~speedprog/mtg/mtg_card_detector.git

			@@ -1,4 +1,5 @@
			#include "connected_layer.h"
			//#include "old_conv.h"
			#include "convolutional_layer.h"
			#include "maxpool_layer.h"
			#include "network.h"
			@@ -7,6 +8,7 @@
			#include "data.h"
			#include "matrix.h"
			#include "utils.h"
			#include "mini_blas.h"

			#include <time.h>
			#include <stdlib.h>
			@@ -28,35 +30,41 @@
			show_image_layers(edge, "Test Convolve");
			}

			void test_convolve_matrix()
			{
			image dog = load_image("dog.jpg");
			printf("dog channels %d\n", dog.c);

			int size = 11;
			int stride = 4;
			int n = 40;
			double filters = make_random_image(size, size, dog.cn).data;

			int mw = ((dog.h-size)/stride+1)*((dog.w-size)/stride+1);
			int mh = (sizesizedog.c);
			double matrix = calloc(mhmw, sizeof(double));

			image edge = make_image((dog.h-size)/stride+1, (dog.w-size)/stride+1, n);


			int i;
			clock_t start = clock(), end;
			for(i = 0; i < 1000; ++i){
			im2col_cpu(dog.data, dog.c, dog.h, dog.w, size, stride, matrix);
			gemm(0,0,n,mw,mh,1,filters,mh,matrix,mw,1,edge.data,mw);
			}
			end = clock();
			printf("Convolutions: %lf seconds\n", (double)(end-start)/CLOCKS_PER_SEC);
			show_image_layers(edge, "Test Convolve");
			cvWaitKey(0);
			}

			void test_color()
			{
			image dog = load_image("test_color.png");
			show_image_layers(dog, "Test Color");
			}

			void test_convolutional_layer()
			{
			srand(0);
			image dog = load_image("dog.jpg");
			int i;
			int n = 3;
			int stride = 1;
			int size = 3;
			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);
			}
			forward_convolutional_layer(layer, dog.data);

			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(get_maxpool_image(mlayer), "Test Maxpool Layer");
			}

			void verify_convolutional_layer()
			{
			srand(0);
			@@ -87,7 +95,7 @@
			image out_delta = get_convolutional_delta(layer);
			for(i = 0; i < out.hout.wout.c; ++i){
			out_delta.data[i] = 1;
			backward_convolutional_layer(layer, test.data, in_delta.data);
			//backward_convolutional_layer(layer, test.data, in_delta.data);
			image partial = copy_image(in_delta);
			jacobian2[i] = partial.data;
			out_delta.data[i] = 0;
			@@ -199,7 +207,7 @@
			{
			srand(444444);
			srand(888888);
			network net = parse_network_cfg("nist.cfg");
			network net = parse_network_cfg("nist_basic.cfg");
			data train = load_categorical_data_csv("mnist/mnist_train.csv", 0, 10);
			data test = load_categorical_data_csv("mnist/mnist_test.csv",0,10);
			normalize_data_rows(train);
			@@ -210,16 +218,16 @@
			double momentum = .9;
			double decay = 0.01;
			clock_t start = clock(), end;
			while(++count <= 1000){
			double acc = train_network_sgd(net, train, 6400, lr, momentum, decay);
			printf("%5d Training Loss: %lf, Params: %f %f %f, ",count*100, 1.-acc, lr, momentum, decay);
			while(++count <= 100){
			visualize_network(net);
			double loss = train_network_sgd(net, train, 10000, lr, momentum, decay);
			printf("%5d Training Loss: %lf, Params: %f %f %f, ",count*100, loss, lr, momentum, decay);
			end = clock();
			printf("Time: %lf seconds\n", (double)(end-start)/CLOCKS_PER_SEC);
			start=end;
			visualize_network(net);
			cvWaitKey(100);
			//lr /= 2;
			if(count%5 == 0 && 0){
			if(count%5 == 0){
			double train_acc = network_accuracy(net, train);
			fprintf(stderr, "\nTRAIN: %f\n", train_acc);
			double test_acc = network_accuracy(net, test);
			@@ -238,11 +246,9 @@
			data test = load_categorical_data_csv("mnist/mnist_test.csv", 0,10);
			normalize_data_rows(test);
			data train = d;
			/*
			data *split = split_data(d, 1, 10);
			data train = split[0];
			data test = split[1];
			*/
			// data *split = split_data(d, 1, 10);
			// data train = split[0];
			// data test = split[1];
			matrix prediction = make_matrix(test.y.rows, test.y.cols);
			int n = 30;
			for(i = 0; i < n; ++i){
			@@ -268,22 +274,6 @@
			printf("Full Ensemble Accuracy: %lf\n", acc);
			}

			void test_kernel_update()
			{
			srand(0);
			double delta[] = {.1};
			double input[] = {.3, .5, .3, .5, .5, .5, .5, .0, .5};
			double kernel[] = {1,2,3,4,5,6,7,8,9};
			convolutional_layer layer = *make_convolutional_layer(3, 3, 1, 1, 3, 1, LINEAR);
			layer.kernels[0].data = kernel;
			layer.delta = delta;
			learn_convolutional_layer(layer, input);
			print_image(layer.kernels[0]);
			print_image(get_convolutional_delta(layer));
			print_image(layer.kernel_updates[0]);

			}

			void test_random_classify()
			{
			network net = parse_network_cfg("connected.cfg");
			@@ -336,10 +326,55 @@
			printf("%d, %d, %d\n", train.X.rows, split[0].X.rows, split[1].X.rows);
			}

			double *random_matrix(int rows, int cols)
			{
			int i, j;
			double m = calloc(rowscols, sizeof(double));
			for(i = 0; i < rows; ++i){
			for(j = 0; j < cols; ++j){
			m[i*cols+j] = (double)rand()/RAND_MAX;
			}
			}
			return m;
			}

			void test_blas()
			{
			int m = 1000, n = 1000, k = 1000;
			double *a = random_matrix(m,k);
			double *b = random_matrix(k,n);
			double *c = random_matrix(m,n);
			int i;
			for(i = 0; i<1000; ++i){
			gemm(0,0,m,n,k,1,a,k,b,n,1,c,n);
			}
			}

			void test_im2row()
			{
			int h = 20;
			int w = 20;
			int c = 3;
			int stride = 1;
			int size = 11;
			image test = make_random_image(h,w,c);
			int mc = 1;
			int mw = ((h-size)/stride+1)*((w-size)/stride+1);
			int mh = (sizesizec);
			int msize = mcmwmh;
			double *matrix = calloc(msize, sizeof(double));
			int i;
			for(i = 0; i < 1000; ++i){
			im2col_cpu(test.data, c, h, w, size, stride, matrix);
			image render = double_to_image(mh, mw, mc, matrix);
			}
			}

			int main()
			{
			//test_kernel_update();
			//test_blas();
			//test_convolve_matrix();
			// test_im2row();
			//test_split();
			//test_ensemble();
			test_nist();