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test_dataloader.py
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test_dataloader.py
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# Owner(s): ["module: dataloader"]
import math
import sys
import errno
import os
import ctypes
import faulthandler
import torch
import gc
import time
import signal
import unittest
import itertools
import warnings
import tempfile
import torch.utils.data.datapipes as dp
from torch import multiprocessing as mp
from torch.utils.data import (
ChainDataset,
ConcatDataset,
DataLoader,
Dataset,
IterableDataset,
IterDataPipe,
Subset,
TensorDataset,
_utils
)
from torch.utils.data._utils import MP_STATUS_CHECK_INTERVAL
from torch.utils.data.dataset import random_split
from torch.utils.data.datapipes.iter import IterableWrapper
from torch._utils import ExceptionWrapper
from torch.testing._internal.common_utils import (TestCase, run_tests, TEST_NUMPY, IS_WINDOWS,
IS_CI, NO_MULTIPROCESSING_SPAWN, skipIfRocm, slowTest,
load_tests, TEST_WITH_ASAN, TEST_WITH_TSAN, IS_SANDCASTLE,
IS_MACOS)
try:
import psutil
HAS_PSUTIL = True
except ImportError:
HAS_PSUTIL = False
err_msg = ("psutil not found. Some critical data loader tests relying on it "
"(e.g., TestDataLoader.test_proper_exit) will not run.")
if IS_CI:
raise ImportError(err_msg) from None
else:
warnings.warn(err_msg)
try:
import dill
# XXX: By default, dill writes the Pickler dispatch table to inject its
# own logic there. This globally affects the behavior of the standard library
# pickler for any user who transitively depends on this module!
# Undo this extension to avoid altering the behavior of the pickler globally.
dill.extend(use_dill=False)
HAS_DILL = True
except ImportError:
HAS_DILL = False
skipIfNoDill = unittest.skipIf(not HAS_DILL, "no dill")
try:
import numpy as np
HAS_NUMPY = True
except ImportError:
HAS_NUMPY = False
skipIfNoNumpy = unittest.skipIf(not HAS_NUMPY, "no NumPy")
# load_tests from torch.testing._internal.common_utils is used to automatically filter tests for
# sharding on sandcastle. This line silences flake warnings
load_tests = load_tests
# We cannot import TEST_CUDA from torch.testing._internal.common_cuda here, because if we do that,
# the TEST_CUDNN line from torch.testing._internal.common_cuda will be executed multiple times
# as well during the execution of this test suite, and it will cause
# CUDA OOM error on Windows.
TEST_CUDA = torch.cuda.is_available()
if TEST_CUDA:
dev_name = torch.cuda.get_device_name(torch.cuda.current_device()).lower()
IS_JETSON = 'xavier' in dev_name or 'nano' in dev_name or 'jetson' in dev_name or 'tegra' in dev_name
else:
IS_JETSON = False
if not NO_MULTIPROCESSING_SPAWN:
# We want to use `spawn` if able because some of our tests check that the
# data loader terminiates gracefully. To prevent hanging in the testing
# process, such data loaders are run in a separate subprocess.
#
# We also want to test the `pin_memory=True` configuration, thus `spawn` is
# required to launch such processes and they initialize the CUDA context.
#
# Mixing different start method is a recipe for disaster (e.g., using a fork
# `mp.Event` with a spawn `mp.Process` segfaults). So we set this globally
# to avoid bugs.
#
# Get a multiprocessing context because some test / third party library will
# set start_method when imported, and setting again triggers `RuntimeError`.
mp = mp.get_context(method='spawn')
# 60s of timeout?
# Yes, in environments where physical CPU resources are shared, e.g., CI, the
# time for a inter-process communication can be highly varying. With 15~17s of
# timeout, we have observed flakiness in some CI builds (see
# pytorch/pytorch#14501, pytorch/pytorch#16608). We follow the CPython
# multiprocessing setup and set the timeout to 60s here:
#
# https://github.com/python/cpython/blob/e8113f51a8bdf33188ee30a1c038a298329e7bfa/Lib/test/_test_multiprocessing.py#L73
JOIN_TIMEOUT = 60.0 # seconds
supported_multiprocessing_contexts = [None] + list(torch.multiprocessing.get_all_start_methods())
@unittest.skipIf(
TEST_WITH_TSAN,
"Fails with TSAN with the following error: starting new threads after multi-threaded "
"fork is not supported. Dying (set die_after_fork=0 to override)")
class TestDatasetRandomSplit(TestCase):
def test_lengths_must_equal_dataset_size(self):
with self.assertRaises(ValueError):
random_split([1, 2, 3, 4], [1, 2])
def test_splits_have_correct_size(self):
splits = random_split([1, 2, 3, 4, 5, 6], [2, 4])
self.assertEqual(len(splits), 2)
self.assertEqual(len(splits[0]), 2)
self.assertEqual(len(splits[1]), 4)
splits = random_split([1, 2, 3, 4, 5, 6], [0.5, 0.5])
self.assertEqual(len(splits), 2)
self.assertEqual(len(splits[0]), 3)
self.assertEqual(len(splits[1]), 3)
# Odd size splits
self.assertEqual(
len(random_split(range(3), [0.5, 0.5], generator=torch.Generator().manual_seed(1))),
2
)
# Odd sized round-robin splits
splits = random_split(range(106), [0.1, 0.2, 0.3, 0.4],
generator=torch.Generator().manual_seed(1))
self.assertEqual(len(splits[0]), 11)
self.assertEqual(len(splits[1]), 22)
self.assertEqual(len(splits[2]), 31)
self.assertEqual(len(splits[3]), 42)
def test_splits_are_mutually_exclusive(self):
data = [5, 2, 3, 4, 1, 6]
splits = random_split(data, [2, 4])
all_values = []
all_values.extend(list(splits[0]))
all_values.extend(list(splits[1]))
data.sort()
all_values.sort()
self.assertListEqual(data, all_values)
splits = random_split(data, [0.33, 0.67])
all_values = []
all_values.extend(list(splits[0]))
all_values.extend(list(splits[1]))
data.sort()
all_values.sort()
self.assertListEqual(data, all_values)
data = [1, 2, 3, 4]
splits = random_split(data, [0.25, 0.75])
all_values = []
all_values.extend(list(splits[0]))
all_values.extend(list(splits[1]))
data.sort()
all_values.sort()
self.assertListEqual(data, all_values)
def test_splits_indexing_type(self):
r"""Indices generated by random_split
should be of integer type
"""
class CustomDataset():
def __init__(self, test_object, custom_list):
self.data = custom_list
self.test_object = test_object
def __getitem__(self, key):
self.test_object.assertEqual(type(key), type(0))
return self.data[key]
def __len__(self):
return len(self.data)
x = [1, 2, 3, 4, 5]
dataset = CustomDataset(self, x)
dataset = random_split(dataset, [5])[0]
data_loader = DataLoader(dataset)
for batch in data_loader:
pass
# fractional splitting
dataset = CustomDataset(self, x)
dataset = random_split(dataset, [1.0])[0]
data_loader = DataLoader(dataset)
for batch in data_loader:
pass
def test_splits_reproducibility(self):
self.assertEqual(
[list(x) for x in random_split(range(10), [3, 7], generator=torch.Generator().manual_seed(1))],
[[5, 6, 1], [2, 0, 8, 9, 3, 7, 4]],
)
self.assertEqual(
random_split(range(100), [60, 40], generator=torch.Generator().manual_seed(42)),
random_split(range(100), [60, 40], generator=torch.Generator().manual_seed(42)),
)
self.assertEqual(
random_split(range(100), [0.5, 0.5], generator=torch.Generator().manual_seed(42)),
random_split(range(100), [0.5, 0.5], generator=torch.Generator().manual_seed(42)),
)
self.assertEqual(
random_split(range(100), [0.33, 0.33, 0.34], generator=torch.Generator().manual_seed(42)),
random_split(range(100), [0.33, 0.33, 0.34], generator=torch.Generator().manual_seed(42)),
)
def test_incomplete_fractional_splits(self):
with self.assertRaises(ValueError):
# should raise since the sum of fractions is not 1
random_split([1, 2, 3, 4], [0.1])
with self.assertRaises(ValueError):
# should raise since fraction > 1
random_split([1, 2, 3, 4], [1.1])
def test_splits_generator(self):
# A random_split without a specific generator should affect the default one
state = torch.get_rng_state()
a = torch.rand(10)
torch.set_rng_state(state)
random_split(range(10), [5, 5])
b = torch.rand(10)
self.assertNotEqual(a, b)
# A random_split with a specific generator should not affect the default one
state = torch.get_rng_state()
a = torch.rand(10)
torch.set_rng_state(state)
random_split(range(10), [5, 5], generator=torch.Generator().manual_seed(42))
b = torch.rand(10)
self.assertEqual(a, b)
def test_slicing_of_subset_of_dataset(self):
# Testing slicing a subset initialized with a dataset
dataset = TensorDataset(torch.tensor([1, 2, 3, 4, 5]))
subset_of_dataset = Subset(dataset, [0, 1, 2, 3, 4])
self.assertEqual(subset_of_dataset[:], dataset[:])
self.assertEqual(subset_of_dataset[1:2], dataset[1:2])
self.assertEqual(subset_of_dataset[0:-1:2], dataset[0:-1:2])
# Testing slicing of subset from random split
subset1, subset2 = random_split(dataset, [3, 2])
self.assertEqual(subset1[:], dataset[subset1.indices[:]])
self.assertEqual(subset1[0:2], dataset[subset1.indices[0:2]])
self.assertEqual(subset1[0:-1:2], dataset[subset1.indices[0:-1:2]])
def test_slicing_of_subset_of_subset(self):
# Testing slicing a subset initialized with a subset
dataset = TensorDataset(torch.tensor([1, 2, 3, 4, 5]))
subset_of_dataset = Subset(dataset, [0, 1, 2, 3, 4])
subset_of_subset = Subset(subset_of_dataset, [0, 1, 2, 3, 4])
self.assertEqual(subset_of_subset[:], dataset[:])
self.assertEqual(subset_of_subset[0:2], dataset[0:2])
self.assertEqual(subset_of_subset[0:-1:2], dataset[0:-1:2])
# Testing slicing of subset of subset from random split
subset1, subset2 = random_split(dataset, [4, 1])
subset_of_subset1, subset_of_subset2 = random_split(subset1, [3, 1])
idx = [subset1.indices[i] for i in subset_of_subset1.indices]
self.assertEqual(subset_of_subset1[:], dataset[idx[:]])
self.assertEqual(subset_of_subset1[0:2], dataset[idx[0:2]])
self.assertEqual(subset_of_subset1[0:-1:2], dataset[idx[0:-1:2]])
class CUDACountingDataset(Dataset):
def __init__(self, n):
super(CUDACountingDataset, self).__init__()
self.n = n
def __getitem__(self, i):
return torch.as_tensor(i, device='cuda')
def __len__(self):
return self.n
class CountingDataset(Dataset):
def __init__(self, n):
super(CountingDataset, self).__init__()
self.n = n
def __getitem__(self, i):
return i
def __len__(self):
return self.n
class CountingIterableDataset(IterableDataset):
def __init__(self, n):
super(CountingIterableDataset, self).__init__()
self.n = n
def __iter__(self):
return iter(range(self.n))
def __len__(self):
return self.n
@unittest.skipIf(
TEST_WITH_TSAN,
"Fails with TSAN with the following error: starting new threads after multi-threaded "
"fork is not supported. Dying (set die_after_fork=0 to override)")
class TestTensorDataset(TestCase):
def test_len(self):
source = TensorDataset(torch.randn(15, 10, 2, 3, 4, 5), torch.randperm(15))
self.assertEqual(len(source), 15)
def test_getitem(self):
t = torch.randn(15, 10, 2, 3, 4, 5)
l = torch.randn(15, 10)
source = TensorDataset(t, l)
for i in range(15):
self.assertEqual(t[i], source[i][0])
self.assertEqual(l[i], source[i][1])
def test_getitem_1d(self):
t = torch.randn(15)
l = torch.randn(15)
source = TensorDataset(t, l)
for i in range(15):
self.assertEqual(t[i], source[i][0])
self.assertEqual(l[i], source[i][1])
def test_single_tensor(self):
t = torch.randn(5, 10)
source = TensorDataset(t)
self.assertEqual(len(source), 5)
for i in range(5):
self.assertEqual(t[i], source[i][0])
def test_many_tensors(self):
t0 = torch.randn(5, 10, 2, 3, 4, 5)
t1 = torch.randn(5, 10)
t2 = torch.randn(5, 10, 2, 5)
t3 = torch.randn(5, 10, 3, 7)
source = TensorDataset(t0, t1, t2, t3)
self.assertEqual(len(source), 5)
for i in range(5):
self.assertEqual(t0[i], source[i][0])
self.assertEqual(t1[i], source[i][1])
self.assertEqual(t2[i], source[i][2])
self.assertEqual(t3[i], source[i][3])
@unittest.skipIf(
TEST_WITH_TSAN,
"Fails with TSAN with the following error: starting new threads after multi-threaded "
"fork is not supported. Dying (set die_after_fork=0 to override)")
class TestConcatDataset(TestCase):
def test_concat_two_singletons(self):
result = ConcatDataset([[0], [1]])
self.assertEqual(2, len(result))
self.assertEqual(0, result[0])
self.assertEqual(1, result[1])
def test_concat_two_non_singletons(self):
result = ConcatDataset([[0, 1, 2, 3, 4],
[5, 6, 7, 8, 9]])
self.assertEqual(10, len(result))
self.assertEqual(0, result[0])
self.assertEqual(5, result[5])
def test_concat_two_non_singletons_with_empty(self):
# Adding an empty dataset somewhere is correctly handled
result = ConcatDataset([[0, 1, 2, 3, 4],
[],
[5, 6, 7, 8, 9]])
self.assertEqual(10, len(result))
self.assertEqual(0, result[0])
self.assertEqual(5, result[5])
def test_concat_raises_index_error(self):
result = ConcatDataset([[0, 1, 2, 3, 4],
[5, 6, 7, 8, 9]])
with self.assertRaises(IndexError):
# this one goes to 11
result[11]
def test_add_dataset(self):
d1 = TensorDataset(torch.rand(7, 3, 28, 28), torch.rand(7))
d2 = TensorDataset(torch.rand(7, 3, 28, 28), torch.rand(7))
d3 = TensorDataset(torch.rand(7, 3, 28, 28), torch.rand(7))
result = d1 + d2 + d3
self.assertEqual(21, len(result))
self.assertEqual(0, (d1[0][0] - result[0][0]).abs().sum())
self.assertEqual(0, (d2[0][0] - result[7][0]).abs().sum())
self.assertEqual(0, (d3[0][0] - result[14][0]).abs().sum())
def test_iterable_dataset_err(self):
d1 = TensorDataset(torch.rand(7, 3, 28, 28), torch.rand(7))
it1 = CountingIterableDataset(5)
it2 = CountingIterableDataset(10)
with self.assertRaisesRegex(AssertionError, "does not support IterableDataset"):
ConcatDataset([d1, it2, it1])
with self.assertRaisesRegex(AssertionError, "does not support IterableDataset"):
ConcatDataset([it2])
with self.assertRaisesRegex(AssertionError, "does not support IterableDataset"):
ConcatDataset([it1, d1])
# takes in dummy var so this can also be used as a `worker_init_fn`
def set_faulthander_if_available(_=None):
faulthandler.enable(sys.__stderr__)
if not IS_WINDOWS:
# windows does not have faulthandler.register
# chain=False prevents the default behavior of killing the process
faulthandler.register(signal.SIGUSR1, file=sys.__stderr__, chain=False)
set_faulthander_if_available()
# Process `pid` must have called `set_faulthander_if_available`
def print_traces_of_all_threads(pid):
if not IS_WINDOWS:
# use the custom signal if available
os.kill(pid, signal.SIGUSR1)
else:
# otherwise we can still use the handler given by faulthandler.enable()
# at the cost of killing the process.
os.kill(pid, signal.SIGSEGV)
# wait in parent process to give subprocess some time to print
time.sleep(5)
# The following `ErrorTrackingProcess` stores the first encountered exception in
# its `.exception` attribute.
# Inspired by https://stackoverflow.com/a/33599967
class ErrorTrackingProcess(mp.Process):
# Why no *args?
# py2 doesn't support def fn(x, *args, key=val, **kwargs)
# Setting disable_stderr=True may generate a lot of unrelated error outputs
# but could be helpful for debugging.
def __init__(self, disable_stderr=True, **kwargs):
super(ErrorTrackingProcess, self).__init__(**kwargs)
self._pconn, self._cconn = mp.Pipe()
self._exception = None
self.disable_stderr = disable_stderr
def run(self):
set_faulthander_if_available()
if self.disable_stderr:
# Disable polluting stderr with errors that are supposed to happen.
with open(os.devnull, 'w') as devnull:
os.dup2(devnull.fileno(), sys.stderr.fileno())
try:
super(ErrorTrackingProcess, self).run()
self._cconn.send(None)
except Exception:
self._cconn.send(ExceptionWrapper(sys.exc_info()))
raise
def print_traces_of_all_threads(self):
assert self.is_alive(), "can only use print_traces_of_all_threads if the process is alive"
assert not self.disable_stderr, "do not disable stderr if you use print_traces_of_all_threads"
# On platforms without `SIGUSR1`, `set_faulthander_if_available` sets
# `faulthandler.enable()`, and `print_traces_of_all_threads` may kill
# the process. So let's poll the exception first
_ = self.exception
print_traces_of_all_threads(self.pid)
@property
def exception(self):
if self._pconn.poll():
self._exception = self._pconn.recv()
if self._exception is None:
return None
else:
return self._exception.exc_type(self._exception.exc_msg)
# ESRCH means that os.kill can't finds alive proc
def send_signal(self, signum, ignore_ESRCH=False):
try:
os.kill(self.pid, signum)
except OSError as e:
if not ignore_ESRCH or e.errno != errno.ESRCH:
raise
class ErrorDataset(Dataset):
def __init__(self, size):
self.size = size
def __len__(self):
return self.size
class SegfaultDataset(Dataset):
def __init__(self, size):
self.size = size
def __getitem__(self, idx):
return ctypes.string_at(0)
def __len__(self):
return self.size
class SleepDataset(Dataset):
def __init__(self, size, sleep_sec):
self.size = size
self.sleep_sec = sleep_sec
self.sleeped = False
def __getitem__(self, idx):
if not self.sleeped:
time.sleep(self.sleep_sec)
self.sleeped = True
return idx
def __len__(self):
return self.size
class SeedDataset(Dataset):
def __init__(self, size):
self.size = size
def __getitem__(self, idx):
return torch.initial_seed()
def __len__(self):
return self.size
class WorkerSpecificIterableDataset(IterableDataset):
def __init__(self, sizes_for_all_workers):
self.sizes_for_all_workers = sizes_for_all_workers
def __iter__(self):
worker_info = torch.utils.data.get_worker_info()
assert worker_info is not None
return iter(range(self.sizes_for_all_workers[worker_info.id]))
def __len__(self):
return sum(self.sizes_for_all_workers)
# Inspired by https://stackoverflow.com/a/26703365
# If all workers will call `sync_once`, they will be blocked until all workers
# reach the call (i.e., acting like a barrier).
# This can be used to ensure that each worker at least processes one data.
class SynchronizedDataset(Dataset):
def __init__(self, size, batch_size, num_workers):
assert size >= num_workers * batch_size
self.count = mp.Value('i', 0, lock=True)
self.barrier = mp.Semaphore(0)
self.num_workers = num_workers
self.size = size
def sync_once(self):
with self.count.get_lock():
self.count.value += 1
if self.count.value == self.num_workers:
self.barrier.release()
self.barrier.acquire()
self.barrier.release()
def __getitem__(self, idx):
raise NotImplementedError
def __len__(self):
return self.size
class EmptyTensorDataset(torch.utils.data.Dataset):
def __init__(self, len):
self.len = len
def __len__(self):
return self.len
def __getitem__(self, any):
return torch.empty(0)
class SynchronizedSeedDataset(SynchronizedDataset):
def __getitem__(self, idx):
self.sync_once()
return torch.initial_seed()
def _test_timeout(persistent_workers):
dataset = SleepDataset(10, 3)
dataloader = DataLoader(dataset, batch_size=2, num_workers=2, timeout=1,
persistent_workers=persistent_workers)
_ = next(iter(dataloader))
def _test_timeout_pin_memory(persistent_workers):
dataset = SleepDataset(10, 3)
dataloader = DataLoader(dataset, batch_size=2, num_workers=2, timeout=1, pin_memory=True,
persistent_workers=persistent_workers)
_ = next(iter(dataloader))
def _test_large_sampler_indices(persistent_workers):
# See
# test_large_sampler_indices
# https://github.com/pytorch/pytorch/issues/48666
dataloader = torch.utils.data.DataLoader(
EmptyTensorDataset(10000000),
batch_size=40960,
persistent_workers=persistent_workers,
num_workers=1)
it = iter(dataloader)
for x in it:
assert x.numel() == 0
raise RuntimeError('My Error')
def disable_stderr(worker_id):
r"""
Avoids printing "ERROR: Unexpected segmentation fault encountered in worker."
from workers. Since worker signal handler prints with low-level write(),
this has to be done on OS level via dup.
This is used as worker_init_fn for test_segfault.
"""
sys.stderr.flush() # flush library buffers that dup2 knows nothing about
# Can't use a with-block because otherwise the fd will be closed when this
# function ends.
with open(os.devnull, 'w') as devnull:
os.dup2(devnull.fileno(), sys.stderr.fileno())
def _test_segfault():
dataset = SegfaultDataset(10)
dataloader = DataLoader(dataset, batch_size=2, num_workers=2, worker_init_fn=disable_stderr)
_ = next(iter(dataloader))
def _test_no_segfault():
dataset = [1, 2, 3]
num_threads = torch.get_num_threads()
if num_threads < 4:
torch.set_num_threads(4)
else:
torch.set_num_threads(num_threads)
mp_ctx = torch.multiprocessing.get_context(method='fork')
dataloader = DataLoader(dataset, num_workers=1, worker_init_fn=disable_stderr,
multiprocessing_context=mp_ctx)
_ = next(iter(dataloader))
class TestProperExitDataset(Dataset):
def __init__(self, size, error_event):
self.size = size
self.error_event = error_event
def __len__(self):
return self.size
def __getitem__(self, idx):
worker_info = torch.utils.data.get_worker_info()
if self.error_event is not None and self.error_event.is_set() and \
worker_info.id == worker_info.num_workers - 1:
# only error in the last worker
raise RuntimeError('Worker error')
return torch.tensor([idx])
class TestProperExitIterableDataset(IterableDataset):
def __init__(self, size, error_event):
self.error_event = error_event
self.size = size
self.remaining = size
def __len__(self):
return self.size
def __iter__(self):
return self
def __next__(self):
worker_info = torch.utils.data.get_worker_info()
if self.error_event is not None and self.error_event.is_set() and \
worker_info.id == worker_info.num_workers - 1:
# only error in the last worker
raise RuntimeError('Worker error')
self.remaining -= 1
if self.remaining < 0:
raise StopIteration
return torch.tensor(-1000)
# See TestDataLoader.test_proper_exit for usage
def _test_proper_exit(is_iterable_dataset, use_workers, pin_memory, exit_method,
hold_iter_reference, loader_setup_event, tester_setup_event,
persistent_workers):
num_workers = 2 if use_workers else 0
if exit_method == 'worker_error' or exit_method == 'worker_kill':
assert use_workers is True
if exit_method == 'worker_error':
worker_error_event = mp.Event()
else:
worker_error_event = None
if is_iterable_dataset:
ds = TestProperExitIterableDataset(7, worker_error_event)
else:
ds = TestProperExitDataset(12, worker_error_event)
loader = DataLoader(ds, batch_size=1, shuffle=False,
num_workers=num_workers, pin_memory=pin_memory,
worker_init_fn=set_faulthander_if_available,
persistent_workers=persistent_workers)
error_it = 2
if use_workers:
# 2 is the magical per-worker prefetch number...
# FIXME: change this after the number becomes configurable.
if is_iterable_dataset:
assert len(ds) * num_workers > (error_it + 2 + 1)
else:
assert len(loader) > (error_it + 2 + 1) * num_workers
else:
if is_iterable_dataset:
assert len(ds) > error_it + 1
else:
assert len(loader) > error_it + 1
it = iter(loader)
if use_workers:
workers = it._workers
def kill_pid(pid):
psutil_p = psutil.Process(pid)
psutil_p.kill()
psutil_p.wait(JOIN_TIMEOUT)
assert not psutil_p.is_running()
for i, _ in enumerate(it):
if i == 0:
if not hold_iter_reference:
del it
del loader
loader_setup_event.set()
tester_setup_event.wait()
# ensure that the workers are still alive
if use_workers:
for w in workers:
assert w.is_alive()
if worker_error_event is not None:
worker_error_event.set()
if i == error_it:
if exit_method == 'loader_error':
raise RuntimeError('Loader error')
elif exit_method == 'loader_kill':
kill_pid(os.getpid())
elif exit_method == 'worker_kill':
kill_pid(workers[-1].pid) # kill last worker
if not hold_iter_reference:
# Tries to trigger the __del__ clean-up rather than the automatic
# exiting of daemonic children. Technically it should be automatically
# triggered, but I don't want to rely on the implementation detail of
# Python gc.
gc.collect()
class TestWorkerInfoDataset(SynchronizedDataset):
def __getitem__(self, idx):
self.sync_once()
return torch.tensor(self.value)
# Should be used as worker_init_fn with TestWorkerInfoDataset.
# See _test_get_worker_info below for usage.
def _test_worker_info_init_fn(worker_id):
worker_info = torch.utils.data.get_worker_info()
assert worker_id == worker_info.id, "worker_init_fn and worker_info should have consistent id"
assert worker_id < worker_info.num_workers, "worker_init_fn and worker_info should have valid id"
assert worker_info.seed == torch.initial_seed(), "worker_init_fn and worker_info should have consistent seed"
dataset = worker_info.dataset
assert isinstance(dataset, TestWorkerInfoDataset), "worker_info should have correct dataset copy"
assert not hasattr(dataset, 'value'), "worker_info should have correct dataset copy"
# test that WorkerInfo attributes are read-only
try:
worker_info.id = 3999
except RuntimeError as e:
assert str(e) == "Cannot assign attributes to WorkerInfo objects"
try:
worker_info.a = 3
except RuntimeError as e:
assert str(e) == "Cannot assign attributes to WorkerInfo objects"
for k in ['id', 'num_workers', 'seed', 'dataset']:
assert "{}=".format(k) in repr(worker_info)
dataset.value = [worker_id, os.getpid()]
def _test_get_worker_info():
# get_worker_info returns None in main proc
assert torch.utils.data.get_worker_info() is None
num_workers = 2
batch_size = 2
dataset = TestWorkerInfoDataset(6, batch_size, num_workers)
dataloader = DataLoader(dataset, batch_size=batch_size,
num_workers=num_workers,
worker_init_fn=_test_worker_info_init_fn)
it = iter(dataloader)
data = []
for d in it:
data.append(d)
worker_pids = [w.pid for w in it._workers]
data = torch.cat(data, 0)
for d in data:
# each `d` is a [worker_id, worker_pid] pair, which is set in
# _test_worker_info_init_fn
assert d[1] == worker_pids[d[0]]
# get_worker_info returns None in main proc after data loading
assert torch.utils.data.get_worker_info() is None
# main proc dataset was never assigned this attribute
assert not hasattr(dataset, 'value')
try:
_ = dataset[0]
except AttributeError:
return
raise RuntimeError('Expected AttributeError')
# test custom init function
def init_fn(worker_id):
torch.manual_seed(12345)
# used with test_error_in_init
class ErrorIterableDataset(IterableDataset):
def __iter__(self):
raise RuntimeError("Error in __iter__")
# used with test_error_in_init
def error_worker_init_fn(_):
raise RuntimeError("Error in worker_init_fn")
class BulkLoadingDataset(Dataset):
def __init__(self, length):
self.length = length
def __getitem__(self, indices):
assert isinstance(indices, (list, tuple))
return torch.as_tensor(indices)
def __len__(self):
return self.length
class BulkLoadingSampler(torch.utils.data.Sampler):
def __init__(self, dataset, batch_size):
self.dataset = dataset
self.batch_size = batch_size
def __iter__(self):
for x in torch.randperm(len(self.dataset)).split(self.batch_size):
yield x.tolist()
def __len__(self):
return int(math.ceil(len(self.dataset) / float(self.batch_size)))
class TestMultiEpochDataset(IterableDataset):
def __init__(self, length):
self.length = length
def __iter__(self):
worker_info = torch.utils.data.get_worker_info()
assert worker_info is not None
worker_id = worker_info.id
for idx in range(self.length // worker_info.num_workers):
yield worker_id
def __len__(self):
return self.length
class CustomList(list):
pass
class CustomDict(dict):
pass
def row_processor(row):
return np.add(row, 1)
def filter_len(row):
return len(row) == 4
@unittest.skipIf(
TEST_WITH_TSAN,
"Fails with TSAN with the following error: starting new threads after multi-threaded "
"fork is not supported. Dying (set die_after_fork=0 to override)")
@unittest.skipIf(
TEST_WITH_ASAN,
"DataLoader tests hang in ASAN, see: https://github.com/pytorch/pytorch/issues/66223")
class TestDataLoader(TestCase):
def setUp(self):
super(TestDataLoader, self).setUp()
self.data = torch.randn(100, 2, 3, 5)
self.labels = torch.randperm(50).repeat(2)
self.dataset = TensorDataset(self.data, self.labels)
self.persistent_workers = False
def _get_data_loader(self, dataset, **kwargs):
persistent_workers = kwargs.get('persistent_workers', self.persistent_workers)
if persistent_workers and kwargs.get('num_workers', 0) == 0:
persistent_workers = False
kwargs['persistent_workers'] = persistent_workers
return DataLoader(dataset, **kwargs)
def _test_sequential(self, loader):
batch_size = loader.batch_size
if batch_size is None:
for idx, (sample, target) in enumerate(loader):
self.assertEqual(sample, self.data[idx])
self.assertEqual(target, self.labels[idx])
self.assertEqual(idx, len(self.dataset) - 1)
else:
for i, (sample, target) in enumerate(loader):
idx = i * batch_size
self.assertEqual(sample, self.data[idx:idx + batch_size])
self.assertEqual(target, self.labels[idx:idx + batch_size])
self.assertEqual(i, math.floor((len(self.dataset) - 1) / batch_size))
def _test_shuffle(self, loader):
found_data = {i: 0 for i in range(self.data.size(0))}
found_labels = {i: 0 for i in range(self.labels.size(0))}
batch_size = loader.batch_size
if batch_size is None:
for i, (batch_samples, batch_targets) in enumerate(loader):
sample, target = (batch_samples, batch_targets)
for data_point_idx, data_point in enumerate(self.data):
if data_point.eq(sample).all():
self.assertFalse(found_data[data_point_idx])
found_data[data_point_idx] += 1
break
self.assertEqual(target, self.labels[data_point_idx])
found_labels[data_point_idx] += 1
self.assertEqual(sum(found_data.values()), (i + 1))
self.assertEqual(sum(found_labels.values()), (i + 1))
self.assertEqual(i, (len(self.dataset) - 1))
else:
for i, (batch_samples, batch_targets) in enumerate(loader):
for sample, target in zip(batch_samples, batch_targets):
for data_point_idx, data_point in enumerate(self.data):
if data_point.eq(sample).all():
self.assertFalse(found_data[data_point_idx])
found_data[data_point_idx] += 1
break
self.assertEqual(target, self.labels[data_point_idx])
found_labels[data_point_idx] += 1
self.assertEqual(sum(found_data.values()), (i + 1) * batch_size)
self.assertEqual(sum(found_labels.values()), (i + 1) * batch_size)
self.assertEqual(i, math.floor((len(self.dataset) - 1) / batch_size))