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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 Template for a pipelined Rank2K kernel. Does not compute batching or support split-K. */ #pragma once #include "cutlass/blas3.h" #include "cutlass/arch/arch.h" #include "cutlass/device_kernel.h" #include "cutlass/gemm/threadblock/threadblock_swizzle.h" #include "cutlass/gemm/kernel/rank_2k_universal.h" #include "cutlass/gemm/kernel/default_rank_2k_universal.h" #include "cutlass/gemm/device/default_gemm_configuration.h" //////////////////////////////////////////////////////////////////////////////// namespace cutlass { namespace gemm { namespace device { ///////////////////////////////////////////////////////////////////////////////////////////////// template < /// Element type for A matrix operand typename ElementA_, /// Layout type for A matrix operand typename LayoutA_, /// Element type for B matrix operand typename ElementB_, /// Layout type for B matrix operand typename LayoutB_, /// Element type for C and D matrix operands typename ElementC_, /// Layout type for C and D matrix operands typename LayoutC_, /// Fill Mode for C (kLower or kUpper) FillMode FillModeC, /// Element type for internal accumulation typename ElementAccumulator_ = ElementC_, /// Operator class tag typename OperatorClass_ = arch::OpClassTensorOp, /// Tag indicating architecture to tune for typename ArchTag_ = arch::Sm80, /// Threadblock-level tile size (concept: GemmShape) typename ThreadblockShape_ = typename DefaultGemmConfiguration< OperatorClass_, ArchTag_, ElementA_, ElementA_, ElementC_, ElementAccumulator_>::ThreadblockShape, /// Warp-level tile size (concept: GemmShape) typename WarpShape_ = typename DefaultGemmConfiguration< OperatorClass_, ArchTag_, ElementA_, ElementA_, ElementC_, ElementAccumulator_>::WarpShape, /// Instruction-level tile size (concept: GemmShape) typename InstructionShape_ = typename DefaultGemmConfiguration< OperatorClass_, ArchTag_, ElementA_, ElementA_, ElementC_, ElementAccumulator_>::InstructionShape, /// Epilogue output operator typename EpilogueOutputOp_ = typename DefaultGemmConfiguration< OperatorClass_, ArchTag_, ElementA_, ElementA_, ElementC_, ElementAccumulator_>::EpilogueOutputOp, /// Threadblock-level swizzling operator typename ThreadblockSwizzle_ = typename threadblock::GemmIdentityThreadblockSwizzle<>, /// Number of stages used in the pipelined mainloop int Stages = DefaultGemmConfiguration::kStages, /// Access granularity of A matrix in units of elements int AlignmentA = DefaultGemmConfiguration::kAlignmentA, /// Access granularity of B matrix in units of elements int AlignmentB = DefaultGemmConfiguration::kAlignmentB, /// If true, kernel supports split-K with serial reduction bool SplitKSerial = false, /// Operation performed by SYRK typename Operator_ = typename DefaultGemmConfiguration< OperatorClass_, ArchTag_, ElementA_, ElementB_, ElementC_, ElementAccumulator_>::Operator, /// Complex elementwise transformation ComplexTransform TransformA = ComplexTransform::kNone, /// Complex elementwise transformation ComplexTransform TransformB = ComplexTransform::kNone, /// Blas3 computation mode (symmetric/hermitian) BlasMode BlasMode_ = BlasMode::kSymmetric> class Rank2K { public: using ElementA = ElementA_; using LayoutA = LayoutA_; using ElementB = ElementB_; using LayoutB = LayoutB_; using ElementC = ElementC_; using LayoutC = LayoutC_; using ElementAccumulator = ElementAccumulator_; using OperatorClass = OperatorClass_; using ArchTag = ArchTag_; using ThreadblockShape = ThreadblockShape_; using WarpShape = WarpShape_; using InstructionShape = InstructionShape_; using EpilogueOutputOp = EpilogueOutputOp_; using ThreadblockSwizzle = ThreadblockSwizzle_; using Operator = Operator_; static FillMode const kFillModeC = FillModeC; static int const kStages = Stages; static int const kAlignmentA = AlignmentA; static int const kAlignmentB = AlignmentB; static int const kAlignmentC = EpilogueOutputOp::kCount; static bool const kSplitKSerial = SplitKSerial; static ComplexTransform const kTransformA = TransformA; static ComplexTransform const kTransformB = TransformB; static BlasMode const kBlasMode = BlasMode_; static int const kUpdateRank = 2; // static asserts for rank 2k update kernel static_assert(platform::is_same::value, "Rank 2K update operator support same layouts for operandA and B"); /// Define the kernel using Rank2Kkernel = typename kernel::DefaultRank2KUniversal< ElementA, LayoutA, kTransformA, kAlignmentA, ElementB, LayoutB, kTransformB, kAlignmentB, ElementC, LayoutC, kFillModeC, ElementAccumulator, OperatorClass, ArchTag, ThreadblockShape, WarpShape, InstructionShape, EpilogueOutputOp, ThreadblockSwizzle, kStages, kSplitKSerial, Operator, kBlasMode >::Rank2Kkernel; using Arguments = typename Rank2Kkernel::Arguments; private: /// Kernel parameters object typename Rank2Kkernel::Params params_; public: /// Constructs the SYRK. Rank2K() { } /// Determines whether the SYRK can execute the given problem. static Status can_implement(Arguments const &args) { if (!kSplitKSerial && args.batch_count > 1) { return Status::kErrorInvalidProblem; } Status status = Rank2Kkernel::can_implement(args); if (FillModeC != FillMode::kLower && FillModeC != FillMode::kUpper) { return Status::kErrorInvalidProblem; } if (status != Status::kSuccess) { return status; } return Status::kSuccess; } /// Gets the workspace size static size_t get_workspace_size(Arguments const &args) { size_t bytes = 0; // Determine grid shape ThreadblockSwizzle threadblock_swizzle; cutlass::gemm::GemmCoord tiled_shape = threadblock_swizzle.get_tiled_shape( args.problem_size, {ThreadblockShape::kM, ThreadblockShape::kN, ThreadblockShape::kK}, args.batch_count); if (kSplitKSerial && args.batch_count > 1) { bytes += sizeof(int) * size_t(tiled_shape.m()) * size_t(tiled_shape.n()); } return bytes; } /// Initializes SYRK state from arguments. Status initialize(Arguments const &args, void *workspace = nullptr, cudaStream_t stream = nullptr) { // Determine grid shape ThreadblockSwizzle threadblock_swizzle; cutlass::gemm::GemmCoord grid_tiled_shape = threadblock_swizzle.get_tiled_shape( args.problem_size, {ThreadblockShape::kM, ThreadblockShape::kN, ThreadblockShape::kK}, args.batch_count); if (kSplitKSerial) { if (args.batch_count > 1) { if (!workspace) { return Status::kErrorWorkspaceNull; } size_t bytes = get_workspace_size(args); cudaError_t result = cudaMemsetAsync(workspace, 0, bytes, stream); if (result != cudaSuccess) { return Status::kErrorInternal; } } } else { if (args.batch_count > 1) { return Status::kErrorInvalidProblem; } } int gemm_k_size = args.problem_size.k(); // Initialize the Params structure params_ = typename Rank2Kkernel::Params{ args, grid_tiled_shape, gemm_k_size, static_cast(workspace) }; int smem_size = int(sizeof(typename Rank2Kkernel::SharedStorage)); if (smem_size >= (48 << 10)) { cudaError_t result = cudaFuncSetAttribute(Kernel, cudaFuncAttributeMaxDynamicSharedMemorySize, smem_size); if (result != cudaSuccess) { return Status::kErrorInternal; } } return Status::kSuccess; } /// Lightweight update given a subset of arguments Status update(Arguments const &args, void *workspace = nullptr) { if (kSplitKSerial && args.batch_count > 1) { if (!workspace) { return Status::kErrorWorkspaceNull; } } size_t workspace_bytes = get_workspace_size(args); if (workspace_bytes && !workspace) { return Status::kErrorWorkspaceNull; } params_.update(args, workspace); return Status::kSuccess; } /// Runs the kernel using initialized state. Status run(cudaStream_t stream = nullptr) { ThreadblockSwizzle threadblock_swizzle; dim3 grid = threadblock_swizzle.get_grid_shape(params_.grid_tiled_shape); dim3 block(Rank2Kkernel::kThreadCount, 1, 1); int smem_size = int(sizeof(typename Rank2Kkernel::SharedStorage)); cutlass::arch::synclog_setup(); cutlass::Kernel<<>>(params_); cudaError_t result = cudaGetLastError(); return result == cudaSuccess ? Status::kSuccess : Status::kErrorInternal; } /// Runs the kernel using initialized state. Status operator()(cudaStream_t stream = nullptr) { return run(stream); } /// Runs the kernel using initialized state. Status operator()( Arguments const &args, void *workspace = nullptr, cudaStream_t stream = nullptr) { Status status = initialize(args, workspace); if (status == Status::kSuccess) { status = run(stream); } return status; } }; //////////////////////////////////////////////////////////////////////////////// /// Partial specialization for column-major output exchange operand. template < /// Element type for A matrix operand typename ElementA_, /// Layout type for A matrix operand typename LayoutA_, /// Element type for B matrix operand typename ElementB_, /// Layout type for B matrix operand typename LayoutB_, /// Element type for C and D matrix operands typename ElementC_, /// Fill Mode for C (kLower or kUpper) FillMode FillModeC, /// Element type for internal accumulation typename ElementAccumulator_, /// Operator class tag typename OperatorClass_, /// Tag indicating architecture to tune for. This is the minimum SM that /// supports the intended feature. The device kernel can be built /// targeting any SM larger than this number. typename ArchTag_, /// Threadblock-level tile size (concept: GemmShape) typename ThreadblockShape_, /// Warp-level tile size (concept: GemmShape) typename WarpShape_, /// Instruction-level tile size (concept: GemmShape) typename InstructionShape_, /// Epilogue output operator typename EpilogueOutputOp_, /// Threadblock-level swizzling operator typename ThreadblockSwizzle_, /// Number of stages used in the pipelined mainloop int Stages, /// Access granularity of A matrix in units of elements int AlignmentA, /// Access granularity of B matrix in units of elements int AlignmentB, /// If true, kernel supports split-K with serial reduction bool SplitKSerial, /// Operation performed by Rank2K update kernel typename Operator_, /// Complex elementwise transformation ComplexTransform TransformA, /// Complex elementwise transformation ComplexTransform TransformB, /// Blas3 computation mode (symmetric/hermitian) BlasMode BlasMode_ > class Rank2K { public: using ElementA = ElementA_; using LayoutA = LayoutA_; using ElementB = ElementB_; using LayoutB = LayoutB_; using ElementC = ElementC_; using LayoutC = layout::ColumnMajor; using ElementAccumulator = ElementAccumulator_; using OperatorClass = OperatorClass_; using ArchTag = ArchTag_; using ThreadblockShape = ThreadblockShape_; using WarpShape = WarpShape_; using InstructionShape = InstructionShape_; using EpilogueOutputOp = EpilogueOutputOp_; using ThreadblockSwizzle = ThreadblockSwizzle_; using Operator = Operator_; static FillMode const kFillModeC = FillModeC; static int const kStages = Stages; static int const kAlignmentA = AlignmentA; static int const kAlignmentB = AlignmentB; static int const kAlignmentC = EpilogueOutputOp::kCount; static bool const kSplitKSerial = SplitKSerial; static BlasMode const kBlasMode = BlasMode_; static ComplexTransform const kTransformA = TransformA; static ComplexTransform const kTransformB = TransformB; static int const kUpdateRank = 2; /// Define the kernel using UnderlyingOperator = typename cutlass::gemm::device::Rank2K< ElementB, LayoutB, ElementA, LayoutA, ElementC, layout::RowMajor, InvertFillMode::mode, ElementAccumulator, OperatorClass, ArchTag, ThreadblockShape, WarpShape, InstructionShape, EpilogueOutputOp, ThreadblockSwizzle, kStages, kAlignmentB, kAlignmentA, kSplitKSerial, Operator, kTransformA, kTransformB, kBlasMode >; /// Argument structure using Arguments = typename UnderlyingOperator::Arguments; using Rank2Kkernel = typename UnderlyingOperator::Rank2Kkernel; private: UnderlyingOperator underlying_operator_; public: /// Constructs the Rank2K. Rank2K() { } /// Helper to construct a transposed equivalent for the underlying Rank2K operator static Arguments to_underlying_arguments(Arguments const &args) { return args.transposed_problem(); } /// Determines whether the Rank2K can execute the given problem. static Status can_implement(Arguments const &args) { return UnderlyingOperator::can_implement(to_underlying_arguments(args)); } /// Gets the workspace size static size_t get_workspace_size(Arguments const &args) { return UnderlyingOperator::get_workspace_size(to_underlying_arguments(args)); } /// Computes the grid shape static dim3 get_grid_shape(Arguments const &args) { return UnderlyingOperator::get_grid_shape(to_underlying_arguments(args)); } /// Computes the maximum number of active blocks per multiprocessor static int maximum_active_blocks(int smem_capacity = -1) { return UnderlyingOperator::maximum_active_blocks(smem_capacity); } /// Initializes Rank2K state from arguments. Status initialize(Arguments const &args, void *workspace = nullptr, cudaStream_t stream = nullptr) { return underlying_operator_.initialize(to_underlying_arguments(args), workspace, stream); } /// Lightweight update given a subset of arguments Status update(Arguments const &args, void *workspace = nullptr) { return underlying_operator_.update(to_underlying_arguments(args), workspace); } /// Runs the kernel using initialized state. Status run(cudaStream_t stream = nullptr) { return underlying_operator_.run(stream); } /// Runs the kernel using initialized state. Status operator()(cudaStream_t stream = nullptr) { return run(stream); } /// Runs the kernel using initialized state. Status operator()( Arguments const &args, void *workspace = nullptr, cudaStream_t stream = nullptr) { Status status = initialize(args, workspace, stream); if (status == Status::kSuccess) { status = run(stream); } return status; } }; //////////////////////////////////////////////////////////////////////////////// } // namespace device } // namespace Rank2K } // namespace cutlass ////////////////////////////////////////////////////////////////////////////////