argument
bool takes_float_argument(const TargetInfo &target_info)
Definition: TargetInfo.h:157

ResultSet::parallelTop
void parallelTop(const std::list< Analyzer::OrderEntry > &order_entries, const size_t top_n, const Executor *executor)
Definition: ResultSet.cpp:601

ResultSet::colCount
size_t colCount() const
Definition: ResultSet.cpp:275

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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Definition: InPlaceSort.cpp:46

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Definition: ResultSet.cpp:279

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Definition: ResultSet.cpp:192

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Definition: ResultSet.cpp:1074

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Definition: ResultSet.cpp:475

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Definition: ResultSet.cpp:491

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Definition: ResultSetStorage.h:98

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Definition: ResultSet.cpp:597

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Definition: Parser_wnd_pregen.cpp:2082

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Definition: ResultSet.cpp:241

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Definition: QueryMemoryDescriptor.h:265

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Definition: ResultSet.cpp:233

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Definition: Execute.cpp:76

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Definition: Logger.h:209

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Definition: Logger.cpp:454

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Definition: Logger.h:352

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Definition: ResultSet.cpp:422

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Definition: ResultSet.cpp:786

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Basic constructors and methods of the row set interface.

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Definition: ResultSet.cpp:384

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Definition: ResultSet.cpp:417

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Allocate GPU memory using GpuBuffers via DataMgr.

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Definition: Utm.h:46

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Definition: Analyzer.h:1573

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Definition: thread_count.h:24

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Definition: ResultSet.cpp:170

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Definition: sqldefs.h:72

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void copy_group_by_buffers_from_gpu(DeviceAllocator &device_allocator, const std::vector< int64_t * > &group_by_buffers, const size_t groups_buffer_size, const int8_t *group_by_dev_buffers_mem, const QueryMemoryDescriptor &query_mem_desc, const unsigned block_size_x, const unsigned grid_size_x, const int device_id, const bool prepend_index_buffer, const bool has_varlen_output)
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Definition: ResultSet.cpp:1135

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Definition: ResultSet.cpp:462

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Definition: ResultSet.cpp:346

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Definition: ResultSet.cpp:1049

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Definition: ResultSet.cpp:351

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Definition: VectorView.h:35

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Definition: ResultSet.cpp:487

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Definition: VectorView.h:68