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UvmPinAsync / workloads /realworld /async /darknet /src /data.c
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#include "data.h"
#include "utils.h"
#include "image.h"
#include "cuda_dark.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
pthread_mutex_t mutex = PTHREAD_MUTEX_INITIALIZER;
list *get_paths(char *filename)
{
 char *path;
 FILE *file = fopen(filename, "r");
 if(!file) file_error(filename);
 list *lines = make_list();
 while((path=fgetl(file))){
 list_insert(lines, path);
 }
 fclose(file);
 return lines;
}
/*
char **get_random_paths_indexes(char **paths, int n, int m, int *indexes)
{
 char **random_paths = calloc(n, sizeof(char*));
 int i;
 pthread_mutex_lock(&mutex);
 for(i = 0; i < n; ++i){
 int index = rand()%m;
 indexes[i] = index;
 random_paths[i] = paths[index];
 if(i == 0) printf("%s\n", paths[index]);
 }
 pthread_mutex_unlock(&mutex);
 return random_paths;
}
*/
char **get_random_paths(char **paths, int n, int m)
{
 char **random_paths = calloc(n, sizeof(char*));
 int i;
 pthread_mutex_lock(&mutex);
 for(i = 0; i < n; ++i){
 int index = rand()%m;
 random_paths[i] = paths[index];
 //if(i == 0) printf("%s\n", paths[index]);
 }
 pthread_mutex_unlock(&mutex);
 return random_paths;
}
char **find_replace_paths(char **paths, int n, char *find, char *replace)
{
 char **replace_paths = calloc(n, sizeof(char*));
 int i;
 for(i = 0; i < n; ++i){
 char replaced[4096];
 find_replace(paths[i], find, replace, replaced);
 replace_paths[i] = copy_string(replaced);
 }
 return replace_paths;
}
matrix load_image_paths_gray(char **paths, int n, int w, int h)
{
 int i;
 matrix X;
 X.rows = n;
 X.vals = calloc(X.rows, sizeof(float*));
 X.cols = 0;
for(i = 0; i < n; ++i){
 image im = load_image(paths[i], w, h, 3);
image gray = grayscale_image(im);
 free_image(im);
 im = gray;
X.vals[i] = im.data;
 X.cols = im.h*im.w*im.c;
 }
 return X;
}
matrix load_image_paths(char **paths, int n, int w, int h)
{
 int i;
 matrix X;
 X.rows = n;
 X.vals = calloc(X.rows, sizeof(float*));
 X.cols = 0;
for(i = 0; i < n; ++i){
 image im = load_image_color(paths[i], w, h);
 X.vals[i] = im.data;
 X.cols = im.h*im.w*im.c;
 }
 return X;
}
matrix load_image_augment_paths(char **paths, int n, int min, int max, int size, float angle, float aspect, float hue, float saturation, float exposure, int center)
{
 int i;
 matrix X;
 X.rows = n;
 X.vals = calloc(X.rows, sizeof(float*));
 X.cols = 0;
for(i = 0; i < n; ++i){
 image im = load_image_color(paths[i], 0, 0);
 image crop;
 if(center){
 crop = center_crop_image(im, size, size);
 } else {
 crop = random_augment_image(im, angle, aspect, min, max, size, size);
 }
 int flip = rand()%2;
 if (flip) flip_image(crop);
 random_distort_image(crop, hue, saturation, exposure);
/*
 show_image(im, "orig");
 show_image(crop, "crop");
 cvWaitKey(0);
 */
 //grayscale_image_3c(crop);
 free_image(im);
 X.vals[i] = crop.data;
 X.cols = crop.h*crop.w*crop.c;
 }
 return X;
}
box_label *read_boxes(char *filename, int *n)
{
 FILE *file = fopen(filename, "r");
 if(!file) file_error(filename);
 float x, y, h, w;
 int id;
 int count = 0;
 int size = 64;
 box_label *boxes = calloc(size, sizeof(box_label));
 while(fscanf(file, "%d %f %f %f %f", &id, &x, &y, &w, &h) == 5){
 if(count == size) {
 size = size * 2;
 boxes = realloc(boxes, size*sizeof(box_label));
 }
 boxes[count].id = id;
 boxes[count].x = x;
 boxes[count].y = y;
 boxes[count].h = h;
 boxes[count].w = w;
 boxes[count].left = x - w/2;
 boxes[count].right = x + w/2;
 boxes[count].top = y - h/2;
 boxes[count].bottom = y + h/2;
 ++count;
 }
 fclose(file);
 *n = count;
 return boxes;
}
void randomize_boxes(box_label *b, int n)
{
 int i;
 for(i = 0; i < n; ++i){
 box_label swap = b[i];
 int index = rand()%n;
 b[i] = b[index];
 b[index] = swap;
 }
}
void correct_boxes(box_label *boxes, int n, float dx, float dy, float sx, float sy, int flip)
{
 int i;
 for(i = 0; i < n; ++i){
 if(boxes[i].x == 0 && boxes[i].y == 0) {
 boxes[i].x = 999999;
 boxes[i].y = 999999;
 boxes[i].w = 999999;
 boxes[i].h = 999999;
 continue;
 }
 boxes[i].left = boxes[i].left * sx - dx;
 boxes[i].right = boxes[i].right * sx - dx;
 boxes[i].top = boxes[i].top * sy - dy;
 boxes[i].bottom = boxes[i].bottom* sy - dy;
if(flip){
 float swap = boxes[i].left;
 boxes[i].left = 1. - boxes[i].right;
 boxes[i].right = 1. - swap;
 }
boxes[i].left = constrain(0, 1, boxes[i].left);
 boxes[i].right = constrain(0, 1, boxes[i].right);
 boxes[i].top = constrain(0, 1, boxes[i].top);
 boxes[i].bottom = constrain(0, 1, boxes[i].bottom);
boxes[i].x = (boxes[i].left+boxes[i].right)/2;
 boxes[i].y = (boxes[i].top+boxes[i].bottom)/2;
 boxes[i].w = (boxes[i].right - boxes[i].left);
 boxes[i].h = (boxes[i].bottom - boxes[i].top);
boxes[i].w = constrain(0, 1, boxes[i].w);
 boxes[i].h = constrain(0, 1, boxes[i].h);
 }
}
void fill_truth_swag(char *path, float *truth, int classes, int flip, float dx, float dy, float sx, float sy)
{
 char labelpath[4096];
 find_replace(path, "images", "labels", labelpath);
 find_replace(labelpath, "JPEGImages", "labels", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
int count = 0;
 box_label *boxes = read_boxes(labelpath, &count);
 randomize_boxes(boxes, count);
 correct_boxes(boxes, count, dx, dy, sx, sy, flip);
 float x,y,w,h;
 int id;
 int i;
for (i = 0; i < count && i < 90; ++i) {
 x = boxes[i].x;
 y = boxes[i].y;
 w = boxes[i].w;
 h = boxes[i].h;
 id = boxes[i].id;
if (w < .0 || h < .0) continue;
int index = (4+classes) * i;
truth[index++] = x;
 truth[index++] = y;
 truth[index++] = w;
 truth[index++] = h;
if (id < classes) truth[index+id] = 1;
 }
 free(boxes);
}
void fill_truth_region(char *path, float *truth, int classes, int num_boxes, int flip, float dx, float dy, float sx, float sy)
{
 char labelpath[4096];
 find_replace(path, "images", "labels", labelpath);
 find_replace(labelpath, "JPEGImages", "labels", labelpath);
find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".png", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 int count = 0;
 box_label *boxes = read_boxes(labelpath, &count);
 randomize_boxes(boxes, count);
 correct_boxes(boxes, count, dx, dy, sx, sy, flip);
 float x,y,w,h;
 int id;
 int i;
for (i = 0; i < count; ++i) {
 x = boxes[i].x;
 y = boxes[i].y;
 w = boxes[i].w;
 h = boxes[i].h;
 id = boxes[i].id;
if (w < .005 || h < .005) continue;
int col = (int)(x*num_boxes);
 int row = (int)(y*num_boxes);
x = x*num_boxes - col;
 y = y*num_boxes - row;
int index = (col+row*num_boxes)*(5+classes);
 if (truth[index]) continue;
 truth[index++] = 1;
if (id < classes) truth[index+id] = 1;
 index += classes;
truth[index++] = x;
 truth[index++] = y;
 truth[index++] = w;
 truth[index++] = h;
 }
 free(boxes);
}
void load_rle(image im, int *rle, int n)
{
 int count = 0;
 int curr = 0;
 int i,j;
 for(i = 0; i < n; ++i){
 for(j = 0; j < rle[i]; ++j){
 im.data[count++] = curr;
 }
 curr = 1 - curr;
 }
 for(; count < im.h*im.w*im.c; ++count){
 im.data[count] = curr;
 }
}
void or_image(image src, image dest, int c)
{
 int i;
 for(i = 0; i < src.w*src.h; ++i){
 if(src.data[i]) dest.data[dest.w*dest.h*c + i] = 1;
 }
}
void exclusive_image(image src)
{
 int k, j, i;
 int s = src.w*src.h;
 for(k = 0; k < src.c-1; ++k){
 for(i = 0; i < s; ++i){
 if (src.data[k*s + i]){
 for(j = k+1; j < src.c; ++j){
 src.data[j*s + i] = 0;
 }
 }
 }
 }
}
box bound_image(image im)
{
 int x,y;
 int minx = im.w;
 int miny = im.h;
 int maxx = 0;
 int maxy = 0;
 for(y = 0; y < im.h; ++y){
 for(x = 0; x < im.w; ++x){
 if(im.data[y*im.w + x]){
 minx = (x < minx) ? x : minx;
 miny = (y < miny) ? y : miny;
 maxx = (x > maxx) ? x : maxx;
 maxy = (y > maxy) ? y : maxy;
 }
 }
 }
 box b = {minx, miny, maxx-minx + 1, maxy-miny + 1};
 //printf("%f %f %f %f\n", b.x, b.y, b.w, b.h);
 return b;
}
void fill_truth_iseg(char *path, int num_boxes, float *truth, int classes, int w, int h, augment_args aug, int flip, int mw, int mh)
{
 char labelpath[4096];
 find_replace(path, "images", "mask", labelpath);
 find_replace(labelpath, "JPEGImages", "mask", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 FILE *file = fopen(labelpath, "r");
 if(!file) file_error(labelpath);
 char buff[32788];
 int id;
 int i = 0;
 int j;
 image part = make_image(w, h, 1);
 while((fscanf(file, "%d %s", &id, buff) == 2) && i < num_boxes){
 int n = 0;
 int *rle = read_intlist(buff, &n, 0);
 load_rle(part, rle, n);
 image sized = rotate_crop_image(part, aug.rad, aug.scale, aug.w, aug.h, aug.dx, aug.dy, aug.aspect);
 if(flip) flip_image(sized);
image mask = resize_image(sized, mw, mh);
 truth[i*(mw*mh+1)] = id;
 for(j = 0; j < mw*mh; ++j){
 truth[i*(mw*mh + 1) + 1 + j] = mask.data[j];
 }
 ++i;
free_image(mask);
 free_image(sized);
 free(rle);
 }
 if(i < num_boxes) truth[i*(mw*mh+1)] = -1;
 fclose(file);
 free_image(part);
}
void fill_truth_mask(char *path, int num_boxes, float *truth, int classes, int w, int h, augment_args aug, int flip, int mw, int mh)
{
 char labelpath[4096];
 find_replace(path, "images", "mask", labelpath);
 find_replace(labelpath, "JPEGImages", "mask", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 FILE *file = fopen(labelpath, "r");
 if(!file) file_error(labelpath);
 char buff[32788];
 int id;
 int i = 0;
 image part = make_image(w, h, 1);
 while((fscanf(file, "%d %s", &id, buff) == 2) && i < num_boxes){
 int n = 0;
 int *rle = read_intlist(buff, &n, 0);
 load_rle(part, rle, n);
 image sized = rotate_crop_image(part, aug.rad, aug.scale, aug.w, aug.h, aug.dx, aug.dy, aug.aspect);
 if(flip) flip_image(sized);
 box b = bound_image(sized);
 if(b.w > 0){
 image crop = crop_image(sized, b.x, b.y, b.w, b.h);
 image mask = resize_image(crop, mw, mh);
 truth[i*(4 + mw*mh + 1) + 0] = (b.x + b.w/2.)/sized.w;
 truth[i*(4 + mw*mh + 1) + 1] = (b.y + b.h/2.)/sized.h;
 truth[i*(4 + mw*mh + 1) + 2] = b.w/sized.w;
 truth[i*(4 + mw*mh + 1) + 3] = b.h/sized.h;
 int j;
 for(j = 0; j < mw*mh; ++j){
 truth[i*(4 + mw*mh + 1) + 4 + j] = mask.data[j];
 }
 truth[i*(4 + mw*mh + 1) + 4 + mw*mh] = id;
 free_image(crop);
 free_image(mask);
 ++i;
 }
 free_image(sized);
 free(rle);
 }
 fclose(file);
 free_image(part);
}
void fill_truth_detection(char *path, int num_boxes, float *truth, int classes, int flip, float dx, float dy, float sx, float sy)
{
 char labelpath[4096];
 find_replace(path, "images", "labels", labelpath);
 find_replace(labelpath, "JPEGImages", "labels", labelpath);
find_replace(labelpath, "raw", "labels", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".png", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 int count = 0;
 box_label *boxes = read_boxes(labelpath, &count);
 randomize_boxes(boxes, count);
 correct_boxes(boxes, count, dx, dy, sx, sy, flip);
 if(count > num_boxes) count = num_boxes;
 float x,y,w,h;
 int id;
 int i;
 int sub = 0;
for (i = 0; i < count; ++i) {
 x = boxes[i].x;
 y = boxes[i].y;
 w = boxes[i].w;
 h = boxes[i].h;
 id = boxes[i].id;
if ((w < .001 || h < .001)) {
 ++sub;
 continue;
 }
truth[(i-sub)*5+0] = x;
 truth[(i-sub)*5+1] = y;
 truth[(i-sub)*5+2] = w;
 truth[(i-sub)*5+3] = h;
 truth[(i-sub)*5+4] = id;
 }
 free(boxes);
}
#define NUMCHARS 37
void print_letters(float *pred, int n)
{
 int i;
 for(i = 0; i < n; ++i){
 int index = max_index(pred+i*NUMCHARS, NUMCHARS);
 printf("%c", int_to_alphanum(index));
 }
 printf("\n");
}
void fill_truth_captcha(char *path, int n, float *truth)
{
 char *begin = strrchr(path, '/');
 ++begin;
 int i;
 for(i = 0; i < strlen(begin) && i < n && begin[i] != '.'; ++i){
 int index = alphanum_to_int(begin[i]);
 if(index > 35) printf("Bad %c\n", begin[i]);
 truth[i*NUMCHARS+index] = 1;
 }
 for(;i < n; ++i){
 truth[i*NUMCHARS + NUMCHARS-1] = 1;
 }
}
data load_data_captcha(char **paths, int n, int m, int k, int w, int h)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
 d.X = load_image_paths(paths, n, w, h);
 d.y = make_matrix(n, k*NUMCHARS);
 int i;
 for(i = 0; i < n; ++i){
 fill_truth_captcha(paths[i], k, d.y.vals[i]);
 }
 if(m) free(paths);
 return d;
}
data load_data_captcha_encode(char **paths, int n, int m, int w, int h)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
 d.X = load_image_paths(paths, n, w, h);
 d.X.cols = 17100;
 d.y = d.X;
 if(m) free(paths);
 return d;
}
void fill_truth(char *path, char **labels, int k, float *truth)
{
 int i;
 memset(truth, 0, k*sizeof(float));
 int count = 0;
 for(i = 0; i < k; ++i){
 if(strstr(path, labels[i])){
 truth[i] = 1;
 ++count;
 //printf("%s %s %d\n", path, labels[i], i);
 }
 }
 if(count != 1 && (k != 1 || count != 0)) printf("Too many or too few labels: %d, %s\n", count, path);
}
void fill_hierarchy(float *truth, int k, tree *hierarchy)
{
 int j;
 for(j = 0; j < k; ++j){
 if(truth[j]){
 int parent = hierarchy->parent[j];
 while(parent >= 0){
 truth[parent] = 1;
 parent = hierarchy->parent[parent];
 }
 }
 }
 int i;
 int count = 0;
 for(j = 0; j < hierarchy->groups; ++j){
 //printf("%d\n", count);
 int mask = 1;
 for(i = 0; i < hierarchy->group_size[j]; ++i){
 if(truth[count + i]){
 mask = 0;
 break;
 }
 }
 if (mask) {
 for(i = 0; i < hierarchy->group_size[j]; ++i){
 truth[count + i] = SECRET_NUM;
 }
 }
 count += hierarchy->group_size[j];
 }
}
matrix load_regression_labels_paths(char **paths, int n, int k)
{
 matrix y = make_matrix(n, k);
 int i,j;
 for(i = 0; i < n; ++i){
 char labelpath[4096];
 find_replace(paths[i], "images", "labels", labelpath);
 find_replace(labelpath, "JPEGImages", "labels", labelpath);
 find_replace(labelpath, ".BMP", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPeG", ".txt", labelpath);
 find_replace(labelpath, ".Jpeg", ".txt", labelpath);
 find_replace(labelpath, ".PNG", ".txt", labelpath);
 find_replace(labelpath, ".TIF", ".txt", labelpath);
 find_replace(labelpath, ".bmp", ".txt", labelpath);
 find_replace(labelpath, ".jpeg", ".txt", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".png", ".txt", labelpath);
 find_replace(labelpath, ".tif", ".txt", labelpath);
FILE *file = fopen(labelpath, "r");
 for(j = 0; j < k; ++j){
 fscanf(file, "%f", &(y.vals[i][j]));
 }
 fclose(file);
 }
 return y;
}
matrix load_labels_paths(char **paths, int n, char **labels, int k, tree *hierarchy)
{
 matrix y = make_matrix(n, k);
 int i;
 for(i = 0; i < n && labels; ++i){
 fill_truth(paths[i], labels, k, y.vals[i]);
 if(hierarchy){
 fill_hierarchy(y.vals[i], k, hierarchy);
 }
 }
 return y;
}
matrix load_tags_paths(char **paths, int n, int k)
{
 matrix y = make_matrix(n, k);
 int i;
 //int count = 0;
 for(i = 0; i < n; ++i){
 char label[4096];
 find_replace(paths[i], "images", "labels", label);
 find_replace(label, ".jpg", ".txt", label);
 FILE *file = fopen(label, "r");
 if (!file) continue;
 //++count;
 int tag;
 while(fscanf(file, "%d", &tag) == 1){
 if(tag < k){
 y.vals[i][tag] = 1;
 }
 }
 fclose(file);
 }
 //printf("%d/%d\n", count, n);
 return y;
}
char **get_labels(char *filename)
{
 list *plist = get_paths(filename);
 char **labels = (char **)list_to_array(plist);
 free_list(plist);
 return labels;
}
void free_data(data d)
{
 if(!d.shallow){
 free_matrix(d.X);
 free_matrix(d.y);
 }else{
 free(d.X.vals);
 free(d.y.vals);
 }
}
image get_segmentation_image(char *path, int w, int h, int classes)
{
 char labelpath[4096];
 find_replace(path, "images", "mask", labelpath);
 find_replace(labelpath, "JPEGImages", "mask", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 image mask = make_image(w, h, classes);
 FILE *file = fopen(labelpath, "r");
 if(!file) file_error(labelpath);
 char buff[32788];
 int id;
 image part = make_image(w, h, 1);
 while(fscanf(file, "%d %s", &id, buff) == 2){
 int n = 0;
 int *rle = read_intlist(buff, &n, 0);
 load_rle(part, rle, n);
 or_image(part, mask, id);
 free(rle);
 }
 //exclusive_image(mask);
 fclose(file);
 free_image(part);
 return mask;
}
image get_segmentation_image2(char *path, int w, int h, int classes)
{
 char labelpath[4096];
 find_replace(path, "images", "mask", labelpath);
 find_replace(labelpath, "JPEGImages", "mask", labelpath);
 find_replace(labelpath, ".jpg", ".txt", labelpath);
 find_replace(labelpath, ".JPG", ".txt", labelpath);
 find_replace(labelpath, ".JPEG", ".txt", labelpath);
 image mask = make_image(w, h, classes+1);
 int i;
 for(i = 0; i < w*h; ++i){
 mask.data[w*h*classes + i] = 1;
 }
 FILE *file = fopen(labelpath, "r");
 if(!file) file_error(labelpath);
 char buff[32788];
 int id;
 image part = make_image(w, h, 1);
 while(fscanf(file, "%d %s", &id, buff) == 2){
 int n = 0;
 int *rle = read_intlist(buff, &n, 0);
 load_rle(part, rle, n);
 or_image(part, mask, id);
 for(i = 0; i < w*h; ++i){
 if(part.data[i]) mask.data[w*h*classes + i] = 0;
 }
 free(rle);
 }
 //exclusive_image(mask);
 fclose(file);
 free_image(part);
 return mask;
}
data load_data_seg(int n, char **paths, int m, int w, int h, int classes, int min, int max, float angle, float aspect, float hue, float saturation, float exposure, int div)
{
 char **random_paths = get_random_paths(paths, n, m);
 int i;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
d.y.rows = n;
 d.y.cols = h*w*classes/div/div;
 d.y.vals = calloc(d.X.rows, sizeof(float*));
for(i = 0; i < n; ++i){
 image orig = load_image_color(random_paths[i], 0, 0);
 augment_args a = random_augment_args(orig, angle, aspect, min, max, w, h);
 image sized = rotate_crop_image(orig, a.rad, a.scale, a.w, a.h, a.dx, a.dy, a.aspect);
int flip = rand()%2;
 if(flip) flip_image(sized);
 random_distort_image(sized, hue, saturation, exposure);
 d.X.vals[i] = sized.data;
image mask = get_segmentation_image(random_paths[i], orig.w, orig.h, classes);
 //image mask = make_image(orig.w, orig.h, classes+1);
 image sized_m = rotate_crop_image(mask, a.rad, a.scale/div, a.w/div, a.h/div, a.dx/div, a.dy/div, a.aspect);
if(flip) flip_image(sized_m);
 d.y.vals[i] = sized_m.data;
free_image(orig);
 free_image(mask);
/*
 image rgb = mask_to_rgb(sized_m, classes);
 show_image(rgb, "part");
 show_image(sized, "orig");
 cvWaitKey(0);
 free_image(rgb);
 */
 }
 free(random_paths);
 return d;
}
data load_data_iseg(int n, char **paths, int m, int w, int h, int classes, int boxes, int div, int min, int max, float angle, float aspect, float hue, float saturation, float exposure)
{
 char **random_paths = get_random_paths(paths, n, m);
 int i;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
d.y = make_matrix(n, (((w/div)*(h/div))+1)*boxes);
for(i = 0; i < n; ++i){
 image orig = load_image_color(random_paths[i], 0, 0);
 augment_args a = random_augment_args(orig, angle, aspect, min, max, w, h);
 image sized = rotate_crop_image(orig, a.rad, a.scale, a.w, a.h, a.dx, a.dy, a.aspect);
int flip = rand()%2;
 if(flip) flip_image(sized);
 random_distort_image(sized, hue, saturation, exposure);
 d.X.vals[i] = sized.data;
 //show_image(sized, "image");
fill_truth_iseg(random_paths[i], boxes, d.y.vals[i], classes, orig.w, orig.h, a, flip, w/div, h/div);
free_image(orig);
/*
 image rgb = mask_to_rgb(sized_m, classes);
 show_image(rgb, "part");
 show_image(sized, "orig");
 cvWaitKey(0);
 free_image(rgb);
 */
 }
 free(random_paths);
 return d;
}
data load_data_mask(int n, char **paths, int m, int w, int h, int classes, int boxes, int coords, int min, int max, float angle, float aspect, float hue, float saturation, float exposure)
{
 char **random_paths = get_random_paths(paths, n, m);
 int i;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
d.y = make_matrix(n, (coords+1)*boxes);
for(i = 0; i < n; ++i){
 image orig = load_image_color(random_paths[i], 0, 0);
 augment_args a = random_augment_args(orig, angle, aspect, min, max, w, h);
 image sized = rotate_crop_image(orig, a.rad, a.scale, a.w, a.h, a.dx, a.dy, a.aspect);
int flip = rand()%2;
 if(flip) flip_image(sized);
 random_distort_image(sized, hue, saturation, exposure);
 d.X.vals[i] = sized.data;
 //show_image(sized, "image");
fill_truth_mask(random_paths[i], boxes, d.y.vals[i], classes, orig.w, orig.h, a, flip, 14, 14);
free_image(orig);
/*
 image rgb = mask_to_rgb(sized_m, classes);
 show_image(rgb, "part");
 show_image(sized, "orig");
 cvWaitKey(0);
 free_image(rgb);
 */
 }
 free(random_paths);
 return d;
}
data load_data_region(int n, char **paths, int m, int w, int h, int size, int classes, float jitter, float hue, float saturation, float exposure)
{
 char **random_paths = get_random_paths(paths, n, m);
 int i;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
int k = size*size*(5+classes);
 d.y = make_matrix(n, k);
 for(i = 0; i < n; ++i){
 image orig = load_image_color(random_paths[i], 0, 0);
int oh = orig.h;
 int ow = orig.w;
int dw = (ow*jitter);
 int dh = (oh*jitter);
int pleft = rand_uniform(-dw, dw);
 int pright = rand_uniform(-dw, dw);
 int ptop = rand_uniform(-dh, dh);
 int pbot = rand_uniform(-dh, dh);
int swidth = ow - pleft - pright;
 int sheight = oh - ptop - pbot;
float sx = (float)swidth / ow;
 float sy = (float)sheight / oh;
int flip = rand()%2;
 image cropped = crop_image(orig, pleft, ptop, swidth, sheight);
float dx = ((float)pleft/ow)/sx;
 float dy = ((float)ptop /oh)/sy;
image sized = resize_image(cropped, w, h);
 if(flip) flip_image(sized);
 random_distort_image(sized, hue, saturation, exposure);
 d.X.vals[i] = sized.data;
fill_truth_region(random_paths[i], d.y.vals[i], classes, size, flip, dx, dy, 1./sx, 1./sy);
free_image(orig);
 free_image(cropped);
 }
 free(random_paths);
 return d;
}
data load_data_compare(int n, char **paths, int m, int classes, int w, int h)
{
 if(m) paths = get_random_paths(paths, 2*n, m);
 int i,j;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*6;
int k = 2*(classes);
 d.y = make_matrix(n, k);
 for(i = 0; i < n; ++i){
 image im1 = load_image_color(paths[i*2], w, h);
 image im2 = load_image_color(paths[i*2+1], w, h);
d.X.vals[i] = calloc(d.X.cols, sizeof(float));
 memcpy(d.X.vals[i], im1.data, h*w*3*sizeof(float));
 memcpy(d.X.vals[i] + h*w*3, im2.data, h*w*3*sizeof(float));
int id;
 float iou;
char imlabel1[4096];
 char imlabel2[4096];
 find_replace(paths[i*2], "imgs", "labels", imlabel1);
 find_replace(imlabel1, "jpg", "txt", imlabel1);
 FILE *fp1 = fopen(imlabel1, "r");
while(fscanf(fp1, "%d %f", &id, &iou) == 2){
 if (d.y.vals[i][2*id] < iou) d.y.vals[i][2*id] = iou;
 }
find_replace(paths[i*2+1], "imgs", "labels", imlabel2);
 find_replace(imlabel2, "jpg", "txt", imlabel2);
 FILE *fp2 = fopen(imlabel2, "r");
while(fscanf(fp2, "%d %f", &id, &iou) == 2){
 if (d.y.vals[i][2*id + 1] < iou) d.y.vals[i][2*id + 1] = iou;
 }
for (j = 0; j < classes; ++j){
 if (d.y.vals[i][2*j] > .5 && d.y.vals[i][2*j+1] < .5){
 d.y.vals[i][2*j] = 1;
 d.y.vals[i][2*j+1] = 0;
 } else if (d.y.vals[i][2*j] < .5 && d.y.vals[i][2*j+1] > .5){
 d.y.vals[i][2*j] = 0;
 d.y.vals[i][2*j+1] = 1;
 } else {
 d.y.vals[i][2*j] = SECRET_NUM;
 d.y.vals[i][2*j+1] = SECRET_NUM;
 }
 }
 fclose(fp1);
 fclose(fp2);
free_image(im1);
 free_image(im2);
 }
 if(m) free(paths);
 return d;
}
data load_data_swag(char **paths, int n, int classes, float jitter)
{
 int index = rand()%n;
 char *random_path = paths[index];
image orig = load_image_color(random_path, 0, 0);
 int h = orig.h;
 int w = orig.w;
data d = {0};
 d.shallow = 0;
 d.w = w;
 d.h = h;
d.X.rows = 1;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
int k = (4+classes)*90;
 d.y = make_matrix(1, k);
int dw = w*jitter;
 int dh = h*jitter;
int pleft = rand_uniform(-dw, dw);
 int pright = rand_uniform(-dw, dw);
 int ptop = rand_uniform(-dh, dh);
 int pbot = rand_uniform(-dh, dh);
int swidth = w - pleft - pright;
 int sheight = h - ptop - pbot;
float sx = (float)swidth / w;
 float sy = (float)sheight / h;
int flip = rand()%2;
 image cropped = crop_image(orig, pleft, ptop, swidth, sheight);
float dx = ((float)pleft/w)/sx;
 float dy = ((float)ptop /h)/sy;
image sized = resize_image(cropped, w, h);
 if(flip) flip_image(sized);
 d.X.vals[0] = sized.data;
fill_truth_swag(random_path, d.y.vals[0], classes, flip, dx, dy, 1./sx, 1./sy);
free_image(orig);
 free_image(cropped);
return d;
}
data load_data_detection(int n, char **paths, int m, int w, int h, int boxes, int classes, float jitter, float hue, float saturation, float exposure)
{
 char **random_paths = get_random_paths(paths, n, m);
 int i;
 data d = {0};
 d.shallow = 0;
d.X.rows = n;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
 d.X.cols = h*w*3;
d.y = make_matrix(n, 5*boxes);
 for(i = 0; i < n; ++i){
 image orig = load_image_color(random_paths[i], 0, 0);
 image sized = make_image(w, h, orig.c);
 fill_image(sized, .5);
float dw = jitter * orig.w;
 float dh = jitter * orig.h;
float new_ar = (orig.w + rand_uniform(-dw, dw)) / (orig.h + rand_uniform(-dh, dh));
 //float scale = rand_uniform(.25, 2);
 float scale = 1;
float nw, nh;
if(new_ar < 1){
 nh = scale * h;
 nw = nh * new_ar;
 } else {
 nw = scale * w;
 nh = nw / new_ar;
 }
float dx = rand_uniform(0, w - nw);
 float dy = rand_uniform(0, h - nh);
place_image(orig, nw, nh, dx, dy, sized);
random_distort_image(sized, hue, saturation, exposure);
int flip = rand()%2;
 if(flip) flip_image(sized);
 d.X.vals[i] = sized.data;
fill_truth_detection(random_paths[i], boxes, d.y.vals[i], classes, flip, -dx/w, -dy/h, nw/w, nh/h);
free_image(orig);
 }
 free(random_paths);
 return d;
}
void *load_thread(void *ptr)
{
 //printf("Loading data: %d\n", rand());
 load_args a = *(struct load_args*)ptr;
 if(a.exposure == 0) a.exposure = 1;
 if(a.saturation == 0) a.saturation = 1;
 if(a.aspect == 0) a.aspect = 1;
if (a.type == OLD_CLASSIFICATION_DATA){
 *a.d = load_data_old(a.paths, a.n, a.m, a.labels, a.classes, a.w, a.h);
 } else if (a.type == REGRESSION_DATA){
 *a.d = load_data_regression(a.paths, a.n, a.m, a.classes, a.min, a.max, a.size, a.angle, a.aspect, a.hue, a.saturation, a.exposure);
 } else if (a.type == CLASSIFICATION_DATA){
 *a.d = load_data_augment(a.paths, a.n, a.m, a.labels, a.classes, a.hierarchy, a.min, a.max, a.size, a.angle, a.aspect, a.hue, a.saturation, a.exposure, a.center);
 } else if (a.type == SUPER_DATA){
 *a.d = load_data_super(a.paths, a.n, a.m, a.w, a.h, a.scale);
 } else if (a.type == WRITING_DATA){
 *a.d = load_data_writing(a.paths, a.n, a.m, a.w, a.h, a.out_w, a.out_h);
 } else if (a.type == ISEG_DATA){
 *a.d = load_data_iseg(a.n, a.paths, a.m, a.w, a.h, a.classes, a.num_boxes, a.scale, a.min, a.max, a.angle, a.aspect, a.hue, a.saturation, a.exposure);
 } else if (a.type == INSTANCE_DATA){
 *a.d = load_data_mask(a.n, a.paths, a.m, a.w, a.h, a.classes, a.num_boxes, a.coords, a.min, a.max, a.angle, a.aspect, a.hue, a.saturation, a.exposure);
 } else if (a.type == SEGMENTATION_DATA){
 *a.d = load_data_seg(a.n, a.paths, a.m, a.w, a.h, a.classes, a.min, a.max, a.angle, a.aspect, a.hue, a.saturation, a.exposure, a.scale);
 } else if (a.type == REGION_DATA){
 *a.d = load_data_region(a.n, a.paths, a.m, a.w, a.h, a.num_boxes, a.classes, a.jitter, a.hue, a.saturation, a.exposure);
 } else if (a.type == DETECTION_DATA){
 *a.d = load_data_detection(a.n, a.paths, a.m, a.w, a.h, a.num_boxes, a.classes, a.jitter, a.hue, a.saturation, a.exposure);
 } else if (a.type == SWAG_DATA){
 *a.d = load_data_swag(a.paths, a.n, a.classes, a.jitter);
 } else if (a.type == COMPARE_DATA){
 *a.d = load_data_compare(a.n, a.paths, a.m, a.classes, a.w, a.h);
 } else if (a.type == IMAGE_DATA){
 *(a.im) = load_image_color(a.path, 0, 0);
 *(a.resized) = resize_image(*(a.im), a.w, a.h);
 } else if (a.type == LETTERBOX_DATA){
 *(a.im) = load_image_color(a.path, 0, 0);
 *(a.resized) = letterbox_image(*(a.im), a.w, a.h);
 } else if (a.type == TAG_DATA){
 *a.d = load_data_tag(a.paths, a.n, a.m, a.classes, a.min, a.max, a.size, a.angle, a.aspect, a.hue, a.saturation, a.exposure);
 }
 free(ptr);
 return 0;
}
pthread_t load_data_in_thread(load_args args)
{
 pthread_t thread;
 struct load_args *ptr = calloc(1, sizeof(struct load_args));
 *ptr = args;
 if(pthread_create(&thread, 0, load_thread, ptr)) error("Thread creation failed");
 return thread;
}
void *load_threads(void *ptr)
{
 int i;
 load_args args = *(load_args *)ptr;
 if (args.threads == 0) args.threads = 1;
 data *out = args.d;
 int total = args.n;
 free(ptr);
 data *buffers = calloc(args.threads, sizeof(data));
 pthread_t *threads = calloc(args.threads, sizeof(pthread_t));
 for(i = 0; i < args.threads; ++i){
 args.d = buffers + i;
 args.n = (i+1) * total/args.threads - i * total/args.threads;
 threads[i] = load_data_in_thread(args);
 }
 for(i = 0; i < args.threads; ++i){
 pthread_join(threads[i], 0);
 }
 *out = concat_datas(buffers, args.threads);
 out->shallow = 0;
 for(i = 0; i < args.threads; ++i){
 buffers[i].shallow = 1;
 free_data(buffers[i]);
 }
 free(buffers);
 free(threads);
 return 0;
}
void load_data_blocking(load_args args)
{
 struct load_args *ptr = calloc(1, sizeof(struct load_args));
 *ptr = args;
 load_thread(ptr);
}
pthread_t load_data(load_args args)
{
 pthread_t thread;
 struct load_args *ptr = calloc(1, sizeof(struct load_args));
 *ptr = args;
 if(pthread_create(&thread, 0, load_threads, ptr)) error("Thread creation failed");
 return thread;
}
data load_data_writing(char **paths, int n, int m, int w, int h, int out_w, int out_h)
{
 if(m) paths = get_random_paths(paths, n, m);
 char **replace_paths = find_replace_paths(paths, n, ".png", "-label.png");
 data d = {0};
 d.shallow = 0;
 d.X = load_image_paths(paths, n, w, h);
 d.y = load_image_paths_gray(replace_paths, n, out_w, out_h);
 if(m) free(paths);
 int i;
 for(i = 0; i < n; ++i) free(replace_paths[i]);
 free(replace_paths);
 return d;
}
data load_data_old(char **paths, int n, int m, char **labels, int k, int w, int h)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
 d.X = load_image_paths(paths, n, w, h);
 d.y = load_labels_paths(paths, n, labels, k, 0);
 if(m) free(paths);
 return d;
}
/*
 data load_data_study(char **paths, int n, int m, char **labels, int k, int min, int max, int size, float angle, float aspect, float hue, float saturation, float exposure)
 {
 data d = {0};
 d.indexes = calloc(n, sizeof(int));
 if(m) paths = get_random_paths_indexes(paths, n, m, d.indexes);
 d.shallow = 0;
 d.X = load_image_augment_paths(paths, n, min, max, size, angle, aspect, hue, saturation, exposure);
 d.y = load_labels_paths(paths, n, labels, k);
 if(m) free(paths);
 return d;
 }
 */
data load_data_super(char **paths, int n, int m, int w, int h, int scale)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
int i;
 d.X.rows = n;
 d.X.vals = calloc(n, sizeof(float*));
 d.X.cols = w*h*3;
d.y.rows = n;
 d.y.vals = calloc(n, sizeof(float*));
 d.y.cols = w*scale * h*scale * 3;
for(i = 0; i < n; ++i){
 image im = load_image_color(paths[i], 0, 0);
 image crop = random_crop_image(im, w*scale, h*scale);
 int flip = rand()%2;
 if (flip) flip_image(crop);
 image resize = resize_image(crop, w, h);
 d.X.vals[i] = resize.data;
 d.y.vals[i] = crop.data;
 free_image(im);
 }
if(m) free(paths);
 return d;
}
data load_data_regression(char **paths, int n, int m, int k, int min, int max, int size, float angle, float aspect, float hue, float saturation, float exposure)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
 d.X = load_image_augment_paths(paths, n, min, max, size, angle, aspect, hue, saturation, exposure, 0);
 d.y = load_regression_labels_paths(paths, n, k);
 if(m) free(paths);
 return d;
}
data select_data(data *orig, int *inds)
{
 data d = {0};
 d.shallow = 1;
 d.w = orig[0].w;
 d.h = orig[0].h;
d.X.rows = orig[0].X.rows;
 d.y.rows = orig[0].X.rows;
d.X.cols = orig[0].X.cols;
 d.y.cols = orig[0].y.cols;
d.X.vals = calloc(orig[0].X.rows, sizeof(float *));
 d.y.vals = calloc(orig[0].y.rows, sizeof(float *));
 int i;
 for(i = 0; i < d.X.rows; ++i){
 d.X.vals[i] = orig[inds[i]].X.vals[i];
 d.y.vals[i] = orig[inds[i]].y.vals[i];
 }
 return d;
}
data *tile_data(data orig, int divs, int size)
{
 data *ds = calloc(divs*divs, sizeof(data));
 int i, j;
#pragma omp parallel for
 for(i = 0; i < divs*divs; ++i){
 data d;
 d.shallow = 0;
 d.w = orig.w/divs * size;
 d.h = orig.h/divs * size;
 d.X.rows = orig.X.rows;
 d.X.cols = d.w*d.h*3;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
d.y = copy_matrix(orig.y);
#pragma omp parallel for
 for(j = 0; j < orig.X.rows; ++j){
 int x = (i%divs) * orig.w / divs - (d.w - orig.w/divs)/2;
 int y = (i/divs) * orig.h / divs - (d.h - orig.h/divs)/2;
 image im = float_to_image(orig.w, orig.h, 3, orig.X.vals[j]);
 d.X.vals[j] = crop_image(im, x, y, d.w, d.h).data;
 }
 ds[i] = d;
 }
 return ds;
}
data resize_data(data orig, int w, int h)
{
 data d = {0};
 d.shallow = 0;
 d.w = w;
 d.h = h;
 int i;
 d.X.rows = orig.X.rows;
 d.X.cols = w*h*3;
 d.X.vals = calloc(d.X.rows, sizeof(float*));
d.y = copy_matrix(orig.y);
#pragma omp parallel for
 for(i = 0; i < orig.X.rows; ++i){
 image im = float_to_image(orig.w, orig.h, 3, orig.X.vals[i]);
 d.X.vals[i] = resize_image(im, w, h).data;
 }
 return d;
}
data load_data_augment(char **paths, int n, int m, char **labels, int k, tree *hierarchy, int min, int max, int size, float angle, float aspect, float hue, float saturation, float exposure, int center)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.shallow = 0;
 d.w=size;
 d.h=size;
 d.X = load_image_augment_paths(paths, n, min, max, size, angle, aspect, hue, saturation, exposure, center);
 d.y = load_labels_paths(paths, n, labels, k, hierarchy);
 if(m) free(paths);
 return d;
}
data load_data_tag(char **paths, int n, int m, int k, int min, int max, int size, float angle, float aspect, float hue, float saturation, float exposure)
{
 if(m) paths = get_random_paths(paths, n, m);
 data d = {0};
 d.w = size;
 d.h = size;
 d.shallow = 0;
 d.X = load_image_augment_paths(paths, n, min, max, size, angle, aspect, hue, saturation, exposure, 0);
 d.y = load_tags_paths(paths, n, k);
 if(m) free(paths);
 return d;
}
matrix concat_matrix(matrix m1, matrix m2)
{
 int i, count = 0;
 matrix m;
 m.cols = m1.cols;
 m.rows = m1.rows+m2.rows;
 m.vals = calloc(m1.rows + m2.rows, sizeof(float*));
 for(i = 0; i < m1.rows; ++i){
 m.vals[count++] = m1.vals[i];
 }
 for(i = 0; i < m2.rows; ++i){
 m.vals[count++] = m2.vals[i];
 }
 return m;
}
data concat_data(data d1, data d2)
{
 data d = {0};
 d.shallow = 1;
 d.X = concat_matrix(d1.X, d2.X);
 d.y = concat_matrix(d1.y, d2.y);
 d.w = d1.w;
 d.h = d1.h;
 return d;
}
data concat_datas(data *d, int n)
{
 int i;
 data out = {0};
 for(i = 0; i < n; ++i){
 data new = concat_data(d[i], out);
 free_data(out);
 out = new;
 }
 return out;
}
data load_categorical_data_csv(char *filename, int target, int k)
{
 data d = {0};
 d.shallow = 0;
 matrix X = csv_to_matrix(filename);
 float *truth_1d = pop_column(&X, target);
 float **truth = one_hot_encode(truth_1d, X.rows, k);
 matrix y;
 y.rows = X.rows;
 y.cols = k;
 y.vals = truth;
 d.X = X;
 d.y = y;
 free(truth_1d);
 return d;
}
data load_cifar10_data(char *filename)
{
 data d = {0};
 d.shallow = 0;
 long i,j;
 matrix X = make_matrix(10000, 3072);
 matrix y = make_matrix(10000, 10);
 d.X = X;
 d.y = y;
FILE *fp = fopen(filename, "rb");
 if(!fp) file_error(filename);
 for(i = 0; i < 10000; ++i){
 unsigned char bytes[3073];
 fread(bytes, 1, 3073, fp);
 int class = bytes[0];
 y.vals[i][class] = 1;
 for(j = 0; j < X.cols; ++j){
 X.vals[i][j] = (double)bytes[j+1];
 }
 }
 scale_data_rows(d, 1./255);
 //normalize_data_rows(d);
 fclose(fp);
 return d;
}
void get_random_batch(data d, int n, float *X, float *y)
{
 int j;
 for(j = 0; j < n; ++j){
 int index = rand()%d.X.rows;
 memcpy(X+j*d.X.cols, d.X.vals[index], d.X.cols*sizeof(float));
 memcpy(y+j*d.y.cols, d.y.vals[index], d.y.cols*sizeof(float));
 }
}
void get_next_batch(data d, int n, int offset, float *X, float *y)
{
 int j;
 for(j = 0; j < n; ++j){
 int index = offset + j;
 memcpy(X+j*d.X.cols, d.X.vals[index], d.X.cols*sizeof(float));
 if(y) memcpy(y+j*d.y.cols, d.y.vals[index], d.y.cols*sizeof(float));
 }
}
void smooth_data(data d)
{
 int i, j;
 float scale = 1. / d.y.cols;
 float eps = .1;
 for(i = 0; i < d.y.rows; ++i){
 for(j = 0; j < d.y.cols; ++j){
 d.y.vals[i][j] = eps * scale + (1-eps) * d.y.vals[i][j];
 }
 }
}
data load_all_cifar10()
{
 data d = {0};
 d.shallow = 0;
 int i,j,b;
 matrix X = make_matrix(50000, 3072);
 matrix y = make_matrix(50000, 10);
 d.X = X;
 d.y = y;
for(b = 0; b < 5; ++b){
 char buff[256];
 sprintf(buff, "data/cifar/cifar-10-batches-bin/data_batch_%d.bin", b+1);
 FILE *fp = fopen(buff, "rb");
 if(!fp) file_error(buff);
 for(i = 0; i < 10000; ++i){
 unsigned char bytes[3073];
 fread(bytes, 1, 3073, fp);
 int class = bytes[0];
 y.vals[i+b*10000][class] = 1;
 for(j = 0; j < X.cols; ++j){
 X.vals[i+b*10000][j] = (double)bytes[j+1];
 }
 }
 fclose(fp);
 }
 //normalize_data_rows(d);
 scale_data_rows(d, 1./255);
 smooth_data(d);
 return d;
}
data load_go(char *filename)
{
 FILE *fp = fopen(filename, "rb");
 matrix X = make_matrix(3363059, 361);
 matrix y = make_matrix(3363059, 361);
 int row, col;
if(!fp) file_error(filename);
 char *label;
 int count = 0;
 while((label = fgetl(fp))){
 int i;
 if(count == X.rows){
 X = resize_matrix(X, count*2);
 y = resize_matrix(y, count*2);
 }
 sscanf(label, "%d %d", &row, &col);
 char *board = fgetl(fp);
int index = row*19 + col;
 y.vals[count][index] = 1;
for(i = 0; i < 19*19; ++i){
 float val = 0;
 if(board[i] == '1') val = 1;
 else if(board[i] == '2') val = -1;
 X.vals[count][i] = val;
 }
 ++count;
 free(label);
 free(board);
 }
 X = resize_matrix(X, count);
 y = resize_matrix(y, count);
data d = {0};
 d.shallow = 0;
 d.X = X;
 d.y = y;
fclose(fp);
return d;
}
void randomize_data(data d)
{
 int i;
 for(i = d.X.rows-1; i > 0; --i){
 int index = rand()%i;
 float *swap = d.X.vals[index];
 d.X.vals[index] = d.X.vals[i];
 d.X.vals[i] = swap;
swap = d.y.vals[index];
 d.y.vals[index] = d.y.vals[i];
 d.y.vals[i] = swap;
 }
}
void scale_data_rows(data d, float s)
{
 int i;
 for(i = 0; i < d.X.rows; ++i){
 scale_array(d.X.vals[i], d.X.cols, s);
 }
}
void translate_data_rows(data d, float s)
{
 int i;
 for(i = 0; i < d.X.rows; ++i){
 translate_array(d.X.vals[i], d.X.cols, s);
 }
}
data copy_data(data d)
{
 data c = {0};
 c.w = d.w;
 c.h = d.h;
 c.shallow = 0;
 c.num_boxes = d.num_boxes;
 c.boxes = d.boxes;
 c.X = copy_matrix(d.X);
 c.y = copy_matrix(d.y);
 return c;
}
void normalize_data_rows(data d)
{
 int i;
 for(i = 0; i < d.X.rows; ++i){
 normalize_array(d.X.vals[i], d.X.cols);
 }
}
data get_data_part(data d, int part, int total)
{
 data p = {0};
 p.shallow = 1;
 p.X.rows = d.X.rows * (part + 1) / total - d.X.rows * part / total;
 p.y.rows = d.y.rows * (part + 1) / total - d.y.rows * part / total;
 p.X.cols = d.X.cols;
 p.y.cols = d.y.cols;
 p.X.vals = d.X.vals + d.X.rows * part / total;
 p.y.vals = d.y.vals + d.y.rows * part / total;
 return p;
}
data get_random_data(data d, int num)
{
 data r = {0};
 r.shallow = 1;
r.X.rows = num;
 r.y.rows = num;
r.X.cols = d.X.cols;
 r.y.cols = d.y.cols;
r.X.vals = calloc(num, sizeof(float *));
 r.y.vals = calloc(num, sizeof(float *));
int i;
 for(i = 0; i < num; ++i){
 int index = rand()%d.X.rows;
 r.X.vals[i] = d.X.vals[index];
 r.y.vals[i] = d.y.vals[index];
 }
 return r;
}
data *split_data(data d, int part, int total)
{
 data *split = calloc(2, sizeof(data));
 int i;
 int start = part*d.X.rows/total;
 int end = (part+1)*d.X.rows/total;
 data train;
 data test;
 train.shallow = test.shallow = 1;
test.X.rows = test.y.rows = end-start;
 train.X.rows = train.y.rows = d.X.rows - (end-start);
 train.X.cols = test.X.cols = d.X.cols;
 train.y.cols = test.y.cols = d.y.cols;
train.X.vals = calloc(train.X.rows, sizeof(float*));
 test.X.vals = calloc(test.X.rows, sizeof(float*));
 train.y.vals = calloc(train.y.rows, sizeof(float*));
 test.y.vals = calloc(test.y.rows, sizeof(float*));
for(i = 0; i < start; ++i){
 train.X.vals[i] = d.X.vals[i];
 train.y.vals[i] = d.y.vals[i];
 }
 for(i = start; i < end; ++i){
 test.X.vals[i-start] = d.X.vals[i];
 test.y.vals[i-start] = d.y.vals[i];
 }
 for(i = end; i < d.X.rows; ++i){
 train.X.vals[i-(end-start)] = d.X.vals[i];
 train.y.vals[i-(end-start)] = d.y.vals[i];
 }
 split[0] = train;
 split[1] = test;
 return split;
}