~speedprog/mtg/mtg_card_detector.git

			@@ -4,6 +4,8 @@
			#include "network.h"
			#include "image.h"
			#include "parser.h"
			#include "data.h"
			#include "matrix.h"

			#include <time.h>
			#include <stdlib.h>
			@@ -40,18 +42,19 @@
			int n = 3;
			int stride = 1;
			int size = 3;
			convolutional_layer layer = *make_convolutional_layer(dog.h, dog.w, dog.c, n, size, stride);
			convolutional_layer layer = *make_convolutional_layer(dog.h, dog.w, dog.c, n, size, stride, RELU);
			char buff[256];
			for(i = 0; i < n; ++i) {
			sprintf(buff, "Kernel %d", i);
			show_image(layer.kernels[i], buff);
			}
			run_convolutional_layer(dog, layer);
			forward_convolutional_layer(layer, dog.data);

			maxpool_layer mlayer = *make_maxpool_layer(layer.output.h, layer.output.w, layer.output.c, 2);
			run_maxpool_layer(layer.output,mlayer);
			image output = get_convolutional_image(layer);
			maxpool_layer mlayer = *make_maxpool_layer(output.h, output.w, output.c, 2);
			forward_maxpool_layer(mlayer, layer.output);

			show_image_layers(mlayer.output, "Test Maxpool Layer");
			show_image_layers(get_maxpool_image(mlayer), "Test Maxpool Layer");
			}

			void test_load()
			@@ -90,168 +93,144 @@
			show_image(random, "Test Rotate Random");
			}

			void test_network()
			{
			network net;
			net.n = 11;
			net.layers = calloc(net.n, sizeof(void *));
			net.types = calloc(net.n, sizeof(LAYER_TYPE));
			net.types[0] = CONVOLUTIONAL;
			net.types[1] = MAXPOOL;
			net.types[2] = CONVOLUTIONAL;
			net.types[3] = MAXPOOL;
			net.types[4] = CONVOLUTIONAL;
			net.types[5] = CONVOLUTIONAL;
			net.types[6] = CONVOLUTIONAL;
			net.types[7] = MAXPOOL;
			net.types[8] = CONNECTED;
			net.types[9] = CONNECTED;
			net.types[10] = CONNECTED;

			image dog = load_image("test_hinton.jpg");

			int n = 48;
			int stride = 4;
			int size = 11;
			convolutional_layer cl = *make_convolutional_layer(dog.h, dog.w, dog.c, n, size, stride);
			maxpool_layer ml = *make_maxpool_layer(cl.output.h, cl.output.w, cl.output.c, 2);

			n = 128;
			size = 5;
			stride = 1;
			convolutional_layer cl2 = *make_convolutional_layer(ml.output.h, ml.output.w, ml.output.c, n, size, stride);
			maxpool_layer ml2 = *make_maxpool_layer(cl2.output.h, cl2.output.w, cl2.output.c, 2);

			n = 192;
			size = 3;
			convolutional_layer cl3 = *make_convolutional_layer(ml2.output.h, ml2.output.w, ml2.output.c, n, size, stride);
			convolutional_layer cl4 = *make_convolutional_layer(cl3.output.h, cl3.output.w, cl3.output.c, n, size, stride);
			n = 128;
			convolutional_layer cl5 = *make_convolutional_layer(cl4.output.h, cl4.output.w, cl4.output.c, n, size, stride);
			maxpool_layer ml3 = *make_maxpool_layer(cl5.output.h, cl5.output.w, cl5.output.c, 4);
			connected_layer nl = make_connected_layer(ml3.output.hml3.output.w*ml3.output.c, 4096, RELU);
			connected_layer nl2 = *make_connected_layer(4096, 4096, RELU);
			connected_layer nl3 = *make_connected_layer(4096, 1000, RELU);

			net.layers[0] = &cl;
			net.layers[1] = &ml;
			net.layers[2] = &cl2;
			net.layers[3] = &ml2;
			net.layers[4] = &cl3;
			net.layers[5] = &cl4;
			net.layers[6] = &cl5;
			net.layers[7] = &ml3;
			net.layers[8] = &nl;
			net.layers[9] = &nl2;
			net.layers[10] = &nl3;

			int i;
			clock_t start = clock(), end;
			for(i = 0; i < 10; ++i){
			run_network(dog, net);
			rotate_image(dog);
			}
			end = clock();
			printf("Ran %lf second per iteration\n", (double)(end-start)/CLOCKS_PER_SEC/10);

			show_image_layers(get_network_image(net), "Test Network Layer");
			}

			void test_backpropagate()
			{
			int n = 3;
			int size = 4;
			int stride = 10;
			image dog = load_image("dog.jpg");
			show_image(dog, "Test Backpropagate Input");
			image dog_copy = copy_image(dog);
			convolutional_layer cl = *make_convolutional_layer(dog.h, dog.w, dog.c, n, size, stride);
			run_convolutional_layer(dog, cl);
			show_image(cl.output, "Test Backpropagate Output");
			int i;
			clock_t start = clock(), end;
			for(i = 0; i < 100; ++i){
			backpropagate_convolutional_layer(dog_copy, cl);
			}
			end = clock();
			printf("Backpropagate: %lf seconds\n", (double)(end-start)/CLOCKS_PER_SEC);
			start = clock();
			for(i = 0; i < 100; ++i){
			backpropagate_convolutional_layer_convolve(dog, cl);
			}
			end = clock();
			printf("Backpropagate Using Convolutions: %lf seconds\n", (double)(end-start)/CLOCKS_PER_SEC);
			show_image(dog_copy, "Test Backpropagate 1");
			show_image(dog, "Test Backpropagate 2");
			subtract_image(dog, dog_copy);
			show_image(dog, "Test Backpropagate Difference");
			}

			void test_ann()
			{
			network net;
			net.n = 3;
			net.layers = calloc(net.n, sizeof(void *));
			net.types = calloc(net.n, sizeof(LAYER_TYPE));
			net.types[0] = CONNECTED;
			net.types[1] = CONNECTED;
			net.types[2] = CONNECTED;

			connected_layer nl = *make_connected_layer(1, 20, RELU);
			connected_layer nl2 = *make_connected_layer(20, 20, RELU);
			connected_layer nl3 = *make_connected_layer(20, 1, RELU);

			net.layers[0] = &nl;
			net.layers[1] = &nl2;
			net.layers[2] = &nl3;

			image t = make_image(1,1,1);
			int count = 0;

			double avgerr = 0;
			while(1){
			double v = ((double)rand()/RAND_MAX);
			double truth = v*v;
			set_pixel(t,0,0,0,v);
			run_network(t, net);
			double *out = get_network_output(net);
			double err = pow((out[0]-truth),2.);
			avgerr = .99 * avgerr + .01 * err;
			//if(++count % 100000 == 0) printf("%f\n", avgerr);
			if(++count % 100000 == 0) printf("%f %f :%f AVG %f \n", truth, out[0], err, avgerr);
			out[0] = truth - out[0];
			learn_network(t, net);
			update_network(net, .001);
			}

			}

			void test_parser()
			{
			network net = parse_network_cfg("test.cfg");
			image t = make_image(1,1,1);
			network net = parse_network_cfg("test_parser.cfg");
			double input[1];
			int count = 0;

			double avgerr = 0;
			while(1){
			double v = ((double)rand()/RAND_MAX);
			double truth = v*v;
			set_pixel(t,0,0,0,v);
			run_network(t, net);
			input[0] = v;
			forward_network(net, input);
			double *out = get_network_output(net);
			double *delta = get_network_delta(net);
			double err = pow((out[0]-truth),2.);
			avgerr = .99 * avgerr + .01 * err;
			//if(++count % 100000 == 0) printf("%f\n", avgerr);
			if(++count % 100000 == 0) printf("%f %f :%f AVG %f \n", truth, out[0], err, avgerr);
			out[0] = truth - out[0];
			learn_network(t, net);
			if(++count % 1000000 == 0) printf("%f %f :%f AVG %f \n", truth, out[0], err, avgerr);
			delta[0] = truth - out[0];
			learn_network(net, input);
			update_network(net, .001);
			}
			}

			void test_data()
			{
			batch train = random_batch("train_paths.txt", 101);
			show_image(train.images[0], "Test Data Loading");
			show_image(train.images[100], "Test Data Loading");
			show_image(train.images[10], "Test Data Loading");
			free_batch(train);
			}

			void test_train()
			{
			network net = parse_network_cfg("test.cfg");
			srand(0);
			//visualize_network(net);
			int i = 1000;
			//while(1){
			while(i > 0){
			batch train = random_batch("train_paths.txt", 100);
			train_network_batch(net, train);
			//show_image_layers(get_network_image(net), "hey");
			//visualize_network(net);
			//cvWaitKey(0);
			free_batch(train);
			--i;
			}
			//}
			}

			double error_network(network net, matrix m, double *truth)
			{
			int i;
			int correct = 0;
			for(i = 0; i < m.rows; ++i){
			forward_network(net, m.vals[i]);
			double *out = get_network_output(net);
			double err = truth[i] - out[0];
			if(fabs(err) < .5) ++correct;
			}
			return (double)correct/m.rows;
			}

			void classify_random_filters()
			{
			network net = parse_network_cfg("random_filter_finish.cfg");
			matrix m = csv_to_matrix("train.csv");
			matrix ho = hold_out_matrix(&m, 2500);
			double *truth = pop_column(&m, 0);
			double *ho_truth = pop_column(&ho, 0);
			int i;
			clock_t start = clock(), end;
			int count = 0;
			while(++count <= 300){
			for(i = 0; i < m.rows; ++i){
			int index = rand()%m.rows;
			//image p = double_to_image(1690,1,1,m.vals[index]);
			//normalize_image(p);
			forward_network(net, m.vals[index]);
			double *out = get_network_output(net);
			double *delta = get_network_delta(net);
			//printf("%f\n", out[0]);
			delta[0] = truth[index] - out[0];
			// printf("%f\n", delta[0]);
			//printf("%f %f\n", truth[index], out[0]);
			learn_network(net, m.vals[index]);
			update_network(net, .000005);
			}
			double test_acc = error_network(net, m, truth);
			double valid_acc = error_network(net, ho, ho_truth);
			printf("%f, %f\n", test_acc, valid_acc);
			fprintf(stderr, "%5d: %f Valid: %f\n",count, test_acc, valid_acc);
			//if(valid_acc > .70) break;
			}
			end = clock();
			FILE *fp = fopen("submission/out.txt", "w");
			matrix test = csv_to_matrix("test.csv");
			truth = pop_column(&test, 0);
			for(i = 0; i < test.rows; ++i){
			forward_network(net, test.vals[i]);
			double *out = get_network_output(net);
			if(fabs(out[0]) < .5) fprintf(fp, "0\n");
			else fprintf(fp, "1\n");
			}
			fclose(fp);
			printf("Neural Net Learning: %lf seconds\n", (double)(end-start)/CLOCKS_PER_SEC);
			}

			void test_random_filters()
			{
			FILE *file = fopen("test.csv", "w");
			int i,j,k;
			srand(0);
			network net = parse_network_cfg("test_random_filter.cfg");
			for(i = 0; i < 100; ++i){
			printf("%d\n", i);
			batch part = get_batch("test_paths.txt", i, 100);
			for(j = 0; j < part.n; ++j){
			forward_network(net, part.images[j].data);
			double *out = get_network_output(net);
			fprintf(file, "%f", part.truth[j][0]);
			for(k = 0; k < get_network_output_size(net); ++k){
			fprintf(file, ",%f", out[k]);
			}
			fprintf(file, "\n");
			}
			free_batch(part);
			}
			}

			int main()
			{
			test_parser();
			//classify_random_filters();
			//test_random_filters();
			test_train();
			//test_parser();
			//test_backpropagate();
			//test_ann();
			//test_convolve();