import contextlib import itertools import multiprocessing import os import pickle import urllib from pathlib import Path from contextlib import ExitStack import quapy as qp import numpy as np from joblib import Parallel, delayed from time import time import signal def _get_parallel_slices(n_tasks, n_jobs): if n_jobs == -1: n_jobs = multiprocessing.cpu_count() batch = int(n_tasks / n_jobs) remainder = n_tasks % n_jobs return [slice(job * batch, (job + 1) * batch + (remainder if job == n_jobs - 1 else 0)) for job in range(n_jobs)] def map_parallel(func, args, n_jobs): """ Applies func to n_jobs slices of args. E.g., if args is an array of 99 items and n_jobs=2, then func is applied in two parallel processes to args[0:50] and to args[50:99]. func is a function that already works with a list of arguments. :param func: function to be parallelized :param args: array-like of arguments to be passed to the function in different parallel calls :param n_jobs: the number of workers """ args = np.asarray(args) slices = _get_parallel_slices(len(args), n_jobs) results = Parallel(n_jobs=n_jobs)( delayed(func)(args[slice_i]) for slice_i in slices ) return list(itertools.chain.from_iterable(results)) def parallel(func, args, n_jobs, seed=None, asarray=True, backend='loky'): """ A wrapper of multiprocessing: >>> Parallel(n_jobs=n_jobs)( >>> delayed(func)(args_i) for args_i in args >>> ) that takes the `quapy.environ` variable as input silently. Seeds the child processes to ensure reproducibility when n_jobs>1. :param func: callable :param args: args of func :param seed: the numeric seed :param asarray: set to True to return a np.ndarray instead of a list :param backend: indicates the backend used for handling parallel works :param open_args: if True, then the delayed function is called on *args_i, instead of on args_i """ def func_dec(environ, seed, *args): qp.environ = environ.copy() qp.environ['N_JOBS'] = 1 #set a context with a temporal seed to ensure results are reproducibles in parallel with ExitStack() as stack: if seed is not None: stack.enter_context(qp.util.temp_seed(seed)) return func(*args) out = Parallel(n_jobs=n_jobs, backend=backend)( delayed(func_dec)(qp.environ, None if seed is None else seed+i, args_i) for i, args_i in enumerate(args) ) if asarray: out = np.asarray(out) return out def parallel_unpack(func, args, n_jobs, seed=None, asarray=True, backend='loky'): """ A wrapper of multiprocessing: >>> Parallel(n_jobs=n_jobs)( >>> delayed(func)(*args_i) for args_i in args >>> ) that takes the `quapy.environ` variable as input silently. Seeds the child processes to ensure reproducibility when n_jobs>1. :param func: callable :param args: args of func :param seed: the numeric seed :param asarray: set to True to return a np.ndarray instead of a list :param backend: indicates the backend used for handling parallel works """ def func_dec(environ, seed, *args): qp.environ = environ.copy() qp.environ['N_JOBS'] = 1 # set a context with a temporal seed to ensure results are reproducibles in parallel with ExitStack() as stack: if seed is not None: stack.enter_context(qp.util.temp_seed(seed)) return func(*args) out = Parallel(n_jobs=n_jobs, backend=backend)( delayed(func_dec)(qp.environ, None if seed is None else seed + i, *args_i) for i, args_i in enumerate(args) ) if asarray: out = np.asarray(out) return out @contextlib.contextmanager def temp_seed(random_state): """ Can be used in a "with" context to set a temporal seed without modifying the outer numpy's current state. E.g.: >>> with temp_seed(random_seed): >>> pass # do any computation depending on np.random functionality :param random_state: the seed to set within the "with" context """ if random_state is not None: state = np.random.get_state() #save the seed just in case is needed (for instance for setting the seed to child processes) qp.environ['_R_SEED'] = random_state np.random.seed(random_state) try: yield finally: if random_state is not None: np.random.set_state(state) def download_file(url, archive_filename): """ Downloads a file from a url :param url: the url :param archive_filename: destination filename """ def progress(blocknum, bs, size): total_sz_mb = '%.2f MB' % (size / 1e6) current_sz_mb = '%.2f MB' % ((blocknum * bs) / 1e6) print('\rdownloaded %s / %s' % (current_sz_mb, total_sz_mb), end='') print("Downloading %s" % url) urllib.request.urlretrieve(url, filename=archive_filename, reporthook=progress) print("") def download_file_if_not_exists(url, archive_filename): """ Dowloads a function (using :meth:`download_file`) if the file does not exist. :param url: the url :param archive_filename: destination filename """ if os.path.exists(archive_filename): return create_if_not_exist(os.path.dirname(archive_filename)) download_file(url, archive_filename) def create_if_not_exist(path): """ An alias to `os.makedirs(path, exist_ok=True)` that also returns the path. This is useful in cases like, e.g.: >>> path = create_if_not_exist(os.path.join(dir, subdir, anotherdir)) :param path: path to create :return: the path itself """ os.makedirs(path, exist_ok=True) return path def get_quapy_home(): """ Gets the home directory of QuaPy, i.e., the directory where QuaPy saves permanent data, such as dowloaded datasets. This directory is `~/quapy_data` :return: a string representing the path """ home = os.path.join(str(Path.home()), 'quapy_data') os.makedirs(home, exist_ok=True) return home def create_parent_dir(path): """ Creates the parent dir (if any) of a given path, if not exists. E.g., for `./path/to/file.txt`, the path `./path/to` is created. :param path: the path """ parentdir = Path(path).parent if parentdir: os.makedirs(parentdir, exist_ok=True) def save_text_file(path, text): """ Saves a text file to disk, given its full path, and creates the parent directory if missing. :param path: path where to save the path. :param text: text to save. """ create_parent_dir(path) with open(text, 'wt') as fout: fout.write(text) def pickled_resource(pickle_path:str, generation_func:callable, *args): """ Allows for fast reuse of resources that are generated only once by calling generation_func(\\*args). The next times this function is invoked, it loads the pickled resource. Example: >>> def some_array(n): # a mock resource created with one parameter (`n`) >>> return np.random.rand(n) >>> pickled_resource('./my_array.pkl', some_array, 10) # the resource does not exist: it is created by calling some_array(10) >>> pickled_resource('./my_array.pkl', some_array, 10) # the resource exists; it is loaded from './my_array.pkl' :param pickle_path: the path where to save (first time) and load (next times) the resource :param generation_func: the function that generates the resource, in case it does not exist in pickle_path :param args: any arg that generation_func uses for generating the resources :return: the resource """ if pickle_path is None: return generation_func(*args) else: if os.path.exists(pickle_path): return pickle.load(open(pickle_path, 'rb')) else: instance = generation_func(*args) os.makedirs(str(Path(pickle_path).parent), exist_ok=True) pickle.dump(instance, open(pickle_path, 'wb'), pickle.HIGHEST_PROTOCOL) return instance def _check_sample_size(sample_size): if sample_size is None: assert qp.environ['SAMPLE_SIZE'] is not None, \ 'error: sample_size set to None, and cannot be resolved from the environment' sample_size = qp.environ['SAMPLE_SIZE'] assert isinstance(sample_size, int) and sample_size > 0, \ 'error: sample_size is not a positive integer' return sample_size class EarlyStop: """ A class implementing the early-stopping condition typically used for training neural networks. >>> earlystop = EarlyStop(patience=2, lower_is_better=True) >>> earlystop(0.9, epoch=0) >>> earlystop(0.7, epoch=1) >>> earlystop.IMPROVED # is True >>> earlystop(1.0, epoch=2) >>> earlystop.STOP # is False (patience=1) >>> earlystop(1.0, epoch=3) >>> earlystop.STOP # is True (patience=0) >>> earlystop.best_epoch # is 1 >>> earlystop.best_score # is 0.7 :param patience: the number of (consecutive) times that a monitored evaluation metric (typically obtaind in a held-out validation split) can be found to be worse than the best one obtained so far, before flagging the stopping condition. An instance of this class is `callable`, and is to be used as follows: :param lower_is_better: if True (default) the metric is to be minimized. :ivar best_score: keeps track of the best value seen so far :ivar best_epoch: keeps track of the epoch in which the best score was set :ivar STOP: flag (boolean) indicating the stopping condition :ivar IMPROVED: flag (boolean) indicating whether there was an improvement in the last call """ def __init__(self, patience, lower_is_better=True): self.PATIENCE_LIMIT = patience self.better = lambda a,b: ab self.patience = patience self.best_score = None self.best_epoch = None self.STOP = False self.IMPROVED = False def __call__(self, watch_score, epoch): """ Commits the new score found in epoch `epoch`. If the score improves over the best score found so far, then the patiente counter gets reset. If otherwise, the patience counter is decreased, and in case it reachs 0, the flag STOP becomes True. :param watch_score: the new score :param epoch: the current epoch """ self.IMPROVED = (self.best_score is None or self.better(watch_score, self.best_score)) if self.IMPROVED: self.best_score = watch_score self.best_epoch = epoch self.patience = self.PATIENCE_LIMIT else: self.patience -= 1 if self.patience <= 0: self.STOP = True @contextlib.contextmanager def timeout(seconds): """ Opens a context that will launch an exception if not closed after a given number of seconds >>> def func(start_msg, end_msg): >>> print(start_msg) >>> sleep(2) >>> print(end_msg) >>> >>> with timeout(1): >>> func('begin function', 'end function') >>> Out[] >>> begin function >>> TimeoutError :param seconds: number of seconds, set to <=0 to ignore the timer """ if seconds > 0: def handler(signum, frame): raise TimeoutError() signal.signal(signal.SIGALRM, handler) signal.alarm(seconds) yield if seconds > 0: signal.alarm(0)