import sys from contextlib import contextmanager from functools import wraps from time import sleep, time # Use relative/cpu timer to have reliable timings when there is a sudden load try: from time import process_time except ImportError: from time import clock process_time = clock from tqdm import tqdm, trange from .tests_tqdm import importorskip, mark, patch_lock, skip pytestmark = mark.slow def cpu_sleep(t): """Sleep the given amount of cpu time""" start = process_time() while (process_time() - start) < t: pass def checkCpuTime(sleeptime=0.2): """Check if cpu time works correctly""" if checkCpuTime.passed: return True # First test that sleeping does not consume cputime start1 = process_time() sleep(sleeptime) t1 = process_time() - start1 # secondly check by comparing to cpusleep (where we actually do something) start2 = process_time() cpu_sleep(sleeptime) t2 = process_time() - start2 if abs(t1) < 0.0001 and t1 < t2 / 10: checkCpuTime.passed = True return True skip("cpu time not reliable on this machine") checkCpuTime.passed = False @contextmanager def relative_timer(): """yields a context timer function which stops ticking on exit""" start = process_time() def elapser(): return process_time() - start yield lambda: elapser() spent = elapser() def elapser(): # NOQA return spent def retry_on_except(n=3, check_cpu_time=True): """decroator for retrying `n` times before raising Exceptions""" def wrapper(func): """actual decorator""" @wraps(func) def test_inner(*args, **kwargs): """may skip if `check_cpu_time` fails""" for i in range(1, n + 1): try: if check_cpu_time: checkCpuTime() func(*args, **kwargs) except Exception: if i >= n: raise else: return return test_inner return wrapper def simple_progress(iterable=None, total=None, file=sys.stdout, desc='', leave=False, miniters=1, mininterval=0.1, width=60): """Simple progress bar reproducing tqdm's major features""" n = [0] # use a closure start_t = [time()] last_n = [0] last_t = [0] if iterable is not None: total = len(iterable) def format_interval(t): mins, s = divmod(int(t), 60) h, m = divmod(mins, 60) if h: return '{0:d}:{1:02d}:{2:02d}'.format(h, m, s) else: return '{0:02d}:{1:02d}'.format(m, s) def update_and_print(i=1): n[0] += i if (n[0] - last_n[0]) >= miniters: last_n[0] = n[0] if (time() - last_t[0]) >= mininterval: last_t[0] = time() # last_t[0] == current time spent = last_t[0] - start_t[0] spent_fmt = format_interval(spent) rate = n[0] / spent if spent > 0 else 0 rate_fmt = "%.2fs/it" % (1.0 / rate) if 0.0 < rate < 1.0 else "%.2fit/s" % rate frac = n[0] / total percentage = int(frac * 100) eta = (total - n[0]) / rate if rate > 0 else 0 eta_fmt = format_interval(eta) # full_bar = "#" * int(frac * width) barfill = " " * int((1.0 - frac) * width) bar_length, frac_bar_length = divmod(int(frac * width * 10), 10) full_bar = '#' * bar_length frac_bar = chr(48 + frac_bar_length) if frac_bar_length else ' ' file.write("\r%s %i%%|%s%s%s| %i/%i [%s<%s, %s]" % (desc, percentage, full_bar, frac_bar, barfill, n[0], total, spent_fmt, eta_fmt, rate_fmt)) if n[0] == total and leave: file.write("\n") file.flush() def update_and_yield(): for elt in iterable: yield elt update_and_print() update_and_print(0) if iterable is not None: return update_and_yield() else: return update_and_print def assert_performance(thresh, name_left, time_left, name_right, time_right): """raises if time_left > thresh * time_right""" if time_left > thresh * time_right: raise ValueError( ('{name[0]}: {time[0]:f}, ' '{name[1]}: {time[1]:f}, ' 'ratio {ratio:f} > {thresh:f}').format( name=(name_left, name_right), time=(time_left, time_right), ratio=time_left / time_right, thresh=thresh)) @retry_on_except() def test_iter_basic_overhead(): """Test overhead of iteration based tqdm""" total = int(1e6) a = 0 with trange(total) as t: with relative_timer() as time_tqdm: for i in t: a += i assert a == (total ** 2 - total) / 2.0 a = 0 with relative_timer() as time_bench: for i in range(total): a += i sys.stdout.write(str(a)) assert_performance(3, 'trange', time_tqdm(), 'range', time_bench()) @retry_on_except() def test_manual_basic_overhead(): """Test overhead of manual tqdm""" total = int(1e6) with tqdm(total=total * 10, leave=True) as t: a = 0 with relative_timer() as time_tqdm: for i in range(total): a += i t.update(10) a = 0 with relative_timer() as time_bench: for i in range(total): a += i sys.stdout.write(str(a)) assert_performance(5, 'tqdm', time_tqdm(), 'range', time_bench()) def worker(total, blocking=True): def incr_bar(x): for _ in trange(total, lock_args=None if blocking else (False,), miniters=1, mininterval=0, maxinterval=0): pass return x + 1 return incr_bar @retry_on_except() @patch_lock(thread=True) def test_lock_args(): """Test overhead of nonblocking threads""" ThreadPoolExecutor = importorskip('concurrent.futures').ThreadPoolExecutor total = 16 subtotal = 10000 with ThreadPoolExecutor() as pool: sys.stderr.write('block ... ') sys.stderr.flush() with relative_timer() as time_tqdm: res = list(pool.map(worker(subtotal, True), range(total))) assert sum(res) == sum(range(total)) + total sys.stderr.write('noblock ... ') sys.stderr.flush() with relative_timer() as time_noblock: res = list(pool.map(worker(subtotal, False), range(total))) assert sum(res) == sum(range(total)) + total assert_performance(0.5, 'noblock', time_noblock(), 'tqdm', time_tqdm()) @retry_on_except(10) def test_iter_overhead_hard(): """Test overhead of iteration based tqdm (hard)""" total = int(1e5) a = 0 with trange(total, leave=True, miniters=1, mininterval=0, maxinterval=0) as t: with relative_timer() as time_tqdm: for i in t: a += i assert a == (total ** 2 - total) / 2.0 a = 0 with relative_timer() as time_bench: for i in range(total): a += i sys.stdout.write(("%i" % a) * 40) assert_performance(130, 'trange', time_tqdm(), 'range', time_bench()) @retry_on_except(10) def test_manual_overhead_hard(): """Test overhead of manual tqdm (hard)""" total = int(1e5) with tqdm(total=total * 10, leave=True, miniters=1, mininterval=0, maxinterval=0) as t: a = 0 with relative_timer() as time_tqdm: for i in range(total): a += i t.update(10) a = 0 with relative_timer() as time_bench: for i in range(total): a += i sys.stdout.write(("%i" % a) * 40) assert_performance(130, 'tqdm', time_tqdm(), 'range', time_bench()) @retry_on_except(10) def test_iter_overhead_simplebar_hard(): """Test overhead of iteration based tqdm vs simple progress bar (hard)""" total = int(1e4) a = 0 with trange(total, leave=True, miniters=1, mininterval=0, maxinterval=0) as t: with relative_timer() as time_tqdm: for i in t: a += i assert a == (total ** 2 - total) / 2.0 a = 0 s = simple_progress(range(total), leave=True, miniters=1, mininterval=0) with relative_timer() as time_bench: for i in s: a += i assert_performance(10, 'trange', time_tqdm(), 'simple_progress', time_bench()) @retry_on_except(10) def test_manual_overhead_simplebar_hard(): """Test overhead of manual tqdm vs simple progress bar (hard)""" total = int(1e4) with tqdm(total=total * 10, leave=True, miniters=1, mininterval=0, maxinterval=0) as t: a = 0 with relative_timer() as time_tqdm: for i in range(total): a += i t.update(10) simplebar_update = simple_progress(total=total * 10, leave=True, miniters=1, mininterval=0) a = 0 with relative_timer() as time_bench: for i in range(total): a += i simplebar_update(10) assert_performance(10, 'tqdm', time_tqdm(), 'simple_progress', time_bench())