darknet/src/cnn.c

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#include "connected_layer.h"
#include "convolutional_layer.h"
#include "maxpool_layer.h"
#include "network.h"
#include "image.h"
#include "parser.h"
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#include "data.h"
#include "matrix.h"
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#include "utils.h"
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#include "mini_blas.h"
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#include <time.h>
#include <stdlib.h>
#include <stdio.h>
#define _GNU_SOURCE
#include <fenv.h>
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void test_convolve()
{
image dog = load_image("dog.jpg",300,400);
printf("dog channels %d\n", dog.c);
image kernel = make_random_image(3,3,dog.c);
image edge = make_image(dog.h, dog.w, 1);
int i;
clock_t start = clock(), end;
for(i = 0; i < 1000; ++i){
convolve(dog, kernel, 1, 0, edge, 1);
}
end = clock();
printf("Convolutions: %lf seconds\n", (float)(end-start)/CLOCKS_PER_SEC);
show_image_layers(edge, "Test Convolve");
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}
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#ifdef GPU
void test_convolutional_layer()
{
int i;
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image dog = load_image("data/dog.jpg",224,224);
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network net = parse_network_cfg("cfg/convolutional.cfg");
// data test = load_cifar10_data("data/cifar10/test_batch.bin");
// float *X = calloc(net.batch*test.X.cols, sizeof(float));
// float *y = calloc(net.batch*test.y.cols, sizeof(float));
int in_size = get_network_input_size(net)*net.batch;
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int del_size = get_network_output_size_layer(net, 0)*net.batch;
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int size = get_network_output_size(net)*net.batch;
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float *X = calloc(in_size, sizeof(float));
float *y = calloc(size, sizeof(float));
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for(i = 0; i < in_size; ++i){
X[i] = dog.data[i%get_network_input_size(net)];
}
// get_batch(test, net.batch, X, y);
clock_t start, end;
cl_mem input_cl = cl_make_array(X, in_size);
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cl_mem truth_cl = cl_make_array(y, size);
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forward_network_gpu(net, input_cl, truth_cl, 1);
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start = clock();
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forward_network_gpu(net, input_cl, truth_cl, 1);
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end = clock();
float gpu_sec = (float)(end-start)/CLOCKS_PER_SEC;
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printf("forward gpu: %f sec\n", gpu_sec);
start = clock();
backward_network_gpu(net, input_cl);
end = clock();
gpu_sec = (float)(end-start)/CLOCKS_PER_SEC;
printf("backward gpu: %f sec\n", gpu_sec);
//float gpu_cost = get_network_cost(net);
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float *gpu_out = calloc(size, sizeof(float));
memcpy(gpu_out, get_network_output(net), size*sizeof(float));
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float *gpu_del = calloc(del_size, sizeof(float));
memcpy(gpu_del, get_network_delta_layer(net, 0), del_size*sizeof(float));
/*
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start = clock();
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forward_network(net, X, y, 1);
backward_network(net, X);
float cpu_cost = get_network_cost(net);
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end = clock();
float cpu_sec = (float)(end-start)/CLOCKS_PER_SEC;
float *cpu_out = calloc(size, sizeof(float));
memcpy(cpu_out, get_network_output(net), size*sizeof(float));
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float *cpu_del = calloc(del_size, sizeof(float));
memcpy(cpu_del, get_network_delta_layer(net, 0), del_size*sizeof(float));
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float sum = 0;
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float del_sum = 0;
for(i = 0; i < size; ++i) sum += pow(gpu_out[i] - cpu_out[i], 2);
for(i = 0; i < del_size; ++i) {
//printf("%f %f\n", cpu_del[i], gpu_del[i]);
del_sum += pow(cpu_del[i] - gpu_del[i], 2);
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}
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printf("GPU cost: %f, CPU cost: %f\n", gpu_cost, cpu_cost);
printf("gpu: %f sec, cpu: %f sec, diff: %f, delta diff: %f, size: %d\n", gpu_sec, cpu_sec, sum, del_sum, size);
*/
}
void test_col2im()
{
float col[] = {1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2,
1,2,1,2};
float im[16] = {0};
int batch = 1;
int channels = 1;
int height=4;
int width=4;
int ksize = 3;
int stride = 1;
int pad = 0;
col2im_gpu(col, batch,
channels, height, width,
ksize, stride, pad, im);
int i;
for(i = 0; i < 16; ++i)printf("%f,", im[i]);
printf("\n");
/*
float data_im[] = {
1,2,3,4,
5,6,7,8,
9,10,11,12
};
float data_col[18] = {0};
im2col_cpu(data_im, batch,
channels, height, width,
ksize, stride, pad, data_col) ;
for(i = 0; i < 18; ++i)printf("%f,", data_col[i]);
printf("\n");
*/
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}
#endif
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void test_convolve_matrix()
{
image dog = load_image("dog.jpg",300,400);
printf("dog channels %d\n", dog.c);
int size = 11;
int stride = 4;
int n = 40;
float *filters = make_random_image(size, size, dog.c*n).data;
int mw = ((dog.h-size)/stride+1)*((dog.w-size)/stride+1);
int mh = (size*size*dog.c);
float *matrix = calloc(mh*mw, sizeof(float));
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){
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im2col_cpu(dog.data,1, dog.c, dog.h, dog.w, size, stride, 0, matrix);
gemm(0,0,n,mw,mh,1,filters,mh,matrix,mw,1,edge.data,mw);
}
end = clock();
printf("Convolutions: %lf seconds\n", (float)(end-start)/CLOCKS_PER_SEC);
show_image_layers(edge, "Test Convolve");
cvWaitKey(0);
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}
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void test_color()
{
image dog = load_image("test_color.png", 300, 400);
show_image_layers(dog, "Test Color");
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}
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void verify_convolutional_layer()
{
srand(0);
int i;
int n = 1;
int stride = 1;
int size = 3;
float eps = .00000001;
image test = make_random_image(5,5, 1);
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convolutional_layer layer = *make_convolutional_layer(1,test.h,test.w,test.c, n, size, stride, 0, RELU,0,0,0);
image out = get_convolutional_image(layer);
float **jacobian = calloc(test.h*test.w*test.c, sizeof(float));
forward_convolutional_layer(layer, test.data);
image base = copy_image(out);
for(i = 0; i < test.h*test.w*test.c; ++i){
test.data[i] += eps;
forward_convolutional_layer(layer, test.data);
image partial = copy_image(out);
subtract_image(partial, base);
scale_image(partial, 1/eps);
jacobian[i] = partial.data;
test.data[i] -= eps;
}
float **jacobian2 = calloc(out.h*out.w*out.c, sizeof(float));
image in_delta = make_image(test.h, test.w, test.c);
image out_delta = get_convolutional_delta(layer);
for(i = 0; i < out.h*out.w*out.c; ++i){
out_delta.data[i] = 1;
backward_convolutional_layer(layer, in_delta.data);
image partial = copy_image(in_delta);
jacobian2[i] = partial.data;
out_delta.data[i] = 0;
}
int j;
float *j1 = calloc(test.h*test.w*test.c*out.h*out.w*out.c, sizeof(float));
float *j2 = calloc(test.h*test.w*test.c*out.h*out.w*out.c, sizeof(float));
for(i = 0; i < test.h*test.w*test.c; ++i){
for(j =0 ; j < out.h*out.w*out.c; ++j){
j1[i*out.h*out.w*out.c + j] = jacobian[i][j];
j2[i*out.h*out.w*out.c + j] = jacobian2[j][i];
printf("%f %f\n", jacobian[i][j], jacobian2[j][i]);
}
}
image mj1 = float_to_image(test.w*test.h*test.c, out.w*out.h*out.c, 1, j1);
image mj2 = float_to_image(test.w*test.h*test.c, out.w*out.h*out.c, 1, j2);
printf("%f %f\n", avg_image_layer(mj1,0), avg_image_layer(mj2,0));
show_image(mj1, "forward jacobian");
show_image(mj2, "backward jacobian");
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}
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void test_load()
{
image dog = load_image("dog.jpg", 300, 400);
show_image(dog, "Test Load");
show_image_layers(dog, "Test Load");
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}
void test_upsample()
{
image dog = load_image("dog.jpg", 300, 400);
int n = 3;
image up = make_image(n*dog.h, n*dog.w, dog.c);
upsample_image(dog, n, up);
show_image(up, "Test Upsample");
show_image_layers(up, "Test Upsample");
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}
void test_rotate()
{
int i;
image dog = load_image("dog.jpg",300,400);
clock_t start = clock(), end;
for(i = 0; i < 1001; ++i){
rotate_image(dog);
}
end = clock();
printf("Rotations: %lf seconds\n", (float)(end-start)/CLOCKS_PER_SEC);
show_image(dog, "Test Rotate");
image random = make_random_image(3,3,3);
show_image(random, "Test Rotate Random");
rotate_image(random);
show_image(random, "Test Rotate Random");
rotate_image(random);
show_image(random, "Test Rotate Random");
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}
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void test_parser()
{
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network net = parse_network_cfg("cfg/test_parser.cfg");
save_network(net, "cfg/test_parser_1.cfg");
network net2 = parse_network_cfg("cfg/test_parser_1.cfg");
save_network(net2, "cfg/test_parser_2.cfg");
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}
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void test_data()
{
char *labels[] = {"cat","dog"};
data train = load_data_image_pathfile_random("train_paths.txt", 101,labels, 2, 300, 400);
free_data(train);
}
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void train_assira()
{
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network net = parse_network_cfg("cfg/assira.cfg");
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int imgs = 1000/net.batch+1;
//imgs = 1;
srand(2222222);
int i = 0;
char *labels[] = {"cat","dog"};
while(1){
i += 1000;
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data train = load_data_image_pathfile_random("data/assira/train.list", imgs*net.batch, labels, 2, 256, 256);
normalize_data_rows(train);
clock_t start = clock(), end;
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float loss = train_network_sgd_gpu(net, train, imgs);
end = clock();
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printf("%d: %f, Time: %lf seconds\n", i, loss, (float)(end-start)/CLOCKS_PER_SEC );
free_data(train);
if(i%10000==0){
char buff[256];
sprintf(buff, "cfg/assira_backup_%d.cfg", i);
save_network(net, buff);
}
//lr *= .99;
}
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}
void test_visualize()
{
network net = parse_network_cfg("cfg/voc_imagenet.cfg");
srand(2222222);
visualize_network(net);
cvWaitKey(0);
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}
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void test_full()
{
network net = parse_network_cfg("cfg/backup_1300.cfg");
srand(2222222);
int i,j;
int total = 100;
char *labels[] = {"cat","dog"};
FILE *fp = fopen("preds.txt","w");
for(i = 0; i < total; ++i){
visualize_network(net);
cvWaitKey(100);
data test = load_data_image_pathfile_part("images/assira/test.list", i, total, labels, 2, 256, 256);
image im = float_to_image(256, 256, 3,test.X.vals[0]);
show_image(im, "input");
cvWaitKey(100);
normalize_data_rows(test);
for(j = 0; j < test.X.rows; ++j){
float *x = test.X.vals[j];
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forward_network(net, x, 0, 0);
int class = get_predicted_class_network(net);
fprintf(fp, "%d\n", class);
}
free_data(test);
}
fclose(fp);
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}
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void test_cifar10()
{
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network net = parse_network_cfg("cfg/cifar10_part5.cfg");
data test = load_cifar10_data("data/cifar10/test_batch.bin");
clock_t start = clock(), end;
float test_acc = network_accuracy(net, test);
end = clock();
printf("%f in %f Sec\n", test_acc, (float)(end-start)/CLOCKS_PER_SEC);
visualize_network(net);
cvWaitKey(0);
}
void train_cifar10()
{
srand(555555);
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network net = parse_network_cfg("cfg/cifar10.cfg");
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data test = load_cifar10_data("data/cifar10/test_batch.bin");
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int count = 0;
int iters = 10000/net.batch;
data train = load_all_cifar10();
while(++count <= 10000){
clock_t start = clock(), end;
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float loss = train_network_sgd(net, train, iters);
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end = clock();
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//visualize_network(net);
//cvWaitKey(5000);
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//float test_acc = network_accuracy(net, test);
//printf("%d: Loss: %f, Test Acc: %f, Time: %lf seconds, LR: %f, Momentum: %f, Decay: %f\n", count, loss, test_acc,(float)(end-start)/CLOCKS_PER_SEC, net.learning_rate, net.momentum, net.decay);
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if(count%10 == 0){
float test_acc = network_accuracy(net, test);
printf("%d: Loss: %f, Test Acc: %f, Time: %lf seconds, LR: %f, Momentum: %f, Decay: %f\n", count, loss, test_acc,(float)(end-start)/CLOCKS_PER_SEC, net.learning_rate, net.momentum, net.decay);
char buff[256];
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sprintf(buff, "/home/pjreddie/cifar/cifar10_2_%d.cfg", count);
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save_network(net, buff);
}else{
printf("%d: Loss: %f, Time: %lf seconds, LR: %f, Momentum: %f, Decay: %f\n", count, loss, (float)(end-start)/CLOCKS_PER_SEC, net.learning_rate, net.momentum, net.decay);
}
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}
free_data(train);
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}
void test_vince()
{
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network net = parse_network_cfg("cfg/vince.cfg");
data train = load_categorical_data_csv("images/vince.txt", 144, 2);
normalize_data_rows(train);
int count = 0;
//float lr = .00005;
//float momentum = .9;
//float decay = 0.0001;
//decay = 0;
int batch = 10000;
while(++count <= 10000){
float loss = train_network_sgd(net, train, batch);
printf("%5f %5f\n",(double)count*batch/train.X.rows, loss);
}
}
void test_nist_single()
{
srand(222222);
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network net = parse_network_cfg("cfg/nist_single.cfg");
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data train = load_categorical_data_csv("data/mnist/mnist_tiny.csv", 0, 10);
normalize_data_rows(train);
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float loss = train_network_sgd(net, train, 1);
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printf("Loss: %f, LR: %f, Momentum: %f, Decay: %f\n", loss, net.learning_rate, net.momentum, net.decay);
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}
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void test_nist()
{
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srand(222222);
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network net = parse_network_cfg("cfg/nist_final.cfg");
data test = load_categorical_data_csv("data/mnist/mnist_test.csv",0,10);
translate_data_rows(test, -144);
clock_t start = clock(), end;
float test_acc = network_accuracy_multi(net, test,16);
end = clock();
printf("Accuracy: %f, Time: %lf seconds\n", test_acc,(float)(end-start)/CLOCKS_PER_SEC);
}
void train_nist()
{
srand(222222);
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network net = parse_network_cfg("cfg/nist.cfg");
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data train = load_categorical_data_csv("data/mnist/mnist_train.csv", 0, 10);
data test = load_categorical_data_csv("data/mnist/mnist_test.csv",0,10);
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translate_data_rows(train, -144);
//scale_data_rows(train, 1./128);
translate_data_rows(test, -144);
//scale_data_rows(test, 1./128);
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//randomize_data(train);
int count = 0;
//clock_t start = clock(), end;
int iters = 10000/net.batch;
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while(++count <= 2000){
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clock_t start = clock(), end;
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float loss = train_network_sgd_gpu(net, train, iters);
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end = clock();
float test_acc = network_accuracy(net, test);
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//float test_acc = 0;
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printf("%d: Loss: %f, Test Acc: %f, Time: %lf seconds, LR: %f, Momentum: %f, Decay: %f\n", count, loss, test_acc,(float)(end-start)/CLOCKS_PER_SEC, net.learning_rate, net.momentum, net.decay);
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/*printf("%f %f %f %f %f\n", mean_array(get_network_output_layer(net,0), 100),
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mean_array(get_network_output_layer(net,1), 100),
mean_array(get_network_output_layer(net,2), 100),
mean_array(get_network_output_layer(net,3), 100),
mean_array(get_network_output_layer(net,4), 100));
*/
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//save_network(net, "cfg/nist_final2.cfg");
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//printf("%5d Training Loss: %lf, Params: %f %f %f, ",count*1000, loss, lr, momentum, decay);
//end = clock();
//printf("Time: %lf seconds\n", (float)(end-start)/CLOCKS_PER_SEC);
//start=end;
//lr *= .5;
}
//save_network(net, "cfg/nist_basic_trained.cfg");
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}
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void test_ensemble()
{
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int i;
srand(888888);
data d = load_categorical_data_csv("mnist/mnist_train.csv", 0, 10);
normalize_data_rows(d);
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];
matrix prediction = make_matrix(test.y.rows, test.y.cols);
int n = 30;
for(i = 0; i < n; ++i){
int count = 0;
float lr = .0005;
float momentum = .9;
float decay = .01;
network net = parse_network_cfg("nist.cfg");
while(++count <= 15){
float acc = train_network_sgd(net, train, train.X.rows);
printf("Training Accuracy: %lf Learning Rate: %f Momentum: %f Decay: %f\n", acc, lr, momentum, decay );
lr /= 2;
}
matrix partial = network_predict_data(net, test);
float acc = matrix_accuracy(test.y, partial);
printf("Model Accuracy: %lf\n", acc);
matrix_add_matrix(partial, prediction);
acc = matrix_accuracy(test.y, prediction);
printf("Current Ensemble Accuracy: %lf\n", acc);
free_matrix(partial);
}
float acc = matrix_accuracy(test.y, prediction);
printf("Full Ensemble Accuracy: %lf\n", acc);
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}
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void test_random_classify()
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{
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network net = parse_network_cfg("connected.cfg");
matrix m = csv_to_matrix("train.csv");
//matrix ho = hold_out_matrix(&m, 2500);
float *truth = pop_column(&m, 0);
//float *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 = float_to_image(1690,1,1,m.vals[index]);
//normalize_image(p);
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forward_network(net, m.vals[index], 0, 1);
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float *out = get_network_output(net);
float *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]);
//backward_network(net, m.vals[index], );
update_network(net);
}
//float test_acc = error_network(net, m, truth);
//float 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){
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forward_network(net, test.vals[i],0, 0);
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float *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", (float)(end-start)/CLOCKS_PER_SEC);
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}
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void test_split()
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{
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data train = load_categorical_data_csv("mnist/mnist_train.csv", 0, 10);
data *split = split_data(train, 0, 13);
printf("%d, %d, %d\n", train.X.rows, split[0].X.rows, split[1].X.rows);
}
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void test_im2row()
{
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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 = (size*size*c);
int msize = mc*mw*mh;
float *matrix = calloc(msize, sizeof(float));
int i;
for(i = 0; i < 1000; ++i){
im2col_cpu(test.data,1, c, h, w, size, stride, 0, matrix);
//image render = float_to_image(mh, mw, mc, matrix);
}
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}
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void flip_network()
{
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network net = parse_network_cfg("cfg/voc_imagenet_orig.cfg");
save_network(net, "cfg/voc_imagenet_rev.cfg");
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}
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void tune_VOC()
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{
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network net = parse_network_cfg("cfg/voc_start.cfg");
srand(2222222);
int i = 20;
char *labels[] = {"aeroplane","bicycle","bird","boat","bottle","bus","car","cat","chair","cow","diningtable","dog","horse","motorbike","person","pottedplant","sheep","sofa","train","tvmonitor"};
float lr = .000005;
float momentum = .9;
float decay = 0.0001;
while(i++ < 1000 || 1){
data train = load_data_image_pathfile_random("/home/pjreddie/VOC2012/trainval_paths.txt", 10, labels, 20, 256, 256);
image im = float_to_image(256, 256, 3,train.X.vals[0]);
show_image(im, "input");
visualize_network(net);
cvWaitKey(100);
translate_data_rows(train, -144);
clock_t start = clock(), end;
float loss = train_network_sgd(net, train, 10);
end = clock();
printf("%d: %f, Time: %lf seconds, LR: %f, Momentum: %f, Decay: %f\n", i, loss, (float)(end-start)/CLOCKS_PER_SEC, lr, momentum, decay);
free_data(train);
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/*
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if(i%10==0){
char buff[256];
sprintf(buff, "/home/pjreddie/voc_cfg/voc_ramp_%d.cfg", i);
save_network(net, buff);
}
*/
//lr *= .99;
}
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}
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int voc_size(int x)
{
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x = x-1+3;
x = x-1+3;
x = x-1+3;
x = (x-1)*2+1;
x = x-1+5;
x = (x-1)*2+1;
x = (x-1)*4+11;
return x;
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}
image features_output_size(network net, IplImage *src, int outh, int outw)
{
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int h = voc_size(outh);
int w = voc_size(outw);
fprintf(stderr, "%d %d\n", h, w);
IplImage *sized = cvCreateImage(cvSize(w,h), src->depth, src->nChannels);
cvResize(src, sized, CV_INTER_LINEAR);
image im = ipl_to_image(sized);
//normalize_array(im.data, im.h*im.w*im.c);
translate_image(im, -144);
resize_network(net, im.h, im.w, im.c);
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forward_network(net, im.data, 0, 0);
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image out = get_network_image(net);
free_image(im);
cvReleaseImage(&sized);
return copy_image(out);
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}
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void features_VOC_image_size(char *image_path, int h, int w)
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{
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int j;
network net = parse_network_cfg("cfg/voc_imagenet.cfg");
fprintf(stderr, "%s\n", image_path);
IplImage* src = 0;
if( (src = cvLoadImage(image_path,-1)) == 0 ) file_error(image_path);
image out = features_output_size(net, src, h, w);
for(j = 0; j < out.c*out.h*out.w; ++j){
if(j != 0) printf(",");
printf("%g", out.data[j]);
}
printf("\n");
free_image(out);
cvReleaseImage(&src);
}
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void visualize_imagenet_topk(char *filename)
{
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int i,j,k,l;
int topk = 10;
network net = parse_network_cfg("cfg/voc_imagenet.cfg");
list *plist = get_paths(filename);
node *n = plist->front;
int h = voc_size(1), w = voc_size(1);
int num = get_network_image(net).c;
image **vizs = calloc(num, sizeof(image*));
float **score = calloc(num, sizeof(float *));
for(i = 0; i < num; ++i){
vizs[i] = calloc(topk, sizeof(image));
for(j = 0; j < topk; ++j) vizs[i][j] = make_image(h,w,3);
score[i] = calloc(topk, sizeof(float));
}
int count = 0;
while(n){
++count;
char *image_path = (char *)n->val;
image im = load_image(image_path, 0, 0);
n = n->next;
if(im.h < 200 || im.w < 200) continue;
printf("Processing %dx%d image\n", im.h, im.w);
resize_network(net, im.h, im.w, im.c);
//scale_image(im, 1./255);
translate_image(im, -144);
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forward_network(net, im.data, 0, 0);
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image out = get_network_image(net);
int dh = (im.h - h)/(out.h-1);
int dw = (im.w - w)/(out.w-1);
//printf("%d %d\n", dh, dw);
for(k = 0; k < out.c; ++k){
float topv = 0;
int topi = -1;
int topj = -1;
for(i = 0; i < out.h; ++i){
for(j = 0; j < out.w; ++j){
float val = get_pixel(out, i, j, k);
if(val > topv){
topv = val;
topi = i;
topj = j;
}
}
}
if(topv){
image sub = get_sub_image(im, dh*topi, dw*topj, h, w);
for(l = 0; l < topk; ++l){
if(topv > score[k][l]){
float swap = score[k][l];
score[k][l] = topv;
topv = swap;
image swapi = vizs[k][l];
vizs[k][l] = sub;
sub = swapi;
}
}
free_image(sub);
}
}
free_image(im);
if(count%50 == 0){
image grid = grid_images(vizs, num, topk);
//show_image(grid, "IMAGENET Visualization");
save_image(grid, "IMAGENET Grid Single Nonorm");
free_image(grid);
}
}
//cvWaitKey(0);
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}
void visualize_imagenet_features(char *filename)
{
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int i,j,k;
network net = parse_network_cfg("cfg/voc_imagenet.cfg");
list *plist = get_paths(filename);
node *n = plist->front;
int h = voc_size(1), w = voc_size(1);
int num = get_network_image(net).c;
image *vizs = calloc(num, sizeof(image));
for(i = 0; i < num; ++i) vizs[i] = make_image(h, w, 3);
while(n){
char *image_path = (char *)n->val;
image im = load_image(image_path, 0, 0);
printf("Processing %dx%d image\n", im.h, im.w);
resize_network(net, im.h, im.w, im.c);
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forward_network(net, im.data, 0, 0);
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image out = get_network_image(net);
int dh = (im.h - h)/h;
int dw = (im.w - w)/w;
for(i = 0; i < out.h; ++i){
for(j = 0; j < out.w; ++j){
image sub = get_sub_image(im, dh*i, dw*j, h, w);
for(k = 0; k < out.c; ++k){
float val = get_pixel(out, i, j, k);
//printf("%f, ", val);
image sub_c = copy_image(sub);
scale_image(sub_c, val);
add_into_image(sub_c, vizs[k], 0, 0);
free_image(sub_c);
}
free_image(sub);
}
}
//printf("\n");
show_images(vizs, 10, "IMAGENET Visualization");
cvWaitKey(1000);
n = n->next;
}
cvWaitKey(0);
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}
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void visualize_cat()
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{
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network net = parse_network_cfg("cfg/voc_imagenet.cfg");
image im = load_image("data/cat.png", 0, 0);
printf("Processing %dx%d image\n", im.h, im.w);
resize_network(net, im.h, im.w, im.c);
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forward_network(net, im.data, 0, 0);
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visualize_network(net);
cvWaitKey(0);
}
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void features_VOC_image(char *image_file, char *image_dir, char *out_dir, int flip, int interval)
{
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int i,j;
network net = parse_network_cfg("cfg/voc_imagenet.cfg");
char image_path[1024];
sprintf(image_path, "%s/%s",image_dir, image_file);
char out_path[1024];
if (flip)sprintf(out_path, "%s%d/%s_r.txt",out_dir, interval, image_file);
else sprintf(out_path, "%s%d/%s.txt",out_dir, interval, image_file);
printf("%s\n", image_file);
IplImage* src = 0;
if( (src = cvLoadImage(image_path,-1)) == 0 ) file_error(image_path);
if(flip)cvFlip(src, 0, 1);
int w = src->width;
int h = src->height;
int sbin = 8;
double scale = pow(2., 1./interval);
int m = (w<h)?w:h;
int max_scale = 1+floor((double)log((double)m/(5.*sbin))/log(scale));
if(max_scale < interval) error("max_scale must be >= interval");
image *ims = calloc(max_scale+interval, sizeof(image));
for(i = 0; i < interval; ++i){
double factor = 1./pow(scale, i);
double ih = round(h*factor);
double iw = round(w*factor);
int ex_h = round(ih/4.) - 2;
int ex_w = round(iw/4.) - 2;
ims[i] = features_output_size(net, src, ex_h, ex_w);
ih = round(h*factor);
iw = round(w*factor);
ex_h = round(ih/8.) - 2;
ex_w = round(iw/8.) - 2;
ims[i+interval] = features_output_size(net, src, ex_h, ex_w);
for(j = i+interval; j < max_scale; j += interval){
factor /= 2.;
ih = round(h*factor);
iw = round(w*factor);
ex_h = round(ih/8.) - 2;
ex_w = round(iw/8.) - 2;
ims[j+interval] = features_output_size(net, src, ex_h, ex_w);
}
}
FILE *fp = fopen(out_path, "w");
if(fp == 0) file_error(out_path);
for(i = 0; i < max_scale+interval; ++i){
image out = ims[i];
fprintf(fp, "%d, %d, %d\n",out.c, out.h, out.w);
for(j = 0; j < out.c*out.h*out.w; ++j){
if(j != 0)fprintf(fp, ",");
float o = out.data[j];
if(o < 0) o = 0;
fprintf(fp, "%g", o);
}
fprintf(fp, "\n");
free_image(out);
}
free(ims);
fclose(fp);
cvReleaseImage(&src);
}
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void test_distribution()
{
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IplImage* img = 0;
if( (img = cvLoadImage("im_small.jpg",-1)) == 0 ) file_error("im_small.jpg");
network net = parse_network_cfg("cfg/voc_features.cfg");
int h = img->height/8-2;
int w = img->width/8-2;
image out = features_output_size(net, img, h, w);
int c = out.c;
out.c = 1;
show_image(out, "output");
out.c = c;
image input = ipl_to_image(img);
show_image(input, "input");
CvScalar s;
int i,j;
image affects = make_image(input.h, input.w, 1);
int count = 0;
for(i = 0; i<img->height; i += 1){
for(j = 0; j < img->width; j += 1){
IplImage *copy = cvCloneImage(img);
s=cvGet2D(copy,i,j); // get the (i,j) pixel value
printf("%d/%d\n", count++, img->height*img->width);
s.val[0]=0;
s.val[1]=0;
s.val[2]=0;
cvSet2D(copy,i,j,s); // set the (i,j) pixel value
image mod = features_output_size(net, copy, h, w);
image dist = image_distance(out, mod);
show_image(affects, "affects");
cvWaitKey(1);
cvReleaseImage(&copy);
//affects.data[i*affects.w + j] += dist.data[3*dist.w+5];
affects.data[i*affects.w + j] += dist.data[1*dist.w+1];
free_image(mod);
free_image(dist);
}
}
show_image(affects, "Origins");
cvWaitKey(0);
cvWaitKey(0);
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}
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int main(int argc, char *argv[])
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{
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//test_blas();
train_assira();
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//test_distribution();
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//feenableexcept(FE_DIVBYZERO | FE_INVALID | FE_OVERFLOW);
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//test_blas();
//test_visualize();
//test_gpu_blas();
//test_blas();
//test_convolve_matrix();
// test_im2row();
//test_split();
//test_ensemble();
//test_nist_single();
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//test_nist();
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//train_nist();
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//test_convolutional_layer();
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//test_col2im();
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//test_cifar10();
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//train_cifar10();
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//test_vince();
//test_full();
//tune_VOC();
//features_VOC_image(argv[1], argv[2], argv[3], 0);
//features_VOC_image(argv[1], argv[2], argv[3], 1);
//train_VOC();
//features_VOC_image(argv[1], argv[2], argv[3], 0, 4);
//features_VOC_image(argv[1], argv[2], argv[3], 1, 4);
//features_VOC_image_size(argv[1], atoi(argv[2]), atoi(argv[3]));
//visualize_imagenet_features("data/assira/train.list");
//visualize_imagenet_topk("data/VOC2012.list");
//visualize_cat();
//flip_network();
//test_visualize();
//test_parser();
fprintf(stderr, "Success!\n");
//test_random_preprocess();
//test_random_classify();
//test_parser();
//test_backpropagate();
//test_ann();
//test_convolve();
//test_upsample();
//test_rotate();
//test_load();
//test_network();
//test_convolutional_layer();
//verify_convolutional_layer();
//test_color();
//cvWaitKey(0);
return 0;
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}