_table_function_execution_context_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 "QueryEngine/TableFunctions/TableFunctionExecutionContext.h"


 #include "Analyzer/Analyzer.h"

 #include "QueryEngine/ColumnFetcher.h"

 #include "QueryEngine/GpuMemUtils.h"

 #include "QueryEngine/TableFunctions/TableFunctionCompilationContext.h"

 #include "Shared/Logger.h"


 namespace {


 template <typename T>

 const int8_t* create_literal_buffer(T literal,

                                     const ExecutorDeviceType device_type,

                                     std::vector<std::unique_ptr<char[]>>& literals_owner,

                                     CudaAllocator* gpu_allocator) {

   CHECK_LE(sizeof(T), sizeof(int64_t));  // pad to 8 bytes

   switch (device_type) {

     case ExecutorDeviceType::CPU: {

       literals_owner.emplace_back(std::make_unique<char[]>(sizeof(int64_t)));

       std::memcpy(literals_owner.back().get(), &literal, sizeof(T));

       return reinterpret_cast<const int8_t*>(literals_owner.back().get());

     }

     case ExecutorDeviceType::GPU: {

       CHECK(gpu_allocator);

       const auto gpu_literal_buf_ptr = gpu_allocator->alloc(sizeof(int64_t));

       gpu_allocator->copyToDevice(

           gpu_literal_buf_ptr, reinterpret_cast<int8_t*>(&literal), sizeof(T));

       return gpu_literal_buf_ptr;

     }

   }

   UNREACHABLE();

   return nullptr;

 }


 size_t get_output_row_count(const TableFunctionExecutionUnit& exe_unit,

                             size_t input_element_count) {

   size_t allocated_output_row_count = 0;

   if (*exe_unit.output_buffer_multiplier) {

     allocated_output_row_count = *exe_unit.output_buffer_multiplier * input_element_count;

   } else {

     throw std::runtime_error(

         "Only row multiplier output buffer configuration is supported for table "

         "functions.");

   }

   return allocated_output_row_count;

 }


 }  // namespace


 ResultSetPtr TableFunctionExecutionContext::execute(

     const TableFunctionExecutionUnit& exe_unit,

     const InputTableInfo& table_info,

     const TableFunctionCompilationContext* compilation_context,

     const ColumnFetcher& column_fetcher,

     const ExecutorDeviceType device_type,

     Executor* executor) {

   CHECK(compilation_context);


   std::vector<std::shared_ptr<Chunk_NS::Chunk>> chunks_owner;

   std::vector<std::unique_ptr<char[]>> literals_owner;


   const int device_id = 0;  // TODO(adb): support multi-gpu table functions

   std::unique_ptr<CudaAllocator> device_allocator;

   if (device_type == ExecutorDeviceType::GPU) {

     auto& data_mgr = executor->catalog_->getDataMgr();

     device_allocator.reset(new CudaAllocator(&data_mgr, device_id));

   }


   std::vector<const int8_t*> col_buf_ptrs;

   ssize_t element_count = -1;

   for (const auto& input_expr : exe_unit.input_exprs) {

     if (auto col_var = dynamic_cast<Analyzer::ColumnVar*>(input_expr)) {

       auto [col_buf, buf_elem_count] = ColumnFetcher::getOneColumnFragment(

           executor,

           *col_var,

           table_info.info.fragments.front(),

           device_type == ExecutorDeviceType::CPU ? Data_Namespace::MemoryLevel::CPU_LEVEL

                                                  : Data_Namespace::MemoryLevel::GPU_LEVEL,

           device_id,

           chunks_owner,

           column_fetcher.columnarized_table_cache_);

       if (element_count < 0) {

         element_count = static_cast<ssize_t>(buf_elem_count);

       } else {

         CHECK_EQ(static_cast<ssize_t>(buf_elem_count), element_count);

       }

       col_buf_ptrs.push_back(col_buf);

     } else if (const auto& constant_val = dynamic_cast<Analyzer::Constant*>(input_expr)) {

       // TODO(adb): Unify literal handling with rest of system, either in Codegen or as a

       // separate serialization component

       const auto const_val_datum = constant_val->get_constval();

       const auto& ti = constant_val->get_type_info();

       if (ti.is_fp()) {

         switch (get_bit_width(ti)) {

           case 32:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.floatval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           case 64:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.doubleval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           default:

             UNREACHABLE();

         }

       } else if (ti.is_integer()) {

         switch (get_bit_width(ti)) {

           case 8:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.tinyintval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           case 16:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.smallintval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           case 32:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.intval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           case 64:

             col_buf_ptrs.push_back(create_literal_buffer(const_val_datum.bigintval,

                                                          device_type,

                                                          literals_owner,

                                                          device_allocator.get()));

             break;

           default:

             UNREACHABLE();

         }

       } else {

         throw std::runtime_error("Literal value " + constant_val->toString() +

                                  " is not yet supported.");

       }

     }

   }

   CHECK_EQ(col_buf_ptrs.size(), exe_unit.input_exprs.size());


   CHECK_GE(element_count, ssize_t(0));

   switch (device_type) {

     case ExecutorDeviceType::CPU:

       return launchCpuCode(exe_unit,

                            compilation_context,

                            col_buf_ptrs,

                            static_cast<size_t>(element_count),

                            executor);

     case ExecutorDeviceType::GPU:

       return launchGpuCode(exe_unit,

                            compilation_context,

                            col_buf_ptrs,

                            static_cast<size_t>(element_count),

                            /*device_id=*/0,

                            executor);

   }

   UNREACHABLE();

   return nullptr;

 }


 ResultSetPtr TableFunctionExecutionContext::launchCpuCode(

     const TableFunctionExecutionUnit& exe_unit,

     const TableFunctionCompilationContext* compilation_context,

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

     const size_t elem_count,

     Executor* executor) {

   // setup the inputs

   const auto byte_stream_ptr = reinterpret_cast<const int8_t**>(col_buf_ptrs.data());

   CHECK(byte_stream_ptr);


   // initialize output memory

   QueryMemoryDescriptor query_mem_desc(

       executor, elem_count, QueryDescriptionType::Projection, /*is_table_function=*/true);

   query_mem_desc.setOutputColumnar(true);


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

     // All outputs padded to 8 bytes

     query_mem_desc.addColSlotInfo({std::make_tuple(8, 8)});

   }


   const auto allocated_output_row_count = get_output_row_count(exe_unit, elem_count);

   auto query_buffers = std::make_unique<QueryMemoryInitializer>(

       exe_unit,

       query_mem_desc,

       /*device_id=*/0,

       ExecutorDeviceType::CPU,

       allocated_output_row_count,

       std::vector<std::vector<const int8_t*>>{col_buf_ptrs},

       std::vector<std::vector<uint64_t>>{{0}},  // frag offsets

       row_set_mem_owner_,

       nullptr,

       executor);


   // setup the output

   int64_t output_row_count = -1;

   auto group_by_buffers_ptr = query_buffers->getGroupByBuffersPtr();

   CHECK(group_by_buffers_ptr);


   // execute

   const auto kernel_element_count = static_cast<int64_t>(elem_count);

   const auto err =

       compilation_context->getFuncPtr()(byte_stream_ptr,

                                         &kernel_element_count,

                                         query_buffers->getGroupByBuffersPtr(),

                                         &output_row_count);

   if (err) {

     throw std::runtime_error("Error executing table function: " + std::to_string(err));

   }

   if (output_row_count < 0) {

     throw std::runtime_error("Table function did not properly set output row count.");

   }


   // Update entry count, it may differ from allocated mem size

   query_buffers->getResultSet(0)->updateStorageEntryCount(output_row_count);


   return query_buffers->getResultSetOwned(0);

 }


 namespace {

 enum {

   ERROR_BUFFER,

   COL_BUFFERS,

   INPUT_ROW_COUNT,

   OUTPUT_BUFFERS,

   OUTPUT_ROW_COUNT,

   KERNEL_PARAM_COUNT,

 };

 }


 ResultSetPtr TableFunctionExecutionContext::launchGpuCode(

     const TableFunctionExecutionUnit& exe_unit,

     const TableFunctionCompilationContext* compilation_context,

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

     const size_t elem_count,

     const int device_id,

     Executor* executor) {

 #ifdef HAVE_CUDA

   auto& data_mgr = executor->catalog_->getDataMgr();

   auto gpu_allocator = std::make_unique<CudaAllocator>(&data_mgr, device_id);

   CHECK(gpu_allocator);


   std::vector<CUdeviceptr> kernel_params(KERNEL_PARAM_COUNT, 0);

   // setup the inputs

   auto byte_stream_ptr = gpu_allocator->alloc(col_buf_ptrs.size() * sizeof(int64_t));

   gpu_allocator->copyToDevice(byte_stream_ptr,

                               reinterpret_cast<int8_t*>(col_buf_ptrs.data()),

                               col_buf_ptrs.size() * sizeof(int64_t));

   kernel_params[COL_BUFFERS] = reinterpret_cast<CUdeviceptr>(byte_stream_ptr);


   kernel_params[INPUT_ROW_COUNT] =

       reinterpret_cast<CUdeviceptr>(gpu_allocator->alloc(sizeof(elem_count)));

   gpu_allocator->copyToDevice(reinterpret_cast<int8_t*>(kernel_params[INPUT_ROW_COUNT]),

                               reinterpret_cast<const int8_t*>(&elem_count),

                               sizeof(elem_count));


   kernel_params[ERROR_BUFFER] =

       reinterpret_cast<CUdeviceptr>(gpu_allocator->alloc(sizeof(int32_t)));


   // initialize output memory

   QueryMemoryDescriptor query_mem_desc(

       executor, elem_count, QueryDescriptionType::Projection, /*is_table_function=*/true);

   query_mem_desc.setOutputColumnar(true);


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

     // All outputs padded to 8 bytes

     query_mem_desc.addColSlotInfo({std::make_tuple(8, 8)});

   }

   const auto allocated_output_row_count = get_output_row_count(exe_unit, elem_count);

   auto query_buffers = std::make_unique<QueryMemoryInitializer>(

       exe_unit,

       query_mem_desc,

       device_id,

       ExecutorDeviceType::GPU,

       allocated_output_row_count,

       std::vector<std::vector<const int8_t*>>{col_buf_ptrs},

       std::vector<std::vector<uint64_t>>{{0}},  // frag offsets

       row_set_mem_owner_,

       gpu_allocator.get(),

       executor);


   // setup the output

   int64_t output_row_count = -1;

   kernel_params[OUTPUT_ROW_COUNT] =

       reinterpret_cast<CUdeviceptr>(gpu_allocator->alloc(sizeof(int64_t*)));

   gpu_allocator->copyToDevice(reinterpret_cast<int8_t*>(kernel_params[OUTPUT_ROW_COUNT]),

                               reinterpret_cast<int8_t*>(&output_row_count),

                               sizeof(output_row_count));


   auto group_by_buffers_ptr = query_buffers->getGroupByBuffersPtr();

   CHECK(group_by_buffers_ptr);


   const unsigned block_size_x = executor->blockSize();

   const unsigned block_size_y = 1;

   const unsigned block_size_z = 1;

   const unsigned grid_size_x = executor->gridSize();

   const unsigned grid_size_y = 1;

   const unsigned grid_size_z = 1;


   auto gpu_output_buffers = query_buffers->setupTableFunctionGpuBuffers(

       query_mem_desc, device_id, block_size_x, grid_size_x);

   kernel_params[OUTPUT_BUFFERS] = reinterpret_cast<CUdeviceptr>(gpu_output_buffers.first);


   // execute

   CHECK_EQ(static_cast<size_t>(KERNEL_PARAM_COUNT), kernel_params.size());


   std::vector<void*> param_ptrs;

   for (auto& param : kernel_params) {

     param_ptrs.push_back(&param);

   }


   // Get cu func

   const auto gpu_code_ptr = compilation_context->getGpuCode();

   CHECK(gpu_code_ptr);

   CHECK_LT(static_cast<size_t>(device_id), gpu_code_ptr->native_functions.size());

   const auto native_function_pointer = gpu_code_ptr->native_functions[device_id].first;

   auto cu_func = static_cast<CUfunction>(native_function_pointer);

   checkCudaErrors(cuLaunchKernel(cu_func,

                                  grid_size_x,

                                  grid_size_y,

                                  grid_size_z,

                                  block_size_x,

                                  block_size_y,

                                  block_size_z,

                                  0,  // shared mem bytes

                                  nullptr,

                                  &param_ptrs[0],

                                  nullptr));

   // TODO(adb): read errors


   // read output row count from GPU

   int64_t new_output_row_count = -1;

   gpu_allocator->copyFromDevice(

       reinterpret_cast<int8_t*>(&new_output_row_count),

       reinterpret_cast<int8_t*>(kernel_params[OUTPUT_ROW_COUNT]),

       sizeof(int64_t));

   if (new_output_row_count < 0) {

     new_output_row_count = allocated_output_row_count;

   }


   // Update entry count, it may differ from allocated mem size

   query_buffers->getResultSet(0)->updateStorageEntryCount(new_output_row_count);


   // Copy back to CPU storage

   query_buffers->copyGroupByBuffersFromGpu(&data_mgr,

                                            query_mem_desc,

                                            new_output_row_count,

                                            gpu_output_buffers,

                                            nullptr,

                                            block_size_x,

                                            grid_size_x,

                                            device_id,

                                            false);


   return query_buffers->getResultSetOwned(0);

 #else

   UNREACHABLE();

   return nullptr;

 #endif

 }

Analyzer.h
Defines data structures for the semantic analysis phase of query processing.

CHECK_EQ
#define CHECK_EQ(x, y)
Definition: Logger.h:198

TableFunctionCompilationContext
Definition: TableFunctionCompilationContext.h:29

anonymous_namespace{TableFunctionExecutionContext.cpp}::get_output_row_count
size_t get_output_row_count(const TableFunctionExecutionUnit &exe_unit, size_t input_element_count)
Definition: TableFunctionExecutionContext.cpp:51

ExecutorDeviceType::GPU

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

TableFunctionExecutionContext::launchCpuCode
ResultSetPtr launchCpuCode(const TableFunctionExecutionUnit &exe_unit, const TableFunctionCompilationContext *compilation_context, std::vector< const int8_t * > &col_buf_ptrs, const size_t elem_count, Executor *executor)
Definition: TableFunctionExecutionContext.cpp:183

TableFunctionExecutionUnit::input_exprs
std::vector< Analyzer::Expr * > input_exprs
Definition: RelAlgExecutionUnit.h:79

ExecutorDeviceType
ExecutorDeviceType
Definition: CompilationOptions.h:20

TableFunctionExecutionUnit::output_buffer_multiplier
const std::optional< size_t > output_buffer_multiplier
Definition: RelAlgExecutionUnit.h:82

TableFunctionExecutionContext::launchGpuCode
ResultSetPtr launchGpuCode(const TableFunctionExecutionUnit &exe_unit, const TableFunctionCompilationContext *compilation_context, std::vector< const int8_t * > &col_buf_ptrs, const size_t elem_count, const int device_id, Executor *executor)
Definition: TableFunctionExecutionContext.cpp:252

CudaAllocator::copyToDevice
void copyToDevice(int8_t *device_dst, const int8_t *host_src, const size_t num_bytes) const override
Definition: CudaAllocator.cpp:67

CudaAllocator
Definition: CudaAllocator.h:43

QueryMemoryDescriptor
Definition: QueryMemoryDescriptor.h:66

TableFunctionExecutionContext::execute
ResultSetPtr execute(const TableFunctionExecutionUnit &exe_unit, const InputTableInfo &table_info, const TableFunctionCompilationContext *compilation_context, const ColumnFetcher &column_fetcher, const ExecutorDeviceType device_type, Executor *executor)
Definition: TableFunctionExecutionContext.cpp:66

anonymous_namespace{TableFunctionExecutionContext.cpp}::OUTPUT_BUFFERS
Definition: TableFunctionExecutionContext.cpp:246

checkCudaErrors
void checkCudaErrors(CUresult err)
Definition: sample.cpp:38

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

UNREACHABLE
#define UNREACHABLE()
Definition: Logger.h:234

QueryMemoryDescriptor::setOutputColumnar
void setOutputColumnar(const bool val)
Definition: QueryMemoryDescriptor.cpp:957

CHECK_GE
#define CHECK_GE(x, y)
Definition: Logger.h:203

anonymous_namespace{TableFunctionExecutionContext.cpp}::ERROR_BUFFER
Definition: TableFunctionExecutionContext.cpp:243

ColumnFetcher::columnarized_table_cache_
ColumnCacheMap columnarized_table_cache_
Definition: ColumnFetcher.h:79

Fragmenter_Namespace::TableInfo::fragments
std::deque< FragmentInfo > fragments
Definition: Fragmenter.h:167

ResultSetPtr
std::shared_ptr< ResultSet > ResultSetPtr
Definition: RelAlgExecutionUnit.h:87

TableFunctionCompilationContext::getGpuCode
CodeGenerator::GPUCode * getGpuCode() const
Definition: TableFunctionCompilationContext.h:48

Data_Namespace::CPU_LEVEL
Definition: MemoryLevel.h:21

to_string
std::string to_string(char const *&&v)
Definition: StringTransform.cpp:93

anonymous_namespace{TableFunctionExecutionContext.cpp}::COL_BUFFERS
Definition: TableFunctionExecutionContext.cpp:244

ColumnFetcher.h

CudaAllocator::alloc
static int8_t * alloc(Data_Namespace::DataMgr *data_mgr, const size_t num_bytes, const int device_id)
Definition: CudaAllocator.cpp:35

get_bit_width
size_t get_bit_width(const SQLTypeInfo &ti)
Definition: SqlTypesLayout.h:167

CHECK
CHECK(cgen_state)

ColumnFetcher
Definition: ColumnFetcher.h:21

Logger.h

CUfunction
void * CUfunction
Definition: nocuda.h:24

QueryDescriptionType::Projection

TableFunctionExecutionContext::row_set_mem_owner_
std::shared_ptr< RowSetMemoryOwner > row_set_mem_owner_
Definition: TableFunctionExecutionContext.h:57

ColumnFetcher::getOneColumnFragment
static std::pair< const int8_t *, size_t > getOneColumnFragment(Executor *executor, const Analyzer::ColumnVar &hash_col, const Fragmenter_Namespace::FragmentInfo &fragment, const Data_Namespace::MemoryLevel effective_mem_lvl, const int device_id, std::vector< std::shared_ptr< Chunk_NS::Chunk >> &chunks_owner, ColumnCacheMap &column_cache)
Definition: ColumnFetcher.cpp:23

TableFunctionExecutionUnit
Definition: RelAlgExecutionUnit.h:76

CHECK_LT
#define CHECK_LT(x, y)
Definition: Logger.h:200

TableFunctionCompilationContext::getFuncPtr
TableFunctionCompilationContext::FuncPtr getFuncPtr() const
Definition: TableFunctionCompilationContext.h:46

CHECK_LE
#define CHECK_LE(x, y)
Definition: Logger.h:201

anonymous_namespace{TableFunctionExecutionContext.cpp}::KERNEL_PARAM_COUNT
Definition: TableFunctionExecutionContext.cpp:248

GpuMemUtils.h

TableFunctionCompilationContext.h

InputTableInfo
Definition: InputMetadata.h:33

TableFunctionExecutionUnit::target_exprs
std::vector< Analyzer::Expr * > target_exprs
Definition: RelAlgExecutionUnit.h:81

TableFunctionExecutionContext.h

QueryMemoryDescriptor::addColSlotInfo
void addColSlotInfo(const std::vector< std::tuple< int8_t, int8_t >> &slots_for_col)
Definition: QueryMemoryDescriptor.cpp:1090

ExecutorDeviceType::CPU

query_mem_desc
query_mem_desc
Definition: QueryMemoryInitializer.cpp:325

anonymous_namespace{TableFunctionExecutionContext.cpp}::OUTPUT_ROW_COUNT
Definition: TableFunctionExecutionContext.cpp:247

anonymous_namespace{TableFunctionExecutionContext.cpp}::create_literal_buffer
const int8_t * create_literal_buffer(T literal, const ExecutorDeviceType device_type, std::vector< std::unique_ptr< char[]>> &literals_owner, CudaAllocator *gpu_allocator)
Definition: TableFunctionExecutionContext.cpp:28

Data_Namespace::GPU_LEVEL
Definition: MemoryLevel.h:21

anonymous_namespace{TableFunctionExecutionContext.cpp}::INPUT_ROW_COUNT
Definition: TableFunctionExecutionContext.cpp:245