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Align to block size and block stride. @param block_size Block size in pixels. Align to cell size. Only (16,16) is supported for now. @param block_stride Block stride. It must be a multiple of cell size. @param cell_size Cell size. Only (8, 8) is supported for now. @param nbins Number of bins. Only 9 bins per cell are supported for now. */ static Ptr<HOG> create(Size win_size = Size(64, 128), Size block_size = Size(16, 16), Size block_stride = Size(8, 8), Size cell_size = Size(8, 8), int nbins = 9); //! Gaussian smoothing window parameter. virtual void setWinSigma(double win_sigma) = 0; virtual double getWinSigma() const = 0; //! L2-Hys normalization method shrinkage. virtual void setL2HysThreshold(double threshold_L2hys) = 0; virtual double getL2HysThreshold() const = 0; //! Flag to specify whether the gamma correction preprocessing is required or not. virtual void setGammaCorrection(bool gamma_correction) = 0; virtual bool getGammaCorrection() const = 0; //! Maximum number of detection window increases. virtual void setNumLevels(int nlevels) = 0; virtual int getNumLevels() const = 0; //! Threshold for the distance between features and SVM classifying plane. //! Usually it is 0 and should be specfied in the detector coefficients (as the last free //! coefficient). But if the free coefficient is omitted (which is allowed), you can specify it //! manually here. virtual void setHitThreshold(double hit_threshold) = 0; virtual double getHitThreshold() const = 0; //! Window stride. It must be a multiple of block stride. virtual void setWinStride(Size win_stride) = 0; virtual Size getWinStride() const = 0; //! Coefficient of the detection window increase. virtual void setScaleFactor(double scale0) = 0; virtual double getScaleFactor() const = 0; //! Coefficient to regulate the similarity threshold. When detected, some //! objects can be covered by many rectangles. 0 means not to perform grouping. //! See groupRectangles. virtual void setGroupThreshold(int group_threshold) = 0; virtual int getGroupThreshold() const = 0; //! Descriptor storage format: //! - **DESCR_FORMAT_ROW_BY_ROW** - Row-major order. //! - **DESCR_FORMAT_COL_BY_COL** - Column-major order. virtual void setDescriptorFormat(int descr_format) = 0; virtual int getDescriptorFormat() const = 0; /** @brief Returns the number of coefficients required for the classification. */ virtual size_t getDescriptorSize() const = 0; /** @brief Returns the block histogram size. */ virtual size_t getBlockHistogramSize() const = 0; /** @brief Sets coefficients for the linear SVM classifier. */ virtual void setSVMDetector(InputArray detector) = 0; /** @brief Returns coefficients of the classifier trained for people detection. */ virtual Mat getDefaultPeopleDetector() const = 0; /** @brief Performs object detection without a multi-scale window. @param img Source image. CV_8UC1 and CV_8UC4 types are supported for now. @param found_locations Left-top corner points of detected objects boundaries. @param confidences Optional output array for confidences. */ virtual void detect(InputArray img, std::vector<Point>& found_locations, std::vector<double>* confidences = NULL) = 0; /** @brief Performs object detection with a multi-scale window. @param img Source image. See cuda::HOGDescriptor::detect for type limitations. @param found_locations Detected objects boundaries. @param confidences Optional output array for confidences. */ virtual void detectMultiScale(InputArray img, std::vector<Rect>& found_locations, std::vector<double>* confidences = NULL) = 0; /** @brief Returns block descriptors computed for the whole image. @param img Source image. See cuda::HOGDescriptor::detect for type limitations. @param descriptors 2D array of descriptors. @param stream CUDA stream. */ virtual void compute(InputArray img, OutputArray descriptors, Stream& stream = Stream::Null()) = 0; }; // // CascadeClassifier // /** @brief Cascade classifier class used for object detection. Supports HAAR and LBP cascades. : @note - A cascade classifier example can be found at opencv_source_code/samples/gpu/cascadeclassifier.cpp - A Nvidea API specific cascade classifier example can be found at opencv_source_code/samples/gpu/cascadeclassifier_nvidia_api.cpp */ class CV_EXPORTS CascadeClassifier : public Algorithm { public: /** @brief Loads the classifier from a file. Cascade type is detected automatically by constructor parameter. @param filename Name of the file from which the classifier is loaded. Only the old haar classifier (trained by the haar training application) and NVIDIA's nvbin are supported for HAAR and only new type of OpenCV XML cascade supported for LBP. The working haar models can be found at opencv_folder/data/haarcascades_cuda/ */ static Ptr<CascadeClassifier> create(const String& filename); /** @overload */ static Ptr<CascadeClassifier> create(const FileStorage& file); //! Maximum possible object size. Objects larger than that are ignored. Used for //! second signature and supported only for LBP cascades. virtual void setMaxObjectSize(Size maxObjectSize) = 0; virtual Size getMaxObjectSize() const = 0; //! Minimum possible object size. Objects smaller than that are ignored. virtual void setMinObjectSize(Size minSize) = 0; virtual Size getMinObjectSize() const = 0; //! Parameter specifying how much the image size is reduced at each image scale. virtual void setScaleFactor(double scaleFactor) = 0; virtual double getScaleFactor() const = 0; //! Parameter specifying how many neighbors each candidate rectangle should have //! to retain it. virtual void setMinNeighbors(int minNeighbors) = 0; virtual int getMinNeighbors() const = 0; virtual void setFindLargestObject(bool findLargestObject) = 0; virtual bool getFindLargestObject() = 0; virtual void setMaxNumObjects(int maxNumObjects) = 0; virtual int getMaxNumObjects() const = 0; virtual Size getClassifierSize() const = 0; /** @brief Detects objects of different sizes in the input image. @param image Matrix of type CV_8U containing an image where objects should be detected. @param objects Buffer to store detected objects (rectangles). @param stream CUDA stream. To get final array of detected objects use CascadeClassifier::convert method. @code Ptr<cuda::CascadeClassifier> cascade_gpu = cuda::CascadeClassifier::create(...); Mat image_cpu = imread(...) GpuMat image_gpu(image_cpu); GpuMat objbuf; cascade_gpu->detectMultiScale(image_gpu, objbuf); std::vector<Rect> faces; cascade_gpu->convert(objbuf, faces); for(int i = 0; i < detections_num; ++i) cv::rectangle(image_cpu, faces[i], Scalar(255)); imshow("Faces", image_cpu); @endcode @sa CascadeClassifier::detectMultiScale */ virtual void detectMultiScale(InputArray image, OutputArray objects, Stream& stream = Stream::Null()) = 0; /** @brief Converts objects array from internal representation to standard vector. @param gpu_objects Objects array in internal representation. @param objects Resulting array. */ virtual void convert(OutputArray gpu_objects, std::vector<Rect>& objects) = 0; }; //! @} }} // namespace cv { namespace cuda { #endif /* __OPENCV_CUDAOBJDETECT_HPP__ */