~speedprog/mtg/mtg_card_detector.git

			@@ -11,10 +11,10 @@

			#ifdef _WIN32
			#define OPENCV
			#include "windows.h"
			#endif

			#define TRACK_OPTFLOW
			// To use tracking - uncomment the following line. Tracking is supported only by OpenCV 3.x
			//#define TRACK_OPTFLOW

			#include "yolo_v2_class.hpp" // imported functions from DLL

			@@ -91,17 +91,27 @@

			int main(int argc, char *argv[])
			{
			std::string names_file = "data/voc.names";
			std::string cfg_file = "cfg/yolo-voc.cfg";
			std::string weights_file = "yolo-voc.weights";
			std::string filename;
			if (argc > 1) filename = argv[1];

			//Detector detector("cfg/yolo-voc.cfg", "yolo-voc.weights");
			Detector detector("tiny-yolo-voc_air.cfg", "backup/tiny-yolo-voc_air_5000.weights");
			if (argc > 4) { //voc.names yolo-voc.cfg yolo-voc.weights test.mp4
			names_file = argv[1];
			cfg_file = argv[2];
			weights_file = argv[3];
			filename = argv[4];
			}
			else if (argc > 1) filename = argv[1];

			auto obj_names = objects_names_from_file("data/voc.names");
			Detector detector(cfg_file, weights_file);

			auto obj_names = objects_names_from_file(names_file);
			std::string out_videofile = "result.avi";
			bool const save_output_videofile = false;
			#ifdef TRACK_OPTFLOW
			Tracker_optflow tracker_flow;
			detector.wait_stream = true;
			#endif

			while (true)
			@@ -158,7 +168,6 @@
			det_image = detector.mat_to_image_resize(cur_frame);
			result_vec = thread_result_vec;
			result_vec = detector.tracking(result_vec); // comment it - if track_id is not required

			#ifdef TRACK_OPTFLOW
			// track optical flow
			if (track_optflow_queue.size() > 0) {
			@@ -173,7 +182,6 @@
			new_track_optflow_queue = track_optflow_queue;
			}
			track_optflow_queue = new_track_optflow_queue;
			new_track_optflow_queue.swap(std::queue<cv::Mat>());
			passed_flow_frames = 0;
			}
			#endif
			@@ -186,17 +194,15 @@
			auto current_image = det_image;
			consumed = true;
			while (current_image.use_count() > 0) {
			//std::vector<bbox_t> result;
			auto result = detector.detect_resized(*current_image, frame_size, 0.24, false); // true
			//Sleep(200);
			Sleep(50);
			auto result = detector.detect_resized(*current_image, frame_size, 0.20, false); // true
			++fps_det_counter;
			std::unique_lock<std::mutex> lock(mtx);
			thread_result_vec = result;
			current_image = det_image;
			consumed = true;
			cv_detected.notify_all();
			while (consumed) cv_pre_tracked.wait(lock);
			if(detector.wait_stream)
			while (consumed) cv_pre_tracked.wait(lock);
			}
			});
			}
			@@ -217,7 +223,7 @@
			result_vec = tracker_flow.tracking_flow(cur_frame, result_vec); // track optical flow
			#endif

			draw_boxes(cur_frame, result_vec, obj_names, 3, current_det_fps, current_cap_fps);
			draw_boxes(cur_frame, result_vec, obj_names, 3, current_det_fps, current_cap_fps); // 3 or 16ms
			//show_console_result(result_vec, obj_names);

			if (output_video.isOpened() && videowrite_ready) {
			@@ -230,11 +236,13 @@
			}
			}

			#ifndef TRACK_OPTFLOW
			// wait detection result for video-file only (not for net-cam)
			//if (protocol != "rtsp://" && protocol != "http://" && protocol != "https:/") {
			// std::unique_lock<std::mutex> lock(mtx);
			// while (!consumed) cv_detected.wait(lock);
			//}
			if (protocol != "rtsp://" && protocol != "http://" && protocol != "https:/") {
			std::unique_lock<std::mutex> lock(mtx);
			while (!consumed) cv_detected.wait(lock);
			}
			#endif
			}
			if (t_cap.joinable()) t_cap.join();
			if (t_detect.joinable()) t_detect.join();