conv_transpose_cudnn_op.cu 50.0 KB
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/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserved.

Licensed under the Apache License, Version 2.0 (the "License");
you may not use this file except in compliance with the License.
You may obtain a copy of the License at

    http://www.apache.org/licenses/LICENSE-2.0

Unless required by applicable law or agreed to in writing, software
distributed under the License is distributed on an "AS IS" BASIS,
WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
See the License for the specific language governing permissions and
limitations under the License. */

#include "paddle/fluid/framework/eigen.h"
#include "paddle/fluid/framework/op_registry.h"
#include "paddle/fluid/memory/memory.h"
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#ifdef PADDLE_WITH_HIP
#include "paddle/fluid/operators/conv_miopen_helper.h"
#else
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#include "paddle/fluid/operators/conv_cudnn_helper.h"
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#endif
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#include "paddle/fluid/operators/conv_transpose_op.h"
#include "paddle/fluid/operators/math/math_function.h"
#include "paddle/fluid/operators/math/padding.h"

namespace paddle {
namespace operators {

using Tensor = framework::Tensor;

template <typename T, int D>
static void DataTranspose(const framework::ExecutionContext& ctx,
                          const Tensor* input, Tensor* output,
                          const std::vector<int>& axis, int flag = 0) {
  auto& dev_ctx = ctx.template device_context<platform::CUDADeviceContext>();
  math::Transpose<platform::CUDADeviceContext, T, D> transpose;
  auto in_dims = input->dims();
  std::vector<int64_t> input_transpose_vec;
  for (size_t i = 0; i < axis.size(); ++i) {
    if (flag == 0)
      input_transpose_vec.push_back(in_dims[axis[i]]);
    else
      input_transpose_vec.push_back(in_dims[i]);
  }
  framework::DDim input_transpose_dims(
      framework::make_ddim(input_transpose_vec));
  output->mutable_data<T>(input_transpose_dims, ctx.GetPlace());
  transpose(dev_ctx, *input, output, axis);
}

template <typename T>
class CUDNNConvTransposeOpKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
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    PADDLE_ENFORCE_EQ(
        platform::is_gpu_place(ctx.GetPlace()), true,
        paddle::platform::errors::PreconditionNotMet("It must use CUDAPlace."));
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    auto* input = ctx.Input<Tensor>("Input");
    auto* filter = ctx.Input<Tensor>("Filter");
    auto* output = ctx.Output<Tensor>("Output");

    std::vector<int> strides = ctx.Attr<std::vector<int>>("strides");
    std::vector<int> paddings = ctx.Attr<std::vector<int>>("paddings");
    std::string padding_algorithm = ctx.Attr<std::string>("padding_algorithm");

    // cudnn v5 does not support dilations
    std::vector<int> dilations = ctx.Attr<std::vector<int>>("dilations");
    int groups = ctx.Attr<int>("groups");
    const T* filter_data = filter->data<T>();
    const std::string data_layout_str = ctx.Attr<std::string>("data_format");
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    const paddle::platform::DataLayout data_layout =
        (data_layout_str != "NHWC" ? platform::DataLayout::kNCHW
                                   : platform::DataLayout::kNHWC);
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    // if channel_last, transpose to channel_first
    Tensor input_transpose;
    std::vector<int> input_vec = framework::vectorize<int>(input->dims());
    std::vector<int> output_vec = framework::vectorize<int>(output->dims());
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    if (data_layout == platform::DataLayout::kNHWC) {
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      if (strides.size() == 2U) {
        std::vector<int> axis = {0, 3, 1, 2};
        for (size_t i = 0; i < axis.size(); ++i) {
          input_vec[i] = input->dims()[axis[i]];
          output_vec[i] = output->dims()[axis[i]];
        }
        DataTranspose<T, 4>(ctx, input, &input_transpose, axis);
      } else if (strides.size() == 3U) {
        std::vector<int> axis = {0, 4, 1, 2, 3};
        for (size_t i = 0; i < axis.size(); ++i) {
          input_vec[i] = input->dims()[axis[i]];
          output_vec[i] = output->dims()[axis[i]];
        }
        DataTranspose<T, 5>(ctx, input, &input_transpose, axis);
      }
    } else {
      input_transpose = *input;
    }

    // update padding and dilation
    auto in_dims = input_transpose.dims();
    auto filter_dims = filter->dims();
    framework::DDim in_data_dims;
    in_data_dims = framework::slice_ddim(in_dims, 2, in_dims.size());
    framework::DDim filter_data_dims =
        framework::slice_ddim(filter_dims, 2, filter_dims.size());
    std::vector<int> ksize = framework::vectorize<int>(filter_data_dims);
    UpdatePaddingAndDilation(&paddings, &dilations, padding_algorithm,
                             in_data_dims, strides, ksize);

    int data_dim = strides.size();  // 2d or 3d
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    bool is_sys_pad = math::IsSymmetricPadding(paddings, data_dim);
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    std::vector<int> input_pad(input_transpose.dims().size() * 2, 0);
    Tensor transformed_input;
    std::vector<int> padding_common(data_dim, 0);
    if (!is_sys_pad) {
      std::vector<int> padding_diff(data_dim);
      std::vector<int> new_input_shape_vec(data_dim + 2);
      new_input_shape_vec[0] = input_transpose.dims()[0];
      new_input_shape_vec[1] = input_transpose.dims()[1];

      for (size_t i = 0; i < data_dim; ++i) {
        padding_diff[i] = std::abs(paddings[2 * i] - paddings[2 * i + 1]);
        padding_common[i] = std::min(paddings[2 * i], paddings[2 * i + 1]);
        new_input_shape_vec[i + 2] =
            input_transpose.dims()[i + 2] + padding_diff[i];
        input_pad[2 * i + 4] = paddings[2 * i] - padding_common[i];
        input_pad[2 * i + 4 + 1] = paddings[2 * i + 1] - padding_common[i];
      }
      framework::DDim new_input_shape(
          framework::make_ddim(new_input_shape_vec));
      transformed_input.Resize(new_input_shape);
      auto& dev_ctx =
          ctx.template device_context<paddle::platform::CUDADeviceContext>();

      transformed_input =
          ctx.AllocateTmpTensor<T, paddle::platform::CUDADeviceContext>(
              new_input_shape, dev_ctx);
      const int rank = input_transpose.dims().size();
      T pad_value(0.0);
      switch (rank) {
        case 4: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 4>(
              ctx, input_pad, input_transpose, pad_value, &transformed_input);
        } break;
        case 5: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 5>(
              ctx, input_pad, input_transpose, pad_value, &transformed_input);
        } break;
        default:
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          PADDLE_THROW(platform::errors::InvalidArgument(
              "Op(ConvTranspose) only supports 4-D or 5-D input Tensor."));
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      }
    } else {
      transformed_input = input_transpose;
      if (paddings.size() == data_dim) {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[i];
        }
      } else {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[2 * i];
        }
      }
    }

    std::vector<int64_t> starts(data_dim, 0);
    std::vector<int64_t> ends(data_dim, 0);
    std::vector<int64_t> axes(data_dim, 0);
    for (size_t i = 0; i < data_dim; ++i) {
      starts[i] = input_pad[2 * i + 4] * (strides[i] + 1);
      ends[i] = starts[i] + output_vec[i + 2];
      axes[i] = i + 2;
    }

    const T* input_data = transformed_input.data<T>();
    input_vec = framework::vectorize<int>(transformed_input.dims());

    std::vector<int> transformed_output_vec = output_vec;
    for (size_t i = 0; i < data_dim; ++i) {
      transformed_output_vec[i + 2] =
          output_vec[i + 2] +
          (input_pad[2 * i + 4] + input_pad[2 * i + 5]) * strides[i] -
          2 * padding_common[i] + paddings[2 * i] + paddings[2 * i + 1];
    }

    Tensor transformed_output;
    if (!is_sys_pad) {
      DDim transformed_output_shape(
          framework::make_ddim(transformed_output_vec));
      transformed_output.mutable_data<T>(transformed_output_shape,
                                         ctx.GetPlace());
    } else {
      output->mutable_data<T>(ctx.GetPlace());
      transformed_output.ShareDataWith(*output);
      transformed_output.Resize(framework::make_ddim(transformed_output_vec));
    }
    T* transformed_output_data = transformed_output.data<T>();

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    platform::DataLayout layout;
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    int iwo_groups = groups;
    int c_groups = 1;
#if CUDNN_VERSION_MIN(7, 0, 1)
    iwo_groups = 1;
    c_groups = groups;
    groups = 1;
#endif

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    if (strides.size() == 2U) {
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      layout = platform::DataLayout::kNCHW;
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    } else {
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      layout = platform::DataLayout::kNCDHW;
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    }

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    size_t workspace_size = 0;
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#ifdef PADDLE_WITH_HIP
    miopenConvBwdDataAlgorithm_t algo{};
#else
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    cudnnConvolutionBwdDataAlgo_t algo{};
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#endif
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    // ------------------- cudnn conv algorithm ---------------------
    auto& dev_ctx = ctx.template device_context<platform::CUDADeviceContext>();
    auto handle = dev_ctx.cudnn_handle();
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    auto layout_tensor = GetCudnnTensorFormat(layout);
    bool deterministic = FLAGS_cudnn_deterministic;
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    auto dtype = platform::CudnnDataType<T>::type;
    // ------------------- cudnn descriptors ---------------------
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    ConvArgs args{&transformed_output,
                  filter,
                  &transformed_input,
                  strides,
                  padding_common,
                  dilations,
                  dtype};
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    args.handle = handle;
    args.idesc.set(transformed_output, iwo_groups);
    args.wdesc.set(*filter, layout_tensor, iwo_groups);
    args.odesc.set(transformed_input, iwo_groups);
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    args.cdesc.set(dtype, padding_common, strides, dilations,
                   platform::AllowTF32Cudnn(), c_groups);
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#ifdef PADDLE_WITH_HIP
    using search = SearchAlgorithm<miopenConvBwdDataAlgorithm_t>;
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    workspace_size = std::max(workspace_size, search::GetWorkspaceSize(args));
    algo = search::Find<T>(args, false, deterministic, workspace_size, ctx);
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#else
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    using search = SearchAlgorithm<cudnnConvolutionBwdDataAlgoPerf_t>;
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    algo = search::Find<T>(args, false, deterministic, ctx);
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    workspace_size =
        std::max(workspace_size, search::GetWorkspaceSize(args, algo));
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#endif
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    // ------------------- cudnn conv transpose forward ---------------------
    int input_offset =
        transformed_input.numel() / transformed_input.dims()[0] / groups;
    int output_offset =
        transformed_output.numel() / transformed_output.dims()[0] / groups;
    int filter_offset = filter->numel() / groups;
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    ScalingParamType<T> alpha = 1.0f;
    ScalingParamType<T> beta = 0.0f;
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    auto workspace_handle = dev_ctx.cudnn_workspace_handle();
    for (int g = 0; g < groups; g++) {
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#ifdef PADDLE_WITH_HIP
      auto cudnn_func = [&](void* cudnn_workspace) {
        PADDLE_ENFORCE_CUDA_SUCCESS(
            platform::dynload::miopenConvolutionBackwardData(
                handle, &alpha, args.odesc.desc(),
                input_data + input_offset * g, args.wdesc.desc(),
                filter_data + filter_offset * g, args.cdesc.desc(), algo, &beta,
                args.idesc.desc(), transformed_output_data + output_offset * g,
                cudnn_workspace, workspace_size));
      };
#else   // PADDLE_WITH_HIP
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      auto cudnn_func = [&](void* cudnn_workspace) {
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        PADDLE_ENFORCE_CUDA_SUCCESS(
            platform::dynload::cudnnConvolutionBackwardData(
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                handle, &alpha, args.wdesc.desc(),
                filter_data + filter_offset * g, args.odesc.desc(),
                input_data + input_offset * g, args.cdesc.desc(), algo,
                cudnn_workspace, workspace_size, &beta, args.idesc.desc(),
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                transformed_output_data + output_offset * g));
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      };
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#endif  // PADDLE_WITH_HIP
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      workspace_handle.RunFunc(cudnn_func, workspace_size);
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    }
    if (!is_sys_pad && strides.size() == 2U) {
      Slice<paddle::platform::CUDADeviceContext, T, 4>(
          ctx, &transformed_output, output, starts, ends, axes);
    } else if (!is_sys_pad && strides.size() == 3U) {
      Slice<paddle::platform::CUDADeviceContext, T, 5>(
          ctx, &transformed_output, output, starts, ends, axes);
    }

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    if (data_layout == platform::DataLayout::kNHWC) {
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      Tensor output_transpose;
      Tensor output_nchw;
      output_nchw.ShareDataWith(*output);
      output_nchw.Resize(framework::make_ddim(output_vec));
      if (strides.size() == 2U) {
        std::vector<int> axis = {0, 2, 3, 1};
        DataTranspose<T, 4>(ctx, &output_nchw, &output_transpose, axis);
        *output = output_transpose;
      } else if (strides.size() == 3U) {
        std::vector<int> axis = {0, 2, 3, 4, 1};
        DataTranspose<T, 5>(ctx, &output_nchw, &output_transpose, axis);
        *output = output_transpose;
      }
    }
  }
};

template <typename T>
class CUDNNConvTransposeGradOpKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
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    PADDLE_ENFORCE_EQ(
        platform::is_gpu_place(ctx.GetPlace()), true,
        paddle::platform::errors::PreconditionNotMet("It must use CUDAPlace."));
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    auto input = ctx.Input<Tensor>("Input");
    auto filter = ctx.Input<Tensor>("Filter");
    auto output_grad = ctx.Input<Tensor>(framework::GradVarName("Output"));
    auto input_grad = ctx.Output<Tensor>(framework::GradVarName("Input"));
    auto filter_grad = ctx.Output<Tensor>(framework::GradVarName("Filter"));
    const T* filter_data = filter->data<T>();

    std::vector<int> strides = ctx.Attr<std::vector<int>>("strides");
    std::vector<int> paddings = ctx.Attr<std::vector<int>>("paddings");
    // cudnn v5 does not support dilations
    std::vector<int> dilations = ctx.Attr<std::vector<int>>("dilations");
    int groups = ctx.Attr<int>("groups");
    std::string padding_algorithm = ctx.Attr<std::string>("padding_algorithm");
    int user_workspace_size = ctx.Attr<int>("workspace_size_MB");
    const std::string data_layout_str = ctx.Attr<std::string>("data_format");
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    const paddle::platform::DataLayout data_layout =
        (data_layout_str != "NHWC" ? platform::DataLayout::kNCHW
                                   : platform::DataLayout::kNHWC);
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    // if channel_last, transpose to channel_first
    Tensor input_transpose;
    Tensor output_grad_transpose;
    std::vector<int> input_vec = framework::vectorize<int>(input->dims());
    std::vector<int> output_vec =
        framework::vectorize<int>(output_grad->dims());
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    if (data_layout == platform::DataLayout::kNHWC) {
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      if (strides.size() == 2U) {
        std::vector<int> axis = {0, 3, 1, 2};
        for (size_t i = 0; i < axis.size(); ++i) {
          input_vec[i] = input->dims()[axis[i]];
          output_vec[i] = output_grad->dims()[axis[i]];
        }
        DataTranspose<T, 4>(ctx, input, &input_transpose, axis);
        DataTranspose<T, 4>(ctx, output_grad, &output_grad_transpose, axis);
      } else if (strides.size() == 3U) {
        std::vector<int> axis = {0, 4, 1, 2, 3};
        for (size_t i = 0; i < axis.size(); ++i) {
          input_vec[i] = input->dims()[axis[i]];
          output_vec[i] = output_grad->dims()[axis[i]];
        }
        DataTranspose<T, 5>(ctx, input, &input_transpose, axis);
        DataTranspose<T, 5>(ctx, output_grad, &output_grad_transpose, axis);
      }
    } else {
      input_transpose = *input;
      output_grad_transpose = *output_grad;
    }

    // update padding and dilation
    auto in_dims = input_transpose.dims();
    auto filter_dims = filter->dims();
    framework::DDim in_data_dims;
    in_data_dims = framework::slice_ddim(in_dims, 2, in_dims.size());
    framework::DDim filter_data_dims =
        framework::slice_ddim(filter_dims, 2, filter_dims.size());
    std::vector<int> ksize = framework::vectorize<int>(filter_data_dims);
    UpdatePaddingAndDilation(&paddings, &dilations, padding_algorithm,
                             in_data_dims, strides, ksize);

    int data_dim = strides.size();  // 2d or 3d
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    bool is_sys_pad = math::IsSymmetricPadding(paddings, data_dim);
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    std::vector<int> input_pad(input_transpose.dims().size() * 2, 0);
    Tensor transformed_output_grad;
    std::vector<int> padding_common(data_dim, 0);
    if (!is_sys_pad) {
      std::vector<int> padding_diff(data_dim);
      std::vector<int> new_output_grad_shape_vec(data_dim + 2);
      new_output_grad_shape_vec[0] = output_grad_transpose.dims()[0];
      new_output_grad_shape_vec[1] = output_grad_transpose.dims()[1];

      for (size_t i = 0; i < data_dim; ++i) {
        padding_diff[i] = std::abs(paddings[2 * i] - paddings[2 * i + 1]);
        padding_common[i] = std::min(paddings[2 * i], paddings[2 * i + 1]);
        new_output_grad_shape_vec[i + 2] =
            output_grad_transpose.dims()[i + 2] + padding_diff[i];
        input_pad[2 * i + 4] = paddings[2 * i] - padding_common[i];
        input_pad[2 * i + 4 + 1] = paddings[2 * i + 1] - padding_common[i];
      }
      framework::DDim new_output_grad_shape(
          framework::make_ddim(new_output_grad_shape_vec));
      transformed_output_grad.Resize(new_output_grad_shape);
      auto& dev_ctx =
          ctx.template device_context<paddle::platform::CUDADeviceContext>();

      transformed_output_grad =
          ctx.AllocateTmpTensor<T, paddle::platform::CUDADeviceContext>(
              new_output_grad_shape, dev_ctx);
      const int rank = input_transpose.dims().size();
      T pad_value(0.0);
      switch (rank) {
        case 4: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 4>(
              ctx, input_pad, output_grad_transpose, pad_value,
              &transformed_output_grad);
        } break;
        case 5: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 5>(
              ctx, input_pad, output_grad_transpose, pad_value,
              &transformed_output_grad);
        } break;
        default:
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          PADDLE_THROW(platform::errors::InvalidArgument(
              "Op(ConvTranspose) only supports 4-D or 5-D input Tensor."));
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      }
    } else {
      transformed_output_grad = output_grad_transpose;
      if (paddings.size() == data_dim) {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[i];
        }
      } else {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[2 * i];
        }
      }
    }

    const T* input_data = input_transpose.data<T>();
    const T* output_grad_data = transformed_output_grad.data<T>();
    output_vec = framework::vectorize<int>(transformed_output_grad.dims());

    // ------------------- cudnn descriptors ---------------------
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    platform::DataLayout layout;
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    if (strides.size() == 2U) {
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      layout = platform::DataLayout::kNCHW;
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    } else {
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      layout = platform::DataLayout::kNCDHW;
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    }

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    int iwo_groups = groups;
    int c_groups = 1;
#if CUDNN_VERSION_MIN(7, 0, 1)
    iwo_groups = 1;
    c_groups = groups;
    groups = 1;
#endif
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    auto dtype = platform::CudnnDataType<T>::type;

    ConvArgs args1{&transformed_output_grad,
                   filter,
                   &input_transpose,
                   strides,
                   padding_common,
                   dilations,
                   dtype};
    ConvArgs args2{&transformed_output_grad,
                   filter,
                   &input_transpose,
                   strides,
                   padding_common,
                   dilations,
                   dtype};
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#ifdef PADDLE_WITH_HIP
    miopenConvFwdAlgorithm_t data_algo{};
    miopenConvBwdWeightsAlgorithm_t filter_algo{};
#else
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    cudnnConvolutionFwdAlgo_t data_algo{};
    cudnnConvolutionBwdFilterAlgo_t filter_algo{};
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#endif
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    auto layout_tensor = GetCudnnTensorFormat(layout);
    size_t workspace_size = 0;
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    auto& dev_ctx = ctx.template device_context<platform::CUDADeviceContext>();
    auto handle = dev_ctx.cudnn_handle();
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    bool deterministic = FLAGS_cudnn_deterministic;
    T* input_grad_data = nullptr;
    T* filter_grad_data = nullptr;
    if (input_grad)
      input_grad_data = input_grad->mutable_data<T>(ctx.GetPlace());
    if (filter_grad)
      filter_grad_data = filter_grad->mutable_data<T>(ctx.GetPlace());

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    if (input_grad) {
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      input_grad_data = input_grad->mutable_data<T>(ctx.GetPlace());
      args1.handle = handle;
      args1.idesc.set(transformed_output_grad, iwo_groups);
      args1.wdesc.set(*filter, layout_tensor, iwo_groups);
      args1.odesc.set(input_transpose, iwo_groups);
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      args1.cdesc.set(dtype, padding_common, strides, dilations,
                      platform::AllowTF32Cudnn(), c_groups);
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#ifdef PADDLE_WITH_HIP
      using search1 = SearchAlgorithm<miopenConvFwdAlgorithm_t>;
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      workspace_size =
          std::max(workspace_size, search1::GetWorkspaceSize(args1));
      data_algo =
          search1::Find<T>(args1, false, deterministic, workspace_size, ctx);
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#else
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      using search1 = SearchAlgorithm<cudnnConvolutionFwdAlgoPerf_t>;
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      data_algo = search1::Find<T>(args1, false, deterministic, ctx);
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      workspace_size =
          std::max(workspace_size, search1::GetWorkspaceSize(args1, data_algo));
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#endif
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    }

    if (filter_grad) {
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      filter_grad_data = filter_grad->mutable_data<T>(ctx.GetPlace());
      args2.handle = handle;
      args2.idesc.set(transformed_output_grad, iwo_groups);
      args2.wdesc.set(*filter_grad, layout_tensor, iwo_groups);
      args2.odesc.set(input_transpose, iwo_groups);
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      args2.cdesc.set(dtype, padding_common, strides, dilations,
                      platform::AllowTF32Cudnn(), c_groups);
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#ifdef PADDLE_WITH_HIP
      using search2 = SearchAlgorithm<miopenConvBwdWeightsAlgorithm_t>;
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      workspace_size =
          std::max(workspace_size, search2::GetWorkspaceSize(args2));
      filter_algo =
          search2::Find<T>(args2, false, deterministic, workspace_size, ctx);
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#else
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      using search2 = SearchAlgorithm<cudnnConvolutionBwdFilterAlgoPerf_t>;
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      filter_algo = search2::Find<T>(args2, false, deterministic, ctx);
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      workspace_size = std::max(workspace_size,
                                search2::GetWorkspaceSize(args2, filter_algo));
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#endif
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    }

    // ------------------- cudnn conv backward data ---------------------
    // FIXME(typhoonzero): template type T may not be the same as cudnn call.
    int input_offset = input->numel() / input->dims()[0] / groups;
    int output_grad_offset = transformed_output_grad.numel() /
                             transformed_output_grad.dims()[0] / groups;
    int filter_offset = filter->numel() / groups;
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    ScalingParamType<T> alpha = 1.0f;
    ScalingParamType<T> beta = 0.0f;
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    auto workspace_handle = dev_ctx.cudnn_workspace_handle();
    if (input_grad) {
      // Because beta is zero, it is unnecessary to reset input_grad.
      for (int g = 0; g < groups; g++) {
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#ifdef PADDLE_WITH_HIP
        auto cudnn_func = [&](void* cudnn_workspace) {
          PADDLE_ENFORCE_CUDA_SUCCESS(
              platform::dynload::miopenConvolutionForward(
                  handle, &alpha, args1.idesc.desc(),
                  output_grad_data + output_grad_offset * g, args1.wdesc.desc(),
                  filter_data + filter_offset * g, args1.cdesc.desc(),
                  data_algo, &beta, args1.odesc.desc(),
                  input_grad_data + input_offset * g, cudnn_workspace,
                  workspace_size));
        };
#else   // PADDLE_WITH_HIP
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        auto cudnn_func = [&](void* cudnn_workspace) {
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          PADDLE_ENFORCE_CUDA_SUCCESS(
              platform::dynload::cudnnConvolutionForward(
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                  handle, &alpha, args1.idesc.desc(),
                  output_grad_data + output_grad_offset * g, args1.wdesc.desc(),
                  filter_data + filter_offset * g, args1.cdesc.desc(),
                  data_algo, cudnn_workspace, workspace_size, &beta,
                  args1.odesc.desc(), input_grad_data + input_offset * g));
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        };
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#endif  // PADDLE_WITH_HIP
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        workspace_handle.RunFunc(cudnn_func, workspace_size);
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      }

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      if (data_layout == platform::DataLayout::kNHWC) {
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        Tensor input_grad_transpose;
        Tensor input_grad_nchw;
        input_grad_nchw.ShareDataWith(*input_grad);
        input_grad_nchw.Resize(framework::make_ddim(input_vec));
        if (strides.size() == 2U) {
          std::vector<int> axis = {0, 2, 3, 1};
          DataTranspose<T, 4>(ctx, &input_grad_nchw, &input_grad_transpose,
                              axis);
          *input_grad = input_grad_transpose;
        } else if (strides.size() == 3U) {
          std::vector<int> axis = {0, 2, 3, 4, 1};
          DataTranspose<T, 5>(ctx, &input_grad_nchw, &input_grad_transpose,
                              axis);
          *input_grad = input_grad_transpose;
        }
      }
    }

    // ------------------- cudnn conv backward filter ---------------------
    if (filter_grad) {
      // Because beta is zero, it is unnecessary to reset filter_grad.
      // Gradient with respect to the filter
      for (int g = 0; g < groups; g++) {
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#ifdef PADDLE_WITH_HIP
        auto cudnn_func = [&](void* cudnn_workspace) {
          PADDLE_ENFORCE_CUDA_SUCCESS(
              platform::dynload::miopenConvolutionBackwardWeights(
                  handle, &alpha, args2.odesc.desc(),
                  input_data + input_offset * g, args2.idesc.desc(),
                  output_grad_data + output_grad_offset * g, args2.cdesc.desc(),
                  filter_algo, &beta, args2.wdesc.desc(),
                  filter_grad_data + filter_offset * g, cudnn_workspace,
                  workspace_size));
        };
#else   // PADDLE_WITH_HIP
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        auto cudnn_func = [&](void* cudnn_workspace) {
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          PADDLE_ENFORCE_CUDA_SUCCESS(
              platform::dynload::cudnnConvolutionBackwardFilter(
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                  handle, &alpha, args2.idesc.desc(),
                  output_grad_data + output_grad_offset * g, args2.odesc.desc(),
                  input_data + input_offset * g, args2.cdesc.desc(),
                  filter_algo, cudnn_workspace, workspace_size, &beta,
                  args2.wdesc.desc(), filter_grad_data + filter_offset * g));
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        };
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#endif  // PADDLE_WITH_HIP
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        workspace_handle.RunFunc(cudnn_func, workspace_size);
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      }
    }
  }
};

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/*
 * Inputs:  I, W, dO, ddI, ddW
 * Outputs: ddO, dW, dI
 * ddo = conv_bp_data(W, ddI) + conv_bp_data(ddW, I)
 * dW = conv_bp_filter(dO, ddI)
 * dI = conv(dO, ddW)
 */
template <typename T>
class CUDNNConvTransposeDoubleGradOpKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
    auto& dev_ctx = ctx.template device_context<platform::CUDADeviceContext>();
    PADDLE_ENFORCE_EQ(
        platform::is_gpu_place(ctx.GetPlace()), true,
        paddle::platform::errors::PreconditionNotMet("It must use CUDAPlace."));
    auto X = ctx.Input<Tensor>("Input");
    auto W = ctx.Input<Tensor>("Filter");
    auto dO = ctx.Input<Tensor>("DOutput");
    auto ddX = ctx.Input<Tensor>("DDInput");
    auto ddW = ctx.Input<Tensor>("DDFilter");

    auto ddO = ctx.Output<Tensor>("DDOutput");
    auto dW = ctx.Output<Tensor>("DFilter");
    auto dX = ctx.Output<Tensor>("DInput");

    if (ddO) {
      ddO->mutable_data<T>(ctx.GetPlace());
      math::SetConstant<platform::CUDADeviceContext, T> set_zero;
      set_zero(dev_ctx, ddO, static_cast<T>(0));
    }
    if (dW) {
      dW->mutable_data<T>(ctx.GetPlace());
    }
    if (dX) {
      dX->mutable_data<T>(ctx.GetPlace());
    }

    const T* dy = dO->data<T>();
    const T* w = W->data<T>();

    const T* ddx = nullptr;
    const T* ddw = nullptr;
    T *dw, *dx, *ddy;
    dw = dx = ddy = nullptr;
    T* transformed_dx = nullptr;
    const std::vector<int>& strides = ctx.Attr<std::vector<int>>("strides");
    std::vector<int> dilations = ctx.Attr<std::vector<int>>("dilations");
    int groups = ctx.Attr<int>("groups");

    bool deterministic = FLAGS_cudnn_deterministic;

    std::vector<int> paddings = ctx.Attr<std::vector<int>>("paddings");

    std::string padding_algorithm = ctx.Attr<std::string>("padding_algorithm");
    const std::string data_format = ctx.Attr<std::string>("data_format");
    const bool channel_last = (data_format == "NHWC" || data_format == "NDHWC");

    // transform Tensors to channel first-----------
    Tensor transformed_X_channel(X->type());
    Tensor transformed_dO_channel(dO->type());
    Tensor transformed_ddX_channel(X->type());

    Tensor transformed_ddO_channel(dO->type());
    Tensor transformed_dX_channel(X->type());

    if (channel_last) {
      ResizeToChannelFirst<platform::CUDADeviceContext, T>(
          ctx, X, &transformed_X_channel);
      TransToChannelFirst<platform::CUDADeviceContext, T>(
          ctx, X, &transformed_X_channel);

      ResizeToChannelFirst<platform::CUDADeviceContext, T>(
          ctx, dO, &transformed_dO_channel);
      TransToChannelFirst<platform::CUDADeviceContext, T>(
          ctx, dO, &transformed_dO_channel);

      if (ddX) {
        ResizeToChannelFirst<platform::CUDADeviceContext, T>(
            ctx, ddX, &transformed_ddX_channel);
        TransToChannelFirst<platform::CUDADeviceContext, T>(
            ctx, ddX, &transformed_ddX_channel);
      }

      if (ddO) {
        ResizeToChannelFirst<platform::CUDADeviceContext, T>(
            ctx, ddO, &transformed_ddO_channel);
      }
      if (dX) {
        ResizeToChannelFirst<platform::CUDADeviceContext, T>(
            ctx, dX, &transformed_dX_channel);
        transformed_dX_channel.mutable_data<T>(ctx.GetPlace());
      }

    } else {
      transformed_X_channel = *X;
      transformed_dO_channel = *dO;
      if (ddX) {
        transformed_ddX_channel = *ddX;
      }
      if (dX) {
        transformed_dX_channel = *dX;
      }
    }
    std::vector<int> output_vec =
        framework::vectorize<int>(transformed_dO_channel.dims());

    auto in_dims = transformed_X_channel.dims();
    auto filter_dims = W->dims();
    framework::DDim in_data_dims =
        framework::slice_ddim(in_dims, 2, in_dims.size());
    framework::DDim filter_data_dims =
        framework::slice_ddim(filter_dims, 2, filter_dims.size());
    std::vector<int> ksize = framework::vectorize<int>(filter_data_dims);
    UpdatePaddingAndDilation(&paddings, &dilations, padding_algorithm,
                             in_data_dims, strides, ksize);

    int data_dim = strides.size();  // 2d or 3d
    bool is_sys_pad = math::IsSymmetricPadding(paddings, data_dim);
    Tensor transformed_X(X->type());
    Tensor transformed_ddX(X->type());

    Tensor transformed_dO(dO->type());

    std::vector<int> padding_common(data_dim, 0);
    std::vector<int> input_pad(X->dims().size() * 2, 0);

    if (!is_sys_pad) {
      // get pad
      std::vector<int> padding_diff(data_dim);
      std::vector<int> new_input_shape_vec(data_dim + 2);
      std::vector<int> new_output_grad_shape_vec(data_dim + 2);

      new_input_shape_vec[0] = transformed_X_channel.dims()[0];
      new_input_shape_vec[1] = transformed_X_channel.dims()[1];

      new_output_grad_shape_vec[0] = transformed_dO_channel.dims()[0];
      new_output_grad_shape_vec[1] = transformed_dO_channel.dims()[1];

      for (size_t i = 0; i < data_dim; ++i) {
        padding_diff[i] = std::abs(paddings[2 * i] - paddings[2 * i + 1]);
        padding_common[i] = std::min(paddings[2 * i], paddings[2 * i + 1]);
        new_input_shape_vec[i + 2] =
            transformed_X_channel.dims()[i + 2] + padding_diff[i];

        new_output_grad_shape_vec[i + 2] =
            transformed_dO_channel.dims()[i + 2] + padding_diff[i];

        input_pad[2 * i + 4] = paddings[2 * i] - padding_common[i];
        input_pad[2 * i + 4 + 1] = paddings[2 * i + 1] - padding_common[i];
      }
      framework::DDim new_input_shape(
          framework::make_ddim(new_input_shape_vec));
      transformed_X.Resize(new_input_shape);
      transformed_ddX.Resize(new_input_shape);

      framework::DDim new_output_grad_shape(
          framework::make_ddim(new_output_grad_shape_vec));
      transformed_dO.Resize(new_output_grad_shape);

      transformed_dO =
          ctx.AllocateTmpTensor<T, paddle::platform::CUDADeviceContext>(
              new_output_grad_shape, dev_ctx);

      transformed_X =
          ctx.AllocateTmpTensor<T, paddle::platform::CUDADeviceContext>(
              new_input_shape, dev_ctx);
      if (ddX) {
        transformed_ddX =
            ctx.AllocateTmpTensor<T, paddle::platform::CUDADeviceContext>(
                new_input_shape, dev_ctx);
      }

      // pad for input
      const int rank = X->dims().size();
      T pad_value(0.0);
      switch (rank) {
        case 4: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 4>(
              ctx, input_pad, transformed_X_channel, pad_value, &transformed_X);
          if (dO) {
            math::PadFunction<paddle::platform::CUDADeviceContext, T, 4>(
                ctx, input_pad, transformed_dO_channel, pad_value,
                &transformed_dO);
          }

          if (ddX) {
            math::PadFunction<paddle::platform::CUDADeviceContext, T, 4>(
                ctx, input_pad, transformed_ddX_channel, pad_value,
                &transformed_ddX);
          }
        } break;
        case 5: {
          math::PadFunction<paddle::platform::CUDADeviceContext, T, 5>(
              ctx, input_pad, transformed_X_channel, pad_value, &transformed_X);
          if (ddX) {
            math::PadFunction<paddle::platform::CUDADeviceContext, T, 5>(
                ctx, input_pad, transformed_ddX_channel, pad_value,
                &transformed_ddX);
          }
        } break;
        default:
          PADDLE_THROW(platform::errors::InvalidArgument(
              "ConvOp only support tensors with 4 or 5 dimensions."));
      }

    } else {
      transformed_X = transformed_X_channel;
      transformed_dO = transformed_dO_channel;
      if (ddX) {
        transformed_ddX = transformed_ddX_channel;
      }

      if (paddings.size() == data_dim) {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[i];
        }
      } else {
        for (size_t i = 0; i < data_dim; ++i) {
          padding_common[i] = paddings[2 * i];
        }
      }
    }

    std::vector<int64_t> starts(data_dim, 0);
    std::vector<int64_t> ends(data_dim, 0);
    std::vector<int64_t> axes(data_dim, 0);
    for (size_t i = 0; i < data_dim; ++i) {
      starts[i] = input_pad[2 * i + 4] * (strides[i] + 1);
      ends[i] = starts[i] + output_vec[i + 2];
      axes[i] = i + 2;
    }

    std::vector<int> transformed_output_vec = output_vec;
    for (size_t i = 0; i < data_dim; ++i) {
      transformed_output_vec[i + 2] =
          output_vec[i + 2] +
          (input_pad[2 * i + 4] + input_pad[2 * i + 5]) * strides[i] -
          2 * padding_common[i] + paddings[2 * i] + paddings[2 * i + 1];
    }

    if (!is_sys_pad) {
      DDim transformed_output_shape(
          framework::make_ddim(transformed_output_vec));
      transformed_ddO_channel.mutable_data<T>(transformed_output_shape,
                                              ctx.GetPlace());
    } else {
      ddO->mutable_data<T>(ctx.GetPlace());
      transformed_ddO_channel = *ddO;
      transformed_ddO_channel.Resize(
          framework::make_ddim(transformed_output_vec));
    }

    const T* x = transformed_X.data<T>();

    int iwo_group = groups;
    int c_group = 1;
#if CUDNN_VERSION_MIN(7, 0, 1)
    iwo_group = 1;
    c_group = groups;
    groups = 1;
#endif
    auto dtype = platform::CudnnDataType<T>::type;

    auto handle = dev_ctx.cudnn_handle();

    ConvArgs args1{&transformed_ddO_channel,
                   W,
                   &transformed_ddX,
                   strides,
                   padding_common,
                   dilations,
                   dtype};
    ConvArgs args2{&transformed_ddO_channel, ddW,       &transformed_X, strides,
                   padding_common,           dilations, dtype};

    ConvArgs args3{&transformed_dO,
                   dW,
                   &transformed_ddX_channel,
                   strides,
                   padding_common,
                   dilations,
                   dtype};
    ConvArgs args4{
        &transformed_dO, ddW,  &transformed_dX_channel, strides, padding_common,
        dilations,       dtype};
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#ifdef PADDLE_WITH_HIP
    miopenConvBwdDataAlgorithm_t bwd_algo1 =
        static_cast<miopenConvBwdDataAlgorithm_t>(0);
    miopenConvBwdDataAlgorithm_t bwd_algo2 =
        static_cast<miopenConvBwdDataAlgorithm_t>(0);
    miopenConvFwdAlgorithm_t data_algo =
        static_cast<miopenConvFwdAlgorithm_t>(0);
    miopenConvBwdWeightsAlgorithm_t filter_algo =
        static_cast<miopenConvBwdWeightsAlgorithm_t>(0);
#else
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    cudnnConvolutionBwdDataAlgo_t bwd_algo1 =
        static_cast<cudnnConvolutionBwdDataAlgo_t>(0);
    cudnnConvolutionBwdDataAlgo_t bwd_algo2 =
        static_cast<cudnnConvolutionBwdDataAlgo_t>(0);
    cudnnConvolutionFwdAlgo_t data_algo =
        static_cast<cudnnConvolutionFwdAlgo_t>(0);
    cudnnConvolutionBwdFilterAlgo_t filter_algo =
        static_cast<cudnnConvolutionBwdFilterAlgo_t>(0);
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#endif
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    auto layout = GetCudnnTensorFormat(platform::DataLayout::kNCHW);
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    // ddo = conv(ddI, W) + conv(I, ddW)
    size_t workspace_size = 0;

    T* transformed_ddy_channel = nullptr;

    if (ddO) {
      ddy = ddO->data<T>();
      transformed_ddy_channel = transformed_ddO_channel.data<T>();
      if (ddX) {
        args1.handle = handle;
        args1.idesc.set(transformed_ddO_channel, iwo_group);
        args1.wdesc.set(*W, layout, iwo_group);
        args1.odesc.set(transformed_ddX, iwo_group);
        args1.cdesc.set(dtype, padding_common, strides, dilations, c_group);
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#ifdef PADDLE_WITH_HIP
        using search1 = SearchAlgorithm<miopenConvBwdDataAlgorithm_t>;
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        workspace_size = search1::GetWorkspaceSize(args1);
        bwd_algo1 =
            search1::Find<T>(args1, false, deterministic, workspace_size, ctx);
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#else
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        using search1 = SearchAlgorithm<cudnnConvolutionBwdDataAlgoPerf_t>;
        bwd_algo1 = search1::Find<T>(args1, false, deterministic, ctx);
        workspace_size = search1::GetWorkspaceSize(args1, bwd_algo1);
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#endif
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      }

      if (ddW) {
        ddw = ddW->data<T>();
        args2.handle = handle;
        args2.idesc.set(transformed_ddO_channel, iwo_group);
        args2.wdesc.set(*ddW, layout, iwo_group);
        args2.odesc.set(transformed_X, iwo_group);
        args2.cdesc.set(dtype, padding_common, strides, dilations, c_group);
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#ifdef PADDLE_WITH_HIP
        using search2 = SearchAlgorithm<miopenConvBwdDataAlgorithm_t>;
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        workspace_size =
            std::max(workspace_size, search2::GetWorkspaceSize(args2));
        bwd_algo2 =
            search2::Find<T>(args2, false, deterministic, workspace_size, ctx);
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#else
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        using search2 = SearchAlgorithm<cudnnConvolutionBwdDataAlgoPerf_t>;
        bwd_algo2 = search2::Find<T>(args2, false, deterministic, ctx);
        workspace_size = std::max(workspace_size,
                                  search2::GetWorkspaceSize(args2, bwd_algo2));
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#endif
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      }
    }

    if (dW && ddX) {
      dw = dW->data<T>();
      args3.handle = handle;
      args3.idesc.set(transformed_dO, iwo_group);
      args3.wdesc.set(*dW, layout, iwo_group);

      args3.odesc.set(transformed_ddX_channel, iwo_group);

      args3.cdesc.set(dtype, padding_common, strides, dilations, c_group);
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#ifdef PADDLE_WITH_HIP
      using search3 = SearchAlgorithm<miopenConvBwdWeightsAlgorithm_t>;
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      workspace_size =
          std::max(workspace_size, search3::GetWorkspaceSize(args3));
      filter_algo =
          search3::Find<T>(args3, false, deterministic, workspace_size, ctx);
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#else
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      using search3 = SearchAlgorithm<cudnnConvolutionBwdFilterAlgoPerf_t>;
      filter_algo = search3::Find<T>(args3, false, deterministic, ctx);
      workspace_size = std::max(workspace_size,
                                search3::GetWorkspaceSize(args3, filter_algo));
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#endif
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    }

    if (ddW && dX) {
      transformed_dx = transformed_dX_channel.data<T>();

      args4.handle = handle;
      args4.idesc.set(transformed_dO, iwo_group);
      args4.wdesc.set(*ddW, layout, iwo_group);
      args4.odesc.set(transformed_dX_channel, iwo_group);
      args4.cdesc.set(dtype, padding_common, strides, dilations, c_group);
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#ifdef PADDLE_WITH_HIP
      using search4 = SearchAlgorithm<miopenConvFwdAlgorithm_t>;
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      workspace_size =
          std::max(workspace_size, search4::GetWorkspaceSize(args4));
      data_algo =
          search4::Find<T>(args4, false, deterministic, workspace_size, ctx);
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#else
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      using search4 = SearchAlgorithm<cudnnConvolutionFwdAlgoPerf_t>;
      data_algo = search4::Find<T>(args4, false, deterministic, ctx);
      workspace_size =
          std::max(workspace_size, search4::GetWorkspaceSize(args4, data_algo));
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#endif
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    }

    int i_n, i_c, i_d, i_h, i_w;
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    GetNCDHW(transformed_X.dims(), platform::DataLayout::kNCHW, &i_n, &i_c,
             &i_d, &i_h, &i_w);
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    int o_n, o_c, o_d, o_h, o_w;
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    GetNCDHW(transformed_dO.dims(), platform::DataLayout::kNCHW, &o_n, &o_c,
             &o_d, &o_h, &o_w);
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    int group_offset_in =
        transformed_X.numel() / transformed_X.dims()[0] / groups;
    int group_offset_out =
        transformed_dO.numel() / transformed_dO.dims()[0] / groups;
    int group_offset_filter = W->numel() / groups;

    ScalingParamType<T> alpha = 1.0f;
    ScalingParamType<T> beta = 0.0f;

    auto wkspace_handle = dev_ctx.cudnn_workspace_handle();

    if (ddO) {
      if (ddX) {
        ddx = transformed_ddX.data<T>();
        for (int i = 0; i < groups; i++) {
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#ifdef PADDLE_WITH_HIP
          wkspace_handle.RunFunc(
              [&](void* workspace_ptr) {
                PADDLE_ENFORCE_CUDA_SUCCESS(
                    platform::dynload::miopenConvolutionBackwardData(
                        handle, &alpha, args1.odesc.desc(),
                        ddx + i * group_offset_in, args1.wdesc.desc(),
                        w + i * group_offset_filter, args1.cdesc.desc(),
                        bwd_algo1, &beta, args1.idesc.desc(),
                        transformed_ddy_channel + i * group_offset_out,
                        workspace_ptr, workspace_size));
              },
              workspace_size);
#else   // PADDLE_WITH_HIP
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          wkspace_handle.RunFunc(
              [&](void* workspace_ptr) {
                PADDLE_ENFORCE_CUDA_SUCCESS(
                    platform::dynload::cudnnConvolutionBackwardData(
                        handle, &alpha, args1.wdesc.desc(),
                        w + i * group_offset_filter, args1.odesc.desc(),
                        ddx + i * group_offset_in, args1.cdesc.desc(),
                        bwd_algo1, workspace_ptr, workspace_size, &beta,
                        args1.idesc.desc(),
                        transformed_ddy_channel + i * group_offset_out));
              },
              workspace_size);
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#endif  // PADDLE_WITH_HIP
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        }
      }
      if (ddW) {
        for (int i = 0; i < groups; i++) {
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#ifdef PADDLE_WITH_HIP
          wkspace_handle.RunFunc(
              [&](void* workspace_ptr) {
                PADDLE_ENFORCE_CUDA_SUCCESS(
                    platform::dynload::miopenConvolutionBackwardData(
                        handle, &alpha, args2.odesc.desc(),
                        x + i * group_offset_in, args2.wdesc.desc(),
                        ddw + i * group_offset_filter, args2.cdesc.desc(),
                        bwd_algo2, &alpha, args2.idesc.desc(),
                        transformed_ddy_channel + i * group_offset_out,
                        workspace_ptr, workspace_size));
              },
              workspace_size);
#else   // PADDLE_WITH_HIP
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          wkspace_handle.RunFunc(
              [&](void* workspace_ptr) {
                PADDLE_ENFORCE_CUDA_SUCCESS(
                    platform::dynload::cudnnConvolutionBackwardData(
                        handle, &alpha, args2.wdesc.desc(),
                        ddw + i * group_offset_filter, args2.odesc.desc(),
                        x + i * group_offset_in, args2.cdesc.desc(), bwd_algo2,
                        workspace_ptr, workspace_size, &alpha,
                        args2.idesc.desc(),
                        transformed_ddy_channel + i * group_offset_out));
              },
              workspace_size);
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#endif  // PADDLE_WITH_HIP
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        }
      }
      if ((!is_sys_pad) && (!channel_last)) {
        if (strides.size() == 2U) {
          Slice<paddle::platform::CUDADeviceContext, T, 4>(
              ctx, &transformed_ddO_channel, ddO, starts, ends, axes);
        } else if (!is_sys_pad && strides.size() == 3U) {
          Slice<paddle::platform::CUDADeviceContext, T, 5>(
              ctx, &transformed_ddO_channel, ddO, starts, ends, axes);
        }
      } else if ((!is_sys_pad) && (channel_last)) {
        if (strides.size() == 2U) {
          Slice<paddle::platform::CUDADeviceContext, T, 4>(
              ctx, &transformed_ddO_channel, &transformed_ddO_channel, starts,
              ends, axes);
        } else if (!is_sys_pad && strides.size() == 3U) {
          Slice<paddle::platform::CUDADeviceContext, T, 5>(
              ctx, &transformed_ddO_channel, &transformed_ddO_channel, starts,
              ends, axes);
        }

        TransToChannelLast<paddle::platform::CUDADeviceContext, T>(
            ctx, &transformed_ddO_channel, ddO);
      }
    }

    T* transformed_dy_channel = transformed_dO.data<T>();
    if (dW && ddX) {
      ddx = transformed_ddX_channel.data<T>();
      for (int i = 0; i < groups; i++) {
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#ifdef PADDLE_WITH_HIP
        wkspace_handle.RunFunc(
            [&](void* workspace_ptr) {
              PADDLE_ENFORCE_CUDA_SUCCESS(
                  platform::dynload::miopenConvolutionBackwardWeights(
                      handle, &alpha, args3.odesc.desc(),
                      ddx + i * group_offset_in, args3.idesc.desc(),
                      transformed_dy_channel + i * group_offset_out,
                      args3.cdesc.desc(), filter_algo, &beta,
                      args3.wdesc.desc(), dw + i * group_offset_filter,
                      workspace_ptr, workspace_size));
            },
            workspace_size);
#else   // PADDLE_WITH_HIP
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        wkspace_handle.RunFunc(
            [&](void* workspace_ptr) {
              PADDLE_ENFORCE_CUDA_SUCCESS(
                  platform::dynload::cudnnConvolutionBackwardFilter(
                      handle, &alpha, args3.idesc.desc(),
                      transformed_dy_channel + i * group_offset_out,
                      args3.odesc.desc(), ddx + i * group_offset_in,
                      args3.cdesc.desc(), filter_algo, workspace_ptr,
                      workspace_size, &beta, args3.wdesc.desc(),
                      dw + i * group_offset_filter));
            },
            workspace_size);
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#endif  // PADDLE_WITH_HIP
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      }
    }

    if (dX && ddW) {
      ddw = ddW->data<T>();
      for (int i = 0; i < groups; i++) {
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#ifdef PADDLE_WITH_HIP
        wkspace_handle.RunFunc(
            [&](void* workspace_ptr) {
              PADDLE_ENFORCE_CUDA_SUCCESS(
                  platform::dynload::miopenConvolutionForward(
                      handle, &alpha, args4.idesc.desc(),
                      transformed_dy_channel + i * group_offset_out,
                      args4.wdesc.desc(), ddw + i * group_offset_filter,
                      args4.cdesc.desc(), data_algo, &beta, args4.odesc.desc(),
                      transformed_dx + i * group_offset_in, workspace_ptr,
                      workspace_size));
            },
            workspace_size);
#else   // PADDLE_WITH_HIP
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        wkspace_handle.RunFunc(
            [&](void* workspace_ptr) {
              PADDLE_ENFORCE_CUDA_SUCCESS(
                  platform::dynload::cudnnConvolutionForward(
                      handle, &alpha, args4.idesc.desc(),
                      transformed_dy_channel + i * group_offset_out,
                      args4.wdesc.desc(), ddw + i * group_offset_filter,
                      args4.cdesc.desc(), data_algo, workspace_ptr,
                      workspace_size, &beta, args4.odesc.desc(),
                      transformed_dx + i * group_offset_in));
            },
            workspace_size);
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#endif  // PADDLE_WITH_HIP
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      }
      if (channel_last) {
        TransToChannelLast<paddle::platform::CUDADeviceContext, T>(
            ctx, &transformed_dX_channel, dX);
      }
    }
  }
};

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}  // namespace operators
}  // namespace paddle

namespace ops = paddle::operators;
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namespace plat = paddle::platform;
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#ifdef PADDLE_WITH_HIP
// MIOPEN do not support double
REGISTER_OP_KERNEL(conv2d_transpose, CUDNN, ::paddle::platform::CUDAPlace,
                   ops::CUDNNConvTransposeOpKernel<plat::float16>,
                   ops::CUDNNConvTransposeOpKernel<float>);
REGISTER_OP_KERNEL(conv2d_transpose_grad, CUDNN, ::paddle::platform::CUDAPlace,
                   ops::CUDNNConvTransposeGradOpKernel<plat::float16>,
                   ops::CUDNNConvTransposeGradOpKernel<float>);
REGISTER_OP_KERNEL(
    conv2d_transpose_grad_grad, CUDNN, plat::CUDAPlace,
    paddle::operators::CUDNNConvTransposeDoubleGradOpKernel<float>,
    paddle::operators::CUDNNConvTransposeDoubleGradOpKernel<plat::float16>);

REGISTER_OP_KERNEL(conv3d_transpose, CUDNN, ::paddle::platform::CUDAPlace,
                   ops::CUDNNConvTransposeOpKernel<plat::float16>,
                   ops::CUDNNConvTransposeOpKernel<float>);
REGISTER_OP_KERNEL(conv3d_transpose_grad, CUDNN, ::paddle::platform::CUDAPlace,
                   ops::CUDNNConvTransposeGradOpKernel<plat::float16>,
                   ops::CUDNNConvTransposeGradOpKernel<float>);
#else
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REGISTER_OP_KERNEL(conv2d_transpose, CUDNN, ::paddle::platform::CUDAPlace,
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                   ops::CUDNNConvTransposeOpKernel<plat::float16>,
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                   ops::CUDNNConvTransposeOpKernel<float>,
                   ops::CUDNNConvTransposeOpKernel<double>);
REGISTER_OP_KERNEL(conv2d_transpose_grad, CUDNN, ::paddle::platform::CUDAPlace,
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                   ops::CUDNNConvTransposeGradOpKernel<plat::float16>,
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                   ops::CUDNNConvTransposeGradOpKernel<float>,
                   ops::CUDNNConvTransposeGradOpKernel<double>);
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REGISTER_OP_KERNEL(
    conv2d_transpose_grad_grad, CUDNN, plat::CUDAPlace,
    paddle::operators::CUDNNConvTransposeDoubleGradOpKernel<float>,
    paddle::operators::CUDNNConvTransposeDoubleGradOpKernel<double>,
    paddle::operators::CUDNNConvTransposeDoubleGradOpKernel<plat::float16>);
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REGISTER_OP_KERNEL(conv3d_transpose, CUDNN, ::paddle::platform::CUDAPlace,
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                   ops::CUDNNConvTransposeOpKernel<plat::float16>,
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                   ops::CUDNNConvTransposeOpKernel<float>,
                   ops::CUDNNConvTransposeOpKernel<double>);
REGISTER_OP_KERNEL(conv3d_transpose_grad, CUDNN, ::paddle::platform::CUDAPlace,
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                   ops::CUDNNConvTransposeGradOpKernel<plat::float16>,
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                   ops::CUDNNConvTransposeGradOpKernel<float>,
                   ops::CUDNNConvTransposeGradOpKernel<double>);
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#endif