~speedprog/mtg/mtg_card_detector.git

			@@ -28,6 +28,25 @@
			#include "route_layer.h"
			#include "shortcut_layer.h"
			#include "yolo_layer.h"
			#include "upsample_layer.h"
			#include "parser.h"

			network load_network_custom(char cfg, char *weights, int clear, int batch)
			{
			printf(" Try to load cfg: %s, weights: %s, clear = %d \n", cfg, weights, clear);
			network *net = calloc(1, sizeof(network));
			*net = parse_network_cfg_custom(cfg, batch);
			if (weights && weights[0] != 0) {
			load_weights(net, weights);
			}
			if (clear) (*net->seen) = 0;
			return net;
			}

			network load_network(char cfg, char *weights, int clear)
			{
			return load_network_custom(cfg, weights, clear, 0);
			}

			int get_current_batch(network net)
			{
			@@ -46,12 +65,33 @@
			#endif
			}

			void reset_network_state(network *net, int b)
			{
			int i;
			for (i = 0; i < net->n; ++i) {
			#ifdef GPU
			layer l = net->layers[i];
			if (l.state_gpu) {
			fill_ongpu(l.outputs, 0, l.state_gpu + l.outputs*b, 1);
			}
			if (l.h_gpu) {
			fill_ongpu(l.outputs, 0, l.h_gpu + l.outputs*b, 1);
			}
			#endif
			}
			}

			void reset_rnn(network *net)
			{
			reset_network_state(net, 0);
			}

			float get_current_rate(network net)
			{
			int batch_num = get_current_batch(net);
			int i;
			float rate;
			if (batch_num < net.burn_in) return net.learning_rate * pow((float)batch_num / net.burn_in, net.power);
			if (batch_num < net.burn_in) return net.learning_rate * pow((float)batch_num / net.burn_in, net.power);
			switch (net.policy) {
			case CONSTANT:
			return net.learning_rate;
			@@ -68,7 +108,7 @@
			case EXP:
			return net.learning_rate * pow(net.gamma, batch_num);
			case POLY:
			return net.learning_rate * pow(1 - (float)batch_num / net.max_batches, net.power);
			return net.learning_rate * pow(1 - (float)batch_num / net.max_batches, net.power);
			//if (batch_num < net.burn_in) return net.learning_rate * pow((float)batch_num / net.burn_in, net.power);
			//return net.learning_rate * pow(1 - (float)batch_num / net.max_batches, net.power);
			case RANDOM:
			@@ -138,15 +178,15 @@
			net.n = n;
			net.layers = calloc(net.n, sizeof(layer));
			net.seen = calloc(1, sizeof(int));
			#ifdef GPU
			#ifdef GPU
			net.input_gpu = calloc(1, sizeof(float *));
			net.truth_gpu = calloc(1, sizeof(float *));

			net.input16_gpu = calloc(1, sizeof(float *));
			net.output16_gpu = calloc(1, sizeof(float *));
			net.max_input16_size = calloc(1, sizeof(size_t));
			net.max_output16_size = calloc(1, sizeof(size_t));
			#endif
			net.input16_gpu = calloc(1, sizeof(float *));
			net.output16_gpu = calloc(1, sizeof(float *));
			net.max_input16_size = calloc(1, sizeof(size_t));
			net.max_output16_size = calloc(1, sizeof(size_t));
			#endif
			return net;
			}

			@@ -182,7 +222,7 @@
			{
			#ifdef GPU
			if (gpu_index >= 0) return get_network_output_gpu(net);
			#endif
			#endif
			int i;
			for(i = net.n-1; i > 0; --i) if(net.layers[i].type != COST) break;
			return net.layers[i].output;
			@@ -322,20 +362,20 @@
			net->layers[i].batch = b;
			#ifdef CUDNN
			if(net->layers[i].type == CONVOLUTIONAL){
			cudnn_convolutional_setup(net->layers + i, cudnn_fastest);
			/*
			layer *l = net->layers + i;
			cudnn_convolutional_setup(net->layers + i, cudnn_fastest);
			/*
			layer *l = net->layers + i;
			cudnn_convolutional_setup(l, cudnn_fastest);
			// check for excessive memory consumption
			size_t free_byte;
			size_t total_byte;
			check_error(cudaMemGetInfo(&free_byte, &total_byte));
			if (l->workspace_size > free_byte \|\| l->workspace_size >= total_byte / 2) {
			printf(" used slow CUDNN algo without Workspace! \n");
			cudnn_convolutional_setup(l, cudnn_smallest);
			l->workspace_size = get_workspace_size(*l);
			}
			*/
			// check for excessive memory consumption
			size_t free_byte;
			size_t total_byte;
			check_error(cudaMemGetInfo(&free_byte, &total_byte));
			if (l->workspace_size > free_byte \|\| l->workspace_size >= total_byte / 2) {
			printf(" used slow CUDNN algo without Workspace! \n");
			cudnn_convolutional_setup(l, cudnn_smallest);
			l->workspace_size = get_workspace_size(*l);
			}
			*/
			}
			#endif
			}
			@@ -347,12 +387,12 @@
			cuda_set_device(net->gpu_index);
			if(gpu_index >= 0){
			cuda_free(net->workspace);
			if (net->input_gpu) {
			cuda_free(*net->input_gpu);
			*net->input_gpu = 0;
			cuda_free(*net->truth_gpu);
			*net->truth_gpu = 0;
			}
			if (net->input_gpu) {
			cuda_free(*net->input_gpu);
			*net->input_gpu = 0;
			cuda_free(*net->truth_gpu);
			*net->truth_gpu = 0;
			}
			}
			#endif
			int i;
			@@ -365,7 +405,7 @@
			//fflush(stderr);
			for (i = 0; i < net->n; ++i){
			layer l = net->layers[i];
			//printf(" %d: layer = %d,", i, l.type);
			//printf(" %d: layer = %d,", i, l.type);
			if(l.type == CONVOLUTIONAL){
			resize_convolutional_layer(&l, w, h);
			}else if(l.type == CROP){
			@@ -374,14 +414,14 @@
			resize_maxpool_layer(&l, w, h);
			}else if(l.type == REGION){
			resize_region_layer(&l, w, h);
			}else if (l.type == YOLO) {
			resize_yolo_layer(&l, w, h);
			}else if (l.type == YOLO) {
			resize_yolo_layer(&l, w, h);
			}else if(l.type == ROUTE){
			resize_route_layer(&l, net);
			}else if (l.type == SHORTCUT) {
			resize_shortcut_layer(&l, w, h);
			}else if (l.type == UPSAMPLE) {
			resize_upsample_layer(&l, w, h);
			}else if (l.type == SHORTCUT) {
			resize_shortcut_layer(&l, w, h);
			}else if (l.type == UPSAMPLE) {
			resize_upsample_layer(&l, w, h);
			}else if(l.type == REORG){
			resize_reorg_layer(&l, w, h);
			}else if(l.type == AVGPOOL){
			@@ -391,7 +431,7 @@
			}else if(l.type == COST){
			resize_cost_layer(&l, inputs);
			}else{
			fprintf(stderr, "Resizing type %d \n", (int)l.type);
			fprintf(stderr, "Resizing type %d \n", (int)l.type);
			error("Cannot resize this type of layer");
			}
			if(l.workspace_size > workspace_size) workspace_size = l.workspace_size;
			@@ -403,9 +443,9 @@
			}
			#ifdef GPU
			if(gpu_index >= 0){
			printf(" try to allocate workspace = %zu * sizeof(float), ", (workspace_size - 1) / sizeof(float) + 1);
			net->workspace = cuda_make_array(0, (workspace_size-1)/sizeof(float)+1);
			printf(" CUDA allocate done! \n");
			printf(" try to allocate workspace = %zu * sizeof(float), ", workspace_size / sizeof(float) + 1);
			net->workspace = cuda_make_array(0, workspace_size/sizeof(float) + 1);
			printf(" CUDA allocate done! \n");
			}else {
			free(net->workspace);
			net->workspace = calloc(1, workspace_size);
			@@ -453,6 +493,11 @@
			return def;
			}

			layer* get_network_layer(network* net, int i)
			{
			return net->layers + i;
			}

			image get_network_image(network net)
			{
			int i;
			@@ -475,7 +520,7 @@
			if(l.type == CONVOLUTIONAL){
			prev = visualize_convolutional_layer(l, buff, prev);
			}
			}
			}
			}

			void top_predictions(network net, int k, int *index)
			@@ -506,102 +551,112 @@

			int num_detections(network *net, float thresh)
			{
			int i;
			int s = 0;
			for (i = 0; i < net->n; ++i) {
			layer l = net->layers[i];
			if (l.type == YOLO) {
			s += yolo_num_detections(l, thresh);
			}
			if (l.type == DETECTION \|\| l.type == REGION) {
			s += l.wl.hl.n;
			}
			}
			return s;
			int i;
			int s = 0;
			for (i = 0; i < net->n; ++i) {
			layer l = net->layers[i];
			if (l.type == YOLO) {
			s += yolo_num_detections(l, thresh);
			}
			if (l.type == DETECTION \|\| l.type == REGION) {
			s += l.wl.hl.n;
			}
			}
			return s;
			}

			detection make_network_boxes(network net, float thresh, int *num)
			{
			layer l = net->layers[net->n - 1];
			int i;
			int nboxes = num_detections(net, thresh);
			if (num) *num = nboxes;
			detection *dets = calloc(nboxes, sizeof(detection));
			for (i = 0; i < nboxes; ++i) {
			dets[i].prob = calloc(l.classes, sizeof(float));
			if (l.coords > 4) {
			dets[i].mask = calloc(l.coords - 4, sizeof(float));
			}
			}
			return dets;
			layer l = net->layers[net->n - 1];
			int i;
			int nboxes = num_detections(net, thresh);
			if (num) *num = nboxes;
			detection *dets = calloc(nboxes, sizeof(detection));
			for (i = 0; i < nboxes; ++i) {
			dets[i].prob = calloc(l.classes, sizeof(float));
			if (l.coords > 4) {
			dets[i].mask = calloc(l.coords - 4, sizeof(float));
			}
			}
			return dets;
			}


			void custom_get_region_detections(layer l, int w, int h, int net_w, int net_h, float thresh, int map, float hier, int relative, detection dets, int letter)
			{
			box boxes = calloc(l.wl.h*l.n, sizeof(box));
			float *probs = calloc(l.wl.hl.n, sizeof(float ));
			int i, j;
			for (j = 0; j < l.wl.hl.n; ++j) probs[j] = calloc(l.classes, sizeof(float *));
			get_region_boxes(l, w, h, thresh, probs, boxes, 0, map);
			for (j = 0; j < l.wl.hl.n; ++j) {
			dets[j].classes = l.classes;
			dets[j].bbox = boxes[j];
			dets[j].objectness = 1;
			for (i = 0; i < l.classes; ++i) {
			dets[j].prob[i] = probs[j][i];
			}
			}
			box boxes = calloc(l.wl.h*l.n, sizeof(box));
			float *probs = calloc(l.wl.hl.n, sizeof(float ));
			int i, j;
			for (j = 0; j < l.wl.hl.n; ++j) probs[j] = calloc(l.classes, sizeof(float));
			get_region_boxes(l, 1, 1, thresh, probs, boxes, 0, map);
			for (j = 0; j < l.wl.hl.n; ++j) {
			dets[j].classes = l.classes;
			dets[j].bbox = boxes[j];
			dets[j].objectness = 1;
			for (i = 0; i < l.classes; ++i) {
			dets[j].prob[i] = probs[j][i];
			}
			}

			free(boxes);
			free_ptrs((void *)probs, l.wl.h*l.n);
			free(boxes);
			free_ptrs((void *)probs, l.wl.h*l.n);

			//correct_region_boxes(dets, l.wl.hl.n, w, h, net_w, net_h, relative);
			correct_yolo_boxes(dets, l.wl.hl.n, w, h, net_w, net_h, relative, letter);
			}

			void fill_network_boxes(network net, int w, int h, float thresh, float hier, int map, int relative, detection *dets, int letter)
			{
			int j;
			for (j = 0; j < net->n; ++j) {
			layer l = net->layers[j];
			if (l.type == YOLO) {
			int count = get_yolo_detections(l, w, h, net->w, net->h, thresh, map, relative, dets, letter);
			dets += count;
			}
			if (l.type == REGION) {
			custom_get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets, letter);
			//get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets);
			dets += l.wl.hl.n;
			}
			if (l.type == DETECTION) {
			get_detection_detections(l, w, h, thresh, dets);
			dets += l.wl.hl.n;
			}
			}
			int prev_classes = -1;
			int j;
			for (j = 0; j < net->n; ++j) {
			layer l = net->layers[j];
			if (l.type == YOLO) {
			int count = get_yolo_detections(l, w, h, net->w, net->h, thresh, map, relative, dets, letter);
			dets += count;
			if (prev_classes < 0) prev_classes = l.classes;
			else if (prev_classes != l.classes) {
			printf(" Error: Different [yolo] layers have different number of classes = %d and %d - check your cfg-file! \n",
			prev_classes, l.classes);
			}
			}
			if (l.type == REGION) {
			custom_get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets, letter);
			//get_region_detections(l, w, h, net->w, net->h, thresh, map, hier, relative, dets);
			dets += l.wl.hl.n;
			}
			if (l.type == DETECTION) {
			get_detection_detections(l, w, h, thresh, dets);
			dets += l.wl.hl.n;
			}
			}
			}

			detection get_network_boxes(network net, int w, int h, float thresh, float hier, int map, int relative, int num, int letter)
			{
			detection *dets = make_network_boxes(net, thresh, num);
			fill_network_boxes(net, w, h, thresh, hier, map, relative, dets, letter);
			return dets;
			detection *dets = make_network_boxes(net, thresh, num);
			fill_network_boxes(net, w, h, thresh, hier, map, relative, dets, letter);
			return dets;
			}

			void free_detections(detection *dets, int n)
			{
			int i;
			for (i = 0; i < n; ++i) {
			free(dets[i].prob);
			if (dets[i].mask) free(dets[i].mask);
			}
			free(dets);
			int i;
			for (i = 0; i < n; ++i) {
			free(dets[i].prob);
			if (dets[i].mask) free(dets[i].mask);
			}
			free(dets);
			}

			float network_predict_image(network net, image im)
			{
			image imr = letterbox_image(im, net->w, net->h);
			set_batch_network(net, 1);
			float p = network_predict(net, imr.data);
			free_image(imr);
			return p;
			//image imr = letterbox_image(im, net->w, net->h);
			image imr = resize_image(im, net->w, net->h);
			set_batch_network(net, 1);
			float p = network_predict(net, imr.data);
			free_image(imr);
			return p;
			}

			int network_width(network *net) { return net->w; }
			@@ -629,7 +684,7 @@
			}
			}
			free(X);
			return pred;
			return pred;
			}

			matrix network_predict_data(network net, data test)
			@@ -652,7 +707,7 @@
			}
			}
			free(X);
			return pred;
			return pred;
			}

			void print_network(network net)
			@@ -694,7 +749,7 @@
			printf("%5d %5d\n%5d %5d\n", a, b, c, d);
			float num = pow((abs(b - c) - 1.), 2.);
			float den = b + c;
			printf("%f\n", num/den);
			printf("%f\n", num/den);
			}

			float network_accuracy(network net, data d)
			@@ -725,26 +780,93 @@

			void free_network(network net)
			{
			int i;
			for (i = 0; i < net.n; ++i) {
			free_layer(net.layers[i]);
			}
			free(net.layers);
			#ifdef GPU
			if (gpu_index >= 0) cuda_free(net.workspace);
			else free(net.workspace);
			if (net.input_gpu) cuda_free(net.input_gpu);
			if (net.truth_gpu) cuda_free(net.truth_gpu);
			if (net.input_gpu) free(net.input_gpu);
			if (net.truth_gpu) free(net.truth_gpu);
			int i;
			for (i = 0; i < net.n; ++i) {
			free_layer(net.layers[i]);
			}
			free(net.layers);

			if (net.input16_gpu) cuda_free(net.input16_gpu);
			if (net.output16_gpu) cuda_free(net.output16_gpu);
			if (net.input16_gpu) free(net.input16_gpu);
			if (net.output16_gpu) free(net.output16_gpu);
			if (net.max_input16_size) free(net.max_input16_size);
			if (net.max_output16_size) free(net.max_output16_size);
			free(net.scales);
			free(net.steps);
			free(net.seen);

			#ifdef GPU
			if (gpu_index >= 0) cuda_free(net.workspace);
			else free(net.workspace);
			if (net.input_gpu) cuda_free(net.input_gpu);
			if (net.truth_gpu) cuda_free(net.truth_gpu);
			if (net.input_gpu) free(net.input_gpu);
			if (net.truth_gpu) free(net.truth_gpu);

			if (net.input16_gpu) cuda_free(net.input16_gpu);
			if (net.output16_gpu) cuda_free(net.output16_gpu);
			if (net.input16_gpu) free(net.input16_gpu);
			if (net.output16_gpu) free(net.output16_gpu);
			if (net.max_input16_size) free(net.max_input16_size);
			if (net.max_output16_size) free(net.max_output16_size);
			#else
			free(net.workspace);
			free(net.workspace);
			#endif
			}


			void fuse_conv_batchnorm(network net)
			{
			int j;
			for (j = 0; j < net.n; ++j) {
			layer *l = &net.layers[j];

			if (l->type == CONVOLUTIONAL) {
			//printf(" Merges Convolutional-%d and batch_norm \n", j);

			if (l->batch_normalize) {
			int f;
			for (f = 0; f < l->n; ++f)
			{
			l->biases[f] = l->biases[f] - (double)l->scales[f] * l->rolling_mean[f] / (sqrt((double)l->rolling_variance[f]) + .000001f);

			const size_t filter_size = l->sizel->sizel->c;
			int i;
			for (i = 0; i < filter_size; ++i) {
			int w_index = f*filter_size + i;

			l->weights[w_index] = (double)l->weights[w_index] * l->scales[f] / (sqrt((double)l->rolling_variance[f]) + .000001f);
			}
			}

			l->batch_normalize = 0;
			#ifdef GPU
			if (gpu_index >= 0) {
			push_convolutional_layer(*l);
			}
			#endif
			}
			}
			else {
			//printf(" Fusion skip layer type: %d \n", l->type);
			}
			}
			}



			void calculate_binary_weights(network net)
			{
			int j;
			for (j = 0; j < net.n; ++j) {
			layer *l = &net.layers[j];

			if (l->type == CONVOLUTIONAL) {
			//printf(" Merges Convolutional-%d and batch_norm \n", j);

			if (l->xnor) {
			//printf("\n %d \n", j);
			l->lda_align = 256; // 256bit for AVX2

			binary_align_weights(l);
			}
			}
			}
			//printf("\n calculate_binary_weights Done! \n");

			}