ClickHouse/dbms/src/Functions/modulo.cpp

#include <Functions/FunctionFactory.h>
#include <Functions/FunctionBinaryArithmetic.h>

#if __SSE2__
    #define LIBDIVIDE_USE_SSE2 1
#endif

#include <libdivide.h>


namespace DB
{

namespace ErrorCodes
{
    extern const int ILLEGAL_DIVISION;
}

template <typename A, typename B>
struct ModuloImpl
{
    using ResultType = typename NumberTraits::ResultOfModulo<A, B>::Type;

    template <typename Result = ResultType>
    static inline Result apply(A a, B b)
    {
        throwIfDivisionLeadsToFPE(typename NumberTraits::ToInteger<A>::Type(a), typename NumberTraits::ToInteger<B>::Type(b));
        return typename NumberTraits::ToInteger<A>::Type(a) % typename NumberTraits::ToInteger<B>::Type(b);
    }

#if USE_EMBEDDED_COMPILER
    static constexpr bool compilable = false; /// don't know how to throw from LLVM IR
#endif
};

template <typename A, typename B>
struct ModuloByConstantImpl
    : BinaryOperationImplBase<A, B, ModuloImpl<A, B>>
{
    using ResultType = typename ModuloImpl<A, B>::ResultType;

    static void vector_constant(const PaddedPODArray<A> & a, B b, PaddedPODArray<ResultType> & c)
    {
        if (unlikely(b == 0))
            throw Exception("Division by zero", ErrorCodes::ILLEGAL_DIVISION);

#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wsign-compare"

        if (unlikely((std::is_signed_v<B> && b == -1) || b == 1))
        {
            size_t size = a.size();
            for (size_t i = 0; i < size; ++i)
                c[i] = 0;
            return;
        }

#pragma GCC diagnostic pop

        libdivide::divider<A> divider(b);

        /// Here we failed to make the SSE variant from libdivide give an advantage.
        size_t size = a.size();
        for (size_t i = 0; i < size; ++i)
            c[i] = a[i] - (a[i] / divider) * b; /// NOTE: perhaps, the division semantics with the remainder of negative numbers is not preserved.
    }
};

/** Specializations are specified for dividing numbers of the type UInt64 and UInt32 by the numbers of the same sign.
  * Can be expanded to all possible combinations, but more code is needed.
  */

template <> struct BinaryOperationImpl<UInt64, UInt8, ModuloImpl<UInt64, UInt8>> : ModuloByConstantImpl<UInt64, UInt8> {};
template <> struct BinaryOperationImpl<UInt64, UInt16, ModuloImpl<UInt64, UInt16>> : ModuloByConstantImpl<UInt64, UInt16> {};
template <> struct BinaryOperationImpl<UInt64, UInt32, ModuloImpl<UInt64, UInt32>> : ModuloByConstantImpl<UInt64, UInt32> {};
template <> struct BinaryOperationImpl<UInt64, UInt64, ModuloImpl<UInt64, UInt64>> : ModuloByConstantImpl<UInt64, UInt64> {};

template <> struct BinaryOperationImpl<UInt32, UInt8, ModuloImpl<UInt32, UInt8>> : ModuloByConstantImpl<UInt32, UInt8> {};
template <> struct BinaryOperationImpl<UInt32, UInt16, ModuloImpl<UInt32, UInt16>> : ModuloByConstantImpl<UInt32, UInt16> {};
template <> struct BinaryOperationImpl<UInt32, UInt32, ModuloImpl<UInt32, UInt32>> : ModuloByConstantImpl<UInt32, UInt32> {};
template <> struct BinaryOperationImpl<UInt32, UInt64, ModuloImpl<UInt32, UInt64>> : ModuloByConstantImpl<UInt32, UInt64> {};

template <> struct BinaryOperationImpl<Int64, Int8, ModuloImpl<Int64, Int8>> : ModuloByConstantImpl<Int64, Int8> {};
template <> struct BinaryOperationImpl<Int64, Int16, ModuloImpl<Int64, Int16>> : ModuloByConstantImpl<Int64, Int16> {};
template <> struct BinaryOperationImpl<Int64, Int32, ModuloImpl<Int64, Int32>> : ModuloByConstantImpl<Int64, Int32> {};
template <> struct BinaryOperationImpl<Int64, Int64, ModuloImpl<Int64, Int64>> : ModuloByConstantImpl<Int64, Int64> {};

template <> struct BinaryOperationImpl<Int32, Int8, ModuloImpl<Int32, Int8>> : ModuloByConstantImpl<Int32, Int8> {};
template <> struct BinaryOperationImpl<Int32, Int16, ModuloImpl<Int32, Int16>> : ModuloByConstantImpl<Int32, Int16> {};
template <> struct BinaryOperationImpl<Int32, Int32, ModuloImpl<Int32, Int32>> : ModuloByConstantImpl<Int32, Int32> {};
template <> struct BinaryOperationImpl<Int32, Int64, ModuloImpl<Int32, Int64>> : ModuloByConstantImpl<Int32, Int64> {};


struct NameModulo { static constexpr auto name = "modulo"; };
using FunctionModulo = FunctionBinaryArithmetic<ModuloImpl, NameModulo, false>;

void registerFunctionModulo(FunctionFactory & factory)
{
    factory.registerFunction<FunctionModulo>();
}

}
Every function in its own file, part 7 (#3666) * Every function in its own file, part 7 [#CLICKHOUSE-2] * Every function in its own file, part 7 [#CLICKHOUSE-2] * Every function in its own file, part 7 [#CLICKHOUSE-2] * Every function in its own file, part 7 [#CLICKHOUSE-2] * Every function in its own file, part 7 [#CLICKHOUSE-2] * Fixed build #3666 2018-11-26 16:20:40 +00:00			`#include <Functions/FunctionFactory.h>`
			`#include <Functions/FunctionBinaryArithmetic.h>`

			`#if __SSE2__`
			`#define LIBDIVIDE_USE_SSE2 1`
			`#endif`

			`#include <libdivide.h>`


			`namespace DB`
			`{`

			`namespace ErrorCodes`
			`{`
			`extern const int ILLEGAL_DIVISION;`
			`}`

			`template <typename A, typename B>`
			`struct ModuloImpl`
			`{`
			`using ResultType = typename NumberTraits::ResultOfModulo<A, B>::Type;`

			`template <typename Result = ResultType>`
			`static inline Result apply(A a, B b)`
			`{`
			`throwIfDivisionLeadsToFPE(typename NumberTraits::ToInteger<A>::Type(a), typename NumberTraits::ToInteger<B>::Type(b));`
			`return typename NumberTraits::ToInteger<A>::Type(a) % typename NumberTraits::ToInteger<B>::Type(b);`
			`}`

			`#if USE_EMBEDDED_COMPILER`
			`static constexpr bool compilable = false; /// don't know how to throw from LLVM IR`
			`#endif`
			`};`

			`template <typename A, typename B>`
			`struct ModuloByConstantImpl`
			`: BinaryOperationImplBase<A, B, ModuloImpl<A, B>>`
			`{`
			`using ResultType = typename ModuloImpl<A, B>::ResultType;`

			`static void vector_constant(const PaddedPODArray<A> & a, B b, PaddedPODArray<ResultType> & c)`
			`{`
			`if (unlikely(b == 0))`
			`throw Exception("Division by zero", ErrorCodes::ILLEGAL_DIVISION);`

			`#pragma GCC diagnostic push`
			`#pragma GCC diagnostic ignored "-Wsign-compare"`

			`if (unlikely((std::is_signed_v<B> && b == -1) \|\| b == 1))`
			`{`
			`size_t size = a.size();`
			`for (size_t i = 0; i < size; ++i)`
			`c[i] = 0;`
			`return;`
			`}`

			`#pragma GCC diagnostic pop`

			`libdivide::divider<A> divider(b);`

			`/// Here we failed to make the SSE variant from libdivide give an advantage.`
			`size_t size = a.size();`
			`for (size_t i = 0; i < size; ++i)`
			`c[i] = a[i] - (a[i] / divider) * b; /// NOTE: perhaps, the division semantics with the remainder of negative numbers is not preserved.`
			`}`
			`};`

			`/** Specializations are specified for dividing numbers of the type UInt64 and UInt32 by the numbers of the same sign.`
			`* Can be expanded to all possible combinations, but more code is needed.`
			`*/`

			`template <> struct BinaryOperationImpl<UInt64, UInt8, ModuloImpl<UInt64, UInt8>> : ModuloByConstantImpl<UInt64, UInt8> {};`
			`template <> struct BinaryOperationImpl<UInt64, UInt16, ModuloImpl<UInt64, UInt16>> : ModuloByConstantImpl<UInt64, UInt16> {};`
			`template <> struct BinaryOperationImpl<UInt64, UInt32, ModuloImpl<UInt64, UInt32>> : ModuloByConstantImpl<UInt64, UInt32> {};`
			`template <> struct BinaryOperationImpl<UInt64, UInt64, ModuloImpl<UInt64, UInt64>> : ModuloByConstantImpl<UInt64, UInt64> {};`

			`template <> struct BinaryOperationImpl<UInt32, UInt8, ModuloImpl<UInt32, UInt8>> : ModuloByConstantImpl<UInt32, UInt8> {};`
			`template <> struct BinaryOperationImpl<UInt32, UInt16, ModuloImpl<UInt32, UInt16>> : ModuloByConstantImpl<UInt32, UInt16> {};`
			`template <> struct BinaryOperationImpl<UInt32, UInt32, ModuloImpl<UInt32, UInt32>> : ModuloByConstantImpl<UInt32, UInt32> {};`
			`template <> struct BinaryOperationImpl<UInt32, UInt64, ModuloImpl<UInt32, UInt64>> : ModuloByConstantImpl<UInt32, UInt64> {};`

			`template <> struct BinaryOperationImpl<Int64, Int8, ModuloImpl<Int64, Int8>> : ModuloByConstantImpl<Int64, Int8> {};`
			`template <> struct BinaryOperationImpl<Int64, Int16, ModuloImpl<Int64, Int16>> : ModuloByConstantImpl<Int64, Int16> {};`
			`template <> struct BinaryOperationImpl<Int64, Int32, ModuloImpl<Int64, Int32>> : ModuloByConstantImpl<Int64, Int32> {};`
			`template <> struct BinaryOperationImpl<Int64, Int64, ModuloImpl<Int64, Int64>> : ModuloByConstantImpl<Int64, Int64> {};`

			`template <> struct BinaryOperationImpl<Int32, Int8, ModuloImpl<Int32, Int8>> : ModuloByConstantImpl<Int32, Int8> {};`
			`template <> struct BinaryOperationImpl<Int32, Int16, ModuloImpl<Int32, Int16>> : ModuloByConstantImpl<Int32, Int16> {};`
			`template <> struct BinaryOperationImpl<Int32, Int32, ModuloImpl<Int32, Int32>> : ModuloByConstantImpl<Int32, Int32> {};`
			`template <> struct BinaryOperationImpl<Int32, Int64, ModuloImpl<Int32, Int64>> : ModuloByConstantImpl<Int32, Int64> {};`


			`struct NameModulo { static constexpr auto name = "modulo"; };`
			`using FunctionModulo = FunctionBinaryArithmetic<ModuloImpl, NameModulo, false>;`

			`void registerFunctionModulo(FunctionFactory & factory)`
			`{`
			`factory.registerFunction<FunctionModulo>();`
			`}`

			`}`