mirror of https://github.com/pjreddie/darknet.git
415 lines
13 KiB
C
415 lines
13 KiB
C
#include "darknet.h"
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#include <math.h>
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// ./darknet nightmare cfg/extractor.recon.cfg ~/trained/yolo-coco.conv frame6.png -reconstruct -iters 500 -i 3 -lambda .1 -rate .01 -smooth 2
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float abs_mean(float *x, int n)
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{
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int i;
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float sum = 0;
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for (i = 0; i < n; ++i){
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sum += fabs(x[i]);
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}
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return sum/n;
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}
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void calculate_loss(float *output, float *delta, int n, float thresh)
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{
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int i;
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float mean = mean_array(output, n);
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float var = variance_array(output, n);
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for(i = 0; i < n; ++i){
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if(delta[i] > mean + thresh*sqrt(var)) delta[i] = output[i];
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else delta[i] = 0;
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}
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}
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void optimize_picture(network *net, image orig, int max_layer, float scale, float rate, float thresh, int norm)
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{
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//scale_image(orig, 2);
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//translate_image(orig, -1);
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net->n = max_layer + 1;
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int dx = rand()%16 - 8;
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int dy = rand()%16 - 8;
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int flip = rand()%2;
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image crop = crop_image(orig, dx, dy, orig.w, orig.h);
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image im = resize_image(crop, (int)(orig.w * scale), (int)(orig.h * scale));
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if(flip) flip_image(im);
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resize_network(net, im.w, im.h);
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layer last = net->layers[net->n-1];
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//net->layers[net->n - 1].activation = LINEAR;
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image delta = make_image(im.w, im.h, im.c);
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#ifdef GPU
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net->delta_gpu = cuda_make_array(delta.data, im.w*im.h*im.c);
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copy_cpu(net->inputs, im.data, 1, net->input, 1);
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forward_network_gpu(net);
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copy_gpu(last.outputs, last.output_gpu, 1, last.delta_gpu, 1);
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cuda_pull_array(last.delta_gpu, last.delta, last.outputs);
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calculate_loss(last.delta, last.delta, last.outputs, thresh);
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cuda_push_array(last.delta_gpu, last.delta, last.outputs);
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backward_network_gpu(net);
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cuda_pull_array(net->delta_gpu, delta.data, im.w*im.h*im.c);
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cuda_free(net->delta_gpu);
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net->delta_gpu = 0;
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#else
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printf("\nnet: %d %d %d im: %d %d %d\n", net->w, net->h, net->inputs, im.w, im.h, im.c);
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copy_cpu(net->inputs, im.data, 1, net->input, 1);
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net->delta = delta.data;
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forward_network(net);
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copy_cpu(last.outputs, last.output, 1, last.delta, 1);
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calculate_loss(last.output, last.delta, last.outputs, thresh);
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backward_network(net);
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#endif
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if(flip) flip_image(delta);
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//normalize_array(delta.data, delta.w*delta.h*delta.c);
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image resized = resize_image(delta, orig.w, orig.h);
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image out = crop_image(resized, -dx, -dy, orig.w, orig.h);
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/*
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image g = grayscale_image(out);
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free_image(out);
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out = g;
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*/
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//rate = rate / abs_mean(out.data, out.w*out.h*out.c);
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image gray = make_image(out.w, out.h, out.c);
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fill_image(gray, .5);
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axpy_cpu(orig.w*orig.h*orig.c, -1, orig.data, 1, gray.data, 1);
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axpy_cpu(orig.w*orig.h*orig.c, .1, gray.data, 1, out.data, 1);
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if(norm) normalize_array(out.data, out.w*out.h*out.c);
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axpy_cpu(orig.w*orig.h*orig.c, rate, out.data, 1, orig.data, 1);
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/*
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normalize_array(orig.data, orig.w*orig.h*orig.c);
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scale_image(orig, sqrt(var));
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translate_image(orig, mean);
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*/
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//translate_image(orig, 1);
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//scale_image(orig, .5);
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//normalize_image(orig);
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constrain_image(orig);
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free_image(crop);
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free_image(im);
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free_image(delta);
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free_image(resized);
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free_image(out);
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}
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void smooth(image recon, image update, float lambda, int num)
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{
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int i, j, k;
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int ii, jj;
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for(k = 0; k < recon.c; ++k){
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for(j = 0; j < recon.h; ++j){
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for(i = 0; i < recon.w; ++i){
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int out_index = i + recon.w*(j + recon.h*k);
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for(jj = j-num; jj <= j + num && jj < recon.h; ++jj){
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if (jj < 0) continue;
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for(ii = i-num; ii <= i + num && ii < recon.w; ++ii){
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if (ii < 0) continue;
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int in_index = ii + recon.w*(jj + recon.h*k);
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update.data[out_index] += lambda * (recon.data[in_index] - recon.data[out_index]);
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}
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}
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}
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}
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}
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}
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void reconstruct_picture(network *net, float *features, image recon, image update, float rate, float momentum, float lambda, int smooth_size, int iters)
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{
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int iter = 0;
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for (iter = 0; iter < iters; ++iter) {
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image delta = make_image(recon.w, recon.h, recon.c);
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#ifdef GPU
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layer l = get_network_output_layer(net);
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cuda_push_array(net->input_gpu, recon.data, recon.w*recon.h*recon.c);
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//cuda_push_array(net->truth_gpu, features, net->truths);
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net->delta_gpu = cuda_make_array(delta.data, delta.w*delta.h*delta.c);
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forward_network_gpu(net);
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cuda_push_array(l.delta_gpu, features, l.outputs);
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axpy_gpu(l.outputs, -1, l.output_gpu, 1, l.delta_gpu, 1);
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backward_network_gpu(net);
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cuda_pull_array(net->delta_gpu, delta.data, delta.w*delta.h*delta.c);
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cuda_free(net->delta_gpu);
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#else
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net->input = recon.data;
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net->delta = delta.data;
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net->truth = features;
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forward_network(net);
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backward_network(net);
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#endif
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//normalize_array(delta.data, delta.w*delta.h*delta.c);
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axpy_cpu(recon.w*recon.h*recon.c, 1, delta.data, 1, update.data, 1);
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//smooth(recon, update, lambda, smooth_size);
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axpy_cpu(recon.w*recon.h*recon.c, rate, update.data, 1, recon.data, 1);
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scal_cpu(recon.w*recon.h*recon.c, momentum, update.data, 1);
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float mag = mag_array(delta.data, recon.w*recon.h*recon.c);
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printf("mag: %f\n", mag);
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//scal_cpu(recon.w*recon.h*recon.c, 600/mag, recon.data, 1);
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constrain_image(recon);
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free_image(delta);
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}
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}
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/*
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void run_lsd(int argc, char **argv)
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{
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srand(0);
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if(argc < 3){
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fprintf(stderr, "usage: %s %s [cfg] [weights] [image] [options! (optional)]\n", argv[0], argv[1]);
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return;
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}
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char *cfg = argv[2];
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char *weights = argv[3];
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char *input = argv[4];
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int norm = find_int_arg(argc, argv, "-norm", 1);
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int rounds = find_int_arg(argc, argv, "-rounds", 1);
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int iters = find_int_arg(argc, argv, "-iters", 10);
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float rate = find_float_arg(argc, argv, "-rate", .04);
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float momentum = find_float_arg(argc, argv, "-momentum", .9);
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float lambda = find_float_arg(argc, argv, "-lambda", .01);
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char *prefix = find_char_arg(argc, argv, "-prefix", 0);
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int reconstruct = find_arg(argc, argv, "-reconstruct");
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int smooth_size = find_int_arg(argc, argv, "-smooth", 1);
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network net = parse_network_cfg(cfg);
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load_weights(&net, weights);
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char *cfgbase = basecfg(cfg);
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char *imbase = basecfg(input);
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set_batch_network(&net, 1);
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image im = load_image_color(input, 0, 0);
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float *features = 0;
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image update;
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if (reconstruct){
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im = letterbox_image(im, net->w, net->h);
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int zz = 0;
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network_predict(net, im.data);
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image out_im = get_network_image(net);
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image crop = crop_image(out_im, zz, zz, out_im.w-2*zz, out_im.h-2*zz);
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//flip_image(crop);
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image f_im = resize_image(crop, out_im.w, out_im.h);
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free_image(crop);
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printf("%d features\n", out_im.w*out_im.h*out_im.c);
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im = resize_image(im, im.w, im.h);
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f_im = resize_image(f_im, f_im.w, f_im.h);
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features = f_im.data;
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int i;
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for(i = 0; i < 14*14*512; ++i){
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features[i] += rand_uniform(-.19, .19);
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}
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free_image(im);
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im = make_random_image(im.w, im.h, im.c);
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update = make_image(im.w, im.h, im.c);
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}
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int e;
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int n;
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for(e = 0; e < rounds; ++e){
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fprintf(stderr, "Iteration: ");
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fflush(stderr);
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for(n = 0; n < iters; ++n){
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fprintf(stderr, "%d, ", n);
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fflush(stderr);
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if(reconstruct){
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reconstruct_picture(net, features, im, update, rate, momentum, lambda, smooth_size, 1);
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//if ((n+1)%30 == 0) rate *= .5;
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show_image(im, "reconstruction");
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#ifdef OPENCV
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cvWaitKey(10);
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#endif
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}else{
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int layer = max_layer + rand()%range - range/2;
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int octave = rand()%octaves;
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optimize_picture(&net, im, layer, 1/pow(1.33333333, octave), rate, thresh, norm);
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}
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}
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fprintf(stderr, "done\n");
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char buff[256];
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if (prefix){
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sprintf(buff, "%s/%s_%s_%d_%06d",prefix, imbase, cfgbase, max_layer, e);
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}else{
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sprintf(buff, "%s_%s_%d_%06d",imbase, cfgbase, max_layer, e);
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}
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printf("%d %s\n", e, buff);
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save_image(im, buff);
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//show_image(im, buff);
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//cvWaitKey(0);
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if(rotate){
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image rot = rotate_image(im, rotate);
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free_image(im);
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im = rot;
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}
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image crop = crop_image(im, im.w * (1. - zoom)/2., im.h * (1.-zoom)/2., im.w*zoom, im.h*zoom);
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image resized = resize_image(crop, im.w, im.h);
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free_image(im);
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free_image(crop);
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im = resized;
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}
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}
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*/
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void run_nightmare(int argc, char **argv)
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{
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srand(0);
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if(argc < 4){
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fprintf(stderr, "usage: %s %s [cfg] [weights] [image] [layer] [options! (optional)]\n", argv[0], argv[1]);
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return;
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}
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char *cfg = argv[2];
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char *weights = argv[3];
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char *input = argv[4];
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int max_layer = atoi(argv[5]);
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int range = find_int_arg(argc, argv, "-range", 1);
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int norm = find_int_arg(argc, argv, "-norm", 1);
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int rounds = find_int_arg(argc, argv, "-rounds", 1);
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int iters = find_int_arg(argc, argv, "-iters", 10);
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int octaves = find_int_arg(argc, argv, "-octaves", 4);
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float zoom = find_float_arg(argc, argv, "-zoom", 1.);
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float rate = find_float_arg(argc, argv, "-rate", .04);
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float thresh = find_float_arg(argc, argv, "-thresh", 1.);
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float rotate = find_float_arg(argc, argv, "-rotate", 0);
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float momentum = find_float_arg(argc, argv, "-momentum", .9);
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float lambda = find_float_arg(argc, argv, "-lambda", .01);
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char *prefix = find_char_arg(argc, argv, "-prefix", 0);
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int reconstruct = find_arg(argc, argv, "-reconstruct");
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int smooth_size = find_int_arg(argc, argv, "-smooth", 1);
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network *net = load_network(cfg, weights, 0);
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char *cfgbase = basecfg(cfg);
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char *imbase = basecfg(input);
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set_batch_network(net, 1);
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image im = load_image_color(input, 0, 0);
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if(0){
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float scale = 1;
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if(im.w > 512 || im.h > 512){
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if(im.w > im.h) scale = 512.0/im.w;
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else scale = 512.0/im.h;
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}
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image resized = resize_image(im, scale*im.w, scale*im.h);
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free_image(im);
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im = resized;
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}
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//im = letterbox_image(im, net->w, net->h);
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float *features = 0;
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image update;
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if (reconstruct){
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net->n = max_layer;
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im = letterbox_image(im, net->w, net->h);
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//resize_network(&net, im.w, im.h);
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network_predict(net, im.data);
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if(net->layers[net->n-1].type == REGION){
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printf("region!\n");
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zero_objectness(net->layers[net->n-1]);
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}
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image out_im = copy_image(get_network_image(net));
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/*
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image crop = crop_image(out_im, zz, zz, out_im.w-2*zz, out_im.h-2*zz);
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//flip_image(crop);
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image f_im = resize_image(crop, out_im.w, out_im.h);
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free_image(crop);
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*/
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printf("%d features\n", out_im.w*out_im.h*out_im.c);
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features = out_im.data;
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/*
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int i;
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for(i = 0; i < 14*14*512; ++i){
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//features[i] += rand_uniform(-.19, .19);
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}
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free_image(im);
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im = make_random_image(im.w, im.h, im.c);
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*/
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update = make_image(im.w, im.h, im.c);
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}
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int e;
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int n;
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for(e = 0; e < rounds; ++e){
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fprintf(stderr, "Iteration: ");
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fflush(stderr);
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for(n = 0; n < iters; ++n){
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fprintf(stderr, "%d, ", n);
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fflush(stderr);
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if(reconstruct){
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reconstruct_picture(net, features, im, update, rate, momentum, lambda, smooth_size, 1);
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//if ((n+1)%30 == 0) rate *= .5;
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show_image(im, "reconstruction", 10);
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}else{
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int layer = max_layer + rand()%range - range/2;
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int octave = rand()%octaves;
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optimize_picture(net, im, layer, 1/pow(1.33333333, octave), rate, thresh, norm);
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}
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}
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fprintf(stderr, "done\n");
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if(0){
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image g = grayscale_image(im);
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free_image(im);
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im = g;
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}
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char buff[256];
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if (prefix){
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sprintf(buff, "%s/%s_%s_%d_%06d",prefix, imbase, cfgbase, max_layer, e);
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}else{
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sprintf(buff, "%s_%s_%d_%06d",imbase, cfgbase, max_layer, e);
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}
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printf("%d %s\n", e, buff);
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save_image(im, buff);
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//show_image(im, buff, 0);
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if(rotate){
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image rot = rotate_image(im, rotate);
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free_image(im);
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im = rot;
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}
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image crop = crop_image(im, im.w * (1. - zoom)/2., im.h * (1.-zoom)/2., im.w*zoom, im.h*zoom);
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image resized = resize_image(crop, im.w, im.h);
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free_image(im);
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free_image(crop);
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im = resized;
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}
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}
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