ClickHouse/dbms/src/Functions/FunctionsFindCluster.h

302 lines
12 KiB
C++

#pragma once
#include <DataTypes/DataTypesNumber.h>
#include <DataTypes/DataTypeArray.h>
#include <Columns/ColumnArray.h>
#include <Columns/ColumnConst.h>
#include <Columns/ColumnsNumber.h>
#include <Functions/IFunction.h>
#include <Functions/FunctionHelpers.h>
#include <IO/WriteHelpers.h>
#include <Common/typeid_cast.h>
namespace DB
{
namespace ErrorCodes
{
extern const int NUMBER_OF_ARGUMENTS_DOESNT_MATCH;
extern const int ILLEGAL_COLUMN;
}
enum ClusterOperation
{
FindClusterIndex = 0,
FindCentroidValue = 1
};
/// The centroid values are converted to Float64 for easier coding of
/// distance calculations.
///
/// We assume to have 10th to 100th centroids, usually of type Float64, as a typical use case.
/// While it is possible to sort centroids and use a modification of a binary search to find the
/// nearest centroid, we think for arrays of 10th to 100th this might be an overkill.
///
/// Also, even though centroids of other types are feasible, this first implementation
/// lacks support of them for simplicity. Date, DateTime and Strings (eg. with the
/// Levenshtein distance) could be theoretically supported, as well as custom distance
/// functions (eg. Hamming distance) using Clickhouse lambdas.
// Centroids array has the same size as number of clusters.
size_t find_centroid(Float64 x, std::vector<Float64> & centroids)
{
// Centroids array has to have at least one element, and if it has only one element,
// it is also the result of this Function.
Float64 distance = std::abs(centroids[0] - x);
size_t index = 0;
// Check if we have more clusters and if we have, whether some is closer to src[i]
for (size_t j = 1; j < centroids.size(); ++j)
{
Float64 next_distance = std::abs(centroids[j] - x);
if (next_distance < distance)
{
distance = next_distance;
index = j;
}
}
// Index of the closest cluster, or 0 in case of just one cluster
return index;
}
/** findClusterIndex(x, centroids_array) - find index of element in centroids_array with the value nearest to x
* findClusterValue(x, centroids_array) - find value of element in centroids_array with the value nearest to x
*
* Types:
* findClusterIndex(T, Array(T)) -> UInt64
* findClusterValue(T, Array(T)) -> T
*
* T can be any numeric type.
* centroids_array must be constant
*/
class FunctionFindClusterIndex : public IFunction
{
public:
static constexpr auto name = "findClusterIndex";
static FunctionPtr create(const Context &)
{
return std::make_shared<FunctionFindClusterIndex>();
}
String getName() const override
{
return FunctionFindClusterIndex::name;
}
bool isVariadic() const override
{
return true;
}
size_t getNumberOfArguments() const override
{
return 0;
}
bool useDefaultImplementationForConstants() const override { return true; }
ColumnNumbers getArgumentsThatAreAlwaysConstant() const override { return {1}; }
DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override
{
const auto args_size = arguments.size();
if (args_size != 2)
throw Exception{"Number of arguments for function " + getName() + " doesn't match: passed " + toString(args_size) + ", should be 2",
ErrorCodes::NUMBER_OF_ARGUMENTS_DOESNT_MATCH};
const auto type_x = arguments[0];
if (!isNativeNumber(type_x))
throw Exception{"Unsupported type " + type_x->getName() + " of first argument of function " + getName() + " must be a numeric type",
ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT};
const DataTypeArray * type_arr_from = checkAndGetDataType<DataTypeArray>(arguments[1].get());
if (!type_arr_from)
throw Exception{"Second argument of function " + getName() + " must be literal array", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT};
return std::make_shared<DataTypeUInt64>();
}
void executeImpl(Block & block, const ColumnNumbers & arguments, size_t result, size_t /*input_rows_count*/) override
{
const auto in_untyped = block.getByPosition(arguments[0]).column.get();
const auto centroids_array_untyped = block.getByPosition(arguments[1]).column.get();
auto column_result = block.getByPosition(result).type->createColumn();
auto out_untyped = column_result.get();
if (!isColumnConst(*centroids_array_untyped))
throw Exception{"Second argument of function " + getName() + " must be literal array", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT};
executeImplTyped(in_untyped, out_untyped, centroids_array_untyped);
block.getByPosition(result).column = std::move(column_result);
}
protected:
virtual ClusterOperation getOperation()
{
return ClusterOperation::FindClusterIndex;
}
virtual void executeImplTyped(const IColumn* in_untyped, IColumn* out_untyped, const IColumn* centroids_array_untyped)
{
if (!executeOperation<UInt8, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt16, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt32, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt64, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int8, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int16, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int32, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int64, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Float32, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Float64, UInt64>(in_untyped, out_untyped, centroids_array_untyped))
{
throw Exception{"Function " + getName() + " expects both x and centroids_array of a numeric type."
" Passed arguments are " + in_untyped->getName() + " and " + centroids_array_untyped->getName(), ErrorCodes::ILLEGAL_COLUMN};
}
}
// Match the type of the centrods array and convert them to Float64, because we
// don't want to have problems calculating negative distances of UInts
template <typename CentroidsType>
bool fillCentroids(const IColumn * centroids_array_untyped, std::vector<Float64> & centroids)
{
const ColumnConst * const_centroids_array = checkAndGetColumnConst<ColumnVector<Array>>(centroids_array_untyped);
if (!const_centroids_array)
return false;
Array array = const_centroids_array->getValue<Array>();
if (array.empty())
throw Exception{"Centroids array must be not empty", ErrorCodes::ILLEGAL_COLUMN};
for (size_t k = 0; k < array.size(); ++k)
{
const Field & tmp_field = array[k];
NearestFieldType<CentroidsType> value;
if (!tmp_field.tryGet(value))
return false;
centroids.push_back(Float64(value));
}
return true;
}
template <typename CentroidsType, typename OutputType>
bool executeOperation(const IColumn * in_untyped, IColumn * out_untyped, const IColumn * centroids_array_untyped)
{
// Match the type of the output
auto out = typeid_cast<ColumnVector<OutputType> *>(out_untyped);
if (!out)
return false;
PaddedPODArray<OutputType> & dst = out->getData();
// try to match the type of the input column
if (!executeOperationTyped<UInt8, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<UInt16, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<UInt32, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<UInt64, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Int8, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Int16, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Int32, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Int64, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Float32, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped)
&& !executeOperationTyped<Float64, OutputType, CentroidsType>(in_untyped, dst, centroids_array_untyped))
{
return false;
}
return true;
}
template <typename InputType, typename OutputType, typename CentroidsType>
bool executeOperationTyped(const IColumn * in_untyped, PaddedPODArray<OutputType> & dst, const IColumn * centroids_array_untyped)
{
const auto maybe_const = in_untyped->convertToFullColumnIfConst();
in_untyped = maybe_const.get();
const auto in_vector = checkAndGetColumn<ColumnVector<InputType>>(in_untyped);
if (in_vector)
{
const PaddedPODArray<InputType> & src = in_vector->getData();
std::vector<Float64> centroids;
if (!fillCentroids<CentroidsType>(centroids_array_untyped, centroids))
return false;
for (size_t i = 0; i < src.size(); ++i)
{
size_t index = find_centroid(Float64(src[i]), centroids);
if (getOperation() == ClusterOperation::FindClusterIndex)
// Note that array indexes start with 1 in Clickhouse
dst.push_back(UInt64(index + 1));
else if (getOperation() == ClusterOperation::FindCentroidValue)
dst.push_back(centroids[index]);
else
throw Exception{"Unexpected error in findCluster* function", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT};
}
return true;
}
return false;
}
};
class FunctionFindClusterValue : public FunctionFindClusterIndex
{
public:
static constexpr auto name = "findClusterValue";
static FunctionPtr create(const Context &)
{
return std::make_shared<FunctionFindClusterValue>();
}
DataTypePtr getReturnTypeImpl(const DataTypes & arguments) const override
{
FunctionFindClusterIndex::getReturnTypeImpl(arguments);
const DataTypeArray * type_arr_from = checkAndGetDataType<DataTypeArray>(arguments[1].get());
return type_arr_from->getNestedType();
}
String getName() const override
{
return FunctionFindClusterValue::name;
}
protected:
ClusterOperation getOperation() override
{
return ClusterOperation::FindCentroidValue;
}
void executeImplTyped(const IColumn* in_untyped, IColumn* out_untyped, const IColumn* centroids_array_untyped) override
{
if (!executeOperation<UInt8, UInt8>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt16, UInt16>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt32, UInt32>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<UInt64, UInt64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int8, Int8>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int16, Int16>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int32, Int32>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Int64, Int64>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Float32, Float32>(in_untyped, out_untyped, centroids_array_untyped)
&& !executeOperation<Float64, Float64>(in_untyped, out_untyped, centroids_array_untyped))
{
throw Exception{"Function " + getName() + " expects both x and centroids_array of a numeric type."
"Passed arguments are " + in_untyped->getName() + " and " + centroids_array_untyped->getName(), ErrorCodes::ILLEGAL_COLUMN};
}
}
};
}