def generate_list_from_data(save_path, src_data, debug=True): ''' generate a file which contains a 1-d numpy array data parameter: src_data: a list of 1 element data, or a 1-d numpy array data ''' save_path = safepath(save_path) if debug: if isnparray(src_data): assert src_data.ndim == 1, 'source data is incorrect' elif islist(src_data): assert all(np.array(data_tmp).size == 1 for data_tmp in src_data), 'source data is in correct' assert isfolder(save_path) or isfile( save_path), 'save path is not correct' if isfolder(save_path): save_path = os.path.join(save_path, 'datalist.txt') if debug: assert is_path_exists_or_creatable( save_path), 'the file cannot be created' with open(save_path, 'w') as file: for item in src_data: file.write('%f\n' % item) file.close()
def save_2dmatrix_to_file(data, save_path, formatting='%.1f', debug=True): save_path = safepath(save_path) if debug: assert isnparray(data) and len( data.shape) == 2, 'input data is not 2d numpy array' assert is_path_exists_or_creatable( save_path), 'save path is not correct' mkdir_if_missing(save_path) # assert isnparray(data) and len(data.shape) <= 2, 'the data is not correct' np.savetxt(save_path, data, delimiter=' ', fmt=formatting)
def save_image(input_image, save_path, debug=True, vis=False): save_path = safepath(save_path) mkdir_if_missing(save_path) if debug: assert isimage(input_image), 'input data is not image format' assert is_path_exists_or_creatable( save_path), 'save path is not correct' pil_image = Image.fromarray(input_image) # imsave(save_path, input_image) pil_image.save(save_path)
def mkdir_if_missing(pathname, debug=True): pathname = safepath(pathname) if debug: assert is_path_exists_or_creatable( pathname), 'input path is not valid or creatable: %s' % pathname dirname, _, _ = fileparts(pathname) if not is_path_exists(dirname): mkdir_if_missing(dirname) if isfolder(pathname) and not is_path_exists(pathname): os.mkdir(pathname)
def save_image(input_image, save_path, resize_factor=None, target_size=None, input_angle=0, warning=True, debug=True): ''' load an image to a given path, with preprocessing of resizing and rotating parameters: resize_factor: a scalar target_size: a list of tuple or numpy array with 2 elements, representing height and width input_angle: a scalar, counterclockwise rotation in degree ''' save_path = safe_path(save_path, warning=warning, debug=debug); mkdir_if_missing(save_path) if debug: is_path_exists_or_creatable(save_path), 'the path is not good to save' np_image, _ = safe_image(input_image, warning=warning, debug=debug) if resize_factor is None and target_size is None: resize_factor = 1.0 # default not to have resizing # preprocessing the image before saving np_image = image_rotate(np_image, input_angle=input_angle, warning=warning, debug=debug) np_image = image_resize(np_image, resize_factor=resize_factor, target_size=target_size, warning=warning, debug=debug) # saving pil_image = Image.fromarray(np_image) pil_image.save(save_path)
def mkdir_if_missing(input_path, warning=True, debug=True): ''' create a directory if not existing: 1. if the input is a path of file, then create the parent directory of this file 2. if the root directory does not exists for the input, then create all the root directories recursively until the parent directory of input exists parameters: input_path: a string path ''' good_path = safe_path(input_path, warning=warning, debug=debug) if debug: assert is_path_exists_or_creatable( good_path), 'input path is not valid or creatable: %s' % good_path dirname, _, _ = fileparts(good_path) if not is_path_exists(dirname): mkdir_if_missing(dirname) if isfolder(good_path) and not is_path_exists(good_path): os.mkdir(good_path)
def save(self, save_path): if self.debug: assert is_path_exists_or_creatable(save_path), 'the save path is not correct' meta = {'pts_root': self.pts_root, 'pts_forward': self.pts_forward, 'pts_backward': self.pts_backward, 'pts_anno': self.pts_anno, 'image_prev_path': self.image_prev_path, 'image_next_path': self.image_next_path, 'length': self.length, 'pts_valid_index': self.pts_valid_index, 'index_dict': self.index_dict, 'key_list': self.key_list, } torch.save(meta, save_path) print('save point meta data into {}'.format(save_path))
def save_txt_file(data_list, save_path, debug=True): ''' save a list of string to a file ''' save_path = safe_path(save_path) if debug: assert is_path_exists_or_creatable( save_path ), 'text file is not able to be created at path: %s!' % save_path first_line = True with open(save_path, 'w') as file: for item in data_list: if first_line: file.write('%s' % item) first_line = False else: file.write('\n%s' % item) file.close()
def load_list_from_folders(folder_path_list, ext_filter=None, depth=1, recursive=False, save_path=None, debug=True): ''' load a list of files or folders from a list of system path ''' if debug: assert islist(folder_path_list) or isstring( folder_path_list), 'input path list is not correct' if isstring(folder_path_list): folder_path_list = [folder_path_list] fulllist = list() num_elem = 0 for folder_path_tmp in folder_path_list: fulllist_tmp, num_elem_tmp = load_list_from_folder( folder_path_tmp, ext_filter=ext_filter, depth=depth, recursive=recursive) fulllist += fulllist_tmp num_elem += num_elem_tmp # save list to a path if save_path is not None: save_path = safepath(save_path) if debug: assert is_path_exists_or_creatable( save_path), 'the file cannot be created' with open(save_path, 'w') as file: for item in fulllist: file.write('%s\n' % item) file.close() return fulllist, num_elem
def anno_writer(pts_array, pts_savepath, num_pts=68, anno_version=1, debug=True): ''' write the point array to a .pts file parameter: pts_array: 2 or 3 x num_pts numpy array ''' if debug: assert is_path_exists_or_creatable( pts_savepath), 'the save path is not correct' assert ( is2dptsarray(pts_array) or is2dptsarray_occlusion(pts_array) or is2dptsarray_confidence(pts_array) ) and pts_array.shape[1] == num_pts, 'the input point is not correct' with open(pts_savepath, 'w') as file: file.write('version: %d\n' % anno_version) file.write('n_points: %d\n' % num_pts) file.write('{\n') # main content for pts_index in xrange(num_pts): if is2dptsarray(pts_array): file.write('%.3f %.3f %f\n' % (pts_array[0, pts_index], pts_array[1, pts_index], 1.0)) # all visible else: file.write('%.3f %.3f %f\n' % (pts_array[0, pts_index], pts_array[1, pts_index], pts_array[2, pts_index])) file.write('}') file.close()
def visualize_nearest_neighbor(featuremap_dict, num_neighbor=5, top_number=5, vis=True, save_csv=False, csv_save_path=None, save_vis=False, save_img=False, save_thumb_name='nearest_neighbor.png', img_src_folder=None, ext_filter='.jpg', nn_save_folder=None, debug=True): ''' visualize nearest neighbor for featuremap from images parameter: featuremap_dict: a dictionary contains image path as key, and featuremap as value, the featuremap needs to be numpy array with any shape. No flatten needed num_neighbor: number of neighbor to visualize, the first nearest is itself top_number: number of top to visualize, since there might be tons of featuremap (length of dictionary), we choose the top ten with lowest distance with their nearest neighbor csv_save_path: path to save .csv file which contains indices and distance array for all elements nn_save_folder: save the nearest neighbor images for top featuremap return: all_sorted_nearest_id: a 2d matrix, each row is a feature followed by its nearest neighbor in whole feature dataset, the column is sorted by the distance of all nearest neighbor each row selected_nearest_id: only top number of sorted nearest id ''' print('processing feature map to nearest neightbor.......') if debug: assert isdict(featuremap_dict), 'featuremap should be dictionary' assert all( isnparray(featuremap_tmp) for featuremap_tmp in featuremap_dict. values()), 'value of dictionary should be numpy array' assert isinteger( num_neighbor ) and num_neighbor > 1, 'number of neighborhodd is an integer larger than 1' if save_csv and csv_save_path is not None: assert is_path_exists_or_creatable( csv_save_path), 'path to save .csv file is not correct' if save_vis or save_img: if nn_save_folder is not None: # save image directly assert isstring(ext_filter), 'extension filter is not correct' assert is_path_exists( img_src_folder), 'source folder for image is not correct' assert all( isstring(path_tmp) for path_tmp in featuremap_dict.keys() ) # key should be the path for the image assert is_path_exists_or_creatable( nn_save_folder ), 'folder to save top visualized images is not correct' assert isstring( save_thumb_name), 'name of thumbnail is not correct' if ext_filter.find('.') == -1: ext_filter = '.%s' % ext_filter # flatten the feature map nn_feature_dict = dict() for key, featuremap_tmp in featuremap_dict.items(): nn_feature_dict[key] = featuremap_tmp.flatten() num_features = len(nn_feature_dict) # nearest neighbor featuremap = np.array(nn_feature_dict.values()) nearbrs = NearestNeighbors(n_neighbors=num_neighbor, algorithm='ball_tree').fit(featuremap) distances, indices = nearbrs.kneighbors(featuremap) if debug: assert featuremap.shape[ 0] == num_features, 'shape of feature map is not correct' assert indices.shape == ( num_features, num_neighbor), 'shape of indices is not correct' assert distances.shape == ( num_features, num_neighbor), 'shape of indices is not correct' # convert the nearest indices for all featuremap to the key accordingly id_list = nn_feature_dict.keys() max_length = len(max( id_list, key=len)) # find the maximum length of string in the key nearest_id = np.chararray(indices.shape, itemsize=max_length + 1) for x in range(nearest_id.shape[0]): for y in range(nearest_id.shape[1]): nearest_id[x, y] = id_list[indices[x, y]] if debug: assert list(nearest_id[:, 0]) == id_list, 'nearest neighbor has problem' # sort the feature based on distance print('sorting the feature based on distance') featuremap_distance = np.sum(distances, axis=1) if debug: assert featuremap_distance.shape == ( num_features, ), 'distance is not correct' sorted_indices = np.argsort(featuremap_distance) all_sorted_nearest_id = nearest_id[sorted_indices, :] # save to the csv file if save_csv and csv_save_path is not None: print('Saving nearest neighbor result as .csv to path: %s' % csv_save_path) with open(csv_save_path, 'w+') as file: np.savetxt(file, distances, delimiter=',', fmt='%f') np.savetxt(file, all_sorted_nearest_id, delimiter=',', fmt='%s') file.close() # choose the best to visualize selected_sorted_indices = sorted_indices[0:top_number] if debug: for i in range(num_features - 1): assert featuremap_distance[ sorted_indices[i]] < featuremap_distance[sorted_indices[ i + 1]], 'feature map is not well sorted based on distance' selected_nearest_id = nearest_id[selected_sorted_indices, :] if save_vis: fig, axarray = plt.subplots(top_number, num_neighbor) for index in range(top_number): for nearest_index in range(num_neighbor): img_path = os.path.join( img_src_folder, '%s%s' % (selected_nearest_id[index, nearest_index], ext_filter)) if debug: print('loading image from %s' % img_path) img = imread(img_path) if isgrayimage_dimension(img): axarray[index, nearest_index].imshow(img, cmap='gray') elif iscolorimage_dimension(img): axarray[index, nearest_index].imshow(img) else: assert False, 'unknown error' axarray[index, nearest_index].axis('off') save_thumb = os.path.join(nn_save_folder, save_thumb_name) fig.savefig(save_thumb) if vis: plt.show() plt.close(fig) # save top visualization to the folder if save_img and nn_save_folder is not None: for top_index in range(top_number): file_list = selected_nearest_id[top_index] save_subfolder = os.path.join(nn_save_folder, file_list[0]) mkdir_if_missing(save_subfolder) for file_tmp in file_list: file_src = os.path.join(img_src_folder, '%s%s' % (file_tmp, ext_filter)) save_path = os.path.join(save_subfolder, '%s%s' % (file_tmp, ext_filter)) if debug: print('saving %s to %s' % (file_src, save_path)) shutil.copyfile(file_src, save_path) return all_sorted_nearest_id, selected_nearest_id
def visualize_ced(normed_mean_error_dict, error_threshold, normalized=True, truncated_list=None, display2terminal=True, display_list=None, title='2D PCK curve', debug=True, vis=False, pck_savepath=None, table_savepath=None, closefig=True): ''' visualize the cumulative error distribution curve (alse called NME curve or pck curve) all parameters are represented by percentage parameter: normed_mean_error_dict: a dictionary whose keys are the method name and values are (N, ) numpy array to represent error in evaluation error_threshold: threshold to display in x axis return: AUC: area under the curve MSE: mean square error ''' if debug: assert isdict( normed_mean_error_dict ), 'the input normalized mean error dictionary is not correct' assert islogical( normalized), 'the normalization flag should be logical' if normalized: assert error_threshold > 0 and error_threshold < 100, 'threshold percentage is not well set' if save: assert is_path_exists_or_creatable( pck_savepath ), 'please provide a valid path to save the pck results' assert is_path_exists_or_creatable( table_savepath ), 'please provide a valid path to save the table results' assert isstring(title), 'title is not correct' if truncated_list is not None: assert islistofscalar( truncated_list), 'the input truncated list is not correct' if display_list is not None: assert islist(display_list) and len( display_list) == len(normed_mean_error_dict ), 'the input display list is not correct' assert CHECK_EQ_LIST_UNORDERED( display_list, normed_mean_error_dict.keys(), debug=debug ), 'the input display list does not match the error dictionary key list' else: display_list = normed_mean_error_dict.keys() # set display parameters width, height = 1000, 800 legend_fontsize = 10 scale_distance = 48.8 line_index, color_index = 0, 0 figsize = width / float(dpi), height / float(dpi) fig = plt.figure(figsize=figsize) # set figure handle num_bins = 1000 if normalized: maximum_x = 1 scale = num_bins / 100 else: maximum_x = error_threshold + 1 scale = num_bins / maximum_x x_axis = np.linspace( 0, maximum_x, num_bins) # error axis, percentage of normalization factor y_axis = np.zeros(num_bins) interval_y = 10 interval_x = 1 plt.xlim(0, error_threshold) plt.ylim(0, 100) plt.yticks(np.arange(0, 100 + interval_y, interval_y)) plt.xticks(np.arange(0, error_threshold + interval_x, interval_x)) plt.grid() plt.title(title, fontsize=20) if normalized: plt.xlabel('Normalized error euclidean distance (%)', fontsize=16) else: plt.xlabel('Absolute error euclidean distance', fontsize=16) # calculate metrics for each method num_methods = len(normed_mean_error_dict) num_images = len(normed_mean_error_dict.values()[0]) metrics_dict = dict() metrics_table = list() table_title = ['Method Name / Metrics', 'AUC', 'MSE'] append2title = False assert num_images > 0, 'number of error array should be larger than 0' for ordered_index in range(num_methods): method_name = display_list[ordered_index] normed_mean_error = normed_mean_error_dict[method_name] if debug: assert isnparray( normed_mean_error ) and normed_mean_error.ndim == 1, 'shape of error distance is not good' assert len( normed_mean_error ) == num_images, 'number of testing images should be equal for all methods' assert len(linestyle_set) * len(color_set) >= len( normed_mean_error_dict) color_tmp = color_set[color_index] line_tmp = linestyle_set[line_index] for i in range(num_bins): y_axis[i] = float( (normed_mean_error < x_axis[i]).sum()) / num_images # percentage of error # calculate area under the curve and mean square error entry = dict() entry['AUC'] = np.sum(y_axis[:error_threshold * scale]) / ( error_threshold * scale) # bigger, better entry['MSE'] = np.mean(normed_mean_error) # smaller, better metrics_table_tmp = [ str(method_name), '%.2f' % (entry['AUC']), '%.1f' % (entry['MSE']) ] if truncated_list is not None: tmse_dict = calculate_truncated_mse(normed_mean_error.tolist(), truncated_list, debug=debug) for threshold in truncated_list: entry['AUC/%s' % threshold] = np.sum(y_axis[:error_threshold * scale]) / ( error_threshold * scale) # bigger, better entry['MSE/%s' % threshold] = tmse_dict[threshold]['T-MSE'] entry['percentage/%s' % threshold] = tmse_dict[threshold]['percentage'] if not append2title: table_title.append('AUC/%s' % threshold) table_title.append('MSE/%s' % threshold) table_title.append('pct/%s' % threshold) metrics_table_tmp.append('%.2f' % (entry['AUC/%s' % threshold])) metrics_table_tmp.append('%.1f' % (entry['MSE/%s' % threshold])) metrics_table_tmp.append( '%.1f' % (100 * entry['percentage/%s' % threshold]) + '%') # print metrics_table_tmp metrics_table.append(metrics_table_tmp) append2title = True metrics_dict[method_name] = entry # draw label = '%s, AUC: %.2f, MSE: %.1f (%.0f um)' % ( method_name, entry['AUC'], entry['MSE'], entry['MSE'] * scale_distance) if normalized: plt.plot(x_axis * 100, y_axis * 100, color=color_tmp, linestyle=line_tmp, label=label, lw=3) else: plt.plot(x_axis, y_axis * 100, color=color_tmp, linestyle=line_tmp, label=label, lw=3) plt.legend(loc=4, fontsize=legend_fontsize) color_index += 1 if color_index / len(color_set) == 1: line_index += 1 color_index = color_index % len(color_set) # plt.grid() plt.ylabel('{} Test Images (%)'.format(num_images), fontsize=16) save_vis_close_helper(fig=fig, ax=None, vis=vis, transparent=False, save_path=pck_savepath, debug=debug, closefig=closefig) # reorder the table order_index_list = [ display_list.index(method_name_tmp) for method_name_tmp in normed_mean_error_dict.keys() ] order_index_list = [0] + [ order_index_tmp + 1 for order_index_tmp in order_index_list ] # print table to terminal metrics_table = [table_title] + metrics_table # metrics_table = list_reorder([table_title] + metrics_table, order_index_list, debug=debug) table = AsciiTable(metrics_table) if display2terminal: print('\nprint detailed metrics') print(table.table) # save table to file if table_savepath is not None: table_file = open(table_savepath, 'w') table_file.write(table.table) table_file.close() if display2terminal: print('\nsave detailed metrics to %s' % table_savepath) return metrics_dict, metrics_table
def generate_hdf5(data_src, save_dir, data_name='data', batch_size=1, ext_filter='png', label_src1=None, label_name1='label', label_preprocess_function1=identity, label_range1=None, label_src2=None, label_name2='label2', label_preprocess_function2=identity, label_range2=None, debug=True, vis=False): ''' # this function creates data in hdf5 format from a image path # input parameter # data_src: source of image data, which can be a list of image path, a txt file contains a list of image path, a folder contains a set of images, a list of numpy array image data # label_src: source of label data, which can be none, a file contains a set of labels, a dictionary of labels, a 1-d numpy array data, a list of label data # save_dir: where to store the hdf5 data # batch_size: how many image to store in a single hdf file # ext_filder: what format of data to use for generating hdf5 data ''' # parse input assert is_path_exists_or_creatable( save_dir), 'save path should be a folder to save all hdf5 files' mkdir_if_missing(save_dir) assert isstring( data_name), 'dataset name is not correct' # name for hdf5 data # convert data source to a list of numpy array image data if isfolder(data_src): print 'data is loading from %s with extension .%s' % (data_src, ext_filter) filelist, num_data = load_list_from_folder(data_src, ext_filter=ext_filter) datalist = None elif isfile(data_src): print 'data is loading from %s with extension .%s' % (data_src, ext_filter) filelist, num_data = load_list_from_file(data_src) datalist = None elif islist(data_src): if debug: assert all( isimage(data_tmp) for data_tmp in data_src ), 'input data source is not a list of numpy array image data' datalist = data_src num_data = len(datalist) filelist = None else: assert False, 'data source format is not correct.' if debug: assert (datalist is None and filelist is not None) or ( filelist is None and datalist is not None), 'data is not correct' if datalist is not None: assert len(datalist) == num_data, 'number of data is not equal' if filelist is not None: assert len(filelist) == num_data, 'number of data is not equal' # convert label source to a list of numpy array label if label_src1 is None: labeldict1 = None labellist1 = None elif isfile(label_src1): assert is_path_exists(label_src1), 'file not found' _, _, ext = fileparts(label_src1) assert ext == '.json', 'only json extension is supported' labeldict1 = json.load(label_src1) num_label1 = len(labeldict1) assert num_data == num_label1, 'number of data and label is not equal.' labellist1 = None elif isdict(label_src1): labeldict1 = label_src1 labellist1 = None elif isnparray(label_src1): if debug: assert label_src1.ndim == 1, 'only 1-d label is supported' labeldict1 = None labellist1 = label_src1 elif islist(label_src1): if debug: assert all( np.array(label_tmp).size == 1 for label_tmp in label_src1), 'only 1-d label is supported' labellist1 = label_src1 labeldict1 = None else: assert False, 'label source format is not correct.' assert isfunction(label_preprocess_function1 ), 'label preprocess function is not correct.' # convert label source to a list of numpy array label if label_src2 is None: labeldict2 = None labellist2 = None elif isfile(label_src2): assert is_path_exists(label_src2), 'file not found' _, _, ext = fileparts(label_src2) assert ext == '.json', 'only json extension is supported' labeldict2 = json.load(label_src2) num_label2 = len(labeldict2) assert num_data == num_label2, 'number of data and label is not equal.' labellist2 = None elif isdict(label_src2): labeldict2 = label_src2 labellist2 = None elif isnparray(label_src2): if debug: assert label_src2.ndim == 1, 'only 1-d label is supported' labeldict2 = None labellist2 = label_src2 elif islist(label_src2): if debug: assert all( np.array(label_tmp).size == 1 for label_tmp in label_src2), 'only 1-d label is supported' labellist2 = label_src2 labeldict2 = None else: assert False, 'label source format is not correct.' assert isfunction(label_preprocess_function2 ), 'label preprocess function is not correct.' # warm up if datalist is not None: size_data = datalist[0].shape else: size_data = imread(filelist[0]).shape if labeldict1 is not None: if debug: assert isstring(label_name1), 'label name is not correct' labels1 = np.zeros((batch_size, 1), dtype='float32') # label_value1 = [float(label_tmp_char) for label_tmp_char in labeldict1.values()] # label_range1 = np.array([min(label_value1), max(label_value1)]) if labellist1 is not None: labels1 = np.zeros((batch_size, 1), dtype='float32') # label_range1 = [np.min(labellist1), np.max(labellist1)] if label_src1 is not None and debug: assert label_range1 is not None, 'label range is not correct' assert (labeldict1 is not None and labellist1 is None) or ( labellist1 is not None and labeldict1 is None), 'label is not correct' if labeldict2 is not None: if debug: assert isstring(label_name2), 'label name is not correct' labels2 = np.zeros((batch_size, 1), dtype='float32') # label_value2 = [float(label_tmp_char) for label_tmp_char in labeldict2.values()] # label_range2 = np.array([min(label_value2), max(label_value2)]) if labellist2 is not None: labels2 = np.zeros((batch_size, 1), dtype='float32') # label_range2 = [np.min(labellist2), np.max(labellist2)] if label_src2 is not None and debug: assert label_range2 is not None, 'label range is not correct' assert (labeldict2 is not None and labellist2 is None) or ( labellist2 is not None and labeldict2 is None), 'label is not correct' # start generating count_hdf = 1 # count number of hdf5 file clock = Timer() datalist_batch = list() for i in xrange(num_data): clock.tic() if filelist is not None: imagefile = filelist[i] _, name, _ = fileparts(imagefile) img = imread(imagefile).astype('float32') max_value = np.max(img) if max_value > 1 and max_value <= 255: img = img / 255.0 # [rows,col,channel,numbers], scale the image data to (0, 1) if debug: min_value = np.min(img) assert min_value >= 0 and min_value <= 1, 'data is not in [0, 1]' if datalist is not None: img = datalist[i] if debug: assert size_data == img.shape datalist_batch.append(img) # process label if labeldict1 is not None: if debug: assert len(filelist) == len( labeldict1), 'file list is not equal to label dictionary' labels1[i % batch_size, 0] = float(labeldict1[name]) if labellist1 is not None: labels1[i % batch_size, 0] = float(labellist1[i]) if labeldict2 is not None: if debug: assert len(filelist) == len( labeldict2), 'file list is not equal to label dictionary' labels2[i % batch_size, 0] = float(labeldict2[name]) if labellist2 is not None: labels2[i % batch_size, 0] = float(labellist2[i]) # save to hdf5 if i % batch_size == 0: data = preprocess_image_caffe( datalist_batch, debug=debug, vis=vis ) # swap channel, transfer from list of HxWxC to NxCxHxW # write to hdf5 format if filelist is not None: save_path = os.path.join(save_dir, '%s.hdf5' % name) else: save_path = os.path.join(save_dir, 'image_%010d.hdf5' % count_hdf) h5f = h5py.File(save_path, 'w') h5f.create_dataset(data_name, data=data, dtype='float32') if (labeldict1 is not None) or (labellist1 is not None): # print(labels1) labels1 = label_preprocess_function1(data=labels1, data_range=label_range1, debug=debug) # print(labels1) h5f.create_dataset(label_name1, data=labels1, dtype='float32') labels1 = np.zeros((batch_size, 1), dtype='float32') if (labeldict2 is not None) or (labellist2 is not None): labels2 = label_preprocess_function2(data=labels2, data_range=label_range2, debug=debug) h5f.create_dataset(label_name2, data=labels2, dtype='float32') labels2 = np.zeros((batch_size, 1), dtype='float32') h5f.close() count_hdf = count_hdf + 1 del datalist_batch[:] if debug: assert len(datalist_batch) == 0, 'list has not been cleared' average_time = clock.toc() print( 'saving to %s: %d/%d, average time:%.3f, elapsed time:%s, estimated time remaining:%s' % (save_path, i + 1, num_data, average_time, convert_secs2time(average_time * i), convert_secs2time(average_time * (num_data - i)))) return count_hdf - 1, num_data
def load_list_from_folder(folder_path, ext_filter=None, depth=1, recursive=False, sort=True, save_path=None, debug=True): ''' load a list of files or folders from a system path parameters: folder_path: root to search ext_filter: a string to represent the extension of files interested depth: maximum depth of folder to search, when it's None, all levels of folders will be searched recursive: False: only return current level True: return all levels till to the input depth outputs: fulllist: a list of elements num_elem: number of the elements ''' folder_path = safepath(folder_path) if debug: assert isfolder( folder_path), 'input folder path is not correct: %s' % folder_path if not is_path_exists(folder_path): return [], 0 if debug: assert islogical( recursive), 'recursive should be a logical variable: {}'.format( recursive) assert depth is None or ( isinteger(depth) and depth >= 1), 'input depth is not correct {}'.format(depth) assert ext_filter is None or (islist(ext_filter) and all( isstring(ext_tmp) for ext_tmp in ext_filter)) or isstring( ext_filter), 'extension filter is not correct' if isstring(ext_filter): # convert to a list ext_filter = [ext_filter] fulllist = list() if depth is None: # find all files recursively recursive = True wildcard_prefix = '**' if ext_filter is not None: for ext_tmp in ext_filter: wildcard = os.path.join(wildcard_prefix, '*' + string2ext_filter(ext_tmp)) curlist = glob2.glob(os.path.join(folder_path, wildcard)) if sort: curlist = sorted(curlist) fulllist += curlist else: wildcard = wildcard_prefix curlist = glob2.glob(os.path.join(folder_path, wildcard)) if sort: curlist = sorted(curlist) fulllist += curlist else: # find files based on depth and recursive flag wildcard_prefix = '*' for index in range(depth - 1): wildcard_prefix = os.path.join(wildcard_prefix, '*') if ext_filter is not None: for ext_tmp in ext_filter: wildcard = wildcard_prefix + string2ext_filter(ext_tmp) curlist = glob.glob(os.path.join(folder_path, wildcard)) if sort: curlist = sorted(curlist) fulllist += curlist else: wildcard = wildcard_prefix curlist = glob.glob(os.path.join(folder_path, wildcard)) if sort: curlist = sorted(curlist) fulllist += curlist if recursive and depth > 1: newlist, _ = load_list_from_folder(folder_path=folder_path, ext_filter=ext_filter, depth=depth - 1, recursive=True) fulllist += newlist fulllist = [os.path.normpath(path_tmp) for path_tmp in fulllist] num_elem = len(fulllist) # save list to a path if save_path is not None: save_path = safepath(save_path) if debug: assert is_path_exists_or_creatable( save_path), 'the file cannot be created' with open(save_path, 'w') as file: for item in fulllist: file.write('%s\n' % item) file.close() return fulllist, num_elem