_result_set_iteration_8cpp_source.html

 /*
  * Copyright 2017 MapD Technologies, Inc.
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *     http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "Execute.h"
 #include "Geospatial/Compression.h"
 #include "Geospatial/Types.h"
 #include "ParserNode.h"
 #include "QueryEngine/TargetValue.h"
 #include "ResultSet.h"
 #include "ResultSetGeoSerialization.h"
 #include "RuntimeFunctions.h"
 #include "Shared/SqlTypesLayout.h"
 #include "Shared/likely.h"
 #include "Shared/quantile.h"
 #include "Shared/sqltypes.h"
 #include "TypePunning.h"

 #include <boost/math/special_functions/fpclassify.hpp>

 #include <memory>
 #include <utility>

 namespace {

 // Interprets ptr1, ptr2 as the sum and count pair used for AVG.
 TargetValue make_avg_target_value(const int8_t* ptr1,
                                   const int8_t compact_sz1,
                                   const int8_t* ptr2,
                                   const int8_t compact_sz2,
                                   const TargetInfo& target_info) {
   int64_t sum{0};
   CHECK(target_info.agg_kind == kAVG);
   const bool float_argument_input = takes_float_argument(target_info);
   const auto actual_compact_sz1 = float_argument_input ? sizeof(float) : compact_sz1;
   const auto& agg_ti = target_info.agg_arg_type;
   if (agg_ti.is_integer() || agg_ti.is_decimal()) {
     sum = read_int_from_buff(ptr1, actual_compact_sz1);
   } else if (agg_ti.is_fp()) {
     switch (actual_compact_sz1) {
       case 8: {
         double d = *reinterpret_cast<const double*>(ptr1);
         sum = *reinterpret_cast<const int64_t*>(may_alias_ptr(&d));
         break;
       }
       case 4: {
         double d = *reinterpret_cast<const float*>(ptr1);
         sum = *reinterpret_cast<const int64_t*>(may_alias_ptr(&d));
         break;
       }
       default:
         CHECK(false);
     }
   } else {
     CHECK(false);
   }
   const auto count = read_int_from_buff(ptr2, compact_sz2);
   return pair_to_double({sum, count}, target_info.sql_type, false);
 }

 // Given the entire buffer for the result set, buff, finds the beginning of the
 // column for slot_idx. Only makes sense for column-wise representation.
 const int8_t* advance_col_buff_to_slot(const int8_t* buff,
                                        const QueryMemoryDescriptor& query_mem_desc,
                                        const std::vector<TargetInfo>& targets,
                                        const size_t slot_idx,
                                        const bool separate_varlen_storage) {
   auto crt_col_ptr = get_cols_ptr(buff, query_mem_desc);
   const auto buffer_col_count = query_mem_desc.getBufferColSlotCount();
   size_t agg_col_idx{0};
   for (size_t target_idx = 0; target_idx < targets.size(); ++target_idx) {
     if (agg_col_idx == slot_idx) {
       return crt_col_ptr;
     }
     CHECK_LT(agg_col_idx, buffer_col_count);
     const auto& agg_info = targets[target_idx];
     crt_col_ptr =
         advance_to_next_columnar_target_buff(crt_col_ptr, query_mem_desc, agg_col_idx);
     if (agg_info.is_agg && agg_info.agg_kind == kAVG) {
       if (agg_col_idx + 1 == slot_idx) {
         return crt_col_ptr;
       }
       crt_col_ptr = advance_to_next_columnar_target_buff(
           crt_col_ptr, query_mem_desc, agg_col_idx + 1);
     }
     agg_col_idx = advance_slot(agg_col_idx, agg_info, separate_varlen_storage);
   }
   CHECK(false);
   return nullptr;
 }
 }  // namespace

 // Gets the byte offset, starting from the beginning of the row targets buffer, of
 // the value in position slot_idx (only makes sense for row-wise representation).
 size_t result_set::get_byteoff_of_slot(const size_t slot_idx,
                                        const QueryMemoryDescriptor& query_mem_desc) {
   return query_mem_desc.getPaddedColWidthForRange(0, slot_idx);
 }

 std::vector<TargetValue> ResultSet::getRowAt(
     const size_t global_entry_idx,
     const bool translate_strings,
     const bool decimal_to_double,
     const bool fixup_count_distinct_pointers,
     const std::vector<bool>& targets_to_skip /* = {}*/) const {
   const auto storage_lookup_result =
       fixup_count_distinct_pointers
           ? StorageLookupResult{storage_.get(), global_entry_idx, 0}
           : findStorage(global_entry_idx);
   const auto storage = storage_lookup_result.storage_ptr;
   const auto local_entry_idx = storage_lookup_result.fixedup_entry_idx;
   if (!fixup_count_distinct_pointers && storage->isEmptyEntry(local_entry_idx)) {
     return {};
   }

   const auto buff = storage->buff_;
   CHECK(buff);
   std::vector<TargetValue> row;
   size_t agg_col_idx = 0;
   int8_t* rowwise_target_ptr{nullptr};
   int8_t* keys_ptr{nullptr};
   const int8_t* crt_col_ptr{nullptr};
   if (query_mem_desc_.didOutputColumnar()) {
     keys_ptr = buff;
     crt_col_ptr = get_cols_ptr(buff, storage->query_mem_desc_);
   } else {
     keys_ptr = row_ptr_rowwise(buff, query_mem_desc_, local_entry_idx);
     const auto key_bytes_with_padding =
         align_to_int64(get_key_bytes_rowwise(query_mem_desc_));
     rowwise_target_ptr = keys_ptr + key_bytes_with_padding;
   }
   for (size_t target_idx = 0; target_idx < storage->targets_.size(); ++target_idx) {
     const auto& agg_info = storage->targets_[target_idx];
     if (query_mem_desc_.didOutputColumnar()) {
       if (UNLIKELY(!targets_to_skip.empty())) {
         row.push_back(!targets_to_skip[target_idx]
                           ? getTargetValueFromBufferColwise(crt_col_ptr,
                                                             keys_ptr,
                                                             storage->query_mem_desc_,
                                                             local_entry_idx,
                                                             global_entry_idx,
                                                             agg_info,
                                                             target_idx,
                                                             agg_col_idx,
                                                             translate_strings,
                                                             decimal_to_double)
                           : nullptr);
       } else {
         row.push_back(getTargetValueFromBufferColwise(crt_col_ptr,
                                                       keys_ptr,
                                                       storage->query_mem_desc_,
                                                       local_entry_idx,
                                                       global_entry_idx,
                                                       agg_info,
                                                       target_idx,
                                                       agg_col_idx,
                                                       translate_strings,
                                                       decimal_to_double));
       }
       crt_col_ptr = advance_target_ptr_col_wise(crt_col_ptr,
                                                 agg_info,
                                                 agg_col_idx,
                                                 storage->query_mem_desc_,
                                                 separate_varlen_storage_valid_);
     } else {
       if (UNLIKELY(!targets_to_skip.empty())) {
         row.push_back(!targets_to_skip[target_idx]
                           ? getTargetValueFromBufferRowwise(rowwise_target_ptr,
                                                             keys_ptr,
                                                             global_entry_idx,
                                                             agg_info,
                                                             target_idx,
                                                             agg_col_idx,
                                                             translate_strings,
                                                             decimal_to_double,
                                                             fixup_count_distinct_pointers)
                           : nullptr);
       } else {
         row.push_back(getTargetValueFromBufferRowwise(rowwise_target_ptr,
                                                       keys_ptr,
                                                       global_entry_idx,
                                                       agg_info,
                                                       target_idx,
                                                       agg_col_idx,
                                                       translate_strings,
                                                       decimal_to_double,
                                                       fixup_count_distinct_pointers));
       }
       rowwise_target_ptr = advance_target_ptr_row_wise(rowwise_target_ptr,
                                                        agg_info,
                                                        agg_col_idx,
                                                        query_mem_desc_,
                                                        separate_varlen_storage_valid_);
     }
     agg_col_idx = advance_slot(agg_col_idx, agg_info, separate_varlen_storage_valid_);
   }

   return row;
 }

 TargetValue ResultSet::getRowAt(const size_t row_idx,
                                 const size_t col_idx,
                                 const bool translate_strings,
                                 const bool decimal_to_double /* = true */) const {
   std::lock_guard<std::mutex> lock(row_iteration_mutex_);
   moveToBegin();
   for (size_t i = 0; i < row_idx; ++i) {
     auto crt_row = getNextRowUnlocked(translate_strings, decimal_to_double);
     CHECK(!crt_row.empty());
   }
   auto crt_row = getNextRowUnlocked(translate_strings, decimal_to_double);
   CHECK(!crt_row.empty());
   return crt_row[col_idx];
 }

 OneIntegerColumnRow ResultSet::getOneColRow(const size_t global_entry_idx) const {
   const auto storage_lookup_result = findStorage(global_entry_idx);
   const auto storage = storage_lookup_result.storage_ptr;
   const auto local_entry_idx = storage_lookup_result.fixedup_entry_idx;
   if (storage->isEmptyEntry(local_entry_idx)) {
     return {0, false};
   }
   const auto buff = storage->buff_;
   CHECK(buff);
   CHECK(!query_mem_desc_.didOutputColumnar());
   const auto keys_ptr = row_ptr_rowwise(buff, query_mem_desc_, local_entry_idx);
   const auto key_bytes_with_padding =
       align_to_int64(get_key_bytes_rowwise(query_mem_desc_));
   const auto rowwise_target_ptr = keys_ptr + key_bytes_with_padding;
   const auto tv = getTargetValueFromBufferRowwise(rowwise_target_ptr,
                                                   keys_ptr,
                                                   global_entry_idx,
                                                   targets_.front(),
                                                   0,
                                                   0,
                                                   false,
                                                   false,
                                                   false);
   const auto scalar_tv = boost::get<ScalarTargetValue>(&tv);
   CHECK(scalar_tv);
   const auto ival_ptr = boost::get<int64_t>(scalar_tv);
   CHECK(ival_ptr);
   return {*ival_ptr, true};
 }

 std::vector<TargetValue> ResultSet::getRowAt(const size_t logical_index) const {
   if (logical_index >= entryCount()) {
     return {};
   }
   const auto entry_idx =
       permutation_.empty() ? logical_index : permutation_[logical_index];
   return getRowAt(entry_idx, true, false, false);
 }

 std::vector<TargetValue> ResultSet::getRowAtNoTranslations(
     const size_t logical_index,
     const std::vector<bool>& targets_to_skip /* = {}*/) const {
   if (logical_index >= entryCount()) {
     return {};
   }
   const auto entry_idx =
       permutation_.empty() ? logical_index : permutation_[logical_index];
   return getRowAt(entry_idx, false, false, false, targets_to_skip);
 }

 bool ResultSet::isRowAtEmpty(const size_t logical_index) const {
   if (logical_index >= entryCount()) {
     return true;
   }
   const auto entry_idx =
       permutation_.empty() ? logical_index : permutation_[logical_index];
   const auto storage_lookup_result = findStorage(entry_idx);
   const auto storage = storage_lookup_result.storage_ptr;
   const auto local_entry_idx = storage_lookup_result.fixedup_entry_idx;
   return storage->isEmptyEntry(local_entry_idx);
 }

 std::vector<TargetValue> ResultSet::getNextRow(const bool translate_strings,
                                                const bool decimal_to_double) const {
   std::lock_guard<std::mutex> lock(row_iteration_mutex_);
   if (!storage_ && !just_explain_) {
     return {};
   }
   return getNextRowUnlocked(translate_strings, decimal_to_double);
 }

 std::vector<TargetValue> ResultSet::getNextRowUnlocked(
     const bool translate_strings,
     const bool decimal_to_double) const {
   if (just_explain_) {
     if (fetched_so_far_) {
       return {};
     }
     fetched_so_far_ = 1;
     return {explanation_};
   }
   return getNextRowImpl(translate_strings, decimal_to_double);
 }

 std::vector<TargetValue> ResultSet::getNextRowImpl(const bool translate_strings,
                                                    const bool decimal_to_double) const {
   size_t entry_buff_idx = 0;
   do {
     if (keep_first_ && fetched_so_far_ >= drop_first_ + keep_first_) {
       return {};
     }

     entry_buff_idx = advanceCursorToNextEntry();

     if (crt_row_buff_idx_ >= entryCount()) {
       CHECK_EQ(entryCount(), crt_row_buff_idx_);
       return {};
     }
     ++crt_row_buff_idx_;
     ++fetched_so_far_;

   } while (drop_first_ && fetched_so_far_ <= drop_first_);

   auto row = getRowAt(entry_buff_idx, translate_strings, decimal_to_double, false);
   CHECK(!row.empty());

   return row;
 }

 namespace {

 const int8_t* columnar_elem_ptr(const size_t entry_idx,
                                 const int8_t* col1_ptr,
                                 const int8_t compact_sz1) {
   return col1_ptr + compact_sz1 * entry_idx;
 }

 int64_t int_resize_cast(const int64_t ival, const size_t sz) {
   switch (sz) {
     case 8:
       return ival;
     case 4:
       return static_cast<int32_t>(ival);
     case 2:
       return static_cast<int16_t>(ival);
     case 1:
       return static_cast<int8_t>(ival);
     default:
       UNREACHABLE();
   }
   UNREACHABLE();
   return 0;
 }

 }  // namespace

 void ResultSet::RowWiseTargetAccessor::initializeOffsetsForStorage() {
   // Compute offsets for base storage and all appended storage
   for (size_t storage_idx = 0; storage_idx < result_set_->appended_storage_.size() + 1;
        ++storage_idx) {
     offsets_for_storage_.emplace_back();

     const int8_t* rowwise_target_ptr{0};

     size_t agg_col_idx = 0;
     for (size_t target_idx = 0; target_idx < result_set_->storage_->targets_.size();
          ++target_idx) {
       const auto& agg_info = result_set_->storage_->targets_[target_idx];

       auto ptr1 = rowwise_target_ptr;
       const auto compact_sz1 =
           result_set_->query_mem_desc_.getPaddedSlotWidthBytes(agg_col_idx)
               ? result_set_->query_mem_desc_.getPaddedSlotWidthBytes(agg_col_idx)
               : key_width_;

       const int8_t* ptr2{nullptr};
       int8_t compact_sz2{0};
       if ((agg_info.is_agg && agg_info.agg_kind == kAVG)) {
         ptr2 = ptr1 + compact_sz1;
         compact_sz2 =
             result_set_->query_mem_desc_.getPaddedSlotWidthBytes(agg_col_idx + 1);
       } else if (is_real_str_or_array(agg_info)) {
         ptr2 = ptr1 + compact_sz1;
         if (!result_set_->separate_varlen_storage_valid_) {
           // None encoded strings explicitly attached to ResultSetStorage do not have a
           // second slot in the QueryMemoryDescriptor col width vector
           compact_sz2 =
               result_set_->query_mem_desc_.getPaddedSlotWidthBytes(agg_col_idx + 1);
         }
       }
       offsets_for_storage_[storage_idx].push_back(
           TargetOffsets{ptr1,
                         static_cast<size_t>(compact_sz1),
                         ptr2,
                         static_cast<size_t>(compact_sz2)});
       rowwise_target_ptr =
           advance_target_ptr_row_wise(rowwise_target_ptr,
                                       agg_info,
                                       agg_col_idx,
                                       result_set_->query_mem_desc_,
                                       result_set_->separate_varlen_storage_valid_);

       agg_col_idx = advance_slot(
           agg_col_idx, agg_info, result_set_->separate_varlen_storage_valid_);
     }
     CHECK_EQ(offsets_for_storage_[storage_idx].size(),
              result_set_->storage_->targets_.size());
   }
 }

 InternalTargetValue ResultSet::RowWiseTargetAccessor::getColumnInternal(
     const int8_t* buff,
     const size_t entry_idx,
     const size_t target_logical_idx,
     const StorageLookupResult& storage_lookup_result) const {
   CHECK(buff);
   const int8_t* rowwise_target_ptr{nullptr};
   const int8_t* keys_ptr{nullptr};

   const size_t storage_idx = storage_lookup_result.storage_idx;

   CHECK_LT(storage_idx, offsets_for_storage_.size());
   CHECK_LT(target_logical_idx, offsets_for_storage_[storage_idx].size());

   const auto& offsets_for_target = offsets_for_storage_[storage_idx][target_logical_idx];
   const auto& agg_info = result_set_->storage_->targets_[target_logical_idx];
   const auto& type_info = agg_info.sql_type;

   keys_ptr = get_rowwise_ptr(buff, entry_idx);
   rowwise_target_ptr = keys_ptr + key_bytes_with_padding_;
   auto ptr1 = rowwise_target_ptr + reinterpret_cast<size_t>(offsets_for_target.ptr1);
   if (result_set_->query_mem_desc_.targetGroupbyIndicesSize() > 0) {
     if (result_set_->query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) >= 0) {
       ptr1 = keys_ptr +
              result_set_->query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) *
                  key_width_;
     }
   }
   const auto i1 =
       result_set_->lazyReadInt(read_int_from_buff(ptr1, offsets_for_target.compact_sz1),
                                target_logical_idx,
                                storage_lookup_result);
   if (agg_info.is_agg && agg_info.agg_kind == kAVG) {
     CHECK(offsets_for_target.ptr2);
     const auto ptr2 =
         rowwise_target_ptr + reinterpret_cast<size_t>(offsets_for_target.ptr2);
     const auto i2 = read_int_from_buff(ptr2, offsets_for_target.compact_sz2);
     return InternalTargetValue(i1, i2);
   } else {
     if (type_info.is_string() && type_info.get_compression() == kENCODING_NONE) {
       CHECK(!agg_info.is_agg);
       if (!result_set_->lazy_fetch_info_.empty()) {
         CHECK_LT(target_logical_idx, result_set_->lazy_fetch_info_.size());
         const auto& col_lazy_fetch = result_set_->lazy_fetch_info_[target_logical_idx];
         if (col_lazy_fetch.is_lazily_fetched) {
           return InternalTargetValue(reinterpret_cast<const std::string*>(i1));
         }
       }
       if (result_set_->separate_varlen_storage_valid_) {
         if (i1 < 0) {
           CHECK_EQ(-1, i1);
           return InternalTargetValue(static_cast<const std::string*>(nullptr));
         }
         CHECK_LT(storage_lookup_result.storage_idx,
                  result_set_->serialized_varlen_buffer_.size());
         const auto& varlen_buffer_for_fragment =
             result_set_->serialized_varlen_buffer_[storage_lookup_result.storage_idx];
         CHECK_LT(static_cast<size_t>(i1), varlen_buffer_for_fragment.size());
         return InternalTargetValue(&varlen_buffer_for_fragment[i1]);
       }
       CHECK(offsets_for_target.ptr2);
       const auto ptr2 =
           rowwise_target_ptr + reinterpret_cast<size_t>(offsets_for_target.ptr2);
       const auto str_len = read_int_from_buff(ptr2, offsets_for_target.compact_sz2);
       CHECK_GE(str_len, 0);
       return result_set_->getVarlenOrderEntry(i1, str_len);
     }
     return InternalTargetValue(
         type_info.is_fp() ? i1 : int_resize_cast(i1, type_info.get_logical_size()));
   }
 }

 void ResultSet::ColumnWiseTargetAccessor::initializeOffsetsForStorage() {
   // Compute offsets for base storage and all appended storage
   const auto key_width = result_set_->query_mem_desc_.getEffectiveKeyWidth();
   for (size_t storage_idx = 0; storage_idx < result_set_->appended_storage_.size() + 1;
        ++storage_idx) {
     offsets_for_storage_.emplace_back();

     const int8_t* buff = storage_idx == 0
                              ? result_set_->storage_->buff_
                              : result_set_->appended_storage_[storage_idx - 1]->buff_;
     CHECK(buff);

     const auto& crt_query_mem_desc =
         storage_idx == 0
             ? result_set_->storage_->query_mem_desc_
             : result_set_->appended_storage_[storage_idx - 1]->query_mem_desc_;
     const int8_t* crt_col_ptr = get_cols_ptr(buff, crt_query_mem_desc);

     size_t agg_col_idx = 0;
     for (size_t target_idx = 0; target_idx < result_set_->storage_->targets_.size();
          ++target_idx) {
       const auto& agg_info = result_set_->storage_->targets_[target_idx];

       const auto compact_sz1 =
           crt_query_mem_desc.getPaddedSlotWidthBytes(agg_col_idx)
               ? crt_query_mem_desc.getPaddedSlotWidthBytes(agg_col_idx)
               : key_width;

       const auto next_col_ptr = advance_to_next_columnar_target_buff(
           crt_col_ptr, crt_query_mem_desc, agg_col_idx);
       const bool uses_two_slots = (agg_info.is_agg && agg_info.agg_kind == kAVG) ||
                                   is_real_str_or_array(agg_info);
       const auto col2_ptr = uses_two_slots ? next_col_ptr : nullptr;
       const auto compact_sz2 =
           (agg_info.is_agg && agg_info.agg_kind == kAVG) || is_real_str_or_array(agg_info)
               ? crt_query_mem_desc.getPaddedSlotWidthBytes(agg_col_idx + 1)
               : 0;

       offsets_for_storage_[storage_idx].push_back(
           TargetOffsets{crt_col_ptr,
                         static_cast<size_t>(compact_sz1),
                         col2_ptr,
                         static_cast<size_t>(compact_sz2)});

       crt_col_ptr = next_col_ptr;
       if (uses_two_slots) {
         crt_col_ptr = advance_to_next_columnar_target_buff(
             crt_col_ptr, crt_query_mem_desc, agg_col_idx + 1);
       }
       agg_col_idx = advance_slot(
           agg_col_idx, agg_info, result_set_->separate_varlen_storage_valid_);
     }
     CHECK_EQ(offsets_for_storage_[storage_idx].size(),
              result_set_->storage_->targets_.size());
   }
 }

 InternalTargetValue ResultSet::ColumnWiseTargetAccessor::getColumnInternal(
     const int8_t* buff,
     const size_t entry_idx,
     const size_t target_logical_idx,
     const StorageLookupResult& storage_lookup_result) const {
   const size_t storage_idx = storage_lookup_result.storage_idx;

   CHECK_LT(storage_idx, offsets_for_storage_.size());
   CHECK_LT(target_logical_idx, offsets_for_storage_[storage_idx].size());

   const auto& offsets_for_target = offsets_for_storage_[storage_idx][target_logical_idx];
   const auto& agg_info = result_set_->storage_->targets_[target_logical_idx];
   const auto& type_info = agg_info.sql_type;
   auto ptr1 = offsets_for_target.ptr1;
   if (result_set_->query_mem_desc_.targetGroupbyIndicesSize() > 0) {
     if (result_set_->query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) >= 0) {
       ptr1 =
           buff + result_set_->query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) *
                      result_set_->query_mem_desc_.getEffectiveKeyWidth() *
                      result_set_->query_mem_desc_.entry_count_;
     }
   }

   const auto i1 = result_set_->lazyReadInt(
       read_int_from_buff(
           columnar_elem_ptr(entry_idx, ptr1, offsets_for_target.compact_sz1),
           offsets_for_target.compact_sz1),
       target_logical_idx,
       storage_lookup_result);
   if (agg_info.is_agg && agg_info.agg_kind == kAVG) {
     CHECK(offsets_for_target.ptr2);
     const auto i2 = read_int_from_buff(
         columnar_elem_ptr(
             entry_idx, offsets_for_target.ptr2, offsets_for_target.compact_sz2),
         offsets_for_target.compact_sz2);
     return InternalTargetValue(i1, i2);
   } else {
     // for TEXT ENCODING NONE:
     if (type_info.is_string() && type_info.get_compression() == kENCODING_NONE) {
       CHECK(!agg_info.is_agg);
       if (!result_set_->lazy_fetch_info_.empty()) {
         CHECK_LT(target_logical_idx, result_set_->lazy_fetch_info_.size());
         const auto& col_lazy_fetch = result_set_->lazy_fetch_info_[target_logical_idx];
         if (col_lazy_fetch.is_lazily_fetched) {
           return InternalTargetValue(reinterpret_cast<const std::string*>(i1));
         }
       }
       if (result_set_->separate_varlen_storage_valid_) {
         if (i1 < 0) {
           CHECK_EQ(-1, i1);
           return InternalTargetValue(static_cast<const std::string*>(nullptr));
         }
         CHECK_LT(storage_lookup_result.storage_idx,
                  result_set_->serialized_varlen_buffer_.size());
         const auto& varlen_buffer_for_fragment =
             result_set_->serialized_varlen_buffer_[storage_lookup_result.storage_idx];
         CHECK_LT(static_cast<size_t>(i1), varlen_buffer_for_fragment.size());
         return InternalTargetValue(&varlen_buffer_for_fragment[i1]);
       }
       CHECK(offsets_for_target.ptr2);
       const auto i2 = read_int_from_buff(
           columnar_elem_ptr(
               entry_idx, offsets_for_target.ptr2, offsets_for_target.compact_sz2),
           offsets_for_target.compact_sz2);
       CHECK_GE(i2, 0);
       return result_set_->getVarlenOrderEntry(i1, i2);
     }
     return InternalTargetValue(
         type_info.is_fp() ? i1 : int_resize_cast(i1, type_info.get_logical_size()));
   }
 }

 InternalTargetValue ResultSet::getVarlenOrderEntry(const int64_t str_ptr,
                                                    const size_t str_len) const {
   char* host_str_ptr{nullptr};
   std::vector<int8_t> cpu_buffer;
   if (device_type_ == ExecutorDeviceType::GPU) {
     cpu_buffer.resize(str_len);
     const auto executor = query_mem_desc_.getExecutor();
     CHECK(executor);
     auto& data_mgr = executor->catalog_->getDataMgr();
     copy_from_gpu(&data_mgr,
                   &cpu_buffer[0],
                   static_cast<CUdeviceptr>(str_ptr),
                   str_len,
                   device_id_);
     host_str_ptr = reinterpret_cast<char*>(&cpu_buffer[0]);
   } else {
     CHECK(device_type_ == ExecutorDeviceType::CPU);
     host_str_ptr = reinterpret_cast<char*>(str_ptr);
   }
   std::string str(host_str_ptr, str_len);
   return InternalTargetValue(row_set_mem_owner_->addString(str));
 }

 int64_t ResultSet::lazyReadInt(const int64_t ival,
                                const size_t target_logical_idx,
                                const StorageLookupResult& storage_lookup_result) const {
   if (!lazy_fetch_info_.empty()) {
     CHECK_LT(target_logical_idx, lazy_fetch_info_.size());
     const auto& col_lazy_fetch = lazy_fetch_info_[target_logical_idx];
     if (col_lazy_fetch.is_lazily_fetched) {
       CHECK_LT(static_cast<size_t>(storage_lookup_result.storage_idx),
                col_buffers_.size());
       int64_t ival_copy = ival;
       auto& frag_col_buffers =
           getColumnFrag(static_cast<size_t>(storage_lookup_result.storage_idx),
                         target_logical_idx,
                         ival_copy);
       auto& frag_col_buffer = frag_col_buffers[col_lazy_fetch.local_col_id];
       CHECK_LT(target_logical_idx, targets_.size());
       const TargetInfo& target_info = targets_[target_logical_idx];
       CHECK(!target_info.is_agg);
       if (target_info.sql_type.is_string() &&
           target_info.sql_type.get_compression() == kENCODING_NONE) {
         VarlenDatum vd;
         bool is_end{false};
         ChunkIter_get_nth(
             reinterpret_cast<ChunkIter*>(const_cast<int8_t*>(frag_col_buffer)),
             storage_lookup_result.fixedup_entry_idx,
             false,
             &vd,
             &is_end);
         CHECK(!is_end);
         if (vd.is_null) {
           return 0;
         }
         std::string fetched_str(reinterpret_cast<char*>(vd.pointer), vd.length);
         return reinterpret_cast<int64_t>(row_set_mem_owner_->addString(fetched_str));
       }
       return result_set::lazy_decode(col_lazy_fetch, frag_col_buffer, ival_copy);
     }
   }
   return ival;
 }

 // Not all entries in the buffer represent a valid row. Advance the internal cursor
 // used for the getNextRow method to the next row which is valid.
 void ResultSet::advanceCursorToNextEntry(ResultSetRowIterator& iter) const {
   if (keep_first_ && iter.fetched_so_far_ >= drop_first_ + keep_first_) {
     iter.global_entry_idx_valid_ = false;
     return;
   }

   while (iter.crt_row_buff_idx_ < entryCount()) {
     const auto entry_idx = permutation_.empty() ? iter.crt_row_buff_idx_
                                                 : permutation_[iter.crt_row_buff_idx_];
     const auto storage_lookup_result = findStorage(entry_idx);
     const auto storage = storage_lookup_result.storage_ptr;
     const auto fixedup_entry_idx = storage_lookup_result.fixedup_entry_idx;
     if (!storage->isEmptyEntry(fixedup_entry_idx)) {
       if (iter.fetched_so_far_ < drop_first_) {
         ++iter.fetched_so_far_;
       } else {
         break;
       }
     }
     ++iter.crt_row_buff_idx_;
   }
   if (permutation_.empty()) {
     iter.global_entry_idx_ = iter.crt_row_buff_idx_;
   } else {
     CHECK_LE(iter.crt_row_buff_idx_, permutation_.size());
     iter.global_entry_idx_ = iter.crt_row_buff_idx_ == permutation_.size()
                                  ? iter.crt_row_buff_idx_
                                  : permutation_[iter.crt_row_buff_idx_];
   }

   iter.global_entry_idx_valid_ = iter.crt_row_buff_idx_ < entryCount();

   if (iter.global_entry_idx_valid_) {
     ++iter.crt_row_buff_idx_;
     ++iter.fetched_so_far_;
   }
 }

 // Not all entries in the buffer represent a valid row. Advance the internal cursor
 // used for the getNextRow method to the next row which is valid.
 size_t ResultSet::advanceCursorToNextEntry() const {
   while (crt_row_buff_idx_ < entryCount()) {
     const auto entry_idx =
         permutation_.empty() ? crt_row_buff_idx_ : permutation_[crt_row_buff_idx_];
     const auto storage_lookup_result = findStorage(entry_idx);
     const auto storage = storage_lookup_result.storage_ptr;
     const auto fixedup_entry_idx = storage_lookup_result.fixedup_entry_idx;
     if (!storage->isEmptyEntry(fixedup_entry_idx)) {
       break;
     }
     ++crt_row_buff_idx_;
   }
   if (permutation_.empty()) {
     return crt_row_buff_idx_;
   }
   CHECK_LE(crt_row_buff_idx_, permutation_.size());
   return crt_row_buff_idx_ == permutation_.size() ? crt_row_buff_idx_
                                                   : permutation_[crt_row_buff_idx_];
 }

 size_t ResultSet::entryCount() const {
   return permutation_.empty() ? query_mem_desc_.getEntryCount() : permutation_.size();
 }

 size_t ResultSet::getBufferSizeBytes(const ExecutorDeviceType device_type) const {
   CHECK(storage_);
   return storage_->query_mem_desc_.getBufferSizeBytes(device_type);
 }

 namespace {

 template <class T>
 ScalarTargetValue make_scalar_tv(const T val) {
   return ScalarTargetValue(static_cast<int64_t>(val));
 }

 template <>
 ScalarTargetValue make_scalar_tv(const float val) {
   return ScalarTargetValue(val);
 }

 template <>
 ScalarTargetValue make_scalar_tv(const double val) {
   return ScalarTargetValue(val);
 }

 template <class T>
 TargetValue build_array_target_value(
     const int8_t* buff,
     const size_t buff_sz,
     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner) {
   std::vector<ScalarTargetValue> values;
   auto buff_elems = reinterpret_cast<const T*>(buff);
   CHECK_EQ(size_t(0), buff_sz % sizeof(T));
   const size_t num_elems = buff_sz / sizeof(T);
   for (size_t i = 0; i < num_elems; ++i) {
     values.push_back(make_scalar_tv<T>(buff_elems[i]));
   }
   return ArrayTargetValue(values);
 }

 TargetValue build_string_array_target_value(
     const int32_t* buff,
     const size_t buff_sz,
     const int dict_id,
     const bool translate_strings,
     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
     const Catalog_Namespace::Catalog* catalog) {
   std::vector<ScalarTargetValue> values;
   CHECK_EQ(size_t(0), buff_sz % sizeof(int32_t));
   const size_t num_elems = buff_sz / sizeof(int32_t);
   if (translate_strings) {
     for (size_t i = 0; i < num_elems; ++i) {
       const auto string_id = buff[i];

       if (string_id == NULL_INT) {
         values.emplace_back(NullableString(nullptr));
       } else {
         if (dict_id == 0) {
           StringDictionaryProxy* sdp = row_set_mem_owner->getLiteralStringDictProxy();
           values.emplace_back(sdp->getString(string_id));
         } else {
           values.emplace_back(NullableString(
               row_set_mem_owner
                   ->getOrAddStringDictProxy(dict_id, /*with_generation=*/false, catalog)
                   ->getString(string_id)));
         }
       }
     }
   } else {
     for (size_t i = 0; i < num_elems; i++) {
       values.emplace_back(static_cast<int64_t>(buff[i]));
     }
   }
   return ArrayTargetValue(values);
 }

 TargetValue build_array_target_value(const SQLTypeInfo& array_ti,
                                      const int8_t* buff,
                                      const size_t buff_sz,
                                      const bool translate_strings,
                                      std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,
                                      const Catalog_Namespace::Catalog* catalog) {
   CHECK(array_ti.is_array());
   const auto& elem_ti = array_ti.get_elem_type();
   if (elem_ti.is_string()) {
     return build_string_array_target_value(reinterpret_cast<const int32_t*>(buff),
                                            buff_sz,
                                            elem_ti.get_comp_param(),
                                            translate_strings,
                                            row_set_mem_owner,
                                            catalog);
   }
   switch (elem_ti.get_size()) {
     case 1:
       return build_array_target_value<int8_t>(buff, buff_sz, row_set_mem_owner);
     case 2:
       return build_array_target_value<int16_t>(buff, buff_sz, row_set_mem_owner);
     case 4:
       if (elem_ti.is_fp()) {
         return build_array_target_value<float>(buff, buff_sz, row_set_mem_owner);
       } else {
         return build_array_target_value<int32_t>(buff, buff_sz, row_set_mem_owner);
       }
     case 8:
       if (elem_ti.is_fp()) {
         return build_array_target_value<double>(buff, buff_sz, row_set_mem_owner);
       } else {
         return build_array_target_value<int64_t>(buff, buff_sz, row_set_mem_owner);
       }
     default:
       CHECK(false);
   }
   CHECK(false);
   return TargetValue(nullptr);
 }

 template <class Tuple, size_t... indices>
 inline std::vector<std::pair<const int8_t*, const int64_t>> make_vals_vector(
     std::index_sequence<indices...>,
     const Tuple& tuple) {
   return std::vector<std::pair<const int8_t*, const int64_t>>{
       std::make_pair(std::get<2 * indices>(tuple), std::get<2 * indices + 1>(tuple))...};
 }

 inline std::unique_ptr<ArrayDatum> lazy_fetch_chunk(const int8_t* ptr,
                                                     const int64_t varlen_ptr) {
   auto ad = std::make_unique<ArrayDatum>();
   bool is_end;
   ChunkIter_get_nth(reinterpret_cast<ChunkIter*>(const_cast<int8_t*>(ptr)),
                     varlen_ptr,
                     ad.get(),
                     &is_end);
   CHECK(!is_end);
   return ad;
 }

 struct GeoLazyFetchHandler {
   template <typename... T>
   static inline auto fetch(const SQLTypeInfo& geo_ti,
                            const ResultSet::GeoReturnType return_type,
                            T&&... vals) {
     constexpr int num_vals = sizeof...(vals);
     static_assert(
         num_vals % 2 == 0,
         "Must have consistent pointer/size pairs for lazy fetch of geo target values.");
     const auto vals_vector = make_vals_vector(std::make_index_sequence<num_vals / 2>{},
                                               std::make_tuple(vals...));
     std::array<VarlenDatumPtr, num_vals / 2> ad_arr;
     size_t ctr = 0;
     for (const auto& col_pair : vals_vector) {
       ad_arr[ctr] = lazy_fetch_chunk(col_pair.first, col_pair.second);
       // Regular chunk iterator used to fetch this datum sets the right nullness.
       // That includes the fixlen bounds array.
       // However it may incorrectly set it for the POINT coord array datum
       // if 1st byte happened to hold NULL_ARRAY_TINYINT. One should either use
       // the specialized iterator for POINT coords or rely on regular iterator +
       // reset + recheck, which is what is done below.
       auto is_point = (geo_ti.get_type() == kPOINT && ctr == 0);
       if (is_point) {
         // Resetting POINT coords array nullness here
         ad_arr[ctr]->is_null = false;
       }
       if (!geo_ti.get_notnull()) {
         // Recheck and set nullness
         if (ad_arr[ctr]->length == 0 || ad_arr[ctr]->pointer == NULL ||
             (is_point &&
              is_null_point(geo_ti, ad_arr[ctr]->pointer, ad_arr[ctr]->length))) {
           ad_arr[ctr]->is_null = true;
         }
       }
       ctr++;
     }
     return ad_arr;
   }
 };

 inline std::unique_ptr<ArrayDatum> fetch_data_from_gpu(int64_t varlen_ptr,
                                                        const int64_t length,
                                                        Data_Namespace::DataMgr* data_mgr,
                                                        const int device_id) {
   auto cpu_buf = std::shared_ptr<int8_t>(new int8_t[length], FreeDeleter());
   copy_from_gpu(
       data_mgr, cpu_buf.get(), static_cast<CUdeviceptr>(varlen_ptr), length, device_id);
   // Just fetching the data from gpu, not checking geo nullness
   return std::make_unique<ArrayDatum>(length, cpu_buf, false);
 }

 struct GeoQueryOutputFetchHandler {
   static inline auto yieldGpuPtrFetcher() {
     return [](const int64_t ptr, const int64_t length) -> VarlenDatumPtr {
       // Just fetching the data from gpu, not checking geo nullness
       return std::make_unique<VarlenDatum>(length, reinterpret_cast<int8_t*>(ptr), false);
     };
   }

   static inline auto yieldGpuDatumFetcher(Data_Namespace::DataMgr* data_mgr_ptr,
                                           const int device_id) {
     return [data_mgr_ptr, device_id](const int64_t ptr,
                                      const int64_t length) -> VarlenDatumPtr {
       return fetch_data_from_gpu(ptr, length, data_mgr_ptr, device_id);
     };
   }

   static inline auto yieldCpuDatumFetcher() {
     return [](const int64_t ptr, const int64_t length) -> VarlenDatumPtr {
       // Just fetching the data from gpu, not checking geo nullness
       return std::make_unique<VarlenDatum>(length, reinterpret_cast<int8_t*>(ptr), false);
     };
   }

   template <typename... T>
   static inline auto fetch(const SQLTypeInfo& geo_ti,
                            const ResultSet::GeoReturnType return_type,
                            Data_Namespace::DataMgr* data_mgr,
                            const bool fetch_data_from_gpu,
                            const int device_id,
                            T&&... vals) {
     auto ad_arr_generator = [&](auto datum_fetcher) {
       constexpr int num_vals = sizeof...(vals);
       static_assert(
           num_vals % 2 == 0,
           "Must have consistent pointer/size pairs for lazy fetch of geo target values.");
       const auto vals_vector = std::vector<int64_t>{vals...};

       std::array<VarlenDatumPtr, num_vals / 2> ad_arr;
       size_t ctr = 0;
       for (size_t i = 0; i < vals_vector.size(); i += 2) {
         ad_arr[ctr] = datum_fetcher(vals_vector[i], vals_vector[i + 1]);
         // All fetched datums come in with is_null set to false
         if (!geo_ti.get_notnull()) {
           bool is_null = false;
           // Now need to set the nullness
           if (ad_arr[ctr]->length == 0 || ad_arr[ctr]->pointer == NULL) {
             is_null = true;
           } else if (geo_ti.get_type() == kPOINT && ctr == 0 &&
                      is_null_point(geo_ti, ad_arr[ctr]->pointer, ad_arr[ctr]->length)) {
             is_null = true;  // recognizes compressed and uncompressed points
           } else if (ad_arr[ctr]->length == 4 * sizeof(double)) {
             // Bounds
             auto dti = SQLTypeInfo(kARRAY, 0, 0, false, kENCODING_NONE, 0, kDOUBLE);
             is_null = dti.is_null_fixlen_array(ad_arr[ctr]->pointer, ad_arr[ctr]->length);
           }
           ad_arr[ctr]->is_null = is_null;
         }
         ctr++;
       }
       return ad_arr;
     };

     if (fetch_data_from_gpu) {
       if (return_type == ResultSet::GeoReturnType::GeoTargetValueGpuPtr) {
         return ad_arr_generator(yieldGpuPtrFetcher());
       } else {
         return ad_arr_generator(yieldGpuDatumFetcher(data_mgr, device_id));
       }
     } else {
       return ad_arr_generator(yieldCpuDatumFetcher());
     }
   }
 };

 template <SQLTypes GEO_SOURCE_TYPE, typename GeoTargetFetcher>
 struct GeoTargetValueBuilder {
   template <typename... T>
   static inline TargetValue build(const SQLTypeInfo& geo_ti,
                                   const ResultSet::GeoReturnType return_type,
                                   T&&... vals) {
     auto ad_arr = GeoTargetFetcher::fetch(geo_ti, return_type, std::forward<T>(vals)...);
     static_assert(std::tuple_size<decltype(ad_arr)>::value > 0,
                   "ArrayDatum array for Geo Target must contain at least one value.");

     // Fetcher sets the geo nullness based on geo typeinfo's notnull, type and
     // compression. Serializers will generate appropriate NULL geo where necessary.
     switch (return_type) {
       case ResultSet::GeoReturnType::GeoTargetValue: {
         if (!geo_ti.get_notnull() && ad_arr[0]->is_null) {
           return GeoTargetValue();
         }
         return GeoReturnTypeTraits<ResultSet::GeoReturnType::GeoTargetValue,
                                    GEO_SOURCE_TYPE>::GeoSerializerType::serialize(geo_ti,
                                                                                   ad_arr);
       }
       case ResultSet::GeoReturnType::WktString: {
         if (!geo_ti.get_notnull() && ad_arr[0]->is_null) {
           // Generating NULL wkt string to represent NULL geo
           return NullableString(nullptr);
         }
         return GeoReturnTypeTraits<ResultSet::GeoReturnType::WktString,
                                    GEO_SOURCE_TYPE>::GeoSerializerType::serialize(geo_ti,
                                                                                   ad_arr);
       }
       case ResultSet::GeoReturnType::GeoTargetValuePtr:
       case ResultSet::GeoReturnType::GeoTargetValueGpuPtr: {
         if (!geo_ti.get_notnull() && ad_arr[0]->is_null) {
           // NULL geo
           // Pass along null datum, instead of an empty/null GeoTargetValuePtr
           // return GeoTargetValuePtr();
         }
         return GeoReturnTypeTraits<ResultSet::GeoReturnType::GeoTargetValuePtr,
                                    GEO_SOURCE_TYPE>::GeoSerializerType::serialize(geo_ti,
                                                                                   ad_arr);
       }
       default: {
         UNREACHABLE();
         return TargetValue(nullptr);
       }
     }
   }
 };

 template <typename T>
 inline std::pair<int64_t, int64_t> get_frag_id_and_local_idx(
     const std::vector<std::vector<T>>& frag_offsets,
     const size_t tab_or_col_idx,
     const int64_t global_idx) {
   CHECK_GE(global_idx, int64_t(0));
   for (int64_t frag_id = frag_offsets.size() - 1; frag_id > 0; --frag_id) {
     CHECK_LT(tab_or_col_idx, frag_offsets[frag_id].size());
     const auto frag_off = static_cast<int64_t>(frag_offsets[frag_id][tab_or_col_idx]);
     if (frag_off < global_idx) {
       return {frag_id, global_idx - frag_off};
     }
   }
   return {-1, -1};
 }

 }  // namespace

 const std::vector<const int8_t*>& ResultSet::getColumnFrag(const size_t storage_idx,
                                                            const size_t col_logical_idx,
                                                            int64_t& global_idx) const {
   CHECK_LT(static_cast<size_t>(storage_idx), col_buffers_.size());
   if (col_buffers_[storage_idx].size() > 1) {
     int64_t frag_id = 0;
     int64_t local_idx = global_idx;
     if (consistent_frag_sizes_[storage_idx][col_logical_idx] != -1) {
       frag_id = global_idx / consistent_frag_sizes_[storage_idx][col_logical_idx];
       local_idx = global_idx % consistent_frag_sizes_[storage_idx][col_logical_idx];
     } else {
       std::tie(frag_id, local_idx) = get_frag_id_and_local_idx(
           frag_offsets_[storage_idx], col_logical_idx, global_idx);
       CHECK_LE(local_idx, global_idx);
     }
     CHECK_GE(frag_id, int64_t(0));
     CHECK_LT(static_cast<size_t>(frag_id), col_buffers_[storage_idx].size());
     global_idx = local_idx;
     return col_buffers_[storage_idx][frag_id];
   } else {
     CHECK_EQ(size_t(1), col_buffers_[storage_idx].size());
     return col_buffers_[storage_idx][0];
   }
 }

 void ResultSet::copyColumnIntoBuffer(const size_t column_idx,
                                      int8_t* output_buffer,
                                      const size_t output_buffer_size) const {
   CHECK(isDirectColumnarConversionPossible());
   CHECK_LT(column_idx, query_mem_desc_.getSlotCount());
   CHECK(output_buffer_size > 0);
   CHECK(output_buffer);
   const auto column_width_size = query_mem_desc_.getPaddedSlotWidthBytes(column_idx);
   size_t out_buff_offset = 0;

   // the main storage:
   const size_t crt_storage_row_count = storage_->query_mem_desc_.getEntryCount();
   const size_t crt_buffer_size = crt_storage_row_count * column_width_size;
   const size_t column_offset = storage_->query_mem_desc_.getColOffInBytes(column_idx);
   const int8_t* storage_buffer = storage_->getUnderlyingBuffer() + column_offset;
   CHECK(crt_buffer_size <= output_buffer_size);
   std::memcpy(output_buffer, storage_buffer, crt_buffer_size);

   out_buff_offset += crt_buffer_size;

   // the appended storages:
   for (size_t i = 0; i < appended_storage_.size(); i++) {
     const size_t crt_storage_row_count =
         appended_storage_[i]->query_mem_desc_.getEntryCount();
     if (crt_storage_row_count == 0) {
       // skip an empty appended storage
       continue;
     }
     CHECK_LT(out_buff_offset, output_buffer_size);
     const size_t crt_buffer_size = crt_storage_row_count * column_width_size;
     const size_t column_offset =
         appended_storage_[i]->query_mem_desc_.getColOffInBytes(column_idx);
     const int8_t* storage_buffer =
         appended_storage_[i]->getUnderlyingBuffer() + column_offset;
     CHECK(out_buff_offset + crt_buffer_size <= output_buffer_size);
     std::memcpy(output_buffer + out_buff_offset, storage_buffer, crt_buffer_size);

     out_buff_offset += crt_buffer_size;
   }
 }

 template <typename ENTRY_TYPE, QueryDescriptionType QUERY_TYPE, bool COLUMNAR_FORMAT>
 ENTRY_TYPE ResultSet::getEntryAt(const size_t row_idx,
                                  const size_t target_idx,
                                  const size_t slot_idx) const {
   if constexpr (QUERY_TYPE == QueryDescriptionType::GroupByPerfectHash) {  // NOLINT
     if constexpr (COLUMNAR_FORMAT) {                                       // NOLINT
       return getColumnarPerfectHashEntryAt<ENTRY_TYPE>(row_idx, target_idx, slot_idx);
     } else {
       return getRowWisePerfectHashEntryAt<ENTRY_TYPE>(row_idx, target_idx, slot_idx);
     }
   } else if constexpr (QUERY_TYPE == QueryDescriptionType::GroupByBaselineHash) {
     if constexpr (COLUMNAR_FORMAT) {  // NOLINT
       return getColumnarBaselineEntryAt<ENTRY_TYPE>(row_idx, target_idx, slot_idx);
     } else {
       return getRowWiseBaselineEntryAt<ENTRY_TYPE>(row_idx, target_idx, slot_idx);
     }
   } else {
     UNREACHABLE() << "Invalid query type is used";
     return 0;
   }
 }

 #define DEF_GET_ENTRY_AT(query_type, columnar_output)                         \
   template DATA_T ResultSet::getEntryAt<DATA_T, query_type, columnar_output>( \
       const size_t row_idx, const size_t target_idx, const size_t slot_idx) const;

 #define DATA_T int64_t
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #define DATA_T int32_t
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #define DATA_T int16_t
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #define DATA_T int8_t
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #define DATA_T float
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #define DATA_T double
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByPerfectHash, false)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, true)
 DEF_GET_ENTRY_AT(QueryDescriptionType::GroupByBaselineHash, false)
 #undef DATA_T

 #undef DEF_GET_ENTRY_AT

 template <typename ENTRY_TYPE>
 ENTRY_TYPE ResultSet::getColumnarPerfectHashEntryAt(const size_t row_idx,
                                                     const size_t target_idx,
                                                     const size_t slot_idx) const {
   const size_t column_offset = storage_->query_mem_desc_.getColOffInBytes(slot_idx);
   const int8_t* storage_buffer = storage_->getUnderlyingBuffer() + column_offset;
   return reinterpret_cast<const ENTRY_TYPE*>(storage_buffer)[row_idx];
 }

 template <typename ENTRY_TYPE>
 ENTRY_TYPE ResultSet::getRowWisePerfectHashEntryAt(const size_t row_idx,
                                                    const size_t target_idx,
                                                    const size_t slot_idx) const {
   const size_t row_offset = storage_->query_mem_desc_.getRowSize() * row_idx;
   const size_t column_offset = storage_->query_mem_desc_.getColOffInBytes(slot_idx);
   const int8_t* storage_buffer =
       storage_->getUnderlyingBuffer() + row_offset + column_offset;
   return *reinterpret_cast<const ENTRY_TYPE*>(storage_buffer);
 }

 template <typename ENTRY_TYPE>
 ENTRY_TYPE ResultSet::getRowWiseBaselineEntryAt(const size_t row_idx,
                                                 const size_t target_idx,
                                                 const size_t slot_idx) const {
   CHECK_NE(storage_->query_mem_desc_.targetGroupbyIndicesSize(), size_t(0));
   const auto key_width = storage_->query_mem_desc_.getEffectiveKeyWidth();
   auto keys_ptr = row_ptr_rowwise(
       storage_->getUnderlyingBuffer(), storage_->query_mem_desc_, row_idx);
   const auto column_offset =
       (storage_->query_mem_desc_.getTargetGroupbyIndex(target_idx) < 0)
           ? storage_->query_mem_desc_.getColOffInBytes(slot_idx)
           : storage_->query_mem_desc_.getTargetGroupbyIndex(target_idx) * key_width;
   const auto storage_buffer = keys_ptr + column_offset;
   return *reinterpret_cast<const ENTRY_TYPE*>(storage_buffer);
 }

 template <typename ENTRY_TYPE>
 ENTRY_TYPE ResultSet::getColumnarBaselineEntryAt(const size_t row_idx,
                                                  const size_t target_idx,
                                                  const size_t slot_idx) const {
   CHECK_NE(storage_->query_mem_desc_.targetGroupbyIndicesSize(), size_t(0));
   const auto key_width = storage_->query_mem_desc_.getEffectiveKeyWidth();
   const auto column_offset =
       (storage_->query_mem_desc_.getTargetGroupbyIndex(target_idx) < 0)
           ? storage_->query_mem_desc_.getColOffInBytes(slot_idx)
           : storage_->query_mem_desc_.getTargetGroupbyIndex(target_idx) * key_width *
                 storage_->query_mem_desc_.getEntryCount();
   const auto column_buffer = storage_->getUnderlyingBuffer() + column_offset;
   return reinterpret_cast<const ENTRY_TYPE*>(column_buffer)[row_idx];
 }

 // Interprets ptr1, ptr2 as the ptr and len pair used for variable length data.
 TargetValue ResultSet::makeVarlenTargetValue(const int8_t* ptr1,
                                              const int8_t compact_sz1,
                                              const int8_t* ptr2,
                                              const int8_t compact_sz2,
                                              const TargetInfo& target_info,
                                              const size_t target_logical_idx,
                                              const bool translate_strings,
                                              const size_t entry_buff_idx) const {
   auto varlen_ptr = read_int_from_buff(ptr1, compact_sz1);
   if (separate_varlen_storage_valid_ && !target_info.is_agg) {
     if (varlen_ptr < 0) {
       CHECK_EQ(-1, varlen_ptr);
       if (target_info.sql_type.get_type() == kARRAY) {
         return ArrayTargetValue(boost::optional<std::vector<ScalarTargetValue>>{});
       }
       return TargetValue(nullptr);
     }
     const auto storage_idx = getStorageIndex(entry_buff_idx);
     if (target_info.sql_type.is_string()) {
       CHECK(target_info.sql_type.get_compression() == kENCODING_NONE);
       CHECK_LT(storage_idx.first, serialized_varlen_buffer_.size());
       const auto& varlen_buffer_for_storage =
           serialized_varlen_buffer_[storage_idx.first];
       CHECK_LT(static_cast<size_t>(varlen_ptr), varlen_buffer_for_storage.size());
       return varlen_buffer_for_storage[varlen_ptr];
     } else if (target_info.sql_type.get_type() == kARRAY) {
       CHECK_LT(storage_idx.first, serialized_varlen_buffer_.size());
       const auto& varlen_buffer = serialized_varlen_buffer_[storage_idx.first];
       CHECK_LT(static_cast<size_t>(varlen_ptr), varlen_buffer.size());

       return build_array_target_value(
           target_info.sql_type,
           reinterpret_cast<const int8_t*>(varlen_buffer[varlen_ptr].data()),
           varlen_buffer[varlen_ptr].size(),
           translate_strings,
           row_set_mem_owner_,
           catalog_);
     } else {
       CHECK(false);
     }
   }
   if (!lazy_fetch_info_.empty()) {
     CHECK_LT(target_logical_idx, lazy_fetch_info_.size());
     const auto& col_lazy_fetch = lazy_fetch_info_[target_logical_idx];
     if (col_lazy_fetch.is_lazily_fetched) {
       const auto storage_idx = getStorageIndex(entry_buff_idx);
       CHECK_LT(storage_idx.first, col_buffers_.size());
       auto& frag_col_buffers =
           getColumnFrag(storage_idx.first, target_logical_idx, varlen_ptr);
       bool is_end{false};
       if (target_info.sql_type.is_string()) {
         VarlenDatum vd;
         ChunkIter_get_nth(reinterpret_cast<ChunkIter*>(const_cast<int8_t*>(
                               frag_col_buffers[col_lazy_fetch.local_col_id])),
                           varlen_ptr,
                           false,
                           &vd,
                           &is_end);
         CHECK(!is_end);
         if (vd.is_null) {
           return TargetValue(nullptr);
         }
         CHECK(vd.pointer);
         CHECK_GT(vd.length, 0u);
         std::string fetched_str(reinterpret_cast<char*>(vd.pointer), vd.length);
         return fetched_str;
       } else {
         CHECK(target_info.sql_type.is_array());
         ArrayDatum ad;
         ChunkIter_get_nth(reinterpret_cast<ChunkIter*>(const_cast<int8_t*>(
                               frag_col_buffers[col_lazy_fetch.local_col_id])),
                           varlen_ptr,
                           &ad,
                           &is_end);
         CHECK(!is_end);
         if (ad.is_null) {
           return ArrayTargetValue(boost::optional<std::vector<ScalarTargetValue>>{});
         }
         CHECK_GE(ad.length, 0u);
         if (ad.length > 0) {
           CHECK(ad.pointer);
         }
         return build_array_target_value(target_info.sql_type,
                                         ad.pointer,
                                         ad.length,
                                         translate_strings,
                                         row_set_mem_owner_,
                                         catalog_);
       }
     }
   }
   if (!varlen_ptr) {
     if (target_info.sql_type.is_array()) {
       return ArrayTargetValue(boost::optional<std::vector<ScalarTargetValue>>{});
     }
     return TargetValue(nullptr);
   }
   auto length = read_int_from_buff(ptr2, compact_sz2);
   if (target_info.sql_type.is_array()) {
     const auto& elem_ti = target_info.sql_type.get_elem_type();
     length *= elem_ti.get_array_context_logical_size();
   }
   std::vector<int8_t> cpu_buffer;
   if (varlen_ptr && device_type_ == ExecutorDeviceType::GPU) {
     cpu_buffer.resize(length);
     const auto executor = query_mem_desc_.getExecutor();
     CHECK(executor);
     auto& data_mgr = executor->catalog_->getDataMgr();
     copy_from_gpu(&data_mgr,
                   &cpu_buffer[0],
                   static_cast<CUdeviceptr>(varlen_ptr),
                   length,
                   device_id_);
     varlen_ptr = reinterpret_cast<int64_t>(&cpu_buffer[0]);
   }
   if (target_info.sql_type.is_array()) {
     return build_array_target_value(target_info.sql_type,
                                     reinterpret_cast<const int8_t*>(varlen_ptr),
                                     length,
                                     translate_strings,
                                     row_set_mem_owner_,
                                     catalog_);
   }
   return std::string(reinterpret_cast<char*>(varlen_ptr), length);
 }

 bool ResultSet::isGeoColOnGpu(const size_t col_idx) const {
   // This should match the logic in makeGeoTargetValue which ultimately calls
   // fetch_data_from_gpu when the geo column is on the device.
   // TODO(croot): somehow find a way to refactor this and makeGeoTargetValue to use a
   // utility function that handles this logic in one place
   CHECK_LT(col_idx, targets_.size());
   if (!IS_GEO(targets_[col_idx].sql_type.get_type())) {
     throw std::runtime_error("Column target at index " + std::to_string(col_idx) +
                              " is not a geo column. It is of type " +
                              targets_[col_idx].sql_type.get_type_name() + ".");
   }

   const auto& target_info = targets_[col_idx];
   if (separate_varlen_storage_valid_ && !target_info.is_agg) {
     return false;
   }

   if (!lazy_fetch_info_.empty()) {
     CHECK_LT(col_idx, lazy_fetch_info_.size());
     if (lazy_fetch_info_[col_idx].is_lazily_fetched) {
       return false;
     }
   }

   return device_type_ == ExecutorDeviceType::GPU;
 }

 // Reads a geo value from a series of ptrs to var len types
 // In Columnar format, geo_target_ptr is the geo column ptr (a pointer to the beginning
 // of that specific geo column) and should be appropriately adjusted with the
 // entry_buff_idx
 TargetValue ResultSet::makeGeoTargetValue(const int8_t* geo_target_ptr,
                                           const size_t slot_idx,
                                           const TargetInfo& target_info,
                                           const size_t target_logical_idx,
                                           const size_t entry_buff_idx) const {
   CHECK(target_info.sql_type.is_geometry());

   auto getNextTargetBufferRowWise = [&](const size_t slot_idx, const size_t range) {
     return geo_target_ptr + query_mem_desc_.getPaddedColWidthForRange(slot_idx, range);
   };

   auto getNextTargetBufferColWise = [&](const size_t slot_idx, const size_t range) {
     const auto storage_info = findStorage(entry_buff_idx);
     auto crt_geo_col_ptr = geo_target_ptr;
     for (size_t i = slot_idx; i < slot_idx + range; i++) {
       crt_geo_col_ptr = advance_to_next_columnar_target_buff(
           crt_geo_col_ptr, storage_info.storage_ptr->query_mem_desc_, i);
     }
     // adjusting the column pointer to represent a pointer to the geo target value
     return crt_geo_col_ptr +
            storage_info.fixedup_entry_idx *
                storage_info.storage_ptr->query_mem_desc_.getPaddedSlotWidthBytes(
                    slot_idx + range);
   };

   auto getNextTargetBuffer = [&](const size_t slot_idx, const size_t range) {
     return query_mem_desc_.didOutputColumnar()
                ? getNextTargetBufferColWise(slot_idx, range)
                : getNextTargetBufferRowWise(slot_idx, range);
   };

   auto getCoordsDataPtr = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 0),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx));
   };

   auto getCoordsLength = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 1),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 1));
   };

   auto getRingSizesPtr = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 2),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 2));
   };

   auto getRingSizesLength = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 3),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 3));
   };

   auto getPolyRingsPtr = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 4),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 4));
   };

   auto getPolyRingsLength = [&](const int8_t* geo_target_ptr) {
     return read_int_from_buff(getNextTargetBuffer(slot_idx, 5),
                               query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 5));
   };

   auto getFragColBuffers = [&]() -> decltype(auto) {
     const auto storage_idx = getStorageIndex(entry_buff_idx);
     CHECK_LT(storage_idx.first, col_buffers_.size());
     auto global_idx = getCoordsDataPtr(geo_target_ptr);
     return getColumnFrag(storage_idx.first, target_logical_idx, global_idx);
   };

   const bool is_gpu_fetch = device_type_ == ExecutorDeviceType::GPU;

   auto getDataMgr = [&]() {
     auto executor = query_mem_desc_.getExecutor();
     CHECK(executor);
     auto& data_mgr = executor->catalog_->getDataMgr();
     return &data_mgr;
   };

   auto getSeparateVarlenStorage = [&]() -> decltype(auto) {
     const auto storage_idx = getStorageIndex(entry_buff_idx);
     CHECK_LT(storage_idx.first, serialized_varlen_buffer_.size());
     const auto& varlen_buffer = serialized_varlen_buffer_[storage_idx.first];
     return varlen_buffer;
   };

   if (separate_varlen_storage_valid_ && getCoordsDataPtr(geo_target_ptr) < 0) {
     CHECK_EQ(-1, getCoordsDataPtr(geo_target_ptr));
     return TargetValue(nullptr);
   }

   const ColumnLazyFetchInfo* col_lazy_fetch = nullptr;
   if (!lazy_fetch_info_.empty()) {
     CHECK_LT(target_logical_idx, lazy_fetch_info_.size());
     col_lazy_fetch = &lazy_fetch_info_[target_logical_idx];
   }

   switch (target_info.sql_type.get_type()) {
     case kPOINT: {
       if (separate_varlen_storage_valid_ && !target_info.is_agg) {
         const auto& varlen_buffer = getSeparateVarlenStorage();
         CHECK_LT(static_cast<size_t>(getCoordsDataPtr(geo_target_ptr)),
                  varlen_buffer.size());

         return GeoTargetValueBuilder<kPOINT, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             nullptr,
             false,
             device_id_,
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr)].data()),
             static_cast<int64_t>(varlen_buffer[getCoordsDataPtr(geo_target_ptr)].size()));
       } else if (col_lazy_fetch && col_lazy_fetch->is_lazily_fetched) {
         const auto& frag_col_buffers = getFragColBuffers();
         return GeoTargetValueBuilder<kPOINT, GeoLazyFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             frag_col_buffers[col_lazy_fetch->local_col_id],
             getCoordsDataPtr(geo_target_ptr));
       } else {
         return GeoTargetValueBuilder<kPOINT, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             is_gpu_fetch ? getDataMgr() : nullptr,
             is_gpu_fetch,
             device_id_,
             getCoordsDataPtr(geo_target_ptr),
             getCoordsLength(geo_target_ptr));
       }
       break;
     }
     case kLINESTRING: {
       if (separate_varlen_storage_valid_ && !target_info.is_agg) {
         const auto& varlen_buffer = getSeparateVarlenStorage();
         CHECK_LT(static_cast<size_t>(getCoordsDataPtr(geo_target_ptr)),
                  varlen_buffer.size());

         return GeoTargetValueBuilder<kLINESTRING, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             nullptr,
             false,
             device_id_,
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr)].data()),
             static_cast<int64_t>(varlen_buffer[getCoordsDataPtr(geo_target_ptr)].size()));
       } else if (col_lazy_fetch && col_lazy_fetch->is_lazily_fetched) {
         const auto& frag_col_buffers = getFragColBuffers();
         return GeoTargetValueBuilder<kLINESTRING, GeoLazyFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             frag_col_buffers[col_lazy_fetch->local_col_id],
             getCoordsDataPtr(geo_target_ptr));
       } else {
         return GeoTargetValueBuilder<kLINESTRING, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             is_gpu_fetch ? getDataMgr() : nullptr,
             is_gpu_fetch,
             device_id_,
             getCoordsDataPtr(geo_target_ptr),
             getCoordsLength(geo_target_ptr));
       }
       break;
     }
     case kPOLYGON: {
       if (separate_varlen_storage_valid_ && !target_info.is_agg) {
         const auto& varlen_buffer = getSeparateVarlenStorage();
         CHECK_LT(static_cast<size_t>(getCoordsDataPtr(geo_target_ptr) + 1),
                  varlen_buffer.size());

         return GeoTargetValueBuilder<kPOLYGON, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             nullptr,
             false,
             device_id_,
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr)].data()),
             static_cast<int64_t>(varlen_buffer[getCoordsDataPtr(geo_target_ptr)].size()),
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 1].data()),
             static_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 1].size()));
       } else if (col_lazy_fetch && col_lazy_fetch->is_lazily_fetched) {
         const auto& frag_col_buffers = getFragColBuffers();

         return GeoTargetValueBuilder<kPOLYGON, GeoLazyFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             frag_col_buffers[col_lazy_fetch->local_col_id],
             getCoordsDataPtr(geo_target_ptr),
             frag_col_buffers[col_lazy_fetch->local_col_id + 1],
             getCoordsDataPtr(geo_target_ptr));
       } else {
         return GeoTargetValueBuilder<kPOLYGON, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             is_gpu_fetch ? getDataMgr() : nullptr,
             is_gpu_fetch,
             device_id_,
             getCoordsDataPtr(geo_target_ptr),
             getCoordsLength(geo_target_ptr),
             getRingSizesPtr(geo_target_ptr),
             getRingSizesLength(geo_target_ptr) * 4);
       }
       break;
     }
     case kMULTIPOLYGON: {
       if (separate_varlen_storage_valid_ && !target_info.is_agg) {
         const auto& varlen_buffer = getSeparateVarlenStorage();
         CHECK_LT(static_cast<size_t>(getCoordsDataPtr(geo_target_ptr) + 2),
                  varlen_buffer.size());

         return GeoTargetValueBuilder<kMULTIPOLYGON, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             nullptr,
             false,
             device_id_,
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr)].data()),
             static_cast<int64_t>(varlen_buffer[getCoordsDataPtr(geo_target_ptr)].size()),
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 1].data()),
             static_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 1].size()),
             reinterpret_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 2].data()),
             static_cast<int64_t>(
                 varlen_buffer[getCoordsDataPtr(geo_target_ptr) + 2].size()));
       } else if (col_lazy_fetch && col_lazy_fetch->is_lazily_fetched) {
         const auto& frag_col_buffers = getFragColBuffers();

         return GeoTargetValueBuilder<kMULTIPOLYGON, GeoLazyFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             frag_col_buffers[col_lazy_fetch->local_col_id],
             getCoordsDataPtr(geo_target_ptr),
             frag_col_buffers[col_lazy_fetch->local_col_id + 1],
             getCoordsDataPtr(geo_target_ptr),
             frag_col_buffers[col_lazy_fetch->local_col_id + 2],
             getCoordsDataPtr(geo_target_ptr));
       } else {
         return GeoTargetValueBuilder<kMULTIPOLYGON, GeoQueryOutputFetchHandler>::build(
             target_info.sql_type,
             geo_return_type_,
             is_gpu_fetch ? getDataMgr() : nullptr,
             is_gpu_fetch,
             device_id_,
             getCoordsDataPtr(geo_target_ptr),
             getCoordsLength(geo_target_ptr),
             getRingSizesPtr(geo_target_ptr),
             getRingSizesLength(geo_target_ptr) * 4,
             getPolyRingsPtr(geo_target_ptr),
             getPolyRingsLength(geo_target_ptr) * 4);
       }
       break;
     }
     default:
       throw std::runtime_error("Unknown Geometry type encountered: " +
                                target_info.sql_type.get_type_name());
   }
   UNREACHABLE();
   return TargetValue(nullptr);
 }

 // Reads an integer or a float from ptr based on the type and the byte width.
 TargetValue ResultSet::makeTargetValue(const int8_t* ptr,
                                        const int8_t compact_sz,
                                        const TargetInfo& target_info,
                                        const size_t target_logical_idx,
                                        const bool translate_strings,
                                        const bool decimal_to_double,
                                        const size_t entry_buff_idx) const {
   auto actual_compact_sz = compact_sz;
   const auto& type_info = target_info.sql_type;
   if (type_info.get_type() == kFLOAT && !query_mem_desc_.forceFourByteFloat()) {
     if (query_mem_desc_.isLogicalSizedColumnsAllowed()) {
       actual_compact_sz = sizeof(float);
     } else {
       actual_compact_sz = sizeof(double);
     }
     if (target_info.is_agg &&
         (target_info.agg_kind == kAVG || target_info.agg_kind == kSUM ||
          target_info.agg_kind == kMIN || target_info.agg_kind == kMAX ||
          target_info.agg_kind == kSINGLE_VALUE)) {
       // The above listed aggregates use two floats in a single 8-byte slot. Set the
       // padded size to 4 bytes to properly read each value.
       actual_compact_sz = sizeof(float);
     }
   }
   if (get_compact_type(target_info).is_date_in_days()) {
     // Dates encoded in days are converted to 8 byte values on read.
     actual_compact_sz = sizeof(int64_t);
   }

   // String dictionary keys are read as 32-bit values regardless of encoding
   if (type_info.is_string() && type_info.get_compression() == kENCODING_DICT &&
       type_info.get_comp_param()) {
     actual_compact_sz = sizeof(int32_t);
   }

   auto ival = read_int_from_buff(ptr, actual_compact_sz);
   const auto& chosen_type = get_compact_type(target_info);
   if (!lazy_fetch_info_.empty()) {
     CHECK_LT(target_logical_idx, lazy_fetch_info_.size());
     const auto& col_lazy_fetch = lazy_fetch_info_[target_logical_idx];
     if (col_lazy_fetch.is_lazily_fetched) {
       CHECK_GE(ival, 0);
       const auto storage_idx = getStorageIndex(entry_buff_idx);
       CHECK_LT(storage_idx.first, col_buffers_.size());
       auto& frag_col_buffers = getColumnFrag(storage_idx.first, target_logical_idx, ival);
       CHECK_LT(size_t(col_lazy_fetch.local_col_id), frag_col_buffers.size());
       ival = result_set::lazy_decode(
           col_lazy_fetch, frag_col_buffers[col_lazy_fetch.local_col_id], ival);
       if (chosen_type.is_fp()) {
         const auto dval = *reinterpret_cast<const double*>(may_alias_ptr(&ival));
         if (chosen_type.get_type() == kFLOAT) {
           return ScalarTargetValue(static_cast<float>(dval));
         } else {
           return ScalarTargetValue(dval);
         }
       }
     }
   }
   if (chosen_type.is_fp()) {
     switch (actual_compact_sz) {
       case 8: {
         const auto dval = *reinterpret_cast<const double*>(ptr);
         return chosen_type.get_type() == kFLOAT
                    ? ScalarTargetValue(static_cast<const float>(dval))
                    : ScalarTargetValue(dval);
       }
       case 4: {
         CHECK_EQ(kFLOAT, chosen_type.get_type());
         return *reinterpret_cast<const float*>(ptr);
       }
       default:
         CHECK(false);
     }
   }
   if (chosen_type.is_integer() | chosen_type.is_boolean() || chosen_type.is_time() ||
       chosen_type.is_timeinterval()) {
     if (is_distinct_target(target_info)) {
       return TargetValue(count_distinct_set_size(
           ival, query_mem_desc_.getCountDistinctDescriptor(target_logical_idx)));
     }
     // TODO(alex): remove int_resize_cast, make read_int_from_buff return the
     // right type instead
     if (inline_int_null_val(chosen_type) ==
         int_resize_cast(ival, chosen_type.get_logical_size())) {
       return inline_int_null_val(type_info);
     }
     return ival;
   }
   if (chosen_type.is_string() && chosen_type.get_compression() == kENCODING_DICT) {
     if (translate_strings) {
       if (static_cast<int32_t>(ival) ==
           NULL_INT) {  // TODO(alex): this isn't nice, fix it
         return NullableString(nullptr);
       }
       StringDictionaryProxy* sdp{nullptr};
       if (!chosen_type.get_comp_param()) {
         sdp = row_set_mem_owner_->getLiteralStringDictProxy();
       } else {
         sdp = catalog_
                   ? row_set_mem_owner_->getOrAddStringDictProxy(
                         chosen_type.get_comp_param(), /*with_generation=*/false, catalog_)
                   : row_set_mem_owner_->getStringDictProxy(
                         chosen_type.get_comp_param());  // unit tests bypass the catalog
       }
       return NullableString(sdp->getString(ival));
     } else {
       return static_cast<int64_t>(static_cast<int32_t>(ival));
     }
   }
   if (chosen_type.is_decimal()) {
     if (decimal_to_double) {
       if (target_info.is_agg &&
           (target_info.agg_kind == kAVG || target_info.agg_kind == kSUM ||
            target_info.agg_kind == kMIN || target_info.agg_kind == kMAX) &&
           ival == inline_int_null_val(SQLTypeInfo(kBIGINT, false))) {
         return NULL_DOUBLE;
       }
       if (ival ==
           inline_int_null_val(SQLTypeInfo(decimal_to_int_type(chosen_type), false))) {
         return NULL_DOUBLE;
       }
       return static_cast<double>(ival) / exp_to_scale(chosen_type.get_scale());
     }
     return ival;
   }
   CHECK(false);
   return TargetValue(int64_t(0));
 }

 namespace {
 double calculate_quantile(int8_t const* ptr, double const q) {
   static_assert(sizeof(int64_t) == sizeof(quantile::TDigest*));
   auto* t_digest = *reinterpret_cast<quantile::TDigest* const*>(ptr);
   CHECK(t_digest) << "ptr=" << (void const*)ptr << ", q=" << q;
   t_digest->mergeBuffer();
   double const median = t_digest->quantile(q);
   return boost::math::isnan(median) ? NULL_DOUBLE : median;
 }
 }  // namespace

 // Gets the TargetValue stored at position local_entry_idx in the col1_ptr and col2_ptr
 // column buffers. The second column is only used for AVG.
 // the global_entry_idx is passed to makeTargetValue to be used for
 // final lazy fetch (if there's any).
 TargetValue ResultSet::getTargetValueFromBufferColwise(
     const int8_t* col_ptr,
     const int8_t* keys_ptr,
     const QueryMemoryDescriptor& query_mem_desc,
     const size_t local_entry_idx,
     const size_t global_entry_idx,
     const TargetInfo& target_info,
     const size_t target_logical_idx,
     const size_t slot_idx,
     const bool translate_strings,
     const bool decimal_to_double) const {
   CHECK(query_mem_desc_.didOutputColumnar());
   const auto col1_ptr = col_ptr;
   const auto compact_sz1 = query_mem_desc.getPaddedSlotWidthBytes(slot_idx);
   const auto next_col_ptr =
       advance_to_next_columnar_target_buff(col1_ptr, query_mem_desc, slot_idx);
   const auto col2_ptr = ((target_info.is_agg && target_info.agg_kind == kAVG) ||
                          is_real_str_or_array(target_info))
                             ? next_col_ptr
                             : nullptr;
   const auto compact_sz2 = ((target_info.is_agg && target_info.agg_kind == kAVG) ||
                             is_real_str_or_array(target_info))
                                ? query_mem_desc.getPaddedSlotWidthBytes(slot_idx + 1)
                                : 0;

   // TODO(Saman): add required logics for count distinct
   // geospatial target values:
   if (target_info.sql_type.is_geometry()) {
     return makeGeoTargetValue(
         col1_ptr, slot_idx, target_info, target_logical_idx, global_entry_idx);
   }

   const auto ptr1 = columnar_elem_ptr(local_entry_idx, col1_ptr, compact_sz1);
   if (target_info.agg_kind == kAVG || is_real_str_or_array(target_info)) {
     CHECK(col2_ptr);
     CHECK(compact_sz2);
     const auto ptr2 = columnar_elem_ptr(local_entry_idx, col2_ptr, compact_sz2);
     return target_info.agg_kind == kAVG
                ? make_avg_target_value(ptr1, compact_sz1, ptr2, compact_sz2, target_info)
                : makeVarlenTargetValue(ptr1,
                                        compact_sz1,
                                        ptr2,
                                        compact_sz2,
                                        target_info,
                                        target_logical_idx,
                                        translate_strings,
                                        global_entry_idx);
   } else if (target_info.agg_kind == kAPPROX_MEDIAN) {
     return calculate_quantile(ptr1, 0.5);
   }
   if (query_mem_desc_.targetGroupbyIndicesSize() == 0 ||
       query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) < 0) {
     return makeTargetValue(ptr1,
                            compact_sz1,
                            target_info,
                            target_logical_idx,
                            translate_strings,
                            decimal_to_double,
                            global_entry_idx);
   }
   const auto key_width = query_mem_desc_.getEffectiveKeyWidth();
   const auto key_idx = query_mem_desc_.getTargetGroupbyIndex(target_logical_idx);
   CHECK_GE(key_idx, 0);
   auto key_col_ptr = keys_ptr + key_idx * query_mem_desc_.getEntryCount() * key_width;
   return makeTargetValue(columnar_elem_ptr(local_entry_idx, key_col_ptr, key_width),
                          key_width,
                          target_info,
                          target_logical_idx,
                          translate_strings,
                          decimal_to_double,
                          global_entry_idx);
 }

 // Gets the TargetValue stored in slot_idx (and slot_idx for AVG) of
 // rowwise_target_ptr.
 TargetValue ResultSet::getTargetValueFromBufferRowwise(
     int8_t* rowwise_target_ptr,
     int8_t* keys_ptr,
     const size_t entry_buff_idx,
     const TargetInfo& target_info,
     const size_t target_logical_idx,
     const size_t slot_idx,
     const bool translate_strings,
     const bool decimal_to_double,
     const bool fixup_count_distinct_pointers) const {
   if (UNLIKELY(fixup_count_distinct_pointers)) {
     if (is_distinct_target(target_info)) {
       auto count_distinct_ptr_ptr = reinterpret_cast<int64_t*>(rowwise_target_ptr);
       const auto remote_ptr = *count_distinct_ptr_ptr;
       if (remote_ptr) {
         const auto ptr = storage_->mappedPtr(remote_ptr);
         if (ptr) {
           *count_distinct_ptr_ptr = ptr;
         } else {
           // need to create a zero filled buffer for this remote_ptr
           const auto& count_distinct_desc =
               query_mem_desc_.count_distinct_descriptors_[target_logical_idx];
           const auto bitmap_byte_sz = count_distinct_desc.sub_bitmap_count == 1
                                           ? count_distinct_desc.bitmapSizeBytes()
                                           : count_distinct_desc.bitmapPaddedSizeBytes();
           auto count_distinct_buffer =
               row_set_mem_owner_->allocateCountDistinctBuffer(bitmap_byte_sz);
           *count_distinct_ptr_ptr = reinterpret_cast<int64_t>(count_distinct_buffer);
         }
       }
     }
     return int64_t(0);
   }
   if (target_info.sql_type.is_geometry()) {
     return makeGeoTargetValue(
         rowwise_target_ptr, slot_idx, target_info, target_logical_idx, entry_buff_idx);
   }

   auto ptr1 = rowwise_target_ptr;
   int8_t compact_sz1 = query_mem_desc_.getPaddedSlotWidthBytes(slot_idx);
   if (query_mem_desc_.isSingleColumnGroupByWithPerfectHash() &&
       !query_mem_desc_.hasKeylessHash() && !target_info.is_agg) {
     // Single column perfect hash group by can utilize one slot for both the key and the
     // target value if both values fit in 8 bytes. Use the target value actual size for
     // this case. If they don't, the target value should be 8 bytes, so we can still use
     // the actual size rather than the compact size.
     compact_sz1 = query_mem_desc_.getLogicalSlotWidthBytes(slot_idx);
   }

   // logic for deciding width of column
   if (target_info.agg_kind == kAVG || is_real_str_or_array(target_info)) {
     const auto ptr2 =
         rowwise_target_ptr + query_mem_desc_.getPaddedSlotWidthBytes(slot_idx);
     int8_t compact_sz2 = 0;
     // Skip reading the second slot if we have a none encoded string and are using
     // the none encoded strings buffer attached to ResultSetStorage
     if (!(separate_varlen_storage_valid_ &&
           (target_info.sql_type.is_array() ||
            (target_info.sql_type.is_string() &&
             target_info.sql_type.get_compression() == kENCODING_NONE)))) {
       compact_sz2 = query_mem_desc_.getPaddedSlotWidthBytes(slot_idx + 1);
     }
     if (separate_varlen_storage_valid_ && target_info.is_agg) {
       compact_sz2 = 8;  // TODO(adb): is there a better way to do this?
     }
     CHECK(ptr2);
     return target_info.agg_kind == kAVG
                ? make_avg_target_value(ptr1, compact_sz1, ptr2, compact_sz2, target_info)
                : makeVarlenTargetValue(ptr1,
                                        compact_sz1,
                                        ptr2,
                                        compact_sz2,
                                        target_info,
                                        target_logical_idx,
                                        translate_strings,
                                        entry_buff_idx);
   } else if (target_info.agg_kind == kAPPROX_MEDIAN) {
     return calculate_quantile(rowwise_target_ptr, 0.5);
   }
   if (query_mem_desc_.targetGroupbyIndicesSize() == 0 ||
       query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) < 0) {
     return makeTargetValue(ptr1,
                            compact_sz1,
                            target_info,
                            target_logical_idx,
                            translate_strings,
                            decimal_to_double,
                            entry_buff_idx);
   }
   const auto key_width = query_mem_desc_.getEffectiveKeyWidth();
   ptr1 = keys_ptr + query_mem_desc_.getTargetGroupbyIndex(target_logical_idx) * key_width;
   return makeTargetValue(ptr1,
                          key_width,
                          target_info,
                          target_logical_idx,
                          translate_strings,
                          decimal_to_double,
                          entry_buff_idx);
 }

 // Returns true iff the entry at position entry_idx in buff contains a valid row.
 bool ResultSetStorage::isEmptyEntry(const size_t entry_idx, const int8_t* buff) const {
   if (QueryDescriptionType::NonGroupedAggregate ==
       query_mem_desc_.getQueryDescriptionType()) {
     return false;
   }
   if (query_mem_desc_.didOutputColumnar()) {
     return isEmptyEntryColumnar(entry_idx, buff);
   }
   if (query_mem_desc_.hasKeylessHash()) {
     CHECK(query_mem_desc_.getQueryDescriptionType() ==
           QueryDescriptionType::GroupByPerfectHash);
     CHECK_GE(query_mem_desc_.getTargetIdxForKey(), 0);
     CHECK_LT(static_cast<size_t>(query_mem_desc_.getTargetIdxForKey()),
              target_init_vals_.size());
     const auto rowwise_target_ptr = row_ptr_rowwise(buff, query_mem_desc_, entry_idx);
     const auto target_slot_off = result_set::get_byteoff_of_slot(
         query_mem_desc_.getTargetIdxForKey(), query_mem_desc_);
     return read_int_from_buff(rowwise_target_ptr + target_slot_off,
                               query_mem_desc_.getPaddedSlotWidthBytes(
                                   query_mem_desc_.getTargetIdxForKey())) ==
            target_init_vals_[query_mem_desc_.getTargetIdxForKey()];
   } else {
     const auto keys_ptr = row_ptr_rowwise(buff, query_mem_desc_, entry_idx);
     switch (query_mem_desc_.getEffectiveKeyWidth()) {
       case 4:
         CHECK(QueryDescriptionType::GroupByPerfectHash !=
               query_mem_desc_.getQueryDescriptionType());
         return *reinterpret_cast<const int32_t*>(keys_ptr) == EMPTY_KEY_32;
       case 8:
         return *reinterpret_cast<const int64_t*>(keys_ptr) == EMPTY_KEY_64;
       default:
         CHECK(false);
         return true;
     }
   }
 }

 /*
  * Returns true if the entry contain empty keys
  * This function should only be used with columanr format.
  */
 bool ResultSetStorage::isEmptyEntryColumnar(const size_t entry_idx,
                                             const int8_t* buff) const {
   CHECK(query_mem_desc_.didOutputColumnar());
   if (query_mem_desc_.getQueryDescriptionType() ==
       QueryDescriptionType::NonGroupedAggregate) {
     return false;
   }
   if (query_mem_desc_.hasKeylessHash()) {
     CHECK(query_mem_desc_.getQueryDescriptionType() ==
           QueryDescriptionType::GroupByPerfectHash);
     CHECK_GE(query_mem_desc_.getTargetIdxForKey(), 0);
     CHECK_LT(static_cast<size_t>(query_mem_desc_.getTargetIdxForKey()),
              target_init_vals_.size());
     const auto col_buff = advance_col_buff_to_slot(
         buff, query_mem_desc_, targets_, query_mem_desc_.getTargetIdxForKey(), false);
     const auto entry_buff =
         col_buff + entry_idx * query_mem_desc_.getPaddedSlotWidthBytes(
                                    query_mem_desc_.getTargetIdxForKey());
     return read_int_from_buff(entry_buff,
                               query_mem_desc_.getPaddedSlotWidthBytes(
                                   query_mem_desc_.getTargetIdxForKey())) ==
            target_init_vals_[query_mem_desc_.getTargetIdxForKey()];
   } else {
     // it's enough to find the first group key which is empty
     if (query_mem_desc_.getQueryDescriptionType() == QueryDescriptionType::Projection) {
       return reinterpret_cast<const int64_t*>(buff)[entry_idx] == EMPTY_KEY_64;
     } else {
       CHECK(query_mem_desc_.getGroupbyColCount() > 0);
       const auto target_buff = buff + query_mem_desc_.getPrependedGroupColOffInBytes(0);
       switch (query_mem_desc_.groupColWidth(0)) {
         case 8:
           return reinterpret_cast<const int64_t*>(target_buff)[entry_idx] == EMPTY_KEY_64;
         case 4:
           return reinterpret_cast<const int32_t*>(target_buff)[entry_idx] == EMPTY_KEY_32;
         case 2:
           return reinterpret_cast<const int16_t*>(target_buff)[entry_idx] == EMPTY_KEY_16;
         case 1:
           return reinterpret_cast<const int8_t*>(target_buff)[entry_idx] == EMPTY_KEY_8;
         default:
           CHECK(false);
       }
     }
     return false;
   }
   return false;
 }

 namespace {

 template <typename T>
 inline size_t make_bin_search(size_t l, size_t r, T&& is_empty_fn) {
   // Avoid search if there are no empty keys.
   if (!is_empty_fn(r - 1)) {
     return r;
   }

   --r;
   while (l != r) {
     size_t c = (l + r) / 2;
     if (is_empty_fn(c)) {
       r = c;
     } else {
       l = c + 1;
     }
   }

   return r;
 }

 }  // namespace

 size_t ResultSetStorage::binSearchRowCount() const {
   CHECK(query_mem_desc_.getQueryDescriptionType() == QueryDescriptionType::Projection);
   CHECK_EQ(query_mem_desc_.getEffectiveKeyWidth(), size_t(8));

   if (!query_mem_desc_.getEntryCount()) {
     return 0;
   }

   if (query_mem_desc_.didOutputColumnar()) {
     return make_bin_search(0, query_mem_desc_.getEntryCount(), [this](size_t idx) {
       return reinterpret_cast<const int64_t*>(buff_)[idx] == EMPTY_KEY_64;
     });
   } else {
     return make_bin_search(0, query_mem_desc_.getEntryCount(), [this](size_t idx) {
       const auto keys_ptr = row_ptr_rowwise(buff_, query_mem_desc_, idx);
       return *reinterpret_cast<const int64_t*>(keys_ptr) == EMPTY_KEY_64;
     });
   }
 }

 bool ResultSetStorage::isEmptyEntry(const size_t entry_idx) const {
   return isEmptyEntry(entry_idx, buff_);
 }

 bool ResultSet::isNull(const SQLTypeInfo& ti,
                        const InternalTargetValue& val,
                        const bool float_argument_input) {
   if (ti.get_notnull()) {
     return false;
   }
   if (val.isInt()) {
     return val.i1 == null_val_bit_pattern(ti, float_argument_input);
   }
   if (val.isPair()) {
     return !val.i2 ||
            pair_to_double({val.i1, val.i2}, ti, float_argument_input) == NULL_DOUBLE;
   }
   if (val.isStr()) {
     return !val.i1;
   }
   CHECK(val.isNull());
   return true;
 }
Compression.h

anonymous_namespace{ResultSetIteration.cpp}::GeoLazyFetchHandler::fetch
static auto fetch(const SQLTypeInfo &geo_ti, const ResultSet::GeoReturnType return_type, T &&... vals)
Definition: ResultSetIteration.cpp:892

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

ResultSet::getNextRowImpl
std::vector< TargetValue > getNextRowImpl(const bool translate_strings, const bool decimal_to_double) const
Definition: ResultSetIteration.cpp:320

kENCODING_NONE
Definition: sqltypes.h:225

ResultSet::TargetOffsets
Definition: ResultSet.h:547

InternalTargetValue::isNull
bool isNull() const
Definition: TargetValue.h:69

NULL_DOUBLE
#define NULL_DOUBLE
Definition: InlineNullValues.h:33

InternalTargetValue::isPair
bool isPair() const
Definition: TargetValue.h:67

ExecutorDeviceType::GPU

run_benchmark_import.optional
optional
Definition: run_benchmark_import.py:56

SQLTypeInfo::is_array
bool is_array() const
Definition: sqltypes.h:486

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

anonymous_namespace{ResultSetIteration.cpp}::GeoTargetValueBuilder
Definition: ResultSetIteration.cpp:1016

EMPTY_KEY_64
#define EMPTY_KEY_64
Definition: GpuRtConstants.h:29

kPOLYGON
Definition: sqltypes.h:58

SQLTypeInfo::is_string
bool is_string() const
Definition: sqltypes.h:478

QueryMemoryDescriptor::getSlotCount
size_t getSlotCount() const
Definition: QueryMemoryDescriptor.cpp:1035

Catalog_Namespace::Catalog
class for a per-database catalog. also includes metadata for the current database and the current use...
Definition: Catalog.h:101

kSINGLE_VALUE
Definition: sqldefs.h:80

anonymous_namespace{TypedDataAccessors.h}::decimal_to_double
double decimal_to_double(const SQLTypeInfo &otype, int64_t oval)
Definition: TypedDataAccessors.h:184

ResultSet::getRowWisePerfectHashEntryAt
ENTRY_TYPE getRowWisePerfectHashEntryAt(const size_t row_idx, const size_t target_idx, const size_t slot_idx) const

kARRAY
Definition: sqltypes.h:53

SqlTypesLayout.h

ResultSet::appended_storage_
AppendedStorage appended_storage_
Definition: ResultSet.h:708

ResultSet::getColumnFrag
const std::vector< const int8_t * > & getColumnFrag(const size_t storge_idx, const size_t col_logical_idx, int64_t &global_idx) const
Definition: ResultSetIteration.cpp:1082

ResultSet::geo_return_type_
GeoReturnType geo_return_type_
Definition: ResultSet.h:748

ExecutorDeviceType
ExecutorDeviceType
Definition: CompilationOptions.h:22

QueryDescriptionType::Projection

VarlenDatum::is_null
bool is_null
Definition: sqltypes.h:144

GeoTargetValue
boost::optional< boost::variant< GeoPointTargetValue, GeoLineStringTargetValue, GeoPolyTargetValue, GeoMultiPolyTargetValue > > GeoTargetValue
Definition: TargetValue.h:161

advance_to_next_columnar_target_buff
T advance_to_next_columnar_target_buff(T target_ptr, const QueryMemoryDescriptor &query_mem_desc, const size_t target_slot_idx)
Definition: ResultSetBufferAccessors.h:110

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

ResultSet::GeoReturnType
GeoReturnType
Definition: ResultSet.h:359

TargetInfo::sql_type
SQLTypeInfo sql_type
Definition: TargetInfo.h:42

TargetInfo
Definition: TargetInfo.h:39

QueryMemoryDescriptor
Definition: QueryMemoryDescriptor.h:68

anonymous_namespace{ResultSetIteration.cpp}::build_string_array_target_value
TargetValue build_string_array_target_value(const int32_t *buff, const size_t buff_sz, const int dict_id, const bool translate_strings, std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner, const Catalog_Namespace::Catalog *catalog)
Definition: ResultSetIteration.cpp:794

quantile.h

anonymous_namespace{ResultSetIteration.cpp}::make_bin_search
size_t make_bin_search(size_t l, size_t r, T &&is_empty_fn)
Definition: ResultSetIteration.cpp:2133

SQLTypeInfo::get_array_context_logical_size
int get_array_context_logical_size() const
Definition: sqltypes.h:538

anonymous_namespace{ResultSetIteration.cpp}::lazy_fetch_chunk
std::unique_ptr< ArrayDatum > lazy_fetch_chunk(const int8_t *ptr, const int64_t varlen_ptr)
Definition: ResultSetIteration.cpp:878

ResultSet::catalog_
const Catalog_Namespace::Catalog * catalog_
Definition: ResultSet.h:716

CUdeviceptr
unsigned long long CUdeviceptr
Definition: nocuda.h:27

ResultSet::getRowWiseBaselineEntryAt
ENTRY_TYPE getRowWiseBaselineEntryAt(const size_t row_idx, const size_t target_idx, const size_t slot_idx) const

ResultSet::isNull
static bool isNull(const SQLTypeInfo &ti, const InternalTargetValue &val, const bool float_argument_input)
Definition: ResultSetIteration.cpp:2178

TypePunning.h

ResultSet::query_mem_desc_
QueryMemoryDescriptor query_mem_desc_
Definition: ResultSet.h:706

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

kFLOAT
Definition: sqltypes.h:46

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

ResultSet::GeoReturnType::GeoTargetValueGpuPtr

ResultSet::storage_
std::unique_ptr< ResultSetStorage > storage_
Definition: ResultSet.h:707

ResultSet::isDirectColumnarConversionPossible
bool isDirectColumnarConversionPossible() const
Definition: ResultSet.cpp:973

Geospatial::is_null_point
bool is_null_point(const SQLTypeInfo &geo_ti, const int8_t *coords, const size_t coords_sz)
Definition: Compression.cpp:178

ResultSet::isGeoColOnGpu
bool isGeoColOnGpu(const size_t col_idx) const
Definition: ResultSetIteration.cpp:1424

ResultSet::StorageLookupResult
Definition: ResultSet.h:517

TargetValue.h

sqltypes.h
Constants for Builtin SQL Types supported by OmniSci.

ResultSet::getBufferSizeBytes
size_t getBufferSizeBytes(const ExecutorDeviceType device_type) const
Definition: ResultSetIteration.cpp:757

quantile::detail::TDigest
Definition: quantile.h:181

read_int_from_buff
int64_t read_int_from_buff(const int8_t *ptr, const int8_t compact_sz)
Definition: ResultSetBufferAccessors.h:262

ResultSet::keep_first_
size_t keep_first_
Definition: ResultSet.h:712

QueryDescriptionType::GroupByBaselineHash

anonymous_namespace{ResultSetIteration.cpp}::make_avg_target_value
TargetValue make_avg_target_value(const int8_t *ptr1, const int8_t compact_sz1, const int8_t *ptr2, const int8_t compact_sz2, const TargetInfo &target_info)
Definition: ResultSetIteration.cpp:47

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

GeoReturnTypeTraits
Definition: ResultSetGeoSerialization.h:54

takes_float_argument
bool takes_float_argument(const TargetInfo &target_info)
Definition: TargetInfo.h:134

ResultSet::serialized_varlen_buffer_
std::vector< SerializedVarlenBufferStorage > serialized_varlen_buffer_
Definition: ResultSet.h:739

SQLTypeInfo::get_compression
HOST DEVICE EncodingType get_compression() const
Definition: sqltypes.h:319

anonymous_namespace{ResultSetIteration.cpp}::make_vals_vector
std::vector< std::pair< const int8_t *, const int64_t > > make_vals_vector(std::index_sequence< indices... >, const Tuple &tuple)
Definition: ResultSetIteration.cpp:871

ResultSet::getNextRowUnlocked
std::vector< TargetValue > getNextRowUnlocked(const bool translate_strings, const bool decimal_to_double) const
Definition: ResultSetIteration.cpp:307

advance_target_ptr_row_wise
T advance_target_ptr_row_wise(T target_ptr, const TargetInfo &target_info, const size_t slot_idx, const QueryMemoryDescriptor &query_mem_desc, const bool separate_varlen_storage)
Definition: ResultSetBufferAccessors.h:150

CHECK_GT
#define CHECK_GT(x, y)
Definition: Logger.h:209

null_val_bit_pattern
int64_t null_val_bit_pattern(const SQLTypeInfo &ti, const bool float_argument_input)
Definition: ResultSetBufferAccessors.h:242

ChunkIter_get_nth
DEVICE void ChunkIter_get_nth(ChunkIter *it, int n, bool uncompress, VarlenDatum *result, bool *is_end)
Definition: ChunkIter.cpp:181

anonymous_namespace{ResultSetIteration.cpp}::GeoTargetValueBuilder::build
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TargetValue build_array_target_value(const SQLTypeInfo &array_ti, const int8_t *buff, const size_t buff_sz, const bool translate_strings, std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner, const Catalog_Namespace::Catalog *catalog)
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Definition: ResultSetIteration.cpp:2154

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Definition: QueryMemoryDescriptor.h:184

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Basic constructors and methods of the row set interface.

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Definition: ResultSetIteration.cpp:733

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Definition: ResultSetIteration.cpp:957

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const CountDistinctDescriptor & getCountDistinctDescriptor(const size_t idx) const
Definition: QueryMemoryDescriptor.h:253

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advance_target_ptr_col_wise
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Definition: sqldefs.h:74

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Definition: sqldefs.h:72

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Definition: ResultSetIteration.cpp:498

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Definition: QueryMemoryDescriptor.h:244

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Definition: QueryMemoryDescriptor.h:170

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FORCE_INLINE HOST DEVICE T align_to_int64(T addr)
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Definition: QueryMemoryDescriptor.cpp:829

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Definition: StringDictionaryProxy.h:29

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Definition: QueryMemoryDescriptor.h:314

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