_columnar_results_8cpp_source.html

 /*

  * Copyright 2022 HEAVY.AI, 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 "ColumnarResults.h"

 #include "Descriptors/RowSetMemoryOwner.h"

 #include "ErrorHandling.h"

 #include "Execute.h"

 #include "Geospatial/Compression.h"

 #include "Geospatial/Types.h"

 #include "Shared/Intervals.h"

 #include "Shared/likely.h"

 #include "Shared/sqltypes.h"

 #include "Shared/thread_count.h"


 #include <tbb/parallel_reduce.h>

 #include <atomic>

 #include <future>

 #include <numeric>


 namespace {


 inline int64_t fixed_encoding_nullable_val(const int64_t val,

                                            const SQLTypeInfo& type_info) {

   if (type_info.get_compression() != kENCODING_NONE) {

     CHECK(type_info.get_compression() == kENCODING_FIXED ||

           type_info.get_compression() == kENCODING_DICT);

     auto logical_ti = get_logical_type_info(type_info);

     if (val == inline_int_null_val(logical_ti)) {

       return inline_fixed_encoding_null_val(type_info);

     }

   }

   return val;

 }


 std::vector<size_t> get_padded_target_sizes(

     const ResultSet& rows,

     const std::vector<SQLTypeInfo>& target_types) {

   std::vector<size_t> padded_target_sizes;

   // We have to check that the result set is valid as one entry point

   // to columnar results constructs effectively a fake result set.

   // In these cases it should be safe to assume that we can use the type

   // target widths

   if (!rows.hasValidBuffer() ||

       rows.getQueryMemDesc().getColCount() < target_types.size()) {

     for (const auto& target_type : target_types) {

       padded_target_sizes.emplace_back(target_type.get_size());

     }

     return padded_target_sizes;

   }


   // If here we have a valid result set, so use it's QMD padded widths

   const auto col_context = rows.getQueryMemDesc().getColSlotContext();

   for (size_t col_idx = 0; col_idx < target_types.size(); col_idx++) {

     // Lazy fetch columns will have 0 as a padded with, so use the type's

     // logical width for those

     const auto idx = col_context.getSlotsForCol(col_idx).front();

     const size_t padded_slot_width =

         static_cast<size_t>(rows.getPaddedSlotWidthBytes(idx));

     padded_target_sizes.emplace_back(

         padded_slot_width == 0UL ? target_types[col_idx].get_size() : padded_slot_width);

   }

   return padded_target_sizes;

 }


 int64_t toBuffer(const TargetValue& col_val, const SQLTypeInfo& type_info, int8_t* buf) {

   CHECK(!type_info.is_geometry());

   if (type_info.is_array()) {

     const auto array_col_val = boost::get<ArrayTargetValue>(&col_val);

     CHECK(array_col_val);

     const auto& vec = array_col_val->get();

     int64_t offset = 0;

     const auto elem_type_info = type_info.get_elem_type();

     for (const auto& item : vec) {

       offset += toBuffer(item, elem_type_info, buf + offset);

     }

     return offset;

   } else if (type_info.is_fp()) {

     const auto scalar_col_val = boost::get<ScalarTargetValue>(&col_val);

     switch (type_info.get_type()) {

       case kFLOAT: {

         auto float_p = boost::get<float>(scalar_col_val);

         *((float*)buf) = static_cast<float>(*float_p);

         return 4;

       }

       case kDOUBLE: {

         auto double_p = boost::get<double>(scalar_col_val);

         *((double*)buf) = static_cast<double>(*double_p);

         return 8;

       }

       default:

         UNREACHABLE();

     }

   } else {

     const auto scalar_col_val = boost::get<ScalarTargetValue>(&col_val);

     CHECK(scalar_col_val);

     auto i64_p = boost::get<int64_t>(scalar_col_val);

     const auto val = fixed_encoding_nullable_val(*i64_p, type_info);

     switch (type_info.get_size()) {

       case 1:

         *buf = static_cast<int8_t>(val);

         return 1;

       case 2:

         *((int16_t*)buf) = static_cast<int16_t>(val);

         return 2;

       case 4:

         *((int32_t*)buf) = static_cast<int32_t>(val);

         return 4;

       case 8:

         *((int64_t*)buf) = static_cast<int64_t>(val);

         return 8;

       default:

         UNREACHABLE();

     }

   }

   return 0;

 }


 /*

   computeTotalNofValuesForColumn<Type> functions compute the total

   number of values that exists in a result set. The total number of

   values defines the maximal number of values that a FlatBuffer

   storage will be able to hold.


   A "value" is defined as the largest fixed-size element in a column

   structure.


   For instance, for a column of scalars or a column of

   (varlen) arrays of scalars, the "value" is a scalar value. For a

   column of geo-types (points, multipoints, etc), the "value" is a

   Point (a Point is a two-tuple of coordinate values). For a column

   of TextEncodingNone and column of arrays of TextEncodingNone, the

   "value" is a byte value.

  */


 int64_t computeTotalNofValuesForColumnArray(const ResultSet& rows,

                                             const size_t column_idx) {

   return tbb::parallel_reduce(

       tbb::blocked_range<int64_t>(0, rows.entryCount()),

       static_cast<int64_t>(0),

       [&](tbb::blocked_range<int64_t> r, int64_t running_count) {

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

           const auto crt_row = rows.getRowAtNoTranslations(i);

           if (crt_row.empty()) {

             continue;

           }

           const auto arr_tv = boost::get<ArrayTargetValue>(&crt_row[column_idx]);

           CHECK(arr_tv);

           if (arr_tv->is_initialized()) {

             const auto& vec = arr_tv->get();

             running_count += vec.size();

           }

         }

         return running_count;

       },

       std::plus<int64_t>());

 }


 template <typename TargetValue, typename TargetValuePtr>

 int64_t computeTotalNofValuesForColumnGeoType(const ResultSet& rows,

                                               const SQLTypeInfo& ti,

                                               const size_t column_idx) {

   return tbb::parallel_reduce(

       tbb::blocked_range<int64_t>(0, rows.entryCount()),

       static_cast<int64_t>(0),

       [&](tbb::blocked_range<int64_t> r, int64_t running_count) {

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

           const auto crt_row = rows.getRowAtNoTranslations(i);

           if (crt_row.empty()) {

             continue;

           }

           if (const auto tv = boost::get<ScalarTargetValue>(&crt_row[column_idx])) {

             const auto ns = boost::get<NullableString>(tv);

             CHECK(ns);

             const auto s_ptr = boost::get<std::string>(ns);

             if (s_ptr) {

               // We count the number of commas in WKT representation

               // (e.g. POLYGON ((0 0,4 0,4 4,0 4,0 0),(1 1,1 2,2 2,2

               // 1,1 1))) to get the number of points it contains.

               // This method is usable for any geo type.

               running_count += std::count(s_ptr->begin(), s_ptr->end(), ',') + 1;

             }

           } else if (const auto tv =

                          boost::get<GeoTargetValuePtr>(&crt_row[column_idx])) {

             const auto s = boost::get<TargetValuePtr>(tv);

             CHECK(s);

             VarlenDatum* d = s->coords_data.get();

             if (d != nullptr) {

               running_count +=

                   d->length /

                   (ti.get_compression() == kENCODING_GEOINT ? sizeof(int32_t)

                                                             : sizeof(double)) /

                   2;

             }  // else s is NULL

           } else if (const auto tv = boost::get<GeoTargetValue>(&crt_row[column_idx])) {

             if (tv->get_ptr() != nullptr) {

               const auto s = boost::get<TargetValue>(tv->get());

               std::vector<double>* d = s.coords.get();

               CHECK(d);

               running_count += d->size();

             }  // else s is NULL

           } else {

             UNREACHABLE();

           }

         }

         return running_count;

       },

       std::plus<int64_t>());

 }


 int64_t computeTotalNofValuesForColumnTextEncodingNone(const ResultSet& rows,

                                                        const size_t column_idx) {

   return tbb::parallel_reduce(

       tbb::blocked_range<int64_t>(0, rows.entryCount()),

       static_cast<int64_t>(0),

       [&](tbb::blocked_range<int64_t> r, int64_t running_count) {

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

           // Apparently, ResultSet permutation vector may be sparse

           // (len(permutation) > entryCount), so we cannot ignore the

           // permutation vector when iterating over all entries.

           const auto crt_row = rows.getRowAtNoTranslations(i);

           if (crt_row.empty()) {

             continue;

           }

           const auto col_val = crt_row[column_idx];

           if (const auto tv = boost::get<ScalarTargetValue>(&col_val)) {

             const auto ns = boost::get<NullableString>(tv);

             CHECK(ns);

             const auto s_ptr = boost::get<std::string>(ns);

             if (s_ptr) {

               running_count += s_ptr->size();

             }

           } else {

             UNREACHABLE();

           }

         }

         return running_count;

       },

       std::plus<int64_t>());

 }


 }  // namespace


 ColumnarResults::ColumnarResults(std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

                                  const ResultSet& rows,

                                  const size_t num_columns,

                                  const std::vector<SQLTypeInfo>& target_types,

                                  const size_t executor_id,

                                  const size_t thread_idx,

                                  const bool is_parallel_execution_enforced)

     : column_buffers_(num_columns)

     , num_rows_(result_set::use_parallel_algorithms(rows) ||

                         rows.isDirectColumnarConversionPossible()

                     ? rows.entryCount()

                     : rows.rowCount())

     , target_types_(target_types)

     , parallel_conversion_(is_parallel_execution_enforced

                                ? true

                                : result_set::use_parallel_algorithms(rows))

     , direct_columnar_conversion_(rows.isDirectColumnarConversionPossible())

     , thread_idx_(thread_idx)

     , padded_target_sizes_(get_padded_target_sizes(rows, target_types)) {

   auto timer = DEBUG_TIMER(__func__);

   column_buffers_.resize(num_columns);

   executor_ = Executor::getExecutor(executor_id);

   CHECK(executor_);

   CHECK_EQ(padded_target_sizes_.size(), target_types.size());


   for (size_t i = 0; i < num_columns; ++i) {

     const auto& src_ti = rows.getColType(i);

     // ti is initialized in columnarize_result() function in

     // ColumnFetcher.cpp and it may differ from src_ti with respect to

     // uses_flatbuffer attribute

     const auto& ti = target_types_[i];


     if (rows.isZeroCopyColumnarConversionPossible(i)) {

       CHECK_EQ(ti.usesFlatBuffer(), src_ti.usesFlatBuffer());

       // The column buffer will be assigned in

       // ColumnarResults::copyAllNonLazyColumns.

       column_buffers_[i] = nullptr;

       continue;

     }

     CHECK(!(src_ti.usesFlatBuffer() && ti.usesFlatBuffer()));

     // When the source result set uses FlatBuffer layout, it must

     // support zero-copy columnar conversion. Otherwise, the source

     // result will be columnarized according to ti.usesFlatBuffer()

     // state that is set in columnarize_result function in

     // ColumnFetcher.cpp.

     if (src_ti.usesFlatBuffer() && ti.usesFlatBuffer()) {

       // If both source and target result sets use FlatBuffer layout,

       // creating a columnar result should be using zero-copy columnar

       // conversion.

       UNREACHABLE();

     } else if (ti.usesFlatBuffer()) {

       int64_t values_count = -1;

       switch (ti.get_type()) {

         case kARRAY:

           if (ti.get_subtype() == kTEXT && ti.get_compression() == kENCODING_NONE) {

             throw std::runtime_error(

                 "Column<Array<TextEncodedNone>> support not implemented yet "

                 "(ColumnarResults)");

           } else {

             values_count = computeTotalNofValuesForColumnArray(rows, i);

           }

           break;

         case kPOINT:

           values_count = num_rows_;

           break;

         case kLINESTRING:

           values_count =

               computeTotalNofValuesForColumnGeoType<GeoLineStringTargetValue,

                                                     GeoLineStringTargetValuePtr>(

                   rows, ti, i);

           break;

         case kPOLYGON:

           values_count =

               computeTotalNofValuesForColumnGeoType<GeoPolyTargetValue,

                                                     GeoPolyTargetValuePtr>(rows, ti, i);

           break;

         case kMULTIPOINT:

           values_count =

               computeTotalNofValuesForColumnGeoType<GeoMultiPointTargetValue,

                                                     GeoMultiPointTargetValuePtr>(

                   rows, ti, i);

           break;

         case kMULTILINESTRING:

           values_count =

               computeTotalNofValuesForColumnGeoType<GeoMultiLineStringTargetValue,

                                                     GeoMultiLineStringTargetValuePtr>(

                   rows, ti, i);

           break;

         case kMULTIPOLYGON:

           values_count =

               computeTotalNofValuesForColumnGeoType<GeoMultiPolyTargetValue,

                                                     GeoMultiPolyTargetValuePtr>(

                   rows, ti, i);

           break;

         case kTEXT:

           if (ti.get_compression() == kENCODING_NONE) {

             values_count = computeTotalNofValuesForColumnTextEncodingNone(rows, i);

             break;

           }

           if (ti.get_compression() == kENCODING_DICT) {

             values_count = num_rows_;

             break;

           }

         default:

           UNREACHABLE() << "computing number of values not implemented for "

                         << ti.toString();

       }

       // TODO: include sizes count to optimize flatbuffer size

       const int64_t flatbuffer_size = getFlatBufferSize(num_rows_, values_count, ti);

       column_buffers_[i] = row_set_mem_owner->allocate(flatbuffer_size, thread_idx_);

       FlatBufferManager m{column_buffers_[i]};

       initializeFlatBuffer(m, num_rows_, values_count, ti);

       // The column buffer will be initialized either directly or

       // through iteration.

       // TODO: implement QE-808 resolution here.

     } else {

       if (ti.is_varlen()) {

         throw ColumnarConversionNotSupported();

       }

       // The column buffer will be initialized either directly or

       // through iteration.

       column_buffers_[i] =

           row_set_mem_owner->allocate(num_rows_ * padded_target_sizes_[i], thread_idx_);

     }

   }


   if (isDirectColumnarConversionPossible() && rows.entryCount() > 0) {

     materializeAllColumnsDirectly(rows, num_columns);

   } else {

     materializeAllColumnsThroughIteration(rows, num_columns);

   }

 }


 ColumnarResults::ColumnarResults(std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

                                  const int8_t* one_col_buffer,

                                  const size_t num_rows,

                                  const SQLTypeInfo& target_type,

                                  const size_t executor_id,

                                  const size_t thread_idx)

     : column_buffers_(1)

     , num_rows_(num_rows)

     , target_types_{target_type}

     , parallel_conversion_(false)

     , direct_columnar_conversion_(false)

     , thread_idx_(thread_idx) {

   auto timer = DEBUG_TIMER(__func__);

   const bool is_varlen =

       target_type.is_array() ||

       (target_type.is_string() && target_type.get_compression() == kENCODING_NONE) ||

       target_type.is_geometry();

   if (is_varlen) {

     throw ColumnarConversionNotSupported();

   }

   executor_ = Executor::getExecutor(executor_id);

   padded_target_sizes_.emplace_back(target_type.get_size());

   CHECK(executor_);

   const auto buf_size = num_rows * target_type.get_size();

   column_buffers_[0] =

       reinterpret_cast<int8_t*>(row_set_mem_owner->allocate(buf_size, thread_idx_));

   memcpy(((void*)column_buffers_[0]), one_col_buffer, buf_size);

 }


 std::unique_ptr<ColumnarResults> ColumnarResults::mergeResults(

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     const std::vector<std::unique_ptr<ColumnarResults>>& sub_results) {

   // TODO: this method requires a safe guard when trying to merge

   // columns using FlatBuffer layout.

   if (sub_results.empty()) {

     return nullptr;

   }

   const auto total_row_count = std::accumulate(

       sub_results.begin(),

       sub_results.end(),

       size_t(0),

       [](const size_t init, const std::unique_ptr<ColumnarResults>& result) {

         return init + result->size();

       });

   std::unique_ptr<ColumnarResults> merged_results(

       new ColumnarResults(total_row_count,

                           sub_results[0]->target_types_,

                           sub_results[0]->padded_target_sizes_));

   const auto col_count = sub_results[0]->column_buffers_.size();

   const auto nonempty_it = std::find_if(

       sub_results.begin(),

       sub_results.end(),

       [](const std::unique_ptr<ColumnarResults>& needle) { return needle->size(); });

   if (nonempty_it == sub_results.end()) {

     return nullptr;

   }

   for (size_t col_idx = 0; col_idx < col_count; ++col_idx) {

     const auto byte_width = merged_results->padded_target_sizes_[col_idx];

     auto write_ptr = row_set_mem_owner->allocate(byte_width * total_row_count);

     merged_results->column_buffers_.push_back(write_ptr);

     for (auto& rs : sub_results) {

       CHECK_EQ(col_count, rs->column_buffers_.size());

       if (!rs->size()) {

         continue;

       }

       CHECK_EQ(byte_width, rs->padded_target_sizes_[col_idx]);

       memcpy(write_ptr, rs->column_buffers_[col_idx], rs->size() * byte_width);

       write_ptr += rs->size() * byte_width;

     }

   }

   return merged_results;

 }


 void ColumnarResults::materializeAllColumnsThroughIteration(const ResultSet& rows,

                                                             const size_t num_columns) {

   if (isParallelConversion()) {

     std::atomic<size_t> row_idx{0};

     const size_t worker_count = cpu_threads();

     std::vector<std::future<void>> conversion_threads;

     std::mutex write_mutex;

     const auto do_work =

         [num_columns, &rows, &row_idx, &write_mutex, this](const size_t i) {

           const auto crt_row = rows.getRowAtNoTranslations(i);

           if (!crt_row.empty()) {

             auto cur_row_idx = row_idx.fetch_add(1);

             for (size_t col_idx = 0; col_idx < num_columns; ++col_idx) {

               auto& type_info = target_types_[col_idx];

               writeBackCell(crt_row[col_idx],

                             cur_row_idx,

                             type_info,

                             column_buffers_[col_idx],

                             &write_mutex);

             }

           }

         };

     for (auto interval : makeIntervals(size_t(0), rows.entryCount(), worker_count)) {

       conversion_threads.push_back(std::async(

           std::launch::async,

           [&do_work, this](const size_t start, const size_t end) {

             if (g_enable_non_kernel_time_query_interrupt) {

               size_t local_idx = 0;

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

                 if (UNLIKELY((local_idx & 0xFFFF) == 0 &&

                              executor_->checkNonKernelTimeInterrupted())) {

                   throw QueryExecutionError(Executor::ERR_INTERRUPTED);

                 }

                 do_work(i);

               }

             } else {

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

                 do_work(i);

               }

             }

           },

           interval.begin,

           interval.end));

     }


     try {

       for (auto& child : conversion_threads) {

         child.wait();

       }

     } catch (QueryExecutionError& e) {

       if (e.getErrorCode() == Executor::ERR_INTERRUPTED) {

         throw QueryExecutionError(Executor::ERR_INTERRUPTED);

       }

       throw e;

     } catch (...) {

       throw;

     }


     num_rows_ = row_idx;

     rows.setCachedRowCount(num_rows_);

     return;

   }

   bool done = false;

   size_t row_idx = 0;

   const auto do_work = [num_columns, &row_idx, &rows, &done, this]() {

     const auto crt_row = rows.getNextRow(false, false);

     if (crt_row.empty()) {

       done = true;

       return;

     }

     for (size_t i = 0; i < num_columns; ++i) {

       auto& type_info = target_types_[i];

       writeBackCell(crt_row[i], row_idx, type_info, column_buffers_[i]);

     }

     ++row_idx;

   };

   if (g_enable_non_kernel_time_query_interrupt) {

     while (!done) {

       if (UNLIKELY((row_idx & 0xFFFF) == 0 &&

                    executor_->checkNonKernelTimeInterrupted())) {

         throw QueryExecutionError(Executor::ERR_INTERRUPTED);

       }

       do_work();

     }

   } else {

     while (!done) {

       do_work();

     }

   }


   rows.moveToBegin();

 }


 template <size_t NDIM,

           typename GeospatialGeoType,

           typename GeoTypeTargetValue,

           typename GeoTypeTargetValuePtr,

           bool is_multi>

 void writeBackCellGeoNestedArray(FlatBufferManager& m,

                                  const int64_t index,

                                  const SQLTypeInfo& ti,

                                  const TargetValue& col_val,

                                  std::mutex* write_mutex) {

   const SQLTypeInfoLite* ti_lite =

       reinterpret_cast<const SQLTypeInfoLite*>(m.get_user_data_buffer());

   CHECK(ti_lite);

   if (ti_lite->is_geoint()) {

     CHECK_EQ(ti.get_compression(), kENCODING_GEOINT);

   } else {

     CHECK_EQ(ti.get_compression(), kENCODING_NONE);

   }

   FlatBufferManager::Status status{};

   if (const auto tv = boost::get<ScalarTargetValue>(&col_val)) {

     const auto ns = boost::get<NullableString>(tv);

     CHECK(ns);

     const auto s_ptr = boost::get<std::string>(ns);

     if (s_ptr == nullptr || *s_ptr == "NULL") {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setNull(index);

     } else {

       std::vector<double> coords;

       std::vector<double> bounds;

       std::vector<int32_t> ring_sizes;

       std::vector<int32_t> poly_rings;

       int64_t approx_nof_coords = 2 * std::count(s_ptr->begin(), s_ptr->end(), ',');

       coords.reserve(approx_nof_coords);

       bounds.reserve(4);

       const auto gdal_wkt_ls = GeospatialGeoType(*s_ptr);

       if constexpr (NDIM == 1) {

         gdal_wkt_ls.getColumns(coords, bounds);

       } else if constexpr (NDIM == 2) {

         int64_t approx_nof_rings = std::count(s_ptr->begin(), s_ptr->end(), '(') - 1;

         ring_sizes.reserve(approx_nof_rings);

         gdal_wkt_ls.getColumns(coords, ring_sizes, bounds);

       } else if constexpr (NDIM == 3) {

         int64_t approx_nof_rings = std::count(s_ptr->begin(), s_ptr->end(), '(') - 1;

         ring_sizes.reserve(approx_nof_rings);

         poly_rings.reserve(approx_nof_rings);

         gdal_wkt_ls.getColumns(coords, ring_sizes, poly_rings, bounds);

       } else {

         UNREACHABLE();

       }

       const std::vector<uint8_t> compressed_coords =

           Geospatial::compress_coords(coords, ti);

       {

         auto lock_scope =

             (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                     : std::unique_lock<std::mutex>(*write_mutex));

         if constexpr (NDIM == 1) {

           status = m.setItem(index, compressed_coords);

         } else if constexpr (NDIM == 2) {

           status = m.setItem(index, compressed_coords, ring_sizes);

         } else if constexpr (NDIM == 3) {

           status = m.setItem(index, compressed_coords, ring_sizes, poly_rings);

         } else {

           UNREACHABLE();

         }

       }

     }

   } else if (const auto tv = boost::get<GeoTargetValuePtr>(&col_val)) {

     const auto s = boost::get<GeoTypeTargetValuePtr>(tv);

     CHECK(s);

     if (s->coords_data == nullptr || s->coords_data->pointer == nullptr) {

       status = m.setNull(index);

     } else {

       const VarlenDatum* d = s->coords_data.get();

       CHECK(d);

       CHECK(d->pointer);


       int32_t nof_values =

           d->length / (ti_lite->is_geoint() ? 2 * sizeof(int32_t) : 2 * sizeof(double));

       {

         auto lock_scope =

             (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                     : std::unique_lock<std::mutex>(*write_mutex));

         if constexpr (NDIM == 1) {

           status = m.setItem<0, false>(index, d->pointer, nof_values);

         } else if constexpr (NDIM == 2) {

           VarlenDatum* r = nullptr;

           if constexpr (is_multi) {

             r = s->linestring_sizes_data.get();

           } else {

             r = s->ring_sizes_data.get();

           }

           status = m.setItem<1, /*check_sizes=*/false>(

               index,

               d->pointer,

               nof_values,

               reinterpret_cast<const int32_t*>(r->pointer),

               r->length / sizeof(int32_t));

         } else if constexpr (NDIM == 3) {

           const VarlenDatum* r = s->ring_sizes_data.get();

           const VarlenDatum* p = s->poly_rings_data.get();

           status = m.setItem<2, /*check_sizes=*/false>(

               index,

               d->pointer,

               nof_values,

               reinterpret_cast<const int32_t*>(r->pointer),

               r->length / sizeof(int32_t),

               reinterpret_cast<const int32_t*>(p->pointer),

               p->length / sizeof(int32_t));

         } else {

           UNREACHABLE();

         }

       }

     }

   } else if (const auto tv = boost::get<GeoTargetValue>(&col_val)) {

     if (tv->get_ptr() == nullptr) {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setNull(index);

     } else {

       const auto s = boost::get<GeoTypeTargetValue>(tv->get());

       const std::vector<double>* d = s.coords.get();

       const std::vector<int32_t>* r = nullptr;

       const std::vector<int32_t>* p = nullptr;

       if constexpr (NDIM == 1) {

         CHECK(r == nullptr);

         CHECK(p == nullptr);

       } else if constexpr (NDIM == 2) {

         if constexpr (is_multi) {

           r = s.linestring_sizes.get();

         } else {

           r = s.ring_sizes.get();

         }

         CHECK(p == nullptr);

       } else if constexpr (NDIM == 3) {

         r = s.ring_sizes.get();

         p = s.poly_rings.get();

       } else {

         UNREACHABLE();

       }

       CHECK(d);

       CHECK_NE(d->size(), 0);

       std::vector<uint8_t> compressed_coords = Geospatial::compress_coords(*d, ti);

       {

         auto lock_scope =

             (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                     : std::unique_lock<std::mutex>(*write_mutex));

         if constexpr (NDIM == 1) {

           status = m.setItem(index, compressed_coords);

         } else if constexpr (NDIM == 2) {

           status = m.setItem(index, compressed_coords, *r);

         } else if constexpr (NDIM == 3) {

           status = m.setItem(index, compressed_coords, *r, *p);

         } else {

           UNREACHABLE();

         }

       }

     }

   } else {

     UNREACHABLE();

   }

   CHECK_EQ(status, FlatBufferManager::Status::Success);

 }


 template <typename scalar_type, typename value_type>

 void writeBackCellArrayScalar(FlatBufferManager& m,

                               const size_t row_idx,

                               const TargetValue& col_val,

                               std::mutex* write_mutex) {

   FlatBufferManager::Status status{};

   const auto arr_tv = boost::get<ArrayTargetValue>(&col_val);

   if (arr_tv->is_initialized()) {

     const auto& vec = arr_tv->get();

     // add a new item to flatbuffer, no initialization

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setItem<1, false>(row_idx, nullptr, vec.size());

     }

     CHECK_EQ(status, FlatBufferManager::Status::Success);

     FlatBufferManager::NestedArrayItem<1> item;

     // retrieve the item

     status = m.getItem(row_idx, item);

     CHECK_EQ(status, FlatBufferManager::Status::Success);

     CHECK_EQ(item.nof_sizes, 0);            // for sanity

     CHECK_EQ(item.nof_values, vec.size());  // for sanity

     // initialize the item's buffer

     scalar_type* values = reinterpret_cast<scalar_type*>(item.values);

     size_t index = 0;

     for (const TargetValue val : vec) {

       const auto& scalar_val = boost::get<ScalarTargetValue>(&val);

       values[index++] = static_cast<scalar_type>(*boost::get<value_type>(scalar_val));

     }

   } else {

     // add a new NULL item to flatbuffer

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setNull(row_idx);

     }

     CHECK_EQ(status, FlatBufferManager::Status::Success);

   }

 }


 inline void writeBackCellTextEncodingNone(FlatBufferManager& m,

                                           const size_t row_idx,

                                           const TargetValue& col_val,

                                           std::mutex* write_mutex) {

   FlatBufferManager::Status status{};

   if (const auto tv = boost::get<ScalarTargetValue>(&col_val)) {

     const auto ns = boost::get<NullableString>(tv);

     CHECK(ns);

     const auto s_ptr = boost::get<std::string>(ns);

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       if (s_ptr) {

         status = m.setItem(row_idx, *s_ptr);

       } else {

         status = m.setNull(row_idx);

       }

     }

     CHECK_EQ(status, FlatBufferManager::Status::Success);

   } else {

     UNREACHABLE();

   }

 }


 inline void writeBackCellGeoPoint(FlatBufferManager& m,

                                   const size_t row_idx,

                                   const SQLTypeInfo& type_info,

                                   const TargetValue& col_val,

                                   std::mutex* write_mutex) {

   FlatBufferManager::Status status{};

   // to be deprecated, this function uses old FlatBuffer API

   if (const auto tv = boost::get<ScalarTargetValue>(&col_val)) {

     const auto ns = boost::get<NullableString>(tv);

     CHECK(ns);

     const auto s_ptr = boost::get<std::string>(ns);

     std::vector<double> coords;

     coords.reserve(2);

     if (s_ptr == nullptr) {

       coords.push_back(NULL_ARRAY_DOUBLE);

       coords.push_back(NULL_ARRAY_DOUBLE);

     } else {

       const auto gdal_wkt_pt = Geospatial::GeoPoint(*s_ptr);

       gdal_wkt_pt.getColumns(coords);

       CHECK_EQ(coords.size(), 2);

     }

     std::vector<std::uint8_t> data = Geospatial::compress_coords(coords, type_info);

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setItemOld(

           row_idx, reinterpret_cast<const int8_t*>(data.data()), data.size());

     }

     CHECK_EQ(status, FlatBufferManager::Status::Success);

   } else if (const auto tv = boost::get<GeoTargetValuePtr>(&col_val)) {

     const auto s = boost::get<GeoPointTargetValuePtr>(tv);

     CHECK(s);

     VarlenDatum* d = s->coords_data.get();

     CHECK(d);

     CHECK_EQ(type_info.get_compression() == kENCODING_GEOINT,

              m.getGeoPointMetadata()->is_geoint);

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status =

           m.setItemOld(row_idx, reinterpret_cast<const int8_t*>(d->pointer), d->length);

     }

     CHECK_EQ(status, FlatBufferManager::Status::Success);

   } else if (const auto tv = boost::get<GeoTargetValue>(&col_val)) {

     /*

       Warning: the following code fails for NULL row values

       because of the failure to detect the nullness correctly.

     */

     const auto s = boost::get<GeoPointTargetValue>(tv->get());

     const std::vector<double>* d = s.coords.get();

     CHECK_EQ(d->size(), 2);

     {

       auto lock_scope =

           (write_mutex == nullptr ? std::unique_lock<std::mutex>()

                                   : std::unique_lock<std::mutex>(*write_mutex));

       status = m.setItemOld(

           row_idx, reinterpret_cast<const int8_t*>(d->data()), m.dtypeSize());

     }

     CHECK_EQ(d->size(), 2);

     CHECK_EQ(status, FlatBufferManager::Status::Success);

   } else {

     UNREACHABLE();

   }

 }


 /*

  * This function processes and decodes its input TargetValue

  * and write it into its corresponding column buffer's cell (with corresponding

  * row and column indices)

  *

  * NOTE: this is not supposed to be processing varlen types (except

  * FlatBuffer supported types such as Array, GeoPoint, etc), and they

  * should be handled differently outside this function. TODO: QE-808.

  */


 inline void ColumnarResults::writeBackCell(const TargetValue& col_val,

                                            const size_t row_idx,

                                            const SQLTypeInfo& type_info,

                                            int8_t* column_buf,

                                            std::mutex* write_mutex) {

   if (!type_info.usesFlatBuffer()) {

     toBuffer(col_val, type_info, column_buf + type_info.get_size() * row_idx);

     return;

   }

   CHECK(FlatBufferManager::isFlatBuffer(column_buf));

   FlatBufferManager m{column_buf};

   if (type_info.is_geometry() && type_info.get_type() == kPOINT) {

     writeBackCellGeoPoint(m, row_idx, type_info, col_val, write_mutex);

     return;

   }

   const SQLTypeInfoLite* ti_lite =

       reinterpret_cast<const SQLTypeInfoLite*>(m.get_user_data_buffer());

   CHECK(ti_lite);

   if (type_info.is_array()) {

     if (type_info.get_subtype() == kTEXT &&

         type_info.get_compression() == kENCODING_NONE) {

       throw std::runtime_error(

           "Column<Array<TextEncodedNone>> support not implemented yet (writeBackCell)");

     }

     switch (ti_lite->subtype) {

       case SQLTypeInfoLite::DOUBLE:

         writeBackCellArrayScalar<double, double>(m, row_idx, col_val, write_mutex);

         break;

       case SQLTypeInfoLite::FLOAT:

         writeBackCellArrayScalar<float, float>(m, row_idx, col_val, write_mutex);

         break;

       case SQLTypeInfoLite::BOOLEAN:

       case SQLTypeInfoLite::TINYINT:

         writeBackCellArrayScalar<int8_t, int64_t>(m, row_idx, col_val, write_mutex);

         break;

       case SQLTypeInfoLite::SMALLINT:

         writeBackCellArrayScalar<int16_t, int64_t>(m, row_idx, col_val, write_mutex);

         break;

       case SQLTypeInfoLite::INT:

       case SQLTypeInfoLite::TEXT:

         writeBackCellArrayScalar<int32_t, int64_t>(m, row_idx, col_val, write_mutex);

         break;

       case SQLTypeInfoLite::BIGINT:

         writeBackCellArrayScalar<int64_t, int64_t>(m, row_idx, col_val, write_mutex);

         break;

       default:

         UNREACHABLE();

     }

   } else if (type_info.is_text_encoding_none()) {

     writeBackCellTextEncodingNone(m, row_idx, col_val, write_mutex);

   } else if (type_info.is_geometry()) {

     switch (type_info.get_type()) {

       case kLINESTRING: {

         writeBackCellGeoNestedArray<1,

                                     Geospatial::GeoLineString,

                                     GeoLineStringTargetValue,

                                     GeoLineStringTargetValuePtr,

                                     /*is_multi=*/false>(

             m, row_idx, type_info, col_val, write_mutex);

         break;

       }

       case kPOLYGON: {

         writeBackCellGeoNestedArray<2,

                                     Geospatial::GeoPolygon,

                                     GeoPolyTargetValue,

                                     GeoPolyTargetValuePtr,

                                     /*is_multi=*/false>(

             m, row_idx, type_info, col_val, write_mutex);

         break;

       }

       case kMULTIPOINT: {

         writeBackCellGeoNestedArray<1,

                                     Geospatial::GeoMultiPoint,

                                     GeoMultiPointTargetValue,

                                     GeoMultiPointTargetValuePtr,

                                     /*is_multi=*/true>(

             m, row_idx, type_info, col_val, write_mutex);

         break;

       }

       case kMULTILINESTRING: {

         writeBackCellGeoNestedArray<2,

                                     Geospatial::GeoMultiLineString,

                                     GeoMultiLineStringTargetValue,

                                     GeoMultiLineStringTargetValuePtr,

                                     /*is_multi=*/true>(

             m, row_idx, type_info, col_val, write_mutex);

         break;

       }

       case kMULTIPOLYGON: {

         writeBackCellGeoNestedArray<3,

                                     Geospatial::GeoMultiPolygon,

                                     GeoMultiPolyTargetValue,

                                     GeoMultiPolyTargetValuePtr,

                                     /*is_true=*/false>(

             m, row_idx, type_info, col_val, write_mutex);

         break;

       }

       default:

         UNREACHABLE() << "writeBackCell not implemented for " << type_info.toString();

     }

   } else {

     UNREACHABLE();

   }

 }


 template <typename DATA_TYPE>

 void ColumnarResults::writeBackCellDirect(const ResultSet& rows,

                                           const size_t input_buffer_entry_idx,

                                           const size_t output_buffer_entry_idx,

                                           const size_t target_idx,

                                           const size_t slot_idx,

                                           const ReadFunction& read_from_function) {

   const auto val = static_cast<DATA_TYPE>(fixed_encoding_nullable_val(

       read_from_function(rows, input_buffer_entry_idx, target_idx, slot_idx),

       target_types_[target_idx]));

   reinterpret_cast<DATA_TYPE*>(column_buffers_[target_idx])[output_buffer_entry_idx] =

       val;

 }


 template <>

 void ColumnarResults::writeBackCellDirect<float>(const ResultSet& rows,

                                                  const size_t input_buffer_entry_idx,

                                                  const size_t output_buffer_entry_idx,

                                                  const size_t target_idx,

                                                  const size_t slot_idx,

                                                  const ReadFunction& read_from_function) {

   const int32_t ival =

       read_from_function(rows, input_buffer_entry_idx, target_idx, slot_idx);

   const float fval = *reinterpret_cast<const float*>(may_alias_ptr(&ival));

   reinterpret_cast<float*>(column_buffers_[target_idx])[output_buffer_entry_idx] = fval;

 }


 template <>

 void ColumnarResults::writeBackCellDirect<double>(

     const ResultSet& rows,

     const size_t input_buffer_entry_idx,

     const size_t output_buffer_entry_idx,

     const size_t target_idx,

     const size_t slot_idx,

     const ReadFunction& read_from_function) {

   const int64_t ival =

       read_from_function(rows, input_buffer_entry_idx, target_idx, slot_idx);

   const double dval = *reinterpret_cast<const double*>(may_alias_ptr(&ival));

   reinterpret_cast<double*>(column_buffers_[target_idx])[output_buffer_entry_idx] = dval;

 }


 void ColumnarResults::materializeAllColumnsDirectly(const ResultSet& rows,

                                                     const size_t num_columns) {

   CHECK(isDirectColumnarConversionPossible());

   switch (rows.getQueryDescriptionType()) {

     case QueryDescriptionType::Projection: {

       materializeAllColumnsProjection(rows, num_columns);

       break;

     }

     case QueryDescriptionType::TableFunction: {

       materializeAllColumnsTableFunction(rows, num_columns);

       break;

     }

     case QueryDescriptionType::GroupByPerfectHash:

     case QueryDescriptionType::GroupByBaselineHash: {

       materializeAllColumnsGroupBy(rows, num_columns);

       break;

     }

     default:

       UNREACHABLE()

           << "Direct columnar conversion for this query type is not supported yet.";

   }

 }


 void ColumnarResults::materializeAllColumnsProjection(const ResultSet& rows,

                                                       const size_t num_columns) {

   CHECK(rows.query_mem_desc_.didOutputColumnar());

   CHECK(isDirectColumnarConversionPossible() &&

         (rows.query_mem_desc_.getQueryDescriptionType() ==

          QueryDescriptionType::Projection));


   const auto& lazy_fetch_info = rows.getLazyFetchInfo();


   // We can directly copy each non-lazy column's content

   copyAllNonLazyColumns(lazy_fetch_info, rows, num_columns);


   // Only lazy columns are iterated through first and then materialized

   materializeAllLazyColumns(lazy_fetch_info, rows, num_columns);

 }


 void ColumnarResults::materializeAllColumnsTableFunction(const ResultSet& rows,

                                                          const size_t num_columns) {

   CHECK(rows.query_mem_desc_.didOutputColumnar());

   CHECK(isDirectColumnarConversionPossible() &&

         (rows.query_mem_desc_.getQueryDescriptionType() ==

          QueryDescriptionType::TableFunction));


   const auto& lazy_fetch_info = rows.getLazyFetchInfo();

   // Lazy fetching is not currently allowed for table function outputs

   for (const auto& col_lazy_fetch_info : lazy_fetch_info) {

     CHECK(!col_lazy_fetch_info.is_lazily_fetched);

   }

   // We can directly copy each non-lazy column's content

   copyAllNonLazyColumns(lazy_fetch_info, rows, num_columns);

 }


 /*

  * For all non-lazy columns, we can directly copy back the results of each column's

  * contents from different storages and put them into the corresponding output buffer.

  *

  * This function is parallelized through assigning each column to a CPU thread.

  */

 void ColumnarResults::copyAllNonLazyColumns(

     const std::vector<ColumnLazyFetchInfo>& lazy_fetch_info,

     const ResultSet& rows,

     const size_t num_columns) {

   CHECK(isDirectColumnarConversionPossible());

   const auto is_column_non_lazily_fetched = [&lazy_fetch_info](const size_t col_idx) {

     // Saman: make sure when this lazy_fetch_info is empty

     if (lazy_fetch_info.empty()) {

       return true;

     } else {

       return !lazy_fetch_info[col_idx].is_lazily_fetched;

     }

   };


   // parallelized by assigning each column to a thread

   std::vector<std::future<void>> direct_copy_threads;

   for (size_t col_idx = 0; col_idx < num_columns; col_idx++) {

     if (rows.isZeroCopyColumnarConversionPossible(col_idx)) {

       CHECK(!column_buffers_[col_idx]);

       // The name of the method implies a copy but this is not a copy!!

       column_buffers_[col_idx] = const_cast<int8_t*>(rows.getColumnarBuffer(col_idx));

     } else if (is_column_non_lazily_fetched(col_idx)) {

       CHECK(!(rows.query_mem_desc_.getQueryDescriptionType() ==

               QueryDescriptionType::TableFunction));

       if (rows.getColType(col_idx).usesFlatBuffer() &&

           target_types_[col_idx].usesFlatBuffer()) {

         // If both source and target result sets use FlatBuffer

         // layout, creating a columnar result should be using

         // zero-copy columnar conversion.

         UNREACHABLE();

       }

       direct_copy_threads.push_back(std::async(

           std::launch::async,

           [&rows, this](const size_t column_index) {

             size_t column_size = rows.getColumnarBufferSize(column_index);

             rows.copyColumnIntoBuffer(

                 column_index, column_buffers_[column_index], column_size);

           },

           col_idx));

     }

   }


   for (auto& child : direct_copy_threads) {

     child.wait();

   }

 }


 void ColumnarResults::materializeAllLazyColumns(

     const std::vector<ColumnLazyFetchInfo>& lazy_fetch_info,

     const ResultSet& rows,

     const size_t num_columns) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(!(rows.query_mem_desc_.getQueryDescriptionType() ==

           QueryDescriptionType::TableFunction));

   std::mutex write_mutex;

   const auto do_work_just_lazy_columns = [num_columns, &rows, &write_mutex, this](

                                              const size_t row_idx,

                                              const std::vector<bool>& targets_to_skip) {

     const auto crt_row = rows.getRowAtNoTranslations(row_idx, targets_to_skip);

     for (size_t i = 0; i < num_columns; ++i) {

       if (!targets_to_skip.empty() && !targets_to_skip[i]) {

         auto& type_info = target_types_[i];

         writeBackCell(crt_row[i], row_idx, type_info, column_buffers_[i], &write_mutex);

       }

     }

   };


   const auto contains_lazy_fetched_column =

       [](const std::vector<ColumnLazyFetchInfo>& lazy_fetch_info) {

         for (auto& col_info : lazy_fetch_info) {

           if (col_info.is_lazily_fetched) {

             return true;

           }

         }

         return false;

       };


   // parallelized by assigning a chunk of rows to each thread)

   const bool skip_non_lazy_columns = rows.isPermutationBufferEmpty();

   if (contains_lazy_fetched_column(lazy_fetch_info)) {

     const size_t worker_count =

         result_set::use_parallel_algorithms(rows) ? cpu_threads() : 1;

     std::vector<std::future<void>> conversion_threads;

     std::vector<bool> targets_to_skip;

     if (skip_non_lazy_columns) {

       CHECK_EQ(lazy_fetch_info.size(), size_t(num_columns));

       targets_to_skip.reserve(num_columns);

       for (size_t i = 0; i < num_columns; i++) {

         // we process lazy columns (i.e., skip non-lazy columns)

         targets_to_skip.push_back(!lazy_fetch_info[i].is_lazily_fetched);

       }

     }

     for (auto interval : makeIntervals(size_t(0), rows.entryCount(), worker_count)) {

       conversion_threads.push_back(std::async(

           std::launch::async,

           [&do_work_just_lazy_columns, &targets_to_skip, this](const size_t start,

                                                                const size_t end) {

             if (g_enable_non_kernel_time_query_interrupt) {

               size_t local_idx = 0;

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

                 if (UNLIKELY((local_idx & 0xFFFF) == 0 &&

                              executor_->checkNonKernelTimeInterrupted())) {

                   throw QueryExecutionError(Executor::ERR_INTERRUPTED);

                 }

                 do_work_just_lazy_columns(i, targets_to_skip);

               }

             } else {

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

                 do_work_just_lazy_columns(i, targets_to_skip);

               }

             }

           },

           interval.begin,

           interval.end));

     }


     try {

       for (auto& child : conversion_threads) {

         child.wait();

       }

     } catch (QueryExecutionError& e) {

       if (e.getErrorCode() == Executor::ERR_INTERRUPTED) {

         throw QueryExecutionError(Executor::ERR_INTERRUPTED);

       }

       throw e;

     } catch (...) {

       throw;

     }

   }

 }


 void ColumnarResults::materializeAllColumnsGroupBy(const ResultSet& rows,

                                                    const size_t num_columns) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);


   const size_t num_threads = isParallelConversion() ? cpu_threads() : 1;

   const size_t entry_count = rows.entryCount();

   const size_t size_per_thread = (entry_count + num_threads - 1) / num_threads;


   // step 1: compute total non-empty elements and store a bitmap per thread

   std::vector<size_t> non_empty_per_thread(num_threads,

                                            0);  // number of non-empty entries per thread


   ColumnBitmap bitmap(size_per_thread, num_threads);


   locateAndCountEntries(

       rows, bitmap, non_empty_per_thread, entry_count, num_threads, size_per_thread);


   // step 2: go through the generated bitmap and copy/decode corresponding entries

   // into the output buffer

   compactAndCopyEntries(rows,

                         bitmap,

                         non_empty_per_thread,

                         num_columns,

                         entry_count,

                         num_threads,

                         size_per_thread);

 }


 void ColumnarResults::locateAndCountEntries(const ResultSet& rows,

                                             ColumnBitmap& bitmap,

                                             std::vector<size_t>& non_empty_per_thread,

                                             const size_t entry_count,

                                             const size_t num_threads,

                                             const size_t size_per_thread) const {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);

   CHECK_EQ(num_threads, non_empty_per_thread.size());

   auto do_work = [&rows, &bitmap](size_t& total_non_empty,

                                   const size_t local_idx,

                                   const size_t entry_idx,

                                   const size_t thread_idx) {

     if (!rows.isRowAtEmpty(entry_idx)) {

       total_non_empty++;

       bitmap.set(local_idx, thread_idx, true);

     }

   };

   auto locate_and_count_func =

       [&do_work, &non_empty_per_thread, this](

           size_t start_index, size_t end_index, size_t thread_idx) {

         size_t total_non_empty = 0;

         size_t local_idx = 0;

         if (g_enable_non_kernel_time_query_interrupt) {

           for (size_t entry_idx = start_index; entry_idx < end_index;

                entry_idx++, local_idx++) {

             if (UNLIKELY((local_idx & 0xFFFF) == 0 &&

                          executor_->checkNonKernelTimeInterrupted())) {

               throw QueryExecutionError(Executor::ERR_INTERRUPTED);

             }

             do_work(total_non_empty, local_idx, entry_idx, thread_idx);

           }

         } else {

           for (size_t entry_idx = start_index; entry_idx < end_index;

                entry_idx++, local_idx++) {

             do_work(total_non_empty, local_idx, entry_idx, thread_idx);

           }

         }

         non_empty_per_thread[thread_idx] = total_non_empty;

       };


   std::vector<std::future<void>> conversion_threads;

   for (size_t thread_idx = 0; thread_idx < num_threads; thread_idx++) {

     const size_t start_entry = thread_idx * size_per_thread;

     const size_t end_entry = std::min(start_entry + size_per_thread, entry_count);

     conversion_threads.push_back(std::async(

         std::launch::async, locate_and_count_func, start_entry, end_entry, thread_idx));

   }


   try {

     for (auto& child : conversion_threads) {

       child.wait();

     }

   } catch (QueryExecutionError& e) {

     if (e.getErrorCode() == Executor::ERR_INTERRUPTED) {

       throw QueryExecutionError(Executor::ERR_INTERRUPTED);

     }

     throw e;

   } catch (...) {

     throw;

   }

 }


 void ColumnarResults::compactAndCopyEntries(

     const ResultSet& rows,

     const ColumnBitmap& bitmap,

     const std::vector<size_t>& non_empty_per_thread,

     const size_t num_columns,

     const size_t entry_count,

     const size_t num_threads,

     const size_t size_per_thread) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);

   CHECK_EQ(num_threads, non_empty_per_thread.size());


   // compute the exclusive scan over all non-empty totals

   std::vector<size_t> global_offsets(num_threads + 1, 0);

   std::partial_sum(non_empty_per_thread.begin(),

                    non_empty_per_thread.end(),

                    std::next(global_offsets.begin()));


   const auto slot_idx_per_target_idx = rows.getSlotIndicesForTargetIndices();

   const auto [single_slot_targets_to_skip, num_single_slot_targets] =

       rows.getSupportedSingleSlotTargetBitmap();


   // We skip multi-slot targets (e.g., AVG). These skipped targets are treated

   // differently and accessed through result set's iterator

   if (num_single_slot_targets < num_columns) {

     compactAndCopyEntriesWithTargetSkipping(rows,

                                             bitmap,

                                             non_empty_per_thread,

                                             global_offsets,

                                             single_slot_targets_to_skip,

                                             slot_idx_per_target_idx,

                                             num_columns,

                                             entry_count,

                                             num_threads,

                                             size_per_thread);

   } else {

     compactAndCopyEntriesWithoutTargetSkipping(rows,

                                                bitmap,

                                                non_empty_per_thread,

                                                global_offsets,

                                                slot_idx_per_target_idx,

                                                num_columns,

                                                entry_count,

                                                num_threads,

                                                size_per_thread);

   }

 }


 void ColumnarResults::compactAndCopyEntriesWithTargetSkipping(

     const ResultSet& rows,

     const ColumnBitmap& bitmap,

     const std::vector<size_t>& non_empty_per_thread,

     const std::vector<size_t>& global_offsets,

     const std::vector<bool>& targets_to_skip,

     const std::vector<size_t>& slot_idx_per_target_idx,

     const size_t num_columns,

     const size_t entry_count,

     const size_t num_threads,

     const size_t size_per_thread) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);


   const auto [write_functions, read_functions] =

       initAllConversionFunctions(rows, slot_idx_per_target_idx, targets_to_skip);

   CHECK_EQ(write_functions.size(), num_columns);

   CHECK_EQ(read_functions.size(), num_columns);

   std::mutex write_mutex;

   auto do_work = [this,

                   &bitmap,

                   &rows,

                   &slot_idx_per_target_idx,

                   &global_offsets,

                   &targets_to_skip,

                   &num_columns,

                   &write_mutex,

                   &write_functions = write_functions,

                   &read_functions = read_functions](size_t& non_empty_idx,

                                                     const size_t total_non_empty,

                                                     const size_t local_idx,

                                                     size_t& entry_idx,

                                                     const size_t thread_idx,

                                                     const size_t end_idx) {

     if (non_empty_idx >= total_non_empty) {

       // all non-empty entries has been written back

       entry_idx = end_idx;

     }

     const size_t output_buffer_row_idx = global_offsets[thread_idx] + non_empty_idx;

     if (bitmap.get(local_idx, thread_idx)) {

       // targets that are recovered from the result set iterators:

       const auto crt_row = rows.getRowAtNoTranslations(entry_idx, targets_to_skip);

       for (size_t column_idx = 0; column_idx < num_columns; ++column_idx) {

         if (!targets_to_skip.empty() && !targets_to_skip[column_idx]) {

           auto& type_info = target_types_[column_idx];

           writeBackCell(crt_row[column_idx],

                         output_buffer_row_idx,

                         type_info,

                         column_buffers_[column_idx],

                         &write_mutex);

         }

       }

       // targets that are copied directly without any translation/decoding from

       // result set

       for (size_t column_idx = 0; column_idx < num_columns; column_idx++) {

         if (!targets_to_skip.empty() && !targets_to_skip[column_idx]) {

           continue;

         }

         write_functions[column_idx](rows,

                                     entry_idx,

                                     output_buffer_row_idx,

                                     column_idx,

                                     slot_idx_per_target_idx[column_idx],

                                     read_functions[column_idx]);

       }

       non_empty_idx++;

     }

   };


   auto compact_buffer_func = [&non_empty_per_thread, &do_work, this](

                                  const size_t start_index,

                                  const size_t end_index,

                                  const size_t thread_idx) {

     const size_t total_non_empty = non_empty_per_thread[thread_idx];

     size_t non_empty_idx = 0;

     size_t local_idx = 0;

     if (g_enable_non_kernel_time_query_interrupt) {

       for (size_t entry_idx = start_index; entry_idx < end_index;

            entry_idx++, local_idx++) {

         if (UNLIKELY((local_idx & 0xFFFF) == 0 &&

                      executor_->checkNonKernelTimeInterrupted())) {

           throw QueryExecutionError(Executor::ERR_INTERRUPTED);

         }

         do_work(

             non_empty_idx, total_non_empty, local_idx, entry_idx, thread_idx, end_index);

       }

     } else {

       for (size_t entry_idx = start_index; entry_idx < end_index;

            entry_idx++, local_idx++) {

         do_work(

             non_empty_idx, total_non_empty, local_idx, entry_idx, thread_idx, end_index);

       }

     }

   };


   std::vector<std::future<void>> compaction_threads;

   for (size_t thread_idx = 0; thread_idx < num_threads; thread_idx++) {

     const size_t start_entry = thread_idx * size_per_thread;

     const size_t end_entry = std::min(start_entry + size_per_thread, entry_count);

     compaction_threads.push_back(std::async(

         std::launch::async, compact_buffer_func, start_entry, end_entry, thread_idx));

   }


   try {

     for (auto& child : compaction_threads) {

       child.wait();

     }

   } catch (QueryExecutionError& e) {

     if (e.getErrorCode() == Executor::ERR_INTERRUPTED) {

       throw QueryExecutionError(Executor::ERR_INTERRUPTED);

     }

     throw e;

   } catch (...) {

     throw;

   }

 }


 void ColumnarResults::compactAndCopyEntriesWithoutTargetSkipping(

     const ResultSet& rows,

     const ColumnBitmap& bitmap,

     const std::vector<size_t>& non_empty_per_thread,

     const std::vector<size_t>& global_offsets,

     const std::vector<size_t>& slot_idx_per_target_idx,

     const size_t num_columns,

     const size_t entry_count,

     const size_t num_threads,

     const size_t size_per_thread) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);


   const auto [write_functions, read_functions] =

       initAllConversionFunctions(rows, slot_idx_per_target_idx);

   CHECK_EQ(write_functions.size(), num_columns);

   CHECK_EQ(read_functions.size(), num_columns);

   auto do_work = [&rows,

                   &bitmap,

                   &global_offsets,

                   &num_columns,

                   &slot_idx_per_target_idx,

                   &write_functions = write_functions,

                   &read_functions = read_functions](size_t& entry_idx,

                                                     size_t& non_empty_idx,

                                                     const size_t total_non_empty,

                                                     const size_t local_idx,

                                                     const size_t thread_idx,

                                                     const size_t end_idx) {

     if (non_empty_idx >= total_non_empty) {

       // all non-empty entries has been written back

       entry_idx = end_idx;

       return;

     }

     const size_t output_buffer_row_idx = global_offsets[thread_idx] + non_empty_idx;

     if (bitmap.get(local_idx, thread_idx)) {

       for (size_t column_idx = 0; column_idx < num_columns; column_idx++) {

         write_functions[column_idx](rows,

                                     entry_idx,

                                     output_buffer_row_idx,

                                     column_idx,

                                     slot_idx_per_target_idx[column_idx],

                                     read_functions[column_idx]);

       }

       non_empty_idx++;

     }

   };

   auto compact_buffer_func = [&non_empty_per_thread, &do_work, this](

                                  const size_t start_index,

                                  const size_t end_index,

                                  const size_t thread_idx) {

     const size_t total_non_empty = non_empty_per_thread[thread_idx];

     size_t non_empty_idx = 0;

     size_t local_idx = 0;

     if (g_enable_non_kernel_time_query_interrupt) {

       for (size_t entry_idx = start_index; entry_idx < end_index;

            entry_idx++, local_idx++) {

         if (UNLIKELY((local_idx & 0xFFFF) == 0 &&

                      executor_->checkNonKernelTimeInterrupted())) {

           throw QueryExecutionError(Executor::ERR_INTERRUPTED);

         }

         do_work(

             entry_idx, non_empty_idx, total_non_empty, local_idx, thread_idx, end_index);

       }

     } else {

       for (size_t entry_idx = start_index; entry_idx < end_index;

            entry_idx++, local_idx++) {

         do_work(

             entry_idx, non_empty_idx, total_non_empty, local_idx, thread_idx, end_index);

       }

     }

   };


   std::vector<std::future<void>> compaction_threads;

   for (size_t thread_idx = 0; thread_idx < num_threads; thread_idx++) {

     const size_t start_entry = thread_idx * size_per_thread;

     const size_t end_entry = std::min(start_entry + size_per_thread, entry_count);

     compaction_threads.push_back(std::async(

         std::launch::async, compact_buffer_func, start_entry, end_entry, thread_idx));

   }


   try {

     for (auto& child : compaction_threads) {

       child.wait();

     }

   } catch (QueryExecutionError& e) {

     if (e.getErrorCode() == Executor::ERR_INTERRUPTED) {

       throw QueryExecutionError(Executor::ERR_INTERRUPTED);

     }

     throw e;

   } catch (...) {

     throw;

   }

 }


 std::vector<ColumnarResults::WriteFunction> ColumnarResults::initWriteFunctions(

     const ResultSet& rows,

     const std::vector<bool>& targets_to_skip) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

         rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash);


   std::vector<WriteFunction> result;

   result.reserve(target_types_.size());


   for (size_t target_idx = 0; target_idx < target_types_.size(); target_idx++) {

     if (!targets_to_skip.empty() && !targets_to_skip[target_idx]) {

       result.emplace_back([](const ResultSet& rows,

                              const size_t input_buffer_entry_idx,

                              const size_t output_buffer_entry_idx,

                              const size_t target_idx,

                              const size_t slot_idx,

                              const ReadFunction& read_function) {

         UNREACHABLE() << "Invalid write back function used.";

       });

       continue;

     }


     if (target_types_[target_idx].is_fp()) {

       switch (target_types_[target_idx].get_size()) {

         case 8:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<double>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         case 4:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<float>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         default:

           UNREACHABLE() << "Invalid target type encountered.";

           break;

       }

     } else {

       switch (target_types_[target_idx].get_size()) {

         case 8:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<int64_t>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         case 4:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<int32_t>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         case 2:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<int16_t>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         case 1:

           result.emplace_back(std::bind(&ColumnarResults::writeBackCellDirect<int8_t>,

                                         this,

                                         std::placeholders::_1,

                                         std::placeholders::_2,

                                         std::placeholders::_3,

                                         std::placeholders::_4,

                                         std::placeholders::_5,

                                         std::placeholders::_6));

           break;

         default:

           UNREACHABLE() << "Invalid target type encountered.";

           break;

       }

     }

   }

   return result;

 }


 namespace {


 int64_t invalid_read_func(const ResultSet& rows,

                           const size_t input_buffer_entry_idx,

                           const size_t target_idx,

                           const size_t slot_idx) {

   UNREACHABLE() << "Invalid read function used, target should have been skipped.";

   return static_cast<int64_t>(0);

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_float_key_baseline(const ResultSet& rows,

                                 const size_t input_buffer_entry_idx,

                                 const size_t target_idx,

                                 const size_t slot_idx) {

   // float keys in baseline hash are written as doubles in the buffer, so

   // the result should properly be casted before being written in the output

   // columns

   auto fval = static_cast<float>(rows.getEntryAt<double, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx));

   return *reinterpret_cast<int32_t*>(may_alias_ptr(&fval));

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_int64_func(const ResultSet& rows,

                         const size_t input_buffer_entry_idx,

                         const size_t target_idx,

                         const size_t slot_idx) {

   return rows.getEntryAt<int64_t, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_int32_func(const ResultSet& rows,

                         const size_t input_buffer_entry_idx,

                         const size_t target_idx,

                         const size_t slot_idx) {

   return rows.getEntryAt<int32_t, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_int16_func(const ResultSet& rows,

                         const size_t input_buffer_entry_idx,

                         const size_t target_idx,

                         const size_t slot_idx) {

   return rows.getEntryAt<int16_t, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_int8_func(const ResultSet& rows,

                        const size_t input_buffer_entry_idx,

                        const size_t target_idx,

                        const size_t slot_idx) {

   return rows.getEntryAt<int8_t, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_float_func(const ResultSet& rows,

                         const size_t input_buffer_entry_idx,

                         const size_t target_idx,

                         const size_t slot_idx) {

   auto fval = rows.getEntryAt<float, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

   return *reinterpret_cast<int32_t*>(may_alias_ptr(&fval));

 }


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 int64_t read_double_func(const ResultSet& rows,

                          const size_t input_buffer_entry_idx,

                          const size_t target_idx,

                          const size_t slot_idx) {

   auto dval = rows.getEntryAt<double, QUERY_TYPE, COLUMNAR_OUTPUT>(

       input_buffer_entry_idx, target_idx, slot_idx);

   return *reinterpret_cast<int64_t*>(may_alias_ptr(&dval));

 }


 }  // namespace


 template <QueryDescriptionType QUERY_TYPE, bool COLUMNAR_OUTPUT>

 std::vector<ColumnarResults::ReadFunction> ColumnarResults::initReadFunctions(

     const ResultSet& rows,

     const std::vector<size_t>& slot_idx_per_target_idx,

     const std::vector<bool>& targets_to_skip) {

   CHECK(isDirectColumnarConversionPossible());

   CHECK(COLUMNAR_OUTPUT == rows.didOutputColumnar());

   CHECK(QUERY_TYPE == rows.getQueryDescriptionType());


   std::vector<ReadFunction> read_functions;

   read_functions.reserve(target_types_.size());


   for (size_t target_idx = 0; target_idx < target_types_.size(); target_idx++) {

     if (!targets_to_skip.empty() && !targets_to_skip[target_idx]) {

       // for targets that should be skipped, we use a placeholder function that should

       // never be called. The CHECKs inside it make sure that never happens.

       read_functions.emplace_back(invalid_read_func);

       continue;

     }


     if (QUERY_TYPE == QueryDescriptionType::GroupByBaselineHash) {

       if (rows.getPaddedSlotWidthBytes(slot_idx_per_target_idx[target_idx]) == 0) {

         // for key columns only

         CHECK(rows.query_mem_desc_.getTargetGroupbyIndex(target_idx) >= 0);

         if (target_types_[target_idx].is_fp()) {

           CHECK_EQ(size_t(8), rows.query_mem_desc_.getEffectiveKeyWidth());

           switch (target_types_[target_idx].get_type()) {

             case kFLOAT:

               read_functions.emplace_back(

                   read_float_key_baseline<QUERY_TYPE, COLUMNAR_OUTPUT>);

               break;

             case kDOUBLE:

               read_functions.emplace_back(read_double_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

               break;

             default:

               UNREACHABLE()

                   << "Invalid data type encountered (BaselineHash, floating point key).";

               break;

           }

         } else {

           switch (rows.query_mem_desc_.getEffectiveKeyWidth()) {

             case 8:

               read_functions.emplace_back(read_int64_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

               break;

             case 4:

               read_functions.emplace_back(read_int32_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

               break;

             default:

               UNREACHABLE()

                   << "Invalid data type encountered (BaselineHash, integer key).";

           }

         }

         continue;

       }

     }

     if (target_types_[target_idx].is_fp()) {

       switch (rows.getPaddedSlotWidthBytes(slot_idx_per_target_idx[target_idx])) {

         case 8:

           read_functions.emplace_back(read_double_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         case 4:

           read_functions.emplace_back(read_float_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         default:

           UNREACHABLE() << "Invalid data type encountered (floating point agg column).";

           break;

       }

     } else {

       switch (rows.getPaddedSlotWidthBytes(slot_idx_per_target_idx[target_idx])) {

         case 8:

           read_functions.emplace_back(read_int64_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         case 4:

           read_functions.emplace_back(read_int32_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         case 2:

           read_functions.emplace_back(read_int16_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         case 1:

           read_functions.emplace_back(read_int8_func<QUERY_TYPE, COLUMNAR_OUTPUT>);

           break;

         default:

           UNREACHABLE() << "Invalid data type encountered (integer agg column).";

           break;

       }

     }

   }

   return read_functions;

 }


 std::tuple<std::vector<ColumnarResults::WriteFunction>,

            std::vector<ColumnarResults::ReadFunction>>

 ColumnarResults::initAllConversionFunctions(

     const ResultSet& rows,

     const std::vector<size_t>& slot_idx_per_target_idx,

     const std::vector<bool>& targets_to_skip) {

   CHECK(isDirectColumnarConversionPossible() &&

         (rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash ||

          rows.getQueryDescriptionType() == QueryDescriptionType::GroupByBaselineHash));


   const auto write_functions = initWriteFunctions(rows, targets_to_skip);

   if (rows.getQueryDescriptionType() == QueryDescriptionType::GroupByPerfectHash) {

     if (rows.didOutputColumnar()) {

       return std::make_tuple(

           std::move(write_functions),

           initReadFunctions<QueryDescriptionType::GroupByPerfectHash, true>(

               rows, slot_idx_per_target_idx, targets_to_skip));

     } else {

       return std::make_tuple(

           std::move(write_functions),

           initReadFunctions<QueryDescriptionType::GroupByPerfectHash, false>(

               rows, slot_idx_per_target_idx, targets_to_skip));

     }

   } else {

     if (rows.didOutputColumnar()) {

       return std::make_tuple(

           std::move(write_functions),

           initReadFunctions<QueryDescriptionType::GroupByBaselineHash, true>(

               rows, slot_idx_per_target_idx, targets_to_skip));

     } else {

       return std::make_tuple(

           std::move(write_functions),

           initReadFunctions<QueryDescriptionType::GroupByBaselineHash, false>(

               rows, slot_idx_per_target_idx, targets_to_skip));

     }

   }

 }

SQLTypeInfoLite::is_geoint
bool is_geoint() const
Definition: sqltypes_lite.h:61

Compression.h

ColumnarResults::isParallelConversion
bool isParallelConversion() const
Definition: ColumnarResults.h:92

SQLTypeInfo::get_subtype
HOST DEVICE SQLTypes get_subtype() const
Definition: sqltypes.h:392

anonymous_namespace{ColumnarResults.cpp}::read_int16_func
int64_t read_int16_func(const ResultSet &rows, const size_t input_buffer_entry_idx, const size_t target_idx, const size_t slot_idx)
Definition: ColumnarResults.cpp:1773

CHECK_EQ
#define CHECK_EQ(x, y)
Definition: Logger.h:301

ColumnarResults::column_buffers_
std::vector< int8_t * > column_buffers_
Definition: ColumnarResults.h:110

kENCODING_NONE
Definition: sqltypes.h:241

FlatBufferManager::Status
Status
Definition: FlatBuffer.h:495

SQLTypeInfo::get_size
HOST DEVICE int get_size() const
Definition: sqltypes.h:403

FlatBufferManager::dtypeSize
HOST DEVICE int64_t dtypeSize() const
Definition: FlatBuffer.h:628

QueryExecutionError::getErrorCode
int32_t getErrorCode() const
Definition: ErrorHandling.h:55

kPOLYGON
Definition: sqltypes.h:86

SQLTypeInfoLite::TEXT
Definition: sqltypes_lite.h:45

writeBackCellGeoPoint
void writeBackCellGeoPoint(FlatBufferManager &m, const size_t row_idx, const SQLTypeInfo &type_info, const TargetValue &col_val, std::mutex *write_mutex)
Definition: ColumnarResults.cpp:792

kENCODING_GEOINT
Definition: sqltypes.h:247

Executor::ERR_INTERRUPTED
static const int32_t ERR_INTERRUPTED
Definition: Execute.h:1621

ColumnarResults::materializeAllColumnsTableFunction
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Definition: ColumnarResults.cpp:1917

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Definition: ColumnarResults.h:27

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Definition: ColumnarResults.h:40

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Definition: ColumnarResults.cpp:1059

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Definition: InlineNullValues.h:115

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Definition: InlineNullValues.h:153

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void compactAndCopyEntriesWithTargetSkipping(const ResultSet &rows, const ColumnBitmap &bitmap, const std::vector< size_t > &non_empty_per_thread, const std::vector< size_t > &global_offsets, const std::vector< bool > &targets_to_skip, const std::vector< size_t > &slot_idx_per_target_idx, const size_t num_columns, const size_t entry_count, const size_t num_threads, const size_t size_per_thread)
Definition: ColumnarResults.cpp:1406

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Definition: ColumnarResults.cpp:1530

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Divide up indexes (A, A+1, A+2, ..., B-2, B-1) among N workers as evenly as possible in a range-based...

ColumnarResults::materializeAllLazyColumns
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