#include "data.h" #include "utils.h" #include "image.h" #include #include #include unsigned int data_seed; struct load_args{ char **paths; int n; int m; char **labels; int k; int h; int w; int nh; int nw; int num_boxes; int classes; int background; data *d; }; 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(char **paths, int n, int m) { char **random_paths = calloc(n, sizeof(char*)); int i; for(i = 0; i < n; ++i){ int index = rand_r(&data_seed)%m; random_paths[i] = paths[index]; if(i == 0) printf("%s\n", paths[index]); } 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 = find_replace(paths[i], find, replace); 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, 1); 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; } typedef struct{ int id; float x,y,w,h; float left, right, top, bottom; } box_label; box_label *read_boxes(char *filename, int *n) { box_label *boxes = calloc(1, sizeof(box_label)); FILE *file = fopen(filename, "r"); if(!file) file_error(filename); float x, y, h, w; int id; int count = 0; while(fscanf(file, "%d %f %f %f %f", &id, &x, &y, &w, &h) == 5){ boxes = realloc(boxes, (count+1)*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_r(&data_seed)%n; b[i] = b[index]; b[index] = swap; } } void fill_truth_detection(char *path, float *truth, int classes, int num_boxes, int flip, int background, float dx, float dy, float sx, float sy) { char *labelpath = find_replace(path, "detection_images", "labels"); labelpath = find_replace(labelpath, ".jpg", ".txt"); labelpath = find_replace(labelpath, ".JPEG", ".txt"); int count = 0; box_label *boxes = read_boxes(labelpath, &count); randomize_boxes(boxes, count); float x,y,w,h; float left, top, right, bot; int id; int i; if(background){ for(i = 0; i < num_boxes*num_boxes*(4+classes+background); i += 4+classes+background){ truth[i] = 1; } } for(i = 0; i < count; ++i){ left = boxes[i].left * sx - dx; right = boxes[i].right * sx - dx; top = boxes[i].top * sy - dy; bot = boxes[i].bottom* sy - dy; id = boxes[i].id; if(flip){ float swap = left; left = 1. - right; right = 1. - swap; } left = constrain(0, 1, left); right = constrain(0, 1, right); top = constrain(0, 1, top); bot = constrain(0, 1, bot); x = (left+right)/2; y = (top+bot)/2; w = (right - left); h = (bot - top); if (x <= 0 || x >= 1 || y <= 0 || y >= 1) continue; int i = (int)(x*num_boxes); int j = (int)(y*num_boxes); x = x*num_boxes - i; y = y*num_boxes - j; /* float maxwidth = distance_from_edge(i, num_boxes); float maxheight = distance_from_edge(j, num_boxes); w = w/maxwidth; h = h/maxheight; */ w = constrain(0, 1, w); h = constrain(0, 1, h); if (w < .01 || h < .01) continue; if(1){ //w = sqrt(w); //h = sqrt(h); w = pow(w, 1./2.); h = pow(h, 1./2.); } int index = (i+j*num_boxes)*(4+classes+background); if(truth[index+classes+background+2]) continue; if(background) truth[index++] = 0; truth[index+id] = 1; index += classes; truth[index++] = x; truth[index++] = y; truth[index++] = w; truth[index++] = h; } free(boxes); } void fill_truth_localization(char *path, float *truth, int classes, int flip, float dx, float dy, float sx, float sy) { char *labelpath = find_replace(path, "objects", "object_labels"); labelpath = find_replace(labelpath, ".jpg", ".txt"); labelpath = find_replace(labelpath, ".JPEG", ".txt"); int count; box_label *boxes = read_boxes(labelpath, &count); box_label box = boxes[0]; free(boxes); float x,y,w,h; float left, top, right, bot; int id; int i; for(i = 0; i < count; ++i){ left = box.left * sx - dx; right = box.right * sx - dx; top = box.top * sy - dy; bot = box.bottom* sy - dy; id = box.id; if(flip){ float swap = left; left = 1. - right; right = 1. - swap; } left = constrain(0, 1, left); right = constrain(0, 1, right); top = constrain(0, 1, top); bot = constrain(0, 1, bot); x = (left+right)/2; y = (top+bot)/2; w = (right - left); h = (bot - top); if (x <= 0 || x >= 1 || y <= 0 || y >= 1) continue; w = constrain(0, 1, w); h = constrain(0, 1, h); if (w == 0 || h == 0) continue; int index = id*4; truth[index++] = x; truth[index++] = y; truth[index++] = w; truth[index++] = h; } } #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; 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; 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; } } if(count != 1) printf("%d, %s\n", count, path); } matrix load_labels_paths(char **paths, int n, char **labels, int k) { matrix y = make_matrix(n, k); int i; for(i = 0; i < n && labels; ++i){ fill_truth(paths[i], labels, k, y.vals[i]); } 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); } } data load_data_localization(int n, char **paths, int m, int classes, int w, int h) { char **random_paths = get_random_paths(paths, n, m); int i; data d; d.shallow = 0; d.X.rows = n; d.X.vals = calloc(d.X.rows, sizeof(float*)); d.X.cols = h*w*3; int k = (4*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 = 32; int dh = 32; int pleft = (rand_uniform() * dw); int pright = (rand_uniform() * dw); int ptop = (rand_uniform() * dh); int pbot = (rand_uniform() * dh); int swidth = ow - pleft - pright; int sheight = oh - ptop - pbot; float sx = (float)swidth / ow; float sy = (float)sheight / oh; int flip = rand_r(&data_seed)%2; image cropped = crop_image(orig, pleft, ptop, swidth, sheight); float dx = ((float)pleft/ow)/sx; float dy = ((float)ptop /oh)/sy; free_image(orig); image sized = resize_image(cropped, w, h); free_image(cropped); if(flip) flip_image(sized); d.X.vals[i] = sized.data; fill_truth_localization(random_paths[i], d.y.vals[i], classes, flip, dx, dy, 1./sx, 1./sy); } free(random_paths); return d; } data load_data_detection_jitter_random(int n, char **paths, int m, int classes, int w, int h, int num_boxes, int background) { char **random_paths = get_random_paths(paths, n, m); int i; data d; d.shallow = 0; d.X.rows = n; d.X.vals = calloc(d.X.rows, sizeof(float*)); d.X.cols = h*w*3; int k = num_boxes*num_boxes*(4+classes+background); 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/10; int dh = oh/10; int pleft = (rand_uniform() * 2*dw - dw); int pright = (rand_uniform() * 2*dw - dw); int ptop = (rand_uniform() * 2*dh - dh); int pbot = (rand_uniform() * 2*dh - dh); int swidth = ow - pleft - pright; int sheight = oh - ptop - pbot; float sx = (float)swidth / ow; float sy = (float)sheight / oh; /* float angle = rand_uniform()*.1 - .05; image rot = rotate_image(orig, angle); free_image(orig); orig = rot; */ int flip = rand_r(&data_seed)%2; image cropped = crop_image(orig, pleft, ptop, swidth, sheight); float dx = ((float)pleft/ow)/sx; float dy = ((float)ptop /oh)/sy; free_image(orig); image sized = resize_image(cropped, w, h); free_image(cropped); if(flip) flip_image(sized); d.X.vals[i] = sized.data; fill_truth_detection(random_paths[i], d.y.vals[i], classes, num_boxes, flip, background, dx, dy, 1./sx, 1./sy); } free(random_paths); return d; } void *load_localization_thread(void *ptr) { printf("Loading data: %d\n", rand_r(&data_seed)); struct load_args a = *(struct load_args*)ptr; *a.d = load_data_localization(a.n, a.paths, a.m, a.classes, a.w, a.h); free(ptr); return 0; } pthread_t load_data_localization_thread(int n, char **paths, int m, int classes, int w, int h, data *d) { pthread_t thread; struct load_args *args = calloc(1, sizeof(struct load_args)); args->n = n; args->paths = paths; args->m = m; args->w = w; args->h = h; args->classes = classes; args->d = d; if(pthread_create(&thread, 0, load_localization_thread, args)) { error("Thread creation failed"); } return thread; } void *load_detection_thread(void *ptr) { printf("Loading data: %d\n", rand_r(&data_seed)); struct load_args a = *(struct load_args*)ptr; *a.d = load_data_detection_jitter_random(a.n, a.paths, a.m, a.classes, a.w, a.h, a.num_boxes, a.background); free(ptr); return 0; } pthread_t load_data_detection_thread(int n, char **paths, int m, int classes, int w, int h, int nh, int nw, int background, data *d) { pthread_t thread; struct load_args *args = calloc(1, sizeof(struct load_args)); args->n = n; args->paths = paths; args->m = m; args->h = h; args->w = w; args->nh = nh; args->nw = nw; args->num_boxes = nw; args->classes = classes; args->background = background; args->d = d; if(pthread_create(&thread, 0, load_detection_thread, args)) { error("Thread creation failed"); } return thread; } data load_data_writing(char **paths, int n, int m, int w, int h) { if(m) paths = get_random_paths(paths, n, m); char **replace_paths = find_replace_paths(paths, n, ".png", "-label.png"); data d; d.shallow = 0; d.X = load_image_paths(paths, n, w, h); d.y = load_image_paths_gray(replace_paths, n, w/8, h/8); if(m) free(paths); int i; for(i = 0; i < n; ++i) free(replace_paths[i]); free(replace_paths); return d; } data load_data(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; d.shallow = 0; d.X = load_image_paths(paths, n, w, h); d.y = load_labels_paths(paths, n, labels, k); if(m) free(paths); return d; } void *load_in_thread(void *ptr) { struct load_args a = *(struct load_args*)ptr; *a.d = load_data(a.paths, a.n, a.m, a.labels, a.k, a.w, a.h); free(ptr); return 0; } pthread_t load_data_thread(char **paths, int n, int m, char **labels, int k, int w, int h, data *d) { pthread_t thread; struct load_args *args = calloc(1, sizeof(struct load_args)); args->n = n; args->paths = paths; args->m = m; args->labels = labels; args->k = k; args->h = h; args->w = w; args->d = d; if(pthread_create(&thread, 0, load_in_thread, args)) { error("Thread creation failed"); } return thread; } 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; d.shallow = 1; d.X = concat_matrix(d1.X, d2.X); d.y = concat_matrix(d1.y, d2.y); return d; } data load_categorical_data_csv(char *filename, int target, int k) { data d; 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; 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]; } } translate_data_rows(d, -128); scale_data_rows(d, 1./128); //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_r(&data_seed)%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)); memcpy(y+j*d.y.cols, d.y.vals[index], d.y.cols*sizeof(float)); } } data load_all_cifar10() { data d; 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/cifar10/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); translate_data_rows(d, -128); scale_data_rows(d, 1./128); return d; } void randomize_data(data d) { int i; for(i = d.X.rows-1; i > 0; --i){ int index = rand_r(&data_seed)%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); } } 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 *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; }