~speedprog/mtg/mtg_card_detector.git

			@@ -1,3 +1,5 @@
			#include <stdio.h>

			#include "network.h"
			#include "detection_layer.h"
			#include "cost_layer.h"
			@@ -5,44 +7,39 @@
			#include "parser.h"
			#include "box.h"

			#ifdef OPENCV
			#include "opencv2/highgui/highgui_c.h"
			#endif

			char *coco_classes[] = {"person","bicycle","car","motorcycle","airplane","bus","train","truck","boat","traffic light","fire hydrant","stop sign","parking meter","bench","bird","cat","dog","horse","sheep","cow","elephant","bear","zebra","giraffe","backpack","umbrella","handbag","tie","suitcase","frisbee","skis","snowboard","sports ball","kite","baseball bat","baseball glove","skateboard","surfboard","tennis racket","bottle","wine glass","cup","fork","knife","spoon","bowl","banana","apple","sandwich","orange","broccoli","carrot","hot dog","pizza","donut","cake","chair","couch","potted plant","bed","dining table","toilet","tv","laptop","mouse","remote","keyboard","cell phone","microwave","oven","toaster","sink","refrigerator","book","clock","vase","scissors","teddy bear","hair drier","toothbrush"};

			void draw_coco(image im, float box, int side, int objectness, char label)
			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};

			void draw_coco(image im, float pred, int side, char label)
			{
			int classes = 80;
			int elems = 4+classes+objectness;
			int classes = 1;
			int elems = 4+classes;
			int j;
			int r, c;

			for(r = 0; r < side; ++r){
			for(c = 0; c < side; ++c){
			j = (rside + c) elems;
			float scale = 1;
			if(objectness) scale = 1 - box[j++];
			int class = max_index(box+j, classes);
			if(scale * box[j+class] > 0.2){
			int width = box[j+class]*5 + 1;
			printf("%f %s\n", scale * box[j+class], coco_classes[class]);
			int class = max_index(pred+j, classes);
			if (pred[j+class] > 0.2){
			int width = pred[j+class]*5 + 1;
			printf("%f %s\n", pred[j+class], "object"); //coco_classes[class-1]);
			float red = get_color(0,class,classes);
			float green = get_color(1,class,classes);
			float blue = get_color(2,class,classes);

			j += classes;
			float x = box[j+0];
			float y = box[j+1];
			x = (x+c)/side;
			y = (y+r)/side;
			float w = box[j+2]; //*maxwidth;
			float h = box[j+3]; //*maxheight;
			h = h*h;
			w = w*w;

			int left = (x-w/2)*im.w;
			int right = (x+w/2)*im.w;
			int top = (y-h/2)*im.h;
			int bot = (y+h/2)*im.h;
			draw_box_width(im, left, top, right, bot, width, red, green, blue);
			box predict = {pred[j+0], pred[j+1], pred[j+2], pred[j+3]};
			predict.x = (predict.x+c)/side;
			predict.y = (predict.y+r)/side;

			draw_bbox(im, predict, width, red, green, blue);
			}
			}
			}
			@@ -51,7 +48,8 @@

			void train_coco(char cfgfile, char weightfile)
			{
			char *train_images = "/home/pjreddie/data/coco/train.txt";
			//char *train_images = "/home/pjreddie/data/coco/train.txt";
			char *train_images = "/home/pjreddie/data/voc/test/train.txt";
			char *backup_directory = "/home/pjreddie/backup/";
			srand(time(0));
			data_seed = time(0);
			@@ -62,90 +60,133 @@
			if(weightfile){
			load_weights(&net, weightfile);
			}
			detection_layer layer = get_network_detection_layer(net);
			printf("Learning Rate: %g, Momentum: %g, Decay: %g\n", net.learning_rate, net.momentum, net.decay);
			int imgs = 128;
			int i = net.seen/imgs;
			int i = *net.seen/imgs;
			data train, buffer;

			int classes = layer.classes;
			int background = layer.objectness;
			int side = sqrt(get_detection_layer_locations(layer));

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

			int side = l.side;
			int classes = l.classes;

			list *plist = get_paths(train_images);
			int N = plist->size;
			char paths = (char )list_to_array(plist);

			paths = (char **)list_to_array(plist);
			pthread_t load_thread = load_data_detection_thread(imgs, paths, plist->size, classes, net.w, net.h, side, side, background, &buffer);
			load_args args = {0};
			args.w = net.w;
			args.h = net.h;
			args.paths = paths;
			args.n = imgs;
			args.m = plist->size;
			args.classes = classes;
			args.num_boxes = side;
			args.d = &buffer;
			args.type = REGION_DATA;

			pthread_t load_thread = load_data_in_thread(args);
			clock_t time;
			while(iimgs < N120){
			i += 1;
			time=clock();
			pthread_join(load_thread, 0);
			train = buffer;
			load_thread = load_data_detection_thread(imgs, paths, plist->size, classes, net.w, net.h, side, side, background, &buffer);
			load_thread = load_data_in_thread(args);

			printf("Loaded: %lf seconds\n", sec(clock()-time));

			/*
			image im = float_to_image(net.w, net.h, 3, train.X.vals[114]);
			image copy = copy_image(im);
			draw_coco(copy, train.y.vals[114], 7, layer.objectness, "truth");
			cvWaitKey(0);
			free_image(copy);
			*/
			/*
			image im = float_to_image(net.w, net.h, 3, train.X.vals[113]);
			image copy = copy_image(im);
			draw_coco(copy, train.y.vals[113], 7, "truth");
			cvWaitKey(0);
			free_image(copy);
			*/

			time=clock();
			float loss = train_network(net, train);
			net.seen += imgs;
			if (avg_loss < 0) avg_loss = loss;
			avg_loss = avg_loss.9 + loss.1;

			printf("%d: %f, %f avg, %lf seconds, %d images\n", i, loss, avg_loss, sec(clock()-time), i*imgs);
			if((i-1)imgs <= 80N && iimgs > N80){
			fprintf(stderr, "First stage done.\n");
			if((i-1)imgs <= N && iimgs > N){
			fprintf(stderr, "First stage done\n");
			net.learning_rate *= 10;
			char buff[256];
			sprintf(buff, "%s/%s_first_stage.weights", backup_directory, base);
			save_weights(net, buff);
			return;
			}
			if(i%1000==0 \|\| 1){

			if((i-1)imgs <= 80N && iimgs > N80){
			fprintf(stderr, "Second stage done.\n");
			char buff[256];
			sprintf(buff, "%s/%s_second_stage.weights", backup_directory, base);
			save_weights(net, buff);
			}
			if(i%1000==0){
			char buff[256];
			sprintf(buff, "%s/%s_%d.weights", backup_directory, base, i);
			save_weights(net, buff);
			}
			free_data(train);
			return;
			}
			char buff[256];
			sprintf(buff, "%s/%s_final.weights", backup_directory, base);
			save_weights(net, buff);
			}

			void convert_cocos(float predictions, int classes, int objectness, int background, int num_boxes, int w, int h, float thresh, float probs, box boxes)
			void get_probs(float predictions, int total, int classes, int inc, float *probs)
			{
			int i,j;
			int per_box = 4+classes+(background \|\| objectness);
			for (i = 0; i < num_boxes*num_boxes; ++i){
			float scale = 1;
			if(objectness) scale = 1-predictions[i*per_box];
			int offset = i*per_box+(background\|\|objectness);
			for (i = 0; i < total; ++i){
			int index = i*inc;
			float scale = predictions[index];
			probs[i][0] = scale;
			for(j = 0; j < classes; ++j){
			float prob = scale*predictions[offset+j];
			probs[i][j] = scale*predictions[index+j+1];
			}
			}
			}
			void get_boxes(float predictions, int n, int num_boxes, int per_box, box boxes)
			{
			int i,j;
			for (i = 0; i < num_boxes*num_boxes; ++i){
			for(j = 0; j < n; ++j){
			int index = i*n+j;
			int offset = index*per_box;
			int row = i / num_boxes;
			int col = i % num_boxes;
			boxes[index].x = (predictions[offset + 0] + col) / num_boxes;
			boxes[index].y = (predictions[offset + 1] + row) / num_boxes;
			boxes[index].w = predictions[offset + 2];
			boxes[index].h = predictions[offset + 3];
			}
			}
			}

			void convert_cocos(float predictions, int classes, int num_boxes, int num, int w, int h, float thresh, float probs, box boxes)
			{
			int i,j;
			int per_box = 4+classes;
			for (i = 0; i < num_boxesnum_boxesnum; ++i){
			int offset = i*per_box;
			for(j = 0; j < classes; ++j){
			float prob = predictions[offset+j];
			probs[i][j] = (prob > thresh) ? prob : 0;
			}
			int row = i / num_boxes;
			int col = i % num_boxes;
			offset += classes;
			boxes[i].x = (predictions[offset + 0] + col) / num_boxes * w;
			boxes[i].y = (predictions[offset + 1] + row) / num_boxes * h;
			boxes[i].w = pow(predictions[offset + 2], 2) * w;
			boxes[i].h = pow(predictions[offset + 3], 2) * h;
			boxes[i].x = (predictions[offset + 0] + col) / num_boxes;
			boxes[i].y = (predictions[offset + 1] + row) / num_boxes;
			boxes[i].w = predictions[offset + 2];
			boxes[i].h = predictions[offset + 3];
			}
			}

			void print_cocos(FILE *fps, char id, box boxes, float *probs, int num_boxes, int classes, int w, int h)
			void print_cocos(FILE fp, int image_id, box boxes, float **probs, int num_boxes, int classes, int w, int h)
			{
			int i, j;
			for(i = 0; i < num_boxes*num_boxes; ++i){
			@@ -159,13 +200,218 @@
			if (xmax > w) xmax = w;
			if (ymax > h) ymax = h;

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

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

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

			void validate_recall(char cfgfile, char weightfile)
			{
			network net = parse_network_cfg(cfgfile);
			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));

			char *val_images = "/home/pjreddie/data/voc/test/2007_test.txt";
			list *plist = get_paths(val_images);
			char paths = (char )list_to_array(plist);

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

			int num_boxes = l.side;
			int num = l.n;
			int classes = l.classes;

			int j;

			box boxes = calloc(num_boxesnum_boxes*num, sizeof(box));
			float *probs = calloc(num_boxesnum_boxesnum, sizeof(float ));
			for(j = 0; j < num_boxesnum_boxesnum; ++j) probs[j] = calloc(classes+1, sizeof(float *));

			int N = plist->size;
			int i=0;
			int k;

			float iou_thresh = .5;
			float thresh = .1;
			int total = 0;
			int correct = 0;
			float avg_iou = 0;
			int nms = 1;
			int proposals = 0;
			int save = 1;

			for (i = 0; i < N; ++i) {
			char *path = paths[i];
			image orig = load_image_color(path, 0, 0);
			image resized = resize_image(orig, net.w, net.h);

			float *X = resized.data;
			float *predictions = network_predict(net, X);
			get_boxes(predictions+1+classes, num, num_boxes, 5+classes, boxes);
			get_probs(predictions, numnum_boxesnum_boxes, classes, 5+classes, probs);
			if (nms) do_nms(boxes, probs, numnum_boxesnum_boxes, (classes>0) ? classes : 1, iou_thresh);

			char *labelpath = find_replace(path, "images", "labels");
			labelpath = find_replace(labelpath, "JPEGImages", "labels");
			labelpath = find_replace(labelpath, ".jpg", ".txt");
			labelpath = find_replace(labelpath, ".JPEG", ".txt");

			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			for(k = 0; k < num_boxesnum_boxesnum; ++k){
			if(probs[k][0] > thresh){
			++proposals;
			if(save){
			char buff[256];
			sprintf(buff, "/data/extracted/nms_preds/%d", proposals);
			int dx = (boxes[k].x - boxes[k].w/2) * orig.w;
			int dy = (boxes[k].y - boxes[k].h/2) * orig.h;
			int w = boxes[k].w * orig.w;
			int h = boxes[k].h * orig.h;
			image cropped = crop_image(orig, dx, dy, w, h);
			image sized = resize_image(cropped, 224, 224);
			#ifdef OPENCV
			save_image_jpg(sized, buff);
			#endif
			free_image(sized);
			free_image(cropped);
			sprintf(buff, "/data/extracted/nms_pred_boxes/%d.txt", proposals);
			char *im_id = basecfg(path);
			FILE *fp = fopen(buff, "w");
			fprintf(fp, "%s %d %d %d %d\n", im_id, dx, dy, dx+w, dy+h);
			fclose(fp);
			free(im_id);
			}
			}
			}
			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 < num_boxesnum_boxesnum; ++k){
			float iou = box_iou(boxes[k], t);
			if(probs[k][0] > thresh && iou > best_iou){
			best_iou = iou;
			}
			}
			avg_iou += best_iou;
			if(best_iou > iou_thresh){
			++correct;
			}
			}
			free(truth);
			free_image(orig);
			free_image(resized);
			fprintf(stderr, "%5d %5d %5d\tRPs/Img: %.2f\tIOU: %.2f%%\tRecall:%.2f%%\n", i, correct, total, (float)proposals/(i+1), avg_iou100/total, 100.correct/total);
			}
			}

			void extract_boxes(char cfgfile, char weightfile)
			{
			network net = parse_network_cfg(cfgfile);
			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));

			char *val_images = "/home/pjreddie/data/voc/test/train.txt";
			list *plist = get_paths(val_images);
			char paths = (char )list_to_array(plist);

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

			int num_boxes = l.side;
			int num = l.n;
			int classes = l.classes;

			int j;

			box boxes = calloc(num_boxesnum_boxes*num, sizeof(box));
			float *probs = calloc(num_boxesnum_boxesnum, sizeof(float ));
			for(j = 0; j < num_boxesnum_boxesnum; ++j) probs[j] = calloc(classes+1, sizeof(float *));

			int N = plist->size;
			int i=0;
			int k;

			int count = 0;
			float iou_thresh = .3;

			for (i = 0; i < N; ++i) {
			fprintf(stderr, "%5d %5d\n", i, count);
			char *path = paths[i];
			image orig = load_image_color(path, 0, 0);
			image resized = resize_image(orig, net.w, net.h);

			float *X = resized.data;
			float *predictions = network_predict(net, X);
			get_boxes(predictions+1+classes, num, num_boxes, 5+classes, boxes);
			get_probs(predictions, numnum_boxesnum_boxes, classes, 5+classes, probs);

			char *labelpath = find_replace(path, "images", "labels");
			labelpath = find_replace(labelpath, "JPEGImages", "labels");
			labelpath = find_replace(labelpath, ".jpg", ".txt");
			labelpath = find_replace(labelpath, ".JPEG", ".txt");

			int num_labels = 0;
			box_label *truth = read_boxes(labelpath, &num_labels);
			FILE *label = stdin;
			for(k = 0; k < num_boxesnum_boxesnum; ++k){
			int overlaps = 0;
			for (j = 0; j < num_labels; ++j) {
			box t = {truth[j].x, truth[j].y, truth[j].w, truth[j].h};
			float iou = box_iou(boxes[k], t);
			if (iou > iou_thresh){
			if (!overlaps) {
			char buff[256];
			sprintf(buff, "/data/extracted/labels/%d.txt", count);
			label = fopen(buff, "w");
			overlaps = 1;
			}
			fprintf(label, "%d %f\n", truth[j].id, iou);
			}
			}
			if (overlaps) {
			char buff[256];
			sprintf(buff, "/data/extracted/imgs/%d", count++);
			int dx = (boxes[k].x - boxes[k].w/2) * orig.w;
			int dy = (boxes[k].y - boxes[k].h/2) * orig.h;
			int w = boxes[k].w * orig.w;
			int h = boxes[k].h * orig.h;
			image cropped = crop_image(orig, dx, dy, w, h);
			image sized = resize_image(cropped, 224, 224);
			#ifdef OPENCV
			save_image_jpg(sized, buff);
			#endif
			free_image(sized);
			free_image(cropped);
			fclose(label);
			}
			}
			free(truth);
			free_image(orig);
			free_image(resized);
			}
			}

			void validate_coco(char cfgfile, char weightfile)
			{
			network net = parse_network_cfg(cfgfile);
			@@ -173,38 +419,40 @@
			load_weights(&net, weightfile);
			}
			set_batch_network(&net, 1);
			detection_layer layer = get_network_detection_layer(net);
			fprintf(stderr, "Learning Rate: %g, Momentum: %g, Decay: %g\n", net.learning_rate, net.momentum, net.decay);
			srand(time(0));

			char *base = "results/comp4_det_test_";
			list *plist = get_paths("data/voc.2012test.list");
			char *base = "/home/pjreddie/backup/";
			list *plist = get_paths("data/coco_val_5k.list");
			char paths = (char )list_to_array(plist);

			int classes = layer.classes;
			int objectness = layer.objectness;
			int background = layer.background;
			int num_boxes = sqrt(get_detection_layer_locations(layer));
			int num_boxes = 9;
			int num = 4;
			int classes = 1;

			int j;
			FILE *fps = calloc(classes, sizeof(FILE ));
			for(j = 0; j < classes; ++j){
			char buff[1024];
			snprintf(buff, 1024, "%s%s.txt", base, coco_classes[j]);
			fps[j] = fopen(buff, "w");
			}
			box boxes = calloc(num_boxesnum_boxes, sizeof(box));
			float *probs = calloc(num_boxesnum_boxes, sizeof(float *));
			for(j = 0; j < num_boxesnum_boxes; ++j) probs[j] = calloc(classes, sizeof(float ));
			char buff[1024];
			snprintf(buff, 1024, "%s/coco_results.json", base);
			FILE *fp = fopen(buff, "w");
			fprintf(fp, "[\n");

			box boxes = calloc(num_boxesnum_boxes*num, sizeof(box));
			float *probs = calloc(num_boxesnum_boxesnum, sizeof(float ));
			for(j = 0; j < num_boxesnum_boxesnum; ++j) probs[j] = calloc(classes, sizeof(float *));

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

			float thresh = .001;
			float thresh = .01;
			int nms = 1;
			float iou_thresh = .5;

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

			int nthreads = 8;
			image *val = calloc(nthreads, sizeof(image));
			image *val_resized = calloc(nthreads, sizeof(image));
			@@ -212,7 +460,10 @@
			image *buf_resized = calloc(nthreads, sizeof(image));
			pthread_t *thr = calloc(nthreads, sizeof(pthread_t));
			for(t = 0; t < nthreads; ++t){
			thr[t] = load_image_thread(paths[i+t], &buf[t], &buf_resized[t], net.w, net.h);
			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){
			@@ -223,23 +474,28 @@
			val_resized[t] = buf_resized[t];
			}
			for(t = 0; t < nthreads && i+t < m; ++t){
			thr[t] = load_image_thread(paths[i+t], &buf[t], &buf_resized[t], net.w, net.h);
			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);
			int image_id = get_coco_image_id(path);
			float *X = val_resized[t].data;
			float *predictions = network_predict(net, X);
			int w = val[t].w;
			int h = val[t].h;
			convert_cocos(predictions, classes, objectness, background, num_boxes, w, h, thresh, probs, boxes);
			convert_cocos(predictions, classes, num_boxes, num, w, h, thresh, probs, boxes);
			if (nms) do_nms(boxes, probs, num_boxes, classes, iou_thresh);
			print_cocos(fps, id, boxes, probs, num_boxes, classes, w, h);
			free(id);
			print_cocos(fp, image_id, boxes, probs, num_boxes, classes, w, h);
			free_image(val[t]);
			free_image(val_resized[t]);
			}
			}
			fseek(fp, -2, SEEK_CUR);
			fprintf(fp, "\n]\n");
			fclose(fp);
			fprintf(stderr, "Total Detection Time: %f Seconds\n", (double)(time(0) - start));
			}

			@@ -250,7 +506,6 @@
			if(weightfile){
			load_weights(&net, weightfile);
			}
			detection_layer layer = get_network_detection_layer(net);
			set_batch_network(&net, 1);
			srand(2222222);
			clock_t time;
			@@ -270,7 +525,7 @@
			time=clock();
			float *predictions = network_predict(net, X);
			printf("%s: Predicted in %f seconds.\n", input, sec(clock()-time));
			draw_coco(im, predictions, 7, layer.objectness, "predictions");
			draw_coco(im, predictions, 7, "predictions");
			free_image(im);
			free_image(sized);
			#ifdef OPENCV
			@@ -293,5 +548,6 @@
			char *filename = (argc > 5) ? argv[5]: 0;
			if(0==strcmp(argv[2], "test")) test_coco(cfg, weights, filename);
			else if(0==strcmp(argv[2], "train")) train_coco(cfg, weights);
			else if(0==strcmp(argv[2], "valid")) validate_coco(cfg, weights);
			else if(0==strcmp(argv[2], "extract")) extract_boxes(cfg, weights);
			else if(0==strcmp(argv[2], "valid")) validate_recall(cfg, weights);
			}