prepared_operator.h

// Copyright (c) 2019 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.

#pragma once
#include <memory>
#include <string>
#include <utility>
#include <vector>

#include "paddle/fluid/eager/eager_tensor.h"
#include "paddle/fluid/framework/data_transform.h"
#include "paddle/fluid/framework/op_kernel_type.h"
#include "paddle/fluid/framework/operator.h"
#include "paddle/fluid/framework/phi_utils.h"
#include "paddle/fluid/framework/type_defs.h"
#include "paddle/fluid/imperative/execution_context.h"
#include "paddle/fluid/imperative/layer.h"
#include "paddle/fluid/imperative/type_defs.h"
#include "paddle/fluid/imperative/var_helper.h"

#include "paddle/fluid/framework/convert_utils.h"
#include "paddle/phi/core/dense_tensor.h"
#include "paddle/phi/core/selected_rows.h"

DECLARE_bool(use_mkldnn);

namespace paddle {
namespace imperative {

const framework::Tensor* GetTensorFromVar(const framework::Variable& var);

template <typename VarType>
static void SetForwardDataTypeOfGradVar(const std::shared_ptr<VarType>& var);

template <>
void SetForwardDataTypeOfGradVar<VariableWrapper>(
    const std::shared_ptr<VariableWrapper>& var) {
  if (var->HasGradVar()) {
    auto grad_var = var->GetGradVar();
    VLOG(6) << "Set grad var (" << grad_var->Name() << ")'s forward dtype to ("
            << framework::DataTypeToString(var->DataType()) << ").";
    grad_var->SetForwardDataType(var->DataType());
  }
}

template <>
void SetForwardDataTypeOfGradVar<VarBase>(const std::shared_ptr<VarBase>& var) {
  if (var->HasGradVar()) {
    auto& shared_var = var->SharedVar();
    SetForwardDataTypeOfGradVar<VariableWrapper>(shared_var);
  }
}

template <>
void SetForwardDataTypeOfGradVar<egr::EagerVariable>(
    const std::shared_ptr<egr::EagerVariable>& var) {
  VLOG(10) << "Var in Eager dose not support SetForwardDataTypeOfGradVar: "
           << var->name();
  // TODO(jiabin): SetForwardDataType of Grad var is not supported yet in
  // EagerMode.
}

template <typename VarType>
std::shared_ptr<NameVarMap<VarType>> PrepareData(
    const framework::OperatorWithKernel& op, const NameVarMap<VarType>& ins,
    const framework::OpKernelType& expected_kernel_key) {
  std::shared_ptr<NameVarMap<VarType>> tmp_ins_ptr = nullptr;
  for (const auto& name_pair : ins) {
    for (size_t i = 0; i < name_pair.second.size(); ++i) {
      auto& template_var = name_pair.second[i];
      SetForwardDataTypeOfGradVar(template_var);
      const auto* tensor = GetTensorFromVar(template_var->Var());
      if (tensor && tensor->IsInitialized()) {
        auto kernel_type_for_var = op.GetKernelTypeForVar(
            name_pair.first, *tensor, expected_kernel_key);
        if (!NeedTransform(kernel_type_for_var, expected_kernel_key)) {
          continue;
        } else {
          VLOG(3) << "Transform Variable " << GetNameFromVar(template_var)
                  << " from " << kernel_type_for_var << " to "
                  << expected_kernel_key;

          if (CheckCachedKey(template_var, expected_kernel_key)) {
            VLOG(3) << "Hit variable_wrapper cache: key="
                    << expected_kernel_key;
            std::shared_ptr<VariableWrapper> cache_var =
                GetCachedValue(template_var, expected_kernel_key);
            if (tmp_ins_ptr == nullptr) {
              tmp_ins_ptr = std::make_shared<NameVarMap<VarType>>(ins);
            }

            const auto* tensor = GetTensorFromVar(cache_var->Var());
            auto tmp_var =
                std::make_shared<VarType>(GetNameFromVar(template_var));
            SetType(tmp_var, GetType(template_var));
            SetTensorToVariable(cache_var->Var(), *tensor,
                                tmp_var->MutableVar());
            (*tmp_ins_ptr)[name_pair.first][i] = tmp_var;
          } else {
            framework::Tensor out;
            TransformData(expected_kernel_key, kernel_type_for_var, *tensor,
                          &out);
            if (NeedTransformDataType(kernel_type_for_var,
                                      expected_kernel_key)) {
              // To avoid NameVarMap copy construction overhead in general
              // scenarios, if inplace transformed, return original input
              // directly
              if (tmp_ins_ptr == nullptr) {
                tmp_ins_ptr = std::make_shared<NameVarMap<VarType>>(ins);
              }
              auto tmp_var =
                  std::make_shared<VarType>(GetNameFromVar(template_var));
              SetType(tmp_var, GetType(template_var));
              SetTensorToVariable(template_var->Var(), out,
                                  tmp_var->MutableVar());
              (*tmp_ins_ptr)[name_pair.first][i] = tmp_var;
              SetCachedValue(template_var, expected_kernel_key, tmp_var);
              VLOG(3) << "Set cache to variable_wrapper: key="
                      << expected_kernel_key;
            } else {
              // if dtype is same, transform inplace will not change the
              // original
              // value, transform inplace to avoid multiple copy
              SetTensorToVariable(template_var->Var(), out,
                                  template_var->MutableVar());
            }
          }
        }
      }
    }
  }
  return tmp_ins_ptr;
}

class PreparedOp {
 public:
  PreparedOp(const framework::OperatorBase& op,
             const framework::RuntimeContext& ctx,
             const framework::OpKernelType& kernel_type,
             const framework::OperatorWithKernel::OpKernelFunc& func,
             platform::DeviceContext* dev_ctx);

  PreparedOp(const framework::OperatorBase& op,
             const framework::RuntimeContext& ctx,
             const framework::OpKernelType& kernel_type,
             const framework::KernelSignature& kernel_signature,
             const phi::Kernel& pt_kernel, platform::DeviceContext* dev_ctx);

  static PreparedOp Prepare(const NameVarMap<VarBase>& ins,
                            const NameVarMap<VarBase>& outs,
                            const framework::OperatorWithKernel& op,
                            const platform::Place& place,
                            const framework::AttributeMap& attrs,
                            const framework::AttributeMap& default_attrs);

  static PreparedOp Prepare(const NameVarMap<VariableWrapper>& ins,
                            const NameVarMap<VariableWrapper>& outs,
                            const framework::OperatorWithKernel& op,
                            const platform::Place& place,
                            const framework::AttributeMap& attrs,
                            const framework::AttributeMap& default_attrs);

  static PreparedOp Prepare(const NameVarMap<egr::EagerVariable>& ins,
                            const NameVarMap<egr::EagerVariable>& outs,
                            const framework::OperatorWithKernel& op,
                            const platform::Place& place,
                            const framework::AttributeMap& attrs,
                            const framework::AttributeMap& default_attrs);

  void Run(const NameVarMap<VarBase>& in, const NameVarMap<VarBase>& out,
           const framework::AttributeMap& attrs,
           const framework::AttributeMap& default_attrs);

  void Run(const NameVarMap<VariableWrapper>& ins,
           const NameVarMap<VariableWrapper>& outs,
           const framework::AttributeMap& attrs,
           const framework::AttributeMap& default_attrs);

  void Run(const NameVarMap<egr::EagerVariable>& ins,
           const NameVarMap<egr::EagerVariable>& outs,
           const framework::AttributeMap& attrs,
           const framework::AttributeMap& default_attrs);

  const framework::OpKernelType& kernel_type() const { return kernel_type_; }

 private:
  const framework::OperatorBase& op_;
  const framework::RuntimeContext& ctx_;
  framework::OpKernelType kernel_type_;
  framework::OperatorWithKernel::OpKernelFunc func_;
  platform::DeviceContext* dev_ctx_;
  // NOTE(chenweihang): Similar op members are used to adapt to
  // new phi kernel, if there is a better design in the future,
  // we may polish the implementation here
  bool run_phi_kernel_{false};
  bool run_kp_kernel_{false};
  framework::KernelSignature pt_kernel_signature_;
  phi::Kernel pt_kernel_;
};

const inline framework::Attribute& GetAttr(
    const framework::AttributeMap& attrs,
    const framework::AttributeMap& default_attrs, const std::string& name) {
  auto it = attrs.find(name);
  bool found = it != attrs.end();
  if (!found) {
    it = default_attrs.find(name);
    found = it != default_attrs.end();
  }
  PADDLE_ENFORCE_EQ(
      found, true,
      platform::errors::NotFound("(%s) is not found in AttributeMap.", name));
  return it->second;
}

template <typename VarType>
void BuildDygraphPhiKernelContext(
    const framework::KernelSignature& pt_kernel_signature,
    const phi::Kernel& pt_kernel, const NameVarMap<VarType>& ins,
    const NameVarMap<VarType>& outs, const framework::AttributeMap& attrs,
    const framework::AttributeMap& default_attrs,
    platform::DeviceContext* dev_ctx, phi::KernelContext* kernel_ctx) {
  kernel_ctx->SetDeviceContext(dev_ctx);

  auto& input_names = std::get<0>(pt_kernel_signature.args);
  auto& attr_names = std::get<1>(pt_kernel_signature.args);
  auto& output_names = std::get<2>(pt_kernel_signature.args);

  auto& input_defs = pt_kernel.args_def().input_defs();
  auto& output_defs = pt_kernel.args_def().output_defs();
  auto& attr_defs = pt_kernel.args_def().attribute_defs();

  PADDLE_ENFORCE_EQ(input_names.size(), input_defs.size(),
                    platform::errors::InvalidArgument(
                        "the size of inputs_args names (%d) must be equal to "
                        "the size of kernel input_defs (%d).",
                        input_names.size(), input_defs.size()));

  PADDLE_ENFORCE_EQ(output_names.size(), output_defs.size(),
                    platform::errors::InvalidArgument(
                        "the size of outputs_args names (%d) must be equal to "
                        "the size of kernel output_defs (%d).",
                        output_names.size(), output_defs.size()));

  PADDLE_ENFORCE_EQ(attr_names.size(), attr_defs.size(),
                    platform::errors::InvalidArgument(
                        "the size of attribute_args names (%d) must be equal "
                        "to the size of kernel attribute_defs (%d).",
                        attr_names.size(), attr_defs.size()));

  for (size_t i = 0; i < input_names.size(); ++i) {
    auto it = ins.find(input_names[i]);

    size_t start_idx = (i == 0 ? 0 : kernel_ctx->InputRangeAt(i - 1).second);

    if (it == ins.end()) {
      if (LIKELY(input_defs[i].type_index ==
                 std::type_index(
                     typeid(paddle::optional<const phi::DenseTensor&>)))) {
        kernel_ctx->EmplaceBackInputWithoutSetRange(nullptr);
        auto end_idx = start_idx + 1;
        kernel_ctx->AssignInputRange(std::make_pair(start_idx, end_idx), i);
        continue;
      } else {
        PADDLE_THROW(phi::errors::NotFound(
            "Can not find input variable '%s' for %s OP, please check whether "
            "the name setting in OpArgumentMapping is consistent with that in "
            "OpMaker.",
            input_names[i], pt_kernel_signature.name));
      }
    }

    auto ins_vector = it->second;
    size_t end_idx = start_idx + ins_vector.size();

    for (size_t offset = 0; offset < ins_vector.size(); ++offset) {
      const phi::TensorBase* tensor_in = nullptr;
      auto& var = ins_vector[offset]->Var();
      if (var.template IsType<phi::DenseTensor>()) {
        tensor_in = &(var.template Get<phi::DenseTensor>());
        kernel_ctx->EmplaceBackInputWithoutSetRange(tensor_in);
      } else if (var.template IsType<phi::SelectedRows>()) {
        tensor_in = &(var.template Get<phi::SelectedRows>());
        kernel_ctx->EmplaceBackInputWithoutSetRange(tensor_in);
      } else if (var.template IsType<framework::LoDTensorArray>()) {
        paddle::SmallVector<const phi::TensorBase*> tensor_vector;
        auto& tensor_array = var.template Get<framework::LoDTensorArray>();
        for (auto& t : tensor_array) {
          tensor_vector.emplace_back(&t);
        }
        kernel_ctx->EmplaceBackInputsWithoutSetRange(tensor_vector);
        end_idx += tensor_array.size() - 1;
      } else {
        PADDLE_THROW(platform::errors::Unimplemented(
            "Unsupported input `%s` type when call pt kernel.",
            framework::ToTypeName(var.Type())));
      }
    }
    kernel_ctx->AssignInputRange(std::make_pair(start_idx, end_idx), i);
  }

  for (size_t i = 0; i < output_names.size(); ++i) {
    size_t start_idx = (i == 0 ? 0 : kernel_ctx->OutputRangeAt(i - 1).second);

    auto iter = outs.find(output_names[i]);
    if (iter == outs.end()) {
      kernel_ctx->EmplaceBackOutputWithoutSetRange({nullptr});
      kernel_ctx->AssignOutputRange(std::make_pair(start_idx, start_idx + 1),
                                    i);
      continue;
    }

    auto& outs_vector = iter->second;
    size_t end_idx = start_idx + outs_vector.size();

    for (size_t offset = 0; offset < outs_vector.size(); ++offset) {
      if (outs_vector[offset] == nullptr) {
        kernel_ctx->EmplaceBackOutputWithoutSetRange({nullptr});
        continue;
      }

      phi::TensorBase* tensor_out = nullptr;
      auto* var = outs_vector[offset]->MutableVar();
      if (var) {
        if (var->template IsType<phi::DenseTensor>()) {
          tensor_out = var->template GetMutable<phi::DenseTensor>();
          kernel_ctx->EmplaceBackOutputWithoutSetRange(tensor_out);
        } else if (var->template IsType<phi::SelectedRows>()) {
          tensor_out = var->template GetMutable<phi::SelectedRows>();
          kernel_ctx->EmplaceBackOutputWithoutSetRange(tensor_out);
        } else if (var->template IsType<framework::LoDTensorArray>()) {
          paddle::SmallVector<phi::TensorBase*> tensor_vector;
          auto* tensor_array =
              var->template GetMutable<framework::LoDTensorArray>();
          for (auto& t : *tensor_array) {
            tensor_vector.emplace_back(&t);
          }
          kernel_ctx->EmplaceBackOutputsWithoutSetRange(tensor_vector);
          end_idx += tensor_array->size() - 1;
        } else {
          PADDLE_THROW(platform::errors::Unimplemented(
              "Unsupported output `%s` type when call pt kernel.",
              framework::ToTypeName(var->Type())));
        }
      } else {
        kernel_ctx->EmplaceBackOutputWithoutSetRange(tensor_out);
      }
    }
    kernel_ctx->AssignOutputRange(std::make_pair(start_idx, end_idx), i);
  }

  for (size_t i = 0; i < attr_names.size(); ++i) {
    if (attr_defs[i].type_index == std::type_index(typeid(phi::ScalarArray))) {
      if (attrs.find(attr_names[i]) !=
          attrs.end()) {  // shape is in the attribute
        auto& attr = GetAttr(attrs, default_attrs, attr_names[i]);
        if (std::type_index(attr.type()) ==
            std::type_index(typeid(std::vector<int64_t>))) {
          kernel_ctx->EmplaceBackAttr(std::move(
              phi::ScalarArray(BOOST_GET_CONST(std::vector<int64_t>, attr))));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(std::vector<int32_t>))) {
          kernel_ctx->EmplaceBackAttr(std::move(
              phi::ScalarArray(BOOST_GET_CONST(std::vector<int32_t>, attr))));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(int64_t))) {
          kernel_ctx->EmplaceBackAttr(
              std::move(phi::ScalarArray(&BOOST_GET_CONST(int64_t, attr), 1)));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(int32_t))) {
          kernel_ctx->EmplaceBackAttr(
              std::move(phi::ScalarArray(&BOOST_GET_CONST(int32_t, attr), 1)));
        } else if (attr_defs[i].type_index ==
                   std::type_index(typeid(std::vector<int32_t>))) {
          const auto& vector_int_attr = BOOST_GET_CONST(std::vector<int>, attr);
          kernel_ctx->EmplaceBackAttr(vector_int_attr);
        } else {
          PADDLE_THROW(platform::errors::Unimplemented(
              "Unsupported cast op attribute `%s` to VectorTensor when "
              "construct KernelContext.",
              attr_names[i]));
        }
      } else {  // shape is in the input
        auto& ins_vector = ins.at(attr_names[i]);
        if (ins_vector.size() == 1) {  // ShapeTensor
          kernel_ctx->EmplaceBackAttr(std::move(
              experimental::MakePhiScalarArrayFromVar(ins_vector[0]->Var())));
        } else {  // ShapeTensorList
          std::vector<framework::Variable*> variables;
          variables.reserve(ins_vector.size());
          for (const auto& var_base : ins_vector) {
            variables.push_back(var_base->MutableVar());
          }
          kernel_ctx->EmplaceBackAttr(std::move(
              experimental::MakePhiScalarArrayFromVarList(variables)));
        }
      }
    } else if (attr_defs[i].type_index ==
               std::type_index(typeid(phi::Scalar))) {
      // TODO(chenweihang): support other attrs later
      // TODO(zhangyunfei): Scalar should hold scaler type, and we should check
      // attribtue type by attr_defs
      if (attrs.find(attr_names[i]) != attrs.end() ||
          default_attrs.find(attr_names[i]) !=
              default_attrs.end()) {  // scalar is in the attribute
        auto& attr = GetAttr(attrs, default_attrs, attr_names[i]);
        if (std::type_index(attr.type()) == std::type_index(typeid(float))) {
          kernel_ctx->EmplaceBackAttr(
              std::move(phi::Scalar(BOOST_GET_CONST(float, attr))));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(std::string))) {
          kernel_ctx->EmplaceBackAttr(
              std::move(phi::Scalar(BOOST_GET_CONST(std::string, attr))));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(int))) {
          kernel_ctx->EmplaceBackAttr(
              std::move(phi::Scalar(BOOST_GET_CONST(int, attr))));
        } else {
          PADDLE_THROW(platform::errors::Unimplemented(
              "Unsupported cast op attribute `%s` to Scalar when construct "
              "KernelContext in dygraph.",
              attr_names[i]));
        }
      } else {  // scalar is in the input
        auto& ins_vector = ins.at(attr_names[i]);
        kernel_ctx->EmplaceBackAttr(std::move(
            experimental::MakePhiScalarFromVar(ins_vector[0]->Var())));
      }

    } else if (ins.find(attr_names[i]) != ins.end()) {
      // deal tensor attr here
      auto& ins_vector = ins.at(attr_names[i]);
      auto tensor_attr =
          experimental::MakePhiScalarFromVar(ins_vector[0]->Var());
      if (attr_defs[i].type_index == std::type_index(typeid(int))) {
        int val = tensor_attr.template to<int>();
        kernel_ctx->EmplaceBackAttr(val);
      } else {
        PADDLE_THROW(platform::errors::Unimplemented("only support int here"));
      }
    } else if (attr_defs[i].type_index ==
               std::type_index(typeid(std::vector<phi::Scalar>))) {
      auto& attr = GetAttr(attrs, default_attrs, attr_names[i]);
      if (std::type_index(attr.type()) ==
          std::type_index(typeid(std::vector<int32_t>))) {
        const auto& vec = BOOST_GET_CONST(std::vector<int32_t>, attr);
        std::vector<phi::Scalar> scalar_list;
        scalar_list.reserve(vec.size());
        for (const auto& val : vec) {
          scalar_list.emplace_back(val);
        }
        kernel_ctx->EmplaceBackAttr(std::move(scalar_list));
      } else if (std::type_index(attr.type()) ==
                 std::type_index(typeid(std::vector<int64_t>))) {
        const auto& vec = BOOST_GET_CONST(std::vector<int64_t>, attr);
        std::vector<phi::Scalar> scalar_list;
        scalar_list.reserve(vec.size());
        for (const auto& val : vec) {
          scalar_list.emplace_back(val);
        }
        kernel_ctx->EmplaceBackAttr(std::move(scalar_list));
      } else if (std::type_index(attr.type()) ==
                 std::type_index(typeid(std::vector<float>))) {
        const auto& vec = BOOST_GET_CONST(std::vector<float>, attr);
        std::vector<phi::Scalar> scalar_list;
        scalar_list.reserve(vec.size());
        for (const auto& val : vec) {
          scalar_list.emplace_back(val);
        }
        kernel_ctx->EmplaceBackAttr(std::move(scalar_list));
      } else if (std::type_index(attr.type()) ==
                 std::type_index(typeid(std::vector<double>))) {
        const auto& vec = BOOST_GET_CONST(std::vector<double>, attr);
        std::vector<phi::Scalar> scalar_list;
        scalar_list.reserve(vec.size());
        for (const auto& val : vec) {
          scalar_list.emplace_back(val);
        }
        kernel_ctx->EmplaceBackAttr(std::move(scalar_list));
      } else if (std::type_index(attr.type()) ==
                 std::type_index(typeid(std::vector<bool>))) {
        const auto& vec = BOOST_GET_CONST(std::vector<bool>, attr);
        std::vector<phi::Scalar> scalar_list;
        scalar_list.reserve(vec.size());
        for (const auto& val : vec) {
          scalar_list.emplace_back(val);
        }
        kernel_ctx->EmplaceBackAttr(std::move(scalar_list));
      } else {
        PADDLE_THROW(platform::errors::Unimplemented(
            "Unsupported cast op attribute `%s` to vector<Scalar> when "
            "construct KernelContext.",
            attr_names[i]));
      }
    } else {
      // TODO(chenweihang): support other attrs later

      auto& attr = GetAttr(attrs, default_attrs, attr_names[i]);
      if (attr_defs[i].type_index == std::type_index(typeid(int))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(int, attr));
      } else if (attr_defs[i].type_index == std::type_index(typeid(float))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(float, attr));
      } else if (attr_defs[i].type_index == std::type_index(typeid(bool))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(bool, attr));
      } else if (attr_defs[i].type_index == std::type_index(typeid(int64_t))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(int64_t, attr));
      } else if (attr_defs[i].type_index ==
                 std::type_index(typeid(std::string))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(std::string, attr));
      } else if (attr_defs[i].type_index ==
                 std::type_index(typeid(phi::DataType))) {
        auto data_type = framework::TransToPhiDataType(
            static_cast<framework::proto::VarType::Type>(
                BOOST_GET_CONST(int, attr)));
        kernel_ctx->EmplaceBackAttr(data_type);
      } else if (attr_defs[i].type_index ==
                 std::type_index(typeid(std::vector<int64_t>))) {
        if (std::type_index(attr.type()) ==
            std::type_index(typeid(std::vector<int64_t>))) {
          kernel_ctx->EmplaceBackAttr(
              BOOST_GET_CONST(std::vector<int64_t>, attr));
        } else if (std::type_index(attr.type()) ==
                   std::type_index(typeid(std::vector<int>))) {
          // Emplace Back Attr according to the type of Phi_Kernel args.
          const auto& vector_int_attr = BOOST_GET_CONST(std::vector<int>, attr);
          const std::vector<int64_t> vector_int64_attr(vector_int_attr.begin(),
                                                       vector_int_attr.end());
          kernel_ctx->EmplaceBackAttr(vector_int64_attr);
        }
      } else if (attr_defs[i].type_index ==
                 std::type_index(typeid(std::vector<int>))) {
        kernel_ctx->EmplaceBackAttr(BOOST_GET_CONST(std::vector<int>, attr));
      } else if (attr_defs[i].type_index ==
                 std::type_index(typeid(std::vector<std::string>))) {
        kernel_ctx->EmplaceBackAttr(
            BOOST_GET_CONST(std::vector<std::string>, attr));
      } else {
        PADDLE_THROW(platform::errors::Unimplemented(
            "Unsupported cast op attribute `%s` when construct "
            "KernelContext in dygraph.",
            attr_names[i]));
      }
    }
  }
}

template <typename VarType>
void PreparePhiData(const phi::Kernel& pt_kernel,
                    const framework::KernelSignature& pt_kernel_signature,
                    const NameVarMap<VarType>& ins) {
  auto& input_names = std::get<0>(pt_kernel_signature.args);
  auto& input_defs = pt_kernel.args_def().input_defs();

  PADDLE_ENFORCE_EQ(input_names.size(), input_defs.size(),
                    platform::errors::InvalidArgument(
                        "the size of inputs_args names (%d) must be equal to "
                        "the size of kernel input_defs (%d).",
                        input_names.size(), input_defs.size()));

  for (size_t i = 0; i < input_names.size(); ++i) {
    auto& in_def = input_defs.at(i);
    if (ins.find(input_names[i]) == ins.end()) {
      continue;
    }
    auto& ins_vector = ins.at(input_names[i]);

    for (size_t offset = 0; offset < ins_vector.size(); ++offset) {
      auto var = ins_vector[offset];
      const auto* tensor_in = GetTensorFromVar(var->Var());
      if (tensor_in && tensor_in->IsInitialized()) {
        if (in_def.backend == phi::Backend::ALL_BACKEND) {
          continue;
        }
        auto expected_place = phi::TransToPhiPlace(in_def.backend);
        if (platform::is_same_place(tensor_in->place(), expected_place)) {
          continue;
        }

        VLOG(3) << "Phi Transform Variable " << input_names[i] << " from "
                << tensor_in->place() << " to " << expected_place;

        framework::Tensor tmp_tensor;
        framework::TensorCopySync(*tensor_in, expected_place, &tmp_tensor);

        SetTensorToVariable(var->Var(), tmp_tensor, var->MutableVar());
      }
    }
  }
}

}  // namespace imperative
}  // namespace paddle