// 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. #pragma once #include "ultra_infer/ultra_infer_model.h" #include "ultra_infer/vision/common/processors/transform.h" #include "ultra_infer/vision/common/result.h" namespace ultra_infer { namespace vision { namespace detection { /*! @brief YOLOv7End2EndTRT model object used when to load a YOLOv7End2EndTRT * model exported by YOLOv7. */ class ULTRAINFER_DECL YOLOv7End2EndTRT : public UltraInferModel { public: /** \brief Set path of model file and the configuration of runtime. * * \param[in] model_file Path of model file, e.g ./yolov7end2end_trt.onnx * \param[in] params_file Path of parameter file, e.g ppyoloe/model.pdiparams, * if the model format is ONNX, this parameter will be ignored \param[in] * custom_option RuntimeOption for inference, the default will use cpu, and * choose the backend defined in "valid_cpu_backends" \param[in] model_format * Model format of the loaded model, default is ONNX format */ YOLOv7End2EndTRT(const std::string &model_file, const std::string ¶ms_file = "", const RuntimeOption &custom_option = RuntimeOption(), const ModelFormat &model_format = ModelFormat::ONNX); ~YOLOv7End2EndTRT(); virtual std::string ModelName() const { return "yolov7end2end_trt"; } /** \brief Predict the detection result for an input image * * \param[in] im The input image data, comes from cv::imread(), is a 3-D array * with layout HWC, BGR format \param[in] result The output detection result * will be written to this structure \param[in] conf_threshold confidence * threshold for postprocessing, default is 0.25 \return true if the * prediction succeeded, otherwise false */ virtual bool Predict(cv::Mat *im, DetectionResult *result, float conf_threshold = 0.25); void UseCudaPreprocessing(int max_img_size = 3840 * 2160); /*! @brief Argument for image preprocessing step, tuple of (width, height), decide the target size after resize, default size = {640, 640} */ std::vector size; // padding value, size should be the same as channels std::vector padding_value; // only pad to the minimum rectangle which height and width is times of stride bool is_mini_pad; // while is_mini_pad = false and is_no_pad = true, // will resize the image to the set size bool is_no_pad; // if is_scale_up is false, the input image only can be zoom out, // the maximum resize scale cannot exceed 1.0 bool is_scale_up; // padding stride, for is_mini_pad int stride; private: bool Initialize(); bool Preprocess(Mat *mat, FDTensor *output, std::map> *im_info); bool CudaPreprocess(Mat *mat, FDTensor *output, std::map> *im_info); bool Postprocess(std::vector &infer_results, DetectionResult *result, const std::map> &im_info, float conf_threshold); void LetterBox(Mat *mat, const std::vector &size, const std::vector &color, bool _auto, bool scale_fill = false, bool scale_up = true, int stride = 32); bool is_dynamic_input_; // CUDA host buffer for input image uint8_t *input_img_cuda_buffer_host_ = nullptr; // CUDA device buffer for input image uint8_t *input_img_cuda_buffer_device_ = nullptr; // CUDA device buffer for TRT input tensor float *input_tensor_cuda_buffer_device_ = nullptr; // Whether to use CUDA preprocessing bool use_cuda_preprocessing_ = false; // CUDA stream void *cuda_stream_ = nullptr; }; } // namespace detection } // namespace vision } // namespace ultra_infer