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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 */ #pragma once #include "cutlass/blas3.h" #include "cutlass/fast_math.h" #include "cutlass/gemm/gemm.h" #include "cutlass/matrix_coord.h" #include "cutlass/complex.h" #include "cutlass/semaphore.h" #include "cutlass/core_io.h" ///////////////////////////////////////////////////////////////////////////////////////////////// namespace cutlass { namespace gemm { namespace kernel { ///////////////////////////////////////////////////////////////////////////////////////////////// template < typename Mma_, ///! Threadblock-scoped matrix multiply-accumulate typename Epilogue_, ///! Epilogue typename ThreadblockSwizzle_, ///! Threadblock swizzling function SideMode SideMode_, ///! Side Mode for the kernel (kLeft or kRight) FillMode FillMode_, ///! Fill Mode for triangular matrix (kLower or kUpper) DiagType DiagType_ ///! Diag Type for triangular matrix (kNonUnit or kUnit) > struct TrmmUniversal { public: using Mma = Mma_; using Epilogue = Epilogue_; using EpilogueOutputOp = typename Epilogue::OutputOp; using ThreadblockSwizzle = ThreadblockSwizzle_; using ElementA = typename Mma::IteratorA::Element; using LayoutA = typename Mma::IteratorA::Layout; using ElementB = typename Mma::IteratorB::Element; using LayoutB = typename Mma::IteratorB::Layout; using ElementC = typename Epilogue::OutputTileIterator::Element; using LayoutC = typename Epilogue::OutputTileIterator::Layout; static SideMode const kSideMode = SideMode_; static FillMode const kFillMode = FillMode_; static DiagType const kDiagType = DiagType_; static ComplexTransform const kTransformA = Mma::kTransformA; static ComplexTransform const kTransformB = Mma::kTransformB; using Operator = typename Mma::Operator; using OperatorClass = typename Mma::Operator::OperatorClass; using ThreadblockShape = typename Mma::Shape; using WarpShape = typename Mma::Operator::Shape; using InstructionShape = typename Mma::Policy::Operator::InstructionShape; using ArchTag = typename Mma::ArchTag; static int const kStages = Mma::kStages; static int const kAlignmentA = Mma::IteratorA::AccessType::kElements; static int const kAlignmentB = Mma::IteratorB::AccessType::kElements; static int const kAlignmentC = Epilogue::OutputTileIterator::kElementsPerAccess; /// Warp count (concept: GemmShape) using WarpCount = typename Mma::WarpCount; static int const kThreadCount = 32 * WarpCount::kCount; /// Split-K preserves splits that are 128b aligned static int const kSplitKAlignment = const_max(128 / sizeof_bits::value, 128 / sizeof_bits::value); // // Structures // /// Argument structure struct Arguments { // // Data members // GemmUniversalMode mode{GemmUniversalMode::kGemm}; GemmCoord problem_size{}; int batch_count{1}; typename EpilogueOutputOp::Params epilogue{}; void const * ptr_A{nullptr}; void const * ptr_B{nullptr}; void * ptr_D{nullptr}; int64_t batch_stride_A{0}; int64_t batch_stride_B{0}; int64_t batch_stride_D{0}; typename LayoutA::Stride::Index lda{0}; typename LayoutB::Stride::Index ldb{0}; typename LayoutC::Stride::Index ldd{0}; // // Methods // Arguments() = default; /// constructs an arguments structure Arguments( GemmUniversalMode mode, GemmCoord problem_size, int batch_count, typename EpilogueOutputOp::Params epilogue, void const * ptr_A, void const * ptr_B, void * ptr_D, int64_t batch_stride_A, int64_t batch_stride_B, int64_t batch_stride_D, typename LayoutA::Stride::Index lda, typename LayoutB::Stride::Index ldb, typename LayoutC::Stride::Index ldd ): mode(mode), problem_size(problem_size), batch_count(batch_count), epilogue(epilogue), ptr_A(ptr_A), ptr_B(ptr_B), ptr_D(ptr_D), batch_stride_A(batch_stride_A), batch_stride_B(batch_stride_B), batch_stride_D(batch_stride_D), lda(lda), ldb(ldb), ldd(ldd) { } /// Returns arguments for the transposed problem sizes Arguments transposed_problem_size() const { Arguments args(*this); std::swap(args.problem_size.m(), args.problem_size.n()); return args; } /// Returns arguments for the transposed matrices Arguments swapped_matrices() const { Arguments args(*this); std::swap(args.ptr_A, args.ptr_B); std::swap(args.lda, args.ldb); std::swap(args.batch_stride_A, args.batch_stride_B); return args; } }; // // Structure for precomputing values in host memory and passing to kernels // /// Parameters structure struct Params { cutlass::gemm::GemmCoord problem_size{}; cutlass::gemm::GemmCoord grid_tiled_shape{}; int swizzle_log_tile{0}; typename Mma::IteratorA::Params params_A{}; typename Mma::IteratorB::Params params_B{}; typename Epilogue::OutputTileIterator::Params params_D{}; typename EpilogueOutputOp::Params output_op{}; GemmUniversalMode mode = cutlass::gemm::GemmUniversalMode::kGemm; int batch_count {0}; int gemm_k_size {0}; void * ptr_A{nullptr}; void * ptr_B{nullptr}; void * ptr_D{nullptr}; int64_t batch_stride_A {0}; int64_t batch_stride_B {0}; int64_t batch_stride_D {0}; int *semaphore{nullptr}; // // Methods // Params() = default; CUTLASS_HOST_DEVICE Params( Arguments const &args, cutlass::gemm::GemmCoord const & grid_tiled_shape, int gemm_k_size, void *workspace = nullptr ): problem_size(args.problem_size), grid_tiled_shape(grid_tiled_shape), swizzle_log_tile(ThreadblockSwizzle().get_log_tile(grid_tiled_shape)), params_A(args.lda), params_B(args.ldb), params_D(args.ldd), output_op(args.epilogue), mode(args.mode), batch_count(args.batch_count), gemm_k_size(gemm_k_size), ptr_A(const_cast(args.ptr_A)), ptr_B(const_cast(args.ptr_B)), ptr_D(args.ptr_D), batch_stride_A(args.batch_stride_A), batch_stride_B(args.batch_stride_B), batch_stride_D(args.batch_stride_D), semaphore(static_cast(workspace)) { } CUTLASS_HOST_DEVICE void update( Arguments const &args, void *workspace = nullptr) { ptr_A = const_cast(args.ptr_A); ptr_B = const_cast(args.ptr_B); ptr_D = args.ptr_D; batch_stride_A = args.batch_stride_A; batch_stride_B = args.batch_stride_B; batch_stride_D = args.batch_stride_D; output_op = args.epilogue; semaphore = static_cast(workspace); } }; /// Shared memory storage structure union SharedStorage { typename Mma::SharedStorage main_loop; typename Epilogue::SharedStorage epilogue; }; public: // // Methods // CUTLASS_DEVICE TrmmUniversal() { } /// Determines whether kernel satisfies alignment static Status can_implement( cutlass::gemm::GemmCoord const & problem_size) { static int const kAlignmentA = Mma::IteratorA::AccessType::kElements; static int const kAlignmentB = Mma::IteratorB::AccessType::kElements; static int const kAlignmentC = Epilogue::OutputTileIterator::kElementsPerAccess; if ((problem_size.m() % kAlignmentA) || (problem_size.k() % kAlignmentA) || (problem_size.n() % kAlignmentB) || (problem_size.k() % kAlignmentB) || (problem_size.m() % kAlignmentC) || (problem_size.n() % kAlignmentC)) { return Status::kErrorMisalignedOperand; } return Status::kSuccess; } static Status can_implement(Arguments const &args) { return can_implement(args.problem_size); } /// Executes one GEMM CUTLASS_DEVICE void operator()(Params const ¶ms, SharedStorage &shared_storage) { // Compute threadblock location ThreadblockSwizzle threadblock_swizzle; cutlass::gemm::GemmCoord threadblock_tile_offset = threadblock_swizzle.get_tile_offset(params.swizzle_log_tile); // Early exit if CTA is out of range if (params.grid_tiled_shape.m() <= threadblock_tile_offset.m() || params.grid_tiled_shape.n() <= threadblock_tile_offset.n()) { return; } int offset_k = 0; int problem_size_k = params.problem_size.k(); ElementA *ptr_A = static_cast(params.ptr_A); ElementB *ptr_B = static_cast(params.ptr_B); // // Fetch pointers based on mode. // if (params.mode == GemmUniversalMode::kGemm || params.mode == GemmUniversalMode::kGemmSplitKParallel) { if (threadblock_tile_offset.k() + 1 < params.grid_tiled_shape.k()) { problem_size_k = (threadblock_tile_offset.k() + 1) * params.gemm_k_size; } offset_k = threadblock_tile_offset.k() * params.gemm_k_size; } else if (params.mode == GemmUniversalMode::kBatched) { ptr_A += threadblock_tile_offset.k() * params.batch_stride_A; ptr_B += threadblock_tile_offset.k() * params.batch_stride_B; } else if (params.mode == GemmUniversalMode::kArray) { ptr_A = static_cast(params.ptr_A)[threadblock_tile_offset.k()]; ptr_B = static_cast(params.ptr_B)[threadblock_tile_offset.k()]; } __syncthreads(); // Compute initial location in logical coordinates cutlass::MatrixCoord tb_offset_A{ threadblock_tile_offset.m() * Mma::Shape::kM, offset_k, }; cutlass::MatrixCoord tb_offset_B{ offset_k, threadblock_tile_offset.n() * Mma::Shape::kN }; // Compute position within threadblock int thread_idx = threadIdx.x; // Broadcast the warp_id computed by lane 0 to ensure dependent code // is compiled as warp-uniform. int warp_idx = canonical_warp_idx_sync(); int lane_idx = threadIdx.x % 32; // // Main loop // // Construct thread-scoped matrix multiply Mma mma(shared_storage.main_loop, thread_idx, warp_idx, lane_idx); typename Mma::FragmentC accumulators; accumulators.clear(); // Compute threadblock-scoped matrix multiply-add int gemm_k_iterations = (problem_size_k - offset_k + Mma::Shape::kK - 1) / Mma::Shape::kK; /****************************************************************************************************** First two cases: (Left Side, Lower Fill) and (Right Side, Upper Fill) are transpose of each other - (Left Side, Lower Fill): calculate bottom of the CTA tile, then find the k-iterations needed to process all elements till that coordinate. - (Right Side, Upper Fill): calculate right end of the CTA tile, then find the k-iterations needed to process all elements till that coordinate. Last two cases: (Left Side, Upper Fill) and (Right Side, Lower Fill) are transpose of each other - (Left Side, Upper Fill): calculate the top of the CTA tile, then find k-iterations that can be skipped for all elements of this tile. - (Right Side, Lower Fill): calculate the left start of the CTA tile, then find k-iterations that can be skipped for all elements of this tile. ********************************************************************************************************/ if (kSideMode == SideMode::kLeft && kFillMode == FillMode::kLower) { int k_iterations_till_diagonal = ((threadblock_tile_offset.m() + 1) * Mma::Shape::kM + Mma::Shape::kK - 1) / Mma::Shape::kK; if (k_iterations_till_diagonal < gemm_k_iterations) { gemm_k_iterations = k_iterations_till_diagonal; } } else if (kSideMode == SideMode::kRight && kFillMode == FillMode::kUpper) { int k_iterations_till_diagonal = ((threadblock_tile_offset.n() + 1) * Mma::Shape::kN + Mma::Shape::kK - 1) / Mma::Shape::kK; if (k_iterations_till_diagonal < gemm_k_iterations) { gemm_k_iterations = k_iterations_till_diagonal; } } else if (kSideMode == SideMode::kLeft && kFillMode == FillMode::kUpper) { int k_iterations_till_diagonal = ((threadblock_tile_offset.m()) * Mma::Shape::kM) / Mma::Shape::kK; if (k_iterations_till_diagonal != 0) { tb_offset_A += cutlass::MatrixCoord({0, k_iterations_till_diagonal * Mma::Shape::kK}); tb_offset_B += cutlass::MatrixCoord({k_iterations_till_diagonal * Mma::Shape::kK, 0}); gemm_k_iterations -= k_iterations_till_diagonal; } } else if (kSideMode == SideMode::kRight && kFillMode == FillMode::kLower) { int k_iterations_till_diagonal = ((threadblock_tile_offset.n()) * Mma::Shape::kN) / Mma::Shape::kK; if (k_iterations_till_diagonal != 0) { tb_offset_A += cutlass::MatrixCoord({0, k_iterations_till_diagonal * Mma::Shape::kK}); tb_offset_B += cutlass::MatrixCoord({k_iterations_till_diagonal * Mma::Shape::kK, 0}); gemm_k_iterations -= k_iterations_till_diagonal; } } // Construct iterators to A and B operands typename Mma::IteratorA iterator_A( params.params_A, ptr_A, {params.problem_size.m(), problem_size_k}, thread_idx, tb_offset_A); typename Mma::IteratorB iterator_B( params.params_B, ptr_B, {problem_size_k, params.problem_size.n()}, thread_idx, tb_offset_B); // Compute threadblock-scoped matrix multiply-add mma( gemm_k_iterations, accumulators, iterator_A, iterator_B, accumulators); // // Epilogue // EpilogueOutputOp output_op(params.output_op); // // Masked tile iterators constructed from members // threadblock_tile_offset = threadblock_swizzle.get_tile_offset(params.swizzle_log_tile); //assume identity swizzle MatrixCoord threadblock_offset( threadblock_tile_offset.m() * Mma::Shape::kM, threadblock_tile_offset.n() * Mma::Shape::kN ); int block_idx = threadblock_tile_offset.m() + threadblock_tile_offset.n() * params.grid_tiled_shape.m(); ElementC *ptr_D = static_cast(params.ptr_D); // // Fetch pointers based on mode. // // Construct the semaphore. Semaphore semaphore(params.semaphore + block_idx, thread_idx); if (params.mode == GemmUniversalMode::kGemm) { // If performing a reduction via split-K, fetch the initial synchronization if (params.grid_tiled_shape.k() > 1) { // Fetch the synchronization lock initially but do not block. semaphore.fetch(); // Indicate which position in a serial reduction the output operator is currently updating output_op.set_k_partition(threadblock_tile_offset.k(), params.grid_tiled_shape.k()); } } else if (params.mode == GemmUniversalMode::kGemmSplitKParallel) { ptr_D += threadblock_tile_offset.k() * params.batch_stride_D; } else if (params.mode == GemmUniversalMode::kBatched) { ptr_D += threadblock_tile_offset.k() * params.batch_stride_D; } else if (params.mode == GemmUniversalMode::kArray) { ptr_D = static_cast(params.ptr_D)[threadblock_tile_offset.k()]; } // Tile iterator loading from source tensor (although irrelevant to this kernel as beta is zero). typename Epilogue::OutputTileIterator iterator_C( params.params_D, ptr_D, params.problem_size.mn(), thread_idx, threadblock_offset ); // Tile iterator writing to destination tensor. typename Epilogue::OutputTileIterator iterator_D( params.params_D, ptr_D, params.problem_size.mn(), thread_idx, threadblock_offset ); Epilogue epilogue( shared_storage.epilogue, thread_idx, warp_idx, lane_idx); // Wait on the semaphore - this latency may have been covered by iterator construction if (params.mode == GemmUniversalMode::kGemm && params.grid_tiled_shape.k() > 1) { // For subsequent threadblocks, the source matrix is held in the 'D' tensor. if (threadblock_tile_offset.k()) { iterator_C = iterator_D; } semaphore.wait(threadblock_tile_offset.k()); __threadfence(); } // Execute the epilogue operator to update the destination tensor. epilogue( output_op, iterator_D, accumulators, iterator_C); // // Release the semaphore // if (params.mode == GemmUniversalMode::kGemm && params.grid_tiled_shape.k() > 1) { int lock = 0; if (params.grid_tiled_shape.k() == threadblock_tile_offset.k() + 1) { // The final threadblock resets the semaphore for subsequent grids. lock = 0; } else { // Otherwise, the semaphore is incremented lock = threadblock_tile_offset.k() + 1; } semaphore.release(lock); } } }; ///////////////////////////////////////////////////////////////////////////////////////////////// } // namespace kernel } // namespace gemm } // namespace cutlass /////////////////////////////////////////////////////////////////////////////////////////////////