/* Copyright (c) 2022 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/operators/detection/iou_similarity_op.h"
#include "paddle/fluid/operators/mlu/mlu_baseop.h"

namespace paddle {
namespace operators {

using Tensor = framework::Tensor;

template <typename T>
struct IouFunction {
 public:
  explicit IouFunction(const framework::ExecutionContext& ctx) : ctx(ctx) {
    place = ctx.GetPlace();
  }
  void Transpose(const Tensor* x, Tensor* y, const std::vector<int>& axis) {
    //  y should be init first
    TransposeFromMLUTensor<T>(ctx, axis, x, y, false /*need_reshape_or_alloc*/);
  }
  void Add(const Tensor* x, const Tensor* y, Tensor* z) {
    //  y should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    MLUCnnlOpTensorDesc add_op_desc(CNNL_OP_TENSOR_ADD, ToCnnlDataType<T>(),
                                    CNNL_NOT_PROPAGATE_NAN);
    MLUCnnl::OpTensor(ctx, add_op_desc.get(), x_desc.get(), GetBasePtr(x),
                      y_desc.get(), GetBasePtr(y), z_desc.get(), GetBasePtr(z),
                      ToCnnlDataType<T>());
  }

  void Sub(const Tensor* x, const Tensor* y, Tensor* z) {
    //  y should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    MLUCnnlOpTensorDesc sub_op_desc(CNNL_OP_TENSOR_SUB, ToCnnlDataType<T>(),
                                    CNNL_NOT_PROPAGATE_NAN);
    MLUCnnl::OpTensor(ctx, sub_op_desc.get(), x_desc.get(), GetBasePtr(x),
                      y_desc.get(), GetBasePtr(y), z_desc.get(), GetBasePtr(z),
                      ToCnnlDataType<T>());
  }
  void Mul(const Tensor* x, const Tensor* y, Tensor* z) {
    //  z should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    MLUCnnlOpTensorDesc mul_op_desc(CNNL_OP_TENSOR_MUL, ToCnnlDataType<T>(),
                                    CNNL_NOT_PROPAGATE_NAN);
    MLUCnnl::OpTensor(ctx, mul_op_desc.get(), x_desc.get(), GetBasePtr(x),
                      y_desc.get(), GetBasePtr(y), z_desc.get(), GetBasePtr(z),
                      ToCnnlDataType<T>());
  }
  void DivNoNan(const Tensor* x, const Tensor* y, Tensor* z) {
    //  z should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    cnnlComputationPreference_t prefer = CNNL_COMPUTATION_FAST;

    MLUCnnl::DivNoNan(ctx, prefer, x_desc.get(), GetBasePtr(x), y_desc.get(),
                      GetBasePtr(y), z_desc.get(), GetBasePtr(z));
  }
  void Adds(const Tensor* x, float scalar, Tensor* y) {
    //  y should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    float alpha = 1.0;
    float beta = scalar;
    MLUCnnl::Transform(ctx, &alpha, &beta, x_desc.get(), GetBasePtr(x),
                       y_desc.get(), GetBasePtr(y));
  }
  void Maximum(const Tensor* x, const Tensor* y, Tensor* z) {
    //  z should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    MLUCnnl::Maximum(ctx, x_desc.get(), GetBasePtr(x), y_desc.get(),
                     GetBasePtr(y), z_desc.get(), GetBasePtr(z));
  }
  void Minimum(const Tensor* x, const Tensor* y, Tensor* z) {
    //  z should be init first
    MLUCnnlTensorDesc x_desc(*x);
    MLUCnnlTensorDesc y_desc(*y);
    MLUCnnlTensorDesc z_desc(*z);

    MLUCnnl::Minimum(ctx, x_desc.get(), GetBasePtr(x), y_desc.get(),
                     GetBasePtr(y), z_desc.get(), GetBasePtr(z));
  }

 private:
  platform::Place place;
  const framework::ExecutionContext& ctx;
};

template <typename T>
class IouSimilarityMLUKernel : public framework::OpKernel<T> {
 public:
  void Compute(const framework::ExecutionContext& ctx) const override {
    auto* x = ctx.Input<framework::LoDTensor>("X");
    auto* y = ctx.Input<framework::Tensor>("Y");
    bool normalized = ctx.Attr<bool>("box_normalized");
    auto* out = ctx.Output<framework::LoDTensor>("Out");

    auto _type = x->dtype();
    auto place = ctx.GetPlace();

    IouFunction<T> F(ctx);

    auto N = x->dims()[0];
    auto M = y->dims()[0];

    out->mutable_data<T>({N, M}, place);
    Tensor xt(_type);
    Tensor yt(_type);
    xt.mutable_data<T>({4, N}, place);
    yt.mutable_data<T>({4, M}, place);
    std::vector<int> vec_trans = {1, 0};
    F.Transpose(x, &xt, vec_trans);
    F.Transpose(y, &yt, vec_trans);
    Tensor xmin1 = xt.Slice(0, 1);
    Tensor ymin1 = xt.Slice(1, 2);
    Tensor xmax1 = xt.Slice(2, 3);
    Tensor ymax1 = xt.Slice(3, 4);
    Tensor xmin2 = yt.Slice(0, 1);
    Tensor ymin2 = yt.Slice(1, 2);
    Tensor xmax2 = yt.Slice(2, 3);
    Tensor ymax2 = yt.Slice(3, 4);
    xmin1.Resize({N, 1});
    ymin1.Resize({N, 1});
    xmax1.Resize({N, 1});
    ymax1.Resize({N, 1});
    xmin2.Resize({1, M});
    ymin2.Resize({1, M});
    xmax2.Resize({1, M});
    ymax2.Resize({1, M});

    Tensor w1(_type);
    Tensor h1(_type);
    Tensor w2(_type);
    Tensor h2(_type);
    Tensor area1(_type);
    Tensor area2(_type);
    w1.mutable_data<T>({N, 1}, place);
    h1.mutable_data<T>({N, 1}, place);
    w2.mutable_data<T>({1, M}, place);
    h2.mutable_data<T>({1, M}, place);
    area1.mutable_data<T>({N, 1}, place);
    area2.mutable_data<T>({1, M}, place);
    F.Sub(&xmax1, &xmin1, &w1);
    F.Sub(&ymax1, &ymin1, &h1);
    F.Sub(&xmax2, &xmin2, &w2);
    F.Sub(&ymax2, &ymin2, &h2);
    if (!normalized) {
      F.Adds(&w1, 1.0f, &w1);
      F.Adds(&h1, 1.0f, &h1);
      F.Adds(&w2, 1.0f, &w2);
      F.Adds(&h2, 1.0f, &h2);
    }
    F.Mul(&w1, &h1, &area1);
    F.Mul(&w2, &h2, &area2);

    Tensor inter_xmax(_type);
    Tensor inter_ymax(_type);
    Tensor inter_xmin(_type);
    Tensor inter_ymin(_type);
    inter_xmax.mutable_data<T>({N, M}, place);
    inter_ymax.mutable_data<T>({N, M}, place);
    inter_xmin.mutable_data<T>({N, M}, place);
    inter_ymin.mutable_data<T>({N, M}, place);
    F.Minimum(&xmax1, &xmax2, &inter_xmax);
    F.Minimum(&ymax1, &ymax2, &inter_ymax);
    F.Maximum(&xmin1, &xmin2, &inter_xmin);
    F.Maximum(&ymin1, &ymin2, &inter_ymin);

    Tensor inter_w(_type);
    Tensor inter_h(_type);
    inter_w.mutable_data<T>({N, M}, place);
    inter_h.mutable_data<T>({N, M}, place);
    F.Sub(&inter_xmax, &inter_xmin, &inter_w);
    F.Sub(&inter_ymax, &inter_ymin, &inter_h);

    if (!normalized) {
      F.Adds(&inter_w, 1.0f, &inter_w);
      F.Adds(&inter_h, 1.0f, &inter_h);
    }
    Tensor zeros(_type);
    zeros.mutable_data<T>({1}, place);
    FillMLUTensorWithHostValue<T>(ctx, static_cast<T>(0), &zeros);
    F.Maximum(&inter_w, &zeros, &inter_w);
    F.Maximum(&inter_h, &zeros, &inter_h);

    F.Mul(&inter_w, &inter_h, out);
    Tensor union_area(_type);
    union_area.mutable_data<T>({N, M}, place);
    F.Add(&area1, &area2, &union_area);
    F.Sub(&union_area, out, &union_area);
    F.DivNoNan(out, &union_area, out);
  }
};

}  // namespace operators
}  // namespace paddle

namespace ops = paddle::operators;
namespace plat = paddle::platform;

REGISTER_OP_MLU_KERNEL(iou_similarity, ops::IouSimilarityMLUKernel<float>,
                       ops::IouSimilarityMLUKernel<plat::float16>);