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Neither the name of the copyright holder nor the names of its * contributors may be used to endorse or promote products derived from * this software without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" * AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER * CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. * **************************************************************************************************/ /*! \file \brief Functor performing linear combination operations on planar-complex arrays */ #pragma once #include "cutlass/cutlass.h" #include "cutlass/numeric_types.h" #include "cutlass/complex.h" #include "cutlass/array_planar_complex.h" #include "cutlass/functional.h" #include "cutlass/numeric_conversion.h" #include "cutlass/epilogue/thread/scale_type.h" ///////////////////////////////////////////////////////////////////////////////////////////////// namespace cutlass { namespace epilogue { namespace thread { ///////////////////////////////////////////////////////////////////////////////////////////////// /// Applies a linear combination operator to arrays of planar-complex elements. /// /// D = alpha * accumulator + beta * source + uniform /// /// Note, as with most CUTLASS components for planar complex, the template arguments describe /// the underlying real data type. template < typename ElementOutput_, ///< Data type used to load and store tensors int Count, ///< Number of elements computed per operation ///< Usually it is 128/sizeof_bits, ///< but we use 64 or 32 sometimes when there are not enough data to store typename ElementAccumulator_ = ElementOutput_, ///< Accumulator data type typename ElementCompute_ = ElementOutput_, ///< Data type used to compute linear combination FloatRoundStyle Round = FloatRoundStyle::round_to_nearest, ScaleType::Kind Scale = ScaleType::Default ///< Control Alpha and Beta scaling > class LinearCombinationPlanarComplex { public: using ElementOutput = ElementOutput_; using ElementAccumulator = ElementAccumulator_; using ElementCompute = ElementCompute_; using ElementScalar = complex; static int const kCount = Count; static const ScaleType::Kind kScale = Scale; using FragmentOutput = ArrayPlanarComplex; using FragmentAccumulator = ArrayPlanarComplex; using ComputeFragment = ArrayPlanarComplex; static FloatRoundStyle const kRound = Round; /// Host-constructable parameters structure struct Params { ElementScalar alpha{ElementCompute(1)}; ///< scales accumulators ElementScalar beta{ElementCompute(0)}; ///< scales source tensor ElementScalar const* alpha_ptr{nullptr}; ///< pointer to accumulator scalar - if not null, loads it from memory ElementScalar const* beta_ptr{nullptr}; ///< pointer to source scalar - if not null, loads it from memory // // Methods // Params() = default; CUTLASS_HOST_DEVICE Params( ElementScalar alpha, ElementScalar beta ): alpha(alpha), beta(beta) {} CUTLASS_HOST_DEVICE Params( ElementScalar const *alpha_ptr, ElementScalar const *beta_ptr ): alpha_ptr(alpha_ptr), beta_ptr(beta_ptr) {} }; private: // // Data members // ElementScalar alpha_; ElementScalar beta_; public: /// Constructs the function object, possibly loading from pointers in host memory CUTLASS_HOST_DEVICE LinearCombinationPlanarComplex(Params const ¶ms) { alpha_ = (params.alpha_ptr ? *params.alpha_ptr : params.alpha); beta_ = (params.beta_ptr ? *params.beta_ptr : params.beta); } /// Returns true if source is needed CUTLASS_HOST_DEVICE bool is_source_needed() const { if (Scale == ScaleType::OnlyAlphaScaling) return false; return beta_.real() != ElementCompute(0) || beta_.imag() != ElementCompute(0); } /// Functionally required for serial reduction in the epilogue CUTLASS_HOST_DEVICE void set_k_partition(int k_partition, int k_partition_count) { if (k_partition) { beta_ = ElementCompute(1); } } /// Computes linear scaling: D = alpha * accumulator + beta * source CUTLASS_HOST_DEVICE FragmentOutput operator()( FragmentAccumulator const &accumulator, FragmentOutput const &source) const { // Convert source to interal compute numeric type NumericArrayConverter source_converter; NumericArrayConverter accumulator_converter; ComputeFragment converted_source{ source_converter(source.real), source_converter(source.imag)}; ComputeFragment converted_accumulator{ accumulator_converter(accumulator.real), accumulator_converter(accumulator.imag)}; multiplies > mul_op; multiply_add > mul_add_op; // Perform binary operations // complex multiply: I = beta * C ComputeFragment intermediate { mul_op(beta_.real(), converted_source.real), mul_op(beta_.real(), converted_source.imag) }; intermediate.real = mul_add_op(-beta_.imag(), converted_source.imag, intermediate.real); intermediate.imag = mul_add_op( beta_.imag(), converted_source.real, intermediate.imag); // complex multiply-add: I = alpha * AB + I intermediate.real = mul_add_op(alpha_.real(), converted_accumulator.real, intermediate.real); intermediate.imag = mul_add_op(alpha_.real(), converted_accumulator.imag, intermediate.imag); intermediate.real = mul_add_op(-alpha_.imag(), converted_accumulator.imag, intermediate.real); intermediate.imag = mul_add_op( alpha_.imag(), converted_accumulator.real, intermediate.imag); // Convert to destination numeric type NumericArrayConverter destination_converter; return FragmentOutput{ destination_converter(intermediate.real), destination_converter(intermediate.imag)}; } /// Computes linear scaling: D = alpha * accumulator + beta * source CUTLASS_HOST_DEVICE FragmentOutput operator()( FragmentAccumulator const &accumulator) const { // Convert source to interal compute numeric type NumericArrayConverter accumulator_converter; ComputeFragment converted_accumulator{ accumulator_converter(accumulator.real), accumulator_converter(accumulator.imag)}; // Perform binary operations multiplies > mul_op; multiply_add > mul_add_op; // complex multiply-add: I = alpha * AB + I ComputeFragment intermediate { mul_op(alpha_.real(), converted_accumulator.real), mul_op(alpha_.real(), converted_accumulator.imag) }; intermediate.real = mul_add_op(-alpha_.imag(), converted_accumulator.imag, intermediate.real); intermediate.imag = mul_add_op( alpha_.imag(), converted_accumulator.real, intermediate.imag); // Convert to destination numeric type NumericArrayConverter destination_converter; return FragmentOutput{ destination_converter(intermediate.real), destination_converter(intermediate.imag)}; } }; ///////////////////////////////////////////////////////////////////////////////////////////////// } // namespace thread } // namespace epilogue } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////