~speedprog/mtg/mtg_card_detector.git

			@@ -16,10 +16,10 @@

			#ifndef CV_VERSION_EPOCH
			#include "opencv2/videoio/videoio_c.h"
			#define OPENCV_VERSION CVAUX_STR(CV_VERSION_MAJOR)""CVAUX_STR(CV_VERSION_MINOR)""CVAUX_STR(CV_VERSION_REVISION)
			#define OPENCV_VERSION CVAUX_STR(CV_VERSION_MAJOR)"" CVAUX_STR(CV_VERSION_MINOR)"" CVAUX_STR(CV_VERSION_REVISION)
			#pragma comment(lib, "opencv_world" OPENCV_VERSION ".lib")
			#else
			#define OPENCV_VERSION CVAUX_STR(CV_VERSION_EPOCH)""CVAUX_STR(CV_VERSION_MAJOR)""CVAUX_STR(CV_VERSION_MINOR)
			#define OPENCV_VERSION CVAUX_STR(CV_VERSION_EPOCH)"" CVAUX_STR(CV_VERSION_MAJOR)"" CVAUX_STR(CV_VERSION_MINOR)
			#pragma comment(lib, "opencv_core" OPENCV_VERSION ".lib")
			#pragma comment(lib, "opencv_imgproc" OPENCV_VERSION ".lib")
			#pragma comment(lib, "opencv_highgui" OPENCV_VERSION ".lib")
			@@ -27,7 +27,7 @@

			IplImage* draw_train_chart(float max_img_loss, int max_batches, int number_of_lines, int img_size);
			void draw_train_loss(IplImage* img, int img_size, float avg_loss, float max_img_loss, int current_batch, int max_batches);
			#endif // OPENCV
			#endif // OPENCV

			static int coco_ids[] = {1,2,3,4,5,6,7,8,9,10,11,13,14,15,16,17,18,19,20,21,22,23,24,25,27,28,31,32,33,34,35,36,37,38,39,40,41,42,43,44,46,47,48,49,50,51,52,53,54,55,56,57,58,59,60,61,62,63,64,65,67,70,72,73,74,75,76,77,78,79,80,81,82,84,85,86,87,88,89,90};

			@@ -61,6 +61,15 @@
			srand(time(0));
			network net = nets[0];

			const int actual_batch_size = net.batch * net.subdivisions;
			if (actual_batch_size == 1) {
			printf("\n Error: You set incorrect value batch=1 for Training! You should set batch=64 subdivision=64 \n");
			getchar();
			}
			else if (actual_batch_size < 64) {
			printf("\n Warning: You set batch=%d lower than 64! It is recommended to set batch=64 subdivision=64 \n", actual_batch_size);
			}

			int imgs = net.batch * net.subdivisions * ngpus;
			printf("Learning Rate: %g, Momentum: %g, Decay: %g\n", net.learning_rate, net.momentum, net.decay);
			data train, buffer;
			@@ -74,24 +83,26 @@
			//int N = plist->size;
			char paths = (char )list_to_array(plist);

			int init_w = net.w;
			int init_h = net.h;
			int iter_save;
			iter_save = get_current_batch(net);
			int init_w = net.w;
			int init_h = net.h;
			int iter_save;
			iter_save = get_current_batch(net);

			load_args args = {0};
			args.w = net.w;
			args.h = net.h;
			args.c = net.c;
			args.paths = paths;
			args.n = imgs;
			args.m = plist->size;
			args.classes = classes;
			args.flip = net.flip;
			args.jitter = jitter;
			args.num_boxes = l.max_boxes;
			args.small_object = net.small_object;
			args.small_object = net.small_object;
			args.d = &buffer;
			args.type = DETECTION_DATA;
			args.threads = 16; // 64
			args.threads = 16; // 64

			args.angle = net.angle;
			args.exposure = net.exposure;
			@@ -99,28 +110,40 @@
			args.hue = net.hue;

			#ifdef OPENCV
			args.threads = 3;
			IplImage* img = NULL;
			float max_img_loss = 5;
			int number_of_lines = 100;
			int img_size = 1000;
			if (!dont_show)
			img = draw_train_chart(max_img_loss, net.max_batches, number_of_lines, img_size);
			#endif //OPENCV
			args.threads = 3 * ngpus;
			IplImage* img = NULL;
			float max_img_loss = 5;
			int number_of_lines = 100;
			int img_size = 1000;
			if (!dont_show)
			img = draw_train_chart(max_img_loss, net.max_batches, number_of_lines, img_size);
			#endif //OPENCV

			pthread_t load_thread = load_data(args);
			double time;
			int count = 0;
			//while(iimgs < N120){
			while(get_current_batch(net) < net.max_batches){
			if(l.random && count++%10 == 0){
			if(l.random && count++%10 == 0){
			printf("Resizing\n");
			int dim = (rand() % 12 + (init_w/32 - 5)) * 32; // +-160
			//if (get_current_batch(net)+100 > net.max_batches) dim = 544;
			//int dim = (rand() % 12 + (init_w/32 - 5)) * 32; // +-160
			//int dim = (rand() % 4 + 16) * 32;
			printf("%d\n", dim);
			args.w = dim;
			args.h = dim;
			//if (get_current_batch(net)+100 > net.max_batches) dim = 544;

			//int random_val = rand() % 12;
			//int dim_w = (random_val + (init_w / 32 - 5)) * 32; // +-160
			//int dim_h = (random_val + (init_h / 32 - 5)) * 32; // +-160

			float random_val = rand_scale(1.4); // *x or /x
			int dim_w = roundl(random_valinit_w / 32) 32;
			int dim_h = roundl(random_valinit_h / 32) 32;

			if (dim_w < 32) dim_w = 32;
			if (dim_h < 32) dim_h = 32;

			printf("%d x %d \n", dim_w, dim_h);
			args.w = dim_w;
			args.h = dim_h;

			pthread_join(load_thread, 0);
			train = buffer;
			@@ -128,7 +151,7 @@
			load_thread = load_data(args);

			for(i = 0; i < ngpus; ++i){
			resize_network(nets + i, dim, dim);
			resize_network(nets + i, dim_w, dim_h);
			}
			net = nets[0];
			}
			@@ -167,28 +190,28 @@
			#else
			loss = train_network(net, train);
			#endif
			if (avg_loss < 0 \|\| avg_loss != avg_loss) avg_loss = loss; // if(-inf or nan)
			if (avg_loss < 0 \|\| avg_loss != avg_loss) avg_loss = loss; // if(-inf or nan)
			avg_loss = avg_loss.9 + loss.1;

			i = get_current_batch(net);
			printf("\n %d: %f, %f avg, %f rate, %lf seconds, %d images\n", get_current_batch(net), loss, avg_loss, get_current_rate(net), (what_time_is_it_now()-time), i*imgs);
			printf("\n %d: %f, %f avg loss, %f rate, %lf seconds, %d images\n", get_current_batch(net), loss, avg_loss, get_current_rate(net), (what_time_is_it_now()-time), i*imgs);

			#ifdef OPENCV
			if(!dont_show)
			draw_train_loss(img, img_size, avg_loss, max_img_loss, i, net.max_batches);
			#endif // OPENCV
			if(!dont_show)
			draw_train_loss(img, img_size, avg_loss, max_img_loss, i, net.max_batches);
			#endif // OPENCV

			//if (i % 1000 == 0 \|\| (i < 1000 && i % 100 == 0)) {
			//if (i % 100 == 0) {
			if(i >= (iter_save + 100)) {
			iter_save = i;
			//if (i % 1000 == 0 \|\| (i < 1000 && i % 100 == 0)) {
			//if (i % 100 == 0) {
			if(i >= (iter_save + 100)) {
			iter_save = i;
			#ifdef GPU
			if (ngpus != 1) sync_nets(nets, ngpus, 0);
			if (ngpus != 1) sync_nets(nets, ngpus, 0);
			#endif
			char buff[256];
			sprintf(buff, "%s/%s_%d.weights", backup_directory, base, i);
			save_weights(net, buff);
			}
			char buff[256];
			sprintf(buff, "%s/%s_%d.weights", backup_directory, base, i);
			save_weights(net, buff);
			}
			free_data(train);
			}
			#ifdef GPU
			@@ -198,834 +221,872 @@
			sprintf(buff, "%s/%s_final.weights", backup_directory, base);
			save_weights(net, buff);

			//cvReleaseImage(&img);
			//cvDestroyAllWindows();
			#ifdef OPENCV
			cvReleaseImage(&img);
			cvDestroyAllWindows();
			#endif

			// free memory
			pthread_join(load_thread, 0);
			free_data(buffer);

			free(base);
			free(paths);
			free_list_contents(plist);
			free_list(plist);

			free_list_contents_kvp(options);
			free_list(options);

			free(nets);
			free_network(net);
			}


			static int get_coco_image_id(char *filename)
			{
			char *p = strrchr(filename, '/');
			char *c = strrchr(filename, '_');
			if (c) p = c;
			return atoi(p + 1);
			char *p = strrchr(filename, '/');
			char *c = strrchr(filename, '_');
			if (c) p = c;
			return atoi(p + 1);
			}

			static void print_cocos(FILE fp, char image_path, detection *dets, int num_boxes, int classes, int w, int h)
			{
			int i, j;
			int image_id = get_coco_image_id(image_path);
			for (i = 0; i < num_boxes; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2.;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2.;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2.;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2.;
			int i, j;
			int image_id = get_coco_image_id(image_path);
			for (i = 0; i < num_boxes; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2.;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2.;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2.;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2.;

			if (xmin < 0) xmin = 0;
			if (ymin < 0) ymin = 0;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;
			if (xmin < 0) xmin = 0;
			if (ymin < 0) ymin = 0;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;

			float bx = xmin;
			float by = ymin;
			float bw = xmax - xmin;
			float bh = ymax - ymin;
			float bx = xmin;
			float by = ymin;
			float bw = xmax - xmin;
			float bh = ymax - ymin;

			for (j = 0; j < classes; ++j) {
			if (dets[i].prob[j]) fprintf(fp, "{\"image_id\":%d, \"category_id\":%d, \"bbox\":[%f, %f, %f, %f], \"score\":%f},\n", image_id, coco_ids[j], bx, by, bw, bh, dets[i].prob[j]);
			}
			}
			for (j = 0; j < classes; ++j) {
			if (dets[i].prob[j]) fprintf(fp, "{\"image_id\":%d, \"category_id\":%d, \"bbox\":[%f, %f, %f, %f], \"score\":%f},\n", image_id, coco_ids[j], bx, by, bw, bh, dets[i].prob[j]);
			}
			}
			}

			void print_detector_detections(FILE *fps, char id, detection *dets, int total, int classes, int w, int h)
			{
			int i, j;
			for (i = 0; i < total; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2. + 1;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2. + 1;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2. + 1;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2. + 1;
			int i, j;
			for (i = 0; i < total; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2. + 1;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2. + 1;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2. + 1;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2. + 1;

			if (xmin < 1) xmin = 1;
			if (ymin < 1) ymin = 1;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;
			if (xmin < 1) xmin = 1;
			if (ymin < 1) ymin = 1;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;

			for (j = 0; j < classes; ++j) {
			if (dets[i].prob[j]) fprintf(fps[j], "%s %f %f %f %f %f\n", id, dets[i].prob[j],
			xmin, ymin, xmax, ymax);
			}
			}
			for (j = 0; j < classes; ++j) {
			if (dets[i].prob[j]) fprintf(fps[j], "%s %f %f %f %f %f\n", id, dets[i].prob[j],
			xmin, ymin, xmax, ymax);
			}
			}
			}

			void print_imagenet_detections(FILE fp, int id, detection dets, int total, int classes, int w, int h)
			{
			int i, j;
			for (i = 0; i < total; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2.;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2.;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2.;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2.;
			int i, j;
			for (i = 0; i < total; ++i) {
			float xmin = dets[i].bbox.x - dets[i].bbox.w / 2.;
			float xmax = dets[i].bbox.x + dets[i].bbox.w / 2.;
			float ymin = dets[i].bbox.y - dets[i].bbox.h / 2.;
			float ymax = dets[i].bbox.y + dets[i].bbox.h / 2.;

			if (xmin < 0) xmin = 0;
			if (ymin < 0) ymin = 0;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;
			if (xmin < 0) xmin = 0;
			if (ymin < 0) ymin = 0;
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;

			for (j = 0; j < classes; ++j) {
			int class = j;
			if (dets[i].prob[class]) fprintf(fp, "%d %d %f %f %f %f %f\n", id, j + 1, dets[i].prob[class],
			xmin, ymin, xmax, ymax);
			}
			}
			for (j = 0; j < classes; ++j) {
			int class = j;
			if (dets[i].prob[class]) fprintf(fp, "%d %d %f %f %f %f %f\n", id, j + 1, dets[i].prob[class],
			xmin, ymin, xmax, ymax);
			}
			}
			}

			void validate_detector(char datacfg, char cfgfile, char weightfile, char outfile)
			{
			int j;
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.list");
			char *name_list = option_find_str(options, "names", "data/names.list");
			char *prefix = option_find_str(options, "results", "results");
			char **names = get_labels(name_list);
			char *mapf = option_find_str(options, "map", 0);
			int *map = 0;
			if (mapf) map = read_map(mapf);
			int j;
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.list");
			char *name_list = option_find_str(options, "names", "data/names.list");
			char *prefix = option_find_str(options, "results", "results");
			char **names = get_labels(name_list);
			char *mapf = option_find_str(options, "map", 0);
			int *map = 0;
			if (mapf) map = read_map(mapf);

			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fprintf(stderr, "Learning Rate: %g, Momentum: %g, Decay: %g\n", net.learning_rate, net.momentum, net.decay);
			srand(time(0));
			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fprintf(stderr, "Learning Rate: %g, Momentum: %g, Decay: %g\n", net.learning_rate, net.momentum, net.decay);
			srand(time(0));

			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);
			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);

			layer l = net.layers[net.n - 1];
			int classes = l.classes;
			layer l = net.layers[net.n - 1];
			int classes = l.classes;

			char buff[1024];
			char *type = option_find_str(options, "eval", "voc");
			FILE *fp = 0;
			FILE **fps = 0;
			int coco = 0;
			int imagenet = 0;
			if (0 == strcmp(type, "coco")) {
			if (!outfile) outfile = "coco_results";
			snprintf(buff, 1024, "%s/%s.json", prefix, outfile);
			fp = fopen(buff, "w");
			fprintf(fp, "[\n");
			coco = 1;
			}
			else if (0 == strcmp(type, "imagenet")) {
			if (!outfile) outfile = "imagenet-detection";
			snprintf(buff, 1024, "%s/%s.txt", prefix, outfile);
			fp = fopen(buff, "w");
			imagenet = 1;
			classes = 200;
			}
			else {
			if (!outfile) outfile = "comp4_det_test_";
			fps = calloc(classes, sizeof(FILE *));
			for (j = 0; j < classes; ++j) {
			snprintf(buff, 1024, "%s/%s%s.txt", prefix, outfile, names[j]);
			fps[j] = fopen(buff, "w");
			}
			}
			char buff[1024];
			char *type = option_find_str(options, "eval", "voc");
			FILE *fp = 0;
			FILE **fps = 0;
			int coco = 0;
			int imagenet = 0;
			if (0 == strcmp(type, "coco")) {
			if (!outfile) outfile = "coco_results";
			snprintf(buff, 1024, "%s/%s.json", prefix, outfile);
			fp = fopen(buff, "w");
			fprintf(fp, "[\n");
			coco = 1;
			}
			else if (0 == strcmp(type, "imagenet")) {
			if (!outfile) outfile = "imagenet-detection";
			snprintf(buff, 1024, "%s/%s.txt", prefix, outfile);
			fp = fopen(buff, "w");
			imagenet = 1;
			classes = 200;
			}
			else {
			if (!outfile) outfile = "comp4_det_test_";
			fps = calloc(classes, sizeof(FILE *));
			for (j = 0; j < classes; ++j) {
			snprintf(buff, 1024, "%s/%s%s.txt", prefix, outfile, names[j]);
			fps[j] = fopen(buff, "w");
			}
			}


			int m = plist->size;
			int i = 0;
			int t;
			int m = plist->size;
			int i = 0;
			int t;

			float thresh = .005;
			float nms = .45;
			float thresh = .005;
			float nms = .45;

			int nthreads = 4;
			image *val = calloc(nthreads, sizeof(image));
			image *val_resized = calloc(nthreads, sizeof(image));
			image *buf = calloc(nthreads, sizeof(image));
			image *buf_resized = calloc(nthreads, sizeof(image));
			pthread_t *thr = calloc(nthreads, sizeof(pthread_t));
			int nthreads = 4;
			image *val = calloc(nthreads, sizeof(image));
			image *val_resized = calloc(nthreads, sizeof(image));
			image *buf = calloc(nthreads, sizeof(image));
			image *buf_resized = calloc(nthreads, sizeof(image));
			pthread_t *thr = calloc(nthreads, sizeof(pthread_t));

			load_args args = { 0 };
			args.w = net.w;
			args.h = net.h;
			args.type = IMAGE_DATA;
			//args.type = LETTERBOX_DATA;
			load_args args = { 0 };
			args.w = net.w;
			args.h = net.h;
			args.c = net.c;
			args.type = IMAGE_DATA;
			//args.type = LETTERBOX_DATA;

			for (t = 0; t < nthreads; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			time_t start = time(0);
			for (i = nthreads; i < m + nthreads; i += nthreads) {
			fprintf(stderr, "%d\n", i);
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			pthread_join(thr[t], 0);
			val[t] = buf[t];
			val_resized[t] = buf_resized[t];
			}
			for (t = 0; t < nthreads && i + t < m; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			char *path = paths[i + t - nthreads];
			char *id = basecfg(path);
			float *X = val_resized[t].data;
			network_predict(net, X);
			int w = val[t].w;
			int h = val[t].h;
			int nboxes = 0;
			int letterbox = (args.type == LETTERBOX_DATA);
			detection *dets = get_network_boxes(&net, w, h, thresh, .5, map, 0, &nboxes, letterbox);
			if (nms) do_nms_sort(dets, nboxes, classes, nms);
			if (coco) {
			print_cocos(fp, path, dets, nboxes, classes, w, h);
			}
			else if (imagenet) {
			print_imagenet_detections(fp, i + t - nthreads + 1, dets, nboxes, classes, w, h);
			}
			else {
			print_detector_detections(fps, id, dets, nboxes, classes, w, h);
			}
			free_detections(dets, nboxes);
			free(id);
			free_image(val[t]);
			free_image(val_resized[t]);
			}
			}
			for (j = 0; j < classes; ++j) {
			if (fps) fclose(fps[j]);
			}
			if (coco) {
			fseek(fp, -2, SEEK_CUR);
			fprintf(fp, "\n]\n");
			fclose(fp);
			}
			fprintf(stderr, "Total Detection Time: %f Seconds\n", time(0) - start);
			for (t = 0; t < nthreads; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			time_t start = time(0);
			for (i = nthreads; i < m + nthreads; i += nthreads) {
			fprintf(stderr, "%d\n", i);
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			pthread_join(thr[t], 0);
			val[t] = buf[t];
			val_resized[t] = buf_resized[t];
			}
			for (t = 0; t < nthreads && i + t < m; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			char *path = paths[i + t - nthreads];
			char *id = basecfg(path);
			float *X = val_resized[t].data;
			network_predict(net, X);
			int w = val[t].w;
			int h = val[t].h;
			int nboxes = 0;
			int letterbox = (args.type == LETTERBOX_DATA);
			detection *dets = get_network_boxes(&net, w, h, thresh, .5, map, 0, &nboxes, letterbox);
			if (nms) do_nms_sort(dets, nboxes, classes, nms);
			if (coco) {
			print_cocos(fp, path, dets, nboxes, classes, w, h);
			}
			else if (imagenet) {
			print_imagenet_detections(fp, i + t - nthreads + 1, dets, nboxes, classes, w, h);
			}
			else {
			print_detector_detections(fps, id, dets, nboxes, classes, w, h);
			}
			free_detections(dets, nboxes);
			free(id);
			free_image(val[t]);
			free_image(val_resized[t]);
			}
			}
			for (j = 0; j < classes; ++j) {
			if (fps) fclose(fps[j]);
			}
			if (coco) {
			fseek(fp, -2, SEEK_CUR);
			fprintf(fp, "\n]\n");
			fclose(fp);
			}
			fprintf(stderr, "Total Detection Time: %f Seconds\n", (double)time(0) - start);
			}

			void validate_detector_recall(char datacfg, char cfgfile, char *weightfile)
			{
			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fuse_conv_batchnorm(net);
			srand(time(0));
			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fuse_conv_batchnorm(net);
			srand(time(0));

			//list *plist = get_paths("data/coco_val_5k.list");
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.txt");
			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);
			//list *plist = get_paths("data/coco_val_5k.list");
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.txt");
			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);

			layer l = net.layers[net.n - 1];
			layer l = net.layers[net.n - 1];

			int j, k;
			int j, k;

			int m = plist->size;
			int i = 0;
			int m = plist->size;
			int i = 0;

			float thresh = .001;
			float iou_thresh = .5;
			float nms = .4;
			float thresh = .001;
			float iou_thresh = .5;
			float nms = .4;

			int total = 0;
			int correct = 0;
			int proposals = 0;
			float avg_iou = 0;
			int total = 0;
			int correct = 0;
			int proposals = 0;
			float avg_iou = 0;

			for (i = 0; i < m; ++i) {
			char *path = paths[i];
			image orig = load_image_color(path, 0, 0);
			image sized = resize_image(orig, net.w, net.h);
			char *id = basecfg(path);
			network_predict(net, sized.data);
			int nboxes = 0;
			int letterbox = 0;
			detection *dets = get_network_boxes(&net, sized.w, sized.h, thresh, .5, 0, 1, &nboxes, letterbox);
			if (nms) do_nms_obj(dets, nboxes, 1, nms);
			for (i = 0; i < m; ++i) {
			char *path = paths[i];
			image orig = load_image(path, 0, 0, net.c);
			image sized = resize_image(orig, net.w, net.h);
			char *id = basecfg(path);
			network_predict(net, sized.data);
			int nboxes = 0;
			int letterbox = 0;
			detection *dets = get_network_boxes(&net, sized.w, sized.h, thresh, .5, 0, 1, &nboxes, letterbox);
			if (nms) do_nms_obj(dets, nboxes, 1, nms);

			char labelpath[4096];
			find_replace(path, "images", "labels", labelpath);
			find_replace(labelpath, "JPEGImages", "labels", labelpath);
			find_replace(labelpath, ".jpg", ".txt", labelpath);
			find_replace(labelpath, ".png", ".txt", labelpath);
			find_replace(labelpath, ".bmp", ".txt", labelpath);
			find_replace(labelpath, ".JPG", ".txt", labelpath);
			find_replace(labelpath, ".JPEG", ".txt", labelpath);
			char labelpath[4096];
			replace_image_to_label(path, labelpath);

			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			for (k = 0; k < nboxes; ++k) {
			if (dets[k].objectness > thresh) {
			++proposals;
			}
			}
			for (j = 0; j < num_labels; ++j) {
			++total;
			box t = { truth[j].x, truth[j].y, truth[j].w, truth[j].h };
			float best_iou = 0;
			for (k = 0; k < nboxes; ++k) {
			float iou = box_iou(dets[k].bbox, t);
			if (dets[k].objectness > thresh && iou > best_iou) {
			best_iou = iou;
			}
			}
			avg_iou += best_iou;
			if (best_iou > iou_thresh) {
			++correct;
			}
			}
			//fprintf(stderr, " %s - %s - ", paths[i], labelpath);
			fprintf(stderr, "%5d %5d %5d\tRPs/Img: %.2f\tIOU: %.2f%%\tRecall:%.2f%%\n", i, correct, total, (float)proposals / (i + 1), avg_iou * 100 / total, 100.*correct / total);
			free(id);
			free_image(orig);
			free_image(sized);
			}
			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			for (k = 0; k < nboxes; ++k) {
			if (dets[k].objectness > thresh) {
			++proposals;
			}
			}
			for (j = 0; j < num_labels; ++j) {
			++total;
			box t = { truth[j].x, truth[j].y, truth[j].w, truth[j].h };
			float best_iou = 0;
			for (k = 0; k < nboxes; ++k) {
			float iou = box_iou(dets[k].bbox, t);
			if (dets[k].objectness > thresh && iou > best_iou) {
			best_iou = iou;
			}
			}
			avg_iou += best_iou;
			if (best_iou > iou_thresh) {
			++correct;
			}
			}
			//fprintf(stderr, " %s - %s - ", paths[i], labelpath);
			fprintf(stderr, "%5d %5d %5d\tRPs/Img: %.2f\tIOU: %.2f%%\tRecall:%.2f%%\n", i, correct, total, (float)proposals / (i + 1), avg_iou * 100 / total, 100.*correct / total);
			free(id);
			free_image(orig);
			free_image(sized);
			}
			}

			typedef struct {
			box b;
			float p;
			int class_id;
			int image_index;
			int truth_flag;
			int unique_truth_index;
			box b;
			float p;
			int class_id;
			int image_index;
			int truth_flag;
			int unique_truth_index;
			} box_prob;

			int detections_comparator(const void pa, const void pb)
			{
			box_prob a = (box_prob )pa;
			box_prob b = (box_prob )pb;
			float diff = a.p - b.p;
			if (diff < 0) return 1;
			else if (diff > 0) return -1;
			return 0;
			box_prob a = (box_prob )pa;
			box_prob b = (box_prob )pb;
			float diff = a.p - b.p;
			if (diff < 0) return 1;
			else if (diff > 0) return -1;
			return 0;
			}

			void validate_detector_map(char datacfg, char cfgfile, char *weightfile, float thresh_calc_avg_iou)
			{
			int j;
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.txt");
			char *difficult_valid_images = option_find_str(options, "difficult", NULL);
			char *name_list = option_find_str(options, "names", "data/names.list");
			char **names = get_labels(name_list);
			char *mapf = option_find_str(options, "map", 0);
			int *map = 0;
			if (mapf) map = read_map(mapf);
			int j;
			list *options = read_data_cfg(datacfg);
			char *valid_images = option_find_str(options, "valid", "data/train.txt");
			char *difficult_valid_images = option_find_str(options, "difficult", NULL);
			char *name_list = option_find_str(options, "names", "data/names.list");
			char **names = get_labels(name_list);
			char *mapf = option_find_str(options, "map", 0);
			int *map = 0;
			if (mapf) map = read_map(mapf);
			FILE* reinforcement_fd = NULL;

			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fuse_conv_batchnorm(net);
			srand(time(0));
			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			if (weightfile) {
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fuse_conv_batchnorm(net);
			calculate_binary_weights(net);
			srand(time(0));

			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);
			list *plist = get_paths(valid_images);
			char paths = (char )list_to_array(plist);

			char **paths_dif = NULL;
			if (difficult_valid_images) {
			list *plist_dif = get_paths(difficult_valid_images);
			paths_dif = (char **)list_to_array(plist_dif);
			}


			layer l = net.layers[net.n - 1];
			int classes = l.classes;

			int m = plist->size;
			int i = 0;
			int t;

			const float thresh = .005;
			const float nms = .45;
			const float iou_thresh = 0.5;

			int nthreads = 4;
			image *val = calloc(nthreads, sizeof(image));
			image *val_resized = calloc(nthreads, sizeof(image));
			image *buf = calloc(nthreads, sizeof(image));
			image *buf_resized = calloc(nthreads, sizeof(image));
			pthread_t *thr = calloc(nthreads, sizeof(pthread_t));

			load_args args = { 0 };
			args.w = net.w;
			args.h = net.h;
			args.type = IMAGE_DATA;
			//args.type = LETTERBOX_DATA;

			//const float thresh_calc_avg_iou = 0.24;
			float avg_iou = 0;
			int tp_for_thresh = 0;
			int fp_for_thresh = 0;

			box_prob *detections = calloc(1, sizeof(box_prob));
			int detections_count = 0;
			int unique_truth_count = 0;

			int *truth_classes_count = calloc(classes, sizeof(int));

			for (t = 0; t < nthreads; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			time_t start = time(0);
			for (i = nthreads; i < m + nthreads; i += nthreads) {
			fprintf(stderr, "%d\n", i);
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			pthread_join(thr[t], 0);
			val[t] = buf[t];
			val_resized[t] = buf_resized[t];
			}
			for (t = 0; t < nthreads && i + t < m; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			const int image_index = i + t - nthreads;
			char *path = paths[image_index];
			char *id = basecfg(path);
			float *X = val_resized[t].data;
			network_predict(net, X);

			int nboxes = 0;
			int letterbox = (args.type == LETTERBOX_DATA);
			float hier_thresh = 0;
			detection *dets = get_network_boxes(&net, 1, 1, thresh, hier_thresh, 0, 0, &nboxes, letterbox);
			//detection *dets = get_network_boxes(&net, val[t].w, val[t].h, thresh, hier_thresh, 0, 1, &nboxes, letterbox); // for letterbox=1
			if (nms) do_nms_sort(dets, nboxes, l.classes, nms);

			char labelpath[4096];
			find_replace(path, "images", "labels", labelpath);
			find_replace(labelpath, "JPEGImages", "labels", labelpath);
			find_replace(labelpath, ".jpg", ".txt", labelpath);
			find_replace(labelpath, ".png", ".txt", labelpath);
			find_replace(labelpath, ".bmp", ".txt", labelpath);
			find_replace(labelpath, ".JPG", ".txt", labelpath);
			find_replace(labelpath, ".JPEG", ".txt", labelpath);
			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			int i, j;
			for (j = 0; j < num_labels; ++j) {
			truth_classes_count[truth[j].id]++;
			}

			// difficult
			box_label *truth_dif = NULL;
			int num_labels_dif = 0;
			if (paths_dif)
			{
			char *path_dif = paths_dif[image_index];

			char labelpath_dif[4096];
			find_replace(path_dif, "images", "labels", labelpath_dif);
			find_replace(labelpath_dif, "JPEGImages", "labels", labelpath_dif);
			find_replace(labelpath_dif, ".jpg", ".txt", labelpath_dif);
			find_replace(labelpath_dif, ".JPEG", ".txt", labelpath_dif);
			find_replace(labelpath_dif, ".png", ".txt", labelpath_dif);
			truth_dif = read_boxes(labelpath_dif, &num_labels_dif);
			}

			for (i = 0; i < nboxes; ++i) {

			int class_id;
			for (class_id = 0; class_id < classes; ++class_id) {
			float prob = dets[i].prob[class_id];
			if (prob > 0) {
			detections_count++;
			detections = realloc(detections, detections_count * sizeof(box_prob));
			detections[detections_count - 1].b = dets[i].bbox;
			detections[detections_count - 1].p = prob;
			detections[detections_count - 1].image_index = image_index;
			detections[detections_count - 1].class_id = class_id;
			detections[detections_count - 1].truth_flag = 0;
			detections[detections_count - 1].unique_truth_index = -1;

			int truth_index = -1;
			float max_iou = 0;
			for (j = 0; j < num_labels; ++j)
			{
			box t = { truth[j].x, truth[j].y, truth[j].w, truth[j].h };
			//printf(" IoU = %f, prob = %f, class_id = %d, truth[j].id = %d \n",
			// box_iou(dets[i].bbox, t), prob, class_id, truth[j].id);
			float current_iou = box_iou(dets[i].bbox, t);
			if (current_iou > iou_thresh && class_id == truth[j].id) {
			if (current_iou > max_iou) {
			max_iou = current_iou;
			truth_index = unique_truth_count + j;
			}
			}
			}

			// best IoU
			if (truth_index > -1) {
			detections[detections_count - 1].truth_flag = 1;
			detections[detections_count - 1].unique_truth_index = truth_index;
			}
			else {
			// if object is difficult then remove detection
			for (j = 0; j < num_labels_dif; ++j) {
			box t = { truth_dif[j].x, truth_dif[j].y, truth_dif[j].w, truth_dif[j].h };
			float current_iou = box_iou(dets[i].bbox, t);
			if (current_iou > iou_thresh && class_id == truth_dif[j].id) {
			--detections_count;
			break;
			}
			}
			}

			// calc avg IoU, true-positives, false-positives for required Threshold
			if (prob > thresh_calc_avg_iou) {
			if (truth_index > -1) {
			avg_iou += max_iou;
			++tp_for_thresh;
			}
			else
			fp_for_thresh++;
			}
			}
			}
			}

			unique_truth_count += num_labels;

			free_detections(dets, nboxes);
			free(id);
			free_image(val[t]);
			free_image(val_resized[t]);
			}
			}

			avg_iou = avg_iou / (tp_for_thresh + fp_for_thresh);


			// SORT(detections)
			qsort(detections, detections_count, sizeof(box_prob), detections_comparator);

			typedef struct {
			double precision;
			double recall;
			int tp, fp, fn;
			} pr_t;

			// for PR-curve
			pr_t *pr = calloc(classes, sizeof(pr_t));
			for (i = 0; i < classes; ++i) {
			pr[i] = calloc(detections_count, sizeof(pr_t));
			}
			printf("detections_count = %d, unique_truth_count = %d \n", detections_count, unique_truth_count);
			char **paths_dif = NULL;
			if (difficult_valid_images) {
			list *plist_dif = get_paths(difficult_valid_images);
			paths_dif = (char **)list_to_array(plist_dif);
			}


			int *truth_flags = calloc(unique_truth_count, sizeof(int));
			layer l = net.layers[net.n - 1];
			int classes = l.classes;

			int rank;
			for (rank = 0; rank < detections_count; ++rank) {
			if(rank % 100 == 0)
			printf(" rank = %d of ranks = %d \r", rank, detections_count);
			int m = plist->size;
			int i = 0;
			int t;

			if (rank > 0) {
			int class_id;
			for (class_id = 0; class_id < classes; ++class_id) {
			pr[class_id][rank].tp = pr[class_id][rank - 1].tp;
			pr[class_id][rank].fp = pr[class_id][rank - 1].fp;
			}
			}
			const float thresh = .005;
			const float nms = .45;
			const float iou_thresh = 0.5;

			box_prob d = detections[rank];
			// if (detected && isn't detected before)
			if (d.truth_flag == 1) {
			if (truth_flags[d.unique_truth_index] == 0)
			{
			truth_flags[d.unique_truth_index] = 1;
			pr[d.class_id][rank].tp++; // true-positive
			}
			}
			else {
			pr[d.class_id][rank].fp++; // false-positive
			}
			int nthreads = 4;
			image *val = calloc(nthreads, sizeof(image));
			image *val_resized = calloc(nthreads, sizeof(image));
			image *buf = calloc(nthreads, sizeof(image));
			image *buf_resized = calloc(nthreads, sizeof(image));
			pthread_t *thr = calloc(nthreads, sizeof(pthread_t));

			for (i = 0; i < classes; ++i)
			{
			const int tp = pr[i][rank].tp;
			const int fp = pr[i][rank].fp;
			const int fn = truth_classes_count[i] - tp; // false-negative = objects - true-positive
			pr[i][rank].fn = fn;
			load_args args = { 0 };
			args.w = net.w;
			args.h = net.h;
			args.c = net.c;
			args.type = IMAGE_DATA;
			//args.type = LETTERBOX_DATA;

			if ((tp + fp) > 0) pr[i][rank].precision = (double)tp / (double)(tp + fp);
			else pr[i][rank].precision = 0;
			//const float thresh_calc_avg_iou = 0.24;
			float avg_iou = 0;
			int tp_for_thresh = 0;
			int fp_for_thresh = 0;

			if ((tp + fn) > 0) pr[i][rank].recall = (double)tp / (double)(tp + fn);
			else pr[i][rank].recall = 0;
			}
			}
			box_prob *detections = calloc(1, sizeof(box_prob));
			int detections_count = 0;
			int unique_truth_count = 0;

			free(truth_flags);


			double mean_average_precision = 0;
			int *truth_classes_count = calloc(classes, sizeof(int));

			for (i = 0; i < classes; ++i) {
			double avg_precision = 0;
			int point;
			for (point = 0; point < 11; ++point) {
			double cur_recall = point * 0.1;
			double cur_precision = 0;
			for (rank = 0; rank < detections_count; ++rank)
			{
			if (pr[i][rank].recall >= cur_recall) { // > or >=
			if (pr[i][rank].precision > cur_precision) {
			cur_precision = pr[i][rank].precision;
			}
			}
			}
			//printf("class_id = %d, point = %d, cur_recall = %.4f, cur_precision = %.4f \n", i, point, cur_recall, cur_precision);
			for (t = 0; t < nthreads; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			time_t start = time(0);
			for (i = nthreads; i < m + nthreads; i += nthreads) {
			fprintf(stderr, "%d\n", i);
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			pthread_join(thr[t], 0);
			val[t] = buf[t];
			val_resized[t] = buf_resized[t];
			}
			for (t = 0; t < nthreads && i + t < m; ++t) {
			args.path = paths[i + t];
			args.im = &buf[t];
			args.resized = &buf_resized[t];
			thr[t] = load_data_in_thread(args);
			}
			for (t = 0; t < nthreads && i + t - nthreads < m; ++t) {
			const int image_index = i + t - nthreads;
			char *path = paths[image_index];
			char *id = basecfg(path);
			float *X = val_resized[t].data;
			network_predict(net, X);

			avg_precision += cur_precision;
			}
			avg_precision = avg_precision / 11;
			printf("class_id = %d, name = %s, \t ap = %2.2f %% \n", i, names[i], avg_precision*100);
			mean_average_precision += avg_precision;
			}

			const float cur_precision = (float)tp_for_thresh / ((float)tp_for_thresh + (float)fp_for_thresh);
			const float cur_recall = (float)tp_for_thresh / ((float)tp_for_thresh + (float)(unique_truth_count - tp_for_thresh));
			const float f1_score = 2.F * cur_precision * cur_recall / (cur_precision + cur_recall);
			printf(" for thresh = %1.2f, precision = %1.2f, recall = %1.2f, F1-score = %1.2f \n",
			thresh_calc_avg_iou, cur_precision, cur_recall, f1_score);
			int nboxes = 0;
			int letterbox = (args.type == LETTERBOX_DATA);
			float hier_thresh = 0;
			detection *dets = get_network_boxes(&net, 1, 1, thresh, hier_thresh, 0, 0, &nboxes, letterbox);
			//detection *dets = get_network_boxes(&net, val[t].w, val[t].h, thresh, hier_thresh, 0, 1, &nboxes, letterbox); // for letterbox=1
			if (nms) do_nms_sort(dets, nboxes, l.classes, nms);

			printf(" for thresh = %0.2f, TP = %d, FP = %d, FN = %d, average IoU = %2.2f %% \n",
			thresh_calc_avg_iou, tp_for_thresh, fp_for_thresh, unique_truth_count - tp_for_thresh, avg_iou * 100);
			char labelpath[4096];
			replace_image_to_label(path, labelpath);
			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			int i, j;
			for (j = 0; j < num_labels; ++j) {
			truth_classes_count[truth[j].id]++;
			}

			mean_average_precision = mean_average_precision / classes;
			printf("\n mean average precision (mAP) = %f, or %2.2f %% \n", mean_average_precision, mean_average_precision*100);
			// difficult
			box_label *truth_dif = NULL;
			int num_labels_dif = 0;
			if (paths_dif)
			{
			char *path_dif = paths_dif[image_index];

			char labelpath_dif[4096];
			replace_image_to_label(path_dif, labelpath_dif);

			truth_dif = read_boxes(labelpath_dif, &num_labels_dif);
			}

			const int checkpoint_detections_count = detections_count;

			for (i = 0; i < nboxes; ++i) {

			int class_id;
			for (class_id = 0; class_id < classes; ++class_id) {
			float prob = dets[i].prob[class_id];
			if (prob > 0) {
			detections_count++;
			detections = realloc(detections, detections_count * sizeof(box_prob));
			detections[detections_count - 1].b = dets[i].bbox;
			detections[detections_count - 1].p = prob;
			detections[detections_count - 1].image_index = image_index;
			detections[detections_count - 1].class_id = class_id;
			detections[detections_count - 1].truth_flag = 0;
			detections[detections_count - 1].unique_truth_index = -1;

			int truth_index = -1;
			float max_iou = 0;
			for (j = 0; j < num_labels; ++j)
			{
			box t = { truth[j].x, truth[j].y, truth[j].w, truth[j].h };
			//printf(" IoU = %f, prob = %f, class_id = %d, truth[j].id = %d \n",
			// box_iou(dets[i].bbox, t), prob, class_id, truth[j].id);
			float current_iou = box_iou(dets[i].bbox, t);
			if (current_iou > iou_thresh && class_id == truth[j].id) {
			if (current_iou > max_iou) {
			max_iou = current_iou;
			truth_index = unique_truth_count + j;
			}
			}
			}

			// best IoU
			if (truth_index > -1) {
			detections[detections_count - 1].truth_flag = 1;
			detections[detections_count - 1].unique_truth_index = truth_index;
			}
			else {
			// if object is difficult then remove detection
			for (j = 0; j < num_labels_dif; ++j) {
			box t = { truth_dif[j].x, truth_dif[j].y, truth_dif[j].w, truth_dif[j].h };
			float current_iou = box_iou(dets[i].bbox, t);
			if (current_iou > iou_thresh && class_id == truth_dif[j].id) {
			--detections_count;
			break;
			}
			}
			}

			// calc avg IoU, true-positives, false-positives for required Threshold
			if (prob > thresh_calc_avg_iou) {
			int z, found = 0;
			for (z = checkpoint_detections_count; z < detections_count-1; ++z)
			if (detections[z].unique_truth_index == truth_index) {
			found = 1; break;
			}

			if(truth_index > -1 && found == 0) {
			avg_iou += max_iou;
			++tp_for_thresh;
			}
			else
			fp_for_thresh++;
			}
			}
			}
			}

			unique_truth_count += num_labels;

			//static int previous_errors = 0;
			//int total_errors = fp_for_thresh + (unique_truth_count - tp_for_thresh);
			//int errors_in_this_image = total_errors - previous_errors;
			//previous_errors = total_errors;
			//if(reinforcement_fd == NULL) reinforcement_fd = fopen("reinforcement.txt", "wb");
			//char buff[1000];
			//sprintf(buff, "%s\n", path);
			//if(errors_in_this_image > 0) fwrite(buff, sizeof(char), strlen(buff), reinforcement_fd);

			free_detections(dets, nboxes);
			free(id);
			free_image(val[t]);
			free_image(val_resized[t]);
			}
			}

			if((tp_for_thresh + fp_for_thresh) > 0)
			avg_iou = avg_iou / (tp_for_thresh + fp_for_thresh);


			for (i = 0; i < classes; ++i) {
			free(pr[i]);
			}
			free(pr);
			free(detections);
			free(truth_classes_count);
			// SORT(detections)
			qsort(detections, detections_count, sizeof(box_prob), detections_comparator);

			fprintf(stderr, "Total Detection Time: %f Seconds\n", (double)(time(0) - start));
			typedef struct {
			double precision;
			double recall;
			int tp, fp, fn;
			} pr_t;

			// for PR-curve
			pr_t *pr = calloc(classes, sizeof(pr_t));
			for (i = 0; i < classes; ++i) {
			pr[i] = calloc(detections_count, sizeof(pr_t));
			}
			printf("detections_count = %d, unique_truth_count = %d \n", detections_count, unique_truth_count);


			int *truth_flags = calloc(unique_truth_count, sizeof(int));

			int rank;
			for (rank = 0; rank < detections_count; ++rank) {
			if(rank % 100 == 0)
			printf(" rank = %d of ranks = %d \r", rank, detections_count);

			if (rank > 0) {
			int class_id;
			for (class_id = 0; class_id < classes; ++class_id) {
			pr[class_id][rank].tp = pr[class_id][rank - 1].tp;
			pr[class_id][rank].fp = pr[class_id][rank - 1].fp;
			}
			}

			box_prob d = detections[rank];
			// if (detected && isn't detected before)
			if (d.truth_flag == 1) {
			if (truth_flags[d.unique_truth_index] == 0)
			{
			truth_flags[d.unique_truth_index] = 1;
			pr[d.class_id][rank].tp++; // true-positive
			}
			}
			else {
			pr[d.class_id][rank].fp++; // false-positive
			}

			for (i = 0; i < classes; ++i)
			{
			const int tp = pr[i][rank].tp;
			const int fp = pr[i][rank].fp;
			const int fn = truth_classes_count[i] - tp; // false-negative = objects - true-positive
			pr[i][rank].fn = fn;

			if ((tp + fp) > 0) pr[i][rank].precision = (double)tp / (double)(tp + fp);
			else pr[i][rank].precision = 0;

			if ((tp + fn) > 0) pr[i][rank].recall = (double)tp / (double)(tp + fn);
			else pr[i][rank].recall = 0;
			}
			}

			free(truth_flags);


			double mean_average_precision = 0;

			for (i = 0; i < classes; ++i) {
			double avg_precision = 0;
			int point;
			for (point = 0; point < 11; ++point) {
			double cur_recall = point * 0.1;
			double cur_precision = 0;
			for (rank = 0; rank < detections_count; ++rank)
			{
			if (pr[i][rank].recall >= cur_recall) { // > or >=
			if (pr[i][rank].precision > cur_precision) {
			cur_precision = pr[i][rank].precision;
			}
			}
			}
			//printf("class_id = %d, point = %d, cur_recall = %.4f, cur_precision = %.4f \n", i, point, cur_recall, cur_precision);

			avg_precision += cur_precision;
			}
			avg_precision = avg_precision / 11;
			printf("class_id = %d, name = %s, \t ap = %2.2f %% \n", i, names[i], avg_precision*100);
			mean_average_precision += avg_precision;
			}

			const float cur_precision = (float)tp_for_thresh / ((float)tp_for_thresh + (float)fp_for_thresh);
			const float cur_recall = (float)tp_for_thresh / ((float)tp_for_thresh + (float)(unique_truth_count - tp_for_thresh));
			const float f1_score = 2.F * cur_precision * cur_recall / (cur_precision + cur_recall);
			printf(" for thresh = %1.2f, precision = %1.2f, recall = %1.2f, F1-score = %1.2f \n",
			thresh_calc_avg_iou, cur_precision, cur_recall, f1_score);

			printf(" for thresh = %0.2f, TP = %d, FP = %d, FN = %d, average IoU = %2.2f %% \n",
			thresh_calc_avg_iou, tp_for_thresh, fp_for_thresh, unique_truth_count - tp_for_thresh, avg_iou * 100);

			mean_average_precision = mean_average_precision / classes;
			printf("\n mean average precision (mAP) = %f, or %2.2f %% \n", mean_average_precision, mean_average_precision*100);


			for (i = 0; i < classes; ++i) {
			free(pr[i]);
			}
			free(pr);
			free(detections);
			free(truth_classes_count);

			fprintf(stderr, "Total Detection Time: %f Seconds\n", (double)(time(0) - start));
			if (reinforcement_fd != NULL) fclose(reinforcement_fd);
			}

			#ifdef OPENCV
			typedef struct {
			float w, h;
			float w, h;
			} anchors_t;

			int anchors_comparator(const void pa, const void pb)
			{
			anchors_t a = (anchors_t )pa;
			anchors_t b = (anchors_t )pb;
			float diff = b.wb.h - a.wa.h;
			if (diff < 0) return 1;
			else if (diff > 0) return -1;
			return 0;
			anchors_t a = (anchors_t )pa;
			anchors_t b = (anchors_t )pb;
			float diff = b.wb.h - a.wa.h;
			if (diff < 0) return 1;
			else if (diff > 0) return -1;
			return 0;
			}

			void calc_anchors(char *datacfg, int num_of_clusters, int width, int height, int show)
			{
			printf("\n num_of_clusters = %d, width = %d, height = %d \n", num_of_clusters, width, height);
			printf("\n num_of_clusters = %d, width = %d, height = %d \n", num_of_clusters, width, height);
			if (width < 0 \|\| height < 0) {
			printf("Usage: darknet detector calc_anchors data/voc.data -num_of_clusters 9 -width 416 -height 416 \n");
			printf("Error: set width and height \n");
			return;
			}

			//float pointsdata[] = { 1,1, 2,2, 6,6, 5,5, 10,10 };
			float *rel_width_height_array = calloc(1000, sizeof(float));
			//float pointsdata[] = { 1,1, 2,2, 6,6, 5,5, 10,10 };
			float *rel_width_height_array = calloc(1000, sizeof(float));

			list *options = read_data_cfg(datacfg);
			char *train_images = option_find_str(options, "train", "data/train.list");
			list *plist = get_paths(train_images);
			int number_of_images = plist->size;
			char paths = (char )list_to_array(plist);
			list *options = read_data_cfg(datacfg);
			char *train_images = option_find_str(options, "train", "data/train.list");
			list *plist = get_paths(train_images);
			int number_of_images = plist->size;
			char paths = (char )list_to_array(plist);

			int number_of_boxes = 0;
			printf(" read labels from %d images \n", number_of_images);
			int number_of_boxes = 0;
			printf(" read labels from %d images \n", number_of_images);

			int i, j;
			for (i = 0; i < number_of_images; ++i) {
			char *path = paths[i];
			char labelpath[4096];
			find_replace(path, "images", "labels", labelpath);
			find_replace(labelpath, "JPEGImages", "labels", labelpath);
			find_replace(labelpath, ".jpg", ".txt", labelpath);
			find_replace(labelpath, ".png", ".txt", labelpath);
			find_replace(labelpath, ".bmp", ".txt", labelpath);
			find_replace(labelpath, ".JPG", ".txt", labelpath);
			find_replace(labelpath, ".JPEG", ".txt", labelpath);
			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			//printf(" new path: %s \n", labelpath);
			for (j = 0; j < num_labels; ++j)
			{
			number_of_boxes++;
			rel_width_height_array = realloc(rel_width_height_array, 2 * number_of_boxes * sizeof(float));
			rel_width_height_array[number_of_boxes * 2 - 2] = truth[j].w * width;
			rel_width_height_array[number_of_boxes * 2 - 1] = truth[j].h * height;
			printf("\r loaded \t image: %d \t box: %d", i+1, number_of_boxes);
			}
			}
			printf("\n all loaded. \n");
			int i, j;
			for (i = 0; i < number_of_images; ++i) {
			char *path = paths[i];
			char labelpath[4096];
			replace_image_to_label(path, labelpath);

			CvMat* points = cvCreateMat(number_of_boxes, 2, CV_32FC1);
			CvMat* centers = cvCreateMat(num_of_clusters, 2, CV_32FC1);
			CvMat* labels = cvCreateMat(number_of_boxes, 1, CV_32SC1);
			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			//printf(" new path: %s \n", labelpath);
			char buff[1024];
			for (j = 0; j < num_labels; ++j)
			{
			if (truth[j].x > 1 \|\| truth[j].x <= 0 \|\| truth[j].y > 1 \|\| truth[j].y <= 0 \|\|
			truth[j].w > 1 \|\| truth[j].w <= 0 \|\| truth[j].h > 1 \|\| truth[j].h <= 0)
			{
			printf("\n\nWrong label: %s - j = %d, x = %f, y = %f, width = %f, height = %f \n",
			labelpath, j, truth[j].x, truth[j].y, truth[j].w, truth[j].h);
			sprintf(buff, "echo \"Wrong label: %s - j = %d, x = %f, y = %f, width = %f, height = %f\" >> bad_label.list",
			labelpath, j, truth[j].x, truth[j].y, truth[j].w, truth[j].h);
			system(buff);
			}
			number_of_boxes++;
			rel_width_height_array = realloc(rel_width_height_array, 2 * number_of_boxes * sizeof(float));
			rel_width_height_array[number_of_boxes * 2 - 2] = truth[j].w * width;
			rel_width_height_array[number_of_boxes * 2 - 1] = truth[j].h * height;
			printf("\r loaded \t image: %d \t box: %d", i+1, number_of_boxes);
			}
			}
			printf("\n all loaded. \n");

			for (i = 0; i < number_of_boxes; ++i) {
			points->data.fl[i * 2] = rel_width_height_array[i * 2];
			points->data.fl[i * 2 + 1] = rel_width_height_array[i * 2 + 1];
			//cvSet1D(points, i * 2, cvScalar(rel_width_height_array[i * 2], 0, 0, 0));
			//cvSet1D(points, i * 2 + 1, cvScalar(rel_width_height_array[i * 2 + 1], 0, 0, 0));
			}
			CvMat* points = cvCreateMat(number_of_boxes, 2, CV_32FC1);
			CvMat* centers = cvCreateMat(num_of_clusters, 2, CV_32FC1);
			CvMat* labels = cvCreateMat(number_of_boxes, 1, CV_32SC1);

			for (i = 0; i < number_of_boxes; ++i) {
			points->data.fl[i * 2] = rel_width_height_array[i * 2];
			points->data.fl[i * 2 + 1] = rel_width_height_array[i * 2 + 1];
			//cvSet1D(points, i * 2, cvScalar(rel_width_height_array[i * 2], 0, 0, 0));
			//cvSet1D(points, i * 2 + 1, cvScalar(rel_width_height_array[i * 2 + 1], 0, 0, 0));
			}


			const int attemps = 10;
			double compactness;
			const int attemps = 10;
			double compactness;

			enum {
			KMEANS_RANDOM_CENTERS = 0,
			KMEANS_USE_INITIAL_LABELS = 1,
			KMEANS_PP_CENTERS = 2
			};

			printf("\n calculating k-means++ ...");
			// Should be used: distance(box, centroid) = 1 - IoU(box, centroid)
			cvKMeans2(points, num_of_clusters, labels,
			cvTermCriteria(CV_TERMCRIT_EPS+CV_TERMCRIT_ITER, 10000, 0), attemps,
			0, KMEANS_PP_CENTERS,
			centers, &compactness);
			enum {
			KMEANS_RANDOM_CENTERS = 0,
			KMEANS_USE_INITIAL_LABELS = 1,
			KMEANS_PP_CENTERS = 2
			};

			// sort anchors
			qsort(centers->data.fl, num_of_clusters, 2*sizeof(float), anchors_comparator);
			printf("\n calculating k-means++ ...");
			// Should be used: distance(box, centroid) = 1 - IoU(box, centroid)
			cvKMeans2(points, num_of_clusters, labels,
			cvTermCriteria(CV_TERMCRIT_EPS+CV_TERMCRIT_ITER, 10000, 0), attemps,
			0, KMEANS_PP_CENTERS,
			centers, &compactness);

			//orig 2.0 anchors = 1.08,1.19, 3.42,4.41, 6.63,11.38, 9.42,5.11, 16.62,10.52
			//float orig_anch[] = { 1.08,1.19, 3.42,4.41, 6.63,11.38, 9.42,5.11, 16.62,10.52 };
			// worse than ours (even for 19x19 final size - for input size 608x608)
			// sort anchors
			qsort(centers->data.fl, num_of_clusters, 2*sizeof(float), anchors_comparator);

			//orig anchors = 1.3221,1.73145, 3.19275,4.00944, 5.05587,8.09892, 9.47112,4.84053, 11.2364,10.0071
			//float orig_anch[] = { 1.3221,1.73145, 3.19275,4.00944, 5.05587,8.09892, 9.47112,4.84053, 11.2364,10.0071 };
			// orig (IoU=59.90%) better than ours (59.75%)
			//orig 2.0 anchors = 1.08,1.19, 3.42,4.41, 6.63,11.38, 9.42,5.11, 16.62,10.52
			//float orig_anch[] = { 1.08,1.19, 3.42,4.41, 6.63,11.38, 9.42,5.11, 16.62,10.52 };
			// worse than ours (even for 19x19 final size - for input size 608x608)

			//gen_anchors.py = 1.19, 1.99, 2.79, 4.60, 4.53, 8.92, 8.06, 5.29, 10.32, 10.66
			//float orig_anch[] = { 1.19, 1.99, 2.79, 4.60, 4.53, 8.92, 8.06, 5.29, 10.32, 10.66 };
			//orig anchors = 1.3221,1.73145, 3.19275,4.00944, 5.05587,8.09892, 9.47112,4.84053, 11.2364,10.0071
			//float orig_anch[] = { 1.3221,1.73145, 3.19275,4.00944, 5.05587,8.09892, 9.47112,4.84053, 11.2364,10.0071 };
			// orig (IoU=59.90%) better than ours (59.75%)

			// ours: anchors = 9.3813,6.0095, 3.3999,5.3505, 10.9476,11.1992, 5.0161,9.8314, 1.5003,2.1595
			//float orig_anch[] = { 9.3813,6.0095, 3.3999,5.3505, 10.9476,11.1992, 5.0161,9.8314, 1.5003,2.1595 };
			//for (i = 0; i < num_of_clusters * 2; ++i) centers->data.fl[i] = orig_anch[i];

			//for (i = 0; i < number_of_boxes; ++i)
			// printf("%2.2f,%2.2f, ", points->data.fl[i * 2], points->data.fl[i * 2 + 1]);
			//gen_anchors.py = 1.19, 1.99, 2.79, 4.60, 4.53, 8.92, 8.06, 5.29, 10.32, 10.66
			//float orig_anch[] = { 1.19, 1.99, 2.79, 4.60, 4.53, 8.92, 8.06, 5.29, 10.32, 10.66 };

			float avg_iou = 0;
			for (i = 0; i < number_of_boxes; ++i) {
			float box_w = points->data.fl[i * 2];
			float box_h = points->data.fl[i * 2 + 1];
			//int cluster_idx = labels->data.i[i];
			int cluster_idx = 0;
			float min_dist = FLT_MAX;
			for (j = 0; j < num_of_clusters; ++j) {
			float anchor_w = centers->data.fl[j * 2];
			float anchor_h = centers->data.fl[j * 2 + 1];
			float w_diff = anchor_w - box_w;
			float h_diff = anchor_h - box_h;
			float distance = sqrt(w_diffw_diff + h_diffh_diff);
			if (distance < min_dist) min_dist = distance, cluster_idx = j;
			}

			float anchor_w = centers->data.fl[cluster_idx * 2];
			float anchor_h = centers->data.fl[cluster_idx * 2 + 1];
			float min_w = (box_w < anchor_w) ? box_w : anchor_w;
			float min_h = (box_h < anchor_h) ? box_h : anchor_h;
			float box_intersect = min_w*min_h;
			float box_union = box_wbox_h + anchor_wanchor_h - box_intersect;
			float iou = box_intersect / box_union;
			if (iou > 1 \|\| iou < 0) {
			printf(" i = %d, box_w = %d, box_h = %d, anchor_w = %d, anchor_h = %d, iou = %f \n",
			i, box_w, box_h, anchor_w, anchor_h, iou);
			}
			else avg_iou += iou;
			}
			avg_iou = 100 * avg_iou / number_of_boxes;
			printf("\n avg IoU = %2.2f %% \n", avg_iou);
			// ours: anchors = 9.3813,6.0095, 3.3999,5.3505, 10.9476,11.1992, 5.0161,9.8314, 1.5003,2.1595
			//float orig_anch[] = { 9.3813,6.0095, 3.3999,5.3505, 10.9476,11.1992, 5.0161,9.8314, 1.5003,2.1595 };
			//for (i = 0; i < num_of_clusters * 2; ++i) centers->data.fl[i] = orig_anch[i];

			char buff[1024];
			FILE* fw = fopen("anchors.txt", "wb");
			printf("\nSaving anchors to the file: anchors.txt \n");
			printf("anchors = ");
			for (i = 0; i < num_of_clusters; ++i) {
			sprintf(buff, "%2.4f,%2.4f", centers->data.fl[i * 2], centers->data.fl[i * 2 + 1]);
			printf("%s", buff);
			fwrite(buff, sizeof(char), strlen(buff), fw);
			if (i + 1 < num_of_clusters) {
			fwrite(", ", sizeof(char), 2, fw);
			printf(", ");
			}
			}
			printf("\n");
			fclose(fw);
			//for (i = 0; i < number_of_boxes; ++i)
			// printf("%2.2f,%2.2f, ", points->data.fl[i * 2], points->data.fl[i * 2 + 1]);

			if (show) {
			size_t img_size = 700;
			IplImage* img = cvCreateImage(cvSize(img_size, img_size), 8, 3);
			cvZero(img);
			for (j = 0; j < num_of_clusters; ++j) {
			CvPoint pt1, pt2;
			pt1.x = pt1.y = 0;
			pt2.x = centers->data.fl[j * 2] * img_size / width;
			pt2.y = centers->data.fl[j * 2 + 1] * img_size / height;
			cvRectangle(img, pt1, pt2, CV_RGB(255, 255, 255), 1, 8, 0);
			}
			printf("\n");
			float avg_iou = 0;
			for (i = 0; i < number_of_boxes; ++i) {
			float box_w = points->data.fl[i * 2];
			float box_h = points->data.fl[i * 2 + 1];
			//int cluster_idx = labels->data.i[i];
			int cluster_idx = 0;
			float min_dist = FLT_MAX;
			for (j = 0; j < num_of_clusters; ++j) {
			float anchor_w = centers->data.fl[j * 2];
			float anchor_h = centers->data.fl[j * 2 + 1];
			float w_diff = anchor_w - box_w;
			float h_diff = anchor_h - box_h;
			float distance = sqrt(w_diffw_diff + h_diffh_diff);
			if (distance < min_dist) min_dist = distance, cluster_idx = j;
			}

			for (i = 0; i < number_of_boxes; ++i) {
			CvPoint pt;
			pt.x = points->data.fl[i * 2] * img_size / width;
			pt.y = points->data.fl[i * 2 + 1] * img_size / height;
			int cluster_idx = labels->data.i[i];
			int red_id = (cluster_idx * (uint64_t)123 + 55) % 255;
			int green_id = (cluster_idx * (uint64_t)321 + 33) % 255;
			int blue_id = (cluster_idx * (uint64_t)11 + 99) % 255;
			cvCircle(img, pt, 1, CV_RGB(red_id, green_id, blue_id), CV_FILLED, 8, 0);
			//if(pt.x > img_size \|\| pt.y > img_size) printf("\n pt.x = %d, pt.y = %d \n", pt.x, pt.y);
			}
			cvShowImage("clusters", img);
			cvWaitKey(0);
			cvReleaseImage(&img);
			cvDestroyAllWindows();
			}
			float anchor_w = centers->data.fl[cluster_idx * 2];
			float anchor_h = centers->data.fl[cluster_idx * 2 + 1];
			float min_w = (box_w < anchor_w) ? box_w : anchor_w;
			float min_h = (box_h < anchor_h) ? box_h : anchor_h;
			float box_intersect = min_w*min_h;
			float box_union = box_wbox_h + anchor_wanchor_h - box_intersect;
			float iou = box_intersect / box_union;
			if (iou > 1 \|\| iou < 0) { // \|\| box_w > width \|\| box_h > height) {
			printf(" Wrong label: i = %d, box_w = %d, box_h = %d, anchor_w = %d, anchor_h = %d, iou = %f \n",
			i, box_w, box_h, anchor_w, anchor_h, iou);
			}
			else avg_iou += iou;
			}
			avg_iou = 100 * avg_iou / number_of_boxes;
			printf("\n avg IoU = %2.2f %% \n", avg_iou);

			free(rel_width_height_array);
			cvReleaseMat(&points);
			cvReleaseMat(&centers);
			cvReleaseMat(&labels);
			char buff[1024];
			FILE* fw = fopen("anchors.txt", "wb");
			printf("\nSaving anchors to the file: anchors.txt \n");
			printf("anchors = ");
			for (i = 0; i < num_of_clusters; ++i) {
			sprintf(buff, "%2.4f,%2.4f", centers->data.fl[i * 2], centers->data.fl[i * 2 + 1]);
			printf("%s", buff);
			fwrite(buff, sizeof(char), strlen(buff), fw);
			if (i + 1 < num_of_clusters) {
			fwrite(", ", sizeof(char), 2, fw);
			printf(", ");
			}
			}
			printf("\n");
			fclose(fw);

			if (show) {
			size_t img_size = 700;
			IplImage* img = cvCreateImage(cvSize(img_size, img_size), 8, 3);
			cvZero(img);
			for (j = 0; j < num_of_clusters; ++j) {
			CvPoint pt1, pt2;
			pt1.x = pt1.y = 0;
			pt2.x = centers->data.fl[j * 2] * img_size / width;
			pt2.y = centers->data.fl[j * 2 + 1] * img_size / height;
			cvRectangle(img, pt1, pt2, CV_RGB(255, 255, 255), 1, 8, 0);
			}

			for (i = 0; i < number_of_boxes; ++i) {
			CvPoint pt;
			pt.x = points->data.fl[i * 2] * img_size / width;
			pt.y = points->data.fl[i * 2 + 1] * img_size / height;
			int cluster_idx = labels->data.i[i];
			int red_id = (cluster_idx * (uint64_t)123 + 55) % 255;
			int green_id = (cluster_idx * (uint64_t)321 + 33) % 255;
			int blue_id = (cluster_idx * (uint64_t)11 + 99) % 255;
			cvCircle(img, pt, 1, CV_RGB(red_id, green_id, blue_id), CV_FILLED, 8, 0);
			//if(pt.x > img_size \|\| pt.y > img_size) printf("\n pt.x = %d, pt.y = %d \n", pt.x, pt.y);
			}
			cvShowImage("clusters", img);
			cvWaitKey(0);
			cvReleaseImage(&img);
			cvDestroyAllWindows();
			}

			free(rel_width_height_array);
			cvReleaseMat(&points);
			cvReleaseMat(&centers);
			cvReleaseMat(&labels);
			}
			#else
			void calc_anchors(char *datacfg, int num_of_clusters, int width, int height, int show) {
			printf(" k-means++ can't be used without OpenCV, because there is used cvKMeans2 implementation \n");
			printf(" k-means++ can't be used without OpenCV, because there is used cvKMeans2 implementation \n");
			}
			#endif // OPENCV

			void test_detector(char datacfg, char cfgfile, char weightfile, char filename, float thresh, float hier_thresh, int dont_show)
			void test_detector(char datacfg, char cfgfile, char weightfile, char filename, float thresh,
			float hier_thresh, int dont_show, int ext_output, int save_labels)
			{
			list *options = read_data_cfg(datacfg);
			char *name_list = option_find_str(options, "names", "data/names.list");
			char **names = get_labels(name_list);
			int names_size = 0;
			char **names = get_labels_custom(name_list, &names_size); //get_labels(name_list);

			image **alphabet = load_alphabet();
			network net = parse_network_cfg_custom(cfgfile, 1); // set batch=1
			@@ -1033,17 +1094,24 @@
			load_weights(&net, weightfile);
			}
			//set_batch_network(&net, 1);
			fuse_conv_batchnorm(net);
			fuse_conv_batchnorm(net);
			calculate_binary_weights(net);
			if (net.layers[net.n - 1].classes != names_size) {
			printf(" Error: in the file %s number of names %d that isn't equal to classes=%d in the file %s \n",
			name_list, names_size, net.layers[net.n - 1].classes, cfgfile);
			if(net.layers[net.n - 1].classes > names_size) getchar();
			}
			srand(2222222);
			double time;
			char buff[256];
			char *input = buff;
			int j;
			float nms=.45; // 0.4F
			float nms=.45; // 0.4F
			while(1){
			if(filename){
			strncpy(input, filename, 256);
			if (input[strlen(input) - 1] == 0x0d) input[strlen(input) - 1] = 0;
			if(strlen(input) > 0)
			if (input[strlen(input) - 1] == 0x0d) input[strlen(input) - 1] = 0;
			} else {
			printf("Enter Image Path: ");
			fflush(stdout);
			@@ -1051,10 +1119,10 @@
			if(!input) return;
			strtok(input, "\n");
			}
			image im = load_image_color(input,0,0);
			int letterbox = 0;
			image im = load_image(input,0,0,net.c);
			int letterbox = 0;
			image sized = resize_image(im, net.w, net.h);
			//image sized = letterbox_image(im, net.w, net.h); letterbox = 1;
			//image sized = letterbox_image(im, net.w, net.h); letterbox = 1;
			layer l = net.layers[net.n-1];

			//box boxes = calloc(l.wl.h*l.n, sizeof(box));
			@@ -1063,51 +1131,98 @@

			float *X = sized.data;
			time= what_time_is_it_now();
			//network_predict(net, X);
			network_predict_image(&net, im); letterbox = 1;
			network_predict(net, X);
			//network_predict_image(&net, im); letterbox = 1;
			printf("%s: Predicted in %f seconds.\n", input, (what_time_is_it_now()-time));
			//get_region_boxes(l, 1, 1, thresh, probs, boxes, 0, 0);
			// if (nms) do_nms_sort_v2(boxes, probs, l.wl.hl.n, l.classes, nms);
			//draw_detections(im, l.wl.hl.n, thresh, boxes, probs, names, alphabet, l.classes);
			int nboxes = 0;
			detection *dets = get_network_boxes(&net, im.w, im.h, thresh, hier_thresh, 0, 1, &nboxes, letterbox);
			if (nms) do_nms_sort(dets, nboxes, l.classes, nms);
			draw_detections_v3(im, dets, nboxes, thresh, names, alphabet, l.classes);
			free_detections(dets, nboxes);
			// if (nms) do_nms_sort_v2(boxes, probs, l.wl.hl.n, l.classes, nms);
			//draw_detections(im, l.wl.hl.n, thresh, boxes, probs, names, alphabet, l.classes);
			int nboxes = 0;
			detection *dets = get_network_boxes(&net, im.w, im.h, thresh, hier_thresh, 0, 1, &nboxes, letterbox);
			if (nms) do_nms_sort(dets, nboxes, l.classes, nms);
			draw_detections_v3(im, dets, nboxes, thresh, names, alphabet, l.classes, ext_output);
			save_image(im, "predictions");
			if (!dont_show) {
			show_image(im, "predictions");
			}
			if (!dont_show) {
			show_image(im, "predictions");
			}

			// pseudo labeling concept - fast.ai
			if(save_labels)
			{
			char labelpath[4096];
			replace_image_to_label(input, labelpath);

			FILE* fw = fopen(labelpath, "wb");
			int i;
			for (i = 0; i < nboxes; ++i) {
			char buff[1024];
			int class_id = -1;
			float prob = 0;
			for (j = 0; j < l.classes; ++j) {
			if (dets[i].prob[j] > thresh && dets[i].prob[j] > prob) {
			prob = dets[i].prob[j];
			class_id = j;
			}
			}
			if (class_id >= 0) {
			sprintf(buff, "%d %2.4f %2.4f %2.4f %2.4f\n", class_id, dets[i].bbox.x, dets[i].bbox.y, dets[i].bbox.w, dets[i].bbox.h);
			fwrite(buff, sizeof(char), strlen(buff), fw);
			}
			}
			fclose(fw);
			}

			free_detections(dets, nboxes);
			free_image(im);
			free_image(sized);
			//free(boxes);
			//free_ptrs((void *)probs, l.wl.h*l.n);
			#ifdef OPENCV
			if (!dont_show) {
			cvWaitKey(0);
			cvDestroyAllWindows();
			}
			if (!dont_show) {
			cvWaitKey(0);
			cvDestroyAllWindows();
			}
			#endif
			if (filename) break;
			}

			// free memory
			free_ptrs(names, net.layers[net.n - 1].classes);
			free_list_contents_kvp(options);
			free_list(options);

			int i;
			const int nsize = 8;
			for (j = 0; j < nsize; ++j) {
			for (i = 32; i < 127; ++i) {
			free_image(alphabet[j][i]);
			}
			free(alphabet[j]);
			}
			free(alphabet);

			free_network(net);
			}

			void run_detector(int argc, char **argv)
			{
			int dont_show = find_arg(argc, argv, "-dont_show");
			int show = find_arg(argc, argv, "-show");
			int http_stream_port = find_int_arg(argc, argv, "-http_port", -1);
			char *out_filename = find_char_arg(argc, argv, "-out_filename", 0);
			char *outfile = find_char_arg(argc, argv, "-out", 0);
			int dont_show = find_arg(argc, argv, "-dont_show");
			int show = find_arg(argc, argv, "-show");
			int http_stream_port = find_int_arg(argc, argv, "-http_port", -1);
			char *out_filename = find_char_arg(argc, argv, "-out_filename", 0);
			char *outfile = find_char_arg(argc, argv, "-out", 0);
			char *prefix = find_char_arg(argc, argv, "-prefix", 0);
			float thresh = find_float_arg(argc, argv, "-thresh", .25); // 0.24
			float hier_thresh = find_float_arg(argc, argv, "-hier", .5);
			float thresh = find_float_arg(argc, argv, "-thresh", .25); // 0.24
			float hier_thresh = find_float_arg(argc, argv, "-hier", .5);
			int cam_index = find_int_arg(argc, argv, "-c", 0);
			int frame_skip = find_int_arg(argc, argv, "-s", 0);
			int num_of_clusters = find_int_arg(argc, argv, "-num_of_clusters", 5);
			int width = find_int_arg(argc, argv, "-width", 13);
			int height = find_int_arg(argc, argv, "-height", 13);
			int num_of_clusters = find_int_arg(argc, argv, "-num_of_clusters", 5);
			int width = find_int_arg(argc, argv, "-width", -1);
			int height = find_int_arg(argc, argv, "-height", -1);
			// extended output in test mode (output of rect bound coords)
			// and for recall mode (extended output table-like format with results for best_class fit)
			int ext_output = find_arg(argc, argv, "-ext_output");
			int save_labels = find_arg(argc, argv, "-save_labels");
			if(argc < 4){
			fprintf(stderr, "usage: %s %s [train/test/valid] [cfg] [weights (optional)]\n", argv[0], argv[1]);
			return;
			@@ -1140,24 +1255,29 @@
			char *datacfg = argv[3];
			char *cfg = argv[4];
			char *weights = (argc > 5) ? argv[5] : 0;
			if(weights)
			if (weights[strlen(weights) - 1] == 0x0d) weights[strlen(weights) - 1] = 0;
			if(weights)
			if(strlen(weights) > 0)
			if (weights[strlen(weights) - 1] == 0x0d) weights[strlen(weights) - 1] = 0;
			char *filename = (argc > 6) ? argv[6]: 0;
			if(0==strcmp(argv[2], "test")) test_detector(datacfg, cfg, weights, filename, thresh, hier_thresh, dont_show);
			if(0==strcmp(argv[2], "test")) test_detector(datacfg, cfg, weights, filename, thresh, hier_thresh, dont_show, ext_output, save_labels);
			else if(0==strcmp(argv[2], "train")) train_detector(datacfg, cfg, weights, gpus, ngpus, clear, dont_show);
			else if(0==strcmp(argv[2], "valid")) validate_detector(datacfg, cfg, weights, outfile);
			else if(0==strcmp(argv[2], "recall")) validate_detector_recall(datacfg, cfg, weights);
			else if(0==strcmp(argv[2], "map")) validate_detector_map(datacfg, cfg, weights, thresh);
			else if(0==strcmp(argv[2], "calc_anchors")) calc_anchors(datacfg, num_of_clusters, width, height, show);
			else if(0==strcmp(argv[2], "map")) validate_detector_map(datacfg, cfg, weights, thresh);
			else if(0==strcmp(argv[2], "calc_anchors")) calc_anchors(datacfg, num_of_clusters, width, height, show);
			else if(0==strcmp(argv[2], "demo")) {
			list *options = read_data_cfg(datacfg);
			int classes = option_find_int(options, "classes", 20);
			char *name_list = option_find_str(options, "names", "data/names.list");
			char **names = get_labels(name_list);
			if(filename)
			if (filename[strlen(filename) - 1] == 0x0d) filename[strlen(filename) - 1] = 0;
			if(filename)
			if(strlen(filename) > 0)
			if (filename[strlen(filename) - 1] == 0x0d) filename[strlen(filename) - 1] = 0;
			demo(cfg, weights, thresh, hier_thresh, cam_index, filename, names, classes, frame_skip, prefix, out_filename,
			http_stream_port, dont_show);
			http_stream_port, dont_show, ext_output);

			free_list_contents_kvp(options);
			free_list(options);
			}
			else printf(" There isn't such command: %s", argv[2]);
			else printf(" There isn't such command: %s", argv[2]);
			}