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/*! \file
    \brief
   Default kernel-level fused activation's scale+bias+relu and implicit GEMM convolution
   definitions that combine threadblock-scoped matrix multiply-add with the
   appropriate threadblock-scoped epilogue.
*/

#pragma once

#include "cutlass/cutlass.h"
#include "cutlass/conv/kernel/default_conv2d.h"

#include "cutlass/conv/threadblock/conv3d_fprop_activation_tile_access_iterator_analytic.h"
#include "cutlass/conv/threadblock/conv3d_fprop_filter_tile_access_iterator_analytic.h"
#include "cutlass/conv/threadblock/conv3d_fprop_activation_tile_access_iterator_optimized.h"
#include "cutlass/conv/threadblock/conv3d_fprop_filter_tile_access_iterator_optimized.h"
#include "cutlass/conv/threadblock/predicated_scale_bias_vector_access_iterator.h"
#include "cutlass/transform/threadblock/regular_scale_bias_vector_access_iterator.h"
#include "cutlass/gemm/warp/scale_bias_tile_iterator.h"

/////////////////////////////////////////////////////////////////////////////////////////////////

namespace cutlass {
namespace conv {
namespace kernel {

/////////////////////////////////////////////////////////////////////////////////////////////////
/// Defines a kernel for fused batch norm and Conv3dFprop
template <
  typename ElementA,
  typename LayoutA,
  typename ElementB,
  typename LayoutB,
  typename ElementScaleBias,
  typename LayoutScaleBias,
  typename ElementC,
  typename LayoutC,
  typename ElementAccumulator,
  typename OperatorClass,
  typename ArchTag,
  typename ThreadblockShape,
  typename WarpShape,
  typename InstructionShape,
  typename EpilogueOutputOp,
  typename ThreadblockSwizzle,
  int Stages,
  typename MathOperatorTag,
  conv::IteratorAlgorithm IteratorAlgorithm = IteratorAlgorithm::kOptimized,
  conv::StrideSupport StrideSupport = StrideSupport::kUnity
> struct DefaultConv3dFpropFusion;

/////////////////////////////////////////////////////////////////////////////////////////////////
//                         OpClassTensorOp convolutions 
/////////////////////////////////////////////////////////////////////////////////////////////////

/// Defines a kernel for Conv3dFprop specialzation for Analytic IteratorAlgorithm and multistage 
/// pipeline.
template <
  typename ElementA,
  typename LayoutA,
  typename ElementB,
  typename LayoutB,
  typename ElementScaleBias,
  typename LayoutScaleBias,
  typename ElementC,
  typename LayoutC,
  typename ElementAccumulator,
  typename ArchTag,
  typename ThreadblockShape,
  typename WarpShape,
  typename InstructionShape,
  typename EpilogueOutputOp,
  typename ThreadblockSwizzle,
  int Stages,
  typename MathOperatorTag
>
struct DefaultConv3dFpropFusion <
  ElementA,
  LayoutA,
  ElementB,
  LayoutB,
  ElementScaleBias,
  LayoutScaleBias,
  ElementC,
  LayoutC,
  ElementAccumulator,
  arch::OpClassTensorOp,
  ArchTag,
  ThreadblockShape,
  WarpShape,
  InstructionShape,
  EpilogueOutputOp,
  ThreadblockSwizzle,
  Stages,
  MathOperatorTag,
  IteratorAlgorithm::kAnalytic
> {

  // Define the core components from GEMM
  using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
      ThreadblockShape, WarpShape, InstructionShape, ElementA, layout::RowMajor,
      ElementB, layout::ColumnMajor, ElementAccumulator, layout::RowMajor, arch::OpClassTensorOp,
      Stages, MathOperatorTag>;

  // Define iterators over tiles from the A operand
  using ThreadMapA = typename MmaCore::IteratorThreadMapA;
  using IteratorA =
    cutlass::conv::threadblock::Conv3dFpropActivationTileAccessIteratorAnalytic<
      cutlass::MatrixShape<ThreadblockShape::kM, ThreadblockShape::kK>,
      ElementA,
      ThreadMapA
    >;

  using SmemIteratorA = typename MmaCore::SmemIteratorA;

  // Define iterators over tiles from the B operand
  using ThreadMapB = typename MmaCore::IteratorThreadMapB;
  using IteratorB =
    cutlass::conv::threadblock::Conv3dFpropFilterTileAccessIteratorAnalytic<
      cutlass::MatrixShape<ThreadblockShape::kK, ThreadblockShape::kN>,
      ElementB,
      ThreadMapB
    >;
  
  using SmemIteratorB = typename MmaCore::SmemIteratorB;

  /// Define iterators over tiles from scale/bias vectors
  using IteratorScaleBias =
      cutlass::conv::threadblock::PredicatedScaleBiasVectorAccessIterator<
          cutlass::MatrixShape<1, ThreadblockShape::kK>, ElementScaleBias,
          LayoutScaleBias>;

  using SmemIteratorScaleBias =
      cutlass::transform::threadblock::RegularScaleBiasVectorAccessIterator<
          cutlass::MatrixShape<1, ThreadblockShape::kK>, ElementScaleBias,
          LayoutScaleBias>;

  // Warp-level GEMM components
  using WarpMmaTensorOp = typename MmaCore::MmaTensorOp;
  using MmaPolicy = typename MmaCore::MmaPolicy;

  static int const kThreadCount = 32;

  // Warp-level iterators to load scale and bias vectors
  using WarpIteratorScaleBias = cutlass::gemm::warp::ScaleBiasTileIterator<
      MatrixShape<WarpShape::kM, WarpShape::kK>, ElementScaleBias,
      LayoutScaleBias, MatrixShape<InstructionShape::kM, InstructionShape::kK>,
      typename WarpMmaTensorOp::IteratorA::Base::Policy, kThreadCount,
      MmaCore::WarpCount::kK>;

  // Define the Mma
  using Mma = threadblock::ImplicitGemmFpropFusionMultistage<
    ThreadblockShape,
    IteratorA,
    SmemIteratorA,
    arch::CacheOperation::Always,
    IteratorB,
    SmemIteratorB,
    arch::CacheOperation::Global,
    IteratorScaleBias,
    SmemIteratorScaleBias,
    arch::CacheOperation::Always,
    MmaPolicy,
    WarpIteratorScaleBias,
    Stages 
  >;

  // Define the epilogue
  using Epilogue = typename epilogue::threadblock::DefaultEpilogueTensorOp<
    ThreadblockShape,
    WarpMmaTensorOp,
    1,
    EpilogueOutputOp,
    EpilogueOutputOp::kCount
  >::Epilogue;

  // Define the kernel
  using Kernel = cutlass::conv::kernel::ImplicitGemmConvolutionFusion<
    Mma,
    Epilogue,
    ThreadblockSwizzle,
    conv::Operator::kFprop,
    Conv3dProblemSize
  >;
};

/////////////////////////////////////////////////////////////////////////////////////////////////

/// Defines a kernel for Conv3dFprop specialzation for Optimized IteratorAlgorithm and 
/// multistage pipeline.
template <
  typename ElementA,
  typename LayoutA,
  typename ElementB,
  typename LayoutB,
  typename ElementScaleBias,
  typename LayoutScaleBias,
  typename ElementC,
  typename LayoutC,
  typename ElementAccumulator,
  typename ArchTag,
  typename ThreadblockShape,
  typename WarpShape,
  typename InstructionShape,
  typename EpilogueOutputOp,
  typename ThreadblockSwizzle,
  int Stages,
  typename MathOperatorTag
>
struct DefaultConv3dFpropFusion <
  ElementA,
  LayoutA,
  ElementB,
  LayoutB,
  ElementScaleBias,
  LayoutScaleBias,
  ElementC,
  LayoutC,
  ElementAccumulator,
  arch::OpClassTensorOp,
  ArchTag,
  ThreadblockShape,
  WarpShape,
  InstructionShape,
  EpilogueOutputOp,
  ThreadblockSwizzle,
  Stages,
  MathOperatorTag,
  IteratorAlgorithm::kOptimized
> {

  // Define the core components from GEMM
  using MmaCore = typename cutlass::gemm::threadblock::DefaultMmaCore<
    ThreadblockShape, WarpShape, InstructionShape, ElementA, layout::RowMajor,
    ElementB, layout::ColumnMajor, ElementAccumulator, layout::RowMajor, arch::OpClassTensorOp,
    Stages, MathOperatorTag
  >;

  // Define iterators over tiles from the A operand
  using ThreadMapA = typename MmaCore::IteratorThreadMapA;
  using IteratorA =
    cutlass::conv::threadblock::Conv3dFpropActivationTileAccessIteratorOptimized<
      cutlass::MatrixShape<ThreadblockShape::kM, ThreadblockShape::kK>,
      ElementA,
      LayoutA,
      ThreadMapA
    >;

  using SmemIteratorA = typename MmaCore::SmemIteratorA;

  // Define iterators over tiles from the B operand 
  using ThreadMapB = typename MmaCore::IteratorThreadMapB;
  using IteratorB =
    cutlass::conv::threadblock::Conv3dFpropFilterTileAccessIteratorOptimized<
      cutlass::MatrixShape<ThreadblockShape::kK, ThreadblockShape::kN>,
      ElementB,
      LayoutB,
      ThreadMapB
    >;
  
  using SmemIteratorB = typename MmaCore::SmemIteratorB;

  /// Define iterators over tiles from scale/bias vectors
  using IteratorScaleBias =
      cutlass::conv::threadblock::PredicatedScaleBiasVectorAccessIterator<
          cutlass::MatrixShape<1, ThreadblockShape::kK>, ElementScaleBias,
          LayoutScaleBias>;

  using SmemIteratorScaleBias =
      cutlass::transform::threadblock::RegularScaleBiasVectorAccessIterator<
          cutlass::MatrixShape<1, ThreadblockShape::kK>, ElementScaleBias,
          LayoutScaleBias>;

  // Warp-level GEMM components
  using WarpMmaTensorOp = typename MmaCore::MmaTensorOp;
  using MmaPolicy = typename MmaCore::MmaPolicy;

  static int const kThreadCount = 32;

  // Warp-level iterators to load scale and bias vectors
  using WarpIteratorScaleBias = cutlass::gemm::warp::ScaleBiasTileIterator<
      MatrixShape<WarpShape::kM, WarpShape::kK>, ElementScaleBias,
      LayoutScaleBias, MatrixShape<InstructionShape::kM, InstructionShape::kK>,
      typename WarpMmaTensorOp::IteratorA::Base::Policy, kThreadCount,
      MmaCore::WarpCount::kK>;

  // Define the Mma
  using Mma = threadblock::ImplicitGemmFpropFusionMultistage<
    ThreadblockShape,
    IteratorA,
    SmemIteratorA,
    arch::CacheOperation::Always,
    IteratorB,
    SmemIteratorB,
    arch::CacheOperation::Global,
    IteratorScaleBias,
    SmemIteratorScaleBias,
    arch::CacheOperation::Always,
    MmaPolicy,
    WarpIteratorScaleBias,
    Stages 
  >;

  // Define the epilogue
  using Epilogue = typename epilogue::threadblock::DefaultEpilogueTensorOp<
    ThreadblockShape,
    WarpMmaTensorOp,
    1,
    EpilogueOutputOp,
    EpilogueOutputOp::kCount
  >::Epilogue;

  // Define the kernel
  using Kernel = cutlass::conv::kernel::ImplicitGemmConvolutionFusion<
    Mma,
    Epilogue,
    ThreadblockSwizzle,
    conv::Operator::kFprop,
    Conv3dProblemSize
  >;
};

/////////////////////////////////////////////////////////////////////////////////////////////////

} // namespace kernel
} // namespace conv
} // namespace cutlass

/////////////////////////////////////////////////////////////////////////////////////////////////