_execute_8cpp_source.html

 /*

  * Copyright 2020 OmniSci, Inc.

  *

  * Licensed under the Apache License, Version 2.0 (the "License");

  * you may not use this file except in compliance with the License.

  * You may obtain a copy of the License at

  *

  *     http://www.apache.org/licenses/LICENSE-2.0

  *

  * Unless required by applicable law or agreed to in writing, software

  * distributed under the License is distributed on an "AS IS" BASIS,

  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.

  * See the License for the specific language governing permissions and

  * limitations under the License.

  */


 #include "Execute.h"


 #include "AggregateUtils.h"

 #include "BaselineJoinHashTable.h"

 #include "CodeGenerator.h"

 #include "ColumnFetcher.h"

 #include "Descriptors/QueryCompilationDescriptor.h"

 #include "Descriptors/QueryFragmentDescriptor.h"

 #include "DynamicWatchdog.h"

 #include "EquiJoinCondition.h"

 #include "ErrorHandling.h"

 #include "ExpressionRewrite.h"

 #include "ExternalCacheInvalidators.h"

 #include "GpuMemUtils.h"

 #include "InPlaceSort.h"

 #include "JsonAccessors.h"

 #include "OutputBufferInitialization.h"

 #include "OverlapsJoinHashTable.h"

 #include "QueryRewrite.h"

 #include "QueryTemplateGenerator.h"

 #include "ResultSetReductionJIT.h"

 #include "RuntimeFunctions.h"

 #include "SpeculativeTopN.h"


 #include "TableFunctions/TableFunctionCompilationContext.h"

 #include "TableFunctions/TableFunctionExecutionContext.h"


 #include "CudaMgr/CudaMgr.h"

 #include "DataMgr/BufferMgr/BufferMgr.h"

 #include "Parser/ParserNode.h"

 #include "Shared/SystemParameters.h"

 #include "Shared/TypedDataAccessors.h"

 #include "Shared/checked_alloc.h"

 #include "Shared/measure.h"

 #include "Shared/misc.h"

 #include "Shared/scope.h"

 #include "Shared/shard_key.h"

 #include "Shared/sql_type_to_string.h"

 #include "Shared/threadpool.h"


 #include "AggregatedColRange.h"

 #include "StringDictionaryGenerations.h"


 #include <llvm/Transforms/Utils/BasicBlockUtils.h>

 #include <boost/filesystem/operations.hpp>

 #include <boost/filesystem/path.hpp>


 #ifdef HAVE_CUDA

 #include <cuda.h>

 #endif  // HAVE_CUDA

 #include <future>

 #include <memory>

 #include <numeric>

 #include <set>

 #include <thread>


 bool g_enable_watchdog{false};

 bool g_enable_dynamic_watchdog{false};

 bool g_use_tbb_pool{false};

 unsigned g_dynamic_watchdog_time_limit{10000};

 bool g_allow_cpu_retry{true};

 bool g_null_div_by_zero{false};

 unsigned g_trivial_loop_join_threshold{1000};

 bool g_from_table_reordering{true};

 bool g_inner_join_fragment_skipping{true};

 extern bool g_enable_smem_group_by;

 extern std::unique_ptr<llvm::Module> udf_gpu_module;

 extern std::unique_ptr<llvm::Module> udf_cpu_module;

 bool g_enable_filter_push_down{false};

 float g_filter_push_down_low_frac{-1.0f};

 float g_filter_push_down_high_frac{-1.0f};

 size_t g_filter_push_down_passing_row_ubound{0};

 bool g_enable_columnar_output{false};

 bool g_enable_overlaps_hashjoin{false};

 bool g_enable_hashjoin_many_to_many{false};

 bool g_cache_string_hash{false};

 size_t g_overlaps_max_table_size_bytes{1024 * 1024 * 1024};

 bool g_strip_join_covered_quals{false};

 size_t g_constrained_by_in_threshold{10};

 size_t g_big_group_threshold{20000};

 bool g_enable_window_functions{true};

 bool g_enable_table_functions{false};

 size_t g_max_memory_allocation_size{2000000000};  // set to max slab size

 size_t g_min_memory_allocation_size{

     256};  // minimum memory allocation required for projection query output buffer

            // without pre-flight count

 bool g_enable_bump_allocator{false};

 double g_bump_allocator_step_reduction{0.75};

 bool g_enable_direct_columnarization{true};

 extern bool g_enable_experimental_string_functions;

 bool g_enable_runtime_query_interrupt{false};

 unsigned g_runtime_query_interrupt_frequency{1000};

 size_t g_gpu_smem_threshold{

     4096};  // GPU shared memory threshold (in bytes), if larger buffer sizes are required

             // we do not use GPU shared memory optimizations

 bool g_enable_smem_non_grouped_agg{

     true};  // enable optimizations for using GPU shared memory in implementation of

             // non-grouped aggregates

 bool g_is_test_env{false};  // operating under a unit test environment. Currently only

                             // limits the allocation for the output buffer arena


 int const Executor::max_gpu_count;


 const int32_t Executor::ERR_SINGLE_VALUE_FOUND_MULTIPLE_VALUES;


 Executor::Executor(const int db_id,

                    const size_t block_size_x,

                    const size_t grid_size_x,

                    const std::string& debug_dir,

                    const std::string& debug_file)

     : cgen_state_(new CgenState({}, false))

     , gpu_active_modules_device_mask_(0x0)

     , interrupted_(false)

     , cpu_code_cache_(code_cache_size)

     , gpu_code_cache_(code_cache_size)

     , block_size_x_(block_size_x)

     , grid_size_x_(grid_size_x)

     , debug_dir_(debug_dir)

     , debug_file_(debug_file)

     , db_id_(db_id)

     , catalog_(nullptr)

     , temporary_tables_(nullptr)

     , input_table_info_cache_(this) {}


 std::shared_ptr<Executor> Executor::getExecutor(

     const int db_id,

     const std::string& debug_dir,

     const std::string& debug_file,

     const SystemParameters system_parameters) {

   INJECT_TIMER(getExecutor);

   const auto executor_key = db_id;

   {

     mapd_shared_lock<mapd_shared_mutex> read_lock(executors_cache_mutex_);

     auto it = executors_.find(executor_key);

     if (it != executors_.end()) {

       return it->second;

     }

   }

   {

     mapd_unique_lock<mapd_shared_mutex> write_lock(executors_cache_mutex_);

     auto it = executors_.find(executor_key);

     if (it != executors_.end()) {

       return it->second;

     }

     auto executor = std::make_shared<Executor>(db_id,

                                                system_parameters.cuda_block_size,

                                                system_parameters.cuda_grid_size,

                                                debug_dir,

                                                debug_file);

     auto it_ok = executors_.insert(std::make_pair(executor_key, executor));

     CHECK(it_ok.second);

     return executor;

   }

 }


 void Executor::clearMemory(const Data_Namespace::MemoryLevel memory_level) {

   switch (memory_level) {

     case Data_Namespace::MemoryLevel::CPU_LEVEL:

     case Data_Namespace::MemoryLevel::GPU_LEVEL: {

       std::lock_guard<std::mutex> flush_lock(

           execute_mutex_);  // Don't flush memory while queries are running


       Catalog_Namespace::SysCatalog::instance().getDataMgr().clearMemory(memory_level);

       if (memory_level == Data_Namespace::MemoryLevel::CPU_LEVEL) {

         // The hash table cache uses CPU memory not managed by the buffer manager. In the

         // future, we should manage these allocations with the buffer manager directly.

         // For now, assume the user wants to purge the hash table cache when they clear

         // CPU memory (currently used in ExecuteTest to lower memory pressure)

         JoinHashTableCacheInvalidator::invalidateCaches();

       }

       break;

     }

     default: {

       throw std::runtime_error(

           "Clearing memory levels other than the CPU level or GPU level is not "

           "supported.");

     }

   }

 }


 size_t Executor::getArenaBlockSize() {

   return g_is_test_env ? 100000000 : (1UL << 32) + kArenaBlockOverhead;

 }


 StringDictionaryProxy* Executor::getStringDictionaryProxy(

     const int dict_id_in,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     const bool with_generation) const {

   const int dict_id{dict_id_in < 0 ? REGULAR_DICT(dict_id_in) : dict_id_in};

   CHECK(catalog_);

   const auto dd = catalog_->getMetadataForDict(dict_id);

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

   if (dd) {

     CHECK(dd->stringDict);

     CHECK_LE(dd->dictNBits, 32);

     CHECK(row_set_mem_owner);

     const auto generation = with_generation

                                 ? string_dictionary_generations_.getGeneration(dict_id)

                                 : ssize_t(-1);

     return row_set_mem_owner->addStringDict(dd->stringDict, dict_id, generation);

   }

   CHECK_EQ(0, dict_id);

   if (!lit_str_dict_proxy_) {

     std::shared_ptr<StringDictionary> tsd =

         std::make_shared<StringDictionary>("", false, true, g_cache_string_hash);

     lit_str_dict_proxy_.reset(new StringDictionaryProxy(tsd, 0));

   }

   return lit_str_dict_proxy_.get();

 }


 bool Executor::isCPUOnly() const {

   CHECK(catalog_);

   return !catalog_->getDataMgr().getCudaMgr();

 }


 const ColumnDescriptor* Executor::getColumnDescriptor(

     const Analyzer::ColumnVar* col_var) const {

   return get_column_descriptor_maybe(

       col_var->get_column_id(), col_var->get_table_id(), *catalog_);

 }


 const ColumnDescriptor* Executor::getPhysicalColumnDescriptor(

     const Analyzer::ColumnVar* col_var,

     int n) const {

   const auto cd = getColumnDescriptor(col_var);

   if (!cd || n > cd->columnType.get_physical_cols()) {

     return nullptr;

   }

   return get_column_descriptor_maybe(

       col_var->get_column_id() + n, col_var->get_table_id(), *catalog_);

 }


 const Catalog_Namespace::Catalog* Executor::getCatalog() const {

   return catalog_;

 }


 void Executor::setCatalog(const Catalog_Namespace::Catalog* catalog) {

   catalog_ = catalog;

 }


 const std::shared_ptr<RowSetMemoryOwner> Executor::getRowSetMemoryOwner() const {

   return row_set_mem_owner_;

 }


 const TemporaryTables* Executor::getTemporaryTables() const {

   return temporary_tables_;

 }


 Fragmenter_Namespace::TableInfo Executor::getTableInfo(const int table_id) const {

   return input_table_info_cache_.getTableInfo(table_id);

 }


 const TableGeneration& Executor::getTableGeneration(const int table_id) const {

   return table_generations_.getGeneration(table_id);

 }


 ExpressionRange Executor::getColRange(const PhysicalInput& phys_input) const {

   return agg_col_range_cache_.getColRange(phys_input);

 }


 size_t Executor::getNumBytesForFetchedRow() const {

   size_t num_bytes = 0;

   if (!plan_state_) {

     return 0;

   }

   for (const auto& fetched_col_pair : plan_state_->columns_to_fetch_) {

     if (fetched_col_pair.first < 0) {

       num_bytes += 8;

     } else {

       const auto cd =

           catalog_->getMetadataForColumn(fetched_col_pair.first, fetched_col_pair.second);

       const auto& ti = cd->columnType;

       const auto sz = ti.get_type() == kTEXT && ti.get_compression() == kENCODING_DICT

                           ? 4

                           : ti.get_size();

       if (sz < 0) {

         // for varlen types, only account for the pointer/size for each row, for now

         num_bytes += 16;

       } else {

         num_bytes += sz;

       }

     }

   }

   return num_bytes;

 }


 std::vector<ColumnLazyFetchInfo> Executor::getColLazyFetchInfo(

     const std::vector<Analyzer::Expr*>& target_exprs) const {

   CHECK(plan_state_);

   CHECK(catalog_);

   std::vector<ColumnLazyFetchInfo> col_lazy_fetch_info;

   for (const auto target_expr : target_exprs) {

     if (!plan_state_->isLazyFetchColumn(target_expr)) {

       col_lazy_fetch_info.emplace_back(

           ColumnLazyFetchInfo{false, -1, SQLTypeInfo(kNULLT, false)});

     } else {

       const auto col_var = dynamic_cast<const Analyzer::ColumnVar*>(target_expr);

       CHECK(col_var);

       auto col_id = col_var->get_column_id();

       auto rte_idx = (col_var->get_rte_idx() == -1) ? 0 : col_var->get_rte_idx();

       auto cd = (col_var->get_table_id() > 0)

                     ? get_column_descriptor(col_id, col_var->get_table_id(), *catalog_)

                     : nullptr;

       if (cd && IS_GEO(cd->columnType.get_type())) {

         // Geo coords cols will be processed in sequence. So we only need to track the

         // first coords col in lazy fetch info.

         {

           auto cd0 =

               get_column_descriptor(col_id + 1, col_var->get_table_id(), *catalog_);

           auto col0_ti = cd0->columnType;

           CHECK(!cd0->isVirtualCol);

           auto col0_var = makeExpr<Analyzer::ColumnVar>(

               col0_ti, col_var->get_table_id(), cd0->columnId, rte_idx);

           auto local_col0_id = plan_state_->getLocalColumnId(col0_var.get(), false);

           col_lazy_fetch_info.emplace_back(

               ColumnLazyFetchInfo{true, local_col0_id, col0_ti});

         }

       } else {

         auto local_col_id = plan_state_->getLocalColumnId(col_var, false);

         const auto& col_ti = col_var->get_type_info();

         col_lazy_fetch_info.emplace_back(ColumnLazyFetchInfo{true, local_col_id, col_ti});

       }

     }

   }

   return col_lazy_fetch_info;

 }


 void Executor::clearMetaInfoCache() {

   input_table_info_cache_.clear();

   agg_col_range_cache_.clear();

   string_dictionary_generations_.clear();

   table_generations_.clear();

 }


 std::vector<int8_t> Executor::serializeLiterals(

     const std::unordered_map<int, CgenState::LiteralValues>& literals,

     const int device_id) {

   if (literals.empty()) {

     return {};

   }

   const auto dev_literals_it = literals.find(device_id);

   CHECK(dev_literals_it != literals.end());

   const auto& dev_literals = dev_literals_it->second;

   size_t lit_buf_size{0};

   std::vector<std::string> real_strings;

   std::vector<std::vector<double>> double_array_literals;

   std::vector<std::vector<int8_t>> align64_int8_array_literals;

   std::vector<std::vector<int32_t>> int32_array_literals;

   std::vector<std::vector<int8_t>> align32_int8_array_literals;

   std::vector<std::vector<int8_t>> int8_array_literals;

   for (const auto& lit : dev_literals) {

     lit_buf_size = CgenState::addAligned(lit_buf_size, CgenState::literalBytes(lit));

     if (lit.which() == 7) {

       const auto p = boost::get<std::string>(&lit);

       CHECK(p);

       real_strings.push_back(*p);

     } else if (lit.which() == 8) {

       const auto p = boost::get<std::vector<double>>(&lit);

       CHECK(p);

       double_array_literals.push_back(*p);

     } else if (lit.which() == 9) {

       const auto p = boost::get<std::vector<int32_t>>(&lit);

       CHECK(p);

       int32_array_literals.push_back(*p);

     } else if (lit.which() == 10) {

       const auto p = boost::get<std::vector<int8_t>>(&lit);

       CHECK(p);

       int8_array_literals.push_back(*p);

     } else if (lit.which() == 11) {

       const auto p = boost::get<std::pair<std::vector<int8_t>, int>>(&lit);

       CHECK(p);

       if (p->second == 64) {

         align64_int8_array_literals.push_back(p->first);

       } else if (p->second == 32) {

         align32_int8_array_literals.push_back(p->first);

       } else {

         CHECK(false);

       }

     }

   }

   if (lit_buf_size > static_cast<size_t>(std::numeric_limits<int16_t>::max())) {

     throw TooManyLiterals();

   }

   int16_t crt_real_str_off = lit_buf_size;

   for (const auto& real_str : real_strings) {

     CHECK_LE(real_str.size(), static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += real_str.size();

   }

   if (double_array_literals.size() > 0) {

     lit_buf_size = align(lit_buf_size, sizeof(double));

   }

   int16_t crt_double_arr_lit_off = lit_buf_size;

   for (const auto& double_array_literal : double_array_literals) {

     CHECK_LE(double_array_literal.size(),

              static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += double_array_literal.size() * sizeof(double);

   }

   if (align64_int8_array_literals.size() > 0) {

     lit_buf_size = align(lit_buf_size, sizeof(uint64_t));

   }

   int16_t crt_align64_int8_arr_lit_off = lit_buf_size;

   for (const auto& align64_int8_array_literal : align64_int8_array_literals) {

     CHECK_LE(align64_int8_array_literals.size(),

              static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += align64_int8_array_literal.size();

   }

   if (int32_array_literals.size() > 0) {

     lit_buf_size = align(lit_buf_size, sizeof(int32_t));

   }

   int16_t crt_int32_arr_lit_off = lit_buf_size;

   for (const auto& int32_array_literal : int32_array_literals) {

     CHECK_LE(int32_array_literal.size(),

              static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += int32_array_literal.size() * sizeof(int32_t);

   }

   if (align32_int8_array_literals.size() > 0) {

     lit_buf_size = align(lit_buf_size, sizeof(int32_t));

   }

   int16_t crt_align32_int8_arr_lit_off = lit_buf_size;

   for (const auto& align32_int8_array_literal : align32_int8_array_literals) {

     CHECK_LE(align32_int8_array_literals.size(),

              static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += align32_int8_array_literal.size();

   }

   int16_t crt_int8_arr_lit_off = lit_buf_size;

   for (const auto& int8_array_literal : int8_array_literals) {

     CHECK_LE(int8_array_literal.size(),

              static_cast<size_t>(std::numeric_limits<int16_t>::max()));

     lit_buf_size += int8_array_literal.size();

   }

   unsigned crt_real_str_idx = 0;

   unsigned crt_double_arr_lit_idx = 0;

   unsigned crt_align64_int8_arr_lit_idx = 0;

   unsigned crt_int32_arr_lit_idx = 0;

   unsigned crt_align32_int8_arr_lit_idx = 0;

   unsigned crt_int8_arr_lit_idx = 0;

   std::vector<int8_t> serialized(lit_buf_size);

   size_t off{0};

   for (const auto& lit : dev_literals) {

     const auto lit_bytes = CgenState::literalBytes(lit);

     off = CgenState::addAligned(off, lit_bytes);

     switch (lit.which()) {

       case 0: {

         const auto p = boost::get<int8_t>(&lit);

         CHECK(p);

         serialized[off - lit_bytes] = *p;

         break;

       }

       case 1: {

         const auto p = boost::get<int16_t>(&lit);

         CHECK(p);

         memcpy(&serialized[off - lit_bytes], p, lit_bytes);

         break;

       }

       case 2: {

         const auto p = boost::get<int32_t>(&lit);

         CHECK(p);

         memcpy(&serialized[off - lit_bytes], p, lit_bytes);

         break;

       }

       case 3: {

         const auto p = boost::get<int64_t>(&lit);

         CHECK(p);

         memcpy(&serialized[off - lit_bytes], p, lit_bytes);

         break;

       }

       case 4: {

         const auto p = boost::get<float>(&lit);

         CHECK(p);

         memcpy(&serialized[off - lit_bytes], p, lit_bytes);

         break;

       }

       case 5: {

         const auto p = boost::get<double>(&lit);

         CHECK(p);

         memcpy(&serialized[off - lit_bytes], p, lit_bytes);

         break;

       }

       case 6: {

         const auto p = boost::get<std::pair<std::string, int>>(&lit);

         CHECK(p);

         const auto str_id =

             g_enable_experimental_string_functions

                 ? getStringDictionaryProxy(p->second, row_set_mem_owner_, true)

                       ->getOrAddTransient(p->first)

                 : getStringDictionaryProxy(p->second, row_set_mem_owner_, true)

                       ->getIdOfString(p->first);

         memcpy(&serialized[off - lit_bytes], &str_id, lit_bytes);

         break;

       }

       case 7: {

         const auto p = boost::get<std::string>(&lit);

         CHECK(p);

         int32_t off_and_len = crt_real_str_off << 16;

         const auto& crt_real_str = real_strings[crt_real_str_idx];

         off_and_len |= static_cast<int16_t>(crt_real_str.size());

         memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

         memcpy(&serialized[crt_real_str_off], crt_real_str.data(), crt_real_str.size());

         ++crt_real_str_idx;

         crt_real_str_off += crt_real_str.size();

         break;

       }

       case 8: {

         const auto p = boost::get<std::vector<double>>(&lit);

         CHECK(p);

         int32_t off_and_len = crt_double_arr_lit_off << 16;

         const auto& crt_double_arr_lit = double_array_literals[crt_double_arr_lit_idx];

         int32_t len = crt_double_arr_lit.size();

         CHECK_EQ((len >> 16), 0);

         off_and_len |= static_cast<int16_t>(len);

         int32_t double_array_bytesize = len * sizeof(double);

         memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

         memcpy(&serialized[crt_double_arr_lit_off],

                crt_double_arr_lit.data(),

                double_array_bytesize);

         ++crt_double_arr_lit_idx;

         crt_double_arr_lit_off += double_array_bytesize;

         break;

       }

       case 9: {

         const auto p = boost::get<std::vector<int32_t>>(&lit);

         CHECK(p);

         int32_t off_and_len = crt_int32_arr_lit_off << 16;

         const auto& crt_int32_arr_lit = int32_array_literals[crt_int32_arr_lit_idx];

         int32_t len = crt_int32_arr_lit.size();

         CHECK_EQ((len >> 16), 0);

         off_and_len |= static_cast<int16_t>(len);

         int32_t int32_array_bytesize = len * sizeof(int32_t);

         memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

         memcpy(&serialized[crt_int32_arr_lit_off],

                crt_int32_arr_lit.data(),

                int32_array_bytesize);

         ++crt_int32_arr_lit_idx;

         crt_int32_arr_lit_off += int32_array_bytesize;

         break;

       }

       case 10: {

         const auto p = boost::get<std::vector<int8_t>>(&lit);

         CHECK(p);

         int32_t off_and_len = crt_int8_arr_lit_off << 16;

         const auto& crt_int8_arr_lit = int8_array_literals[crt_int8_arr_lit_idx];

         int32_t len = crt_int8_arr_lit.size();

         CHECK_EQ((len >> 16), 0);

         off_and_len |= static_cast<int16_t>(len);

         int32_t int8_array_bytesize = len;

         memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

         memcpy(&serialized[crt_int8_arr_lit_off],

                crt_int8_arr_lit.data(),

                int8_array_bytesize);

         ++crt_int8_arr_lit_idx;

         crt_int8_arr_lit_off += int8_array_bytesize;

         break;

       }

       case 11: {

         const auto p = boost::get<std::pair<std::vector<int8_t>, int>>(&lit);

         CHECK(p);

         if (p->second == 64) {

           int32_t off_and_len = crt_align64_int8_arr_lit_off << 16;

           const auto& crt_align64_int8_arr_lit =

               align64_int8_array_literals[crt_align64_int8_arr_lit_idx];

           int32_t len = crt_align64_int8_arr_lit.size();

           CHECK_EQ((len >> 16), 0);

           off_and_len |= static_cast<int16_t>(len);

           int32_t align64_int8_array_bytesize = len;

           memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

           memcpy(&serialized[crt_align64_int8_arr_lit_off],

                  crt_align64_int8_arr_lit.data(),

                  align64_int8_array_bytesize);

           ++crt_align64_int8_arr_lit_idx;

           crt_align64_int8_arr_lit_off += align64_int8_array_bytesize;

         } else if (p->second == 32) {

           int32_t off_and_len = crt_align32_int8_arr_lit_off << 16;

           const auto& crt_align32_int8_arr_lit =

               align32_int8_array_literals[crt_align32_int8_arr_lit_idx];

           int32_t len = crt_align32_int8_arr_lit.size();

           CHECK_EQ((len >> 16), 0);

           off_and_len |= static_cast<int16_t>(len);

           int32_t align32_int8_array_bytesize = len;

           memcpy(&serialized[off - lit_bytes], &off_and_len, lit_bytes);

           memcpy(&serialized[crt_align32_int8_arr_lit_off],

                  crt_align32_int8_arr_lit.data(),

                  align32_int8_array_bytesize);

           ++crt_align32_int8_arr_lit_idx;

           crt_align32_int8_arr_lit_off += align32_int8_array_bytesize;

         } else {

           CHECK(false);

         }

         break;

       }

       default:

         CHECK(false);

     }

   }

   return serialized;

 }


 int Executor::deviceCount(const ExecutorDeviceType device_type) const {

   if (device_type == ExecutorDeviceType::GPU) {

     const auto cuda_mgr = catalog_->getDataMgr().getCudaMgr();

     CHECK(cuda_mgr);

     return cuda_mgr->getDeviceCount();

   } else {

     return 1;

   }

 }


 int Executor::deviceCountForMemoryLevel(

     const Data_Namespace::MemoryLevel memory_level) const {

   return memory_level == GPU_LEVEL ? deviceCount(ExecutorDeviceType::GPU)

                                    : deviceCount(ExecutorDeviceType::CPU);

 }


 // TODO(alex): remove or split

 std::pair<int64_t, int32_t> Executor::reduceResults(const SQLAgg agg,

                                                     const SQLTypeInfo& ti,

                                                     const int64_t agg_init_val,

                                                     const int8_t out_byte_width,

                                                     const int64_t* out_vec,

                                                     const size_t out_vec_sz,

                                                     const bool is_group_by,

                                                     const bool float_argument_input) {

   switch (agg) {

     case kAVG:

     case kSUM:

       if (0 != agg_init_val) {

         if (ti.is_integer() || ti.is_decimal() || ti.is_time() || ti.is_boolean()) {

           int64_t agg_result = agg_init_val;

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

             agg_sum_skip_val(&agg_result, out_vec[i], agg_init_val);

           }

           return {agg_result, 0};

         } else {

           CHECK(ti.is_fp());

           switch (out_byte_width) {

             case 4: {

               int agg_result = static_cast<int32_t>(agg_init_val);

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

                 agg_sum_float_skip_val(

                     &agg_result,

                     *reinterpret_cast<const float*>(may_alias_ptr(&out_vec[i])),

                     *reinterpret_cast<const float*>(may_alias_ptr(&agg_init_val)));

               }

               const int64_t converted_bin =

                   float_argument_input

                       ? static_cast<int64_t>(agg_result)

                       : float_to_double_bin(static_cast<int32_t>(agg_result), true);

               return {converted_bin, 0};

               break;

             }

             case 8: {

               int64_t agg_result = agg_init_val;

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

                 agg_sum_double_skip_val(

                     &agg_result,

                     *reinterpret_cast<const double*>(may_alias_ptr(&out_vec[i])),

                     *reinterpret_cast<const double*>(may_alias_ptr(&agg_init_val)));

               }

               return {agg_result, 0};

               break;

             }

             default:

               CHECK(false);

           }

         }

       }

       if (ti.is_integer() || ti.is_decimal() || ti.is_time()) {

         int64_t agg_result = 0;

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

           agg_result += out_vec[i];

         }

         return {agg_result, 0};

       } else {

         CHECK(ti.is_fp());

         switch (out_byte_width) {

           case 4: {

             float r = 0.;

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

               r += *reinterpret_cast<const float*>(may_alias_ptr(&out_vec[i]));

             }

             const auto float_bin = *reinterpret_cast<const int32_t*>(may_alias_ptr(&r));

             const int64_t converted_bin =

                 float_argument_input ? float_bin : float_to_double_bin(float_bin, true);

             return {converted_bin, 0};

           }

           case 8: {

             double r = 0.;

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

               r += *reinterpret_cast<const double*>(may_alias_ptr(&out_vec[i]));

             }

             return {*reinterpret_cast<const int64_t*>(may_alias_ptr(&r)), 0};

           }

           default:

             CHECK(false);

         }

       }

       break;

     case kCOUNT: {

       uint64_t agg_result = 0;

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

         const uint64_t out = static_cast<uint64_t>(out_vec[i]);

         agg_result += out;

       }

       return {static_cast<int64_t>(agg_result), 0};

     }

     case kMIN: {

       if (ti.is_integer() || ti.is_decimal() || ti.is_time() || ti.is_boolean()) {

         int64_t agg_result = agg_init_val;

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

           agg_min_skip_val(&agg_result, out_vec[i], agg_init_val);

         }

         return {agg_result, 0};

       } else {

         switch (out_byte_width) {

           case 4: {

             int32_t agg_result = static_cast<int32_t>(agg_init_val);

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

               agg_min_float_skip_val(

                   &agg_result,

                   *reinterpret_cast<const float*>(may_alias_ptr(&out_vec[i])),

                   *reinterpret_cast<const float*>(may_alias_ptr(&agg_init_val)));

             }

             const int64_t converted_bin =

                 float_argument_input

                     ? static_cast<int64_t>(agg_result)

                     : float_to_double_bin(static_cast<int32_t>(agg_result), true);

             return {converted_bin, 0};

           }

           case 8: {

             int64_t agg_result = agg_init_val;

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

               agg_min_double_skip_val(

                   &agg_result,

                   *reinterpret_cast<const double*>(may_alias_ptr(&out_vec[i])),

                   *reinterpret_cast<const double*>(may_alias_ptr(&agg_init_val)));

             }

             return {agg_result, 0};

           }

           default:

             CHECK(false);

         }

       }

     }

     case kMAX:

       if (ti.is_integer() || ti.is_decimal() || ti.is_time() || ti.is_boolean()) {

         int64_t agg_result = agg_init_val;

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

           agg_max_skip_val(&agg_result, out_vec[i], agg_init_val);

         }

         return {agg_result, 0};

       } else {

         switch (out_byte_width) {

           case 4: {

             int32_t agg_result = static_cast<int32_t>(agg_init_val);

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

               agg_max_float_skip_val(

                   &agg_result,

                   *reinterpret_cast<const float*>(may_alias_ptr(&out_vec[i])),

                   *reinterpret_cast<const float*>(may_alias_ptr(&agg_init_val)));

             }

             const int64_t converted_bin =

                 float_argument_input ? static_cast<int64_t>(agg_result)

                                      : float_to_double_bin(agg_result, !ti.get_notnull());

             return {converted_bin, 0};

           }

           case 8: {

             int64_t agg_result = agg_init_val;

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

               agg_max_double_skip_val(

                   &agg_result,

                   *reinterpret_cast<const double*>(may_alias_ptr(&out_vec[i])),

                   *reinterpret_cast<const double*>(may_alias_ptr(&agg_init_val)));

             }

             return {agg_result, 0};

           }

           default:

             CHECK(false);

         }

       }

     case kSINGLE_VALUE: {

       int64_t agg_result = agg_init_val;

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

         if (out_vec[i] != agg_init_val) {

           if (agg_result == agg_init_val) {

             agg_result = out_vec[i];

           } else if (out_vec[i] != agg_result) {

             return {agg_result, Executor::ERR_SINGLE_VALUE_FOUND_MULTIPLE_VALUES};

           }

         }

       }

       return {agg_result, 0};

     }

     case kSAMPLE: {

       int64_t agg_result = agg_init_val;

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

         if (out_vec[i] != agg_init_val) {

           agg_result = out_vec[i];

           break;

         }

       }

       return {agg_result, 0};

     }

     default:

       CHECK(false);

   }

   abort();

 }


 namespace {


 ResultSetPtr get_merged_result(

     std::vector<std::pair<ResultSetPtr, std::vector<size_t>>>& results_per_device) {

   auto& first = results_per_device.front().first;

   CHECK(first);

   for (size_t dev_idx = 1; dev_idx < results_per_device.size(); ++dev_idx) {

     const auto& next = results_per_device[dev_idx].first;

     CHECK(next);

     first->append(*next);

   }

   return std::move(first);

 }


 }  // namespace


 ResultSetPtr Executor::resultsUnion(ExecutionDispatch& execution_dispatch) {

   auto& results_per_device = execution_dispatch.getFragmentResults();

   if (results_per_device.empty()) {

     const auto& ra_exe_unit = execution_dispatch.getExecutionUnit();

     std::vector<TargetInfo> targets;

     for (const auto target_expr : ra_exe_unit.target_exprs) {

       targets.push_back(get_target_info(target_expr, g_bigint_count));

     }

     return std::make_shared<ResultSet>(targets,

                                        ExecutorDeviceType::CPU,

                                        QueryMemoryDescriptor(),

                                        row_set_mem_owner_,

                                        this);

   }

   using IndexedResultSet = std::pair<ResultSetPtr, std::vector<size_t>>;

   std::sort(results_per_device.begin(),

             results_per_device.end(),

             [](const IndexedResultSet& lhs, const IndexedResultSet& rhs) {

               CHECK_GE(lhs.second.size(), size_t(1));

               CHECK_GE(rhs.second.size(), size_t(1));

               return lhs.second.front() < rhs.second.front();

             });


   return get_merged_result(results_per_device);

 }


 ResultSetPtr Executor::reduceMultiDeviceResults(

     const RelAlgExecutionUnit& ra_exe_unit,

     std::vector<std::pair<ResultSetPtr, std::vector<size_t>>>& results_per_device,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     const QueryMemoryDescriptor& query_mem_desc) const {

   auto timer = DEBUG_TIMER(__func__);

   if (ra_exe_unit.estimator) {

     return reduce_estimator_results(ra_exe_unit, results_per_device);

   }


   if (results_per_device.empty()) {

     std::vector<TargetInfo> targets;

     for (const auto target_expr : ra_exe_unit.target_exprs) {

       targets.push_back(get_target_info(target_expr, g_bigint_count));

     }

     return std::make_shared<ResultSet>(

         targets, ExecutorDeviceType::CPU, QueryMemoryDescriptor(), nullptr, this);

   }


   return reduceMultiDeviceResultSets(

       results_per_device,

       row_set_mem_owner,

       ResultSet::fixupQueryMemoryDescriptor(query_mem_desc));

 }


 ResultSetPtr Executor::reduceMultiDeviceResultSets(

     std::vector<std::pair<ResultSetPtr, std::vector<size_t>>>& results_per_device,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     const QueryMemoryDescriptor& query_mem_desc) const {

   auto timer = DEBUG_TIMER(__func__);

   std::shared_ptr<ResultSet> reduced_results;


   const auto& first = results_per_device.front().first;


   if (query_mem_desc.getQueryDescriptionType() ==

           QueryDescriptionType::GroupByBaselineHash &&

       results_per_device.size() > 1) {

     const auto total_entry_count = std::accumulate(

         results_per_device.begin(),

         results_per_device.end(),

         size_t(0),

         [](const size_t init, const std::pair<ResultSetPtr, std::vector<size_t>>& rs) {

           const auto& r = rs.first;

           return init + r->getQueryMemDesc().getEntryCount();

         });

     CHECK(total_entry_count);

     auto query_mem_desc = first->getQueryMemDesc();

     query_mem_desc.setEntryCount(total_entry_count);

     reduced_results = std::make_shared<ResultSet>(first->getTargetInfos(),

                                                   ExecutorDeviceType::CPU,

                                                   query_mem_desc,

                                                   row_set_mem_owner,

                                                   this);

     auto result_storage = reduced_results->allocateStorage(plan_state_->init_agg_vals_);

     reduced_results->initializeStorage();

     switch (query_mem_desc.getEffectiveKeyWidth()) {

       case 4:

         first->getStorage()->moveEntriesToBuffer<int32_t>(

             result_storage->getUnderlyingBuffer(), query_mem_desc.getEntryCount());

         break;

       case 8:

         first->getStorage()->moveEntriesToBuffer<int64_t>(

             result_storage->getUnderlyingBuffer(), query_mem_desc.getEntryCount());

         break;

       default:

         CHECK(false);

     }

   } else {

     reduced_results = first;

   }


   const auto& this_result_set = results_per_device[0].first;

   ResultSetReductionJIT reduction_jit(this_result_set->getQueryMemDesc(),

                                       this_result_set->getTargetInfos(),

                                       this_result_set->getTargetInitVals());

   const auto reduction_code = reduction_jit.codegen();

   for (size_t i = 1; i < results_per_device.size(); ++i) {

     reduced_results->getStorage()->reduce(

         *(results_per_device[i].first->getStorage()), {}, reduction_code);

   }


   return reduced_results;

 }


 ResultSetPtr Executor::reduceSpeculativeTopN(

     const RelAlgExecutionUnit& ra_exe_unit,

     std::vector<std::pair<ResultSetPtr, std::vector<size_t>>>& results_per_device,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     const QueryMemoryDescriptor& query_mem_desc) const {

   if (results_per_device.size() == 1) {

     return std::move(results_per_device.front().first);

   }

   const auto top_n = ra_exe_unit.sort_info.limit + ra_exe_unit.sort_info.offset;

   SpeculativeTopNMap m;

   for (const auto& result : results_per_device) {

     auto rows = result.first;

     CHECK(rows);

     if (!rows) {

       continue;

     }

     SpeculativeTopNMap that(

         *rows,

         ra_exe_unit.target_exprs,

         std::max(size_t(10000 * std::max(1, static_cast<int>(log(top_n)))), top_n));

     m.reduce(that);

   }

   CHECK_EQ(size_t(1), ra_exe_unit.sort_info.order_entries.size());

   const auto desc = ra_exe_unit.sort_info.order_entries.front().is_desc;

   return m.asRows(ra_exe_unit, row_set_mem_owner, query_mem_desc, this, top_n, desc);

 }


 std::unordered_set<int> get_available_gpus(const Catalog_Namespace::Catalog& cat) {

   std::unordered_set<int> available_gpus;

   if (cat.getDataMgr().gpusPresent()) {

     int gpu_count = cat.getDataMgr().getCudaMgr()->getDeviceCount();

     CHECK_GT(gpu_count, 0);

     for (int gpu_id = 0; gpu_id < gpu_count; ++gpu_id) {

       available_gpus.insert(gpu_id);

     }

   }

   return available_gpus;

 }


 size_t get_context_count(const ExecutorDeviceType device_type,

                          const size_t cpu_count,

                          const size_t gpu_count) {

   return device_type == ExecutorDeviceType::GPU ? gpu_count

                                                 : static_cast<size_t>(cpu_count);

 }


 namespace {


 // Compute a very conservative entry count for the output buffer entry count using no

 // other information than the number of tuples in each table and multiplying them

 // together.

 size_t compute_buffer_entry_guess(const std::vector<InputTableInfo>& query_infos) {

   using Fragmenter_Namespace::FragmentInfo;

   // Check for overflows since we're multiplying potentially big table sizes.

   using checked_size_t = boost::multiprecision::number<

       boost::multiprecision::cpp_int_backend<64,

                                              64,

                                              boost::multiprecision::unsigned_magnitude,

                                              boost::multiprecision::checked,

                                              void>>;

   checked_size_t max_groups_buffer_entry_guess = 1;

   for (const auto& query_info : query_infos) {

     CHECK(!query_info.info.fragments.empty());

     auto it = std::max_element(query_info.info.fragments.begin(),

                                query_info.info.fragments.end(),

                                [](const FragmentInfo& f1, const FragmentInfo& f2) {

                                  return f1.getNumTuples() < f2.getNumTuples();

                                });

     max_groups_buffer_entry_guess *= it->getNumTuples();

   }

   // Cap the rough approximation to 100M entries, it's unlikely we can do a great job for

   // baseline group layout with that many entries anyway.

   constexpr size_t max_groups_buffer_entry_guess_cap = 100000000;

   try {

     return std::min(static_cast<size_t>(max_groups_buffer_entry_guess),

                     max_groups_buffer_entry_guess_cap);

   } catch (...) {

     return max_groups_buffer_entry_guess_cap;

   }

 }


 std::string get_table_name(const InputDescriptor& input_desc,

                            const Catalog_Namespace::Catalog& cat) {

   const auto source_type = input_desc.getSourceType();

   if (source_type == InputSourceType::TABLE) {

     const auto td = cat.getMetadataForTable(input_desc.getTableId());

     CHECK(td);

     return td->tableName;

   } else {

     return "$TEMPORARY_TABLE" + std::to_string(-input_desc.getTableId());

   }

 }


 inline size_t getDeviceBasedScanLimit(const ExecutorDeviceType device_type,

                                       const int device_count) {

   if (device_type == ExecutorDeviceType::GPU) {

     return device_count * Executor::high_scan_limit;

   }

   return Executor::high_scan_limit;

 }


 void checkWorkUnitWatchdog(const RelAlgExecutionUnit& ra_exe_unit,

                            const std::vector<InputTableInfo>& table_infos,

                            const Catalog_Namespace::Catalog& cat,

                            const ExecutorDeviceType device_type,

                            const int device_count) {

   for (const auto target_expr : ra_exe_unit.target_exprs) {

     if (dynamic_cast<const Analyzer::AggExpr*>(target_expr)) {

       return;

     }

   }

   if (!ra_exe_unit.scan_limit && table_infos.size() == 1 &&

       table_infos.front().info.getPhysicalNumTuples() < Executor::high_scan_limit) {

     // Allow a query with no scan limit to run on small tables

     return;

   }

   if (ra_exe_unit.use_bump_allocator) {

     // Bump allocator removes the scan limit (and any knowledge of the size of the output

     // relative to the size of the input), so we bypass this check for now

     return;

   }

   if (ra_exe_unit.sort_info.algorithm != SortAlgorithm::StreamingTopN &&

       ra_exe_unit.groupby_exprs.size() == 1 && !ra_exe_unit.groupby_exprs.front() &&

       (!ra_exe_unit.scan_limit ||

        ra_exe_unit.scan_limit > getDeviceBasedScanLimit(device_type, device_count))) {

     std::vector<std::string> table_names;

     const auto& input_descs = ra_exe_unit.input_descs;

     for (const auto& input_desc : input_descs) {

       table_names.push_back(get_table_name(input_desc, cat));

     }

     if (!ra_exe_unit.scan_limit) {

       throw WatchdogException(

           "Projection query would require a scan without a limit on table(s): " +

           boost::algorithm::join(table_names, ", "));

     } else {

       throw WatchdogException(

           "Projection query output result set on table(s): " +

           boost::algorithm::join(table_names, ", ") + "  would contain " +

           std::to_string(ra_exe_unit.scan_limit) +

           " rows, which is more than the current system limit of " +

           std::to_string(getDeviceBasedScanLimit(device_type, device_count)));

     }

   }

 }


 }  // namespace


 bool is_trivial_loop_join(const std::vector<InputTableInfo>& query_infos,

                           const RelAlgExecutionUnit& ra_exe_unit) {

   if (ra_exe_unit.input_descs.size() < 2) {

     return false;

   }


   // We only support loop join at the end of folded joins

   // where ra_exe_unit.input_descs.size() > 2 for now.

   const auto inner_table_id = ra_exe_unit.input_descs.back().getTableId();


   ssize_t inner_table_idx = -1;

   for (size_t i = 0; i < query_infos.size(); ++i) {

     if (query_infos[i].table_id == inner_table_id) {

       inner_table_idx = i;

       break;

     }

   }

   CHECK_NE(ssize_t(-1), inner_table_idx);

   return query_infos[inner_table_idx].info.getNumTuples() <=

          g_trivial_loop_join_threshold;

 }


 namespace {


 template <typename T>

 std::vector<std::string> expr_container_to_string(const T& expr_container) {

   std::vector<std::string> expr_strs;

   for (const auto& expr : expr_container) {

     if (!expr) {

       expr_strs.emplace_back("NULL");

     } else {

       expr_strs.emplace_back(expr->toString());

     }

   }

   return expr_strs;

 }


 template <>

 std::vector<std::string> expr_container_to_string(

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

   std::vector<std::string> expr_strs;

   for (const auto& expr : expr_container) {

     expr_strs.emplace_back(expr.toString());

   }

   return expr_strs;

 }


 std::string join_type_to_string(const JoinType type) {

   switch (type) {

     case JoinType::INNER:

       return "INNER";

     case JoinType::LEFT:

       return "LEFT";

     case JoinType::INVALID:

       return "INVALID";

   }

   UNREACHABLE();

   return "";

 }


 std::string sort_algorithm_to_string(const SortAlgorithm algorithm) {

   switch (algorithm) {

     case SortAlgorithm::Default:

       return "ResultSet";

     case SortAlgorithm::SpeculativeTopN:

       return "Speculative Top N";

     case SortAlgorithm::StreamingTopN:

       return "Streaming Top N";

   }

   UNREACHABLE();

   return "";

 }


 }  // namespace


 std::ostream& operator<<(std::ostream& os, const RelAlgExecutionUnit& ra_exe_unit) {

   os << "\n\tTable/Col/Levels: ";

   for (const auto& input_col_desc : ra_exe_unit.input_col_descs) {

     const auto& scan_desc = input_col_desc->getScanDesc();

     os << "(" << scan_desc.getTableId() << ", " << input_col_desc->getColId() << ", "

        << scan_desc.getNestLevel() << ") ";

   }

   if (!ra_exe_unit.simple_quals.empty()) {

     os << "\n\tSimple Quals: "

        << boost::algorithm::join(expr_container_to_string(ra_exe_unit.simple_quals),

                                  ", ");

   }

   if (!ra_exe_unit.quals.empty()) {

     os << "\n\tQuals: "

        << boost::algorithm::join(expr_container_to_string(ra_exe_unit.quals), ", ");

   }

   if (!ra_exe_unit.join_quals.empty()) {

     os << "\n\tJoin Quals: ";

     for (size_t i = 0; i < ra_exe_unit.join_quals.size(); i++) {

       const auto& join_condition = ra_exe_unit.join_quals[i];

       os << "\t\t" << std::to_string(i) << " "

          << join_type_to_string(join_condition.type);

       os << boost::algorithm::join(expr_container_to_string(join_condition.quals), ", ");

     }

   }

   if (!ra_exe_unit.groupby_exprs.empty()) {

     os << "\n\tGroup By: "

        << boost::algorithm::join(expr_container_to_string(ra_exe_unit.groupby_exprs),

                                  ", ");

   }

   os << "\n\tProjected targets: "

      << boost::algorithm::join(expr_container_to_string(ra_exe_unit.target_exprs), ", ");

   os << "\n\tHas Estimator: " << bool_to_string(ra_exe_unit.estimator == nullptr);

   os << "\n\tSort Info: ";

   const auto& sort_info = ra_exe_unit.sort_info;

   os << "\n\t  Order Entries: "

      << boost::algorithm::join(expr_container_to_string(sort_info.order_entries), ", ");

   os << "\n\t  Algorithm: " << sort_algorithm_to_string(sort_info.algorithm);

   os << "\n\t  Limit: " << std::to_string(sort_info.limit);

   os << "\n\t  Offset: " << std::to_string(sort_info.offset);

   os << "\n\tScan Limit: " << std::to_string(ra_exe_unit.scan_limit);

   os << "\n\tBump Allocator: " << bool_to_string(ra_exe_unit.use_bump_allocator);

   if (ra_exe_unit.union_all) {

     os << "\n\tUnion: " << std::string(*ra_exe_unit.union_all ? "UNION ALL" : "UNION");

   }

   return os;

 }


 namespace {


 RelAlgExecutionUnit replace_scan_limit(const RelAlgExecutionUnit& ra_exe_unit_in,

                                        const size_t new_scan_limit) {

   return {ra_exe_unit_in.input_descs,

           ra_exe_unit_in.input_col_descs,

           ra_exe_unit_in.simple_quals,

           ra_exe_unit_in.quals,

           ra_exe_unit_in.join_quals,

           ra_exe_unit_in.groupby_exprs,

           ra_exe_unit_in.target_exprs,

           ra_exe_unit_in.estimator,

           ra_exe_unit_in.sort_info,

           new_scan_limit,

           ra_exe_unit_in.use_bump_allocator,

           ra_exe_unit_in.union_all,

           ra_exe_unit_in.query_state};

 }


 }  // namespace


 ResultSetPtr Executor::executeWorkUnit(

     size_t& max_groups_buffer_entry_guess,

     const bool is_agg,

     const std::vector<InputTableInfo>& query_infos,

     const RelAlgExecutionUnit& ra_exe_unit_in,

     const CompilationOptions& co,

     const ExecutionOptions& eo,

     const Catalog_Namespace::Catalog& cat,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     RenderInfo* render_info,

     const bool has_cardinality_estimation,

     ColumnCacheMap& column_cache) {

   VLOG(1) << "Executing work unit:" << ra_exe_unit_in;


   try {

     return executeWorkUnitImpl(max_groups_buffer_entry_guess,

                                is_agg,

                                true,

                                query_infos,

                                ra_exe_unit_in,

                                co,

                                eo,

                                cat,

                                row_set_mem_owner,

                                render_info,

                                has_cardinality_estimation,

                                column_cache);

   } catch (const CompilationRetryNewScanLimit& e) {

     return executeWorkUnitImpl(max_groups_buffer_entry_guess,

                                is_agg,

                                false,

                                query_infos,

                                replace_scan_limit(ra_exe_unit_in, e.new_scan_limit_),

                                co,

                                eo,

                                cat,

                                row_set_mem_owner,

                                render_info,

                                has_cardinality_estimation,

                                column_cache);

   }

 }


 ResultSetPtr Executor::executeWorkUnitImpl(

     size_t& max_groups_buffer_entry_guess,

     const bool is_agg,

     const bool allow_single_frag_table_opt,

     const std::vector<InputTableInfo>& query_infos,

     const RelAlgExecutionUnit& ra_exe_unit_in,

     const CompilationOptions& co,

     const ExecutionOptions& eo,

     const Catalog_Namespace::Catalog& cat,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner,

     RenderInfo* render_info,

     const bool has_cardinality_estimation,

     ColumnCacheMap& column_cache) {

   INJECT_TIMER(Exec_executeWorkUnit);

   const auto ra_exe_unit = addDeletedColumn(ra_exe_unit_in, co);

   const auto device_type = getDeviceTypeForTargets(ra_exe_unit, co.device_type);

   CHECK(!query_infos.empty());

   if (!max_groups_buffer_entry_guess) {

     // The query has failed the first execution attempt because of running out

     // of group by slots. Make the conservative choice: allocate fragment size

     // slots and run on the CPU.

     CHECK(device_type == ExecutorDeviceType::CPU);

     max_groups_buffer_entry_guess = compute_buffer_entry_guess(query_infos);

   }


   int8_t crt_min_byte_width{get_min_byte_width()};

   do {

     ExecutionDispatch execution_dispatch(

         this, ra_exe_unit, query_infos, cat, row_set_mem_owner, render_info);

     ColumnFetcher column_fetcher(this, column_cache);

     std::unique_ptr<QueryCompilationDescriptor> query_comp_desc_owned;

     std::unique_ptr<QueryMemoryDescriptor> query_mem_desc_owned;

     if (eo.executor_type == ExecutorType::Native) {

       try {

         INJECT_TIMER(execution_dispatch_comp);

         std::tie(query_comp_desc_owned, query_mem_desc_owned) =

             execution_dispatch.compile(max_groups_buffer_entry_guess,

                                        crt_min_byte_width,

                                        {device_type,

                                         co.hoist_literals,

                                         co.opt_level,

                                         co.with_dynamic_watchdog,

                                         co.allow_lazy_fetch,

                                         co.add_delete_column,

                                         co.explain_type,

                                         co.register_intel_jit_listener},

                                        eo,

                                        column_fetcher,

                                        has_cardinality_estimation);

         CHECK(query_comp_desc_owned);

         crt_min_byte_width = query_comp_desc_owned->getMinByteWidth();

       } catch (CompilationRetryNoCompaction&) {

         crt_min_byte_width = MAX_BYTE_WIDTH_SUPPORTED;

         continue;

       }

     } else {

       plan_state_.reset(new PlanState(false, this));

       plan_state_->allocateLocalColumnIds(ra_exe_unit.input_col_descs);

       CHECK(!query_comp_desc_owned);

       query_comp_desc_owned.reset(new QueryCompilationDescriptor());

       CHECK(!query_mem_desc_owned);

       query_mem_desc_owned.reset(

           new QueryMemoryDescriptor(this, 0, QueryDescriptionType::Projection, false));

     }

     if (eo.just_explain) {

       return executeExplain(*query_comp_desc_owned);

     }


     for (const auto target_expr : ra_exe_unit.target_exprs) {

       plan_state_->target_exprs_.push_back(target_expr);

     }


     auto dispatch = [&execution_dispatch,

                      &column_fetcher,

                      &eo,

                      parent_thread_id = logger::thread_id()](

                         const ExecutorDeviceType chosen_device_type,

                         int chosen_device_id,

                         const QueryCompilationDescriptor& query_comp_desc,

                         const QueryMemoryDescriptor& query_mem_desc,

                         const FragmentsList& frag_list,

                         const ExecutorDispatchMode kernel_dispatch_mode,

                         const int64_t rowid_lookup_key) {

       DEBUG_TIMER_NEW_THREAD(parent_thread_id);

       INJECT_TIMER(execution_dispatch_run);

       execution_dispatch.run(chosen_device_type,

                              chosen_device_id,

                              eo,

                              column_fetcher,

                              query_comp_desc,

                              query_mem_desc,

                              frag_list,

                              kernel_dispatch_mode,

                              rowid_lookup_key);

     };


     QueryFragmentDescriptor fragment_descriptor(

         ra_exe_unit,

         query_infos,

         query_comp_desc_owned->getDeviceType() == ExecutorDeviceType::GPU

             ? cat.getDataMgr().getMemoryInfo(Data_Namespace::MemoryLevel::GPU_LEVEL)

             : std::vector<Data_Namespace::MemoryInfo>{},

         eo.gpu_input_mem_limit_percent,

         eo.outer_fragment_indices);


     if (!eo.just_validate) {

       int available_cpus = cpu_threads();

       auto available_gpus = get_available_gpus(cat);


       const auto context_count =

           get_context_count(device_type, available_cpus, available_gpus.size());

       try {

         if (g_use_tbb_pool) {

 #ifdef HAVE_TBB

           VLOG(1) << "Using TBB thread pool for kernel dispatch.";

           dispatchFragments<threadpool::TbbThreadPool<void>>(dispatch,

                                                              execution_dispatch,

                                                              query_infos,

                                                              eo,

                                                              is_agg,

                                                              allow_single_frag_table_opt,

                                                              context_count,

                                                              *query_comp_desc_owned,

                                                              *query_mem_desc_owned,

                                                              fragment_descriptor,

                                                              available_gpus,

                                                              available_cpus);

 #else

           throw std::runtime_error(

               "This build is not TBB enabled. Restart the server with "

               "\"enable-modern-thread-pool\" disabled.");

 #endif

         } else {

           dispatchFragments<threadpool::FuturesThreadPool<void>>(

               dispatch,

               execution_dispatch,

               query_infos,

               eo,

               is_agg,

               allow_single_frag_table_opt,

               context_count,

               *query_comp_desc_owned,

               *query_mem_desc_owned,

               fragment_descriptor,

               available_gpus,

               available_cpus);

         }

       } catch (QueryExecutionError& e) {

         if (eo.with_dynamic_watchdog && interrupted_.load() &&

             e.getErrorCode() == ERR_OUT_OF_TIME) {

           resetInterrupt();

           throw QueryExecutionError(ERR_INTERRUPTED);

         }

         if (eo.allow_runtime_query_interrupt && interrupted_.load()) {

           resetInterrupt();

           throw QueryExecutionError(ERR_INTERRUPTED);

         }

         cat.getDataMgr().freeAllBuffers();

         if (e.getErrorCode() == ERR_OVERFLOW_OR_UNDERFLOW &&

             static_cast<size_t>(crt_min_byte_width << 1) <= sizeof(int64_t)) {

           crt_min_byte_width <<= 1;

           continue;

         }

         throw;

       }

     }

     cat.getDataMgr().freeAllBuffers();

     if (is_agg) {

       try {

         return collectAllDeviceResults(execution_dispatch,

                                        ra_exe_unit.target_exprs,

                                        *query_mem_desc_owned,

                                        query_comp_desc_owned->getDeviceType(),

                                        row_set_mem_owner);

       } catch (ReductionRanOutOfSlots&) {

         throw QueryExecutionError(ERR_OUT_OF_SLOTS);

       } catch (OverflowOrUnderflow&) {

         crt_min_byte_width <<= 1;

         continue;

       }

     }

     return resultsUnion(execution_dispatch);


   } while (static_cast<size_t>(crt_min_byte_width) <= sizeof(int64_t));


   return std::make_shared<ResultSet>(std::vector<TargetInfo>{},

                                      ExecutorDeviceType::CPU,

                                      QueryMemoryDescriptor(),

                                      nullptr,

                                      this);

 }


 void Executor::executeWorkUnitPerFragment(const RelAlgExecutionUnit& ra_exe_unit_in,

                                           const InputTableInfo& table_info,

                                           const CompilationOptions& co,

                                           const ExecutionOptions& eo,

                                           const Catalog_Namespace::Catalog& cat,

                                           PerFragmentCallBack& cb) {

   const auto ra_exe_unit = addDeletedColumn(ra_exe_unit_in, co);

   ColumnCacheMap column_cache;


   std::vector<InputTableInfo> table_infos{table_info};

   // TODO(adb): ensure this is under a try / catch

   ExecutionDispatch execution_dispatch(

       this, ra_exe_unit, table_infos, cat, row_set_mem_owner_, nullptr);

   ColumnFetcher column_fetcher(this, column_cache);

   std::unique_ptr<QueryCompilationDescriptor> query_comp_desc_owned;

   std::unique_ptr<QueryMemoryDescriptor> query_mem_desc_owned;

   std::tie(query_comp_desc_owned, query_mem_desc_owned) =

       execution_dispatch.compile(0, 8, co, eo, column_fetcher, false);

   CHECK_EQ(size_t(1), ra_exe_unit.input_descs.size());

   const auto table_id = ra_exe_unit.input_descs[0].getTableId();

   const auto& outer_fragments = table_info.info.fragments;

   for (size_t fragment_index = 0; fragment_index < outer_fragments.size();

        ++fragment_index) {

     // We may want to consider in the future allowing this to execute on devices other

     // than CPU

     execution_dispatch.run(co.device_type,

                            0,

                            eo,

                            column_fetcher,

                            *query_comp_desc_owned,

                            *query_mem_desc_owned,

                            {{table_id, {fragment_index}}},

                            ExecutorDispatchMode::KernelPerFragment,

                            -1);

   }


   const auto& all_fragment_results = execution_dispatch.getFragmentResults();


   for (size_t fragment_index = 0; fragment_index < outer_fragments.size();

        ++fragment_index) {

     const auto fragment_results = all_fragment_results[fragment_index];

     cb(fragment_results.first, outer_fragments[fragment_index]);

   }

 }


 ResultSetPtr Executor::executeTableFunction(

     const TableFunctionExecutionUnit exe_unit,

     const std::vector<InputTableInfo>& table_infos,

     const CompilationOptions& co,

     const ExecutionOptions& eo,

     const Catalog_Namespace::Catalog& cat) {

   INJECT_TIMER(Exec_executeTableFunction);

   nukeOldState(false, table_infos, nullptr);


   ColumnCacheMap column_cache;  // Note: if we add retries to the table function

                                 // framework, we may want to move this up a level


   ColumnFetcher column_fetcher(this, column_cache);

   TableFunctionCompilationContext compilation_context;

   compilation_context.compile(exe_unit, co, this);


   TableFunctionExecutionContext exe_context(getRowSetMemoryOwner());

   CHECK_EQ(table_infos.size(), size_t(1));

   return exe_context.execute(exe_unit,

                              table_infos.front(),

                              &compilation_context,

                              column_fetcher,

                              co.device_type,

                              this);

 }


 ResultSetPtr Executor::executeExplain(const QueryCompilationDescriptor& query_comp_desc) {

   return std::make_shared<ResultSet>(query_comp_desc.getIR());

 }


 // Looks at the targets and returns a feasible device type. We only punt

 // to CPU for count distinct and we should probably fix it and remove this.

 ExecutorDeviceType Executor::getDeviceTypeForTargets(

     const RelAlgExecutionUnit& ra_exe_unit,

     const ExecutorDeviceType requested_device_type) {

   for (const auto target_expr : ra_exe_unit.target_exprs) {

     const auto agg_info = get_target_info(target_expr, g_bigint_count);

     if (!ra_exe_unit.groupby_exprs.empty() &&

         !isArchPascalOrLater(requested_device_type)) {

       if ((agg_info.agg_kind == kAVG || agg_info.agg_kind == kSUM) &&

           agg_info.agg_arg_type.get_type() == kDOUBLE) {

         return ExecutorDeviceType::CPU;

       }

     }

     if (dynamic_cast<const Analyzer::RegexpExpr*>(target_expr)) {

       return ExecutorDeviceType::CPU;

     }

   }

   return requested_device_type;

 }


 namespace {


 int64_t inline_null_val(const SQLTypeInfo& ti, const bool float_argument_input) {

   CHECK(ti.is_number() || ti.is_time() || ti.is_boolean() || ti.is_string());

   if (ti.is_fp()) {

     if (float_argument_input && ti.get_type() == kFLOAT) {

       int64_t float_null_val = 0;

       *reinterpret_cast<float*>(may_alias_ptr(&float_null_val)) =

           static_cast<float>(inline_fp_null_val(ti));

       return float_null_val;

     }

     const auto double_null_val = inline_fp_null_val(ti);

     return *reinterpret_cast<const int64_t*>(may_alias_ptr(&double_null_val));

   }

   return inline_int_null_val(ti);

 }


 void fill_entries_for_empty_input(std::vector<TargetInfo>& target_infos,

                                   std::vector<int64_t>& entry,

                                   const std::vector<Analyzer::Expr*>& target_exprs,

                                   const QueryMemoryDescriptor& query_mem_desc) {

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

     const auto target_expr = target_exprs[target_idx];

     const auto agg_info = get_target_info(target_expr, g_bigint_count);

     CHECK(agg_info.is_agg);

     target_infos.push_back(agg_info);

     if (g_cluster) {

       const auto executor = query_mem_desc.getExecutor();

       CHECK(executor);

       auto row_set_mem_owner = executor->getRowSetMemoryOwner();

       CHECK(row_set_mem_owner);

       const auto& count_distinct_desc =

           query_mem_desc.getCountDistinctDescriptor(target_idx);

       if (count_distinct_desc.impl_type_ == CountDistinctImplType::Bitmap) {

         auto count_distinct_buffer = static_cast<int8_t*>(

             checked_calloc(count_distinct_desc.bitmapPaddedSizeBytes(), 1));

         CHECK(row_set_mem_owner);

         row_set_mem_owner->addCountDistinctBuffer(

             count_distinct_buffer, count_distinct_desc.bitmapPaddedSizeBytes(), true);

         entry.push_back(reinterpret_cast<int64_t>(count_distinct_buffer));

         continue;

       }

       if (count_distinct_desc.impl_type_ == CountDistinctImplType::StdSet) {

         auto count_distinct_set = new std::set<int64_t>();

         CHECK(row_set_mem_owner);

         row_set_mem_owner->addCountDistinctSet(count_distinct_set);

         entry.push_back(reinterpret_cast<int64_t>(count_distinct_set));

         continue;

       }

     }

     const bool float_argument_input = takes_float_argument(agg_info);

     if (agg_info.agg_kind == kCOUNT || agg_info.agg_kind == kAPPROX_COUNT_DISTINCT) {

       entry.push_back(0);

     } else if (agg_info.agg_kind == kAVG) {

       entry.push_back(inline_null_val(agg_info.sql_type, float_argument_input));

       entry.push_back(0);

     } else if (agg_info.agg_kind == kSINGLE_VALUE || agg_info.agg_kind == kSAMPLE) {

       if (agg_info.sql_type.is_geometry()) {

         for (int i = 0; i < agg_info.sql_type.get_physical_coord_cols() * 2; i++) {

           entry.push_back(0);

         }

       } else if (agg_info.sql_type.is_varlen()) {

         entry.push_back(0);

         entry.push_back(0);

       } else {

         entry.push_back(inline_null_val(agg_info.sql_type, float_argument_input));

       }

     } else {

       entry.push_back(inline_null_val(agg_info.sql_type, float_argument_input));

     }

   }

 }


 ResultSetPtr build_row_for_empty_input(

     const std::vector<Analyzer::Expr*>& target_exprs_in,

     const QueryMemoryDescriptor& query_mem_desc,

     const ExecutorDeviceType device_type) {

   std::vector<std::shared_ptr<Analyzer::Expr>> target_exprs_owned_copies;

   std::vector<Analyzer::Expr*> target_exprs;

   for (const auto target_expr : target_exprs_in) {

     const auto target_expr_copy =

         std::dynamic_pointer_cast<Analyzer::AggExpr>(target_expr->deep_copy());

     CHECK(target_expr_copy);

     auto ti = target_expr->get_type_info();

     ti.set_notnull(false);

     target_expr_copy->set_type_info(ti);

     if (target_expr_copy->get_arg()) {

       auto arg_ti = target_expr_copy->get_arg()->get_type_info();

       arg_ti.set_notnull(false);

       target_expr_copy->get_arg()->set_type_info(arg_ti);

     }

     target_exprs_owned_copies.push_back(target_expr_copy);

     target_exprs.push_back(target_expr_copy.get());

   }

   std::vector<TargetInfo> target_infos;

   std::vector<int64_t> entry;

   fill_entries_for_empty_input(target_infos, entry, target_exprs, query_mem_desc);

   const auto executor = query_mem_desc.getExecutor();

   CHECK(executor);

   auto row_set_mem_owner = executor->getRowSetMemoryOwner();

   CHECK(row_set_mem_owner);

   auto rs = std::make_shared<ResultSet>(

       target_infos, device_type, query_mem_desc, row_set_mem_owner, executor);

   rs->allocateStorage();

   rs->fillOneEntry(entry);

   return rs;

 }


 }  // namespace


 ResultSetPtr Executor::collectAllDeviceResults(

     ExecutionDispatch& execution_dispatch,

     const std::vector<Analyzer::Expr*>& target_exprs,

     const QueryMemoryDescriptor& query_mem_desc,

     const ExecutorDeviceType device_type,

     std::shared_ptr<RowSetMemoryOwner> row_set_mem_owner) {

   auto timer = DEBUG_TIMER(__func__);

   auto& result_per_device = execution_dispatch.getFragmentResults();

   if (result_per_device.empty() && query_mem_desc.getQueryDescriptionType() ==

                                        QueryDescriptionType::NonGroupedAggregate) {

     return build_row_for_empty_input(target_exprs, query_mem_desc, device_type);

   }

   const auto& ra_exe_unit = execution_dispatch.getExecutionUnit();

   if (use_speculative_top_n(ra_exe_unit, query_mem_desc)) {

     try {

       return reduceSpeculativeTopN(

           ra_exe_unit, result_per_device, row_set_mem_owner, query_mem_desc);

     } catch (const std::bad_alloc&) {

       throw SpeculativeTopNFailed("Failed during multi-device reduction.");

     }

   }

   const auto shard_count =

       device_type == ExecutorDeviceType::GPU

           ? GroupByAndAggregate::shard_count_for_top_groups(ra_exe_unit, *catalog_)

           : 0;


   if (shard_count && !result_per_device.empty()) {

     return collectAllDeviceShardedTopResults(execution_dispatch);

   }

   return reduceMultiDeviceResults(

       ra_exe_unit, result_per_device, row_set_mem_owner, query_mem_desc);

 }


 namespace {

 size_t permute_storage_columnar(const ResultSetStorage* input_storage,

                                 const QueryMemoryDescriptor& input_query_mem_desc,

                                 const ResultSetStorage* output_storage,

                                 size_t output_row_index,

                                 const QueryMemoryDescriptor& output_query_mem_desc,

                                 const std::vector<uint32_t>& top_permutation) {

   const auto output_buffer = output_storage->getUnderlyingBuffer();

   const auto input_buffer = input_storage->getUnderlyingBuffer();

   for (const auto sorted_idx : top_permutation) {

     // permuting all group-columns in this result set into the final buffer:

     for (size_t group_idx = 0; group_idx < input_query_mem_desc.getKeyCount();

          group_idx++) {

       const auto input_column_ptr =

           input_buffer + input_query_mem_desc.getPrependedGroupColOffInBytes(group_idx) +

           sorted_idx * input_query_mem_desc.groupColWidth(group_idx);

       const auto output_column_ptr =

           output_buffer +

           output_query_mem_desc.getPrependedGroupColOffInBytes(group_idx) +

           output_row_index * output_query_mem_desc.groupColWidth(group_idx);

       memcpy(output_column_ptr,

              input_column_ptr,

              output_query_mem_desc.groupColWidth(group_idx));

     }

     // permuting all agg-columns in this result set into the final buffer:

     for (size_t slot_idx = 0; slot_idx < input_query_mem_desc.getSlotCount();

          slot_idx++) {

       const auto input_column_ptr =

           input_buffer + input_query_mem_desc.getColOffInBytes(slot_idx) +

           sorted_idx * input_query_mem_desc.getPaddedSlotWidthBytes(slot_idx);

       const auto output_column_ptr =

           output_buffer + output_query_mem_desc.getColOffInBytes(slot_idx) +

           output_row_index * output_query_mem_desc.getPaddedSlotWidthBytes(slot_idx);

       memcpy(output_column_ptr,

              input_column_ptr,

              output_query_mem_desc.getPaddedSlotWidthBytes(slot_idx));

     }

     ++output_row_index;

   }

   return output_row_index;

 }


 size_t permute_storage_row_wise(const ResultSetStorage* input_storage,

                                 const ResultSetStorage* output_storage,

                                 size_t output_row_index,

                                 const QueryMemoryDescriptor& output_query_mem_desc,

                                 const std::vector<uint32_t>& top_permutation) {

   const auto output_buffer = output_storage->getUnderlyingBuffer();

   const auto input_buffer = input_storage->getUnderlyingBuffer();

   for (const auto sorted_idx : top_permutation) {

     const auto row_ptr = input_buffer + sorted_idx * output_query_mem_desc.getRowSize();

     memcpy(output_buffer + output_row_index * output_query_mem_desc.getRowSize(),

            row_ptr,

            output_query_mem_desc.getRowSize());

     ++output_row_index;

   }

   return output_row_index;

 }

 }  // namespace


 // Collect top results from each device, stitch them together and sort. Partial

 // results from each device are guaranteed to be disjunct because we only go on

 // this path when one of the columns involved is a shard key.

 ResultSetPtr Executor::collectAllDeviceShardedTopResults(

     ExecutionDispatch& execution_dispatch) const {

   const auto& ra_exe_unit = execution_dispatch.getExecutionUnit();

   auto& result_per_device = execution_dispatch.getFragmentResults();

   const auto first_result_set = result_per_device.front().first;

   CHECK(first_result_set);

   auto top_query_mem_desc = first_result_set->getQueryMemDesc();

   CHECK(!top_query_mem_desc.hasInterleavedBinsOnGpu());

   const auto top_n = ra_exe_unit.sort_info.limit + ra_exe_unit.sort_info.offset;

   top_query_mem_desc.setEntryCount(0);

   for (auto& result : result_per_device) {

     const auto result_set = result.first;

     CHECK(result_set);

     result_set->sort(ra_exe_unit.sort_info.order_entries, top_n);

     size_t new_entry_cnt = top_query_mem_desc.getEntryCount() + result_set->rowCount();

     top_query_mem_desc.setEntryCount(new_entry_cnt);

   }

   auto top_result_set = std::make_shared<ResultSet>(first_result_set->getTargetInfos(),

                                                     first_result_set->getDeviceType(),

                                                     top_query_mem_desc,

                                                     first_result_set->getRowSetMemOwner(),

                                                     this);

   auto top_storage = top_result_set->allocateStorage();

   size_t top_output_row_idx{0};

   for (auto& result : result_per_device) {

     const auto result_set = result.first;

     CHECK(result_set);

     const auto& top_permutation = result_set->getPermutationBuffer();

     CHECK_LE(top_permutation.size(), top_n);

     if (top_query_mem_desc.didOutputColumnar()) {

       top_output_row_idx = permute_storage_columnar(result_set->getStorage(),

                                                     result_set->getQueryMemDesc(),

                                                     top_storage,

                                                     top_output_row_idx,

                                                     top_query_mem_desc,

                                                     top_permutation);

     } else {

       top_output_row_idx = permute_storage_row_wise(result_set->getStorage(),

                                                     top_storage,

                                                     top_output_row_idx,

                                                     top_query_mem_desc,

                                                     top_permutation);

     }

   }

   CHECK_EQ(top_output_row_idx, top_query_mem_desc.getEntryCount());

   return top_result_set;

 }


 std::unordered_map<int, const Analyzer::BinOper*> Executor::getInnerTabIdToJoinCond()

     const {

   std::unordered_map<int, const Analyzer::BinOper*> id_to_cond;

   const auto& join_info = plan_state_->join_info_;

   CHECK_EQ(join_info.equi_join_tautologies_.size(), join_info.join_hash_tables_.size());

   for (size_t i = 0; i < join_info.join_hash_tables_.size(); ++i) {

     int inner_table_id = join_info.join_hash_tables_[i]->getInnerTableId();

     id_to_cond.insert(

         std::make_pair(inner_table_id, join_info.equi_join_tautologies_[i].get()));

   }

   return id_to_cond;

 }


 namespace {


 bool has_lazy_fetched_columns(const std::vector<ColumnLazyFetchInfo>& fetched_cols) {

   for (const auto& col : fetched_cols) {

     if (col.is_lazily_fetched) {

       return true;

     }

   }

   return false;

 }


 }  // namespace


 template <typename THREAD_POOL>

 void Executor::dispatchFragments(

     const std::function<void(const ExecutorDeviceType chosen_device_type,

                              int chosen_device_id,

                              const QueryCompilationDescriptor& query_comp_desc,

                              const QueryMemoryDescriptor& query_mem_desc,

                              const FragmentsList& frag_list,

                              const ExecutorDispatchMode kernel_dispatch_mode,

                              const int64_t rowid_lookup_key)> dispatch,

     const ExecutionDispatch& execution_dispatch,

     const std::vector<InputTableInfo>& table_infos,

     const ExecutionOptions& eo,

     const bool is_agg,

     const bool allow_single_frag_table_opt,

     const size_t context_count,

     const QueryCompilationDescriptor& query_comp_desc,

     const QueryMemoryDescriptor& query_mem_desc,

     QueryFragmentDescriptor& fragment_descriptor,

     std::unordered_set<int>& available_gpus,

     int& available_cpus) {

   THREAD_POOL query_threads;

   const auto& ra_exe_unit = execution_dispatch.getExecutionUnit();

   CHECK(!ra_exe_unit.input_descs.empty());


   const auto device_type = query_comp_desc.getDeviceType();

   const bool uses_lazy_fetch =

       plan_state_->allow_lazy_fetch_ &&

       has_lazy_fetched_columns(getColLazyFetchInfo(ra_exe_unit.target_exprs));

   const bool use_multifrag_kernel = (device_type == ExecutorDeviceType::GPU) &&

                                     eo.allow_multifrag && (!uses_lazy_fetch || is_agg);


   const auto device_count = deviceCount(device_type);

   CHECK_GT(device_count, 0);


   fragment_descriptor.buildFragmentKernelMap(ra_exe_unit,

                                              execution_dispatch.getFragOffsets(),

                                              device_count,

                                              device_type,

                                              use_multifrag_kernel,

                                              g_inner_join_fragment_skipping,

                                              this);

   if (eo.with_watchdog && fragment_descriptor.shouldCheckWorkUnitWatchdog()) {

     checkWorkUnitWatchdog(ra_exe_unit, table_infos, *catalog_, device_type, device_count);

   }


   if (use_multifrag_kernel) {

     VLOG(1) << "Dispatching multifrag kernels";

     VLOG(1) << query_mem_desc.toString();


     // NB: We should never be on this path when the query is retried because of running

     // out of group by slots; also, for scan only queries on CPU we want the

     // high-granularity, fragment by fragment execution instead. For scan only queries on

     // GPU, we want the multifrag kernel path to save the overhead of allocating an output

     // buffer per fragment.

     auto multifrag_kernel_dispatch =

         [&query_threads, &dispatch, query_comp_desc, query_mem_desc](

             const int device_id,

             const FragmentsList& frag_list,

             const int64_t rowid_lookup_key) {

           query_threads.append(dispatch,

                                ExecutorDeviceType::GPU,

                                device_id,

                                query_comp_desc,

                                query_mem_desc,

                                frag_list,

                                ExecutorDispatchMode::MultifragmentKernel,

                                rowid_lookup_key);

         };

     fragment_descriptor.assignFragsToMultiDispatch(multifrag_kernel_dispatch);

   } else {

     VLOG(1) << "Dispatching kernel per fragment";

     VLOG(1) << query_mem_desc.toString();


     if (!ra_exe_unit.use_bump_allocator && allow_single_frag_table_opt &&

         (query_mem_desc.getQueryDescriptionType() == QueryDescriptionType::Projection) &&

         table_infos.size() == 1 && table_infos.front().table_id > 0) {

       const auto max_frag_size =

           table_infos.front().info.getFragmentNumTuplesUpperBound();

       if (max_frag_size < query_mem_desc.getEntryCount()) {

         LOG(INFO) << "Lowering scan limit from " << query_mem_desc.getEntryCount()

                   << " to match max fragment size " << max_frag_size

                   << " for kernel per fragment execution path.";

         throw CompilationRetryNewScanLimit(max_frag_size);

       }

     }


     size_t frag_list_idx{0};

     auto fragment_per_kernel_dispatch = [&query_threads,

                                          &dispatch,

                                          &frag_list_idx,

                                          &device_type,

                                          query_comp_desc,

                                          query_mem_desc](const int device_id,

                                                          const FragmentsList& frag_list,

                                                          const int64_t rowid_lookup_key) {

       if (!frag_list.size()) {

         return;

       }

       CHECK_GE(device_id, 0);


       query_threads.append(dispatch,

                            device_type,

                            device_id,

                            query_comp_desc,

                            query_mem_desc,

                            frag_list,

                            ExecutorDispatchMode::KernelPerFragment,

                            rowid_lookup_key);


       ++frag_list_idx;

     };


     fragment_descriptor.assignFragsToKernelDispatch(fragment_per_kernel_dispatch,

                                                     ra_exe_unit);

   }

   query_threads.join();

 }


 std::vector<size_t> Executor::getTableFragmentIndices(

     const RelAlgExecutionUnit& ra_exe_unit,

     const ExecutorDeviceType device_type,

     const size_t table_idx,

     const size_t outer_frag_idx,

     std::map<int, const TableFragments*>& selected_tables_fragments,

     const std::unordered_map<int, const Analyzer::BinOper*>&

         inner_table_id_to_join_condition) {

   const int table_id = ra_exe_unit.input_descs[table_idx].getTableId();

   auto table_frags_it = selected_tables_fragments.find(table_id);

   CHECK(table_frags_it != selected_tables_fragments.end());

   const auto& outer_input_desc = ra_exe_unit.input_descs[0];

   const auto outer_table_fragments_it =

       selected_tables_fragments.find(outer_input_desc.getTableId());

   const auto outer_table_fragments = outer_table_fragments_it->second;

   CHECK(outer_table_fragments_it != selected_tables_fragments.end());

   CHECK_LT(outer_frag_idx, outer_table_fragments->size());

   if (!table_idx) {

     return {outer_frag_idx};

   }

   const auto& outer_fragment_info = (*outer_table_fragments)[outer_frag_idx];

   auto& inner_frags = table_frags_it->second;

   CHECK_LT(size_t(1), ra_exe_unit.input_descs.size());

   std::vector<size_t> all_frag_ids;

   for (size_t inner_frag_idx = 0; inner_frag_idx < inner_frags->size();

        ++inner_frag_idx) {

     const auto& inner_frag_info = (*inner_frags)[inner_frag_idx];

     if (skipFragmentPair(outer_fragment_info,

                          inner_frag_info,

                          table_idx,

                          inner_table_id_to_join_condition,

                          ra_exe_unit,

                          device_type)) {

       continue;

     }

     all_frag_ids.push_back(inner_frag_idx);

   }

   return all_frag_ids;

 }


 // Returns true iff the join between two fragments cannot yield any results, per

 // shard information. The pair can be skipped to avoid full broadcast.

 bool Executor::skipFragmentPair(

     const Fragmenter_Namespace::FragmentInfo& outer_fragment_info,

     const Fragmenter_Namespace::FragmentInfo& inner_fragment_info,

     const int table_idx,

     const std::unordered_map<int, const Analyzer::BinOper*>&

         inner_table_id_to_join_condition,

     const RelAlgExecutionUnit& ra_exe_unit,

     const ExecutorDeviceType device_type) {

   if (device_type != ExecutorDeviceType::GPU) {

     return false;

   }

   CHECK(table_idx >= 0 &&

         static_cast<size_t>(table_idx) < ra_exe_unit.input_descs.size());

   const int inner_table_id = ra_exe_unit.input_descs[table_idx].getTableId();

   // Both tables need to be sharded the same way.

   if (outer_fragment_info.shard == -1 || inner_fragment_info.shard == -1 ||

       outer_fragment_info.shard == inner_fragment_info.shard) {

     return false;

   }

   const Analyzer::BinOper* join_condition{nullptr};

   if (ra_exe_unit.join_quals.empty()) {

     CHECK(!inner_table_id_to_join_condition.empty());

     auto condition_it = inner_table_id_to_join_condition.find(inner_table_id);

     CHECK(condition_it != inner_table_id_to_join_condition.end());

     join_condition = condition_it->second;

     CHECK(join_condition);

   } else {

     CHECK_EQ(plan_state_->join_info_.equi_join_tautologies_.size(),

              plan_state_->join_info_.join_hash_tables_.size());

     for (size_t i = 0; i < plan_state_->join_info_.join_hash_tables_.size(); ++i) {

       if (plan_state_->join_info_.join_hash_tables_[i]->getInnerTableRteIdx() ==

           table_idx) {

         CHECK(!join_condition);

         join_condition = plan_state_->join_info_.equi_join_tautologies_[i].get();

       }

     }

   }

   if (!join_condition) {

     return false;

   }

   // TODO(adb): support fragment skipping based on the overlaps operator

   if (join_condition->is_overlaps_oper()) {

     return false;

   }

   size_t shard_count{0};

   if (dynamic_cast<const Analyzer::ExpressionTuple*>(

           join_condition->get_left_operand())) {

     auto inner_outer_pairs =

         normalize_column_pairs(join_condition, *getCatalog(), getTemporaryTables());

     shard_count = BaselineJoinHashTable::getShardCountForCondition(

         join_condition, this, inner_outer_pairs);

   } else {

     shard_count = get_shard_count(join_condition, this);

   }

   if (shard_count && !ra_exe_unit.join_quals.empty()) {

     plan_state_->join_info_.sharded_range_table_indices_.emplace(table_idx);

   }

   return shard_count;

 }


 namespace {


 const ColumnDescriptor* try_get_column_descriptor(const InputColDescriptor* col_desc,

                                                   const Catalog_Namespace::Catalog& cat) {

   const int table_id = col_desc->getScanDesc().getTableId();

   const int col_id = col_desc->getColId();

   return get_column_descriptor_maybe(col_id, table_id, cat);

 }


 }  // namespace


 std::map<size_t, std::vector<uint64_t>> get_table_id_to_frag_offsets(

     const std::vector<InputDescriptor>& input_descs,

     const std::map<int, const TableFragments*>& all_tables_fragments) {

   std::map<size_t, std::vector<uint64_t>> tab_id_to_frag_offsets;

   for (auto& desc : input_descs) {

     const auto fragments_it = all_tables_fragments.find(desc.getTableId());

     CHECK(fragments_it != all_tables_fragments.end());

     const auto& fragments = *fragments_it->second;

     std::vector<uint64_t> frag_offsets(fragments.size(), 0);

     for (size_t i = 0, off = 0; i < fragments.size(); ++i) {

       frag_offsets[i] = off;

       off += fragments[i].getNumTuples();

     }

     tab_id_to_frag_offsets.insert(std::make_pair(desc.getTableId(), frag_offsets));

   }

   return tab_id_to_frag_offsets;

 }


 std::pair<std::vector<std::vector<int64_t>>, std::vector<std::vector<uint64_t>>>

 Executor::getRowCountAndOffsetForAllFrags(

     const RelAlgExecutionUnit& ra_exe_unit,

     const CartesianProduct<std::vector<std::vector<size_t>>>& frag_ids_crossjoin,

     const std::vector<InputDescriptor>& input_descs,

     const std::map<int, const TableFragments*>& all_tables_fragments) {

   std::vector<std::vector<int64_t>> all_num_rows;

   std::vector<std::vector<uint64_t>> all_frag_offsets;

   const auto tab_id_to_frag_offsets =

       get_table_id_to_frag_offsets(input_descs, all_tables_fragments);

   std::unordered_map<size_t, size_t> outer_id_to_num_row_idx;

   for (const auto& selected_frag_ids : frag_ids_crossjoin) {

     std::vector<int64_t> num_rows;

     std::vector<uint64_t> frag_offsets;

     if (!ra_exe_unit.union_all) {

       CHECK_EQ(selected_frag_ids.size(), input_descs.size());

     }

     for (size_t tab_idx = 0; tab_idx < input_descs.size(); ++tab_idx) {

       const auto frag_id = ra_exe_unit.union_all ? 0 : selected_frag_ids[tab_idx];

       const auto fragments_it =

           all_tables_fragments.find(input_descs[tab_idx].getTableId());

       CHECK(fragments_it != all_tables_fragments.end());

       const auto& fragments = *fragments_it->second;

       if (ra_exe_unit.join_quals.empty() || tab_idx == 0 ||

           plan_state_->join_info_.sharded_range_table_indices_.count(tab_idx)) {

         const auto& fragment = fragments[frag_id];

         num_rows.push_back(fragment.getNumTuples());

       } else {

         size_t total_row_count{0};

         for (const auto& fragment : fragments) {

           total_row_count += fragment.getNumTuples();

         }

         num_rows.push_back(total_row_count);

       }

       const auto frag_offsets_it =

           tab_id_to_frag_offsets.find(input_descs[tab_idx].getTableId());

       CHECK(frag_offsets_it != tab_id_to_frag_offsets.end());

       const auto& offsets = frag_offsets_it->second;

       CHECK_LT(frag_id, offsets.size());

       frag_offsets.push_back(offsets[frag_id]);

     }

     all_num_rows.push_back(num_rows);

     // Fragment offsets of outer table should be ONLY used by rowid for now.

     all_frag_offsets.push_back(frag_offsets);

   }

   return {all_num_rows, all_frag_offsets};

 }


 // Only fetch columns of hash-joined inner fact table whose fetch are not deferred from

 // all the table fragments.

 bool Executor::needFetchAllFragments(const InputColDescriptor& inner_col_desc,

                                      const RelAlgExecutionUnit& ra_exe_unit,

                                      const FragmentsList& selected_fragments) const {

   const auto& input_descs = ra_exe_unit.input_descs;

   const int nest_level = inner_col_desc.getScanDesc().getNestLevel();

   if (nest_level < 1 ||

       inner_col_desc.getScanDesc().getSourceType() != InputSourceType::TABLE ||

       ra_exe_unit.join_quals.empty() || input_descs.size() < 2 ||

       (ra_exe_unit.join_quals.empty() &&

        plan_state_->isLazyFetchColumn(inner_col_desc))) {

     return false;

   }

   const int table_id = inner_col_desc.getScanDesc().getTableId();

   CHECK_LT(static_cast<size_t>(nest_level), selected_fragments.size());

   CHECK_EQ(table_id, selected_fragments[nest_level].table_id);

   const auto& fragments = selected_fragments[nest_level].fragment_ids;

   return fragments.size() > 1;

 }


 std::ostream& operator<<(std::ostream& os, FetchResult const& fetch_result) {

   return os << "col_buffers" << shared::printContainer(fetch_result.col_buffers)

             << " num_rows" << shared::printContainer(fetch_result.num_rows)

             << " frag_offsets" << shared::printContainer(fetch_result.frag_offsets);

 }


 FetchResult Executor::fetchChunks(

     const ColumnFetcher& column_fetcher,

     const RelAlgExecutionUnit& ra_exe_unit,

     const int device_id,

     const Data_Namespace::MemoryLevel memory_level,

     const std::map<int, const TableFragments*>& all_tables_fragments,

     const FragmentsList& selected_fragments,

     const Catalog_Namespace::Catalog& cat,

     std::list<ChunkIter>& chunk_iterators,

     std::list<std::shared_ptr<Chunk_NS::Chunk>>& chunks) {

   auto timer = DEBUG_TIMER(__func__);

   INJECT_TIMER(fetchChunks);

   const auto& col_global_ids = ra_exe_unit.input_col_descs;

   std::vector<std::vector<size_t>> selected_fragments_crossjoin;

   std::vector<size_t> local_col_to_frag_pos;

   buildSelectedFragsMapping(selected_fragments_crossjoin,

                             local_col_to_frag_pos,

                             col_global_ids,

                             selected_fragments,

                             ra_exe_unit);


   CartesianProduct<std::vector<std::vector<size_t>>> frag_ids_crossjoin(

       selected_fragments_crossjoin);


   std::vector<std::vector<const int8_t*>> all_frag_col_buffers;

   std::vector<std::vector<int64_t>> all_num_rows;

   std::vector<std::vector<uint64_t>> all_frag_offsets;


   for (const auto& selected_frag_ids : frag_ids_crossjoin) {

     std::vector<const int8_t*> frag_col_buffers(

         plan_state_->global_to_local_col_ids_.size());

     for (const auto& col_id : col_global_ids) {

       // check whether the interrupt flag turns on (non kernel-time query interrupt)

       if ((g_enable_dynamic_watchdog || g_enable_runtime_query_interrupt) &&

           interrupted_.load()) {

         resetInterrupt();

         throw QueryExecutionError(ERR_INTERRUPTED);

       }

       CHECK(col_id);

       const int table_id = col_id->getScanDesc().getTableId();

       const auto cd = try_get_column_descriptor(col_id.get(), cat);

       if (cd && cd->isVirtualCol) {

         CHECK_EQ("rowid", cd->columnName);

         continue;

       }

       const auto fragments_it = all_tables_fragments.find(table_id);

       CHECK(fragments_it != all_tables_fragments.end());

       const auto fragments = fragments_it->second;

       auto it = plan_state_->global_to_local_col_ids_.find(*col_id);

       CHECK(it != plan_state_->global_to_local_col_ids_.end());

       CHECK_LT(static_cast<size_t>(it->second),

                plan_state_->global_to_local_col_ids_.size());

       const size_t frag_id = selected_frag_ids[local_col_to_frag_pos[it->second]];

       if (!fragments->size()) {

         return {};

       }

       CHECK_LT(frag_id, fragments->size());

       auto memory_level_for_column = memory_level;

       if (plan_state_->columns_to_fetch_.find(

               std::make_pair(col_id->getScanDesc().getTableId(), col_id->getColId())) ==

           plan_state_->columns_to_fetch_.end()) {

         memory_level_for_column = Data_Namespace::CPU_LEVEL;

       }

       if (col_id->getScanDesc().getSourceType() == InputSourceType::RESULT) {

         frag_col_buffers[it->second] = column_fetcher.getResultSetColumn(

             col_id.get(), memory_level_for_column, device_id);

       } else {

         if (needFetchAllFragments(*col_id, ra_exe_unit, selected_fragments)) {

           frag_col_buffers[it->second] =

               column_fetcher.getAllTableColumnFragments(table_id,

                                                         col_id->getColId(),

                                                         all_tables_fragments,

                                                         memory_level_for_column,

                                                         device_id);

         } else {

           frag_col_buffers[it->second] =

               column_fetcher.getOneTableColumnFragment(table_id,

                                                        frag_id,

                                                        col_id->getColId(),

                                                        all_tables_fragments,

                                                        chunks,

                                                        chunk_iterators,

                                                        memory_level_for_column,

                                                        device_id);

         }

       }

     }

     all_frag_col_buffers.push_back(frag_col_buffers);

   }

   std::tie(all_num_rows, all_frag_offsets) = getRowCountAndOffsetForAllFrags(

       ra_exe_unit, frag_ids_crossjoin, ra_exe_unit.input_descs, all_tables_fragments);

   return {all_frag_col_buffers, all_num_rows, all_frag_offsets};

 }


 // fetchChunks() is written under the assumption that multiple inputs implies a JOIN.

 // This is written under the assumption that multiple inputs implies a UNION ALL.

 FetchResult Executor::fetchUnionChunks(

     const ColumnFetcher& column_fetcher,

     const RelAlgExecutionUnit& ra_exe_unit,

     const int device_id,

     const Data_Namespace::MemoryLevel memory_level,

     const std::map<int, const TableFragments*>& all_tables_fragments,

     const FragmentsList& selected_fragments,

     const Catalog_Namespace::Catalog& cat,

     std::list<ChunkIter>& chunk_iterators,

     std::list<std::shared_ptr<Chunk_NS::Chunk>>& chunks) {

   auto timer = DEBUG_TIMER(__func__);

   INJECT_TIMER(fetchUnionChunks);


   std::vector<std::vector<const int8_t*>> all_frag_col_buffers;

   std::vector<std::vector<int64_t>> all_num_rows;

   std::vector<std::vector<uint64_t>> all_frag_offsets;


   CHECK(!selected_fragments.empty());

   CHECK_LE(2u, ra_exe_unit.input_descs.size());

   CHECK_LE(2u, ra_exe_unit.input_col_descs.size());

   using TableId = int;

   TableId const selected_table_id = selected_fragments.front().table_id;

   bool const input_descs_index =

       selected_table_id == ra_exe_unit.input_descs[1].getTableId();

   if (!input_descs_index) {

     CHECK_EQ(selected_table_id, ra_exe_unit.input_descs[0].getTableId());

   }

   bool const input_col_descs_index =

       selected_table_id ==

       (*std::next(ra_exe_unit.input_col_descs.begin()))->getScanDesc().getTableId();

   if (!input_col_descs_index) {

     CHECK_EQ(selected_table_id,

              ra_exe_unit.input_col_descs.front()->getScanDesc().getTableId());

   }

   VLOG(2) << "selected_fragments.size()=" << selected_fragments.size()

           << " selected_table_id=" << selected_table_id

           << " input_descs_index=" << int(input_descs_index)

           << " input_col_descs_index=" << int(input_col_descs_index)

           << " ra_exe_unit.input_descs="

           << shared::printContainer(ra_exe_unit.input_descs)

           << " ra_exe_unit.input_col_descs="

           << shared::printContainer(ra_exe_unit.input_col_descs);


   // Partition col_global_ids by table_id

   std::unordered_map<TableId, std::list<std::shared_ptr<const InputColDescriptor>>>

       table_id_to_input_col_descs;

   for (auto const& input_col_desc : ra_exe_unit.input_col_descs) {

     TableId const table_id = input_col_desc->getScanDesc().getTableId();

     table_id_to_input_col_descs[table_id].push_back(input_col_desc);

   }

   for (auto const& pair : table_id_to_input_col_descs) {

     std::vector<std::vector<size_t>> selected_fragments_crossjoin;

     std::vector<size_t> local_col_to_frag_pos;


     buildSelectedFragsMappingForUnion(selected_fragments_crossjoin,

                                       local_col_to_frag_pos,

                                       pair.second,

                                       selected_fragments,

                                       ra_exe_unit);


     CartesianProduct<std::vector<std::vector<size_t>>> frag_ids_crossjoin(

         selected_fragments_crossjoin);


     for (const auto& selected_frag_ids : frag_ids_crossjoin) {

       std::vector<const int8_t*> frag_col_buffers(

           plan_state_->global_to_local_col_ids_.size());

       for (const auto& col_id : pair.second) {

         CHECK(col_id);

         const int table_id = col_id->getScanDesc().getTableId();

         CHECK_EQ(table_id, pair.first);

         const auto cd = try_get_column_descriptor(col_id.get(), cat);

         if (cd && cd->isVirtualCol) {

           CHECK_EQ("rowid", cd->columnName);

           continue;

         }

         const auto fragments_it = all_tables_fragments.find(table_id);

         CHECK(fragments_it != all_tables_fragments.end());

         const auto fragments = fragments_it->second;

         auto it = plan_state_->global_to_local_col_ids_.find(*col_id);

         CHECK(it != plan_state_->global_to_local_col_ids_.end());

         CHECK_LT(static_cast<size_t>(it->second),

                  plan_state_->global_to_local_col_ids_.size());

         const size_t frag_id = ra_exe_unit.union_all

                                    ? 0

                                    : selected_frag_ids[local_col_to_frag_pos[it->second]];

         if (!fragments->size()) {

           return {};

         }

         CHECK_LT(frag_id, fragments->size());

         auto memory_level_for_column = memory_level;

         if (plan_state_->columns_to_fetch_.find(

                 std::make_pair(col_id->getScanDesc().getTableId(), col_id->getColId())) ==

             plan_state_->columns_to_fetch_.end()) {

           memory_level_for_column = Data_Namespace::CPU_LEVEL;

         }

         if (col_id->getScanDesc().getSourceType() == InputSourceType::RESULT) {

           frag_col_buffers[it->second] = column_fetcher.getResultSetColumn(

               col_id.get(), memory_level_for_column, device_id);

         } else {

           if (needFetchAllFragments(*col_id, ra_exe_unit, selected_fragments)) {

             frag_col_buffers[it->second] =

                 column_fetcher.getAllTableColumnFragments(table_id,

                                                           col_id->getColId(),

                                                           all_tables_fragments,

                                                           memory_level_for_column,

                                                           device_id);

           } else {

             frag_col_buffers[it->second] =

                 column_fetcher.getOneTableColumnFragment(table_id,

                                                          frag_id,

                                                          col_id->getColId(),

                                                          all_tables_fragments,

                                                          chunks,

                                                          chunk_iterators,

                                                          memory_level_for_column,

                                                          device_id);

           }

         }

       }

       all_frag_col_buffers.push_back(frag_col_buffers);

     }

     std::vector<std::vector<int64_t>> num_rows;

     std::vector<std::vector<uint64_t>> frag_offsets;

     std::tie(num_rows, frag_offsets) = getRowCountAndOffsetForAllFrags(

         ra_exe_unit, frag_ids_crossjoin, ra_exe_unit.input_descs, all_tables_fragments);

     all_num_rows.insert(all_num_rows.end(), num_rows.begin(), num_rows.end());

     all_frag_offsets.insert(

         all_frag_offsets.end(), frag_offsets.begin(), frag_offsets.end());

   }

   // UNION ALL hacks.

   VLOG(2) << "all_frag_col_buffers=" << shared::printContainer(all_frag_col_buffers);

   for (size_t i = 0; i < all_frag_col_buffers.front().size(); ++i) {

     all_frag_col_buffers[i & 1][i] = all_frag_col_buffers[i & 1][i ^ 1];

   }

   if (input_descs_index == input_col_descs_index) {

     std::swap(all_frag_col_buffers[0], all_frag_col_buffers[1]);

   }


   VLOG(2) << "all_frag_col_buffers=" << shared::printContainer(all_frag_col_buffers)

           << " all_num_rows=" << shared::printContainer(all_num_rows)

           << " all_frag_offsets=" << shared::printContainer(all_frag_offsets)

           << " input_col_descs_index=" << input_col_descs_index;

   return {{all_frag_col_buffers[input_descs_index]},

           {{all_num_rows[0][input_descs_index]}},

           {{all_frag_offsets[0][input_descs_index]}}};

 }


 std::vector<size_t> Executor::getFragmentCount(const FragmentsList& selected_fragments,

                                                const size_t scan_idx,

                                                const RelAlgExecutionUnit& ra_exe_unit) {

   if ((ra_exe_unit.input_descs.size() > size_t(2) || !ra_exe_unit.join_quals.empty()) &&

       scan_idx > 0 &&

       !plan_state_->join_info_.sharded_range_table_indices_.count(scan_idx) &&

       !selected_fragments[scan_idx].fragment_ids.empty()) {

     // Fetch all fragments

     return {size_t(0)};

   }


   return selected_fragments[scan_idx].fragment_ids;

 }


 void Executor::buildSelectedFragsMapping(

     std::vector<std::vector<size_t>>& selected_fragments_crossjoin,

     std::vector<size_t>& local_col_to_frag_pos,

     const std::list<std::shared_ptr<const InputColDescriptor>>& col_global_ids,

     const FragmentsList& selected_fragments,

     const RelAlgExecutionUnit& ra_exe_unit) {

   local_col_to_frag_pos.resize(plan_state_->global_to_local_col_ids_.size());

   size_t frag_pos{0};

   const auto& input_descs = ra_exe_unit.input_descs;

   for (size_t scan_idx = 0; scan_idx < input_descs.size(); ++scan_idx) {

     const int table_id = input_descs[scan_idx].getTableId();

     CHECK_EQ(selected_fragments[scan_idx].table_id, table_id);

     selected_fragments_crossjoin.push_back(

         getFragmentCount(selected_fragments, scan_idx, ra_exe_unit));

     for (const auto& col_id : col_global_ids) {

       CHECK(col_id);

       const auto& input_desc = col_id->getScanDesc();

       if (input_desc.getTableId() != table_id ||

           input_desc.getNestLevel() != static_cast<int>(scan_idx)) {

         continue;

       }

       auto it = plan_state_->global_to_local_col_ids_.find(*col_id);

       CHECK(it != plan_state_->global_to_local_col_ids_.end());

       CHECK_LT(static_cast<size_t>(it->second),

                plan_state_->global_to_local_col_ids_.size());

       local_col_to_frag_pos[it->second] = frag_pos;

     }

     ++frag_pos;

   }

 }


 void Executor::buildSelectedFragsMappingForUnion(

     std::vector<std::vector<size_t>>& selected_fragments_crossjoin,

     std::vector<size_t>& local_col_to_frag_pos,

     const std::list<std::shared_ptr<const InputColDescriptor>>& col_global_ids,

     const FragmentsList& selected_fragments,

     const RelAlgExecutionUnit& ra_exe_unit) {

   local_col_to_frag_pos.resize(plan_state_->global_to_local_col_ids_.size());

   size_t frag_pos{0};

   const auto& input_descs = ra_exe_unit.input_descs;

   for (size_t scan_idx = 0; scan_idx < input_descs.size(); ++scan_idx) {

     const int table_id = input_descs[scan_idx].getTableId();

     // selected_fragments here is from assignFragsToKernelDispatch

     // execution_kernel.fragments

     if (selected_fragments[0].table_id != table_id) {  // TODO 0

       continue;

     }

     // CHECK_EQ(selected_fragments[scan_idx].table_id, table_id);

     selected_fragments_crossjoin.push_back(

         // getFragmentCount(selected_fragments, scan_idx, ra_exe_unit));

         {size_t(1)});  // TODO

     for (const auto& col_id : col_global_ids) {

       CHECK(col_id);

       const auto& input_desc = col_id->getScanDesc();

       if (input_desc.getTableId() != table_id ||

           input_desc.getNestLevel() != static_cast<int>(scan_idx)) {

         continue;

       }

       auto it = plan_state_->global_to_local_col_ids_.find(*col_id);

       CHECK(it != plan_state_->global_to_local_col_ids_.end());

       CHECK_LT(static_cast<size_t>(it->second),

                plan_state_->global_to_local_col_ids_.size());

       local_col_to_frag_pos[it->second] = frag_pos;

     }

     ++frag_pos;

   }

 }


 namespace {


 class OutVecOwner {

  public:

   OutVecOwner(const std::vector<int64_t*>& out_vec) : out_vec_(out_vec) {}

   ~OutVecOwner() {

     for (auto out : out_vec_) {

       delete[] out;

     }

   }


  private:

   std::vector<int64_t*> out_vec_;

 };

 }  // namespace


 int32_t Executor::executePlanWithoutGroupBy(

     const RelAlgExecutionUnit& ra_exe_unit,

     const CompilationResult& compilation_result,

     const bool hoist_literals,

     ResultSetPtr& results,

     const std::vector<Analyzer::Expr*>& target_exprs,

     const ExecutorDeviceType device_type,

     std::vector<std::vector<const int8_t*>>& col_buffers,

     QueryExecutionContext* query_exe_context,

     const std::vector<std::vector<int64_t>>& num_rows,

     const std::vector<std::vector<uint64_t>>& frag_offsets,

     Data_Namespace::DataMgr* data_mgr,

     const int device_id,

     const uint32_t start_rowid,

     const uint32_t num_tables,

     RenderInfo* render_info) {

   INJECT_TIMER(executePlanWithoutGroupBy);

   auto timer = DEBUG_TIMER(__func__);

   CHECK(!results);

   if (col_buffers.empty()) {

     return 0;

   }


   RenderAllocatorMap* render_allocator_map_ptr = nullptr;

   if (render_info) {

     // TODO(adb): make sure that we either never get here in the CPU case, or if we do get

     // here, we are in non-insitu mode.

     CHECK(render_info->useCudaBuffers() || !render_info->isPotentialInSituRender())

         << "CUDA disabled rendering in the executePlanWithoutGroupBy query path is "

            "currently unsupported.";

     render_allocator_map_ptr = render_info->render_allocator_map_ptr.get();

   }


   int32_t error_code = device_type == ExecutorDeviceType::GPU ? 0 : start_rowid;

   std::vector<int64_t*> out_vec;

   const auto hoist_buf = serializeLiterals(compilation_result.literal_values, device_id);

   const auto join_hash_table_ptrs = getJoinHashTablePtrs(device_type, device_id);

   std::unique_ptr<OutVecOwner> output_memory_scope;

   if ((g_enable_dynamic_watchdog || g_enable_runtime_query_interrupt) &&

       interrupted_.load()) {

     resetInterrupt();

     throw QueryExecutionError(ERR_INTERRUPTED);

   }

   if (device_type == ExecutorDeviceType::CPU) {

     out_vec = query_exe_context->launchCpuCode(ra_exe_unit,

                                                compilation_result.native_functions,

                                                hoist_literals,

                                                hoist_buf,

                                                col_buffers,

                                                num_rows,

                                                frag_offsets,

                                                0,

                                                &error_code,

                                                num_tables,

                                                join_hash_table_ptrs);

     output_memory_scope.reset(new OutVecOwner(out_vec));

   } else {

     try {

       out_vec = query_exe_context->launchGpuCode(

           ra_exe_unit,

           compilation_result.native_functions,

           hoist_literals,

           hoist_buf,

           col_buffers,

           num_rows,

           frag_offsets,

           0,

           data_mgr,

           blockSize(),

           gridSize(),

           device_id,

           compilation_result.gpu_smem_context.getSharedMemorySize(),

           &error_code,

           num_tables,

           join_hash_table_ptrs,

           render_allocator_map_ptr);

       output_memory_scope.reset(new OutVecOwner(out_vec));

     } catch (const OutOfMemory&) {

       return ERR_OUT_OF_GPU_MEM;

     } catch (const std::exception& e) {

       LOG(FATAL) << "Error launching the GPU kernel: " << e.what();

     }

   }

   if (error_code == Executor::ERR_OVERFLOW_OR_UNDERFLOW ||

       error_code == Executor::ERR_DIV_BY_ZERO ||

       error_code == Executor::ERR_OUT_OF_TIME ||

       error_code == Executor::ERR_INTERRUPTED ||

       error_code == Executor::ERR_SINGLE_VALUE_FOUND_MULTIPLE_VALUES) {

     return error_code;

   }

   if (ra_exe_unit.estimator) {

     CHECK(!error_code);

     results =

         std::shared_ptr<ResultSet>(query_exe_context->estimator_result_set_.release());

     return 0;

   }

   std::vector<int64_t> reduced_outs;

   const auto num_frags = col_buffers.size();

   const size_t entry_count =

       device_type == ExecutorDeviceType::GPU

           ? (compilation_result.gpu_smem_context.isSharedMemoryUsed()

                  ? 1

                  : blockSize() * gridSize() * num_frags)

           : num_frags;

   if (size_t(1) == entry_count) {

     for (auto out : out_vec) {

       CHECK(out);

       reduced_outs.push_back(*out);

     }

   } else {

     size_t out_vec_idx = 0;


     for (const auto target_expr : target_exprs) {

       const auto agg_info = get_target_info(target_expr, g_bigint_count);

       CHECK(agg_info.is_agg);


       const int num_iterations = agg_info.sql_type.is_geometry()

                                      ? agg_info.sql_type.get_physical_coord_cols()

                                      : 1;


       for (int i = 0; i < num_iterations; i++) {

         int64_t val1;

         const bool float_argument_input = takes_float_argument(agg_info);

         if (is_distinct_target(agg_info)) {

           CHECK(agg_info.agg_kind == kCOUNT ||

                 agg_info.agg_kind == kAPPROX_COUNT_DISTINCT);

           val1 = out_vec[out_vec_idx][0];

           error_code = 0;

         } else {

           const auto chosen_bytes = static_cast<size_t>(

               query_exe_context->query_mem_desc_.getPaddedSlotWidthBytes(out_vec_idx));

           std::tie(val1, error_code) = Executor::reduceResults(

               agg_info.agg_kind,

               agg_info.sql_type,

               query_exe_context->getAggInitValForIndex(out_vec_idx),

               float_argument_input ? sizeof(int32_t) : chosen_bytes,

               out_vec[out_vec_idx],

               entry_count,

               false,

               float_argument_input);

         }

         if (error_code) {

           break;

         }

         reduced_outs.push_back(val1);

         if (agg_info.agg_kind == kAVG ||

             (agg_info.agg_kind == kSAMPLE &&

              (agg_info.sql_type.is_varlen() || agg_info.sql_type.is_geometry()))) {

           const auto chosen_bytes = static_cast<size_t>(

               query_exe_context->query_mem_desc_.getPaddedSlotWidthBytes(out_vec_idx +

                                                                          1));

           int64_t val2;

           std::tie(val2, error_code) = Executor::reduceResults(

               agg_info.agg_kind == kAVG ? kCOUNT : agg_info.agg_kind,

               agg_info.sql_type,

               query_exe_context->getAggInitValForIndex(out_vec_idx + 1),

               float_argument_input ? sizeof(int32_t) : chosen_bytes,

               out_vec[out_vec_idx + 1],

               entry_count,

               false,

               false);

           if (error_code) {

             break;

           }

           reduced_outs.push_back(val2);

           ++out_vec_idx;

         }

         ++out_vec_idx;

       }

     }

   }


   if (error_code) {

     return error_code;

   }


   CHECK_EQ(size_t(1), query_exe_context->query_buffers_->result_sets_.size());

   auto rows_ptr = std::shared_ptr<ResultSet>(

       query_exe_context->query_buffers_->result_sets_[0].release());

   rows_ptr->fillOneEntry(reduced_outs);

   results = std::move(rows_ptr);

   return error_code;

 }


 namespace {


 bool check_rows_less_than_needed(const ResultSetPtr& results, const size_t scan_limit) {

   CHECK(scan_limit);

   return results && results->rowCount() < scan_limit;

 }


 }  // namespace


 int32_t Executor::executePlanWithGroupBy(

     const RelAlgExecutionUnit& ra_exe_unit,

     const CompilationResult& compilation_result,

     const bool hoist_literals,

     ResultSetPtr& results,

     const ExecutorDeviceType device_type,

     std::vector<std::vector<const int8_t*>>& col_buffers,

     const std::vector<size_t> outer_tab_frag_ids,

     QueryExecutionContext* query_exe_context,

     const std::vector<std::vector<int64_t>>& num_rows,

     const std::vector<std::vector<uint64_t>>& frag_offsets,

     Data_Namespace::DataMgr* data_mgr,

     const int device_id,

     const int outer_table_id,

     const int64_t scan_limit,

     const uint32_t start_rowid,

     const uint32_t num_tables,

     RenderInfo* render_info) {

   auto timer = DEBUG_TIMER(__func__);

   INJECT_TIMER(executePlanWithGroupBy);

   CHECK(!results);

   if (col_buffers.empty()) {

     return 0;

   }

   CHECK_NE(ra_exe_unit.groupby_exprs.size(), size_t(0));

   // TODO(alex):

   // 1. Optimize size (make keys more compact).

   // 2. Resize on overflow.

   // 3. Optimize runtime.

   auto hoist_buf = serializeLiterals(compilation_result.literal_values, device_id);

   int32_t error_code = device_type == ExecutorDeviceType::GPU ? 0 : start_rowid;

   const auto join_hash_table_ptrs = getJoinHashTablePtrs(device_type, device_id);

   if ((g_enable_dynamic_watchdog || g_enable_runtime_query_interrupt) &&

       interrupted_.load()) {

     return ERR_INTERRUPTED;

   }


   RenderAllocatorMap* render_allocator_map_ptr = nullptr;

   if (render_info && render_info->useCudaBuffers()) {

     render_allocator_map_ptr = render_info->render_allocator_map_ptr.get();

   }


   VLOG(2) << "bool(ra_exe_unit.union_all)=" << bool(ra_exe_unit.union_all)

           << " ra_exe_unit.input_descs="

           << shared::printContainer(ra_exe_unit.input_descs)

           << " ra_exe_unit.input_col_descs="

           << shared::printContainer(ra_exe_unit.input_col_descs)

           << " ra_exe_unit.scan_limit=" << ra_exe_unit.scan_limit

           << " num_rows=" << shared::printContainer(num_rows)

           << " frag_offsets=" << shared::printContainer(frag_offsets)

           << " query_exe_context->query_buffers_->num_rows_="

           << query_exe_context->query_buffers_->num_rows_

           << " query_exe_context->query_mem_desc_.getEntryCount()="

           << query_exe_context->query_mem_desc_.getEntryCount()

           << " device_id=" << device_id << " outer_table_id=" << outer_table_id

           << " scan_limit=" << scan_limit << " start_rowid=" << start_rowid

           << " num_tables=" << num_tables;


   RelAlgExecutionUnit ra_exe_unit_copy = ra_exe_unit;

   // For UNION ALL, filter out input_descs and input_col_descs that are not associated

   // with outer_table_id.

   if (ra_exe_unit_copy.union_all) {

     // Sort outer_table_id first, then pop the rest off of ra_exe_unit_copy.input_descs.

     std::stable_sort(ra_exe_unit_copy.input_descs.begin(),

                      ra_exe_unit_copy.input_descs.end(),

                      [outer_table_id](auto const& a, auto const& b) {

                        return a.getTableId() == outer_table_id &&

                               b.getTableId() != outer_table_id;

                      });

     while (!ra_exe_unit_copy.input_descs.empty() &&

            ra_exe_unit_copy.input_descs.back().getTableId() != outer_table_id) {

       ra_exe_unit_copy.input_descs.pop_back();

     }

     // Filter ra_exe_unit_copy.input_col_descs.

     ra_exe_unit_copy.input_col_descs.remove_if(

         [outer_table_id](auto const& input_col_desc) {

           return input_col_desc->getScanDesc().getTableId() != outer_table_id;

         });

     query_exe_context->query_mem_desc_.setEntryCount(ra_exe_unit_copy.scan_limit);

   }


   if (device_type == ExecutorDeviceType::CPU) {

     query_exe_context->launchCpuCode(

         ra_exe_unit_copy,

         compilation_result.native_functions,

         hoist_literals,

         hoist_buf,

         col_buffers,

         num_rows,

         frag_offsets,

         ra_exe_unit_copy.union_all ? ra_exe_unit_copy.scan_limit : scan_limit,

         &error_code,

         num_tables,

         join_hash_table_ptrs);

   } else {

     try {

       query_exe_context->launchGpuCode(

           ra_exe_unit_copy,

           compilation_result.native_functions,

           hoist_literals,

           hoist_buf,

           col_buffers,

           num_rows,

           frag_offsets,

           ra_exe_unit_copy.union_all ? ra_exe_unit_copy.scan_limit : scan_limit,

           data_mgr,

           blockSize(),

           gridSize(),

           device_id,

           compilation_result.gpu_smem_context.getSharedMemorySize(),

           &error_code,

           num_tables,

           join_hash_table_ptrs,

           render_allocator_map_ptr);

     } catch (const OutOfMemory&) {

       return ERR_OUT_OF_GPU_MEM;

     } catch (const OutOfRenderMemory&) {

       return ERR_OUT_OF_RENDER_MEM;

     } catch (const StreamingTopNNotSupportedInRenderQuery&) {

       return ERR_STREAMING_TOP_N_NOT_SUPPORTED_IN_RENDER_QUERY;

     } catch (const std::exception& e) {

       LOG(FATAL) << "Error launching the GPU kernel: " << e.what();

     }

   }


   if (error_code == Executor::ERR_OVERFLOW_OR_UNDERFLOW ||

       error_code == Executor::ERR_DIV_BY_ZERO ||

       error_code == Executor::ERR_OUT_OF_TIME ||

       error_code == Executor::ERR_INTERRUPTED ||

       error_code == Executor::ERR_SINGLE_VALUE_FOUND_MULTIPLE_VALUES) {

     return error_code;

   }


   if (error_code != Executor::ERR_OVERFLOW_OR_UNDERFLOW &&

       error_code != Executor::ERR_DIV_BY_ZERO && !render_allocator_map_ptr) {

     results = query_exe_context->getRowSet(ra_exe_unit_copy,

                                            query_exe_context->query_mem_desc_);

     CHECK(results);

     VLOG(2) << "results->rowCount()=" << results->rowCount();

     results->holdLiterals(hoist_buf);

   }

   if (error_code < 0 && render_allocator_map_ptr) {

     auto const adjusted_scan_limit =

         ra_exe_unit_copy.union_all ? ra_exe_unit_copy.scan_limit : scan_limit;

     // More rows passed the filter than available slots. We don't have a count to check,

     // so assume we met the limit if a scan limit is set

     if (adjusted_scan_limit != 0) {

       return 0;

     } else {

       return error_code;

     }

   }

   if (error_code && (!scan_limit || check_rows_less_than_needed(results, scan_limit))) {

     return error_code;  // unlucky, not enough results and we ran out of slots

   }


   return 0;

 }


 std::vector<int64_t> Executor::getJoinHashTablePtrs(const ExecutorDeviceType device_type,

                                                     const int device_id) {

   std::vector<int64_t> table_ptrs;

   const auto& join_hash_tables = plan_state_->join_info_.join_hash_tables_;

   for (auto hash_table : join_hash_tables) {

     if (!hash_table) {

       CHECK(table_ptrs.empty());

       return {};

     }

     table_ptrs.push_back(hash_table->getJoinHashBuffer(

         device_type, device_type == ExecutorDeviceType::GPU ? device_id : 0));

   }

   return table_ptrs;

 }


 void Executor::nukeOldState(const bool allow_lazy_fetch,

                             const std::vector<InputTableInfo>& query_infos,

                             const RelAlgExecutionUnit* ra_exe_unit) {

   const bool contains_left_deep_outer_join =

       ra_exe_unit && std::find_if(ra_exe_unit->join_quals.begin(),

                                   ra_exe_unit->join_quals.end(),

                                   [](const JoinCondition& join_condition) {

                                     return join_condition.type == JoinType::LEFT;

                                   }) != ra_exe_unit->join_quals.end();

   cgen_state_.reset(new CgenState(query_infos, contains_left_deep_outer_join));

   plan_state_.reset(

       new PlanState(allow_lazy_fetch && !contains_left_deep_outer_join, this));

 }


 void Executor::preloadFragOffsets(const std::vector<InputDescriptor>& input_descs,

                                   const std::vector<InputTableInfo>& query_infos) {

   const auto ld_count = input_descs.size();

   auto frag_off_ptr = get_arg_by_name(cgen_state_->row_func_, "frag_row_off");

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

     CHECK_LT(i, query_infos.size());

     const auto frag_count = query_infos[i].info.fragments.size();

     if (i > 0) {

       cgen_state_->frag_offsets_.push_back(nullptr);

     } else {

       if (frag_count > 1) {

         cgen_state_->frag_offsets_.push_back(

             cgen_state_->ir_builder_.CreateLoad(frag_off_ptr));

       } else {

         cgen_state_->frag_offsets_.push_back(nullptr);

       }

     }

   }

 }


 Executor::JoinHashTableOrError Executor::buildHashTableForQualifier(

     const std::shared_ptr<Analyzer::BinOper>& qual_bin_oper,

     const std::vector<InputTableInfo>& query_infos,

     const MemoryLevel memory_level,

     const JoinHashTableInterface::HashType preferred_hash_type,

     ColumnCacheMap& column_cache) {

   if (!g_enable_overlaps_hashjoin && qual_bin_oper->is_overlaps_oper()) {

     return {nullptr, "Overlaps hash join disabled, attempting to fall back to loop join"};

   }

   // check whether the interrupt flag turns on (non kernel-time query interrupt)

   if ((g_enable_dynamic_watchdog || g_enable_runtime_query_interrupt) &&

       interrupted_.load()) {

     resetInterrupt();

     throw QueryExecutionError(ERR_INTERRUPTED);

   }

   try {

     auto tbl =

         JoinHashTableInterface::getInstance(qual_bin_oper,

                                             query_infos,

                                             memory_level,

                                             preferred_hash_type,

                                             deviceCountForMemoryLevel(memory_level),

                                             column_cache,

                                             this);

     return {tbl, ""};

   } catch (const HashJoinFail& e) {

     return {nullptr, e.what()};

   }

 }


 int8_t Executor::warpSize() const {

   CHECK(catalog_);

   const auto cuda_mgr = catalog_->getDataMgr().getCudaMgr();

   CHECK(cuda_mgr);

   const auto& dev_props = cuda_mgr->getAllDeviceProperties();

   CHECK(!dev_props.empty());

   return dev_props.front().warpSize;

 }


 unsigned Executor::gridSize() const {

   CHECK(catalog_);

   const auto cuda_mgr = catalog_->getDataMgr().getCudaMgr();

   CHECK(cuda_mgr);

   const auto& dev_props = cuda_mgr->getAllDeviceProperties();

   return grid_size_x_ ? grid_size_x_ : 2 * dev_props.front().numMPs;

 }


 unsigned Executor::blockSize() const {

   CHECK(catalog_);

   const auto cuda_mgr = catalog_->getDataMgr().getCudaMgr();

   CHECK(cuda_mgr);

   const auto& dev_props = cuda_mgr->getAllDeviceProperties();

   return block_size_x_ ? block_size_x_ : dev_props.front().maxThreadsPerBlock;

 }


 int64_t Executor::deviceCycles(int milliseconds) const {

   CHECK(catalog_);

   const auto cuda_mgr = catalog_->getDataMgr().getCudaMgr();

   CHECK(cuda_mgr);

   const auto& dev_props = cuda_mgr->getAllDeviceProperties();

   return static_cast<int64_t>(dev_props.front().clockKhz) * milliseconds;

 }


 llvm::Value* Executor::castToFP(llvm::Value* val) {

   if (!val->getType()->isIntegerTy()) {

     return val;

   }


   auto val_width = static_cast<llvm::IntegerType*>(val->getType())->getBitWidth();

   llvm::Type* dest_ty{nullptr};

   switch (val_width) {

     case 32:

       dest_ty = llvm::Type::getFloatTy(cgen_state_->context_);

       break;

     case 64:

       dest_ty = llvm::Type::getDoubleTy(cgen_state_->context_);

       break;

     default:

       LOG(FATAL) << "Unsupported FP width: " << std::to_string(val_width);

   }

   return cgen_state_->ir_builder_.CreateSIToFP(val, dest_ty);

 }


 llvm::Value* Executor::castToIntPtrTyIn(llvm::Value* val, const size_t bitWidth) {

   CHECK(val->getType()->isPointerTy());


   const auto val_ptr_type = static_cast<llvm::PointerType*>(val->getType());

   const auto val_type = val_ptr_type->getElementType();

   size_t val_width = 0;

   if (val_type->isIntegerTy()) {

     val_width = val_type->getIntegerBitWidth();

   } else {

     if (val_type->isFloatTy()) {

       val_width = 32;

     } else {

       CHECK(val_type->isDoubleTy());

       val_width = 64;

     }

   }

   CHECK_LT(size_t(0), val_width);

   if (bitWidth == val_width) {

     return val;

   }

   return cgen_state_->ir_builder_.CreateBitCast(

       val, llvm::PointerType::get(get_int_type(bitWidth, cgen_state_->context_), 0));

 }


 #define EXECUTE_INCLUDE

 #include "ArrayOps.cpp"

 #include "DateAdd.cpp"

 #include "StringFunctions.cpp"

 #undef EXECUTE_INCLUDE


 RelAlgExecutionUnit Executor::addDeletedColumn(const RelAlgExecutionUnit& ra_exe_unit,

                                                const CompilationOptions& co) {

   if (!co.add_delete_column) {

     return ra_exe_unit;

   }

   auto ra_exe_unit_with_deleted = ra_exe_unit;

   for (const auto& input_table : ra_exe_unit_with_deleted.input_descs) {

     if (input_table.getSourceType() != InputSourceType::TABLE) {

       continue;

     }

     const auto td = catalog_->getMetadataForTable(input_table.getTableId());

     CHECK(td);

     const auto deleted_cd = catalog_->getDeletedColumnIfRowsDeleted(td);

     if (!deleted_cd) {

       continue;

     }

     CHECK(deleted_cd->columnType.is_boolean());

     // check deleted column is not already present

     bool found = false;

     for (const auto& input_col : ra_exe_unit_with_deleted.input_col_descs) {

       if (input_col.get()->getColId() == deleted_cd->columnId &&

           input_col.get()->getScanDesc().getTableId() == deleted_cd->tableId &&

           input_col.get()->getScanDesc().getNestLevel() == input_table.getNestLevel()) {

         found = true;

       }

     }

     if (!found) {

       // add deleted column

       ra_exe_unit_with_deleted.input_col_descs.emplace_back(new InputColDescriptor(

           deleted_cd->columnId, deleted_cd->tableId, input_table.getNestLevel()));

     }

   }

   return ra_exe_unit_with_deleted;

 }


 namespace {


 int64_t get_hpt_scaled_value(const int64_t& val,

                              const int32_t& ldim,

                              const int32_t& rdim) {

   CHECK(ldim != rdim);

   return ldim > rdim ? val / DateTimeUtils::get_timestamp_precision_scale(ldim - rdim)

                      : val * DateTimeUtils::get_timestamp_precision_scale(rdim - ldim);

 }


 }  // namespace


 std::pair<bool, int64_t> Executor::skipFragment(

     const InputDescriptor& table_desc,

     const Fragmenter_Namespace::FragmentInfo& fragment,

     const std::list<std::shared_ptr<Analyzer::Expr>>& simple_quals,

     const std::vector<uint64_t>& frag_offsets,

     const size_t frag_idx) {

   const int table_id = table_desc.getTableId();

   for (const auto& simple_qual : simple_quals) {

     const auto comp_expr =

         std::dynamic_pointer_cast<const Analyzer::BinOper>(simple_qual);

     if (!comp_expr) {

       // is this possible?

       return {false, -1};

     }

     const auto lhs = comp_expr->get_left_operand();

     auto lhs_col = dynamic_cast<const Analyzer::ColumnVar*>(lhs);

     if (!lhs_col || !lhs_col->get_table_id() || lhs_col->get_rte_idx()) {

       // See if lhs is a simple cast that was allowed through normalize_simple_predicate

       auto lhs_uexpr = dynamic_cast<const Analyzer::UOper*>(lhs);

       if (lhs_uexpr) {

         CHECK(lhs_uexpr->get_optype() ==

               kCAST);  // We should have only been passed a cast expression

         lhs_col = dynamic_cast<const Analyzer::ColumnVar*>(lhs_uexpr->get_operand());

         if (!lhs_col || !lhs_col->get_table_id() || lhs_col->get_rte_idx()) {

           continue;

         }

       } else {

         continue;

       }

     }

     const auto rhs = comp_expr->get_right_operand();

     const auto rhs_const = dynamic_cast<const Analyzer::Constant*>(rhs);

     if (!rhs_const) {

       // is this possible?

       return {false, -1};

     }

     if (!lhs->get_type_info().is_integer() && !lhs->get_type_info().is_time()) {

       continue;

     }

     const int col_id = lhs_col->get_column_id();

     auto chunk_meta_it = fragment.getChunkMetadataMap().find(col_id);

     int64_t chunk_min{0};

     int64_t chunk_max{0};

     bool is_rowid{false};

     size_t start_rowid{0};

     if (chunk_meta_it == fragment.getChunkMetadataMap().end()) {

       auto cd = get_column_descriptor(col_id, table_id, *catalog_);

       if (cd->isVirtualCol) {

         CHECK(cd->columnName == "rowid");

         const auto& table_generation = getTableGeneration(table_id);

         start_rowid = table_generation.start_rowid;

         chunk_min = frag_offsets[frag_idx] + start_rowid;

         chunk_max = frag_offsets[frag_idx + 1] - 1 + start_rowid;

         is_rowid = true;

       }

     } else {

       const auto& chunk_type = lhs_col->get_type_info();

       chunk_min = extract_min_stat(chunk_meta_it->second->chunkStats, chunk_type);

       chunk_max = extract_max_stat(chunk_meta_it->second->chunkStats, chunk_type);

     }

     if (lhs->get_type_info().is_timestamp() &&

         (lhs_col->get_type_info().get_dimension() !=

          rhs_const->get_type_info().get_dimension()) &&

         (lhs_col->get_type_info().is_high_precision_timestamp() ||

          rhs_const->get_type_info().is_high_precision_timestamp())) {

       // If original timestamp lhs col has different precision,

       // column metadata holds value in original precision

       // therefore adjust value to match rhs precision

       const auto lhs_dimen = lhs_col->get_type_info().get_dimension();

       const auto rhs_dimen = rhs_const->get_type_info().get_dimension();

       chunk_min = get_hpt_scaled_value(chunk_min, lhs_dimen, rhs_dimen);

       chunk_max = get_hpt_scaled_value(chunk_max, lhs_dimen, rhs_dimen);

     }

     CodeGenerator code_generator(this);

     const auto rhs_val = code_generator.codegenIntConst(rhs_const)->getSExtValue();

     switch (comp_expr->get_optype()) {

       case kGE:

         if (chunk_max < rhs_val) {

           return {true, -1};

         }

         break;

       case kGT:

         if (chunk_max <= rhs_val) {

           return {true, -1};

         }

         break;

       case kLE:

         if (chunk_min > rhs_val) {

           return {true, -1};

         }

         break;

       case kLT:

         if (chunk_min >= rhs_val) {

           return {true, -1};

         }

         break;

       case kEQ:

         if (chunk_min > rhs_val || chunk_max < rhs_val) {

           return {true, -1};

         } else if (is_rowid) {

           return {false, rhs_val - start_rowid};

         }

         break;

       default:

         break;

     }

   }

   return {false, -1};

 }


 /*

  *   The skipFragmentInnerJoins process all quals stored in the execution unit's

  * join_quals and gather all the ones that meet the "simple_qual" characteristics

  * (logical expressions with AND operations, etc.). It then uses the skipFragment function

  * to decide whether the fragment should be skipped or not. The fragment will be skipped

  * if at least one of these skipFragment calls return a true statment in its first value.

  *   - The code depends on skipFragment's output to have a meaningful (anything but -1)

  * second value only if its first value is "false".

  *   - It is assumed that {false, n  > -1} has higher priority than {true, -1},

  *     i.e., we only skip if none of the quals trigger the code to update the

  * rowid_lookup_key

  *   - Only AND operations are valid and considered:

  *     - `select * from t1,t2 where A and B and C`: A, B, and C are considered for causing

  * the skip

  *     - `select * from t1,t2 where (A or B) and C`: only C is considered

  *     - `select * from t1,t2 where A or B`: none are considered (no skipping).

  *   - NOTE: (re: intermediate projections) the following two queries are fundamentally

  * implemented differently, which cause the first one to skip correctly, but the second

  * one will not skip.

  *     -  e.g. #1, select * from t1 join t2 on (t1.i=t2.i) where (A and B); -- skips if

  * possible

  *     -  e.g. #2, select * from t1 join t2 on (t1.i=t2.i and A and B); -- intermediate

  * projection, no skipping

  */

 std::pair<bool, int64_t> Executor::skipFragmentInnerJoins(

     const InputDescriptor& table_desc,

     const RelAlgExecutionUnit& ra_exe_unit,

     const Fragmenter_Namespace::FragmentInfo& fragment,

     const std::vector<uint64_t>& frag_offsets,

     const size_t frag_idx) {

   std::pair<bool, int64_t> skip_frag{false, -1};

   for (auto& inner_join : ra_exe_unit.join_quals) {

     if (inner_join.type != JoinType::INNER) {

       continue;

     }


     // extracting all the conjunctive simple_quals from the quals stored for the inner

     // join

     std::list<std::shared_ptr<Analyzer::Expr>> inner_join_simple_quals;

     for (auto& qual : inner_join.quals) {

       auto temp_qual = qual_to_conjunctive_form(qual);

       inner_join_simple_quals.insert(inner_join_simple_quals.begin(),

                                      temp_qual.simple_quals.begin(),

                                      temp_qual.simple_quals.end());

     }

     auto temp_skip_frag = skipFragment(

         table_desc, fragment, inner_join_simple_quals, frag_offsets, frag_idx);

     if (temp_skip_frag.second != -1) {

       skip_frag.second = temp_skip_frag.second;

       return skip_frag;

     } else {

       skip_frag.first = skip_frag.first || temp_skip_frag.first;

     }

   }

   return skip_frag;

 }


 AggregatedColRange Executor::computeColRangesCache(

     const std::unordered_set<PhysicalInput>& phys_inputs) {

   AggregatedColRange agg_col_range_cache;

   CHECK(catalog_);

   std::unordered_set<int> phys_table_ids;

   for (const auto& phys_input : phys_inputs) {

     phys_table_ids.insert(phys_input.table_id);

   }

   std::vector<InputTableInfo> query_infos;

   for (const int table_id : phys_table_ids) {

     query_infos.emplace_back(InputTableInfo{table_id, getTableInfo(table_id)});

   }

   for (const auto& phys_input : phys_inputs) {

     const auto cd =

         catalog_->getMetadataForColumn(phys_input.table_id, phys_input.col_id);

     CHECK(cd);

     if (ExpressionRange::typeSupportsRange(cd->columnType)) {

       const auto col_var = boost::make_unique<Analyzer::ColumnVar>(

           cd->columnType, phys_input.table_id, phys_input.col_id, 0);

       const auto col_range = getLeafColumnRange(col_var.get(), query_infos, this, false);

       agg_col_range_cache.setColRange(phys_input, col_range);

     }

   }

   return agg_col_range_cache;

 }


 StringDictionaryGenerations Executor::computeStringDictionaryGenerations(

     const std::unordered_set<PhysicalInput>& phys_inputs) {

   StringDictionaryGenerations string_dictionary_generations;

   CHECK(catalog_);

   for (const auto& phys_input : phys_inputs) {

     const auto cd =

         catalog_->getMetadataForColumn(phys_input.table_id, phys_input.col_id);

     CHECK(cd);

     const auto& col_ti =

         cd->columnType.is_array() ? cd->columnType.get_elem_type() : cd->columnType;

     if (col_ti.is_string() && col_ti.get_compression() == kENCODING_DICT) {

       const int dict_id = col_ti.get_comp_param();

       const auto dd = catalog_->getMetadataForDict(dict_id);

       CHECK(dd && dd->stringDict);

       string_dictionary_generations.setGeneration(dict_id,

                                                   dd->stringDict->storageEntryCount());

     }

   }

   return string_dictionary_generations;

 }


 TableGenerations Executor::computeTableGenerations(

     std::unordered_set<int> phys_table_ids) {

   TableGenerations table_generations;

   for (const int table_id : phys_table_ids) {

     const auto table_info = getTableInfo(table_id);

     table_generations.setGeneration(

         table_id, TableGeneration{table_info.getPhysicalNumTuples(), 0});

   }

   return table_generations;

 }


 void Executor::setupCaching(const std::unordered_set<PhysicalInput>& phys_inputs,

                             const std::unordered_set<int>& phys_table_ids) {

   CHECK(catalog_);

   row_set_mem_owner_ = std::make_shared<RowSetMemoryOwner>(Executor::getArenaBlockSize());

   agg_col_range_cache_ = computeColRangesCache(phys_inputs);

   string_dictionary_generations_ = computeStringDictionaryGenerations(phys_inputs);

   table_generations_ = computeTableGenerations(phys_table_ids);

 }


 mapd_shared_mutex& Executor::getSessionLock() {

   return executor_session_mutex_;

 }


 template <>

 void Executor::setCurrentQuerySession(const std::string& query_session,

                                       mapd_unique_lock<mapd_shared_mutex>& write_lock) {

   if (current_query_session_ == "") {

     // only set the query session if it currently has an invalid session

     current_query_session_ = query_session;

   }

 }


 template <>

 std::string& Executor::getCurrentQuerySession(

     mapd_shared_lock<mapd_shared_mutex>& read_lock) {

   return current_query_session_;

 }


 template <>

 bool Executor::checkCurrentQuerySession(const std::string& candidate_query_session,

                                         mapd_shared_lock<mapd_shared_mutex>& read_lock) {

   // if current_query_session is equal to the candidate_query_session,

   // or it is empty session we consider

   return (current_query_session_ == candidate_query_session);

 }


 template <>

 void Executor::invalidateQuerySession(mapd_unique_lock<mapd_shared_mutex>& write_lock) {

   current_query_session_ = "";

 }


 template <>

 bool Executor::addToQuerySessionList(const std::string& query_session,

                                      mapd_unique_lock<mapd_shared_mutex>& write_lock) {

   return queries_interrupt_flag_.emplace(query_session, false).second;

 }


 template <>

 bool Executor::removeFromQuerySessionList(

     const std::string& query_session,

     mapd_unique_lock<mapd_shared_mutex>& write_lock) {

   return queries_interrupt_flag_.erase(query_session);

 }


 template <>

 void Executor::setQuerySessionAsInterrupted(

     const std::string& query_session,

     mapd_unique_lock<mapd_shared_mutex>& write_lock) {

   queries_interrupt_flag_[query_session] = true;

 }


 template <>

 bool Executor::checkIsQuerySessionInterrupted(

     const std::string& query_session,

     mapd_shared_lock<mapd_shared_mutex>& read_lock) {

   auto flag_it = queries_interrupt_flag_.find(query_session);

   return flag_it != queries_interrupt_flag_.end() && flag_it->second;

 }


 void Executor::enableRuntimeQueryInterrupt(const unsigned interrupt_freq) const {

   // The only one scenario that we intentionally call this function is

   // to allow runtime query interrupt in QueryRunner for test cases.

   // Because test machine's default setting does not allow runtime query interrupt,

   // so we have to turn it on within test code if necessary.

   g_enable_runtime_query_interrupt = true;

   g_runtime_query_interrupt_frequency = interrupt_freq;

 }


 std::map<int, std::shared_ptr<Executor>> Executor::executors_;

 std::mutex Executor::execute_mutex_;

 mapd_shared_mutex Executor::executors_cache_mutex_;

 std::atomic_flag Executor::execute_spin_lock_ = ATOMIC_FLAG_INIT;

 std::string Executor::current_query_session_{""};

 InterruptFlagMap Executor::queries_interrupt_flag_;

 mapd_shared_mutex Executor::executor_session_mutex_;

Analyzer::ColumnVar::get_table_id
int get_table_id() const
Definition: Analyzer.h:194

ExecutorDispatchMode::MultifragmentKernel

CompilationOptions
Definition: CompilationOptions.h:30

Executor::ExecutionDispatch::getFragmentResults
std::vector< std::pair< ResultSetPtr, std::vector< size_t > > > & getFragmentResults()
Definition: ExecutionDispatch.cpp:412

Data_Namespace::DataMgr::getCudaMgr
CudaMgr_Namespace::CudaMgr * getCudaMgr() const
Definition: DataMgr.h:147

StreamingTopNNotSupportedInRenderQuery
Definition: RenderAllocator.h:47

anonymous_namespace{RelAlgExecutor.cpp}::is_agg
bool is_agg(const Analyzer::Expr *expr)
Definition: RelAlgExecutor.cpp:1266

catalog_
catalog_(nullptr)

agg_sum_skip_val
ALWAYS_INLINE int64_t agg_sum_skip_val(int64_t *agg, const int64_t val, const int64_t skip_val)
Definition: RuntimeFunctions.cpp:469

RelAlgExecutionUnit::target_exprs
std::vector< Analyzer::Expr * > target_exprs
Definition: RelAlgExecutionUnit.h:69

Executor::executor_session_mutex_
static mapd_shared_mutex executor_session_mutex_
Definition: Execute.h:1017

Executor::computeColRangesCache
AggregatedColRange computeColRangesCache(const std::unordered_set< PhysicalInput > &phys_inputs)
Definition: Execute.cpp:3264

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

kArenaBlockOverhead
constexpr size_t kArenaBlockOverhead
Definition: ArenaAllocator.h:71

SQLAgg
SQLAgg
Definition: sqldefs.h:71

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

threadpool.h

TableFunctionCompilationContext
Definition: TableFunctionCompilationContext.h:29

g_enable_smem_group_by
bool g_enable_smem_group_by

SpeculativeTopNMap::reduce
void reduce(SpeculativeTopNMap &that)
Definition: SpeculativeTopN.cpp:70

g_filter_push_down_low_frac
float g_filter_push_down_low_frac
Definition: Execute.cpp:86

Executor::collectAllDeviceResults
ResultSetPtr collectAllDeviceResults(ExecutionDispatch &execution_dispatch, const std::vector< Analyzer::Expr * > &target_exprs, const QueryMemoryDescriptor &query_mem_desc, const ExecutorDeviceType device_type, std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner)
Definition: Execute.cpp:1682

anonymous_namespace{Execute.cpp}::try_get_column_descriptor
const ColumnDescriptor * try_get_column_descriptor(const InputColDescriptor *col_desc, const Catalog_Namespace::Catalog &cat)
Definition: Execute.cpp:2093

join_hash_tables
const int8_t const int64_t const uint64_t const int32_t const int64_t int64_t uint32_t const int64_t * join_hash_tables
Definition: RuntimeFunctions.cpp:1287

QueryFragmentDescriptor
Definition: QueryFragmentDescriptor.h:65

agg_max_skip_val
void agg_max_skip_val(int64_t *agg, const int64_t val, const int64_t skip_val)

JoinType
JoinType
Definition: sqldefs.h:107

ExecutorDeviceType::GPU

QueryMemoryDescriptor::getEntryCount
size_t getEntryCount() const
Definition: QueryMemoryDescriptor.h:244

InPlaceSort.h

g_constrained_by_in_threshold
size_t g_constrained_by_in_threshold
Definition: Execute.cpp:95

RenderInfo::useCudaBuffers
bool useCudaBuffers() const
Definition: RenderInfo.cpp:69

InputTableInfo::info
Fragmenter_Namespace::TableInfo info
Definition: InputMetadata.h:35

QueryMemoryDescriptor::getKeyCount
size_t getKeyCount() const
Definition: QueryMemoryDescriptor.h:280

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

db_id_
db_id_(db_id)

QueryCompilationDescriptor::getDeviceType
ExecutorDeviceType getDeviceType() const
Definition: QueryCompilationDescriptor.h:65

Executor::castToFP
llvm::Value * castToFP(llvm::Value *val)
Definition: Execute.cpp:3000

ExternalCacheInvalidators.h

g_gpu_smem_threshold
size_t g_gpu_smem_threshold
Definition: Execute.cpp:109

g_bump_allocator_step_reduction
double g_bump_allocator_step_reduction
Definition: Execute.cpp:104

cat
std::string cat(Ts &&...args)
Definition: StringTransform.h:42

gpu_active_modules_device_mask_
gpu_active_modules_device_mask_(0x0)

WatchdogException
Definition: Execute.h:116

misc.h

CompilationOptions::allow_lazy_fetch
bool allow_lazy_fetch
Definition: CompilationOptions.h:35

SortAlgorithm::StreamingTopN

block_size_x_
block_size_x_(block_size_x)

num_rows
const int8_t const int64_t * num_rows
Definition: RuntimeFunctions.cpp:1287

Executor::ERR_INTERRUPTED
static const int32_t ERR_INTERRUPTED
Definition: Execute.h:1036

Catalog_Namespace::Catalog
class for a per-database catalog. also includes metadata for the current database and the current use...
Definition: Catalog.h:86

kSINGLE_VALUE
Definition: sqldefs.h:79

QueryExecutionContext::launchCpuCode
std::vector< int64_t * > launchCpuCode(const RelAlgExecutionUnit &ra_exe_unit, const std::vector< std::pair< void *, void * >> &fn_ptrs, const bool hoist_literals, const std::vector< int8_t > &literal_buff, std::vector< std::vector< const int8_t * >> col_buffers, const std::vector< std::vector< int64_t >> &num_rows, const std::vector< std::vector< uint64_t >> &frag_row_offsets, const int32_t scan_limit, int32_t *error_code, const uint32_t num_tables, const std::vector< int64_t > &join_hash_tables)
Definition: QueryExecutionContext.cpp:561

CodeGenerator
Definition: CodeGenerator.h:25

OutOfMemory
Definition: BufferMgr.h:41

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

input_table_info_cache_
input_table_info_cache_(this)
Definition: Execute.cpp:139

is_trivial_loop_join
bool is_trivial_loop_join(const std::vector< InputTableInfo > &query_infos, const RelAlgExecutionUnit &ra_exe_unit)
Definition: Execute.cpp:1097

g_enable_bump_allocator
bool g_enable_bump_allocator
Definition: Execute.cpp:103

grid_size_x_
grid_size_x_(grid_size_x)

normalize_column_pairs
std::vector< InnerOuter > normalize_column_pairs(const Analyzer::BinOper *condition, const Catalog_Namespace::Catalog &cat, const TemporaryTables *temporary_tables)
Definition: JoinHashTable.cpp:174

g_strip_join_covered_quals
bool g_strip_join_covered_quals
Definition: Execute.cpp:94

udf_gpu_module
std::unique_ptr< llvm::Module > udf_gpu_module
Definition: NativeCodegen.cpp:30

get_shard_count
size_t get_shard_count(const Analyzer::BinOper *join_condition, const Executor *executor)
Definition: JoinHashTable.cpp:263

Executor::getRowSetMemoryOwner
const std::shared_ptr< RowSetMemoryOwner > getRowSetMemoryOwner() const
Definition: Execute.cpp:257

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Definition: Execute.h:465

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Definition: Execute.cpp:1144

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Definition: Execute.cpp:3311

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Definition: Execute.cpp:630

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Definition: Execute.h:253

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void setQuerySessionAsInterrupted(const std::string &query_session, SESSION_MAP_LOCK &write_lock)

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Definition: RelAlgExecutionUnit.h:92

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Definition: Fragmenter.h:161

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Definition: Execute.cpp:1589

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Definition: PlanState.h:41

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Definition: Execute.cpp:74

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Definition: Execute.cpp:1001

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Definition: Execute.cpp:79

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Definition: TableFunctionExecutionContext.h:28

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Definition: CacheInvalidator.h:23

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Definition: Execute.cpp:613

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Definition: GpuSharedMemoryContext.h:28

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Definition: Execute.cpp:3020

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Definition: Execute.cpp:2291

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Container for compilation results and assorted options for a single execution unit.

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Definition: Execute.cpp:227

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Definition: InlineNullValues.h:128

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Definition: Execute.cpp:1776

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Definition: QueryFragmentDescriptor.h:55

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Definition: sqltypes.h:415

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bool needFetchAllFragments(const InputColDescriptor &col_desc, const RelAlgExecutionUnit &ra_exe_unit, const FragmentsList &selected_fragments) const
Definition: Execute.cpp:2170

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Definition: Analyzer.h:190

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Definition: StringTransform.cpp:93

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static size_t literalBytes(const CgenState::LiteralValue &lit)
Definition: CgenState.h:345

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mapd_shared_mutex & getSessionLock()
Definition: Execute.cpp:3331

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Definition: Execute.h:485

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Definition: Execute.cpp:90

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gpu_code_cache_(code_cache_size)

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Definition: QueryMemoryDescriptor.cpp:731

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Definition: Execute.cpp:99

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Definition: Execute.cpp:172

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Definition: GroupByAndAggregate.h:403

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Definition: Execute.cpp:81

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Definition: Execute.cpp:265

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cpu_code_cache_(code_cache_size)

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Definition: CompilationOptions.h:28

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Definition: CompilationOptions.h:70

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Definition: Execute.h:421

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Definition: ResultSetReductionJIT.h:54

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Definition: Execute.cpp:78

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Definition: sqltypes.h:49

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Definition: InputDescriptors.h:27

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Definition: SysCatalog.h:189

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Definition: Execute.cpp:2967

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Definition: Execute.cpp:75

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ResultSetPtr reduceSpeculativeTopN(const RelAlgExecutionUnit &, std::vector< std::pair< ResultSetPtr, std::vector< size_t >>> &all_fragment_results, std::shared_ptr< RowSetMemoryOwner >, const QueryMemoryDescriptor &) const
Definition: Execute.cpp:950

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Definition: Execute.cpp:89

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Definition: QueryMemoryDescriptor.h:184

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Definition: Execute.h:1028

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Definition: SysCatalog.h:256

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Definition: SpeculativeTopN.h:59

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Definition: CompilationOptions.h:69

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Definition: Execute.cpp:80

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Definition: Execute.h:123

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Definition: Execute.cpp:91

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Definition: Execute.cpp:989

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Definition: Execute.h:177

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Definition: Execute.cpp:2992

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Definition: TableGenerations.h:28

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Definition: sqltypes.h:411

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Definition: RenderInfo.h:30

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const JoinQualsPerNestingLevel join_quals
Definition: RelAlgExecutionUnit.h:67

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ResultSetPtr reduceMultiDeviceResults(const RelAlgExecutionUnit &, std::vector< std::pair< ResultSetPtr, std::vector< size_t >>> &all_fragment_results, std::shared_ptr< RowSetMemoryOwner >, const QueryMemoryDescriptor &) const
Definition: Execute.cpp:866

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Definition: QueryFragmentDescriptor.h:139

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Used by Fragmenter classes to store info about each fragment - the fragment id and number of tuples(r...
Definition: Fragmenter.h:78

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void agg_min_double_skip_val(int64_t *agg, const double val, const double skip_val)

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Definition: Execute.cpp:253

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const std::vector< uint64_t > & getFragOffsets() const
Definition: ExecutionDispatch.cpp:398

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Definition: Fragmenter.h:122

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std::map< size_t, std::vector< uint64_t > > get_table_id_to_frag_offsets(const std::vector< InputDescriptor > &input_descs, const std::map< int, const TableFragments * > &all_tables_fragments)
Definition: Execute.cpp:2102

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Definition: CompilationOptions.h:38

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Definition: InputDescriptors.h:72

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int64_t inline_null_val(const SQLTypeInfo &ti, const bool float_argument_input)
Definition: Execute.cpp:1574

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size_t g_big_group_threshold
Definition: Execute.cpp:96

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Definition: Execute.h:1034

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Definition: MemoryLevel.h:21

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float g_filter_push_down_high_frac
Definition: Execute.cpp:87

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static InterruptFlagMap queries_interrupt_flag_
Definition: Execute.h:1020

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int getTableId() const
Definition: InputDescriptors.h:36

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Definition: Execute.h:1035

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Definition: Execute.cpp:2532

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Definition: Execute.cpp:2976

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Definition: Execute.h:468

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Definition: Execute.cpp:277

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Definition: Execute.h:338

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Definition: Execute.h:250

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Definition: Analyzer.h:436

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Descriptor for the fragments required for a query.

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Definition: Execute.cpp:3322

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void clearMetaInfoCache()
Definition: Execute.cpp:344

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Definition: Execute.h:148

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Definition: MemoryLevel.h:21

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static size_t shard_count_for_top_groups(const RelAlgExecutionUnit &ra_exe_unit, const Catalog_Namespace::Catalog &catalog)
Definition: GroupByAndAggregate.cpp:1918

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Definition: RelAlgExecutionUnit.h:62

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Definition: Execute.h:244

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Definition: QueryExecutionContext.h:35

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Definition: RelAlgExecutionUnit.h:72

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Definition: RelAlgExecutionUnit.h:55

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Definition: run_benchmark_import.py:89

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Definition: run_benchmark_import.py:441

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Definition: Execute.cpp:2031

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Definition: Execute.cpp:1547

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Definition: QueryMemoryDescriptor.cpp:831

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Definition: TableFunctionCompilationContext.cpp:72