~speedprog/mtg/mtg_card_detector.git

			@@ -4,10 +4,16 @@

			#include "parser.h"
			#include "activations.h"
			#include "crop_layer.h"
			#include "cost_layer.h"
			#include "convolutional_layer.h"
			#include "deconvolutional_layer.h"
			#include "connected_layer.h"
			#include "maxpool_layer.h"
			#include "normalization_layer.h"
			#include "softmax_layer.h"
			#include "dropout_layer.h"
			#include "detection_layer.h"
			#include "list.h"
			#include "option_list.h"
			#include "utils.h"
			@@ -17,10 +23,17 @@
			list *options;
			}section;

			int is_network(section *s);
			int is_convolutional(section *s);
			int is_deconvolutional(section *s);
			int is_connected(section *s);
			int is_maxpool(section *s);
			int is_dropout(section *s);
			int is_softmax(section *s);
			int is_crop(section *s);
			int is_cost(section *s);
			int is_detection(section *s);
			int is_normalization(section *s);
			list read_cfg(char filename);

			void free_section(section *s)
			@@ -39,147 +52,293 @@
			free(s);
			}

			convolutional_layer parse_convolutional(list options, network net, int count)
			void parse_data(char data, float a, int n)
			{
			int i;
			int h,w,c;
			if(!data) return;
			char *curr = data;
			char *next = data;
			int done = 0;
			for(i = 0; i < n && !done; ++i){
			while(++next !='\0' && next != ',');
			if(*next == '\0') done = 1;
			*next = '\0';
			sscanf(curr, "%g", &a[i]);
			curr = next+1;
			}
			}

			typedef struct size_params{
			int batch;
			int inputs;
			int h;
			int w;
			int c;
			} size_params;

			deconvolutional_layer parse_deconvolutional(list options, size_params params)
			{
			int n = option_find_int(options, "filters",1);
			int size = option_find_int(options, "size",1);
			int stride = option_find_int(options, "stride",1);
			char *activation_s = option_find_str(options, "activation", "sigmoid");
			char *activation_s = option_find_str(options, "activation", "logistic");
			ACTIVATION activation = get_activation(activation_s);
			if(count == 0){
			h = option_find_int(options, "height",1);
			w = option_find_int(options, "width",1);
			c = option_find_int(options, "channels",1);
			}else{
			image m = get_network_image_layer(net, count-1);
			h = m.h;
			w = m.w;
			c = m.c;
			if(h == 0) error("Layer before convolutional layer must output image.");
			}
			convolutional_layer *layer = make_convolutional_layer(h,w,c,n,size,stride, activation);
			char *data = option_find_str(options, "data", 0);
			if(data){
			char *curr = data;
			char *next = data;
			for(i = 0; i < n; ++i){
			while(++next !='\0' && next != ',');
			*next = '\0';
			sscanf(curr, "%g", &layer->biases[i]);
			curr = next+1;
			}
			for(i = 0; i < cnsize*size; ++i){
			while(++next !='\0' && next != ',');
			*next = '\0';
			sscanf(curr, "%g", &layer->filters[i]);
			curr = next+1;
			}
			}

			int batch,h,w,c;
			h = params.h;
			w = params.w;
			c = params.c;
			batch=params.batch;
			if(!(h && w && c)) error("Layer before deconvolutional layer must output image.");

			deconvolutional_layer *layer = make_deconvolutional_layer(batch,h,w,c,n,size,stride,activation);

			char *weights = option_find_str(options, "weights", 0);
			char *biases = option_find_str(options, "biases", 0);
			parse_data(weights, layer->filters, cnsize*size);
			parse_data(biases, layer->biases, n);
			#ifdef GPU
			if(weights \|\| biases) push_deconvolutional_layer(*layer);
			#endif
			option_unused(options);
			return layer;
			}

			connected_layer parse_connected(list options, network net, int count)
			convolutional_layer parse_convolutional(list options, size_params params)
			{
			int i;
			int input;
			int output = option_find_int(options, "output",1);
			char *activation_s = option_find_str(options, "activation", "sigmoid");
			ACTIVATION activation = get_activation(activation_s);
			if(count == 0){
			input = option_find_int(options, "input",1);
			}else{
			input = get_network_output_size_layer(net, count-1);
			}
			connected_layer *layer = make_connected_layer(input, output, activation);
			char *data = option_find_str(options, "data", 0);
			if(data){
			char *curr = data;
			char *next = data;
			for(i = 0; i < output; ++i){
			while(++next !='\0' && next != ',');
			*next = '\0';
			sscanf(curr, "%g", &layer->biases[i]);
			curr = next+1;
			}
			for(i = 0; i < input*output; ++i){
			while(++next !='\0' && next != ',');
			*next = '\0';
			sscanf(curr, "%g", &layer->weights[i]);
			curr = next+1;
			}
			}
			option_unused(options);
			return layer;
			}

			softmax_layer parse_softmax(list options, network net, int count)
			{
			int input;
			if(count == 0){
			input = option_find_int(options, "input",1);
			}else{
			input = get_network_output_size_layer(net, count-1);
			}
			softmax_layer *layer = make_softmax_layer(input);
			option_unused(options);
			return layer;
			}

			maxpool_layer parse_maxpool(list options, network net, int count)
			{
			int h,w,c;
			int n = option_find_int(options, "filters",1);
			int size = option_find_int(options, "size",1);
			int stride = option_find_int(options, "stride",1);
			if(count == 0){
			h = option_find_int(options, "height",1);
			w = option_find_int(options, "width",1);
			c = option_find_int(options, "channels",1);
			}else{
			image m = get_network_image_layer(net, count-1);
			h = m.h;
			w = m.w;
			c = m.c;
			if(h == 0) error("Layer before convolutional layer must output image.");
			}
			maxpool_layer *layer = make_maxpool_layer(h,w,c,stride);
			int pad = option_find_int(options, "pad",0);
			char *activation_s = option_find_str(options, "activation", "logistic");
			ACTIVATION activation = get_activation(activation_s);

			int batch,h,w,c;
			h = params.h;
			w = params.w;
			c = params.c;
			batch=params.batch;
			if(!(h && w && c)) error("Layer before convolutional layer must output image.");

			convolutional_layer *layer = make_convolutional_layer(batch,h,w,c,n,size,stride,pad,activation);

			char *weights = option_find_str(options, "weights", 0);
			char *biases = option_find_str(options, "biases", 0);
			parse_data(weights, layer->filters, cnsize*size);
			parse_data(biases, layer->biases, n);
			#ifdef GPU
			if(weights \|\| biases) push_convolutional_layer(*layer);
			#endif
			option_unused(options);
			return layer;
			}

			connected_layer parse_connected(list options, size_params params)
			{
			int output = option_find_int(options, "output",1);
			char *activation_s = option_find_str(options, "activation", "logistic");
			ACTIVATION activation = get_activation(activation_s);

			connected_layer *layer = make_connected_layer(params.batch, params.inputs, output, activation);

			char *weights = option_find_str(options, "weights", 0);
			char *biases = option_find_str(options, "biases", 0);
			parse_data(biases, layer->biases, output);
			parse_data(weights, layer->weights, params.inputs*output);
			#ifdef GPU
			if(weights \|\| biases) push_connected_layer(*layer);
			#endif
			option_unused(options);
			return layer;
			}

			softmax_layer parse_softmax(list options, size_params params)
			{
			int groups = option_find_int(options, "groups",1);
			softmax_layer *layer = make_softmax_layer(params.batch, params.inputs, groups);
			option_unused(options);
			return layer;
			}

			detection_layer parse_detection(list options, size_params params)
			{
			int coords = option_find_int(options, "coords", 1);
			int classes = option_find_int(options, "classes", 1);
			int rescore = option_find_int(options, "rescore", 1);
			int background = option_find_int(options, "background", 1);
			detection_layer *layer = make_detection_layer(params.batch, params.inputs, classes, coords, rescore, background);
			option_unused(options);
			return layer;
			}

			cost_layer parse_cost(list options, size_params params)
			{
			char *type_s = option_find_str(options, "type", "sse");
			COST_TYPE type = get_cost_type(type_s);
			cost_layer *layer = make_cost_layer(params.batch, params.inputs, type);
			option_unused(options);
			return layer;
			}

			crop_layer parse_crop(list options, size_params params)
			{
			int crop_height = option_find_int(options, "crop_height",1);
			int crop_width = option_find_int(options, "crop_width",1);
			int flip = option_find_int(options, "flip",0);

			int batch,h,w,c;
			h = params.h;
			w = params.w;
			c = params.c;
			batch=params.batch;
			if(!(h && w && c)) error("Layer before crop layer must output image.");

			crop_layer *layer = make_crop_layer(batch,h,w,c,crop_height,crop_width,flip);
			option_unused(options);
			return layer;
			}

			maxpool_layer parse_maxpool(list options, size_params params)
			{
			int stride = option_find_int(options, "stride",1);
			int size = option_find_int(options, "size",stride);

			int batch,h,w,c;
			h = params.h;
			w = params.w;
			c = params.c;
			batch=params.batch;
			if(!(h && w && c)) error("Layer before maxpool layer must output image.");

			maxpool_layer *layer = make_maxpool_layer(batch,h,w,c,size,stride);
			option_unused(options);
			return layer;
			}

			dropout_layer parse_dropout(list options, size_params params)
			{
			float probability = option_find_float(options, "probability", .5);
			dropout_layer *layer = make_dropout_layer(params.batch, params.inputs, probability);
			option_unused(options);
			return layer;
			}

			normalization_layer parse_normalization(list options, size_params params)
			{
			int size = option_find_int(options, "size",1);
			float alpha = option_find_float(options, "alpha", 0.);
			float beta = option_find_float(options, "beta", 1.);
			float kappa = option_find_float(options, "kappa", 1.);

			int batch,h,w,c;
			h = params.h;
			w = params.w;
			c = params.c;
			batch=params.batch;
			if(!(h && w && c)) error("Layer before normalization layer must output image.");

			normalization_layer *layer = make_normalization_layer(batch,h,w,c,size, alpha, beta, kappa);
			option_unused(options);
			return layer;
			}

			void parse_net_options(list options, network net)
			{
			net->batch = option_find_int(options, "batch",1);
			net->learning_rate = option_find_float(options, "learning_rate", .001);
			net->momentum = option_find_float(options, "momentum", .9);
			net->decay = option_find_float(options, "decay", .0001);
			net->seen = option_find_int(options, "seen",0);
			int subdivs = option_find_int(options, "subdivisions",1);
			net->batch /= subdivs;
			net->subdivisions = subdivs;

			net->h = option_find_int_quiet(options, "height",0);
			net->w = option_find_int_quiet(options, "width",0);
			net->c = option_find_int_quiet(options, "channels",0);
			net->inputs = option_find_int_quiet(options, "inputs", net->h * net->w * net->c);
			if(!net->inputs && !(net->h && net->w && net->c)) error("No input parameters supplied");
			option_unused(options);
			}

			network parse_network_cfg(char *filename)
			{
			list *sections = read_cfg(filename);
			network net = make_network(sections->size);

			node *n = sections->front;
			if(!n) error("Config file has no sections");
			network net = make_network(sections->size - 1);
			size_params params;

			section s = (section )n->val;
			list *options = s->options;
			if(!is_network(s)) error("First section must be [net] or [network]");
			parse_net_options(options, &net);

			params.h = net.h;
			params.w = net.w;
			params.c = net.c;
			params.inputs = net.inputs;
			params.batch = net.batch;

			n = n->next;
			int count = 0;
			while(n){
			section s = (section )n->val;
			list *options = s->options;
			fprintf(stderr, "%d: ", count);
			s = (section *)n->val;
			options = s->options;
			if(is_convolutional(s)){
			convolutional_layer *layer = parse_convolutional(options, net, count);
			convolutional_layer *layer = parse_convolutional(options, params);
			net.types[count] = CONVOLUTIONAL;
			net.layers[count] = layer;
			}else if(is_deconvolutional(s)){
			deconvolutional_layer *layer = parse_deconvolutional(options, params);
			net.types[count] = DECONVOLUTIONAL;
			net.layers[count] = layer;
			}else if(is_connected(s)){
			connected_layer *layer = parse_connected(options, net, count);
			connected_layer *layer = parse_connected(options, params);
			net.types[count] = CONNECTED;
			net.layers[count] = layer;
			}else if(is_crop(s)){
			crop_layer *layer = parse_crop(options, params);
			net.types[count] = CROP;
			net.layers[count] = layer;
			}else if(is_cost(s)){
			cost_layer *layer = parse_cost(options, params);
			net.types[count] = COST;
			net.layers[count] = layer;
			}else if(is_detection(s)){
			detection_layer *layer = parse_detection(options, params);
			net.types[count] = DETECTION;
			net.layers[count] = layer;
			}else if(is_softmax(s)){
			softmax_layer *layer = parse_softmax(options, net, count);
			softmax_layer *layer = parse_softmax(options, params);
			net.types[count] = SOFTMAX;
			net.layers[count] = layer;
			}else if(is_maxpool(s)){
			maxpool_layer *layer = parse_maxpool(options, net, count);
			maxpool_layer *layer = parse_maxpool(options, params);
			net.types[count] = MAXPOOL;
			net.layers[count] = layer;
			}else if(is_normalization(s)){
			normalization_layer *layer = parse_normalization(options, params);
			net.types[count] = NORMALIZATION;
			net.layers[count] = layer;
			}else if(is_dropout(s)){
			dropout_layer *layer = parse_dropout(options, params);
			net.types[count] = DROPOUT;
			net.layers[count] = layer;
			}else{
			fprintf(stderr, "Type not recognized: %s\n", s->type);
			}
			free_section(s);
			++count;
			n = n->next;
			if(n){
			image im = get_network_image_layer(net, count);
			params.h = im.h;
			params.w = im.w;
			params.c = im.c;
			params.inputs = get_network_output_size_layer(net, count);
			}
			++count;
			}
			free_list(sections);
			net.outputs = get_network_output_size(net);
			@@ -187,11 +346,33 @@
			return net;
			}

			int is_crop(section *s)
			{
			return (strcmp(s->type, "[crop]")==0);
			}
			int is_cost(section *s)
			{
			return (strcmp(s->type, "[cost]")==0);
			}
			int is_detection(section *s)
			{
			return (strcmp(s->type, "[detection]")==0);
			}
			int is_deconvolutional(section *s)
			{
			return (strcmp(s->type, "[deconv]")==0
			\|\| strcmp(s->type, "[deconvolutional]")==0);
			}
			int is_convolutional(section *s)
			{
			return (strcmp(s->type, "[conv]")==0
			\|\| strcmp(s->type, "[convolutional]")==0);
			}
			int is_network(section *s)
			{
			return (strcmp(s->type, "[net]")==0
			\|\| strcmp(s->type, "[network]")==0);
			}
			int is_connected(section *s)
			{
			return (strcmp(s->type, "[conn]")==0
			@@ -202,17 +383,26 @@
			return (strcmp(s->type, "[max]")==0
			\|\| strcmp(s->type, "[maxpool]")==0);
			}
			int is_dropout(section *s)
			{
			return (strcmp(s->type, "[dropout]")==0);
			}

			int is_softmax(section *s)
			{
			return (strcmp(s->type, "[soft]")==0
			\|\| strcmp(s->type, "[softmax]")==0);
			}
			int is_normalization(section *s)
			{
			return (strcmp(s->type, "[lrnorm]")==0
			\|\| strcmp(s->type, "[localresponsenormalization]")==0);
			}

			int read_option(char s, list options)
			{
			int i;
			int len = strlen(s);
			size_t i;
			size_t len = strlen(s);
			char *val = 0;
			for(i = 0; i < len; ++i){
			if(s[i] == '='){
			@@ -252,7 +442,7 @@
			break;
			default:
			if(!read_option(line, current->options)){
			printf("Config file error line %d, could parse: %s\n", nu, line);
			fprintf(stderr, "Config file error line %d, could parse: %s\n", nu, line);
			free(line);
			}
			break;
			@@ -262,3 +452,245 @@
			return sections;
			}

			void print_convolutional_cfg(FILE fp, convolutional_layer l, network net, int count)
			{
			#ifdef GPU
			if(gpu_index >= 0) pull_convolutional_layer(*l);
			#endif
			int i;
			fprintf(fp, "[convolutional]\n");
			fprintf(fp, "filters=%d\n"
			"size=%d\n"
			"stride=%d\n"
			"pad=%d\n"
			"activation=%s\n",
			l->n, l->size, l->stride, l->pad,
			get_activation_string(l->activation));
			fprintf(fp, "biases=");
			for(i = 0; i < l->n; ++i) fprintf(fp, "%g,", l->biases[i]);
			fprintf(fp, "\n");
			fprintf(fp, "weights=");
			for(i = 0; i < l->nl->cl->size*l->size; ++i) fprintf(fp, "%g,", l->filters[i]);
			fprintf(fp, "\n\n");
			}

			void print_deconvolutional_cfg(FILE fp, deconvolutional_layer l, network net, int count)
			{
			#ifdef GPU
			if(gpu_index >= 0) pull_deconvolutional_layer(*l);
			#endif
			int i;
			fprintf(fp, "[deconvolutional]\n");
			fprintf(fp, "filters=%d\n"
			"size=%d\n"
			"stride=%d\n"
			"activation=%s\n",
			l->n, l->size, l->stride,
			get_activation_string(l->activation));
			fprintf(fp, "biases=");
			for(i = 0; i < l->n; ++i) fprintf(fp, "%g,", l->biases[i]);
			fprintf(fp, "\n");
			fprintf(fp, "weights=");
			for(i = 0; i < l->nl->cl->size*l->size; ++i) fprintf(fp, "%g,", l->filters[i]);
			fprintf(fp, "\n\n");
			}

			void print_dropout_cfg(FILE fp, dropout_layer l, network net, int count)
			{
			fprintf(fp, "[dropout]\n");
			fprintf(fp, "probability=%g\n\n", l->probability);
			}

			void print_connected_cfg(FILE fp, connected_layer l, network net, int count)
			{
			#ifdef GPU
			if(gpu_index >= 0) pull_connected_layer(*l);
			#endif
			int i;
			fprintf(fp, "[connected]\n");
			fprintf(fp, "output=%d\n"
			"activation=%s\n",
			l->outputs,
			get_activation_string(l->activation));
			fprintf(fp, "biases=");
			for(i = 0; i < l->outputs; ++i) fprintf(fp, "%g,", l->biases[i]);
			fprintf(fp, "\n");
			fprintf(fp, "weights=");
			for(i = 0; i < l->outputs*l->inputs; ++i) fprintf(fp, "%g,", l->weights[i]);
			fprintf(fp, "\n\n");
			}

			void print_crop_cfg(FILE fp, crop_layer l, network net, int count)
			{
			fprintf(fp, "[crop]\n");
			fprintf(fp, "crop_height=%d\ncrop_width=%d\nflip=%d\n\n", l->crop_height, l->crop_width, l->flip);
			}

			void print_maxpool_cfg(FILE fp, maxpool_layer l, network net, int count)
			{
			fprintf(fp, "[maxpool]\n");
			fprintf(fp, "size=%d\nstride=%d\n\n", l->size, l->stride);
			}

			void print_normalization_cfg(FILE fp, normalization_layer l, network net, int count)
			{
			fprintf(fp, "[localresponsenormalization]\n");
			fprintf(fp, "size=%d\n"
			"alpha=%g\n"
			"beta=%g\n"
			"kappa=%g\n\n", l->size, l->alpha, l->beta, l->kappa);
			}

			void print_softmax_cfg(FILE fp, softmax_layer l, network net, int count)
			{
			fprintf(fp, "[softmax]\n");
			fprintf(fp, "\n");
			}

			void print_detection_cfg(FILE fp, detection_layer l, network net, int count)
			{
			fprintf(fp, "[detection]\n");
			fprintf(fp, "classes=%d\ncoords=%d\nrescore=%d\n", l->classes, l->coords, l->rescore);
			fprintf(fp, "\n");
			}

			void print_cost_cfg(FILE fp, cost_layer l, network net, int count)
			{
			fprintf(fp, "[cost]\ntype=%s\n", get_cost_string(l->type));
			fprintf(fp, "\n");
			}

			void save_weights(network net, char *filename)
			{
			fprintf(stderr, "Saving weights to %s\n", filename);
			FILE *fp = fopen(filename, "w");
			if(!fp) file_error(filename);

			fwrite(&net.learning_rate, sizeof(float), 1, fp);
			fwrite(&net.momentum, sizeof(float), 1, fp);
			fwrite(&net.decay, sizeof(float), 1, fp);
			fwrite(&net.seen, sizeof(int), 1, fp);

			int i;
			for(i = 0; i < net.n; ++i){
			if(net.types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer ) net.layers[i];
			#ifdef GPU
			if(gpu_index >= 0){
			pull_convolutional_layer(layer);
			}
			#endif
			int num = layer.nlayer.clayer.size*layer.size;
			fwrite(layer.biases, sizeof(float), layer.n, fp);
			fwrite(layer.filters, sizeof(float), num, fp);
			}
			if(net.types[i] == DECONVOLUTIONAL){
			deconvolutional_layer layer = (deconvolutional_layer ) net.layers[i];
			#ifdef GPU
			if(gpu_index >= 0){
			pull_deconvolutional_layer(layer);
			}
			#endif
			int num = layer.nlayer.clayer.size*layer.size;
			fwrite(layer.biases, sizeof(float), layer.n, fp);
			fwrite(layer.filters, sizeof(float), num, fp);
			}
			if(net.types[i] == CONNECTED){
			connected_layer layer = (connected_layer ) net.layers[i];
			#ifdef GPU
			if(gpu_index >= 0){
			pull_connected_layer(layer);
			}
			#endif
			fwrite(layer.biases, sizeof(float), layer.outputs, fp);
			fwrite(layer.weights, sizeof(float), layer.outputs*layer.inputs, fp);
			}
			}
			fclose(fp);
			}

			void load_weights_upto(network net, char filename, int cutoff)
			{
			fprintf(stderr, "Loading weights from %s\n", filename);
			FILE *fp = fopen(filename, "r");
			if(!fp) file_error(filename);

			fread(&net->learning_rate, sizeof(float), 1, fp);
			fread(&net->momentum, sizeof(float), 1, fp);
			fread(&net->decay, sizeof(float), 1, fp);
			fread(&net->seen, sizeof(int), 1, fp);

			int i;
			for(i = 0; i < net->n && i < cutoff; ++i){
			if(net->types[i] == CONVOLUTIONAL){
			convolutional_layer layer = (convolutional_layer ) net->layers[i];
			int num = layer.nlayer.clayer.size*layer.size;
			fread(layer.biases, sizeof(float), layer.n, fp);
			fread(layer.filters, sizeof(float), num, fp);
			#ifdef GPU
			if(gpu_index >= 0){
			push_convolutional_layer(layer);
			}
			#endif
			}
			if(net->types[i] == DECONVOLUTIONAL){
			deconvolutional_layer layer = (deconvolutional_layer ) net->layers[i];
			int num = layer.nlayer.clayer.size*layer.size;
			fread(layer.biases, sizeof(float), layer.n, fp);
			fread(layer.filters, sizeof(float), num, fp);
			#ifdef GPU
			if(gpu_index >= 0){
			push_deconvolutional_layer(layer);
			}
			#endif
			}
			if(net->types[i] == CONNECTED){
			connected_layer layer = (connected_layer ) net->layers[i];
			fread(layer.biases, sizeof(float), layer.outputs, fp);
			fread(layer.weights, sizeof(float), layer.outputs*layer.inputs, fp);
			#ifdef GPU
			if(gpu_index >= 0){
			push_connected_layer(layer);
			}
			#endif
			}
			}
			fclose(fp);
			}

			void load_weights(network net, char filename)
			{
			load_weights_upto(net, filename, net->n);
			}

			void save_network(network net, char *filename)
			{
			FILE *fp = fopen(filename, "w");
			if(!fp) file_error(filename);
			int i;
			for(i = 0; i < net.n; ++i)
			{
			if(net.types[i] == CONVOLUTIONAL)
			print_convolutional_cfg(fp, (convolutional_layer *)net.layers[i], net, i);
			else if(net.types[i] == DECONVOLUTIONAL)
			print_deconvolutional_cfg(fp, (deconvolutional_layer *)net.layers[i], net, i);
			else if(net.types[i] == CONNECTED)
			print_connected_cfg(fp, (connected_layer *)net.layers[i], net, i);
			else if(net.types[i] == CROP)
			print_crop_cfg(fp, (crop_layer *)net.layers[i], net, i);
			else if(net.types[i] == MAXPOOL)
			print_maxpool_cfg(fp, (maxpool_layer *)net.layers[i], net, i);
			else if(net.types[i] == DROPOUT)
			print_dropout_cfg(fp, (dropout_layer *)net.layers[i], net, i);
			else if(net.types[i] == NORMALIZATION)
			print_normalization_cfg(fp, (normalization_layer *)net.layers[i], net, i);
			else if(net.types[i] == SOFTMAX)
			print_softmax_cfg(fp, (softmax_layer *)net.layers[i], net, i);
			else if(net.types[i] == DETECTION)
			print_detection_cfg(fp, (detection_layer *)net.layers[i], net, i);
			else if(net.types[i] == COST)
			print_cost_cfg(fp, (cost_layer *)net.layers[i], net, i);
			}
			fclose(fp);
			}