""" Benching joblib pickle I/O. Warning: this is slow, and the benches are easily offset by other disk activity. """ import os import time import shutil import numpy as np import joblib import gc from joblib.disk import disk_used try: from memory_profiler import memory_usage except ImportError: memory_usage = None def clear_out(): """Clear output directory.""" if os.path.exists('out'): shutil.rmtree('out') os.mkdir('out') def kill_disk_cache(): """Clear disk cache to avoid side effects.""" if os.name == 'posix' and os.uname()[0] == 'Linux': try: os.system('sudo sh -c "sync; echo 3 > /proc/sys/vm/drop_caches"') except IOError as e: if e.errno == 13: print('Please run me as root') else: raise else: # Write ~100M to the disk open('tmp', 'wb').write(np.random.random(2e7)) def delete_obj(obj): """Force destruction of an object.""" if obj is not None: del obj gc.collect() def memory_used(func, *args, **kwargs): """Compute memory usage of func.""" if memory_usage is None: return np.nan gc.collect() mem_use = memory_usage((func, args, kwargs), interval=.001) return max(mem_use) - min(mem_use) def timeit(func, *args, **kwargs): """Compute the mean execution time of func based on 7 measures.""" times = [] tries = kwargs['tries'] kwargs.pop('tries') if tries > 1: tries += 2 for _ in range(tries): kill_disk_cache() t0 = time.time() out = func(*args, **kwargs) if 1: # Just time the function t1 = time.time() times.append(t1 - t0) else: # Compute a hash of the output, to estimate the time # necessary to access the elements: this is a better # estimate of the time to load with me mmapping. joblib.hash(out) t1 = time.time() joblib.hash(out) t2 = time.time() times.append(t2 - t0 - 2 * (t2 - t1)) times.sort() return np.mean(times[1:-1]) if tries > 1 else t1 - t0, out def generate_rand_dict(size, with_arrays=False, with_string=False, array_shape=(10, 10)): """Generate dictionary with random values from list of keys.""" ret = {} rnd = np.random.RandomState(0) randoms = rnd.random_sample((size)) for key, random in zip(range(size), randoms): if with_arrays: ret[str(key)] = rnd.random_sample(array_shape) elif with_string: ret[str(key)] = str(random) else: ret[str(key)] = int(random) return ret def generate_rand_list(size, with_arrays=False, with_string=False, array_shape=(10, 10)): """Generate list with random values from list of keys.""" ret = [] rnd = np.random.RandomState(0) for random in rnd.random_sample((size)): if with_arrays: ret.append(rnd.random_sample(array_shape)) elif with_string: ret.append(str(random)) else: ret.append(int(random)) return ret def print_line(dataset, strategy, write_time, read_time, mem_write, mem_read, disk_used): """Nice printing function.""" print('% 15s, %12s, % 6.3f, % 7.4f, % 9.1f, % 9.1f, % 5.1f' % ( dataset, strategy, write_time, read_time, mem_write, mem_read, disk_used)) def print_bench_summary(args): """Nice bench summary function.""" summary = """Benchmark summary: - Global values: . Joblib version: {} . Number of tries to compute mean execution time: {} . Compression levels : {} . Compression algorithm: {} . Memory map mode : {} . Bench nifti data : {} . Bench big array : {} . Bench 2 big arrays : {} . Bench big dictionary: {} . Bench array+dict : {} """.format(joblib.__version__, args.tries, ", ".join(map(str, args.compress)), "None" if not args.compress else args.compressor, args.mmap, args.nifti, args.array, args.arrays, args.dict, args.combo) if args.array: shape = tuple(args.shape) size = round(np.multiply.reduce(shape) * 8 / 1024 ** 2, 1) summary += """ - Big array: . shape: {} . size in memory: {} MB """.format(str(shape), size) if args.dict: summary += """ - Big dictionary: . number of keys: {} . value type: {} """.format(args.size, 'np.ndarray' if args.valuearray else 'str' if args.valuestring else 'int') if args.valuearray: summary += """ . arrays shape: {} """.format(str(tuple(args.valuearrayshape))) if args.list: summary += """ - Big list: . number of elements: {} . value type: {} """.format(args.size, 'np.ndarray' if args.valuearray else 'str' if args.valuestring else 'int') if args.valuearray: summary += """ . arrays shape: {} """.format(str(tuple(args.valuearrayshape))) print(summary) def bench_compress(dataset, name='', compress=('zlib', 0), cache_size=0, tries=5): """Bench joblib dump and load functions, compress modes.""" # generate output compression strategy string before joblib compatibility # check as it may override the compress variable with a non tuple type. compress_str = "Raw" if compress[1] == 0 else "{} {}".format(*compress) # joblib versions prior to 0.10 doesn't support tuple in compress argument # so only the second element of the tuple is used for those versions # and the compression strategy is ignored. if (isinstance(compress, tuple) and tuple(map(int, joblib.__version__.split('.')[:2])) < (0, 10)): compress = compress[1] time_write = time_read = du = mem_read = mem_write = [] clear_out() time_write, obj = timeit(joblib.dump, dataset, 'out/test.pkl', tries=tries, compress=compress, cache_size=cache_size) del obj gc.collect() mem_write = memory_used(joblib.dump, dataset, 'out/test.pkl', compress=compress, cache_size=cache_size) delete_obj(dataset) du = disk_used('out') / 1024. time_read, obj = timeit(joblib.load, 'out/test.pkl', tries=tries) delete_obj(obj) mem_read = memory_used(joblib.load, 'out/test.pkl') print_line(name, compress_str, time_write, time_read, mem_write, mem_read, du) def bench_mmap(dataset, name='', cache_size=0, mmap_mode='r', tries=5): """Bench joblib dump and load functions, memmap modes.""" time_write = time_read = du = [] clear_out() time_write, _ = timeit(joblib.dump, dataset, 'out/test.pkl', tries=tries, cache_size=cache_size) mem_write = memory_used(joblib.dump, dataset, 'out/test.pkl', cache_size=cache_size) delete_obj(dataset) time_read, obj = timeit(joblib.load, 'out/test.pkl', tries=tries, mmap_mode=mmap_mode) delete_obj(obj) mem_read = memory_used(joblib.load, 'out/test.pkl', mmap_mode=mmap_mode) du = disk_used('out') / 1024. print_line(name, 'mmap %s' % mmap_mode, time_write, time_read, mem_write, mem_read, du) def run_bench(func, obj, name, **kwargs): """Run the benchmark function.""" func(obj, name, **kwargs) def run(args): """Run the full bench suite.""" if args.summary: print_bench_summary(args) if (not args.nifti and not args.array and not args.arrays and not args.dict and not args.list and not args.combo): print("Nothing to bench. Exiting") return compress_levels = args.compress compress_method = args.compressor mmap_mode = args.mmap container_size = args.size a1_shape = tuple(args.shape) a2_shape = (10000000, ) print('% 15s, %12s, % 6s, % 7s, % 9s, % 9s, % 5s' % ( 'Dataset', 'strategy', 'write', 'read', 'mem_write', 'mem_read', 'disk')) if args.nifti: # Nifti images try: import nibabel except ImportError: print("nibabel is not installed skipping nifti file benchmark.") else: def load_nii(filename): img = nibabel.load(filename) return img.get_data(), img.get_affine() for name, nifti_file in ( ('MNI', '/usr/share/fsl/data/atlases' '/MNI/MNI-prob-1mm.nii.gz'), ('Juelich', '/usr/share/fsl/data/atlases' '/Juelich/Juelich-prob-2mm.nii.gz'), ): for c_order in (True, False): name_d = '% 5s(%s)' % (name, 'C' if c_order else 'F') for compress_level in compress_levels: d = load_nii(nifti_file) if c_order: d = (np.ascontiguousarray(d[0]), d[1]) run_bench(bench_compress, d, name_d, compress=(compress_method, compress_level), tries=args.tries) del d if not args.nommap: d = load_nii(nifti_file) if c_order: d = (np.ascontiguousarray(d[0]), d[1]) run_bench(bench_mmap, d, name_d, mmap_mode=mmap_mode, tries=args.tries) del d # Generate random seed rnd = np.random.RandomState(0) if args.array: # numpy array name = '% 5s' % 'Big array' for compress_level in compress_levels: a1 = rnd.random_sample(a1_shape) run_bench(bench_compress, a1, name, compress=(compress_method, compress_level), tries=args.tries) del a1 if not args.nommap: a1 = rnd.random_sample(a1_shape) run_bench(bench_mmap, a1, name, mmap_mode=mmap_mode, tries=args.tries) del a1 if args.arrays: # Complex object with 2 big arrays name = '% 5s' % '2 big arrays' for compress_level in compress_levels: obj = [rnd.random_sample(a1_shape), rnd.random_sample(a2_shape)] run_bench(bench_compress, obj, name, compress=(compress_method, compress_level), tries=args.tries) del obj if not args.nommap: obj = [rnd.random_sample(a1_shape), rnd.random_sample(a2_shape)] run_bench(bench_mmap, obj, name, mmap_mode=mmap_mode, tries=args.tries) del obj if args.dict: # Big dictionary name = '% 5s' % 'Big dict' array_shape = tuple(args.valuearrayshape) for compress_level in compress_levels: big_dict = generate_rand_dict(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape) run_bench(bench_compress, big_dict, name, compress=(compress_method, compress_level), tries=args.tries) del big_dict if not args.nommap: big_dict = generate_rand_dict(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape) run_bench(bench_mmap, big_dict, name, mmap_mode=mmap_mode, tries=args.tries) del big_dict if args.list: # Big dictionary name = '% 5s' % 'Big list' array_shape = tuple(args.valuearrayshape) for compress_level in compress_levels: big_list = generate_rand_list(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape) run_bench(bench_compress, big_list, name, compress=(compress_method, compress_level), tries=args.tries) del big_list if not args.nommap: big_list = generate_rand_list(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape) run_bench(bench_mmap, big_list, name, mmap_mode=mmap_mode, tries=args.tries) del big_list if args.combo: # 2 big arrays with one big dict name = '% 5s' % 'Dict/arrays' array_shape = tuple(args.valuearrayshape) for compress_level in compress_levels: obj = [rnd.random_sample(a1_shape), generate_rand_dict(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape), rnd.random_sample(a2_shape)] run_bench(bench_compress, obj, name, compress=(compress_method, compress_level), tries=args.tries) del obj if not args.nommap: obj = [rnd.random_sample(a1_shape), generate_rand_dict(container_size, with_arrays=args.valuearray, with_string=args.valuestring, array_shape=array_shape), rnd.random_sample(a2_shape)] run_bench(bench_mmap, obj, name, mmap_mode=mmap_mode, tries=args.tries) del obj if __name__ == "__main__": import argparse parser = argparse.ArgumentParser(description="Joblib benchmark script") parser.add_argument('--compress', nargs='+', type=int, default=(0, 3), help="List of compress levels.") parser.add_argument('--compressor', type=str, default='zlib', choices=['zlib', 'gzip', 'bz2', 'xz', 'lzma'], help="Compression algorithm.") parser.add_argument('--mmap', type=str, default='r', choices=['r', 'r+', 'w+'], help="Memory map mode.") parser.add_argument('--tries', type=int, default=5, help="Number of tries to compute execution time" "mean on.") parser.add_argument('--shape', nargs='+', type=int, default=(10000, 10000), help="Big array shape.") parser.add_argument("-m", "--nommap", action="store_true", help="Don't bench memmap") parser.add_argument('--size', type=int, default=10000, help="Big dictionary size.") parser.add_argument('--valuearray', action="store_true", help="Use numpy arrays type in containers " "(list, dict)") parser.add_argument('--valuearrayshape', nargs='+', type=int, default=(10, 10), help="Shape of arrays in big containers.") parser.add_argument('--valuestring', action="store_true", help="Use string type in containers (list, dict).") parser.add_argument("-n", "--nifti", action="store_true", help="Benchmark Nifti data") parser.add_argument("-a", "--array", action="store_true", help="Benchmark single big numpy array") parser.add_argument("-A", "--arrays", action="store_true", help="Benchmark list of big numpy arrays") parser.add_argument("-d", "--dict", action="store_true", help="Benchmark big dictionary.") parser.add_argument("-l", "--list", action="store_true", help="Benchmark big list.") parser.add_argument("-c", "--combo", action="store_true", help="Benchmark big dictionary + list of " "big numpy arrays.") parser.add_argument("-s", "--summary", action="store_true", help="Show bench summary.") run(parser.parse_args())