_arrow_result_set_converter_8cpp_source.html

 /*

  * Copyright 2019 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 "../Shared/DateConverters.h"

 #include "ArrowResultSet.h"

 #include "Execute.h"

 #include "arrow/ipc/dictionary.h"

 #include "arrow/ipc/options.h"


 #ifndef _MSC_VER

 #include <sys/ipc.h>

 #include <sys/shm.h>

 #include <sys/types.h>

 #else

 // IPC shared memory not yet supported on windows

 using key_t = size_t;

 #define IPC_PRIVATE 0

 #endif


 #include <algorithm>

 #include <cerrno>

 #include <cstdio>

 #include <cstdlib>

 #include <future>

 #include <string>


 #include "arrow/api.h"

 #include "arrow/io/memory.h"

 #include "arrow/ipc/api.h"


 #include "Shared/ArrowUtil.h"


 #ifdef HAVE_CUDA

 #include <arrow/gpu/cuda_api.h>

 #include <cuda.h>

 #endif  // HAVE_CUDA


 #define ARROW_RECORDBATCH_MAKE arrow::RecordBatch::Make


 #define ARROW_CONVERTER_DEBUG true


 #define ARROW_LOG(category) \

   VLOG(1) << "[Arrow]"      \

           << "[" << category "] "


 namespace {


 /* We can create Arrow buffers which refer memory owned by ResultSet.

    For safe memory access we should keep a ResultSetPtr to keep

    data live while buffer lives. Use this custom buffer for that. */

 class ResultSetBuffer : public arrow::Buffer {

  public:

   ResultSetBuffer(const uint8_t* buf, size_t size, ResultSetPtr rs)

       : arrow::Buffer(buf, size), _rs(rs) {}


  private:

   ResultSetPtr _rs;

 };


 inline SQLTypes get_dict_index_type(const SQLTypeInfo& ti) {

   CHECK(ti.is_dict_encoded_string());

   switch (ti.get_size()) {

     case 1:

       return kTINYINT;

     case 2:

       return kSMALLINT;

     case 4:

       return kINT;

     case 8:

       return kBIGINT;

     default:

       CHECK(false);

   }

   return ti.get_type();

 }


 inline SQLTypes get_physical_type(const SQLTypeInfo& ti) {

   auto logical_type = ti.get_type();

   if (IS_INTEGER(logical_type)) {

     switch (ti.get_size()) {

       case 1:

         return kTINYINT;

       case 2:

         return kSMALLINT;

       case 4:

         return kINT;

       case 8:

         return kBIGINT;

       default:

         CHECK(false);

     }

   }

   return logical_type;

 }


 template <typename TYPE, typename VALUE_ARRAY_TYPE>

 void create_or_append_value(const ScalarTargetValue& val_cty,

                             std::shared_ptr<ValueArray>& values,

                             const size_t max_size) {

   auto pval_cty = boost::get<VALUE_ARRAY_TYPE>(&val_cty);

   CHECK(pval_cty);

   auto val_ty = static_cast<TYPE>(*pval_cty);

   if (!values) {

     values = std::make_shared<ValueArray>(std::vector<TYPE>());

     boost::get<std::vector<TYPE>>(*values).reserve(max_size);

   }

   CHECK(values);

   auto values_ty = boost::get<std::vector<TYPE>>(values.get());

   CHECK(values_ty);

   values_ty->push_back(val_ty);

 }


 template <typename TYPE>

 void create_or_append_validity(const ScalarTargetValue& value,

                                const SQLTypeInfo& col_type,

                                std::shared_ptr<std::vector<bool>>& null_bitmap,

                                const size_t max_size) {

   if (col_type.get_notnull()) {

     CHECK(!null_bitmap);

     return;

   }

   auto pvalue = boost::get<TYPE>(&value);

   CHECK(pvalue);

   bool is_valid = false;

   if (col_type.is_boolean()) {

     is_valid = inline_int_null_val(col_type) != static_cast<int8_t>(*pvalue);

   } else if (col_type.is_dict_encoded_string()) {

     is_valid = inline_int_null_val(col_type) != static_cast<int32_t>(*pvalue);

   } else if (col_type.is_integer() || col_type.is_time()) {

     is_valid = inline_int_null_val(col_type) != static_cast<int64_t>(*pvalue);

   } else if (col_type.is_fp()) {

     is_valid = inline_fp_null_val(col_type) != static_cast<double>(*pvalue);

   } else if (col_type.is_decimal()) {

     is_valid = inline_int_null_val(col_type) != static_cast<int64_t>(*pvalue);

   } else {

     UNREACHABLE();

   }


   if (!null_bitmap) {

     null_bitmap = std::make_shared<std::vector<bool>>();

     null_bitmap->reserve(max_size);

   }

   CHECK(null_bitmap);

   null_bitmap->push_back(is_valid);

 }


 template <typename TYPE, typename enable = void>

 class null_type {};


 template <typename TYPE>

 struct null_type<TYPE, std::enable_if_t<std::is_integral<TYPE>::value>> {

   using type = typename std::make_signed<TYPE>::type;

   static constexpr type value = inline_int_null_value<type>();

 };


 template <typename TYPE>

 struct null_type<TYPE, std::enable_if_t<std::is_floating_point<TYPE>::value>> {

   using type = TYPE;

   static constexpr type value = inline_fp_null_value<type>();

 };


 template <typename TYPE>

 using null_type_t = typename null_type<TYPE>::type;


 template <typename C_TYPE,

           typename ARROW_TYPE = typename arrow::CTypeTraits<C_TYPE>::ArrowType>

 void convert_column(ResultSetPtr result,

                     size_t col,

                     size_t entry_count,

                     std::shared_ptr<arrow::Array>& out) {

   CHECK(sizeof(C_TYPE) == result->getColType(col).get_size());


   std::shared_ptr<arrow::Buffer> values;

   std::shared_ptr<arrow::Buffer> is_valid;

   const int64_t buf_size = entry_count * sizeof(C_TYPE);

   if (result->isZeroCopyColumnarConversionPossible(col)) {

     values.reset(new ResultSetBuffer(

         reinterpret_cast<const uint8_t*>(result->getColumnarBuffer(col)),

         buf_size,

         result));

   } else {

     auto res = arrow::AllocateBuffer(buf_size);

     CHECK(res.ok());

     values = std::move(res).ValueOrDie();

     result->copyColumnIntoBuffer(

         col, reinterpret_cast<int8_t*>(values->mutable_data()), buf_size);

   }


   int64_t null_count = 0;

   auto res = arrow::AllocateBuffer((entry_count + 7) / 8);

   CHECK(res.ok());

   is_valid = std::move(res).ValueOrDie();


   auto is_valid_data = is_valid->mutable_data();


   const null_type_t<C_TYPE>* vals =

       reinterpret_cast<const null_type_t<C_TYPE>*>(values->data());

   null_type_t<C_TYPE> null_val = null_type<C_TYPE>::value;


   size_t unroll_count = entry_count & 0xFFFFFFFFFFFFFFF8ULL;

   for (size_t i = 0; i < unroll_count; i += 8) {

     uint8_t valid_byte = 0;

     uint8_t valid;

     valid = vals[i + 0] != null_val;

     valid_byte |= valid << 0;

     null_count += !valid;

     valid = vals[i + 1] != null_val;

     valid_byte |= valid << 1;

     null_count += !valid;

     valid = vals[i + 2] != null_val;

     valid_byte |= valid << 2;

     null_count += !valid;

     valid = vals[i + 3] != null_val;

     valid_byte |= valid << 3;

     null_count += !valid;

     valid = vals[i + 4] != null_val;

     valid_byte |= valid << 4;

     null_count += !valid;

     valid = vals[i + 5] != null_val;

     valid_byte |= valid << 5;

     null_count += !valid;

     valid = vals[i + 6] != null_val;

     valid_byte |= valid << 6;

     null_count += !valid;

     valid = vals[i + 7] != null_val;

     valid_byte |= valid << 7;

     null_count += !valid;

     is_valid_data[i >> 3] = valid_byte;

   }

   if (unroll_count != entry_count) {

     uint8_t valid_byte = 0;

     for (size_t i = unroll_count; i < entry_count; ++i) {

       bool valid = vals[i] != null_val;

       valid_byte |= valid << (i & 7);

       null_count += !valid;

     }

     is_valid_data[unroll_count >> 3] = valid_byte;

   }


   if (!null_count) {

     is_valid.reset();

   }


   // TODO: support date/time + scaling

   // TODO: support booleans

   if (null_count) {

     out.reset(

         new arrow::NumericArray<ARROW_TYPE>(entry_count, values, is_valid, null_count));

   } else {

     out.reset(new arrow::NumericArray<ARROW_TYPE>(entry_count, values));

   }

 }


 #ifndef _MSC_VER

 std::pair<key_t, void*> get_shm(size_t shmsz) {

   if (!shmsz) {

     return std::make_pair(IPC_PRIVATE, nullptr);

   }

   // Generate a new key for a shared memory segment. Keys to shared memory segments

   // are OS global, so we need to try a new key if we encounter a collision. It seems

   // incremental keygen would be deterministically worst-case. If we use a hash

   // (like djb2) + nonce, we could still get collisions if multiple clients specify

   // the same nonce, so using rand() in lieu of a better approach

   // TODO(ptaylor): Is this common? Are these assumptions true?

   auto key = static_cast<key_t>(rand());

   int shmid = -1;

   // IPC_CREAT - indicates we want to create a new segment for this key if it doesn't

   // exist IPC_EXCL - ensures failure if a segment already exists for this key

   while ((shmid = shmget(key, shmsz, IPC_CREAT | IPC_EXCL | 0666)) < 0) {

     // If shmget fails and errno is one of these four values, try a new key.

     // TODO(ptaylor): is checking for the last three values really necessary? Checking

     // them by default to be safe. EEXIST - a shared memory segment is already associated

     // with this key EACCES - a shared memory segment is already associated with this key,

     // but we don't have permission to access it EINVAL - a shared memory segment is

     // already associated with this key, but the size is less than shmsz ENOENT -

     // IPC_CREAT was not set in shmflg and no shared memory segment associated with key

     // was found

     if (!(errno & (EEXIST | EACCES | EINVAL | ENOENT))) {

       throw std::runtime_error("failed to create a shared memory");

     }

     key = static_cast<key_t>(rand());

   }

   // get a pointer to the shared memory segment

   auto ipc_ptr = shmat(shmid, NULL, 0);

   if (reinterpret_cast<int64_t>(ipc_ptr) == -1) {

     throw std::runtime_error("failed to attach a shared memory");

   }


   return std::make_pair(key, ipc_ptr);

 }

 #endif


 std::pair<key_t, std::shared_ptr<arrow::Buffer>> get_shm_buffer(size_t size) {

 #ifdef _MSC_VER

   throw std::runtime_error("Arrow IPC not yet supported on Windows.");

   return std::make_pair(0, nullptr);

 #else

   auto [key, ipc_ptr] = get_shm(size);

   std::shared_ptr<arrow::Buffer> buffer(

       new arrow::MutableBuffer(static_cast<uint8_t*>(ipc_ptr), size));

   return std::make_pair<key_t, std::shared_ptr<arrow::Buffer>>(std::move(key),

                                                                std::move(buffer));

 #endif

 }


 }  // namespace


 namespace arrow {


 key_t get_and_copy_to_shm(const std::shared_ptr<Buffer>& data) {

 #ifdef _MSC_VER

   throw std::runtime_error("Arrow IPC not yet supported on Windows.");

 #else

   auto [key, ipc_ptr] = get_shm(data->size());

   // copy the arrow records buffer to shared memory

   // TODO(ptaylor): I'm sure it's possible to tell Arrow's RecordBatchStreamWriter to

   // write directly to the shared memory segment as a sink

   memcpy(ipc_ptr, data->data(), data->size());

   // detach from the shared memory segment

   shmdt(ipc_ptr);

   return key;

 #endif

 }


 }  // namespace arrow


 ArrowResult ArrowResultSetConverter::getArrowResult() const {

   auto timer = DEBUG_TIMER(__func__);

   std::shared_ptr<arrow::RecordBatch> record_batch = convertToArrow();


   struct BuildResultParams {

     int64_t schemaSize() const {

       return serialized_schema ? serialized_schema->size() : 0;

     };

     int64_t dictSize() const { return serialized_dict ? serialized_dict->size() : 0; };

     int64_t totalSize() const { return schemaSize() + records_size + dictSize(); }

     bool hasRecordBatch() const { return records_size > 0; }

     bool hasDict() const { return dictSize() > 0; }


     int64_t records_size{0};

     std::shared_ptr<arrow::Buffer> serialized_schema{nullptr};

     std::shared_ptr<arrow::Buffer> serialized_dict{nullptr};

   } result_params;


   if (device_type_ == ExecutorDeviceType::CPU ||

       transport_method_ == ArrowTransport::WIRE) {

     const auto getWireResult = [&]() -> ArrowResult {

       auto timer = DEBUG_TIMER("serialize batch to wire");

       const auto total_size = result_params.totalSize();

       std::vector<char> record_handle_data(total_size);

       auto serialized_records =

           arrow::MutableBuffer::Wrap(record_handle_data.data(), total_size);


       ARROW_ASSIGN_OR_THROW(auto writer, arrow::Buffer::GetWriter(serialized_records));


       ARROW_THROW_NOT_OK(writer->Write(

           reinterpret_cast<const uint8_t*>(result_params.serialized_schema->data()),

           result_params.schemaSize()));


       if (result_params.hasDict()) {

         ARROW_THROW_NOT_OK(writer->Write(

             reinterpret_cast<const uint8_t*>(result_params.serialized_dict->data()),

             result_params.dictSize()));

       }


       arrow::io::FixedSizeBufferWriter stream(SliceMutableBuffer(

           serialized_records, result_params.schemaSize() + result_params.dictSize()));


       if (result_params.hasRecordBatch()) {

         ARROW_THROW_NOT_OK(arrow::ipc::SerializeRecordBatch(

             *record_batch, arrow::ipc::IpcWriteOptions::Defaults(), &stream));

       }


       return {std::vector<char>(0),

               0,

               std::vector<char>(0),

               serialized_records->size(),

               std::string{""},

               std::move(record_handle_data)};

     };


     const auto getShmResult = [&]() -> ArrowResult {

       auto timer = DEBUG_TIMER("serialize batch to shared memory");

       std::shared_ptr<arrow::Buffer> serialized_records;

       std::vector<char> schema_handle_buffer;

       std::vector<char> record_handle_buffer(sizeof(key_t), 0);

       key_t records_shm_key = IPC_PRIVATE;

       const int64_t total_size = result_params.totalSize();


       std::tie(records_shm_key, serialized_records) = get_shm_buffer(total_size);


       memcpy(serialized_records->mutable_data(),

              result_params.serialized_schema->data(),

              (size_t)result_params.schemaSize());


       if (result_params.hasDict()) {

         memcpy(serialized_records->mutable_data() + result_params.schemaSize(),

                result_params.serialized_dict->data(),

                (size_t)result_params.dictSize());

       }


       arrow::io::FixedSizeBufferWriter stream(SliceMutableBuffer(

           serialized_records, result_params.schemaSize() + result_params.dictSize()));


       if (result_params.hasRecordBatch()) {

         ARROW_THROW_NOT_OK(arrow::ipc::SerializeRecordBatch(

             *record_batch, arrow::ipc::IpcWriteOptions::Defaults(), &stream));

       }


       memcpy(&record_handle_buffer[0],

              reinterpret_cast<const unsigned char*>(&records_shm_key),

              sizeof(key_t));


       return {schema_handle_buffer,

               0,

               record_handle_buffer,

               serialized_records->size(),

               std::string{""}};

     };


     arrow::ipc::DictionaryFieldMapper mapper(*record_batch->schema());

     auto options = arrow::ipc::IpcWriteOptions::Defaults();

     auto dict_stream = arrow::io::BufferOutputStream::Create(1024).ValueOrDie();


     // If our record batch is going to be empty, we omit it entirely,

     // only serializing the schema.

     if (!record_batch->num_rows()) {

       ARROW_ASSIGN_OR_THROW(result_params.serialized_schema,

                             arrow::ipc::SerializeSchema(*record_batch->schema(),

                                                         arrow::default_memory_pool()));


       switch (transport_method_) {

         case ArrowTransport::WIRE:

           return getWireResult();

         case ArrowTransport::SHARED_MEMORY:

           return getShmResult();

         default:

           UNREACHABLE();

       }

     }


     ARROW_ASSIGN_OR_THROW(auto dictionaries, CollectDictionaries(*record_batch, mapper));


     ARROW_LOG("CPU") << "found " << dictionaries.size() << " dictionaries";


     for (auto& pair : dictionaries) {

       arrow::ipc::IpcPayload payload;

       int64_t dictionary_id = pair.first;

       const auto& dictionary = pair.second;


       ARROW_THROW_NOT_OK(

           GetDictionaryPayload(dictionary_id, dictionary, options, &payload));

       int32_t metadata_length = 0;

       ARROW_THROW_NOT_OK(

           WriteIpcPayload(payload, options, dict_stream.get(), &metadata_length));

     }

     result_params.serialized_dict = dict_stream->Finish().ValueOrDie();


     ARROW_ASSIGN_OR_THROW(result_params.serialized_schema,

                           arrow::ipc::SerializeSchema(*record_batch->schema(),

                                                       arrow::default_memory_pool()));


     ARROW_THROW_NOT_OK(

         arrow::ipc::GetRecordBatchSize(*record_batch, &result_params.records_size));


     switch (transport_method_) {

       case ArrowTransport::WIRE:

         return getWireResult();

       case ArrowTransport::SHARED_MEMORY:

         return getShmResult();

       default:

         UNREACHABLE();

     }

   }

 #ifdef HAVE_CUDA

   CHECK(device_type_ == ExecutorDeviceType::GPU);


   // Copy the schema to the schema handle

   auto out_stream_result = arrow::io::BufferOutputStream::Create(1024);

   ARROW_THROW_NOT_OK(out_stream_result.status());

   auto out_stream = std::move(out_stream_result).ValueOrDie();


   arrow::ipc::DictionaryFieldMapper mapper(*record_batch->schema());

   arrow::ipc::DictionaryMemo current_memo;

   arrow::ipc::DictionaryMemo serialized_memo;


   arrow::ipc::IpcPayload schema_payload;

   ARROW_THROW_NOT_OK(arrow::ipc::GetSchemaPayload(*record_batch->schema(),

                                                   arrow::ipc::IpcWriteOptions::Defaults(),

                                                   mapper,

                                                   &schema_payload));

   int32_t schema_payload_length = 0;

   ARROW_THROW_NOT_OK(arrow::ipc::WriteIpcPayload(schema_payload,

                                                  arrow::ipc::IpcWriteOptions::Defaults(),

                                                  out_stream.get(),

                                                  &schema_payload_length));

   ARROW_ASSIGN_OR_THROW(auto dictionaries, CollectDictionaries(*record_batch, mapper));

   ARROW_LOG("GPU") << "Dictionary "

                    << "found dicts: " << dictionaries.size();


   ARROW_THROW_NOT_OK(

       arrow::ipc::internal::CollectDictionaries(*record_batch, &current_memo));


   // now try a dictionary

   std::shared_ptr<arrow::Schema> dummy_schema;

   std::vector<std::shared_ptr<arrow::RecordBatch>> dict_batches;


   for (const auto& pair : dictionaries) {

     arrow::ipc::IpcPayload payload;

     const auto& dict_id = pair.first;

     CHECK_GE(dict_id, 0);

     ARROW_LOG("GPU") << "Dictionary "

                      << "dict_id: " << dict_id;

     const auto& dict = pair.second;

     CHECK(dict);


     if (!dummy_schema) {

       auto dummy_field = std::make_shared<arrow::Field>("", dict->type());

       dummy_schema = std::make_shared<arrow::Schema>(

           std::vector<std::shared_ptr<arrow::Field>>{dummy_field});

     }

     dict_batches.emplace_back(

         arrow::RecordBatch::Make(dummy_schema, dict->length(), {dict}));

   }


   if (!dict_batches.empty()) {

     ARROW_THROW_NOT_OK(arrow::ipc::WriteRecordBatchStream(

         dict_batches, arrow::ipc::IpcWriteOptions::Defaults(), out_stream.get()));

   }


   auto complete_ipc_stream = out_stream->Finish();

   ARROW_THROW_NOT_OK(complete_ipc_stream.status());

   auto serialized_records = std::move(complete_ipc_stream).ValueOrDie();


   const auto record_key = arrow::get_and_copy_to_shm(serialized_records);

   std::vector<char> schema_record_key_buffer(sizeof(key_t), 0);

   memcpy(&schema_record_key_buffer[0],

          reinterpret_cast<const unsigned char*>(&record_key),

          sizeof(key_t));


   arrow::cuda::CudaDeviceManager* manager;

   ARROW_ASSIGN_OR_THROW(manager, arrow::cuda::CudaDeviceManager::Instance());

   std::shared_ptr<arrow::cuda::CudaContext> context;

   ARROW_ASSIGN_OR_THROW(context, manager->GetContext(device_id_));


   std::shared_ptr<arrow::cuda::CudaBuffer> device_serialized;

   ARROW_ASSIGN_OR_THROW(device_serialized,

                         SerializeRecordBatch(*record_batch, context.get()));


   std::shared_ptr<arrow::cuda::CudaIpcMemHandle> cuda_handle;

   ARROW_ASSIGN_OR_THROW(cuda_handle, device_serialized->ExportForIpc());


   std::shared_ptr<arrow::Buffer> serialized_cuda_handle;

   ARROW_ASSIGN_OR_THROW(serialized_cuda_handle,

                         cuda_handle->Serialize(arrow::default_memory_pool()));


   std::vector<char> record_handle_buffer(serialized_cuda_handle->size(), 0);

   memcpy(&record_handle_buffer[0],

          serialized_cuda_handle->data(),

          serialized_cuda_handle->size());


   return {schema_record_key_buffer,

           serialized_records->size(),

           record_handle_buffer,

           serialized_cuda_handle->size(),

           serialized_cuda_handle->ToString()};

 #else

   UNREACHABLE();

   return {std::vector<char>{}, 0, std::vector<char>{}, 0, ""};

 #endif

 }


 ArrowResultSetConverter::SerializedArrowOutput

 ArrowResultSetConverter::getSerializedArrowOutput(

     arrow::ipc::DictionaryFieldMapper* mapper) const {

   auto timer = DEBUG_TIMER(__func__);

   std::shared_ptr<arrow::RecordBatch> arrow_copy = convertToArrow();

   std::shared_ptr<arrow::Buffer> serialized_records, serialized_schema;


   ARROW_ASSIGN_OR_THROW(

       serialized_schema,

       arrow::ipc::SerializeSchema(*arrow_copy->schema(), arrow::default_memory_pool()));


   if (arrow_copy->num_rows()) {

     auto timer = DEBUG_TIMER("serialize records");

     ARROW_THROW_NOT_OK(arrow_copy->Validate());

     ARROW_ASSIGN_OR_THROW(serialized_records,

                           arrow::ipc::SerializeRecordBatch(

                               *arrow_copy, arrow::ipc::IpcWriteOptions::Defaults()));

   } else {

     ARROW_ASSIGN_OR_THROW(serialized_records, arrow::AllocateBuffer(0));

   }

   return {serialized_schema, serialized_records};

 }


 std::shared_ptr<arrow::RecordBatch> ArrowResultSetConverter::convertToArrow() const {

   auto timer = DEBUG_TIMER(__func__);

   const auto col_count = results_->colCount();

   std::vector<std::shared_ptr<arrow::Field>> fields;

   CHECK(col_names_.empty() || col_names_.size() == col_count);

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

     const auto ti = results_->getColType(i);

     fields.push_back(makeField(col_names_.empty() ? "" : col_names_[i], ti));

   }

 #if ARROW_CONVERTER_DEBUG

   VLOG(1) << "Arrow fields: ";

   for (const auto& f : fields) {

     VLOG(1) << "\t" << f->ToString(true);

   }

 #endif

   return getArrowBatch(arrow::schema(fields));

 }


 std::shared_ptr<arrow::RecordBatch> ArrowResultSetConverter::getArrowBatch(

     const std::shared_ptr<arrow::Schema>& schema) const {

   std::vector<std::shared_ptr<arrow::Array>> result_columns;


   // First, check if the result set is empty.

   // If so, we return an arrow result set that only

   // contains the schema (no record batch will be serialized).

   if (results_->isEmpty()) {

     return ARROW_RECORDBATCH_MAKE(schema, 0, result_columns);

   }


   const size_t entry_count = top_n_ < 0

                                  ? results_->entryCount()

                                  : std::min(size_t(top_n_), results_->entryCount());


   const auto col_count = results_->colCount();

   size_t row_count = 0;


   result_columns.resize(col_count);

   std::vector<ColumnBuilder> builders(col_count);


   // Create array builders

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

     initializeColumnBuilder(builders[i], results_->getColType(i), schema->field(i));

   }


   // TODO(miyu): speed up for columnar buffers

   auto fetch = [&](std::vector<std::shared_ptr<ValueArray>>& value_seg,

                    std::vector<std::shared_ptr<std::vector<bool>>>& null_bitmap_seg,

                    const std::vector<bool>& non_lazy_cols,

                    const size_t start_entry,

                    const size_t end_entry) -> size_t {

     CHECK_EQ(value_seg.size(), col_count);

     CHECK_EQ(null_bitmap_seg.size(), col_count);

     const auto entry_count = end_entry - start_entry;

     size_t seg_row_count = 0;

     for (size_t i = start_entry; i < end_entry; ++i) {

       auto row = results_->getRowAtNoTranslations(i, non_lazy_cols);

       if (row.empty()) {

         continue;

       }

       ++seg_row_count;

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

         if (!non_lazy_cols.empty() && non_lazy_cols[j]) {

           continue;

         }


         auto scalar_value = boost::get<ScalarTargetValue>(&row[j]);

         // TODO(miyu): support more types other than scalar.

         CHECK(scalar_value);

         const auto& column = builders[j];

         switch (column.physical_type) {

           case kBOOLEAN:

             create_or_append_value<bool, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kTINYINT:

             create_or_append_value<int8_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kSMALLINT:

             create_or_append_value<int16_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kINT:

             create_or_append_value<int32_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kBIGINT:

             create_or_append_value<int64_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kDECIMAL:

             create_or_append_value<int64_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kFLOAT:

             create_or_append_value<float, float>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<float>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kDOUBLE:

             create_or_append_value<double, double>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<double>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kTIME:

             create_or_append_value<int32_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kDATE:

             device_type_ == ExecutorDeviceType::GPU

                 ? create_or_append_value<int64_t, int64_t>(

                       *scalar_value, value_seg[j], entry_count)

                 : create_or_append_value<int32_t, int64_t>(

                       *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           case kTIMESTAMP:

             create_or_append_value<int64_t, int64_t>(

                 *scalar_value, value_seg[j], entry_count);

             create_or_append_validity<int64_t>(

                 *scalar_value, column.col_type, null_bitmap_seg[j], entry_count);

             break;

           default:

             // TODO(miyu): support more scalar types.

             throw std::runtime_error(column.col_type.get_type_name() +

                                      " is not supported in Arrow result sets.");

         }

       }

     }

     return seg_row_count;

   };


   auto convert_columns = [&](std::vector<std::shared_ptr<arrow::Array>>& result,

                              const std::vector<bool>& non_lazy_cols,

                              const size_t start_col,

                              const size_t end_col) {

     for (size_t col = start_col; col < end_col; ++col) {

       if (!non_lazy_cols.empty() && !non_lazy_cols[col]) {

         continue;

       }


       const auto& column = builders[col];

       switch (column.physical_type) {

         case kTINYINT:

           convert_column<int8_t>(results_, col, entry_count, result[col]);

           break;

         case kSMALLINT:

           convert_column<int16_t>(results_, col, entry_count, result[col]);

           break;

         case kINT:

           convert_column<int32_t>(results_, col, entry_count, result[col]);

           break;

         case kBIGINT:

           convert_column<int64_t>(results_, col, entry_count, result[col]);

           break;

         case kFLOAT:

           convert_column<float>(results_, col, entry_count, result[col]);

           break;

         case kDOUBLE:

           convert_column<double>(results_, col, entry_count, result[col]);

           break;

         default:

           throw std::runtime_error(column.col_type.get_type_name() +

                                    " is not supported in Arrow column converter.");

       }

     }

   };


   std::vector<std::shared_ptr<ValueArray>> column_values(col_count, nullptr);

   std::vector<std::shared_ptr<std::vector<bool>>> null_bitmaps(col_count, nullptr);

   const bool multithreaded = entry_count > 10000 && !results_->isTruncated();

   bool use_columnar_converter = results_->isDirectColumnarConversionPossible() &&

                                 results_->getQueryMemDesc().getQueryDescriptionType() ==

                                     QueryDescriptionType::Projection &&

                                 entry_count == results_->entryCount();

   std::vector<bool> non_lazy_cols;

   if (use_columnar_converter) {

     auto timer = DEBUG_TIMER("columnar converter");

     std::vector<size_t> non_lazy_col_pos;

     size_t non_lazy_col_count = 0;

     const auto& lazy_fetch_info = results_->getLazyFetchInfo();


     non_lazy_cols.reserve(col_count);

     non_lazy_col_pos.reserve(col_count);

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

       bool is_lazy =

           lazy_fetch_info.empty() ? false : lazy_fetch_info[i].is_lazily_fetched;

       // Currently column converter cannot handle some data types.

       // Treat them as lazy.

       switch (builders[i].physical_type) {

         case kBOOLEAN:

         case kTIME:

         case kDATE:

         case kTIMESTAMP:

           is_lazy = true;

           break;

         default:

           break;

       }

       if (builders[i].field->type()->id() == arrow::Type::DICTIONARY) {

         is_lazy = true;

       }

       non_lazy_cols.emplace_back(!is_lazy);

       if (!is_lazy) {

         ++non_lazy_col_count;

         non_lazy_col_pos.emplace_back(i);

       }

     }


     if (non_lazy_col_count == col_count) {

       non_lazy_cols.clear();

       non_lazy_col_pos.clear();

     } else {

       non_lazy_col_pos.emplace_back(col_count);

     }


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

     size_t num_threads =

         std::min(multithreaded ? (size_t)cpu_threads() : (size_t)1, non_lazy_col_count);


     size_t start_col = 0;

     size_t end_col = 0;

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

       start_col = end_col;

       end_col = (i + 1) * non_lazy_col_count / num_threads;

       size_t phys_start_col =

           non_lazy_col_pos.empty() ? start_col : non_lazy_col_pos[start_col];

       size_t phys_end_col =

           non_lazy_col_pos.empty() ? end_col : non_lazy_col_pos[end_col];

       child_threads.push_back(std::async(std::launch::async,

                                          convert_columns,

                                          std::ref(result_columns),

                                          non_lazy_cols,

                                          phys_start_col,

                                          phys_end_col));

     }

     for (auto& child : child_threads) {

       child.get();

     }

     row_count = entry_count;

   }

   if (!use_columnar_converter || !non_lazy_cols.empty()) {

     auto timer = DEBUG_TIMER("row converter");

     row_count = 0;

     if (multithreaded) {

       const size_t cpu_count = cpu_threads();

       std::vector<std::future<size_t>> child_threads;

       std::vector<std::vector<std::shared_ptr<ValueArray>>> column_value_segs(

           cpu_count, std::vector<std::shared_ptr<ValueArray>>(col_count, nullptr));

       std::vector<std::vector<std::shared_ptr<std::vector<bool>>>> null_bitmap_segs(

           cpu_count, std::vector<std::shared_ptr<std::vector<bool>>>(col_count, nullptr));

       const auto stride = (entry_count + cpu_count - 1) / cpu_count;

       for (size_t i = 0, start_entry = 0; start_entry < entry_count;

            ++i, start_entry += stride) {

         const auto end_entry = std::min(entry_count, start_entry + stride);

         child_threads.push_back(std::async(std::launch::async,

                                            fetch,

                                            std::ref(column_value_segs[i]),

                                            std::ref(null_bitmap_segs[i]),

                                            non_lazy_cols,

                                            start_entry,

                                            end_entry));

       }

       for (auto& child : child_threads) {

         row_count += child.get();

       }

       {

         auto timer = DEBUG_TIMER("append rows to arrow");

         for (int i = 0; i < schema->num_fields(); ++i) {

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

             continue;

           }


           for (size_t j = 0; j < cpu_count; ++j) {

             if (!column_value_segs[j][i]) {

               continue;

             }

             append(builders[i], *column_value_segs[j][i], null_bitmap_segs[j][i]);

           }

         }

       }

     } else {

       row_count =

           fetch(column_values, null_bitmaps, non_lazy_cols, size_t(0), entry_count);

       {

         auto timer = DEBUG_TIMER("append rows to arrow single thread");

         for (int i = 0; i < schema->num_fields(); ++i) {

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

             continue;

           }


           append(builders[i], *column_values[i], null_bitmaps[i]);

         }

       }

     }


     {

       auto timer = DEBUG_TIMER("finish builders");

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

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

           continue;

         }


         result_columns[i] = finishColumnBuilder(builders[i]);

       }

     }

   }


   return ARROW_RECORDBATCH_MAKE(schema, row_count, result_columns);

 }


 namespace {


 std::shared_ptr<arrow::DataType> get_arrow_type(const SQLTypeInfo& sql_type,

                                                 const ExecutorDeviceType device_type) {

   switch (get_physical_type(sql_type)) {

     case kBOOLEAN:

       return arrow::boolean();

     case kTINYINT:

       return arrow::int8();

     case kSMALLINT:

       return arrow::int16();

     case kINT:

       return arrow::int32();

     case kBIGINT:

       return arrow::int64();

     case kFLOAT:

       return arrow::float32();

     case kDOUBLE:

       return arrow::float64();

     case kCHAR:

     case kVARCHAR:

     case kTEXT:

       if (sql_type.is_dict_encoded_string()) {

         auto value_type = std::make_shared<arrow::StringType>();

         return dictionary(arrow::int32(), value_type, false);

       }

       return arrow::utf8();

     case kDECIMAL:

     case kNUMERIC:

       return arrow::decimal(sql_type.get_precision(), sql_type.get_scale());

     case kTIME:

       return time32(arrow::TimeUnit::SECOND);

     case kDATE: {

       // TODO(wamsi) : Remove date64() once date32() support is added in cuDF. date32()

       // Currently support for date32() is missing in cuDF.Hence, if client requests for

       // date on GPU, return date64() for the time being, till support is added.

       if (device_type == ExecutorDeviceType::GPU) {

         return arrow::date64();

       } else {

         return arrow::date32();

       }

     }

     case kTIMESTAMP:

       switch (sql_type.get_precision()) {

         case 0:

           return timestamp(arrow::TimeUnit::SECOND);

         case 3:

           return timestamp(arrow::TimeUnit::MILLI);

         case 6:

           return timestamp(arrow::TimeUnit::MICRO);

         case 9:

           return timestamp(arrow::TimeUnit::NANO);

         default:

           throw std::runtime_error(

               "Unsupported timestamp precision for Arrow result sets: " +

               std::to_string(sql_type.get_precision()));

       }

     case kARRAY:

     case kINTERVAL_DAY_TIME:

     case kINTERVAL_YEAR_MONTH:

     default:

       throw std::runtime_error(sql_type.get_type_name() +

                                " is not supported in Arrow result sets.");

   }

   return nullptr;

 }


 }  // namespace


 std::shared_ptr<arrow::Field> ArrowResultSetConverter::makeField(

     const std::string name,

     const SQLTypeInfo& target_type) const {

   return arrow::field(

       name, get_arrow_type(target_type, device_type_), !target_type.get_notnull());

 }


 void ArrowResultSet::deallocateArrowResultBuffer(

     const ArrowResult& result,

     const ExecutorDeviceType device_type,

     const size_t device_id,

     std::shared_ptr<Data_Namespace::DataMgr>& data_mgr) {

 #ifndef _MSC_VER

   // CPU buffers skip the sm handle, serializing the entire RecordBatch to df.

   // Remove shared memory on sysmem

   if (!result.sm_handle.empty()) {

     CHECK_EQ(sizeof(key_t), result.sm_handle.size());

     const key_t& schema_key = *(key_t*)(&result.sm_handle[0]);

     auto shm_id = shmget(schema_key, result.sm_size, 0666);

     if (shm_id < 0) {

       throw std::runtime_error(

           "failed to get an valid shm ID w/ given shm key of the schema");

     }

     if (-1 == shmctl(shm_id, IPC_RMID, 0)) {

       throw std::runtime_error("failed to deallocate Arrow schema on errorno(" +

                                std::to_string(errno) + ")");

     }

   }


   if (device_type == ExecutorDeviceType::CPU) {

     CHECK_EQ(sizeof(key_t), result.df_handle.size());

     const key_t& df_key = *(key_t*)(&result.df_handle[0]);

     auto shm_id = shmget(df_key, result.df_size, 0666);

     if (shm_id < 0) {

       throw std::runtime_error(

           "failed to get an valid shm ID w/ given shm key of the data");

     }

     if (-1 == shmctl(shm_id, IPC_RMID, 0)) {

       throw std::runtime_error("failed to deallocate Arrow data frame");

     }

   }

   // CUDA buffers become owned by the caller, and will automatically be freed

   // TODO: What if the client never takes ownership of the result? we may want to

   // establish a check to see if the GPU buffer still exists, and then free it.

 #endif

 }


 void ArrowResultSetConverter::initializeColumnBuilder(

     ColumnBuilder& column_builder,

     const SQLTypeInfo& col_type,

     const std::shared_ptr<arrow::Field>& field) const {

   column_builder.field = field;

   column_builder.col_type = col_type;

   column_builder.physical_type = col_type.is_dict_encoded_string()

                                      ? get_dict_index_type(col_type)

                                      : get_physical_type(col_type);


   auto value_type = field->type();

   if (col_type.is_dict_encoded_string()) {

     column_builder.builder.reset(new arrow::StringDictionary32Builder());

     // add values to the builder

     const int dict_id = col_type.get_comp_param();

     auto str_list = results_->getStringDictionaryPayloadCopy(dict_id);


     arrow::StringBuilder str_array_builder;

     ARROW_THROW_NOT_OK(str_array_builder.AppendValues(*str_list));

     std::shared_ptr<arrow::StringArray> string_array;

     ARROW_THROW_NOT_OK(str_array_builder.Finish(&string_array));


     auto dict_builder =

         dynamic_cast<arrow::StringDictionary32Builder*>(column_builder.builder.get());

     CHECK(dict_builder);


     ARROW_THROW_NOT_OK(dict_builder->InsertMemoValues(*string_array));

   } else {

     ARROW_THROW_NOT_OK(arrow::MakeBuilder(

         arrow::default_memory_pool(), value_type, &column_builder.builder));

   }

 }


 std::shared_ptr<arrow::Array> ArrowResultSetConverter::finishColumnBuilder(

     ColumnBuilder& column_builder) const {

   std::shared_ptr<arrow::Array> values;

   ARROW_THROW_NOT_OK(column_builder.builder->Finish(&values));

   return values;

 }


 namespace {


 template <typename BUILDER_TYPE, typename VALUE_ARRAY_TYPE>

 void appendToColumnBuilder(ArrowResultSetConverter::ColumnBuilder& column_builder,

                            const ValueArray& values,

                            const std::shared_ptr<std::vector<bool>>& is_valid) {

   static_assert(!std::is_same<BUILDER_TYPE, arrow::StringDictionary32Builder>::value,

                 "Dictionary encoded string builder requires function specialization.");


   std::vector<VALUE_ARRAY_TYPE> vals = boost::get<std::vector<VALUE_ARRAY_TYPE>>(values);


   if (scale_epoch_values<BUILDER_TYPE>()) {

     auto scale_sec_to_millisec = [](auto seconds) { return seconds * kMilliSecsPerSec; };

     auto scale_values = [&](auto epoch) {

       return std::is_same<BUILDER_TYPE, arrow::Date32Builder>::value

                  ? DateConverters::get_epoch_days_from_seconds(epoch)

                  : scale_sec_to_millisec(epoch);

     };

     std::transform(vals.begin(), vals.end(), vals.begin(), scale_values);

   }


   auto typed_builder = dynamic_cast<BUILDER_TYPE*>(column_builder.builder.get());

   CHECK(typed_builder);

   if (column_builder.field->nullable()) {

     CHECK(is_valid.get());

     ARROW_THROW_NOT_OK(typed_builder->AppendValues(vals, *is_valid));

   } else {

     ARROW_THROW_NOT_OK(typed_builder->AppendValues(vals));

   }

 }


 template <>

 void appendToColumnBuilder<arrow::Decimal128Builder, int64_t>(

     ArrowResultSetConverter::ColumnBuilder& column_builder,

     const ValueArray& values,

     const std::shared_ptr<std::vector<bool>>& is_valid) {

   std::vector<int64_t> vals = boost::get<std::vector<int64_t>>(values);

   auto typed_builder =

       dynamic_cast<arrow::Decimal128Builder*>(column_builder.builder.get());

   CHECK(typed_builder);

   CHECK_EQ(is_valid->size(), vals.size());

   if (column_builder.field->nullable()) {

     CHECK(is_valid.get());

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

       const auto v = vals[i];

       const auto valid = (*is_valid)[i];

       if (valid) {

         ARROW_THROW_NOT_OK(typed_builder->Append(v));

       } else {

         ARROW_THROW_NOT_OK(typed_builder->AppendNull());

       }

     }

   } else {

     for (const auto& v : vals) {

       ARROW_THROW_NOT_OK(typed_builder->Append(v));

     }

   }

 }


 template <>

 void appendToColumnBuilder<arrow::StringDictionary32Builder, int32_t>(

     ArrowResultSetConverter::ColumnBuilder& column_builder,

     const ValueArray& values,

     const std::shared_ptr<std::vector<bool>>& is_valid) {

   auto typed_builder =

       dynamic_cast<arrow::StringDictionary32Builder*>(column_builder.builder.get());

   CHECK(typed_builder);


   std::vector<int32_t> vals = boost::get<std::vector<int32_t>>(values);


   if (column_builder.field->nullable()) {

     CHECK(is_valid.get());

     // TODO(adb): Generate this instead of the boolean bitmap

     std::vector<uint8_t> transformed_bitmap;

     transformed_bitmap.reserve(is_valid->size());

     std::for_each(

         is_valid->begin(), is_valid->end(), [&transformed_bitmap](const bool is_valid) {

           transformed_bitmap.push_back(is_valid ? 1 : 0);

         });


     ARROW_THROW_NOT_OK(typed_builder->AppendIndices(

         vals.data(), static_cast<int64_t>(vals.size()), transformed_bitmap.data()));

   } else {

     ARROW_THROW_NOT_OK(

         typed_builder->AppendIndices(vals.data(), static_cast<int64_t>(vals.size())));

   }

 }


 }  // namespace


 void ArrowResultSetConverter::append(

     ColumnBuilder& column_builder,

     const ValueArray& values,

     const std::shared_ptr<std::vector<bool>>& is_valid) const {

   if (column_builder.col_type.is_dict_encoded_string()) {

     CHECK_EQ(column_builder.physical_type,

              kINT);  // assume all dicts use none-encoded type for now

     appendToColumnBuilder<arrow::StringDictionary32Builder, int32_t>(

         column_builder, values, is_valid);

     return;

   }

   switch (column_builder.physical_type) {

     case kBOOLEAN:

       appendToColumnBuilder<arrow::BooleanBuilder, bool>(

           column_builder, values, is_valid);

       break;

     case kTINYINT:

       appendToColumnBuilder<arrow::Int8Builder, int8_t>(column_builder, values, is_valid);

       break;

     case kSMALLINT:

       appendToColumnBuilder<arrow::Int16Builder, int16_t>(

           column_builder, values, is_valid);

       break;

     case kINT:

       appendToColumnBuilder<arrow::Int32Builder, int32_t>(

           column_builder, values, is_valid);

       break;

     case kBIGINT:

       appendToColumnBuilder<arrow::Int64Builder, int64_t>(

           column_builder, values, is_valid);

       break;

     case kDECIMAL:

       appendToColumnBuilder<arrow::Decimal128Builder, int64_t>(

           column_builder, values, is_valid);

       break;

     case kFLOAT:

       appendToColumnBuilder<arrow::FloatBuilder, float>(column_builder, values, is_valid);

       break;

     case kDOUBLE:

       appendToColumnBuilder<arrow::DoubleBuilder, double>(

           column_builder, values, is_valid);

       break;

     case kTIME:

       appendToColumnBuilder<arrow::Time32Builder, int32_t>(

           column_builder, values, is_valid);

       break;

     case kTIMESTAMP:

       appendToColumnBuilder<arrow::TimestampBuilder, int64_t>(

           column_builder, values, is_valid);

       break;

     case kDATE:

       device_type_ == ExecutorDeviceType::GPU

           ? appendToColumnBuilder<arrow::Date64Builder, int64_t>(

                 column_builder, values, is_valid)

           : appendToColumnBuilder<arrow::Date32Builder, int32_t>(

                 column_builder, values, is_valid);

       break;

     case kCHAR:

     case kVARCHAR:

     case kTEXT:

     default:

       // TODO(miyu): support more scalar types.

       throw std::runtime_error(column_builder.col_type.get_type_name() +

                                " is not supported in Arrow result sets.");

   }

 }

anonymous_namespace{ArrowResultSetConverter.cpp}::create_or_append_value
void create_or_append_value(const ScalarTargetValue &val_cty, std::shared_ptr< ValueArray > &values, const size_t max_size)
Definition: ArrowResultSetConverter.cpp:110

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

ArrowTransport::SHARED_MEMORY

ArrowResultSetConverter::ColumnBuilder::builder
std::unique_ptr< arrow::ArrayBuilder > builder
Definition: ArrowResultSet.h:205

ExecutorDeviceType::GPU

SQLTypeInfo::get_size
HOST DEVICE int get_size() const
Definition: sqltypes.h:339

ARROW_THROW_NOT_OK
#define ARROW_THROW_NOT_OK(s)
Definition: ArrowUtil.h:36

anonymous_namespace{ArrowResultSetConverter.cpp}::get_dict_index_type
SQLTypes get_dict_index_type(const SQLTypeInfo &ti)
Definition: ArrowResultSetConverter.cpp:73

kTIME
Definition: sqltypes.h:49

SQLTypes
SQLTypes
Definition: sqltypes.h:38

ArrowResultSetConverter::append
void append(ColumnBuilder &column_builder, const ValueArray &values, const std::shared_ptr< std::vector< bool >> &is_valid) const
Definition: ArrowResultSetConverter.cpp:1186

kARRAY
Definition: sqltypes.h:54

anonymous_namespace{ArrowResultSetConverter.cpp}::convert_column
void convert_column(ResultSetPtr result, size_t col, size_t entry_count, std::shared_ptr< arrow::Array > &out)
Definition: ArrowResultSetConverter.cpp:180

ArrowResultSetConverter::getArrowResult
ArrowResult getArrowResult() const
Definition: ArrowResultSetConverter.cpp:343

ArrowResult::sm_handle
std::vector< char > sm_handle
Definition: ArrowResultSet.h:88

ExecutorDeviceType
ExecutorDeviceType
Definition: CompilationOptions.h:22

run_benchmark_import.res
tuple res
Definition: run_benchmark_import.py:381

QueryDescriptionType::Projection

anonymous_namespace{ArrowResultSetConverter.cpp}::ResultSetBuffer::ResultSetBuffer
ResultSetBuffer(const uint8_t *buf, size_t size, ResultSetPtr rs)
Definition: ArrowResultSetConverter.cpp:66

anonymous_namespace{ArrowResultSetConverter.cpp}::appendToColumnBuilder
void appendToColumnBuilder(ArrowResultSetConverter::ColumnBuilder &column_builder, const ValueArray &values, const std::shared_ptr< std::vector< bool >> &is_valid)
Definition: ArrowResultSetConverter.cpp:1099

ArrowResultSetConverter::ColumnBuilder::physical_type
SQLTypes physical_type
Definition: ArrowResultSet.h:207

ARROW_ASSIGN_OR_THROW
#define ARROW_ASSIGN_OR_THROW(lhs, rexpr)
Definition: ArrowUtil.h:60

ARROW_LOG
#define ARROW_LOG(category)
Definition: ArrowResultSetConverter.cpp:55

SQLTypeInfo::is_fp
bool is_fp() const
Definition: sqltypes.h:508

SQLTypeInfo::get_scale
HOST DEVICE int get_scale() const
Definition: sqltypes.h:334

ArrowResultSet.h

anonymous_namespace{ArrowResultSetConverter.cpp}::null_type< TYPE, std::enable_if_t< std::is_integral< TYPE >::value > >::type
typename std::make_signed< TYPE >::type type
Definition: ArrowResultSetConverter.cpp:165

ArrowResultSetConverter::finishColumnBuilder
std::shared_ptr< arrow::Array > finishColumnBuilder(ColumnBuilder &column_builder) const
Definition: ArrowResultSetConverter.cpp:1089

setup.name
string name
Definition: setup.in.py:72

foreign_storage::get_physical_type
parquet::Type::type get_physical_type(ReaderPtr &reader, const int logical_column_index)
Definition: ParquetShared.cpp:51

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

kFLOAT
Definition: sqltypes.h:47

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

ArrowResultSetConverter::ColumnBuilder::field
std::shared_ptr< arrow::Field > field
Definition: ArrowResultSet.h:204

DICTIONARY
#define DICTIONARY
Definition: Parser_wnd_pregen.cpp:396

ResultSetPtr
std::shared_ptr< ResultSet > ResultSetPtr
Definition: RelAlgExecutionUnit.h:151

anonymous_namespace{ArrowResultSetConverter.cpp}::get_shm_buffer
std::pair< key_t, std::shared_ptr< arrow::Buffer > > get_shm_buffer(size_t size)
Definition: ArrowResultSetConverter.cpp:306

SQLTypeInfo::get_type
HOST DEVICE SQLTypes get_type() const
Definition: sqltypes.h:329

inline_fp_null_val
double inline_fp_null_val(const SQL_TYPE_INFO &ti)
Definition: InlineNullValues.h:194

SQLTypeInfo::is_time
bool is_time() const
Definition: sqltypes.h:510

to_string
std::string to_string(char const *&&v)
Definition: StringTransform.cpp:101

ArrowResultSetConverter::ColumnBuilder
Definition: ArrowResultSet.h:203

kBOOLEAN
Definition: sqltypes.h:40

anonymous_namespace{ArrowResultSetConverter.cpp}::get_shm
std::pair< key_t, void * > get_shm(size_t shmsz)
Definition: ArrowResultSetConverter.cpp:268

kMilliSecsPerSec
static constexpr int64_t kMilliSecsPerSec
Definition: ExtractFromTime.h:26

kDOUBLE
Definition: sqltypes.h:48

kINTERVAL_YEAR_MONTH
Definition: sqltypes.h:56

ArrowResultSetConverter::transport_method_
ArrowTransport transport_method_
Definition: ArrowResultSet.h:248

field
const rapidjson::Value & field(const rapidjson::Value &obj, const char field[]) noexcept
Definition: JsonAccessors.h:31

ArrowResultSetConverter::top_n_
int32_t top_n_
Definition: ArrowResultSet.h:247

ArrowResultSetConverter::getArrowBatch
std::shared_ptr< arrow::RecordBatch > getArrowBatch(const std::shared_ptr< arrow::Schema > &schema) const
Definition: ArrowResultSetConverter.cpp:630

threading_serial::async
future< Result > async(Fn &&fn, Args &&...args)
Definition: threading_serial.h:11

ARROW_RECORDBATCH_MAKE
#define ARROW_RECORDBATCH_MAKE
Definition: ArrowResultSetConverter.cpp:51

ArrowResultSetConverter::col_names_
std::vector< std::string > col_names_
Definition: ArrowResultSet.h:246

SQLTypeInfo::is_integer
bool is_integer() const
Definition: sqltypes.h:506

ArrowResultSetConverter::device_type_
ExecutorDeviceType device_type_
Definition: ArrowResultSet.h:244

ArrowResult::df_handle
std::vector< char > df_handle
Definition: ArrowResultSet.h:90

ArrowResultSetConverter::makeField
std::shared_ptr< arrow::Field > makeField(const std::string name, const SQLTypeInfo &target_type) const
Definition: ArrowResultSetConverter.cpp:1009

ArrowResultSetConverter::getSerializedArrowOutput
SerializedArrowOutput getSerializedArrowOutput(arrow::ipc::DictionaryFieldMapper *mapper) const
Definition: ArrowResultSetConverter.cpp:590

kBIGINT
Definition: sqltypes.h:51

SQLTypeInfo::is_boolean
bool is_boolean() const
Definition: sqltypes.h:511

anonymous_namespace{ArrowResultSetConverter.cpp}::ResultSetBuffer::_rs
ResultSetPtr _rs
Definition: ArrowResultSetConverter.cpp:70

SQLTypeInfo::get_precision
int get_precision() const
Definition: sqltypes.h:332

arrow::get_and_copy_to_shm
key_t get_and_copy_to_shm(const std::shared_ptr< Buffer > &data)
Definition: ArrowResultSetConverter.cpp:323

ArrowTransport::WIRE

ArrowResultSet::deallocateArrowResultBuffer
static void deallocateArrowResultBuffer(const ArrowResult &result, const ExecutorDeviceType device_type, const size_t device_id, std::shared_ptr< Data_Namespace::DataMgr > &data_mgr)
Definition: ArrowResultSetConverter.cpp:1016

anonymous_namespace{ArrowResultSetConverter.cpp}::get_arrow_type
std::shared_ptr< arrow::DataType > get_arrow_type(const SQLTypeInfo &sql_type, const ExecutorDeviceType device_type)
Definition: ArrowResultSetConverter.cpp:942

kTEXT
Definition: sqltypes.h:52

kDATE
Definition: sqltypes.h:53

ArrowUtil.h

Execute.h

ArrowResultSetConverter::results_
std::shared_ptr< ResultSet > results_
Definition: ArrowResultSet.h:242

ArrowResultSetConverter::SerializedArrowOutput
Definition: ArrowResultSet.h:224

anonymous_namespace{ArrowResultSetConverter.cpp}::null_type
Definition: ArrowResultSetConverter.cpp:161

ArrowResultSetConverter::ColumnBuilder::col_type
SQLTypeInfo col_type
Definition: ArrowResultSet.h:206

ArrowResult::sm_size
int64_t sm_size
Definition: ArrowResultSet.h:89

kTINYINT
Definition: sqltypes.h:61

ArrowResult
Definition: ArrowResultSet.h:87

ValueArray
boost::variant< std::vector< bool >, std::vector< int8_t >, std::vector< int16_t >, std::vector< int32_t >, std::vector< int64_t >, std::vector< arrow::Decimal128 >, std::vector< float >, std::vector< double >, std::vector< std::string >> ValueArray
Definition: ArrowResultSet.h:45

ArrowResult::df_size
int64_t df_size
Definition: ArrowResultSet.h:91

kSMALLINT
Definition: sqltypes.h:46

SQLTypeInfo::get_type_name
std::string get_type_name() const
Definition: sqltypes.h:432

IS_INTEGER
#define IS_INTEGER(T)
Definition: sqltypes.h:245

anonymous_namespace{ArrowResultSetConverter.cpp}::null_type_t
typename null_type< TYPE >::type null_type_t
Definition: ArrowResultSetConverter.cpp:176

kTIMESTAMP
Definition: sqltypes.h:50

kDECIMAL
Definition: sqltypes.h:44

kCHAR
Definition: sqltypes.h:41

SQLTypeInfo::get_comp_param
HOST DEVICE int get_comp_param() const
Definition: sqltypes.h:338

i
int i
Definition: Parser_wnd_pregen.cpp:2082

anonymous_namespace{ArrowResultSetConverter.cpp}::null_type< TYPE, std::enable_if_t< std::is_floating_point< TYPE >::value > >::type
TYPE type
Definition: ArrowResultSetConverter.cpp:171

CHECK
#define CHECK(condition)
Definition: Logger.h:209

DEBUG_TIMER
#define DEBUG_TIMER(name)
Definition: Logger.h:352

SQLTypeInfo
Definition: sqltypes.h:270

inline_int_null_val
int64_t inline_int_null_val(const SQL_TYPE_INFO &ti)
Definition: InlineNullValues.h:115

f
char * f
Definition: Parser_wnd_pregen.cpp:2080

DateConverters::get_epoch_days_from_seconds
int64_t get_epoch_days_from_seconds(const int64_t seconds)
Definition: DateConverters.h:24

ArrowResultSetConverter::initializeColumnBuilder
void initializeColumnBuilder(ColumnBuilder &column_builder, const SQLTypeInfo &col_type, const std::shared_ptr< arrow::Field > &field) const
Definition: ArrowResultSetConverter.cpp:1056

kVARCHAR
Definition: sqltypes.h:42

kINTERVAL_DAY_TIME
Definition: sqltypes.h:55

SQLTypeInfo::is_dict_encoded_string
bool is_dict_encoded_string() const
Definition: sqltypes.h:541

kNUMERIC
Definition: sqltypes.h:43

kINT
Definition: sqltypes.h:45

SQLTypeInfo::get_notnull
HOST DEVICE bool get_notnull() const
Definition: sqltypes.h:336

ExecutorDeviceType::CPU

cpu_threads
int cpu_threads()
Definition: thread_count.h:24

SQLTypeInfo::is_decimal
bool is_decimal() const
Definition: sqltypes.h:507

ArrowResultSetConverter::device_id_
int32_t device_id_
Definition: ArrowResultSet.h:245

anonymous_namespace{ArrowResultSetConverter.cpp}::create_or_append_validity
void create_or_append_validity(const ScalarTargetValue &value, const SQLTypeInfo &col_type, std::shared_ptr< std::vector< bool >> &null_bitmap, const size_t max_size)
Definition: ArrowResultSetConverter.cpp:127

VLOG
#define VLOG(n)
Definition: Logger.h:303

run_benchmark_import.type
type
Definition: run_benchmark_import.py:89

ScalarTargetValue
boost::variant< int64_t, double, float, NullableString > ScalarTargetValue
Definition: TargetValue.h:156

anonymous_namespace{ArrowResultSetConverter.cpp}::ResultSetBuffer
Definition: ArrowResultSetConverter.cpp:64

run_benchmark_import.result
dictionary result
Definition: run_benchmark_import.py:441

ArrowResultSetConverter::convertToArrow
std::shared_ptr< arrow::RecordBatch > convertToArrow() const
Definition: ArrowResultSetConverter.cpp:612