ClickHouse/programs/library-bridge/CatBoostLibraryHandler.cpp
Alexander Tokmakov 70d1adfe4b
Better formatting for exception messages (#45449)
* save format string for NetException

* format exceptions

* format exceptions 2

* format exceptions 3

* format exceptions 4

* format exceptions 5

* format exceptions 6

* fix

* format exceptions 7

* format exceptions 8

* Update MergeTreeIndexGin.cpp

* Update AggregateFunctionMap.cpp

* Update AggregateFunctionMap.cpp

* fix
2023-01-24 00:13:58 +03:00

390 lines
15 KiB
C++

#include "CatBoostLibraryHandler.h"
#include <Columns/ColumnTuple.h>
#include <Common/FieldVisitorConvertToNumber.h>
namespace DB
{
namespace ErrorCodes
{
extern const int BAD_ARGUMENTS;
extern const int CANNOT_APPLY_CATBOOST_MODEL;
extern const int CANNOT_LOAD_CATBOOST_MODEL;
extern const int LOGICAL_ERROR;
}
CatBoostLibraryHandler::APIHolder::APIHolder(SharedLibrary & lib)
{
ModelCalcerCreate = lib.get<CatBoostLibraryAPI::ModelCalcerCreateFunc>(CatBoostLibraryAPI::ModelCalcerCreateName);
ModelCalcerDelete = lib.get<CatBoostLibraryAPI::ModelCalcerDeleteFunc>(CatBoostLibraryAPI::ModelCalcerDeleteName);
GetErrorString = lib.get<CatBoostLibraryAPI::GetErrorStringFunc>(CatBoostLibraryAPI::GetErrorStringName);
LoadFullModelFromFile = lib.get<CatBoostLibraryAPI::LoadFullModelFromFileFunc>(CatBoostLibraryAPI::LoadFullModelFromFileName);
CalcModelPredictionFlat = lib.get<CatBoostLibraryAPI::CalcModelPredictionFlatFunc>(CatBoostLibraryAPI::CalcModelPredictionFlatName);
CalcModelPrediction = lib.get<CatBoostLibraryAPI::CalcModelPredictionFunc>(CatBoostLibraryAPI::CalcModelPredictionName);
CalcModelPredictionWithHashedCatFeatures = lib.get<CatBoostLibraryAPI::CalcModelPredictionWithHashedCatFeaturesFunc>(CatBoostLibraryAPI::CalcModelPredictionWithHashedCatFeaturesName);
GetStringCatFeatureHash = lib.get<CatBoostLibraryAPI::GetStringCatFeatureHashFunc>(CatBoostLibraryAPI::GetStringCatFeatureHashName);
GetIntegerCatFeatureHash = lib.get<CatBoostLibraryAPI::GetIntegerCatFeatureHashFunc>(CatBoostLibraryAPI::GetIntegerCatFeatureHashName);
GetFloatFeaturesCount = lib.get<CatBoostLibraryAPI::GetFloatFeaturesCountFunc>(CatBoostLibraryAPI::GetFloatFeaturesCountName);
GetCatFeaturesCount = lib.get<CatBoostLibraryAPI::GetCatFeaturesCountFunc>(CatBoostLibraryAPI::GetCatFeaturesCountName);
GetTreeCount = lib.tryGet<CatBoostLibraryAPI::GetTreeCountFunc>(CatBoostLibraryAPI::GetTreeCountName);
GetDimensionsCount = lib.tryGet<CatBoostLibraryAPI::GetDimensionsCountFunc>(CatBoostLibraryAPI::GetDimensionsCountName);
}
CatBoostLibraryHandler::CatBoostLibraryHandler(
const std::string & library_path,
const std::string & model_path)
: loading_start_time(std::chrono::system_clock::now())
, library(std::make_shared<SharedLibrary>(library_path))
, api(*library)
{
model_calcer_handle = api.ModelCalcerCreate();
if (!api.LoadFullModelFromFile(model_calcer_handle, model_path.c_str()))
{
throw Exception(ErrorCodes::CANNOT_LOAD_CATBOOST_MODEL,
"Cannot load CatBoost model: {}", api.GetErrorString());
}
float_features_count = api.GetFloatFeaturesCount(model_calcer_handle);
cat_features_count = api.GetCatFeaturesCount(model_calcer_handle);
tree_count = 1;
if (api.GetDimensionsCount)
tree_count = api.GetDimensionsCount(model_calcer_handle);
loading_duration = std::chrono::duration_cast<std::chrono::milliseconds>(std::chrono::system_clock::now() - loading_start_time);
}
CatBoostLibraryHandler::~CatBoostLibraryHandler()
{
api.ModelCalcerDelete(model_calcer_handle);
}
std::chrono::system_clock::time_point CatBoostLibraryHandler::getLoadingStartTime() const
{
return loading_start_time;
}
std::chrono::milliseconds CatBoostLibraryHandler::getLoadingDuration() const
{
return loading_duration;
}
namespace
{
/// Buffer should be allocated with features_count * column->size() elements.
/// Place column elements in positions buffer[0], buffer[features_count], ... , buffer[size * features_count]
template <typename T>
void placeColumnAsNumber(const IColumn * column, T * buffer, size_t features_count)
{
size_t size = column->size();
FieldVisitorConvertToNumber<T> visitor;
for (size_t i = 0; i < size; ++i)
{
/// TODO: Replace with column visitor.
Field field;
column->get(i, field);
*buffer = applyVisitor(visitor, field);
buffer += features_count;
}
}
/// Buffer should be allocated with features_count * column->size() elements.
/// Place string pointers in positions buffer[0], buffer[features_count], ... , buffer[size * features_count]
void placeStringColumn(const ColumnString & column, const char ** buffer, size_t features_count)
{
size_t size = column.size();
for (size_t i = 0; i < size; ++i)
{
*buffer = const_cast<char *>(column.getDataAt(i).data);
buffer += features_count;
}
}
/// Buffer should be allocated with features_count * column->size() elements.
/// Place string pointers in positions buffer[0], buffer[features_count], ... , buffer[size * features_count]
/// Returns PODArray which holds data (because ColumnFixedString doesn't store terminating zero).
PODArray<char> placeFixedStringColumn(const ColumnFixedString & column, const char ** buffer, size_t features_count)
{
size_t size = column.size();
size_t str_size = column.getN();
PODArray<char> data(size * (str_size + 1));
char * data_ptr = data.data();
for (size_t i = 0; i < size; ++i)
{
auto ref = column.getDataAt(i);
memcpy(data_ptr, ref.data, ref.size);
data_ptr[ref.size] = 0;
*buffer = data_ptr;
data_ptr += ref.size + 1;
buffer += features_count;
}
return data;
}
/// Place columns into buffer, returns column which holds placed data. Buffer should contains column->size() values.
template <typename T>
ColumnPtr placeNumericColumns(const ColumnRawPtrs & columns, size_t offset, size_t size, const T** buffer)
{
if (size == 0)
return nullptr;
size_t column_size = columns[offset]->size();
auto data_column = ColumnVector<T>::create(size * column_size);
T * data = data_column->getData().data();
for (size_t i = 0; i < size; ++i)
{
const auto * column = columns[offset + i];
if (column->isNumeric())
placeColumnAsNumber(column, data + i, size);
}
for (size_t i = 0; i < column_size; ++i)
{
*buffer = data;
++buffer;
data += size;
}
return data_column;
}
/// Place columns into buffer, returns data which was used for fixed string columns.
/// Buffer should contains column->size() values, each value contains size strings.
std::vector<PODArray<char>> placeStringColumns(const ColumnRawPtrs & columns, size_t offset, size_t size, const char ** buffer)
{
if (size == 0)
return {};
std::vector<PODArray<char>> data;
for (size_t i = 0; i < size; ++i)
{
const auto * column = columns[offset + i];
if (const auto * column_string = typeid_cast<const ColumnString *>(column))
placeStringColumn(*column_string, buffer + i, size);
else if (const auto * column_fixed_string = typeid_cast<const ColumnFixedString *>(column))
data.push_back(placeFixedStringColumn(*column_fixed_string, buffer + i, size));
else
throw Exception(ErrorCodes::LOGICAL_ERROR, "Cannot place string column.");
}
return data;
}
/// buffer[column_size * cat_features_count] -> char * => cat_features[column_size][cat_features_count] -> char *
void fillCatFeaturesBuffer(
const char *** cat_features, const char ** buffer,
size_t column_size, size_t cat_features_count)
{
for (size_t i = 0; i < column_size; ++i)
{
*cat_features = buffer;
++cat_features;
buffer += cat_features_count;
}
}
/// Calc hash for string cat feature at ps positions.
template <typename Column>
void calcStringHashes(const Column * column, size_t ps, const int ** buffer, const CatBoostLibraryHandler::APIHolder & api)
{
size_t column_size = column->size();
for (size_t j = 0; j < column_size; ++j)
{
auto ref = column->getDataAt(j);
const_cast<int *>(*buffer)[ps] = api.GetStringCatFeatureHash(ref.data, ref.size);
++buffer;
}
}
/// Calc hash for int cat feature at ps position. Buffer at positions ps should contains unhashed values.
void calcIntHashes(size_t column_size, size_t ps, const int ** buffer, const CatBoostLibraryHandler::APIHolder & api)
{
for (size_t j = 0; j < column_size; ++j)
{
const_cast<int *>(*buffer)[ps] = api.GetIntegerCatFeatureHash((*buffer)[ps]);
++buffer;
}
}
/// buffer contains column->size() rows and size columns.
/// For int cat features calc hash inplace.
/// For string cat features calc hash from column rows.
void calcHashes(const ColumnRawPtrs & columns, size_t offset, size_t size, const int ** buffer, const CatBoostLibraryHandler::APIHolder & api)
{
if (size == 0)
return;
size_t column_size = columns[offset]->size();
std::vector<PODArray<char>> data;
for (size_t i = 0; i < size; ++i)
{
const auto * column = columns[offset + i];
if (const auto * column_string = typeid_cast<const ColumnString *>(column))
calcStringHashes(column_string, i, buffer, api);
else if (const auto * column_fixed_string = typeid_cast<const ColumnFixedString *>(column))
calcStringHashes(column_fixed_string, i, buffer, api);
else
calcIntHashes(column_size, i, buffer, api);
}
}
}
/// Convert values to row-oriented format and call evaluation function from CatBoost wrapper api.
/// * CalcModelPredictionFlat if no cat features
/// * CalcModelPrediction if all cat features are strings
/// * CalcModelPredictionWithHashedCatFeatures if has int cat features.
ColumnFloat64::MutablePtr CatBoostLibraryHandler::evalImpl(
const ColumnRawPtrs & columns,
bool cat_features_are_strings) const
{
std::string error_msg = "Error occurred while applying CatBoost model: ";
size_t column_size = columns.front()->size();
auto result = ColumnFloat64::create(column_size * tree_count);
auto * result_buf = result->getData().data();
if (!column_size)
return result;
/// Prepare float features.
PODArray<const float *> float_features(column_size);
auto * float_features_buf = float_features.data();
/// Store all float data into single column. float_features is a list of pointers to it.
auto float_features_col = placeNumericColumns<float>(columns, 0, float_features_count, float_features_buf);
if (cat_features_count == 0)
{
if (!api.CalcModelPredictionFlat(model_calcer_handle, column_size,
float_features_buf, float_features_count,
result_buf, column_size * tree_count))
{
throw Exception(error_msg + api.GetErrorString(), ErrorCodes::CANNOT_APPLY_CATBOOST_MODEL);
}
return result;
}
/// Prepare cat features.
if (cat_features_are_strings)
{
/// cat_features_holder stores pointers to ColumnString data or fixed_strings_data.
PODArray<const char *> cat_features_holder(cat_features_count * column_size);
PODArray<const char **> cat_features(column_size);
auto * cat_features_buf = cat_features.data();
fillCatFeaturesBuffer(cat_features_buf, cat_features_holder.data(), column_size, cat_features_count);
/// Fixed strings are stored without termination zero, so have to copy data into fixed_strings_data.
auto fixed_strings_data = placeStringColumns(columns, float_features_count,
cat_features_count, cat_features_holder.data());
if (!api.CalcModelPrediction(model_calcer_handle, column_size,
float_features_buf, float_features_count,
cat_features_buf, cat_features_count,
result_buf, column_size * tree_count))
{
throw Exception(error_msg + api.GetErrorString(), ErrorCodes::CANNOT_APPLY_CATBOOST_MODEL);
}
}
else
{
PODArray<const int *> cat_features(column_size);
auto * cat_features_buf = cat_features.data();
auto cat_features_col = placeNumericColumns<int>(columns, float_features_count,
cat_features_count, cat_features_buf);
calcHashes(columns, float_features_count, cat_features_count, cat_features_buf, api);
if (!api.CalcModelPredictionWithHashedCatFeatures(
model_calcer_handle, column_size,
float_features_buf, float_features_count,
cat_features_buf, cat_features_count,
result_buf, column_size * tree_count))
{
throw Exception(error_msg + api.GetErrorString(), ErrorCodes::CANNOT_APPLY_CATBOOST_MODEL);
}
}
return result;
}
size_t CatBoostLibraryHandler::getTreeCount() const
{
std::lock_guard lock(mutex);
return tree_count;
}
ColumnPtr CatBoostLibraryHandler::evaluate(const ColumnRawPtrs & columns) const
{
std::lock_guard lock(mutex);
if (columns.empty())
throw Exception(ErrorCodes::BAD_ARGUMENTS, "Got empty columns list for CatBoost model.");
if (columns.size() != float_features_count + cat_features_count)
throw Exception(ErrorCodes::BAD_ARGUMENTS,
"Number of columns is different with number of features: columns size {} float features size {} + cat features size {}",
columns.size(),
float_features_count,
cat_features_count);
for (size_t i = 0; i < float_features_count; ++i)
{
if (!columns[i]->isNumeric())
{
throw Exception(ErrorCodes::BAD_ARGUMENTS, "Column {} should be numeric to make float feature.", i);
}
}
bool cat_features_are_strings = true;
for (size_t i = float_features_count; i < float_features_count + cat_features_count; ++i)
{
const auto * column = columns[i];
if (column->isNumeric())
{
cat_features_are_strings = false;
}
else if (!(typeid_cast<const ColumnString *>(column)
|| typeid_cast<const ColumnFixedString *>(column)))
{
throw Exception(ErrorCodes::BAD_ARGUMENTS, "Column {} should be numeric or string.", i);
}
}
auto result = evalImpl(columns, cat_features_are_strings);
if (tree_count == 1)
return result;
size_t column_size = columns.front()->size();
auto * result_buf = result->getData().data();
/// Multiple trees case. Copy data to several columns.
MutableColumns mutable_columns(tree_count);
std::vector<Float64 *> column_ptrs(tree_count);
for (size_t i = 0; i < tree_count; ++i)
{
auto col = ColumnFloat64::create(column_size);
column_ptrs[i] = col->getData().data();
mutable_columns[i] = std::move(col);
}
Float64 * data = result_buf;
for (size_t row = 0; row < column_size; ++row)
{
for (size_t i = 0; i < tree_count; ++i)
{
*column_ptrs[i] = *data;
++column_ptrs[i];
++data;
}
}
return ColumnTuple::create(std::move(mutable_columns));
}
}