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571f96bf5983281de8da7ec8fce6a6b37bc0995d
pytorch/test/test_cuda.py
Elias Ellison 571f96bf59 cudagraph trees (#89146) 
CUDA Graph Trees

Design doc: https://docs.google.com/document/d/1ZrxLGWz7T45MSX6gPsL6Ln4t0eZCSfWewtJ_qLd_D0E/edit

Not currently implemented :

- Right now, we are using weak tensor refs from outputs to check if a tensor has dies. This doesn't work because a) aliasing, and b) aot_autograd detaches tensors (see note [Detaching saved tensors in AOTAutograd]). Would need either https://github.com/pytorch/pytorch/issues/91395 to land to use storage weak refs or manually add a deleter fn that does what I want. This is doable but theres some interactions with the caching allocator checkpointing so saving for a stacked pr.

- Reclaiming memory from the inputs during model recording. This isn't terribly difficult but deferring to another PR. You would need to write over the input memory during warmup, and therefore copy the inputs to cpu. Saving for a stacked pr.

- Warning on overwriting previous generation outputs. and handling nested torch.compile() calls in generation tracking

Differential Revision: [D43999887](https://our.internmc.facebook.com/intern/diff/D43999887)

Pull Request resolved: https://github.com/pytorch/pytorch/pull/89146
Approved by: https://github.com/ezyang
2023-03-17 02:47:03 +00:00

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# Owner(s): ["module: cuda"]
from itertools import repeat, chain, product
from typing import NamedTuple
import collections
import contextlib
from copy import deepcopy
import ctypes
import gc
import io
import os
import pickle
import queue
import sys
import tempfile
import threading
import unittest
import warnings
import subprocess
from random import randint
import torch
import torch.cuda
import torch.cuda.comm as comm
from torch.cuda._memory_viz import profile_plot
from torch.cuda._memory_viz import trace_plot
from torch.cuda._memory_viz import segment_plot
from torch import inf, nan
from torch.nn.parallel import scatter_gather
from torch.utils.checkpoint import checkpoint_sequential
from torch.testing._internal.common_utils import TestCase, freeze_rng_state, run_tests, \
NO_MULTIPROCESSING_SPAWN, skipIfRocm, load_tests, IS_REMOTE_GPU, IS_SANDCASTLE, IS_WINDOWS, \
slowTest, skipCUDANonDefaultStreamIf, skipCUDAMemoryLeakCheckIf, TEST_WITH_ROCM, TEST_NUMPY, \
get_cycles_per_ms, parametrize, instantiate_parametrized_tests, subtest, IS_JETSON, gcIfJetson, NoTest, IS_LINUX
from torch.testing._internal.autocast_test_lists import AutocastTestLists
# load_tests from 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 and TEST_MULTIGPU 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()
TEST_MULTIGPU = TEST_CUDA and torch.cuda.device_count() >= 2
if not TEST_CUDA:
print('CUDA not available, skipping tests', file=sys.stderr)
TestCase = NoTest # noqa: F811
try:
import torchvision.models # noqa: F401
from torchvision.models import resnet18 # noqa: F401
HAS_TORCHVISION = True
except ImportError:
HAS_TORCHVISION = False
skipIfNoTorchVision = unittest.skipIf(not HAS_TORCHVISION, "no torchvision")
TEST_CUDAMALLOCASYNC = TEST_CUDA and (torch.cuda.get_allocator_backend() == "cudaMallocAsync")
TEST_LARGE_TENSOR = TEST_CUDA
TEST_MEDIUM_TENSOR = TEST_CUDA
TEST_GRAPH = TEST_CUDA
TEST_CUDNN = TEST_CUDA
TEST_BF16 = False
TEST_PYNVML = not torch.cuda._HAS_PYNVML
if TEST_CUDA:
torch.ones(1).cuda() # initialize cuda context
TEST_CUDNN = TEST_CUDA and (TEST_WITH_ROCM or
torch.backends.cudnn.is_acceptable(torch.tensor(1., device=torch.device('cuda:0'))))
TEST_LARGE_TENSOR = torch.cuda.get_device_properties(0).total_memory >= 12e9
TEST_MEDIUM_TENSOR = torch.cuda.get_device_properties(0).total_memory >= 6e9
TEST_BF16 = torch.cuda.is_bf16_supported()
TEST_GRAPH = (torch.version.cuda and int(torch.version.cuda.split(".")[0]) >= 11) or \
(torch.version.hip and float(".".join(torch.version.hip.split(".")[0:2])) >= 5.3)
_cycles_per_ms = None
class TestCuda(TestCase):
_do_cuda_memory_leak_check = True
_do_cuda_non_default_stream = True
FIFTY_MIL_CYCLES = 50000000
def setUp(self):
super().setUp()
self.autocast_lists = AutocastTestLists(torch.device('cuda:0'))
def tearDown(self):
del self.autocast_lists
super().tearDown()
def _check_memory_stat_consistency(self):
snapshot = torch.cuda.memory_snapshot()
expected_each_device = collections.defaultdict(lambda: collections.defaultdict(int))
for segment in snapshot:
expected = expected_each_device[segment["device"]]
pool_str = segment["segment_type"] + "_pool"
expected["segment.all.current"] += 1
expected["segment." + pool_str + ".current"] += 1
expected["allocated_bytes.all.current"] += segment["allocated_size"]
expected["allocated_bytes." + pool_str + ".current"] += segment["allocated_size"]
expected["reserved_bytes.all.current"] += segment["total_size"]
expected["reserved_bytes." + pool_str + ".current"] += segment["total_size"]
expected["active_bytes.all.current"] += segment["active_size"]
expected["active_bytes." + pool_str + ".current"] += segment["active_size"]
expected["requested_bytes.all.current"] += segment["requested_size"]
expected["requested_bytes." + pool_str + ".current"] += segment["requested_size"]
sum_requested = 0
is_split = len(segment["blocks"]) > 1
for block in segment["blocks"]:
if block["state"] == "active_allocated":
expected["allocation.all.current"] += 1
expected["allocation." + pool_str + ".current"] += 1
if block["state"].startswith("active_"):
sum_requested += block["requested_size"]
expected["active.all.current"] += 1
expected["active." + pool_str + ".current"] += 1
if block["state"] == "inactive" and is_split:
expected["inactive_split.all.current"] += 1
expected["inactive_split." + pool_str + ".current"] += 1
expected["inactive_split_bytes.all.current"] += block["size"]
expected["inactive_split_bytes." + pool_str + ".current"] += block["size"]
self.assertEqual(sum_requested, segment["requested_size"])
for device, expected in expected_each_device.items():
stats = torch.cuda.memory_stats(device)
for k, v in expected.items():
self.assertEqual(v, stats[k])
@staticmethod
def _test_memory_stats_generator(self, device=None, N=35):
if device is None:
device = torch.cuda.current_device()
m0 = torch.cuda.memory_allocated(device)
last_m_arr = [torch.cuda.memory_allocated(device)]
max_m_arr = [torch.cuda.max_memory_allocated(device)]
last_r_arr = [torch.cuda.memory_reserved(device)]
max_r_arr = [torch.cuda.max_memory_reserved(device)]
def alloc(*size):
with torch.cuda.device(device):
# NOTE: do **not** use methods that can have additional
# memory overhead, e.g., inplace random sampling methods.
# they can leave some memory occupied even after being
# deallocated, e.g., initialized RNG state, causing some
# memory checks below to fail.
return torch.cuda.FloatTensor(*size)
def assert_change(comp=1, empty_cache=False, reset_peak=False):
# comp > 0: increased
# comp = 0: equal
# comp < 0: decreased
new_m = torch.cuda.memory_allocated(device)
new_max_m = torch.cuda.max_memory_allocated(device)
if comp > 0:
self.assertGreater(new_m, last_m_arr[0])
elif comp < 0:
self.assertLess(new_m, last_m_arr[0])
else:
self.assertEqual(new_m, last_m_arr[0])
self.assertLessEqual(new_m, new_max_m)
self.assertGreaterEqual(new_max_m, max_m_arr[0])
last_m_arr[0] = new_m
max_m_arr[0] = new_max_m
new_r = torch.cuda.memory_reserved(device)
new_max_r = torch.cuda.max_memory_reserved(device)
# emptying cache may happen (due to allocation or empty_cache), so
# we can't assert new_c >= last_c
self.assertLessEqual(new_r, new_max_r)
self.assertGreaterEqual(new_max_r, max_r_arr[0])
last_r_arr[0] = new_r
max_r_arr[0] = new_max_r
if empty_cache:
torch.cuda.empty_cache()
new_r = torch.cuda.memory_reserved(device)
new_max_r = torch.cuda.max_memory_reserved(device)
self.assertLessEqual(new_r, last_r_arr[0])
self.assertLessEqual(new_r, new_max_r)
self.assertEqual(new_max_r, max_r_arr[0])
last_r_arr[0] = new_r
if reset_peak:
torch.cuda.reset_peak_memory_stats(device)
self.assertEqual(torch.cuda.memory_allocated(device), last_m_arr[0])
self.assertEqual(torch.cuda.max_memory_allocated(device), last_m_arr[0])
max_m_arr[0] = last_m_arr[0]
self.assertEqual(torch.cuda.memory_reserved(device), last_r_arr[0])
self.assertEqual(torch.cuda.max_memory_reserved(device), last_r_arr[0])
max_r_arr[0] = last_r_arr[0]
assert_change(0)
assert_change(0, reset_peak=True)
assert_change(0, empty_cache=True)
assert_change(0, reset_peak=True)
assert_change(0)
yield
tensors1 = [alloc(1), alloc(10, 20), alloc(200, 300, 2000)]
m1 = torch.cuda.memory_allocated(device)
assert_change(1)
yield
tensors2 = []
for i in range(1, int(N / 2) + 1):
# small ones
tensors2.append(alloc(i, i * 4))
assert_change(1)
yield
for i in range(5, int(N / 2) + 5):
# large ones
tensors2.append(alloc(i, i * 7, i * 9, i * 11))
assert_change(1, reset_peak=(i % 2 == 0))
yield
tensors2.append(alloc(0, 0, 0))
assert_change(0)
yield
permute = []
for i in torch.randperm(len(tensors2)):
permute.append(tensors2[i])
assert_change(0)
yield
del tensors2
assert_change(0)
yield
tensors2 = permute
assert_change(0)
yield
del permute
assert_change(0, reset_peak=True)
yield
for i in range(int(N / 2)):
x = tensors2[i].numel()
del tensors2[i]
assert_change(-x) # in case that tensors2[i] is empty
yield
for i in range(2, int(2 * N / 3) + 2):
tensors2.append(alloc(i, i * 3, i * 8))
assert_change(1)
yield
del tensors2
assert_change(-1, reset_peak=True)
assert_change(0)
self.assertEqual(torch.cuda.memory_allocated(device), m1)
yield True
del tensors1
assert_change(-1, reset_peak=True)
self.assertEqual(torch.cuda.memory_allocated(device), m0)
# test empty_cache and reset_peak
assert_change(0, empty_cache=True)
assert_change(0, reset_peak=True)
def test_cudart_register(self):
t = torch.ones(20)
self.assertFalse(t.is_pinned())
cudart = torch.cuda.cudart()
r = cudart.cudaHostRegister(t.data_ptr(), t.numel() * t.element_size(), 0)
self.assertEqual(r, 0)
self.assertTrue(t.is_pinned())
r = cudart.cudaHostUnregister(t.data_ptr())
self.assertEqual(r, 0)
self.assertFalse(t.is_pinned())
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "temporarily disabled")
def test_memory_stats(self):
gc.collect()
torch.cuda.empty_cache()
for _ in self._test_memory_stats_generator(self):
self._check_memory_stat_consistency()
def test_memory_allocation(self):
gc.collect()
torch.cuda.empty_cache()
mem = None
size = 1
prev = 0
try:
prev = torch.cuda.memory_allocated()
mem = torch.cuda.caching_allocator_alloc(size)
self.assertGreater(torch.cuda.memory_allocated(), prev)
finally:
if mem is not None:
torch.cuda.caching_allocator_delete(mem)
self.assertEqual(torch.cuda.memory_allocated(), prev)
def test_check_error(self):
# Assert this call doesn't raise.
torch.cuda.check_error(0)
with self.assertRaisesRegex(torch.cuda.CudaError,
"out of memory|hipErrorOutOfMemory"):
torch.cuda.check_error(2)
def test_cuda_get_device_name(self):
# Testing the behaviour with None as an argument
current_device = torch.cuda.current_device()
current_device_name = torch.cuda.get_device_name(current_device)
device_name_None = torch.cuda.get_device_name(None)
self.assertEqual(current_device_name, device_name_None)
# Testing the behaviour for No argument
device_name_no_argument = torch.cuda.get_device_name()
self.assertEqual(current_device_name, device_name_no_argument)
def test_cuda_get_device_capability(self):
# Testing the behaviour with None as an argument
current_device = torch.cuda.current_device()
current_device_capability = torch.cuda.get_device_capability(current_device)
device_capability_None = torch.cuda.get_device_capability(None)
self.assertEqual(current_device_capability, device_capability_None)
# Testing the behaviour for No argument
device_capability_no_argument = torch.cuda.get_device_capability()
self.assertEqual(current_device_capability, device_capability_no_argument)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "temporarily disabled")
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_memory_stats_multigpu(self):
# advance a generator with a end flag
def advance(gen, end):
if not end:
try:
next(gen)
except StopIteration:
end = True
return end
# interlace
torch.cuda.empty_cache()
gen0 = self._test_memory_stats_generator(self, device='cuda:0', N=35)
gen1 = self._test_memory_stats_generator(self, device=torch.device('cuda:1'), N=35)
end0 = end1 = False
while not (end0 and end1):
end0 = advance(gen0, end0)
end1 = advance(gen1, end1)
# semi-random order
torch.cuda.empty_cache()
gen0 = self._test_memory_stats_generator(self, device=0, N=35)
gen1 = self._test_memory_stats_generator(self, device=torch.device('cuda:1'), N=35)
end0 = end1 = False
while not (end0 and end1):
end0 = advance(gen0, end0)
if not end0:
gen1_max_times = torch.LongTensor(1).random_(0, 3)[0]
else:
gen1_max_times = inf
t = 0
while t < gen1_max_times and not end1:
end1 = advance(gen1, end1)
t += 1
def test_out_of_memory(self):
tensor = torch.zeros(1024, device='cuda')
oom_regex = "would exceed allowed memory" if TEST_CUDAMALLOCASYNC else \
"Tried to allocate 800000000.00 GiB"
with self.assertRaisesRegex(RuntimeError, oom_regex):
torch.empty(1024 * 1024 * 1024 * 800000000, dtype=torch.int8, device='cuda')
with self.assertRaisesRegex(RuntimeError, "Tried to allocate more than 1EB memory"):
torch.empty(1024 * 1024 * 1024 * 8000000000, dtype=torch.int8, device='cuda')
# ensure out of memory error doesn't disturb subsequent kernel
tensor.fill_(1)
self.assertTrue((tensor == 1).all())
@unittest.skipIf(TEST_CUDAMALLOCASYNC or IS_JETSON, "Segmentation fault (core dumped)")
def test_out_of_memory_retry(self):
torch.cuda.empty_cache()
total_memory = torch.cuda.get_device_properties(0).total_memory
oom_regex = "would exceed allowed memory" if TEST_CUDAMALLOCASYNC else \
"Tried to allocate"
size = int(total_memory * 0.5)
a = torch.empty(size , dtype=torch.int8, device='cuda')
with self.assertRaisesRegex(RuntimeError, oom_regex):
b = torch.empty(size, dtype=torch.int8, device='cuda')
del a
b = torch.empty(size, dtype=torch.int8, device='cuda')
del b
# We used a lot of memory here, clean up so we don't affect other tests too much
torch.cuda.empty_cache()
torch.cuda.reset_peak_memory_stats()
def test_set_per_process_memory_fraction(self):
# test invalid fraction value.
with self.assertRaisesRegex(TypeError, "Invalid type"):
torch.cuda.set_per_process_memory_fraction(int(1))
with self.assertRaisesRegex(ValueError, "Invalid fraction value"):
torch.cuda.set_per_process_memory_fraction(-0.1)
with self.assertRaisesRegex(ValueError, "Invalid fraction value"):
torch.cuda.set_per_process_memory_fraction(2.0)
tensor = torch.zeros(1024, device='cuda')
torch.cuda.empty_cache()
total_memory = torch.cuda.get_device_properties(0).total_memory
torch.cuda.set_per_process_memory_fraction(0.5, 0)
# test 0.499 allocation is ok.
application = int(total_memory * 0.499) - torch.cuda.max_memory_reserved()
tmp_tensor = torch.empty(application, dtype=torch.int8, device='cuda')
del tmp_tensor
torch.cuda.empty_cache()
application = int(total_memory * 0.5)
# it will get OOM when try to allocate more than half memory.
oom_regex = "would exceed allowed memory" if TEST_CUDAMALLOCASYNC else \
"out of memory"
with self.assertRaisesRegex(RuntimeError, oom_regex):
torch.empty(application, dtype=torch.int8, device='cuda')
# ensure out of memory error doesn't disturb subsequent kernel
tensor.fill_(1)
self.assertTrue((tensor == 1).all())
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_autogpu(self):
x = torch.randn(5, 5).cuda()
y = torch.randn(5, 5).cuda()
self.assertEqual(x.get_device(), 0)
self.assertEqual(x.get_device(), 0)
with torch.cuda.device(1):
z = torch.randn(5, 5).cuda()
self.assertEqual(z.get_device(), 1)
q = x.add(y)
self.assertEqual(q.get_device(), 0)
w = torch.randn(5, 5).cuda()
self.assertEqual(w.get_device(), 1)
self.assertEqual(y.cuda().get_device(), 1)
z = z.cuda()
self.assertEqual(z.get_device(), 0)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_new(self):
x = torch.randn(3, 3).cuda()
self.assertEqual(x.new([0, 1, 2]).get_device(), 0)
self.assertEqual(x.new([0, 1, 2], device=1).get_device(), 1)
with torch.cuda.device(1):
self.assertEqual(x.new([0, 1, 2]).get_device(), 0)
self.assertEqual(x.new([0, 1, 2], device=1).get_device(), 1)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_copy_device(self):
x = torch.randn(5, 5).cuda()
with torch.cuda.device(1):
y = x.cuda()
self.assertEqual(y.get_device(), 1)
self.assertIs(y.cuda(), y)
z = y.cuda(0)
self.assertEqual(z.get_device(), 0)
self.assertIs(z.cuda(0), z)
x = torch.randn(5, 5)
with torch.cuda.device(1):
y = x.cuda()
self.assertEqual(y.get_device(), 1)
self.assertIs(y.cuda(), y)
z = y.cuda(0)
self.assertEqual(z.get_device(), 0)
self.assertIs(z.cuda(0), z)
def _test_copy_sync_current_stream(self, x, y):
x_plus_one = x + 1
s0 = torch.cuda.Stream(device=x.device)
s1 = torch.cuda.Stream(device=y.device)
s2 = torch.cuda.Stream(device=x.device)
s3 = torch.cuda.Stream(device=y.device)
# same dst stream different src streams
with torch.cuda.stream(s0):
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
with torch.cuda.stream(s1):
y.copy_(x_plus_one)
with torch.cuda.stream(s2), torch.cuda.stream(s1):
y.copy_(x)
s1.synchronize()
# The copy() is synchronized on the current streams of both src and dst.
# In the above test, the _sleep() op on s0 will not block the copy() on
# s2, but both copies are synchronized on s1 in the dst device. Hence,
# x is copied to y after x_plus_one is copied to y. If x and y are on
# the same device, both copy() ops are synchronized on s1.
self.assertEqual(y, x)
# same src stream different dst streams
with torch.cuda.stream(s1):
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
with torch.cuda.stream(s0):
y.copy_(x_plus_one)
with torch.cuda.stream(s3), torch.cuda.stream(s0):
y.copy_(x)
s0.synchronize()
# Similarly, both copy() ops are synchronized on s0.
self.assertEqual(y, x)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_copy_streams(self):
d0 = torch.device('cuda:0')
x0 = torch.zeros(5, 5, device=d0)
d1 = torch.device('cuda:1')
x1 = torch.zeros(5, 5, device=d1)
self._test_copy_sync_current_stream(x0, x1)
x2 = torch.zeros(5, 5, device=d0)
self._test_copy_sync_current_stream(x0, x2)
def test_copy_non_blocking(self):
def _test_copy_non_blocking(a, b):
event = torch.cuda.Event()
a.copy_(b, non_blocking=True)
event.record()
event.synchronize()
self.assertEqual(a, b)
# 10MB copies
x = torch.ones(10000000, dtype=torch.uint8).cuda()
y = torch.zeros(10000000, dtype=torch.uint8).pin_memory()
_test_copy_non_blocking(x, y)
x = torch.zeros(10000000, dtype=torch.uint8).pin_memory()
y = torch.ones(10000000, dtype=torch.uint8).cuda()
_test_copy_non_blocking(x, y)
# Test the case where the pinned data_ptr is not equal to the storage data_ptr.
x_base = torch.zeros(10000000, dtype=torch.uint8).pin_memory()
x = x_base[1:]
self.assertTrue(x.is_pinned())
self.assertTrue(x_base.is_pinned())
self.assertNotEqual(x_base.data_ptr(), x.data_ptr())
self.assertEqual(x_base.storage().data_ptr(), x.storage().data_ptr())
y = torch.ones(10000000 - 1, dtype=torch.uint8).cuda()
_test_copy_non_blocking(x, y)
def test_to_non_blocking(self):
stream = torch.cuda.current_stream()
def _test_to_non_blocking(a, non_blocking, dst):
torch.cuda.synchronize()
# Pushes an 0.1 second spin to stream so if the copy is non blocking,
# stream will almost surely be active when we query().
torch.cuda._sleep(int(100 * get_cycles_per_ms()))
b = a.to(device=dst, non_blocking=non_blocking)
self.assertEqual(stream.query(), not non_blocking)
stream.synchronize()
self.assertEqual(a, b)
self.assertTrue(b.is_pinned() == (non_blocking and dst == "cpu"))
for dst, try_non_blocking in product(("cuda", "cpu"), (True, False)):
# Creates source on the opposite device from destination.
src = torch.randn(1000000,
device="cuda" if dst == "cpu" else "cpu",
pin_memory=True if dst == "cuda" else False)
_test_to_non_blocking(src, try_non_blocking, dst)
def test_to_cpu_blocking_by_default(self):
src = torch.randn(1000000, device="cuda")
torch.cuda.synchronize()
torch.cuda._sleep(int(100 * get_cycles_per_ms()))
dst = src.to(device="cpu")
self.assertEqual(torch.cuda.current_stream().query(), True)
self.assertEqual(src, dst)
self.assertFalse(dst.is_pinned())
def test_serialization_array_with_storage(self):
x = torch.randn(5, 5).cuda()
y = torch.IntTensor(2, 5).fill_(0).cuda()
q = [x, y, x, y.storage()]
with tempfile.NamedTemporaryFile() as f:
torch.save(q, f)
f.seek(0)
q_copy = torch.load(f)
self.assertEqual(q_copy, q, atol=0, rtol=0)
q_copy[0].fill_(5)
self.assertEqual(q_copy[0], q_copy[2], atol=0, rtol=0)
self.assertTrue(isinstance(q_copy[0], torch.cuda.FloatTensor))
self.assertTrue(isinstance(q_copy[1], torch.cuda.IntTensor))
self.assertTrue(isinstance(q_copy[2], torch.cuda.FloatTensor))
self.assertTrue(isinstance(q_copy[3], torch.storage.TypedStorage))
self.assertTrue(isinstance(q_copy[3]._untyped_storage, torch.UntypedStorage))
q_copy[1].fill_(10)
self.assertEqual(q_copy[3], torch.cuda.IntStorage(10).fill_(10))
@unittest.skipIf(TEST_CUDAMALLOCASYNC or TEST_WITH_ROCM, "temporarily disabled for async")
def test_cublas_workspace_explicit_allocation(self):
a = torch.randn(7, 7, device='cuda', requires_grad=False)
default_workspace_size = 4096 * 2 * 1024 + 16 * 8 * 1024 # :4096:2:16:8
# different size (32 MiB) expected on Hopper GPU
if torch.cuda.get_device_capability() == (9, 0):
default_workspace_size = 4096 * 8 * 1024
def check_workspace_size(inp):
torch._C._cuda_clearCublasWorkspaces()
start = torch.torch.cuda.memory_stats()['active_bytes.all.allocated']
with torch.no_grad():
torch.matmul(inp, inp)
finish = torch.torch.cuda.memory_stats()['active_bytes.all.allocated']
return finish - start
# check default
os.environ['CUBLAS_WORKSPACE_CONFIG'] = ''
self.assertTrue(abs(check_workspace_size(a) - default_workspace_size) < 524288)
# check default with bad user config
os.environ['CUBLAS_WORKSPACE_CONFIG'] = '-1'
self.assertTrue(abs(check_workspace_size(a) - default_workspace_size) < 524288)
# check valid config
os.environ['CUBLAS_WORKSPACE_CONFIG'] = ':128:8:64:16:32:32'
self.assertTrue(abs(check_workspace_size(a) - (3072 * 1024)) < 524288)
torch._C._cuda_clearCublasWorkspaces()
def test_cublas_allow_tf32_get_set(self):
skip_tf32_cublas = 'TORCH_ALLOW_TF32_CUBLAS_OVERRIDE' in os.environ and\
int(os.environ['TORCH_ALLOW_TF32_CUBLAS_OVERRIDE'])
if skip_tf32_cublas:
self.assertTrue(torch.backends.cuda.matmul.allow_tf32)
return
orig = torch.backends.cuda.matmul.allow_tf32
self.assertEqual(torch._C._get_cublas_allow_tf32(), orig)
torch.backends.cuda.matmul.allow_tf32 = not orig
self.assertEqual(torch._C._get_cublas_allow_tf32(), not orig)
torch.backends.cuda.matmul.allow_tf32 = orig
def test_float32_matmul_precision_get_set(self):
orig = torch.get_float32_matmul_precision()
skip_tf32_cublas = 'TORCH_ALLOW_TF32_CUBLAS_OVERRIDE' in os.environ and\
int(os.environ['TORCH_ALLOW_TF32_CUBLAS_OVERRIDE'])
# this is really just checking that the environment variable is respected during testing
# and not overwritten by another function that doesn't revert it to the intitial value
if not skip_tf32_cublas:
self.assertFalse(torch.backends.cuda.matmul.allow_tf32)
self.assertEqual(torch.get_float32_matmul_precision(), 'highest')
else:
self.assertTrue(torch.backends.cuda.matmul.allow_tf32)
for p in ('medium', 'high'):
torch.set_float32_matmul_precision(p)
self.assertEqual(torch.get_float32_matmul_precision(), p)
self.assertTrue(torch.backends.cuda.matmul.allow_tf32)
torch.set_float32_matmul_precision('highest')
self.assertEqual(torch.get_float32_matmul_precision(), 'highest')
self.assertFalse(torch.backends.cuda.matmul.allow_tf32)
torch.set_float32_matmul_precision(orig)
def test_cublas_allow_fp16_reduced_precision_reduction_get_set(self):
orig = torch.backends.cuda.matmul.allow_fp16_reduced_precision_reduction
self.assertEqual(torch._C._get_cublas_allow_fp16_reduced_precision_reduction(), orig)
torch.backends.cuda.matmul.allow_fp16_reduced_precision_reduction = not orig
self.assertEqual(torch._C._get_cublas_allow_fp16_reduced_precision_reduction(), not orig)
torch.backends.cuda.matmul.allow_fp16_reduced_precision_reduction = orig
def test_cublas_allow_bf16_reduced_precision_reduction_get_set(self):
orig = torch.backends.cuda.matmul.allow_bf16_reduced_precision_reduction
self.assertEqual(torch._C._get_cublas_allow_bf16_reduced_precision_reduction(), orig)
torch.backends.cuda.matmul.allow_bf16_reduced_precision_reduction = not orig
self.assertEqual(torch._C._get_cublas_allow_bf16_reduced_precision_reduction(), not orig)
torch.backends.cuda.matmul.allow_bf16_reduced_precision_reduction = orig
def test_cudnn_allow_tf32_get_set(self):
with torch.backends.cudnn.flags(enabled=None, benchmark=None, deterministic=None, allow_tf32=False):
self.assertFalse(torch.backends.cudnn.allow_tf32)
with torch.backends.cudnn.flags(enabled=None, benchmark=None, deterministic=None, allow_tf32=True):
self.assertTrue(torch.backends.cudnn.allow_tf32)
def test_type_conversions(self):
x = torch.randn(5, 5)
self.assertIsInstance(x.float(), torch.FloatTensor)
self.assertIsInstance(x.cuda().double(), torch.cuda.DoubleTensor)
self.assertIsInstance(x.cuda().float(), torch.cuda.FloatTensor)
self.assertIsInstance(x.cuda().float().cpu(), torch.FloatTensor)
self.assertIsInstance(x.cuda().float().cpu().int(), torch.IntTensor)
y = x.storage()
self.assertIsInstance(y.float(), torch.FloatStorage)
self.assertIsInstance(y.cuda().double(), torch.cuda.DoubleStorage)
self.assertIsInstance(y.cuda().float(), torch.cuda.FloatStorage)
self.assertIsInstance(y.cuda().float().cpu(), torch.FloatStorage)
self.assertIsInstance(y.cuda().float().cpu().int(), torch.IntStorage)
@unittest.skip("was disabled due to not enough memory, but actually it always fail")
def test_arithmetic_large_tensor(self):
x = torch.empty(2**30, device='cuda')
x.fill_(1)
self.assertEqual(x.sum(), 2**30)
x += 1
self.assertEqual(x.sum(), 2**31)
x.fill_(1)
x -= 0.5
self.assertEqual(x.sum(), 2**29)
x.fill_(1)
x *= 2
self.assertEqual(x.sum(), 2**31)
x.fill_(1)
x /= 2
self.assertEqual(x.sum(), 2**29)
def test_gather_bool(self):
t = torch.tensor([[False, True], [True, True]], device='cuda')
self.assertEqual(torch.gather(t, 1, torch.tensor([[0, 0], [1, 0]], device='cuda')),
torch.tensor([[False, False], [True, True]], device='cuda'))
def test_torch_manual_seed_seeds_cuda_devices(self):
with freeze_rng_state():
x = torch.zeros(4, 4).float().cuda()
torch.manual_seed(2)
self.assertEqual(torch.cuda.initial_seed(), 2)
x.uniform_()
torch.manual_seed(2)
y = x.clone().uniform_()
self.assertEqual(x, y)
self.assertEqual(torch.cuda.initial_seed(), 2)
def test_manual_seed(self):
with freeze_rng_state():
x = torch.zeros(4, 4).float().cuda()
torch.cuda.manual_seed(2)
self.assertEqual(torch.cuda.initial_seed(), 2)
x.uniform_()
a = torch.bernoulli(torch.full_like(x, 0.5))
torch.cuda.manual_seed(2)
y = x.clone().uniform_()
b = torch.bernoulli(torch.full_like(x, 0.5))
self.assertEqual(x, y)
self.assertEqual(a, b)
self.assertEqual(torch.cuda.initial_seed(), 2)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_cat_autogpu(self):
x = torch.randn(4, 4).cuda(1)
y = torch.randn(4, 4).cuda(1)
z = torch.cat([x, y], 0)
self.assertEqual(z.get_device(), x.get_device())
@unittest.skipIf(torch.cuda.device_count() >= 10, "Loading a cuda:9 tensor")
def test_load_nonexistent_device(self):
# Setup: create a serialized file object with a 'cuda:9' restore location
tensor = torch.randn(2, device='cuda')
buf = io.BytesIO()
torch.save(tensor, buf)
# NB: this might not work in the future if serialization changes
buf = io.BytesIO(buf.getvalue().replace(b'cuda:0', b'cuda:9'))
msg = r'Attempting to deserialize object on CUDA device 9'
with self.assertRaisesRegex(RuntimeError, msg):
_ = torch.load(buf)
def test_specify_improper_device_name(self):
import os
fname = "tempfile.pt"
try:
with self.assertRaisesRegex(RuntimeError, "Invalid device string"):
torch.save([torch.nn.Parameter(torch.randn(10, 10))], fname,
_use_new_zipfile_serialization=True)
torch.load(fname, 'cuda0')
finally:
if os.path.exists(fname):
os.remove(fname)
def test_get_device_index(self):
from torch.cuda._utils import _get_device_index
with self.assertRaisesRegex(RuntimeError, "Invalid device string"):
_get_device_index('cuda0', optional=True)
with self.assertRaisesRegex(ValueError, "Expected a cuda device"):
cpu_device = torch.device('cpu')
_get_device_index(cpu_device, optional=True)
def test_serialization_array_with_empty(self):
x = [torch.randn(4, 4).cuda(), torch.cuda.FloatTensor()]
with tempfile.NamedTemporaryFile() as f:
torch.save(x, f)
f.seek(0)
x_copy = torch.load(f)
for original, copy in zip(x, x_copy):
self.assertEqual(copy, original)
self.assertIs(type(copy), type(original))
self.assertEqual(copy.get_device(), original.get_device())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_multigpu_serialization_remap(self):
x = [torch.randn(4, 4).cuda(0), torch.randn(4, 4).cuda(1)]
def gpu_remap(storage, location):
if location == 'cuda:1':
return storage.cuda(0)
with tempfile.NamedTemporaryFile() as f:
torch.save(x, f)
f.seek(0)
x_copy = torch.load(f, map_location=gpu_remap)
for original, copy in zip(x, x_copy):
self.assertEqual(copy, original)
self.assertIs(type(copy), type(original))
self.assertEqual(copy.get_device(), 0)
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_multigpu_serialization_remap_dict(self):
x = [torch.randn(4, 4).cuda(0), torch.randn(4, 4).cuda(1)]
with tempfile.NamedTemporaryFile() as f:
torch.save(x, f)
f.seek(0)
x_copy = torch.load(f, map_location={'cuda:1': 'cuda:0'})
for original, copy in zip(x, x_copy):
self.assertEqual(copy, original)
self.assertIs(type(copy), type(original))
self.assertEqual(copy.get_device(), 0)
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_multigpu_storage_clone(self):
x = torch.randn(4, 4, device='cuda:1').storage()
y = x.clone()
self.assertEqual(x.get_device(), y.get_device())
for t in ['byte', 'char', 'short', 'int', 'long', 'half', 'double']:
self.assertEqual(getattr(x, t)().get_device(), x.get_device())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_cuda_set_device(self):
x = torch.randn(5, 5)
with torch.cuda.device(1):
self.assertEqual(x.cuda().get_device(), 1)
torch.cuda.set_device(0)
self.assertEqual(x.cuda().get_device(), 0)
with torch.cuda.device(1):
self.assertEqual(x.cuda().get_device(), 1)
self.assertEqual(x.cuda().get_device(), 0)
torch.cuda.set_device(1)
self.assertEqual(x.cuda().get_device(), 0)
def test_cuda_synchronize(self):
torch.cuda.synchronize()
torch.cuda.synchronize('cuda')
torch.cuda.synchronize('cuda:0')
torch.cuda.synchronize(0)
torch.cuda.synchronize(torch.device('cuda:0'))
if TEST_MULTIGPU:
torch.cuda.synchronize('cuda:1')
torch.cuda.synchronize(1)
torch.cuda.synchronize(torch.device('cuda:1'))
with self.assertRaisesRegex(ValueError, "Expected a cuda device, but"):
torch.cuda.synchronize(torch.device("cpu"))
with self.assertRaisesRegex(ValueError, "Expected a cuda device, but"):
torch.cuda.synchronize("cpu")
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_current_stream(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
s0 = torch.cuda.current_stream()
s1 = torch.cuda.current_stream(device=1)
s2 = torch.cuda.current_stream(device=0)
self.assertEqual(d0, s0.device)
self.assertEqual(d1, s1.device)
self.assertEqual(d0, s2.device)
self.assertEqual(s0, s2)
with torch.cuda.device(d1):
s0 = torch.cuda.current_stream()
s1 = torch.cuda.current_stream(1)
s2 = torch.cuda.current_stream(d0)
self.assertEqual(d1, s0.device)
self.assertEqual(d1, s1.device)
self.assertEqual(d0, s2.device)
self.assertEqual(s0, s1)
with self.assertRaisesRegex(ValueError,
"Expected a cuda device, but got: cpu"):
torch.cuda.current_stream(torch.device('cpu'))
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
@skipCUDANonDefaultStreamIf(True)
def test_default_stream(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
with torch.cuda.device(d0):
s0 = torch.cuda.default_stream()
with torch.cuda.device(d1):
s1 = torch.cuda.default_stream()
s2 = torch.cuda.default_stream(device=0)
s3 = torch.cuda.default_stream(d1)
self.assertEqual(d0, s0.device)
self.assertEqual(d1, s1.device)
self.assertEqual(d0, s2.device)
self.assertEqual(d1, s3.device)
self.assertEqual(s0, s2)
self.assertEqual(s1, s3)
with torch.cuda.device(d0):
self.assertEqual(torch.cuda.current_stream(), s0)
with torch.cuda.device(d1):
self.assertEqual(torch.cuda.current_stream(), s1)
with self.assertRaisesRegex(ValueError,
"Expected a cuda device, but got: cpu"):
torch.cuda.default_stream(torch.device('cpu'))
@skipCUDANonDefaultStreamIf(True)
def test_streams(self):
default_stream = torch.cuda.current_stream()
user_stream = torch.cuda.Stream()
self.assertEqual(torch.cuda.current_stream(), default_stream)
self.assertNotEqual(default_stream, user_stream)
self.assertEqual(default_stream.cuda_stream, 0)
self.assertNotEqual(user_stream.cuda_stream, 0)
with torch.cuda.stream(user_stream):
self.assertEqual(torch.cuda.current_stream(), user_stream)
self.assertTrue(user_stream.query())
tensor1 = torch.ByteTensor(5).pin_memory()
tensor2 = tensor1.cuda(non_blocking=True) + 1
default_stream.synchronize()
self.assertTrue(default_stream.query())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_stream_event_device(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
e0 = torch.cuda.Event()
self.assertEqual(None, e0.device)
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
s0.record_event(e0)
with torch.cuda.device(d1):
s1 = torch.cuda.Stream()
e1 = s1.record_event()
self.assertEqual(s0.device, torch.device('cuda:0'))
self.assertEqual(e0.device, torch.device('cuda:0'))
self.assertEqual(s1.device, torch.device('cuda:1'))
self.assertEqual(e1.device, torch.device('cuda:1'))
def test_stream_event_repr(self):
s = torch.cuda.current_stream()
self.assertTrue("torch.cuda.Stream" in s.__repr__())
e = torch.cuda.Event()
self.assertTrue("torch.cuda.Event" in e.__repr__())
s.record_event(e)
self.assertTrue("torch.cuda.Event" in e.__repr__())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_stream_context(self):
s0 = torch.cuda.current_stream()
s1 = torch.cuda.Stream(device=1)
s2 = torch.cuda.Stream(device=0)
with torch.cuda.device(s1.device):
prev_stream_on_cuda1 = torch.cuda.current_stream()
self.assertEqual(torch.cuda.current_stream(), s0)
self.assertEqual(0, torch.cuda.current_device())
with torch.cuda.stream(s1):
self.assertEqual(torch.cuda.current_stream(), s1)
self.assertEqual(1, torch.cuda.current_device())
with torch.cuda.stream(s2):
self.assertEqual(torch.cuda.current_stream(), s2)
self.assertEqual(0, torch.cuda.current_device())
with torch.cuda.stream(s0):
self.assertEqual(torch.cuda.current_stream(), s0)
self.assertEqual(0, torch.cuda.current_device())
self.assertEqual(torch.cuda.current_stream(), s2)
self.assertEqual(0, torch.cuda.current_device())
self.assertEqual(torch.cuda.current_stream(), s1)
self.assertEqual(1, torch.cuda.current_device())
with torch.cuda.device(s1.device):
self.assertEqual(prev_stream_on_cuda1, torch.cuda.current_stream())
self.assertEqual(torch.cuda.current_stream(), s0)
self.assertEqual(0, torch.cuda.current_device())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_streams_multi_gpu(self):
default_stream = torch.cuda.current_stream()
self.assertEqual(default_stream.device, torch.device('cuda:0'))
stream = torch.cuda.Stream(device=1)
self.assertEqual(stream.device, torch.device('cuda:1'))
with torch.cuda.device(1):
self.assertEqual(
torch.cuda.current_stream().device, torch.device('cuda:1'))
self.assertNotEqual(torch.cuda.current_stream(), default_stream)
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_streams_multi_gpu_query(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
torch.cuda.synchronize(d0)
torch.cuda.synchronize(d1)
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
with torch.cuda.device(d1):
s1 = torch.cuda.current_stream()
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
self.assertTrue(s0.query())
self.assertFalse(s1.query())
with torch.cuda.device(d0):
self.assertTrue(s0.query())
self.assertFalse(s1.query())
with torch.cuda.device(d1):
self.assertTrue(s0.query())
self.assertFalse(s1.query())
# deliberately using a different device
with torch.cuda.device(d0):
s1.synchronize()
self.assertTrue(s0.query())
self.assertTrue(s1.query())
with torch.cuda.device(d0):
self.assertTrue(s0.query())
self.assertTrue(s1.query())
with torch.cuda.device(d1):
self.assertTrue(s0.query())
self.assertTrue(s1.query())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_streams_multi_gpu_eq(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
s1 = torch.cuda.current_stream()
with torch.cuda.device(d1):
s2 = torch.cuda.current_stream()
s3 = torch.cuda.current_stream()
self.assertTrue(s0 == s0)
self.assertTrue(s0 == s1)
self.assertTrue(s2 == s2)
self.assertTrue(s2 == s3)
self.assertFalse(s0 == s2)
self.assertFalse(s1 == s3)
self.assertEqual(s0.device, s1.device)
self.assertEqual(s0.cuda_stream, s1.cuda_stream)
self.assertEqual(s2.device, s3.device)
self.assertEqual(s2.cuda_stream, s3.cuda_stream)
self.assertNotEqual(s0.device, s3.device)
self.assertEqual(hash(s0), hash(s1))
self.assertEqual(hash(s2), hash(s3))
self.assertNotEqual(hash(s0), hash(s3))
@unittest.skipIf(not TEST_MULTIGPU, "multi-GPU not supported")
def test_streams_priority(self):
low, high = torch.cuda.Stream.priority_range()
s0 = torch.cuda.Stream(device=0, priority=low)
self.assertEqual(low, s0.priority)
self.assertEqual(torch.device('cuda:0'), s0.device)
s1 = torch.cuda.Stream(device=1, priority=high)
self.assertEqual(high, s1.priority)
self.assertEqual(torch.device('cuda:1'), s1.device)
@unittest.skipIf(not TEST_MULTIGPU, "multi-GPU not supported")
def test_tensor_device(self):
self.assertEqual(torch.cuda.FloatTensor(1).get_device(), 0)
self.assertEqual(torch.cuda.FloatTensor(1, device=1).get_device(), 1)
with torch.cuda.device(1):
self.assertEqual(torch.cuda.FloatTensor(1).get_device(), 1)
self.assertEqual(torch.cuda.FloatTensor(1, device=0).get_device(), 0)
self.assertEqual(torch.cuda.FloatTensor(1, device=None).get_device(), 1)
def test_events(self):
stream = torch.cuda.current_stream()
event = torch.cuda.Event(enable_timing=True)
self.assertTrue(event.query())
start_event = torch.cuda.Event(enable_timing=True)
stream.record_event(start_event)
torch.cuda._sleep(int(50 * get_cycles_per_ms()))
stream.record_event(event)
self.assertFalse(event.query())
event.synchronize()
self.assertTrue(event.query())
self.assertGreater(start_event.elapsed_time(event), 0)
@staticmethod
def _stream_synchronize(self, spin_time_cycles):
s = torch.cuda.current_stream()
e_tik = torch.cuda.Event(enable_timing=True)
e_tok = torch.cuda.Event(enable_timing=True)
e_tik.record(s)
torch.cuda._sleep(spin_time_cycles)
e_tok.record(s)
s.synchronize()
self.assertTrue(s.query())
# not necessary to check e_tik and e_tok, as elapsed_time would throw
# exception if otherwise.
return e_tik.elapsed_time(e_tok)
@staticmethod
def _event_synchronize(self, spin_time_cycles):
s = torch.cuda.current_stream()
e_tik = torch.cuda.Event(enable_timing=True)
e_tok = torch.cuda.Event(enable_timing=True)
e_tik.record(s)
torch.cuda._sleep(spin_time_cycles)
s.record_event(e_tok)
e_tok.synchronize()
self.assertTrue(s.query())
# not necessary to check e_tik and e_tok, as elapsed_time would throw
# exception if otherwise.
return e_tik.elapsed_time(e_tok)
@staticmethod
def _event_wait(self, spin_time_cycles):
s0 = torch.cuda.current_stream()
s1 = torch.cuda.Stream()
e_tik = torch.cuda.Event(blocking=True, enable_timing=True)
e_tok = torch.cuda.Event(blocking=True, enable_timing=True)
e_tik.record(s0)
torch.cuda._sleep(spin_time_cycles - 10)
e_sync = torch.cuda.Event(blocking=True)
e_sync.record()
e_sync.wait(s1)
with torch.cuda.stream(s1):
torch.cuda._sleep(10)
s1.synchronize()
e_tok.record()
e_tok.synchronize()
self.assertTrue(s0.query())
self.assertTrue(s1.query())
self.assertTrue(e_sync.query())
# not necessary to check e_tik and e_tok, as elapsed_time would throw
# exception if otherwise.
return e_tik.elapsed_time(e_tok)
@staticmethod
def _test_stream_event_nogil(self, sync_func, p2c, c2p):
with torch.cuda.device('cuda:1'):
c2p.put(0)
p2c.get()
c2p.put(sync_func(self, TestCuda.FIFTY_MIL_CYCLES))
# Skip the test for ROCm as per https://github.com/pytorch/pytorch/issues/53190
@skipIfRocm
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_stream_event_nogil(self):
for sync_func in [TestCuda._stream_synchronize,
TestCuda._event_synchronize,
TestCuda._event_wait]:
p2c = queue.Queue()
c2p = queue.Queue()
e_tik = torch.cuda.Event(enable_timing=True)
e_tok = torch.cuda.Event(enable_timing=True)
t = threading.Thread(
target=TestCuda._test_stream_event_nogil,
args=(self, sync_func, p2c, c2p))
t.daemon = True
t.start()
c2p.get()
with torch.cuda.device('cuda:0'):
e_tik.record()
p2c.put(0)
parent_time = sync_func(self, TestCuda.FIFTY_MIL_CYCLES)
child_time = c2p.get()
e_tok.record()
e_tok.synchronize()
total_time = e_tik.elapsed_time(e_tok)
# Without GIL, synchronizations in parent and child threads can
# overlap. The total execution time should be a little bit longer
# than spinning fifty million cycles and much shorter than twice of
# that. However, testing absolute execution time is not reliable as
# it may vary on different hardware in different environments.
# Therefore, this test uses relative comparisons, checking if the
# sum of parent and child threads execution time is greater than the
# real execution time by least 40%.
self.assertGreater(parent_time + child_time, total_time * 1.4)
# This test is flaky for ROCm, see issue #62602
@skipIfRocm
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_events_wait(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
torch.cuda.synchronize(d0)
torch.cuda.synchronize(d1)
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
e0 = torch.cuda.Event()
s0.record_event(e0)
with torch.cuda.device(d1):
s1 = torch.cuda.current_stream()
self.assertFalse(s0.query())
self.assertTrue(s1.query())
s1.wait_event(e0)
s1.synchronize()
self.assertTrue(e0.query())
self.assertTrue(s0.query())
self.assertTrue(s1.query())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_events_multi_gpu_query(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
e0 = s0.record_event()
s0.synchronize()
with torch.cuda.device(d1):
s1 = torch.cuda.current_stream()
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
e1 = s1.record_event()
self.assertTrue(e0.query())
self.assertFalse(e1.query())
with torch.cuda.device(d0):
self.assertTrue(e0.query())
self.assertFalse(e1.query())
with torch.cuda.device(d1):
self.assertTrue(e0.query())
self.assertFalse(e1.query())
# deliberately using a different device
with torch.cuda.device(d0):
e1.synchronize()
self.assertTrue(e0.query())
self.assertTrue(e1.query())
with torch.cuda.device(d0):
self.assertTrue(e0.query())
self.assertTrue(e1.query())
with torch.cuda.device(d1):
self.assertTrue(e0.query())
self.assertTrue(e1.query())
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
@skipIfRocm
def test_events_multi_gpu_elapsed_time(self):
d0 = torch.device('cuda:0')
d1 = torch.device('cuda:1')
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
e0 = torch.cuda.Event(enable_timing=True)
torch.cuda._sleep(10)
s0.record_event(e0)
with torch.cuda.device(d1):
s1 = torch.cuda.current_stream()
e1 = torch.cuda.Event(enable_timing=True)
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
s1.record_event(e1)
e0.synchronize()
e1.synchronize()
with torch.cuda.device(d0):
with self.assertRaises(RuntimeError):
self.assertGreater(e0.elapsed_time(e1), 0)
with torch.cuda.device(d1):
with self.assertRaises(RuntimeError):
self.assertGreater(e0.elapsed_time(e1), 0)
with torch.cuda.device(d0):
s0 = torch.cuda.current_stream()
e2 = torch.cuda.Event(enable_timing=True)
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
s0.record_event(e2)
s0.synchronize()
self.assertGreater(e0.elapsed_time(e2), 0)
# deliberately calling from a different device
with torch.cuda.device(d1):
self.assertGreater(e0.elapsed_time(e2), 0)
def test_record_stream(self):
cycles_per_ms = get_cycles_per_ms()
t = torch.FloatTensor([1, 2, 3, 4]).pin_memory()
result = torch.cuda.FloatTensor(t.size())
stream = torch.cuda.Stream()
ptr = [None]
# Performs the CPU->GPU copy in a background stream
def perform_copy():
with torch.cuda.stream(stream):
tmp = t.cuda(non_blocking=True)
ptr[0] = tmp.data_ptr()
torch.cuda.current_stream().wait_stream(stream)
tmp.record_stream(torch.cuda.current_stream())
torch.cuda._sleep(int(50 * cycles_per_ms)) # delay the copy
result.copy_(tmp)
perform_copy()
with torch.cuda.stream(stream):
tmp2 = torch.cuda.FloatTensor(t.size())
tmp2.zero_()
self.assertNotEqual(tmp2.data_ptr(), ptr[0], msg='allocation re-used to soon')
self.assertEqual(result.tolist(), [1, 2, 3, 4])
if not TEST_CUDAMALLOCASYNC:
# In the native allocator, we expect "tmp"'s side-stream-tagged block will be reused
# in that side stream after result.copy_(tmp) in the main stream finishes.
torch.cuda.current_stream().synchronize()
with torch.cuda.stream(stream):
tmp3 = torch.cuda.FloatTensor(t.size())
self.assertEqual(tmp3.data_ptr(), ptr[0], msg='allocation not re-used')
def test_record_stream_on_shifted_view(self):
# See issue #27366
# This test detects unexpected block reallocation. For reliable test,
# the stream to allocate tensors is isolated. The allocator will not
# reuse free blocks which were allocated from another stream.
stream_alloc = torch.cuda.Stream()
with torch.cuda.stream(stream_alloc):
base = torch.cuda.FloatTensor([10, 10])
# Record another stream on a shifted view tensor.
view = base[5:]
assert view.storage_offset() > 0
stream_record = torch.cuda.Stream()
with torch.cuda.stream(stream_record):
torch.cuda._sleep(int(50 * get_cycles_per_ms()))
view.record_stream(stream_record)
# Delete those tensors to make the block free soon.
data_ptr = base.data_ptr()
del base, view
# A new tensor should not be allocated to the block above.
stream_alloc.synchronize()
with torch.cuda.stream(stream_alloc):
try_realloc = torch.cuda.FloatTensor([10, 10])
self.assertNotEqual(try_realloc.data_ptr(), data_ptr)
@contextlib.contextmanager
def _get_external_stream(self, device):
cudart = torch.cuda.cudart()
stream = ctypes.c_ulonglong(0)
stream_p = ctypes.POINTER(ctypes.c_void_p)(stream)
stream_p_int = ctypes.cast(stream_p, ctypes.c_void_p).value
with device:
try:
out = cudart.cudaStreamCreate(stream_p_int)
self.assertEqual(out, 0)
self.assertNotEqual(stream.value, 0)
yield stream.value
finally:
out = cudart.cudaStreamDestroy(stream.value)
self.assertEqual(out, 0)
def test_external_streams(self):
device = torch.cuda.device(0)
with self._get_external_stream(device) as stream_v:
ext_stream = torch.cuda.ExternalStream(stream_v)
self.assertEqual(stream_v, ext_stream.cuda_stream)
self.assertEqual(ext_stream.device.index, device.idx)
@unittest.skipIf(not TEST_MULTIGPU, "detected only one GPU")
def test_external_streams_multi_device(self):
device = torch.cuda.device(1)
with self._get_external_stream(device) as stream_v:
ext_stream = torch.cuda.ExternalStream(
stream_v, device=device)
self.assertEqual(stream_v, ext_stream.cuda_stream)
self.assertEqual(ext_stream.device.index, device.idx)
def test_noncontiguous_pinned_memory(self):
# See issue #3266
x = torch.arange(0, 10).view((2, 5))
self.assertEqual(x.t(), x.t().pin_memory())
def test_caching_pinned_memory(self):
cycles_per_ms = get_cycles_per_ms()
# check that allocations are re-used after deletion
t = torch.FloatTensor([1]).pin_memory()
ptr = t.data_ptr()
del t
t = torch.FloatTensor([1]).pin_memory()
self.assertEqual(t.data_ptr(), ptr, msg='allocation not reused')
# check that the allocation is not re-used if it's in-use by a copy
gpu_tensor = torch.cuda.FloatTensor([0])
torch.cuda._sleep(int(1000 * cycles_per_ms)) # delay the copy by 1s
gpu_tensor.copy_(t, non_blocking=True)
del t
t = torch.FloatTensor([1]).pin_memory()
self.assertNotEqual(t.data_ptr(), ptr, msg='allocation re-used too soon')
self.assertEqual(list(gpu_tensor), [1])
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_caching_pinned_memory_multi_gpu(self):
# checks that the events preventing pinned memory from being re-used
# too early are recorded on the correct GPU
cycles_per_ms = get_cycles_per_ms()
t = torch.FloatTensor([1]).pin_memory()
ptr = t.data_ptr()
gpu_tensor0 = torch.cuda.FloatTensor([0], device=0)
gpu_tensor1 = torch.cuda.FloatTensor([0], device=1)
with torch.cuda.device(1):
torch.cuda._sleep(int(1000 * cycles_per_ms)) # delay the copy by 1s
gpu_tensor1.copy_(t, non_blocking=True)
del t
t = torch.FloatTensor([2]).pin_memory()
self.assertNotEqual(t.data_ptr(), ptr, msg='allocation re-used too soon')
with torch.cuda.device(0):
gpu_tensor0.copy_(t, non_blocking=True)
self.assertEqual(gpu_tensor1[0], 1)
self.assertEqual(gpu_tensor0[0], 2)
def test_caching_allocator_record_stream_oom(self):
"""allocations delayed by a record_stream call should still be freed on
an out-of-memory in cuda_malloc_retry. see issue #19219"""
stream = torch.cuda.Stream()
with torch.cuda.stream(stream):
y = torch.zeros(40 * 1024 * 1024, device='cuda')
for _ in range(100):
x = torch.empty(40 * 1024 * 1024, device='cuda')
with torch.cuda.stream(stream):
y += x
# delays re-use of `x` until after all operations in `stream`
x.record_stream(stream)
del x
# we've made a mess by allocating up to the device capacity. free any
# cached blocks in case it affects future tests.
torch.cuda.empty_cache()
# Tests for historic illegal memory access, see #17040.
def test_reduction_gpu_memory_accessing(self):
x = torch.ones(512, 8, dtype=torch.float32, device='cuda')
torch.sum(x, 0)
def test_sum_fp16(self):
x = torch.zeros(10, device='cuda', dtype=torch.float16)
self.assertEqual(x.sum(), 0)
x = torch.ones(65504, device='cuda', dtype=torch.float16)
self.assertEqual(x.sum(), 65504)
self.assertEqual(x.sum(dtype=torch.float32), 65504)
x = torch.ones(65536, device='cuda', dtype=torch.float16)
self.assertEqual(x.sum(dtype=torch.float32), 65536)
a = torch.zeros(1203611).bernoulli_(0.0005)
x = a.to(device='cuda', dtype=torch.float16)
self.assertEqual(x.sum().item(), a.sum().item())
a = torch.zeros(100, 121, 80).bernoulli_(0.0005)
x = a.to(device='cuda', dtype=torch.float16)
self.assertEqual(x.sum((0, 2)).float().cpu(), a.sum((0, 2)))
def test_mean_fp16(self):
x = torch.ones(65536, device='cuda', dtype=torch.float16)
self.assertEqual(x.mean(), 1)
x = torch.ones(65536, device='cuda', dtype=torch.float16)
self.assertEqual(x.mean(dtype=torch.float32), 1)
def test_prod_large(self):
# tests global reduction (should_global_reduce = true) in case of non-zero identity element
x = torch.ones(240000, device='cuda', dtype=torch.float32)
self.assertEqual(x.prod(), 1)
# test for complex types. Note 240k is divisible by 4
for dtype in [torch.cfloat, torch.cdouble]:
x = torch.ones(240000, device='cuda', dtype=dtype) * (0 + 1j)
self.assertEqual(x.prod(), 1)
def test_multinomial_ext(self):
# Test two corner cases from older PyTorch (Issue #4858)
freqs = torch.cuda.FloatTensor([
0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0,
0.03178183361887932, 0.027680952101945877, 0.033176131546497345,
0.046052902936935425, 0.07742464542388916, 0.11543981730937958,
0.14148041605949402, 0.15784293413162231, 0.13180233538150787,
0.08271478116512299, 0.049702685326337814, 0.027557924389839172,
0.018125897273421288, 0.011851548217236996, 0.010252203792333603,
0.007422595750540495, 0.005372154992073774, 0.0045109698548913,
0.0036087757907807827, 0.0035267581697553396, 0.0018864056328311563,
0.0024605290964245796, 0.0022964938543736935, 0.0018453967059031129,
0.0010662291897460818, 0.0009842115687206388, 0.00045109697384759784,
0.0007791675161570311, 0.00020504408166743815, 0.00020504408166743815,
0.00020504408166743815, 0.00012302644609007984, 0.0,
0.00012302644609007984, 4.100881778867915e-05, 0.0, 0.0, 0.0, 0.0,
0.0, 0.0])
torch.cuda.manual_seed(11042)
sample = torch.multinomial(freqs, 1000, True)
self.assertNotEqual(freqs[sample].min(), 0)
p = torch.zeros(3421, 2, device="cuda", dtype=torch.float)
p[:, 1] = 1
torch.cuda.manual_seed(5214)
r = torch.multinomial(p, 1)
self.assertNotEqual(r.min().item(), 0)
# test corner case from Issue #13867
torch.cuda.manual_seed(33)
probs = torch.randn(1000000, device='cuda').clamp(min=0) * 3e-5
samples = probs.multinomial(1000000, replacement=True)
self.assertGreater(probs[samples].min().item(), 0)
def _spawn_test_multinomial_invalid_probs_cuda(self, probs):
import subprocess
try:
p = subprocess.Popen([sys.executable, '-c', f"""\
import sys
import torch
from torch import inf, nan
try:
with torch.random.fork_rng(devices=[0]):
torch.multinomial(torch.tensor({probs}).to('cuda'), 2, replacement=True)
torch.cuda.synchronize()
sys.exit(-1) # Should not be reached
except RuntimeError as e:
sys.exit(-2)
"""], stdout=subprocess.PIPE, stderr=subprocess.PIPE, universal_newlines=True)
out, err = p.communicate(timeout=10)
p.wait(timeout=10)
except subprocess.TimeoutExpired as e:
p.kill()
out, err = p.communicate()
expected_messages = [
'device-side assert triggered', # CUDA
'Assertion', # CUDA
'HSA_STATUS_ERROR_EXCEPTION', # ROCm
'Device-side assertion' # ROCm
]
self.assertTrue(any([msg in out or msg in err for msg in expected_messages]))
@slowTest
@unittest.skipIf(TEST_WITH_ROCM, "ROCm doesn't support device side asserts")
@unittest.skipIf(NO_MULTIPROCESSING_SPAWN, "Disabled for environments that \
don't support multiprocessing with spawn start method")
def test_multinomial_invalid_probs_cuda(self):
self._spawn_test_multinomial_invalid_probs_cuda([1., -1., 1.])
self._spawn_test_multinomial_invalid_probs_cuda([1., inf, 1.])
self._spawn_test_multinomial_invalid_probs_cuda([1., -inf, 1.])
self._spawn_test_multinomial_invalid_probs_cuda([1., 1., nan])
@staticmethod
def _mute_init():
os.dup2(os.open(os.devnull, os.O_WRONLY), sys.stderr.fileno())
def _spawn_method(self, method, arg):
ctx = torch.multiprocessing.get_context("spawn")
with ctx.Pool(1, initializer=self._mute_init) as pool:
errors = pool.map(method, [arg])
for e in errors:
if 'device-side assert triggered' not in str(e):
self.fail(e)
@staticmethod
def _test_index_bounds_cuda(idx):
x = torch.arange(10, device="cuda")
try:
y = x[torch.tensor([idx])]
return f"x[torch.tensor([{idx})]={y}"
except RuntimeError as err:
return err
@slowTest
@unittest.skipIf(NO_MULTIPROCESSING_SPAWN, "Disabled for environments that \
don't support multiprocessing with spawn start method")
@skipIfRocm
def test_index_out_of_bounds_exception_cuda(self):
test_method = TestCuda._test_index_bounds_cuda
# Test in-bound access works fine
self.assertEqual(test_method(1), "x[torch.tensor([1)]=tensor([1], device='cuda:0')")
# Test that indexing out of bounds causes assert
self._spawn_method(test_method, 11)
@slowTest
@unittest.skipIf(not TEST_LARGE_TENSOR, "not enough memory")
def test_huge_index(self):
src = torch.empty(15000000, 45, device='cuda', dtype=torch.long).random_(0, 2**22)
idx = torch.randperm(src.shape[0], device='cuda')
res = src[idx]
res_cpu = src.cpu()[idx.cpu()]
self.assertEqual(res.cpu(), res_cpu)
def test_min_max_inits(self):
# Testing if THC_reduceAll received the correct index initialization.
# This affects the result of THC_reduceAll operations at extreme values
x = torch.cuda.ByteTensor([0])
y = torch.cuda.ByteTensor([255])
expected = torch.cuda.LongTensor([0])[0]
_, v = x.max(dim=0)
self.assertEqual(v, expected)
_, v = y.min(dim=0)
self.assertEqual(v, expected)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_get_set_rng_state_all(self):
states = torch.cuda.get_rng_state_all()
before0 = torch.cuda.FloatTensor(100, device=0).normal_()
before1 = torch.cuda.FloatTensor(100, device=1).normal_()
torch.cuda.set_rng_state_all(states)
after0 = torch.cuda.FloatTensor(100, device=0).normal_()
after1 = torch.cuda.FloatTensor(100, device=1).normal_()
self.assertEqual(before0, after0, atol=0, rtol=0)
self.assertEqual(before1, after1, atol=0, rtol=0)
def test_nvtx(self):
# Just making sure we can see the symbols
torch.cuda.nvtx.range_push("foo")
torch.cuda.nvtx.mark("bar")
torch.cuda.nvtx.range_pop()
range_handle = torch.cuda.nvtx.range_start("range_start")
torch.cuda.nvtx.range_end(range_handle)
def test_bincount_ext(self):
# ensure CUDA code coverage
input_size = (5000,)
w = torch.randn(input_size, dtype=torch.double, device='cuda')
w_cpu = w.cpu()
# test shared memory impl
t = torch.randint(50, input_size, dtype=torch.int8, device='cuda')
self.assertEqual(t.cpu().bincount(), t.bincount())
self.assertEqual(t.cpu().bincount(w_cpu), t.bincount(w))
# test multi block memory impl
# see `THRESH_NUMBER_BINS_FOR_MULTI_BLOCK_MEM` in SummaryOps.cu
t = torch.randint(500, input_size, dtype=torch.int64, device='cuda')
self.assertEqual(t.cpu().bincount(), t.bincount())
self.assertEqual(t.cpu().bincount(w_cpu), t.bincount(w))
# test global memory impl
# see `THRESH_NUMBER_BINS_FOR_GLOBAL_MEM` in SummaryOps.cu
t = torch.randint(2000, input_size, dtype=torch.int64, device='cuda')
self.assertEqual(t.cpu().bincount(), t.bincount())
self.assertEqual(t.cpu().bincount(w_cpu), t.bincount(w))
t = torch.zeros([10], dtype=torch.int32, device='cuda')
# 35488 * 65536 as int32 would cause overflow to negative value
# giving negative bin offset
t[0] = 35488
counted = t.bincount(minlength=65536)
self.assertEqual(torch.sum(counted), 10)
def test_tiny_half_norm_(self):
a = torch.arange(25).cuda().float()
a /= 100000000
b = a.half()
self.assertGreater(b.norm().item(), 0)
def test_norm_type_conversion(self):
a = torch.ones(65536).cuda().half()
self.assertEqual(a.norm(p=0, dtype=torch.float32), 65536)
# Verifies that mem_get_info works, including when called for a different device
def test_mem_get_info(self):
def _test(idx):
before_free_bytes, before_available_bytes = torch.cuda.mem_get_info(idx)
# increasing to 8MB to force acquiring a new block and overcome blocksize differences across platforms
t = torch.randn(1024 * 1024 * 8, device='cuda:' + str(idx))
if IS_JETSON:
# w/o syncing, mem_get_info will run before memory allocated has actually increased.
# This race condition causes consistent failure
torch.cuda.synchronize()
after_free_bytes, after_available_bytes = torch.cuda.mem_get_info(idx)
self.assertTrue(after_free_bytes < before_free_bytes)
self.assertEqual(before_available_bytes, after_available_bytes)
_test(0)
if TEST_MULTIGPU:
_test(1)
# Test that wrap_with_cuda_memory_check successfully detects leak
def test_cuda_memory_leak_detection(self):
l = []
@self.wrap_with_cuda_memory_check
def no_leak():
pass
@self.wrap_with_cuda_memory_check
def leak_gpu0():
# increasing to 8MB to force acquiring a new block and overcome blocksize differences across platforms
l.append(torch.randn(1024 * 1024 * 8, device=torch.device("cuda:0")))
no_leak()
regex = r"CUDA driver API confirmed .+ on device 0.+"
if IS_JETSON:
try:
leak_gpu0()
except RuntimeError as e:
import re
assert re.match(regex, str(e)), str(e) + "\n does not match: \n" + regex
else:
# assertRaisesRegex does not pass with Python for Jetson,
# even though the RuntimeError matches regex using re.match
with self.assertRaisesRegex(RuntimeError, regex):
leak_gpu0()
if TEST_MULTIGPU:
@self.wrap_with_cuda_memory_check
def leak_gpu1():
# increasing to 8MB to force acquiring a new block and overcome blocksize differences across platforms
l.append(torch.randn(1024 * 1024 * 8, device=torch.device("cuda:1")))
with self.assertRaisesRegex(RuntimeError, r"CUDA driver API confirmed .+ on device 1.+"):
leak_gpu1()
def test_cuda_memory_leak_detection_propagates_errors(self):
with self.assertRaisesRegex(RuntimeError, r"The size of tensor a \(3\) must match"):
with self.assertLeaksNoCudaTensors():
x = torch.randn(3, 1, device='cuda')
y = torch.randn(2, 1, device='cuda')
z = x + y
@unittest.skipIf(not TEST_MEDIUM_TENSOR, "not enough memory")
def test_cuda_kernel_loop_overflow(self):
# Issue #24309: In extreme cases, the loop variable could overflow and continue
# the kernel loop with a negative index, causing a RuntimeError (invalid write):
x = torch.randn(1, 1, 1, 2**30 + 1, dtype=torch.float16, device="cuda")
expected = x[0, 0, 0, 2**30]
y = torch.nn.functional.avg_pool2d(x, kernel_size=1)
torch.cuda.synchronize()
self.assertEqual(y[0, 0, 0, 2**30], expected)
@unittest.skipIf(not TEST_LARGE_TENSOR, "not enough memory")
@gcIfJetson
def test_cuda_kernel_loop_overflow_large(self):
# Make sure input.numel() > INT_MAX is handled:
x = torch.randn(1, 1, 1, 2**31, dtype=torch.float16, device="cuda")
with self.assertRaisesRegex(RuntimeError, "integer out of range"):
y = torch.nn.functional.avg_pool2d(x, kernel_size=1)
# Issue #24309: In extreme cases, the loop variable could overflow and continue
# the kernel loop with a negative index, causing a RuntimeError (invalid write):
x = torch.randn(1, 1, 1, 2**31 - 1, dtype=torch.float16, device="cuda")
expected = x[0, 0, 0, 2**31 - 2]
y = torch.nn.functional.avg_pool2d(x, kernel_size=1)
torch.cuda.synchronize()
self.assertEqual(y[0, 0, 0, 2**31 - 2], expected)
# this might create a reference cycle on self...
def _make_multiply_in_stream(self):
class MultiplyInStream(torch.autograd.Function):
@staticmethod
def forward(ctx, x, val):
ctx.val = val
ctx.stream = torch.cuda.current_stream()
return x * val
@staticmethod
def backward(ctx, grad):
self.assertEqual(torch.cuda.current_stream(), ctx.stream)
# delays the operation in the the background stream
torch.cuda._sleep(1000 * 5000)
return grad * ctx.val, None
return MultiplyInStream
@skipCUDANonDefaultStreamIf(True)
def test_streaming_backwards_sync(self):
default_stream = torch.cuda.current_stream()
stream = torch.cuda.Stream()
MultiplyInStream = self._make_multiply_in_stream()
# Tests using grads outside the backward() stream context
# See "Stream semantics of backward passes" on https://pytorch.org/docs/stable/notes/cuda.html
x = torch.randn(5, 5, device='cuda', requires_grad=True)
with torch.cuda.stream(stream):
stream.wait_stream(default_stream)
output = MultiplyInStream.apply(x, 2)
output.sum().backward()
# sync needed
default_stream.wait_stream(stream)
self.assertEqual(x.grad, torch.ones_like(x) * 2)
self.assertEqual(torch.cuda.current_stream(), default_stream)
# Tests that using grads in the same stream context as backward()
# is safe regardless what streams bwd ops ran on
bwd_ambient_stream = torch.cuda.Stream()
x = torch.randn(5, 5, device='cuda', requires_grad=True)
with torch.cuda.stream(stream):
stream.wait_stream(default_stream)
output = MultiplyInStream.apply(x, 3)
with torch.cuda.stream(bwd_ambient_stream):
bwd_ambient_stream.wait_stream(stream)
output.sum().backward()
# x was first used on "stream" so its AccumulateGrad leaf should run on "stream".
# The end of backward() should have synced "bwd_ambient_stream" with "stream"
# so it should be safe to use x.grad here without any syncs.
self.assertEqual(x.grad, torch.ones_like(x) * 3)
self.assertEqual(torch.cuda.current_stream(), bwd_ambient_stream)
# Skip the test for ROCm as per https://github.com/pytorch/pytorch/issues/53190
@skipIfRocm
def test_streaming_backwards_multiple_streams(self):
MultiplyInStream = self._make_multiply_in_stream()
class StreamModel(torch.nn.Module):
def __init__(self):
super().__init__()
self.event = torch.cuda.Event()
self.stream0 = torch.cuda.Stream()
self.stream1 = torch.cuda.Stream()
def forward(self, x, x_first_use_on_ambient):
if x_first_use_on_ambient:
x0 = x.clone()
self.stream0.wait_stream(torch.cuda.current_stream())
self.stream1.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(self.stream0):
if not x_first_use_on_ambient:
x0 = x.clone()
y0 = MultiplyInStream.apply(x0, 2)
self.event.record(stream=torch.cuda.current_stream())
with torch.cuda.stream(self.stream1):
y1 = MultiplyInStream.apply(x, 3)
self.stream1.wait_event(self.event)
return y0 + y1
stream = torch.cuda.Stream()
for x_first_use_on_ambient in (True, False):
# the out_of_place=False, iters=1 case stresses if proper syncs are inserted
# when grads are initially None and stolen by backward ops.
for out_of_place, iters in ((True, 1),
(False, 1),
(False, 5)):
with torch.cuda.stream(stream):
x = torch.randn(5, 5, device='cuda', requires_grad=True)
model = StreamModel().cuda()
x.register_hook(lambda grad: self.assertEqual(torch.cuda.current_stream(),
stream if x_first_use_on_ambient else model.stream0))
for p in model.parameters():
self.assertTrue(p.grad is None)
for i in range(iters):
loss = model(x, x_first_use_on_ambient).sum()
if out_of_place:
x_grad = torch.autograd.grad((loss,), (x,))[0]
else:
loss.backward()
# See "Stream semantics of backward passes" on https://pytorch.org/docs/stable/notes/cuda.html
torch.cuda.current_stream().wait_stream(stream)
if out_of_place:
self.assertEqual(x_grad, torch.ones_like(x) * 5 * iters)
else:
self.assertEqual(x.grad, torch.ones_like(x) * 5 * iters)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_streaming_backwards_device_transfer(self):
# This function must run with non-default current streams on all devices, otherwise it's meaningless.
# The intention is to test that to()'s backward (CopyBackward) interacts properly with the
# synchronization logic in torch/csrc/autograd/input_buffer.cpp.
dev0 = torch.device("cuda:0")
dev1 = torch.device("cuda:1")
# Unfortunately I need to make the tensors largeish.
# Bigger tensors = longer D2D transfers = more likely to expose races.
size = 2**26
a = torch.full((size,), 1, device=dev1, dtype=torch.float64, requires_grad=True)
b = torch.full((size,), 1, device=dev1, dtype=torch.float64, requires_grad=True)
# Here to_backward_recipient = a*b is used only once, so MulBackward's InputBuffer slot only expects 1 input.
# This tests the situation where we don't call InputBuffer::accumulate for MulBackward's InputBuffer.
to_backward_recipient = a * b
s = to_backward_recipient.to(device="cuda:0").sum()
torch.cuda.synchronize(device=dev0)
torch.cuda.synchronize(device=dev1)
s.backward()
self.assertTrue(a.grad.sum().item() == size)
self.assertTrue(b.grad.sum().item() == size)
# Here to_backward_recipient = a*b is used twice, so MulBackward's InputBuffer slot expects 2 inputs.
# This tests the situation where we do call InputBuffer::accumulate for MulBackward's InputBuffer.
a.grad = None
b.grad = None
to_backward_recipient = a * b
# Multiply by 2 here so to's backward creates gradient values that are different from the case above,
# to mitigate weirdness if the caching allocator happens to reuse memory regions that were populated
# with 1s by the case above
s0 = to_backward_recipient.to(device="cuda:0").sum() * 2.
s1 = to_backward_recipient.to(device="cuda:0").sum() * 2.
torch.cuda.synchronize(device=dev0)
torch.cuda.synchronize(device=dev1)
s0.backward(retain_graph=True)
s1.backward()
self.assertTrue(a.grad.sum().item() == 4 * size)
self.assertTrue(b.grad.sum().item() == 4 * size)
def test_streaming_backwards_sync_graph_root(self):
# This function tests if bwd ops running on a side stream properly sync with the GraphRoot.
# The potential bug it targets is a race condition. The test uses multiple trials and
# torch.cuda._sleep such that if the race condition exists, the test will almost certainly fail,
# but there's a chance it may spuriously pass. Passing does not guarantee the backend is bug-free,
# but failure does guarantee there is a bug.
fwd_bwd_op_stream = torch.cuda.Stream()
bwd_ambient_stream = torch.cuda.Stream()
# We need these streams to be different otherwise the test is meaningless.
self.assertTrue(fwd_bwd_op_stream != bwd_ambient_stream)
size = int(1e3)
a = torch.full((size,), 2.0, device="cuda", requires_grad=True)
b = torch.full((size,), 3.0, device="cuda", requires_grad=True)
# I don't think we need any manual record_streams below.
# a and b remain in scope for the entire test.
# c and grad remain in scope for each iteration, and there's a full sync between iterations.
for trial in range(5):
torch.cuda.synchronize()
a.grad = b.grad = None
with torch.cuda.stream(fwd_bwd_op_stream):
c = a * b
with torch.cuda.stream(bwd_ambient_stream):
torch.cuda.synchronize()
# Long-running dummy kernel on bwd_ambient_stream delays filling of grad
torch.cuda._sleep(int(50 * get_cycles_per_ms()))
# Fills grad on bwd_ambient_stream
grad = torch.full((size,), float(trial + 1), device="cuda")
# Bwd ops still run on fwd_bwd_ops_stream, so the following will likely fail if
# bwd ops don't sync with bwd_ambient_stream before consuming grad.
torch.autograd.backward(tensors=c, grad_tensors=grad)
# See https://github.com/pytorch/pytorch/issues/47028
# assertEquals below run on bwd_ambient_stream, so this test may also fail
# if backward() fails to sync with bwd_ambient_stream at the end.
# Synchronizing here works around the issue until a proper fix can be made.
torch.cuda.synchronize()
with torch.no_grad():
self.assertEqual(a.grad, grad * b)
self.assertEqual(b.grad, grad * a)
def test_streaming_backwards_callback(self):
# Tests if autograd callbacks sync properly with respect to leaf streams and
# the user-facing stream surrounding backward(). If it fails, first suspect is
# sync logic where "final_callbacks_" are called in torch/csrc/autograd/engine.cpp
MultiplyInStream = self._make_multiply_in_stream()
size = int(1e3)
a = torch.full((size,), 1, device="cuda", dtype=torch.float, requires_grad=True)
b = torch.full((size,), 1, device="cuda", dtype=torch.float, requires_grad=True)
s0 = torch.cuda.Stream()
s1 = torch.cuda.Stream()
s2 = torch.cuda.Stream()
stash = []
# sets up a nontrivial structure of leaf streams
s0.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s0):
c = MultiplyInStream.apply(a, 2)
s1.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s1):
d = MultiplyInStream.apply(b, 3)
s1.wait_stream(s0)
e = c * d
def clone_leaf_grads():
stash.append(a.grad.clone())
stash.append(b.grad.clone())
# Use a hook on e to install the callback
e.register_hook(lambda grad: torch.autograd.Variable._execution_engine.queue_callback(clone_leaf_grads))
s2.wait_stream(s1)
with torch.cuda.stream(s2):
e.sum().backward()
# The autograd engine should sync s2 with all leaf streams then run the callback clone_leaf_grads on s2.
# If those things happened properly, checking the values of the cloned grads on s2 should be safe:
self.assertEqual(stash[0], torch.full_like(a, 6))
self.assertEqual(stash[1], torch.full_like(a, 6))
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
@unittest.skipIf(IS_SANDCASTLE or IS_REMOTE_GPU, "Does not work on Sandcastle")
def test_cuda_init_race(self):
# See https://github.com/pytorch/pytorch/issues/16559
import subprocess
subprocess.check_call([sys.executable, '-c', """\
import torch
import threading
def worker(rank):
torch.tensor([1.]).cuda(rank)
t1 = threading.Thread(target=worker, args=(0,))
t2 = threading.Thread(target=worker, args=(1,))
t1.start()
t2.start()
"""])
@unittest.skipIf(TEST_WITH_ROCM, "In ROCm, kernel asserts are disabled due to performance overhead")
def test_fixed_cuda_assert_async(self):
with self.assertRaisesRegex(RuntimeError, "Boolean value of Tensor with no values is ambiguous"):
torch._assert_async(torch.tensor([], device="cuda"))
with self.assertRaisesRegex(RuntimeError, "Boolean value of Tensor with more than one value is ambiguous"):
torch._assert_async(torch.tensor([0, 0], device="cuda"))
torch._assert_async(torch.tensor(1, device="cuda"))
torch._assert_async(torch.tensor(0.1, device="cuda"))
torch._assert_async(torch.tensor(-0.1, device="cuda"))
torch._assert_async(torch.tensor(True, device="cuda"))
torch._assert_async(torch.tensor(0 + 0.1j, device="cuda"))
fail_stmts = [
"torch._assert_async(torch.tensor(0, device='cuda'))",
"torch._assert_async(torch.tensor(0.0, device='cuda'))",
"torch._assert_async(torch.tensor(False, device='cuda'))",
"torch._assert_async(torch.tensor(0 + 0j, device='cuda'))",
]
import subprocess
for stmt in fail_stmts:
with self.subTest(stmt=stmt):
r = subprocess.call([sys.executable, '-c', f"""\
import torch
{stmt}
torch.cuda.synchronize()
"""])
self.assertTrue(r != 0)
def test_grad_scaling_unscale(self, dtype=torch.float):
inv_scale = torch.full((1,), 0.25, dtype=torch.float, device="cuda:0")
found_inf = torch.full((1,), 0.0, dtype=torch.float, device="cuda:0")
size = 10
g = torch.full((size, size), 4.0, dtype=dtype, device="cuda:0")
ginf = g.clone()
ginf[2, 2] = float('inf')
gnan = g.clone()
gnan[2, 2] = float('nan')
# Tries selected combinations of
# - contiguous grads
# - g.clone().t() which is not contiguous but still non overlapping and dense
# - variants of g.clone()[:, :5] which are not non overlapping and dense
# Non overlapping and dense grads route into a multi tensor apply kernel,
# others use a fallback per-tensor kernel, so we should try both.
cases = (
([g.clone(), g.clone()], False),
([g.clone(), g.clone().t()], False),
([g.clone(), g.clone()[:, :5]], False),
([g.clone()[:, :5], g.clone()[:, :5]], False),
([g.clone(), ginf.clone()], True),
([g.clone(), gnan.clone()], True),
([g.clone(), ginf.clone()[:, :5]], True),
([g.clone(), gnan.clone()[:, :5]], True),
([ginf.clone(), g.clone()[:, :5]], True),
([ginf.clone()[:, :5], g.clone()[:, :5]], True),
)
for grads, has_inf in cases:
found_inf.zero_()
torch._amp_foreach_non_finite_check_and_unscale_(grads, found_inf, inv_scale)
if has_inf:
self.assertEqual(found_inf, 1.0)
else:
self.assertEqual(found_inf, 0.0)
for grad in grads:
self.assertEqual(grad, torch.ones_like(grad), rtol=1e-5, atol=1e-7)
# When passing lists with mismatched dtypes to a raw
# _amp_foreach_non_finite_check_and_unscale_ call,
# it's expected to fall back to single-tensor TensorIterator kernel.
grads = [g.clone(), g.to(dtype=torch.float16)]
torch._amp_foreach_non_finite_check_and_unscale_(grads, found_inf, inv_scale)
for grad in grads:
self.assertEqual(grad, torch.ones_like(grad), rtol=1e-5, atol=1e-7)
# Passing lists with mismatched devices to a raw
# _amp_foreach_non_finite_check_and_unscale_ call should raise errors.
if TEST_MULTIGPU:
with self.assertRaisesRegex(RuntimeError, r"Expected all tensors to be on the same device"):
torch._amp_foreach_non_finite_check_and_unscale_([g.clone(), g.to(device="cuda:1")],
found_inf,
inv_scale)
# Creates a list of grads with mismatched dtypes and devices, to ensure
# scaler._unscale_grads_ organizes grads by dtype and device before calling
# _amp_foreach_non_finite_check_and_unscale_ on each set.
# If inject_inf >= 0, writes an inf into one grad for _unscale_grads_ to find.
def perfect_storm_grads(inject_inf):
grads = [g.clone(), g.clone()[:, :5], g.to(dtype=torch.float16), g.to(dtype=torch.float16)]
if TEST_MULTIGPU:
grads += [g.to(device="cuda:1"),
g.to(device="cuda:1")[:, :5],
g.to(device="cuda:1", dtype=torch.float16),
g.to(device="cuda:1", dtype=torch.float16)]
if inject_inf >= 0:
grads[inject_inf][2, 2] = float('inf')
return grads
scaler = torch.cuda.amp.GradScaler()
dummy_params = [torch.empty_like(g) for g in perfect_storm_grads(-1)]
dummy_opt = torch.optim.SGD(dummy_params, lr=1.)
# Ensures the inf/nan checking can find an inf injected onto any grad in the perfect storm.
for inject_inf in range(-1, len(dummy_params)):
found_inf = torch.full((1,), 0.0, dtype=torch.float, device="cuda:0")
grads = perfect_storm_grads(inject_inf)
for i, p in enumerate(dummy_params):
p.grad = grads[i]
found_inf_per_device = scaler._unscale_grads_(dummy_opt, inv_scale, found_inf, True)
if inject_inf < 0:
# No inf was injected, ensures unscaling worked normally.
self.assertTrue(sum(v.item() for v in found_inf_per_device.values()) == 0)
for grad in grads:
self.assertEqual(grad, torch.ones_like(grad), rtol=1e-5, atol=1e-7)
else:
# inf was injected, ensures inf was found.
self.assertTrue(sum(v.item() for v in found_inf_per_device.values()) == 1)
def test_grad_scaling_update_scale(self, device="cuda", dtype=torch.float):
growth = 2.0
backoff = 0.25
growth_interval = 2
scale = torch.full((1,), 4.0, dtype=dtype, device=device)
growth_tracker = torch.full((1,), 0.0, dtype=torch.int32, device=device)
found_inf = torch.full((1,), 0.0, dtype=torch.float, device="cuda:0")
# Simulates 2 consecutive unskipped iterations
torch._amp_update_scale_(scale, growth_tracker, found_inf, growth, backoff, growth_interval)
self.assertEqual(growth_tracker, 1)
self.assertEqual(scale, 4.0)
torch._amp_update_scale_(scale, growth_tracker, found_inf, growth, backoff, growth_interval)
self.assertEqual(growth_tracker, 0)
self.assertEqual(scale, 8.0)
# Simulates a skipped iteration
found_inf.fill_(1.0)
torch._amp_update_scale_(scale, growth_tracker, found_inf, growth, backoff, growth_interval)
self.assertEqual(growth_tracker, 0)
self.assertEqual(scale, 2.0)
def test_grad_scaling_unscale_sparse(self, device="cuda", dtype=torch.float):
scaler = torch.cuda.amp.GradScaler()
inv_scale = torch.full((1,), 0.25, dtype=dtype, device=device)
found_inf = torch.empty((1,), dtype=dtype, device=device)
cur = found_inf.device
i = torch.tensor([[0, 1, 1],
[2, 0, 2]], device="cuda", dtype=torch.int64)
v = torch.tensor([16., 32., 64.], device="cuda", dtype=torch.float)
s = torch.sparse_coo_tensor(i, v, torch.Size([2, 3]), device="cuda", dtype=dtype)
p = s.clone()
assert p.is_sparse
opt = torch.optim.SGD([p], lr=1.)
p.grad = s.clone()
found_inf.zero_()
found_inf = scaler._unscale_grads_(opt, inv_scale, found_inf, False)[cur]
self.assertEqual(found_inf, 0.0)
self.assertEqual(p.grad.to_dense(), (s / 4).to_dense())
v = torch.FloatTensor([16., 32., float('inf')])
p.grad = torch.sparse_coo_tensor(i, v, torch.Size([2, 3]), device="cuda", dtype=dtype)
found_inf.zero_()
found_inf = scaler._unscale_grads_(opt, inv_scale, found_inf, False)[cur]
self.assertEqual(found_inf, 1.0)
v = torch.FloatTensor([16., 32., float('nan')])
p.grad = torch.sparse_coo_tensor(i, v, torch.Size([2, 3]), device="cuda", dtype=dtype)
found_inf.zero_()
found_inf = scaler._unscale_grads_(opt, inv_scale, found_inf, False)[cur]
self.assertEqual(found_inf, 1.0)
p = s.clone().half()
assert p.is_sparse
opt = torch.optim.SGD([p], lr=1.)
p.grad = s.clone().half()
found_inf.zero_()
found_inf = scaler._unscale_grads_(opt, inv_scale, found_inf, True)[cur]
self.assertEqual(found_inf, 0.0)
self.assertEqual(p.grad.to_dense(), (s.half() / 4).to_dense())
# Creates fp16 sparse tensor with duplicated indices (uncoalesced). The uncoalesced representation
# does not overflow in fp16, but the coalesced representation would, because 64000 + 64000 > fp16 max.
# _amp_non_finite_check_and_unscale_ should report an overflow here.
i = torch.LongTensor([[0, 1, 0],
[2, 0, 2]])
v = torch.FloatTensor([64000., 32., 64000.])
p.grad = torch.sparse_coo_tensor(i, v, torch.Size([2, 3]), device="cuda", dtype=torch.float16)
found_inf.zero_()
found_inf = scaler._unscale_grads_(opt, inv_scale, found_inf, True)[cur]
self.assertEqual(found_inf, 1.0)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_grad_scaling_device_as_key(self):
# Ensure that different instances of "device" objects that point to the same device
# are treated as identical keys by dicts. GradScaler relies on this behavior, and may
# error otherwise in a way that's difficult to detect (a silent performance hit).
d = {}
t = torch.empty((1,), device="cuda:0")
dev0a = torch.device("cuda:0")
dev0b = torch.device("cuda:0")
dev1a = torch.device("cuda:1")
dev1b = torch.device("cuda:1")
self.assertTrue(hash(dev0a) == hash(dev0b))
self.assertTrue(hash(dev1a) == hash(dev1b))
d[dev0a] = "0a"
d[dev0b] = "0b"
self.assertTrue(len(d) == 1)
self.assertTrue(d[dev0a] == "0b")
d[t.device] = "t"
self.assertTrue(len(d) == 1)
self.assertTrue(d[dev0a] == "t")
d[dev1a] = "1a"
d[dev1b] = "1b"
self.assertTrue(len(d) == 2)
self.assertTrue(d[dev1a] == "1b")
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_grad_scaling_scale(self):
scaler = torch.cuda.amp.GradScaler(init_scale=2.)
t0 = torch.full((1,), 4.0, dtype=torch.float32, device="cuda:0")
t1 = torch.full((1,), 4.0, dtype=torch.float32, device="cuda:1")
# Create some nested iterables of tensors on different devices.
outputs = (t1.clone(), (t0.clone(), t1.clone()), [t0.clone(), (t1.clone(), t0.clone())])
outputs = scaler.scale(outputs)
self.assertTrue(outputs[0] == 8.0 and outputs[1][0] == 8.0 and outputs[1][1] == 8.0 and
outputs[2][0] == 8.0 and outputs[2][1][0] == 8.0 and outputs[2][1][1] == 8.0)
self.assertTrue(scaler._scale.device == t1.device)
def test_grad_scaling_state_dict(self):
for lazy_init_scale in True, False:
s0 = torch.cuda.amp.GradScaler(init_scale=3., growth_factor=4., backoff_factor=.5, growth_interval=2)
s1 = torch.cuda.amp.GradScaler(init_scale=6., growth_factor=7., backoff_factor=.8, growth_interval=1)
# sets a random value for load_state_dict to overwrite
s1._init_growth_tracker = 7
if lazy_init_scale:
# Dummy scale() call to ensure the scale tensor is lazily initialized.
s1.scale(torch.full((1,), 4.0, dtype=torch.float32, device="cuda:0"))
self.assertTrue(isinstance(s1._scale, torch.cuda.FloatTensor))
s1.load_state_dict(s0.state_dict())
self.assertEqual(s1.get_scale(), 3.)
self.assertEqual(s1.get_growth_factor(), 4.)
self.assertEqual(s1.get_backoff_factor(), .5)
self.assertEqual(s1.get_growth_interval(), 2)
self.assertEqual(s1._init_growth_tracker, 0)
def _create_scaling_models_optimizers(self, device="cuda", optimizer_ctor=torch.optim.SGD, optimizer_kwargs=None):
# Create a module+optimizer that will use scaling, and a control module+optimizer
# that will not use scaling, against which the scaling-enabled module+optimizer can be compared.
mod_control = torch.nn.Sequential(torch.nn.Linear(8, 8), torch.nn.Linear(8, 8)).to(device=device)
mod_scaling = torch.nn.Sequential(torch.nn.Linear(8, 8), torch.nn.Linear(8, 8)).to(device=device)
with torch.no_grad():
for c, s in zip(mod_control.parameters(), mod_scaling.parameters()):
s.copy_(c)
kwargs = {"lr": 1.0}
if optimizer_kwargs is not None:
kwargs.update(optimizer_kwargs)
opt_control = optimizer_ctor(mod_control.parameters(), **kwargs)
opt_scaling = optimizer_ctor(mod_scaling.parameters(), **kwargs)
return mod_control, mod_scaling, opt_control, opt_scaling
def _create_scaling_case(self, device="cuda", dtype=torch.float, optimizer_ctor=torch.optim.SGD, optimizer_kwargs=None):
data = [(torch.randn((8, 8), dtype=dtype, device=device), torch.randn((8, 8), dtype=dtype, device=device)),
(torch.randn((8, 8), dtype=dtype, device=device), torch.randn((8, 8), dtype=dtype, device=device)),
(torch.randn((8, 8), dtype=dtype, device=device), torch.randn((8, 8), dtype=dtype, device=device)),
(torch.randn((8, 8), dtype=dtype, device=device), torch.randn((8, 8), dtype=dtype, device=device))]
loss_fn = torch.nn.MSELoss().cuda()
skip_iter = 2
return self._create_scaling_models_optimizers(
device=device, optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs,
) + (data, loss_fn, skip_iter)
# _run_scaling_case generalizes some single-optimizer test logic to avoid too much copy-pasting below.
def _run_scaling_case(self, run, unskipped, skipped, atol=1e-7, optimizer_ctor=torch.optim.SGD, optimizer_kwargs=None):
# Ensure scaling can be disabled without changing user control flow.
for enabled in True, False:
(
mod_control, mod_scaling, opt_control, opt_scaling, data, loss_fn, skip_iter,
) = self._create_scaling_case(optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs)
# For functionality, test with a modest initial scale, and an unrealistically-large growth factor
# so any potential errors with the growth factor handling will be magnified.
scaler = torch.cuda.amp.GradScaler(init_scale=128., growth_factor=2.0, enabled=enabled, growth_interval=1)
_ = run(data, mod_control, opt_control, scaler, loss_fn, skip_iter, False)
ret = run(data, mod_scaling, opt_scaling, scaler, loss_fn, skip_iter, True)
# Allows run() to optionally return a different scaler instance.
scaler = ret if ret else scaler
# If scaling was enabled, the scale factor should have been multiplied by the growth factor
# len(data) - skipped times and the backoff factor "skipped" times.
if enabled:
net_growth = scaler.get_growth_factor()**unskipped if unskipped > 0 else 1.0
net_backoff = scaler.get_backoff_factor()**skipped if skipped > 0 else 1.0
self.assertTrue(scaler.get_scale() == (128. * net_growth * net_backoff))
else:
self.assertTrue(scaler.get_scale() == 1.0)
for c, s in zip(mod_control.parameters(), mod_scaling.parameters()):
self.assertEqual(c.grad, s.grad, atol=atol, rtol=1e-05)
c_state, s_state = opt_control.state[c], opt_scaling.state[s]
for k in c_state:
self.assertEqual(c_state[k], s_state[k], atol=atol, rtol=1e-05, msg=k)
self.assertEqual(c, s, atol=atol, rtol=1e-05)
# Compares no scaling + no autocasting against scaling + autocasting.
def _grad_scaling_autocast_test(self, *, atol=1e-3, optimizer_ctor=torch.optim.SGD, optimizer_kwargs=None):
try_pickle = False
def run(data, model, optimizer, scaler, loss_fn, skip_iter, try_scaling_api):
for i, (input, target) in enumerate(data):
optimizer.zero_grad()
with torch.autocast('cuda', enabled=try_scaling_api):
output = model(input)
loss = loss_fn(output, target)
if try_scaling_api:
scaler.scale(loss).backward()
if i == skip_iter and scaler.is_enabled():
with torch.no_grad():
model[1].weight.grad.fill_(float('inf'))
scaler.step(optimizer)
scaler.update()
if try_pickle:
scaler = pickle.loads(pickle.dumps(scaler))
else:
loss.backward()
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer.step()
return scaler
# NOTE(mkozuki): With current way of testing, `torch.optim.Adam` is failing in spite of `foreach` and `fused`.
# Giving some flexibility to this test might help.
context = contextlib.nullcontext
if optimizer_ctor in (torch.optim.Adam, torch.optim.AdamW):
from functools import partial
context = partial(self.assertRaises, AssertionError)
with context():
# sets atol=1e-3 because we're comparing pure fp32 arithmetic vs a mixture of fp16 and fp32
self._run_scaling_case(
run, unskipped=3, skipped=1, atol=atol, optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs,
)
# this will be picked up by try_pickle within run():
try_pickle = True
self._run_scaling_case(
run, unskipped=3, skipped=1, atol=atol, optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs,
)
def test_grad_scaling_autocast(self):
for optimizer_ctor in (torch.optim.SGD, torch.optim.Adam, torch.optim.AdamW):
self._grad_scaling_autocast_test(optimizer_ctor=optimizer_ctor)
def test_grad_scaling_autocast_foreach(self):
for optimizer_ctor in (torch.optim.SGD, torch.optim.Adam, torch.optim.AdamW):
self._grad_scaling_autocast_test(optimizer_ctor=optimizer_ctor, optimizer_kwargs={"foreach": True})
def test_grad_scaling_autocast_fused(self):
for optimizer_ctor in (torch.optim.Adam, torch.optim.AdamW):
self._grad_scaling_autocast_test(optimizer_ctor=optimizer_ctor, optimizer_kwargs={"fused": True})
# Compare non-fused optimizer vs fused one as the fused one unscales gradients
# inside its cuda kernel unlike the other.
def test_grad_scaling_autocast_fused_optimizers(self):
for optimizer_ctor, optimizer_kwargs, separate_unscale in product(
(torch.optim.Adam, torch.optim.AdamW),
({"fused": True, "amsgrad": False}, {"fused": True, "amsgrad": True}),
(False, True),
):
with self.subTest(optim=optimizer_ctor, kwargs=optimizer_kwargs, separate_unscale=separate_unscale):
self._grad_scaling_autocast_fused_optimizers(
optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs, separate_unscale=separate_unscale)
def _grad_scaling_autocast_fused_optimizers(self, optimizer_ctor, optimizer_kwargs, separate_unscale):
(
mod_control, mod_scaling, opt_control, opt_scaling, data, loss_fn, _,
) = self._create_scaling_case(optimizer_ctor=optimizer_ctor, optimizer_kwargs=optimizer_kwargs)
kwargs = deepcopy(optimizer_kwargs)
kwargs["fused"] = False
opt_control = optimizer_ctor(mod_control.parameters(), lr=1.0, **kwargs)
scaler = torch.cuda.amp.GradScaler(init_scale=128.0)
for input, target in data:
opt_control.zero_grad()
with torch.autocast('cuda'):
output_control = mod_control(input)
loss_control = loss_fn(output_control, target)
scaler.scale(loss_control).backward()
scaler.step(opt_control)
scaler.update()
opt_scaling.zero_grad()
with torch.autocast('cuda'):
output_scaling = mod_scaling(input)
loss_scaling = loss_fn(output_scaling, target)
scaler.scale(loss_scaling).backward()
if separate_unscale:
scaler.unscale_(opt_scaling)
scaler.step(opt_scaling)
scaler.update()
self.assertEqual(loss_control, loss_scaling)
for param_control, param_scaling in zip(mod_control.parameters(), mod_scaling.parameters()):
self.assertEqual(param_control.grad, param_scaling.grad)
self.assertEqual(param_control, param_scaling)
state_control, state_scaling = opt_control.state[param_control], opt_scaling.state[param_scaling]
for k in state_control:
actual = state_scaling[k]
if k == "step":
actual = actual.squeeze()
self.assertEqual(state_control[k], actual)
def test_grad_scaling_clipping(self):
def run(data, model, optimizer, scaler, loss_fn, skip_iter, try_scaling_api):
max_norm = 0.2 # A reasonable value that actually has an effect, based on printouts of grads
for i, (input, target) in enumerate(data):
optimizer.zero_grad()
output = model(input)
loss = loss_fn(output, target)
if try_scaling_api:
scaler.scale(loss).backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm * scaler.get_scale())
if i == skip_iter and scaler.is_enabled():
model[1].weight.grad.data.fill_(float('inf'))
scaler.step(optimizer)
scaler.update()
else:
loss.backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm)
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer.step()
self._run_scaling_case(run, unskipped=3, skipped=1, atol=1e-5)
def test_grad_scaling_clipping_separate_unscale(self):
def run(data, model, optimizer, scaler, loss_fn, skip_iter, try_scaling_api):
max_norm = 0.2 # A reasonable value that actually has an effect, based on printouts of grads
for i, (input, target) in enumerate(data):
optimizer.zero_grad()
output = model(input)
loss = loss_fn(output, target)
if try_scaling_api:
scaler.scale(loss).backward()
if i == skip_iter and scaler.is_enabled():
model[1].weight.grad.data.fill_(float('inf'))
scaler.unscale_(optimizer)
torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm, error_if_nonfinite=False)
scaler.step(optimizer)
scaler.update()
else:
loss.backward()
torch.nn.utils.clip_grad_norm_(model.parameters(), max_norm)
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer.step()
self._run_scaling_case(run, unskipped=3, skipped=1)
@unittest.skipIf(IS_WINDOWS, 'FIXME: fix this test for Windows')
def test_grad_scaling_penalty(self):
def run(data, model, optimizer, scaler, loss_fn, skip_iter, try_scaling_api):
for i, (input, target) in enumerate(data):
optimizer.zero_grad()
output = model(input)
loss = loss_fn(output, target)
if try_scaling_api:
grad_params = torch.autograd.grad(scaler.scale(loss),
model.parameters(), create_graph=True)
inv_scale = 1. / scaler.get_scale()
grad_params = [p * inv_scale for p in grad_params]
else:
grad_params = torch.autograd.grad(loss, model.parameters(), create_graph=True)
grad_norm = 0
for grad in grad_params:
grad_norm += grad.pow(2).sum()
grad_norm = grad_norm.sqrt()
loss = loss + grad_norm
if try_scaling_api:
scaler.scale(loss).backward()
if i == skip_iter and scaler.is_enabled():
model[1].weight.grad.data.fill_(float('inf'))
scaler.step(optimizer)
scaler.update()
else:
loss.backward()
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer.step()
self._run_scaling_case(run, unskipped=3, skipped=1)
def test_grad_scaling_accumulation(self):
def run(data, model, optimizer, scaler, loss_fn, skip_iter, try_scaling_api):
iters_to_accumulate = 2
for i, (input, target) in enumerate(data):
output = model(input)
loss = loss_fn(output, target)
loss = loss / iters_to_accumulate
if try_scaling_api:
scaler.scale(loss).backward()
else:
loss.backward()
if (i + 1) % iters_to_accumulate == 0:
if try_scaling_api:
scaler.step(optimizer)
scaler.update()
optimizer.zero_grad()
else:
optimizer.step()
optimizer.zero_grad()
self._run_scaling_case(run, unskipped=2, skipped=0)
def test_grad_scaling_multiple(self):
# Tests gradient scaling with 2 models and 2 optimizers that both receive gradients from 2 losses.
# Some of the logic here cannot reuse the generic helper functions created for the 1-optimizer cases.
for enabled in True, False:
mod_control0, mod_scaling0, opt_control0, opt_scaling0, data, loss_fn, skip_iter = \
self._create_scaling_case()
mod_control1, mod_scaling1, opt_control1, opt_scaling1 = \
self._create_scaling_models_optimizers()
scaler = torch.cuda.amp.GradScaler(init_scale=128., growth_factor=2.0, enabled=enabled, growth_interval=1)
def run(model0, model1, optimizer0, optimizer1, try_scaling_api):
for i, (input, target) in enumerate(data):
optimizer0.zero_grad()
optimizer1.zero_grad()
output0 = model0(input)
output1 = model1(input)
loss0 = loss_fn(0.3 * output0 + 0.7 * output1, target)
loss1 = loss_fn(0.6 * output0 - 0.4 * output1, target)
if try_scaling_api:
scaler.scale(loss0).backward(retain_graph=True)
scaler.scale(loss1).backward()
if i == skip_iter and scaler.is_enabled():
model1[1].weight.grad.data.fill_(float('inf'))
# As an additional stress test, separately unscale for one of the optimizers.
scaler.unscale_(optimizer0)
scaler.step(optimizer0)
scaler.step(optimizer1)
scaler.update()
else:
loss0.backward(retain_graph=True)
loss1.backward()
optimizer0.step()
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer1.step()
run(mod_control0, mod_control1, opt_control0, opt_control1, False)
run(mod_scaling0, mod_scaling1, opt_scaling0, opt_scaling1, True)
# The loss scale should have been multiplied by the growth factor 3 times and the backoff factor once.
self.assertTrue(scaler.get_scale() == (128. * scaler.get_growth_factor()**3 *
scaler.get_backoff_factor()**1) if enabled else 1.0)
for c, s in zip(chain(mod_control0.parameters(), mod_control1.parameters()),
chain(mod_scaling0.parameters(), mod_scaling1.parameters())):
self.assertEqual(c, s, rtol=1e-5, atol=1e-7)
def test_grad_scaler_pass_itself(self):
class _PlaceHolderOptimizer(torch.optim.Optimizer):
tester = self
def __init__(self, params, defaults=None):
if defaults is None:
defaults = {}
super().__init__(params, defaults)
self._step_supports_amp_scaling = True
class Optimizer1(_PlaceHolderOptimizer):
def step(self, closure=None, *, grad_scaler=None):
self.tester.assertTrue(isinstance(grad_scaler, torch.cuda.amp.GradScaler))
self.tester.assertFalse(hasattr(self, "grad_scale"))
self.tester.assertFalse(hasattr(self, "found_inf"))
class Optimizer2(_PlaceHolderOptimizer):
def step(self, closure=None):
self.tester.assertTrue(isinstance(self.grad_scale, torch.Tensor))
self.tester.assertTrue(isinstance(self.found_inf, torch.Tensor))
x = torch.randn(4, 4).cuda()
m = torch.nn.Linear(4, 1).cuda()
o1 = Optimizer1(m.parameters())
o2 = Optimizer2(m.parameters())
scaler = torch.cuda.amp.GradScaler(init_scale=2.0)
with torch.cuda.amp.autocast():
y = m(x)
loss = y.mean()
scaler.scale(loss).backward()
with self.assertWarns(FutureWarning):
scaler.step(o1)
scaler.step(o2)
scaler.update()
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_grad_scaling_multigpu(self):
# Same as above, but runs some of the models on device 1.
# GradScaler should transparently handle losses and gradients on multiple devices.
# This test could be combined with the test above, but I think it makes sense to treat
# multi-GPU operations separately.
dev0 = torch.device("cuda:0")
dev1 = torch.device("cuda:1")
for enabled in True, False:
mod_control0, mod_scaling0, opt_control0, opt_scaling0, data, loss_fn, skip_iter = \
self._create_scaling_case()
mod_control1, mod_scaling1, opt_control1, opt_scaling1 = \
self._create_scaling_models_optimizers(device=dev1)
scaler = torch.cuda.amp.GradScaler(init_scale=128., growth_factor=2.0, enabled=enabled, growth_interval=1)
def run(model0, model1, optimizer0, optimizer1, try_scaling_api):
for i, (input, target) in enumerate(data):
optimizer0.zero_grad()
optimizer1.zero_grad()
output0 = model0(input)
output1 = model1(input.to(dev1))
loss0 = loss_fn(0.3 * output0 + 0.7 * output1.to(dev0), target)
loss1 = loss_fn(0.6 * output0.to(dev1) - 0.4 * output1, target.to(dev1))
if try_scaling_api:
scaler.scale(loss0).backward(retain_graph=True)
scaler.scale(loss1).backward()
if i == skip_iter and scaler.is_enabled():
model1[1].weight.grad.data.fill_(float('inf'))
# As an additional stress test, separately unscale for one of the optimizers.
scaler.unscale_(optimizer0)
scaler.step(optimizer0)
scaler.step(optimizer1)
# Make sure the found_infs were collected properly across optimizers and devices.
if scaler.is_enabled():
self.assertTrue(len(scaler._found_inf_per_device(optimizer0)) == 1)
self.assertTrue(len(scaler._found_inf_per_device(optimizer1)) == 1)
self.assertTrue(scaler._found_inf_per_device(optimizer0)[dev0].item() == 0.)
self.assertTrue(scaler._found_inf_per_device(optimizer1)[dev1].item() ==
float(i == skip_iter))
scaler.update()
else:
loss0.backward(retain_graph=True)
loss1.backward()
optimizer0.step()
if (not scaler.is_enabled()) or (i != skip_iter):
optimizer1.step()
run(mod_control0, mod_control1, opt_control0, opt_control1, False)
run(mod_scaling0, mod_scaling1, opt_scaling0, opt_scaling1, True)
# The loss scale should have been multiplied by the growth factor 3 times and the backoff factor once.
self.assertTrue(scaler.get_scale() == (128. * scaler.get_growth_factor()**3 *
scaler.get_backoff_factor()**1) if enabled else 1.0)
# Copy mod_control1 and mod_scaling1 back the device 0 for comparison
mod_control1.to(dev0)
mod_scaling1.to(dev0)
for c, s in zip(chain(mod_control0.parameters(), mod_control1.parameters()),
chain(mod_scaling0.parameters(), mod_scaling1.parameters())):
self.assertEqual(c, s, rtol=1e-5, atol=1e-7)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "FAIL")
def test_cublas_multiple_threads_same_device(self):
# Note, these parameters should be very carefully tuned
# Too small number makes it hard for the racing condition
# to happen, while too large number sometimes cause hang
size = 1024
num_threads = 2
trials = 3
test_iters = 100
weight = torch.ones((size, size), device='cuda')
results = {}
barrier = threading.Barrier(num_threads)
def _worker(t):
my_stream = torch.cuda.Stream()
# Hard sync so we don't need to worry about creating and using tensors
# across streams or the fact that default streams are thread-local.
# Those issues are not the target of this test.
torch.cuda.synchronize()
# Line up threads to increase likelihood of race conditions.
barrier.wait()
with torch.cuda.stream(my_stream):
for i in range(test_iters):
# If all threads are sharing the same cublas handle,
# the following sequence may occur:
# thread 0 calls cublasSetStream()
# thread 1 calls cublasSetStream()
# thread 0 launches its raw gemm, which it thinks is in
# its own stream, but is actually in thread 1's stream.
# thread 0 enqueues its div_, which IS is its own stream,
# but actually now races with its gemm.
results[t] = torch.mm(results[t], weight)
results[t].div_(float(size))
torch.cuda.synchronize()
for _ in range(trials):
for t in range(num_threads):
results[t] = torch.ones((size, size), device='cuda')
threads = [threading.Thread(target=_worker,
args=(t,)) for t in range(num_threads)]
for thread in threads:
thread.start()
for thread in threads:
thread.join()
for t in range(num_threads):
self.assertEqual(results[t].sum().item(), size * size)
# Test is flaky on Windows (https://github.com/pytorch/pytorch/issues/57401)
@unittest.skipIf(IS_WINDOWS, 'Test is flaky on Windows (see issue 57401)')
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
@skipIfRocm
def test_cudnn_multiple_threads_same_device(self):
# This function is intended to test the lazy creation and reuse of per-thread
# cudnn handles on each device in aten/src/ATen/cudnn/Handles.cpp.
# Failure here likely indicates something wrong with that logic.
weight = torch.ones((1, 1, 2, 2), device='cuda')
results = {}
num_threads = 2
trials = 3
test_iters = 1000
barrier = threading.Barrier(num_threads)
with torch.backends.cudnn.flags(enabled=True):
def _worker(t):
my_stream = torch.cuda.Stream()
# Hard sync so we don't need to worry about creating and using tensors
# across streams or the fact that default streams are thread-local.
# Those issues are not the target of this test.
torch.cuda.synchronize()
# Line up threads to increase likelihood of race conditions.
barrier.wait()
with torch.cuda.stream(my_stream):
for _ in range(test_iters):
# If all threads are sharing the same cudnn handle,
# the following sequence may occur:
# thread 0 calls setCuDNNStreamToCurrent()
# thread 1 calls setCuDNNStreamToCurrent()
# thread 0 launches its raw convolution, which it thinks is in
# its own stream, but is actually in thread 1's stream.
# thread 0 enqueues its div_, which IS is its own stream,
# but now races with its convolution.
results[t] = torch.nn.functional.conv2d(results[t], weight, padding=0)
results[t].div_(4.0)
torch.cuda.synchronize()
for _ in range(trials):
for t in range(num_threads):
results[t] = torch.ones((1, 1, 2048, 2048), device='cuda')
threads = [threading.Thread(target=_worker,
args=(t,)) for t in range(num_threads)]
for thread in threads:
thread.start()
for thread in threads:
thread.join()
for t in range(num_threads):
self.assertEqual(results[t].sum().item(),
(2048 - test_iters) * (2048 - test_iters))
def test_cusparse_multiple_threads_same_device(self):
size = 1024
num_threads = 2
trials = 3
test_iters = 500
def ones_sparse(size):
a = torch.arange(size, device='cuda')
indices = torch.cartesian_prod(a, a).t()
values = torch.ones(size * size, device='cuda')
return torch.sparse_coo_tensor(indices, values)
weight = ones_sparse(size)
results = {}
barrier = threading.Barrier(num_threads)
def _worker(t):
my_stream = torch.cuda.Stream()
# Hard sync so we don't need to worry about creating and using tensors
# across streams or the fact that default streams are thread-local.
# Those issues are not the target of this test.
torch.cuda.synchronize()
# Line up threads to increase likelihood of race conditions.
barrier.wait()
with torch.cuda.stream(my_stream):
for i in range(test_iters):
# If all threads are sharing the same cublas handle,
# the following sequence may occur:
# thread 0 calls cublasSetStream()
# thread 1 calls cublasSetStream()
# thread 0 launches its raw gemm, which it thinks is in
# its own stream, but is actually in thread 1's stream.
# thread 0 enqueues its div_, which IS is its own stream,
# but actually now races with its gemm.
results[t] = weight.mm(results[t])
results[t].div_(float(size))
torch.cuda.synchronize()
for _ in range(trials):
for t in range(num_threads):
results[t] = torch.ones((size, size), device='cuda')
threads = [threading.Thread(target=_worker,
args=(t,)) for t in range(num_threads)]
for thread in threads:
thread.start()
for thread in threads:
thread.join()
for t in range(num_threads):
self.assertEqual(results[t].sum().item(), size * size)
def _run_autocast_outofplace(self, op, args, run_as_type, out_type=None, module=torch, add_kwargs=None):
# helper to cast args
def cast(val, to_type):
if isinstance(val, torch.Tensor):
return val.to(to_type) if val.is_floating_point() else val
elif isinstance(val, collections.abc.Iterable):
return type(val)(cast(v, to_type) for v in val)
else:
return val
if add_kwargs is None:
add_kwargs = {}
fast_dtype = torch.bfloat16 if run_as_type == torch.bfloat16 else torch.float16
self.assertFalse(torch.is_autocast_enabled())
with torch.autocast('cuda', dtype=fast_dtype):
self.assertTrue(torch.is_autocast_enabled())
out_type = out_type if out_type is not None else run_as_type
output = output_method = None
# Try module.* variant, if requested:
if module is not None and hasattr(module, op):
output = getattr(module, op)(*args, **add_kwargs)
if isinstance(output, torch.Tensor):
self.assertTrue(out_type == output.dtype,
"autocast for torch.{} produced {}, should produce {}"
.format(op, output.dtype, out_type))
# Try Tensor.* variant:
if hasattr(torch.Tensor, op):
output_method = getattr(args[0], op)(*args[1:], **add_kwargs)
if isinstance(output_method, torch.Tensor):
self.assertTrue(out_type == output_method.dtype,
"autocast for torch.{} produced {}, should produce torch.{}"
.format(op, output_method.dtype, out_type))
self.assertTrue((output is not None) or (output_method is not None),
"{} not found as an attribute on either Tensor or the requested module {}".format(
op, module))
# Accounts for ops that return Tensors, iterables, and other non-Tensors.
# For example, lstm_cell returns a tuple and equal returns bool.
def compare(first, second):
if isinstance(first, torch.Tensor):
return torch.equal(first, second)
elif isinstance(first, collections.abc.Iterable):
return all(compare(f, s) for f, s in zip(first, second))
else:
return first == second
# If both torch.* and Tensor.* variants were found, check outputs are identical
if (output is not None) and (output_method is not None):
self.assertTrue(type(output) == type(output_method))
comparison = compare(output, output_method)
self.assertTrue(comparison, "torch.{0} result did not match Tensor.{0} result".format(op))
# Compare numerics to Python-side "autocasting" that (we expect) does the same thing
# as the C++-side autocasting, and should be bitwise accurate.
output_to_compare = output if output is not None else output_method
with torch.autocast('cuda', enabled=False):
self.assertFalse(torch.is_autocast_enabled())
if module is not None and hasattr(module, op):
control = getattr(module, op)(*cast(args, run_as_type), **add_kwargs)
else:
control = getattr(args[0].to(run_as_type), op)(*cast(args[1:], run_as_type), **add_kwargs)
self.assertTrue(type(output_to_compare) == type(control))
comparison = compare(output_to_compare, control)
self.assertTrue(comparison, "torch.{} result did not match control".format(op))
self.assertTrue(torch.is_autocast_enabled())
self.assertFalse(torch.is_autocast_enabled())
def args_maybe_kwargs(self, op_with_args):
if len(op_with_args) == 2:
return op_with_args[0], op_with_args[1], {}
else:
return op_with_args[0], op_with_args[1], op_with_args[2]
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_torch_fp16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op_with_args in self.autocast_lists.torch_fp16:
skip_test = False
op, args = op_with_args[0], op_with_args[1]
if len(op_with_args) == 3:
skip_test = op_with_args[2] # TEST_WITH_ROCM
if not skip_test:
self._run_autocast_outofplace(op, args, torch.float16)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_torch_bf16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op_with_args in self.autocast_lists.torch_fp16:
skip_test = False
op, args = op_with_args[0], op_with_args[1]
if len(op_with_args) == 3:
skip_test = op_with_args[2] # TEST_WITH_ROCM
should_error_from_cudnn = 'cudnn' in op and \
('TORCH_CUDNN_V8_API_DISABLED' in os.environ and
int(os.environ['TORCH_CUDNN_V8_API_DISABLED']) or
torch.cuda.get_device_capability() < (8, 0))
should_error_from_not_implemented = should_error_from_cudnn or 'thnn' in op \
or 'fused' in op or 'gru' in op or op == '_thnn_fused_lstm_cell' or op == 'lstm_cell'
if not skip_test:
if should_error_from_not_implemented:
with self.assertRaises(RuntimeError, msg=str(op) + ' should not be supported for bfloat16!'):
self._run_autocast_outofplace(op, args, torch.bfloat16)
else:
if torch.cuda.is_bf16_supported():
self._run_autocast_outofplace(op, args, torch.bfloat16)
else:
with self.assertRaisesRegex(RuntimeError, 'Device does not support bfloat16'):
self._run_autocast_outofplace(op, args, torch.bfloat16)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_torch_fp32(self):
for op_with_args in self.autocast_lists.torch_fp32:
op, args, maybe_kwargs = self.args_maybe_kwargs(op_with_args)
self._run_autocast_outofplace(op, args, torch.float32, add_kwargs=maybe_kwargs)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_torch_need_autocast_promote(self):
for op, args in self.autocast_lists.torch_need_autocast_promote:
self._run_autocast_outofplace(op, args, torch.float32)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_torch_expect_builtin_promote(self):
for op, args, out_type in self.autocast_lists.torch_expect_builtin_promote:
self._run_autocast_outofplace(op, args, torch.float32, out_type=out_type)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_nn_fp16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op, args in self.autocast_lists.nn_fp16:
self._run_autocast_outofplace(op, args, torch.float16, module=torch._C._nn)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_nn_bf16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op, args in self.autocast_lists.nn_fp16:
if torch.cuda.is_bf16_supported():
self._run_autocast_outofplace(op, args, torch.bfloat16, module=torch._C._nn)
else:
with self.assertRaisesRegex(RuntimeError, 'Device does not support bfloat16'):
self._run_autocast_outofplace(op, args, torch.bfloat16, module=torch._C._nn)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_nn_fp32(self):
for op, args in self.autocast_lists.nn_fp32:
self._run_autocast_outofplace(op, args, torch.float32, module=torch._C._nn)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_linalg_fp16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op, args in self.autocast_lists.linalg_fp16:
self._run_autocast_outofplace(op, args, torch.float16, module=torch._C._linalg)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_methods_fp16(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
for op, args in self.autocast_lists.methods_fp16:
self._run_autocast_outofplace(op, args, torch.float16, module=None)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_methods_fp32(self):
for op, args in self.autocast_lists.methods_fp32:
self._run_autocast_outofplace(op, args, torch.float32, module=None)
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_methods_expect_builtin_promote(self):
for op, args, out_type in self.autocast_lists.methods_expect_builtin_promote:
self._run_autocast_outofplace(op, args, torch.float32, module=None, out_type=out_type)
def test_autocast_banned(self):
with torch.autocast('cuda'):
for op, args, module in self.autocast_lists.banned:
with self.assertRaises(RuntimeError):
getattr(module, op)(*args)
def test_autocast_ignored_types(self):
with torch.autocast('cuda'):
for ignore_type in (torch.double, torch.int32):
a_ignore = torch.ones((8, 8), dtype=ignore_type, device="cuda:0")
b_ignore = torch.ones((8, 8), dtype=ignore_type, device="cuda:0")
c_16 = torch.ones((8, 8), dtype=torch.float16, device="cuda:0")
# Tests if CastPolicy::fp16 ops ignore double and int
# Currently, no ops belonging to this policy support integer inputs.
if ignore_type is torch.double:
with self.assertRaises(RuntimeError):
torch.mm(a_ignore, c_16)
with torch.autocast('cuda', enabled=False):
type_no_autocast = torch.mm(a_ignore, b_ignore).dtype
self.assertTrue(torch.mm(a_ignore, b_ignore).dtype is type_no_autocast)
# Tests if CastPolicy::fp32 ops ignore double and int
with torch.autocast('cuda', enabled=False):
type_no_autocast = torch.pow(a_ignore, 2.0).dtype
self.assertTrue(torch.pow(a_ignore, 2.0).dtype is type_no_autocast)
# Tests if CastPolicy::fp32_set_opt_dtype ops ignore double and int
with torch.autocast('cuda', enabled=False):
type_no_autocast = torch.sum(a_ignore).dtype
self.assertTrue(torch.sum(a_ignore).dtype is type_no_autocast)
# Tests if CastPolicy::fp32_append_dtype ops ignore double and int
# Currently, no ops belonging to this policy support integer inputs.
if ignore_type is torch.double:
with torch.autocast('cuda', enabled=False):
type_no_autocast = torch.norm(a_ignore).dtype
self.assertTrue(torch.norm(a_ignore).dtype is type_no_autocast)
def test_autocast_custom_enabled(self):
class MyMM(torch.autograd.Function):
@staticmethod
@torch.cuda.amp.custom_fwd
def forward(ctx, a, b):
self.assertTrue(a.dtype is torch.float32)
self.assertTrue(b.dtype is torch.float32)
self.assertTrue(torch.is_autocast_enabled())
ctx.save_for_backward(a, b)
return a.mm(b)
@staticmethod
@torch.cuda.amp.custom_bwd
def backward(ctx, grad):
self.assertTrue(torch.is_autocast_enabled())
a, b = ctx.saved_tensors
a_grad, b_grad = grad.mm(b.t()), a.t().mm(grad)
self.assertTrue(a_grad.dtype is dtype and b_grad.dtype is dtype)
return a_grad, b_grad
mymm = MyMM.apply
x = torch.randn((8, 8), device="cuda", dtype=torch.float32, requires_grad=True)
y = torch.randn((8, 8), device="cuda", dtype=torch.float32, requires_grad=True)
dtypes = (torch.float16, torch.bfloat16) if TEST_BF16 else (torch.float16,)
for dtype in dtypes:
with torch.cuda.amp.autocast(dtype=dtype):
output = mymm(x, y)
self.assertTrue(output.dtype is dtype)
loss = output.sum()
loss.backward()
def test_autocast_custom_cast_inputs(self):
class MyMM(torch.autograd.Function):
@staticmethod
@torch.cuda.amp.custom_fwd(cast_inputs=torch.float32)
def forward(ctx, a, container, expect_type):
b = container[1][0]
self.assertTrue(a.dtype is expect_type)
self.assertTrue(b.dtype is expect_type)
self.assertFalse(torch.is_autocast_enabled())
ctx.save_for_backward(a, b)
return a.mm(b)
@staticmethod
@torch.cuda.amp.custom_bwd
def backward(ctx, grad):
self.assertFalse(torch.is_autocast_enabled())
a, b = ctx.saved_tensors
return grad.mm(b.t()), None, None
mymm = MyMM.apply
x = torch.randn((8, 8), device="cuda", dtype=torch.float16, requires_grad=True)
# Puts one input tensor in a nested container. y's contained Tensor won't receive a gradient,
# because torch.autograd.Function can't hand gradients back to non-Tensor forward arguments.
# Sets requires_grad=False explicitly so we don't lie about expecting a gradient.
y = (0, {0: torch.randn((8, 8), device="cuda", dtype=torch.float16, requires_grad=False)})
with torch.autocast('cuda', ):
output = mymm(x, y, torch.float32)
self.assertTrue(output.dtype is torch.float32)
loss = output.sum()
loss.backward()
# Tests if custom_fwd becomes a no-op when mymm runs outside an autocast-enabled region.
output = mymm(x, y, torch.float16)
self.assertTrue(output.dtype is torch.float16)
loss = output.sum()
loss.backward()
def test_autocast_cat_jit(self):
# Reported at https://github.com/pytorch/pytorch/issues/38958
class Model(torch.nn.Module):
def forward(self):
a = torch.randn(1)
b = torch.randn(1)
c = torch.cat((a, b), 0)
d = torch.stack([c, c], 0)
return d
# The JIT here doesn't really matter, we just need to call
# cat via the boxed API
model = Model()
model_jit_script = torch.jit.script(model)
with torch.autocast('cuda', enabled=True):
model()
model_jit_script()
# cudnn RNNs require special backend handling (weights are cast to FP16 and reflattened)
# so they get a dedicated test.
# Despite the large number of RNN cases it tries, the test takes < 15 seconds on a Titan V (similar to V100).
@skipIfRocm
@unittest.skipIf(not TEST_CUDNN, 'CUDNN not available')
def test_autocast_rnn(self):
with torch.backends.cudnn.flags(enabled=True, deterministic=True):
# seq, batch, features, hidden size
clses = ("RNN", "GRU", "LSTM")
T, B, F, H = 3, 4, 5, 6
dtypes = (torch.float16, torch.float32)
input_layouts = ("seq_first", "batch_first", "packed")
for (cls, num_layers, bias, input_layout, bidirectional, try_nonpreflattened_weights,
input_dtype, hidden_dtype, weight_dtype) in \
product(clses, (1, 2), (True, False), input_layouts, (True, False), (True, False),
dtypes, dtypes, dtypes):
if input_layout == "seq_first":
batch_first = False
x = torch.randn((T, B, F), device="cuda", dtype=input_dtype)
elif input_layout == "batch_first":
batch_first = True
x = torch.randn((B, T, F), device="cuda", dtype=input_dtype)
elif input_layout == "packed":
batch_first = False
x = torch.nn.utils.rnn.pack_padded_sequence(torch.randn((T, B, F),
device="cuda", dtype=input_dtype),
lengths=(3, 2, 1, 3),
enforce_sorted=False)
rnn = getattr(torch.nn, cls)(F, H, num_layers=num_layers, bidirectional=bidirectional,
bias=bias, batch_first=batch_first).cuda().to(dtype=weight_dtype)
if try_nonpreflattened_weights:
for p in rnn.parameters():
with torch.no_grad():
p.set_(p.clone())
h = torch.randn((num_layers * (2 if bidirectional else 1), B, H),
device="cuda", dtype=hidden_dtype)
if cls == "LSTM":
c = torch.randn((num_layers * (2 if bidirectional else 1), B, H),
device="cuda", dtype=hidden_dtype)
h = (h, c)
with torch.autocast('cuda', ):
out, h_out = rnn(x, h)
out = out.data if input_layout == "packed" else out
self.assertEqual(out.dtype, torch.float16)
# Autocast wrapper requires at::_cudnn_rnn is autograd-exposed. This check can't guarantee
# at::_cudnn_rnn is autograd-exposed, but if it fires, it indicates some funny business has
# occurred and we should double check that at::_cudnn_rnn remains autograd-exposed.
self.assertEqual(out.grad_fn.name(), "CudnnRnnBackward0")
out.sum().backward()
grads = [p.grad.clone() for p in rnn.parameters()]
rnn.zero_grad()
if cls == "LSTM":
out_control, h_out_control = rnn.to(dtype=torch.float16)(x.half(), (h[0].half(), h[1].half()))
else:
out_control, h_out_control = rnn.to(dtype=torch.float16)(x.half(), h.half())
out_control = out_control.data if input_layout == "packed" else out_control
out_control.sum().backward()
grads_control = [p.grad.clone() for p in rnn.parameters()]
# Compares with default tolerances, even for FP16 execution. Barring nondeterminism,
# autocast and control results should be bitwise identical.
self.assertEqual(out, out_control)
if cls == "LSTM":
self.assertTrue(h_out[0].dtype is torch.float16 and h_out[1].dtype is torch.float16)
self.assertEqual(h_out[0], h_out_control[0])
self.assertEqual(h_out[1], h_out_control[1])
else:
self.assertEqual(h_out.dtype, torch.float16)
self.assertEqual(h_out, h_out_control)
for grad, grad_control in zip(grads, grads_control):
self.assertEqual(grad.half(), grad_control)
def test_autocast_cache_leak(self):
# Reported at https://github.com/pytorch/pytorch/issues/48049
# Test is used to check, if autocast recaches the same parameters
# when executed in a `torch.no_grad()` block.
linear = torch.nn.Linear(10, 10).to('cuda')
data = torch.randn(1, 10, device='cuda')
with torch.autocast('cuda', ):
with torch.no_grad():
out = linear(data)
first_iter_mem = torch.cuda.memory_allocated()
for _ in range(3):
out = linear(data)
self.assertTrue(first_iter_mem == torch.cuda.memory_allocated())
def test_autocast_checkpointing(self):
model = torch.nn.Sequential(torch.nn.Linear(8, 8),
torch.nn.Linear(8, 8),
torch.nn.Linear(8, 8)).cuda()
input = torch.rand((8, 8), device="cuda", dtype=torch.float16, requires_grad=True)
with torch.autocast('cuda', ):
output = checkpoint_sequential(model, 2, input)
self.assertTrue(output.requires_grad)
self.assertTrue(output.dtype is torch.float16)
output.sum().backward()
@slowTest
@unittest.skipIf(not TEST_LARGE_TENSOR, "not enough memory")
def test_max_large_axis(self):
x = torch.zeros(2**32, device='cuda', dtype=torch.int8)
x[-1] = 1
val, idx = x.max(0)
self.assertEqual(val, 1)
self.assertEqual(idx, x.shape[0] - 1)
@unittest.skipIf(not TEST_NUMPY, "Numpy not found")
def test_to_numpy(self):
self.assertRaises(TypeError, lambda: torch.empty(1, device="cuda").numpy())
def test_graph_is_current_stream_capturing(self):
self.assertFalse(torch.cuda.is_current_stream_capturing())
if (TEST_CUDA and (not TEST_WITH_ROCM) and int(torch.version.cuda.split(".")[0]) >= 11):
s = torch.cuda.Stream()
with torch.cuda.stream(s):
g = torch.cuda.CUDAGraph()
self.assertFalse(torch.cuda.is_current_stream_capturing())
g.capture_begin()
self.assertTrue(torch.cuda.is_current_stream_capturing())
g.capture_end()
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_capture_simple(self):
s = torch.cuda.Stream()
with torch.cuda.stream(s):
a = torch.full((1000,), 1, device="cuda")
g = torch.cuda.CUDAGraph()
torch.cuda.empty_cache()
g.capture_begin()
b = a
for _ in range(10):
b = b + 1
g.capture_end()
torch.cuda.current_stream().wait_stream(s)
g.replay()
self.assertTrue(b.sum().item() == 11000.)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_error(self):
# We need to run this test in a separate thread as the error we trigger
# puts the cuda context in a bad state
script = """
import torch
g = torch.cuda.CUDAGraph()
try:
g.capture_begin()
except RuntimeError as e:
if "CUDA graphs must be captured on a non-default stream." in str(e):
exit(0)
else:
exit(1)
exit(2)
"""
try:
a = subprocess.check_output(
[sys.executable, '-c', script],
stderr=subprocess.STDOUT,
# On Windows, opening the subprocess with the default CWD makes `import torch`
# fail, so just set CWD to this script's directory
cwd=os.path.dirname(os.path.realpath(__file__)),)
except subprocess.CalledProcessError as e:
if e.returncode == 1:
self.assertTrue(False, "Error raise by starting capture without a stream is not the expected one")
elif e.returncode == 2:
self.assertTrue(False, "Error raised by starting capture without a stream was not caught")
@unittest.skipIf((not TEST_CUDA) or
TEST_WITH_ROCM or
int(torch.version.cuda.split(".")[0]) < 11, "CUDA >= 11.0 required for graphs")
def test_graph_warn_if_has_zero_nodes(self):
with warnings.catch_warnings(record=True) as caught:
g = torch.cuda.CUDAGraph()
s = torch.cuda.Stream()
with torch.cuda.stream(s):
g.capture_begin()
g.capture_end()
self.assertTrue(any("The CUDA Graph is empty" in str(w.message) for w in caught))
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_capture_oom(self):
oom_regex = "would exceed allowed memory" if TEST_CUDAMALLOCASYNC else \
"out of memory"
with self.assertRaisesRegex(RuntimeError, oom_regex):
with torch.cuda.graph(torch.cuda.CUDAGraph()):
torch.zeros(2 ** 40, device="cuda")
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_repeat_graph_capture_cublas_workspace_memory(self):
(x, y, z) = 1024, 512, 64
a = torch.rand((x, y), device='cuda')
b = torch.rand((y, z), device='cuda')
# warmup
torch.mm(a, b)
free_bytes_before, total_bytes = torch.cuda.mem_get_info()
used_gb_before = (total_bytes - free_bytes_before) / 1e9
for i in range(100):
torch_graph = torch.cuda.CUDAGraph()
with torch.cuda.graph(torch_graph):
torch.mm(a, b)
torch_graph.replay()
free_bytes_after, _ = torch.cuda.mem_get_info()
used_gb_after = (total_bytes - free_bytes_after) / 1e9
self.assertFalse(used_gb_before + 0.1 < used_gb_after)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_rng_functional(self):
ops_with_kwargs = ((torch.nn.functional.dropout, {"p": 0.1}),
(torch.nn.functional.rrelu, {"training": True}),)
size = 10000
def run(op, kwargs):
a = torch.randn((size,), device="cuda", dtype=torch.float)
# Control
torch.cuda.manual_seed(5)
eager_out = a
for _ in range(6):
eager_out = op(eager_out, **kwargs)
graph_in = a.clone()
stream = torch.cuda.Stream()
stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(stream):
torch.cuda.manual_seed(5)
g = torch.cuda.CUDAGraph()
torch.cuda.empty_cache()
g.capture_begin()
graph_out = graph_in
for _ in range(2):
graph_out = op(graph_out, **kwargs)
g.capture_end()
torch.cuda.current_stream().wait_stream(stream)
# Runs a graphed->eager->graphed sequence of RNG ops.
# replay() plays 2 invocations of the op, so the sequence has 6
# invocations total, matching Control.
# replay() reads from graph_in and writes to graph_out.
g.replay()
out = op(graph_out, **kwargs)
out = op(out, **kwargs)
graph_in.copy_(out)
g.replay()
# If replay() updated RNG state correctly, graph_out
# should now hold data equal to eager_out.
try:
self.assertEqual(eager_out, graph_out)
except Exception as e:
raise RuntimeError("Failed on ", op) from e
# Do the same operations varying seeds
seeds = [6, 128, 9999]
for seed in seeds:
torch.cuda.manual_seed(seed)
graph_in.copy_(a)
for _ in range(3):
g.replay()
# If the random seed was not updated then the graph would
# generate the same output as in previous check.
try:
self.assertNotEqual(eager_out, graph_out)
except Exception as e:
raise RuntimeError("Failed on ", op) from e
# Now repeat the same operations in non-graphed mode.
torch.cuda.manual_seed(seed)
for _ in range(3):
eager_out.copy_(a)
eager_out = op(eager_out, **kwargs)
eager_out = op(eager_out, **kwargs)
# In the end, graph_out and eager_out must be equal
# as they went under the same set of operations.
try:
self.assertEqual(eager_out, graph_out)
except Exception as e:
raise RuntimeError("Failed on ", op) from e
# We hold references to all tensors used across streams up til this sync,
# so no need to call record_stream on those tensors.
torch.cuda.synchronize()
for op, kwargs in ops_with_kwargs:
run(op, kwargs)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_rng_distributions(self):
size = 10000
input = torch.rand((size,), device="cuda", dtype=torch.float)
alloc = torch.empty((size,), device="cuda", dtype=torch.float)
# Torch ops to test with sample args (tuple) and kwargs (dict)
torch_with_args = (("bernoulli", (input.clone(),), {}),
# multinomial uses some uncapturable CUDA calls.
# TODO: reenable multinomial tests if/when the implementation is capturable.
# ("multinomial", (input.clone(), size, True), {}),
# ("multinomial", (input.clone(), size // 2, False), {}),
# TODO: reenable normal test, where std is a device
# tensor, when graph test failures are fixed
# ("normal", (input.clone() + 1, input.clone()), {}),
("normal", (input.clone() + 1, 1.0), {}),
("poisson", (input.clone(),), {}),
("rand", (size,), {"device": "cuda", "dtype": torch.float}),
("randint", (0, 3, (size,)), {"device": "cuda", "dtype": torch.float}),
("randn", (size,), {"device": "cuda", "dtype": torch.float}),)
# Tensor methods to test with sample args (tuple)
tensor_with_args = (("bernoulli_", (input.clone(),)),
("cauchy_", ()),
("exponential_", ()),
("geometric_", (0.3,)),
("log_normal_", ()),
("normal_", ()),
("random_", ()),
("uniform_", ()),)
def run(module, op, args, kwargs):
torch.cuda.manual_seed(5)
# Each path runs a dummy op to increment the state a bit before creating controls.
if (module == "torch"):
dummy = getattr(torch, op)(*args, **kwargs)
control1 = getattr(torch, op)(*args, **kwargs)
control2 = getattr(torch, op)(*args, **kwargs)
else:
dummy = alloc.clone()
control1 = alloc.clone()
control2 = alloc.clone()
getattr(dummy, op)(*args)
getattr(control1, op)(*args)
getattr(control2, op)(*args)
stream = torch.cuda.Stream()
stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(stream):
torch.cuda.manual_seed(5)
g = torch.cuda.CUDAGraph()
torch.cuda.empty_cache()
if (module == "torch"):
g.capture_begin()
t1 = getattr(torch, op)(*args, **kwargs)
t2 = getattr(torch, op)(*args, **kwargs)
g.capture_end()
else:
t1 = alloc.clone()
t2 = alloc.clone()
g.capture_begin()
getattr(t1, op)(*args)
getattr(t2, op)(*args)
g.capture_end()
torch.cuda.current_stream().wait_stream(stream)
if not TEST_CUDAMALLOCASYNC:
# Makes sure values haven't been populated yet
# (in other words, makes sure capture didn't actually run ops).
# We can only try this with the native allocator, for which captured
# addresses are already backed by cudaMalloced memory.
# If we try it with cudaMallocAsync, CUDA won't event consider
# the captured addresses allocated until replay(), and if we
# access them before replay() we get IMAs.
try:
self.assertNotEqual(control1, t1)
self.assertNotEqual(control2, t2)
except Exception as e:
raise RuntimeError("Failed on " + module + "." + op) from e
# Set a new seed to check if graph would use it
for seed in [6, 314, 271]:
torch.cuda.manual_seed(seed)
# Runs a dummy op prelude, as for controls, to make sure replay()
# picks up the dummy op's state increment.
if (module == "torch"):
dummy = getattr(torch, op)(*args, **kwargs)
control1 = getattr(torch, op)(*args, **kwargs)
control2 = getattr(torch, op)(*args, **kwargs)
else:
getattr(dummy, op)(*args)
getattr(control1, op)(*args)
getattr(control2, op)(*args)
torch.cuda.manual_seed(seed)
if (module == "torch"):
dummy = getattr(torch, op)(*args, **kwargs)
else:
getattr(dummy, op)(*args)
# see above comment on TEST_CUDAMALLOCASYNC
if not TEST_CUDAMALLOCASYNC:
t1.copy_(alloc)
t2.copy_(alloc)
# Runs RNG ops that fill t1 and t2.
g.replay()
try:
self.assertEqual(control1, t1)
self.assertEqual(control2, t2)
except Exception as e:
raise RuntimeError("Failed on " + module + "." + op) from e
# We hold references to all tensors used across streams up til this sync,
# so no need to call record_stream on those tensors.
torch.cuda.synchronize()
for op_with_args in torch_with_args:
run("torch", *op_with_args)
for meth_with_args in tensor_with_args:
# Adds an empty dict for kwargs, which none of the Tensor methods use
run("Tensor", *(meth_with_args + ({},)))
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_two_successive(self):
torch.cuda.empty_cache()
size = 1000
kSmallBuffer = 2097152
def func_with_temps(t, val):
x = t.clone() + val
y = t.clone() + val
return x + y
s = torch.cuda.Stream()
for share_mem in ("Don't share", "via pool()", "via graph_pool_handle()"):
g0 = torch.cuda.CUDAGraph()
g1 = torch.cuda.CUDAGraph()
a = torch.ones((size,), device="cuda")
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
g0_args = (torch.cuda.graph_pool_handle(),) if share_mem == "via graph_pool_handle()" else ()
g0.capture_begin(*g0_args)
b = a.clone()
for _ in range(5):
b = func_with_temps(b, 1)
g0.capture_end()
g1_args = (g0.pool(),) if share_mem == "via pool()" else g0_args
g1.capture_begin(*g1_args)
for _ in range(5):
b = func_with_temps(b, 1)
g1.capture_end()
torch.cuda.current_stream().wait_stream(s)
# mixes unrelated eager ops with replays
c = a.clone()
for _ in range(2):
c = func_with_temps(c, 3)
g0.replay()
for _ in range(2):
c = func_with_temps(c, 3)
g1.replay()
for _ in range(2):
c = func_with_temps(c, 3)
self.assertEqual(b.sum().item(), size * 3070)
self.assertEqual(c.sum().item(), size * 442)
if not TEST_CUDAMALLOCASYNC:
# These stat checks are specific to the native allocator.
if share_mem != "Don't share":
self.assertEqual(reserved_no_sharing - torch.cuda.memory_stats()["reserved_bytes.all.current"],
kSmallBuffer)
else:
reserved_no_sharing = torch.cuda.memory_stats()["reserved_bytes.all.current"]
del a, b, c, g0, g1
# Tensors used across streams (a and b) were held until just now, so no need to call record_stream on them.
torch.cuda.synchronize()
torch.cuda.empty_cache()
@unittest.skipIf((not TEST_GRAPH) or
IS_WINDOWS or # appears to still be broken on Windows as of 11.4+
(torch.version.cuda and
int(torch.version.cuda.split(".")[0]) == 11 and
int(torch.version.cuda.split(".")[1]) < 4),
"Graph bindings disallow concurrent replay for CUDA < 11.4, see " +
"https://github.com/pytorch/pytorch/pull/57556")
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_concurrent_replay(self):
torch.cuda.empty_cache()
size = 1000000 # largeish to help expose race conditions
def func_with_temps(t, val):
x = t.clone() + val
y = t.clone() + val
return x + y
s = torch.cuda.Stream()
for share_mem in ("Don't share", "via pool()", "via graph_pool_handle()"):
g0 = torch.cuda.CUDAGraph()
g1 = torch.cuda.CUDAGraph()
s0 = torch.cuda.Stream()
s1 = torch.cuda.Stream()
a = torch.ones((size,), device="cuda")
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
g0_args = (torch.cuda.graph_pool_handle(),) if share_mem == "via graph_pool_handle()" else ()
g0.capture_begin(*g0_args)
b = a.clone()
for _ in range(5):
b = func_with_temps(b, 1)
g0.capture_end()
g1_args = (g0.pool(),) if share_mem == "via pool()" else g0_args
g1.capture_begin(*g1_args)
c = a.clone()
for _ in range(5):
c = func_with_temps(c, 2)
g1.capture_end()
# To reproduce data corruption, I need g0 and g1's kernels to run concurrently.
# But replay() (especially cudaGraphLaunch) can incur significant CPU overhead.
# The following pattern helps align device-side execution of g0 and g1's kernels.
torch.cuda.synchronize()
with torch.cuda.stream(s0):
torch.cuda._sleep(1000000)
s1.wait_stream(s0)
g0.replay()
with torch.cuda.stream(s1):
g1.replay()
torch.cuda.current_stream().wait_stream(s0)
torch.cuda.current_stream().wait_stream(s1)
if (not TEST_CUDAMALLOCASYNC) and (share_mem != "Don't share"):
# If we used the native allocator and shared mempools,
# we expect the concurrent replays corrupted each other.
self.assertNotEqual(b.sum().item(), size * 94)
self.assertNotEqual(c.sum().item(), size * 156)
else:
# If we EITHER
# - used the native allocator without sharing mempools, OR
# - used cudaMallocAsync, which ignores graph pool-sharing hints and should always be safe
# we don't expect memory corruption.
self.assertEqual(b.sum().item(), size * 94)
self.assertEqual(c.sum().item(), size * 156)
del a, b, c, g0, g1
# Tensors used across streams (a, b, c) were held until just now, so no need to call record_stream on them.
torch.cuda.synchronize()
torch.cuda.empty_cache()
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_three_successive(self):
torch.cuda.empty_cache()
size = 1000
s = torch.cuda.Stream()
for share_mem in ("Don't share", "via pool()", "via graph_pool_handle()"):
a = torch.ones((size,), device="cuda")
g0 = torch.cuda.CUDAGraph()
g1 = torch.cuda.CUDAGraph()
g2 = torch.cuda.CUDAGraph()
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
g0_args = (torch.cuda.graph_pool_handle(),) if share_mem == "via graph_pool_handle()" else ()
g0.capture_begin(*g0_args)
b = a.clone()
c = b + 1
d = b + 2
g0.capture_end()
args = (g0.pool(),) if share_mem == "via pool()" else g0_args
g1.capture_begin(*args)
e = c + 3
del c
g1.capture_end()
g2.capture_begin(*args)
f = d + 4
g2.capture_end()
torch.cuda.current_stream().wait_stream(s)
# Tests that replaying in capture order is valid
g0.replay()
g1.replay()
g2.replay()
self.assertEqual(e.sum().item(), size * 5)
self.assertEqual(f.sum().item(), size * 7)
# Tests that replaying as g0, g2, g1 is only valid if they don't share a pool
g0.replay()
g2.replay()
g1.replay()
expect_corruption = (not TEST_CUDAMALLOCASYNC) and (share_mem != "Don't share")
# If we used the native allocator and shared mempools, g2's capture should have reused c's memory for f.
# We replayed g2 then g1, so we expect g1's captured "e = c + 3" mistakenly filled e with "f's vals + 3".
self.assertEqual(e.sum().item(), size * (7 + 3) if expect_corruption else size * 5)
self.assertEqual(f.sum().item(), size * 7)
del a, b, d, e, f, g0, g1, g2
# Tensors used across streams (a, e, f) were held until just now, so no need to call record_stream on them.
torch.cuda.synchronize()
torch.cuda.empty_cache()
@unittest.skipIf((not TEST_GRAPH) or
TEST_CUDAMALLOCASYNC , "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_memory_stats_and_use_result_after_destroy_graph(self):
kSmallSize = 1048576
kSmallBuffer = 2097152
kLargeBuffer = 20971520
kMinLargeAlloc = 10485760
kRoundLarge = 2097152
elem = 4
# this was annoying to write but stresses the expectations pretty rigorously
cases = ((512 // elem, 1, kSmallBuffer, kSmallBuffer, "small_pool"),
(kSmallSize // elem, 2, 2 * kSmallBuffer, kSmallBuffer, "small_pool"),
((kSmallSize + 512) // elem, 1, kLargeBuffer, kLargeBuffer, "large_pool"),
((kMinLargeAlloc - 512) // elem, 2, 2 * kLargeBuffer, kLargeBuffer, "large_pool"),
((kMinLargeAlloc + 512) // elem, 3,
3 * (kRoundLarge * ((kMinLargeAlloc + 512 + kRoundLarge - 1) // kRoundLarge)),
kRoundLarge * ((kMinLargeAlloc + 512 + kRoundLarge - 1) // kRoundLarge),
"large_pool"),)
stats_to_check = ("segment.",
"reserved_bytes.",
"active.",
"active_bytes.")
gc.collect()
torch.cuda.empty_cache()
s = torch.cuda.Stream()
for (numel,
delta_cudaMallocs,
delta_cudaMalloc_bytes,
delta_cudaMalloc_bytes_post_del_g,
pool_string) in cases:
if pool_string == "small_pool":
delta_active_blocks = 3 # one from "b" plus a sneaky two from CUDAGraph's one-element rng seed and offset holders
delta_active_bytes = numel * elem + 1024 # + 1024 for CUDAGraph's rng seed and offset holders each
else:
delta_active_blocks = 1 # We only check the large pool, which isn't affected by rng offset holder
delta_active_bytes = numel * elem
g = torch.cuda.CUDAGraph()
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
# Allocation stat estimates assume input is created on the same stream as capture_begin()
# (in other words, the same stream silo as the rng offset holder, which is not allocated from the
# capture's private pool).
a = torch.ones((numel,), device="cuda")
precapture_stats = torch.cuda.memory_stats()
g.capture_begin()
b = a.clone()
for _ in range(5):
b = b.clone() + 1
g.capture_end()
torch.cuda.current_stream().wait_stream(s)
gc.collect()
postcapture_stats = torch.cuda.memory_stats()
expecteds = (delta_cudaMallocs,
delta_cudaMalloc_bytes,
delta_active_blocks,
delta_active_bytes)
# Double checks replay and stats before and after a call to empty_cache
for i in range(2):
for stat, expected in zip(stats_to_check, expecteds):
stat = stat + pool_string + ".current"
current = postcapture_stats[stat] - precapture_stats[stat]
self.assertEqual(current, expected, "Pre to post capture delta of " +
stat + " = {}, expected = {}, numel = {}".format(current, expected, numel))
g.replay()
self.assertEqual(b.sum().item(), 6 * numel)
if i == 0:
torch.cuda.empty_cache()
del g
gc.collect()
torch.cuda.empty_cache()
postdel_stats = torch.cuda.memory_stats()
# Uses graph result b after graph has been deleted
self.assertEqual(b.sum().item(), 6 * numel)
# b should be the only live reference remaining from the graph's private pool
expecteds = (1, delta_cudaMalloc_bytes_post_del_g, 1, numel * elem)
for stat, expected in zip(stats_to_check, expecteds):
stat = stat + pool_string + ".current"
current = postdel_stats[stat] - precapture_stats[stat]
self.assertEqual(current, expected, "Pre capture to post graph delete delta of " +
stat + " = {}, expected = {}, numel = {}".format(current, expected, numel))
# del a, b before the next case is essential, otherwise overwriting a and b in the next case
# can throw off its allocation/deallocation counts.
del a, b
# Tensors used across streams (a and b) were held until just now, so no need to call record_stream on them.
torch.cuda.synchronize()
torch.cuda.empty_cache()
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_record_stream(self):
# Makes sure graph capture defers attempting to reclaim allocations used across streams. See
# "Q. Why skip process_events if a capture might be underway?" in c10/cuda/CUDACachingAllocator.cpp
torch.cuda.empty_cache()
potential_problem = torch.zeros((3,), device="cuda")
a = torch.zeros((3,), device="cuda")
s0 = torch.cuda.Stream()
s1 = torch.cuda.Stream()
s2 = torch.cuda.Stream()
g = torch.cuda.CUDAGraph()
torch.cuda.synchronize()
with torch.cuda.stream(s0):
potential_problem.record_stream(s0)
torch.cuda._sleep(TestCuda.FIFTY_MIL_CYCLES)
potential_problem.fill_(1.)
del potential_problem
with torch.cuda.stream(s1):
g.capture_begin()
# potential_problem's allocation should still be outstanding. if DeviceCachingAllocator::malloc
# mistakenly calls process_events, it will trigger cudaEventQueries on potential_problem's end-of-life
# event, which will cause the capture to error.
b = a.clone()
# Let's also see what happens if we record_stream on a tensor during capture.
s2.wait_stream(s1)
with torch.cuda.stream(s2):
b.fill_(1.)
b.record_stream(s2) # dummy record_stream
del b
s1.wait_stream(s2)
g.capture_end()
torch.cuda.synchronize()
# dummy allocation triggers process_events, Hopefully successfully processes b's end-of-life event.
c = torch.zeros((3,), device="cuda")
@skipIfRocm
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
# If this test is the first in the process to try cudnn rnns with dropout, it'll initialize
# DropoutState's long-lived internal buffer. Calling code perceives this (correct) behavior
# as a memory leak unless we skip the leak check.
@skipCUDAMemoryLeakCheckIf(True)
def test_graph_cudnn_dropout(self):
# Tests the interaction of cuda graph capture with DropoutState's syncs in ATen/native/cudnn/RNN.cpp.
# In particular, if user runs a sequence of captured and noncaptured cudnn rnns, DropoutState should
# avoid syncing noncapturing streams with captured events or vice versa.
torch.cuda.empty_cache()
model = torch.nn.LSTM(512, 512, 2, dropout=0.5).cuda()
x = torch.ones(100, 192, 512, device="cuda")
y = model(x)
g = torch.cuda.CUDAGraph()
s = torch.cuda.Stream()
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
g.capture_begin()
y = model(x)
g.capture_end()
torch.cuda.current_stream().wait_stream(s)
g.replay()
y = model(x)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_grad_scaling(self):
torch.cuda.empty_cache()
scaler = torch.cuda.amp.GradScaler(init_scale=4.)
g = torch.cuda.CUDAGraph()
s = torch.cuda.Stream()
weight = torch.ones((100,), device="cuda", requires_grad=True)
opt = torch.optim.SGD([weight], lr=0.1)
static_input = torch.ones_like(weight)
static_grad = torch.ones_like(weight)
# warmup
s = torch.cuda.Stream()
s.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(s):
loss = (weight.half() * static_input).sum()
scaler.scale(loss).backward()
torch.cuda.current_stream().wait_stream(s)
opt.zero_grad(set_to_none=True)
# capture
with torch.cuda.stream(s):
g.capture_begin()
loss = (weight.half() * static_input).sum()
scaler.scale(loss).backward()
g.capture_end()
input_vals = [5, 20000, 5, 40000]
# If the scale gets updated properly, these are the scale, growth tracker,
# and grad values we expect.
expected_scales = [4, 2, 2, 1]
expected_growth_trackers = [1, 0, 1, 0]
expected_grad_vals = [5 * 4, float("inf"), 5 * 2, float("inf")]
for data, scale, growth_tracker, grad_val in zip(input_vals,
expected_scales,
expected_growth_trackers,
expected_grad_vals):
static_input.fill_(data)
g.replay()
self.assertEqual(weight.grad, torch.full_like(weight.grad, grad_val))
scaler.step(opt)
scaler.update()
self.assertEqual(scaler._scale, scale)
self.assertEqual(scaler._growth_tracker, growth_tracker)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
@parametrize(
"with_amp,cache_enabled,allow_unused_input",
[
subtest((False, False, True), decorators=[skipIfRocm]),
subtest((True, False, True), decorators=[skipIfRocm]),
subtest((True, True, True), decorators=[unittest.expectedFailure]),
subtest((False, False, False), decorators=[unittest.expectedFailure]),
],
name_fn=lambda x, y, z: "{}{}{}".format(
{True: "with_amp", False: "without_amp"}[x],
{True: "_cache_enabled", False: "_cache_disabled"}[y] if x else "",
{True: "_allow_unused_input", False: "_not_allow_unused_input"}[z],
),
)
def test_graph_make_graphed_callables(
self, with_amp, cache_enabled, allow_unused_input
):
torch.manual_seed(5)
torch.cuda.manual_seed(5)
N, D_in, H, D_out = 640, 4096, 2048, 1024
class MLP1(torch.nn.Module):
def __init__(self, D_in: int, H: int, D_out: int):
super().__init__()
self.net_1 = torch.nn.Sequential(
torch.nn.Linear(D_in, H), torch.nn.Dropout(p=0.1)
).cuda()
self.net_2 = torch.nn.Sequential(
torch.nn.Linear(H, D_out), torch.nn.Dropout(p=0.2)
).cuda()
def forward(self, input_dict: dict):
x = input_dict["x"]
return self.net_2(self.net_1(x))
class MLP2(torch.nn.Module):
def __init__(self, D_in: int, H: int, D_out: int):
super().__init__()
self.net_1 = torch.nn.Sequential(
torch.nn.Linear(D_in, H), torch.nn.Dropout(p=0.1)
).cuda()
self.net_2 = torch.nn.Sequential(
torch.nn.Linear(H, D_out), torch.nn.Dropout(p=0.2)
).cuda()
def forward(self, x):
return {"output": self.net_2(self.net_1(x))}
models = []
for _ in range(2):
model_section1 = MLP1(D_in, H, H).cuda()
model_section2 = MLP2(H, H, D_out).cuda()
models.append(torch.nn.Sequential(model_section1, model_section2))
model_graphed = models[0]
model_control = models[1]
model_graphed.load_state_dict(model_control.state_dict())
opt_graphed = torch.optim.SGD(model_graphed.parameters(), lr=0.1)
opt_control = torch.optim.SGD(model_control.parameters(), lr=0.1)
x = torch.randn(N, D_in, device="cuda")
h = torch.randn(N, H, device="cuda", requires_grad=True)
unused_input = torch.randn(N, H, device="cuda", requires_grad=True)
y_pred = torch.randn(N, D_out, device="cuda", requires_grad=True)
y = torch.randn(N, D_out, device="cuda")
loss_fn_control = torch.nn.functional.mse_loss
relu_control = torch.nn.functional.relu
# This is a good stress test. It graphs four callables: two Modules and two python functions.
with torch.cuda.amp.autocast(with_amp, cache_enabled=cache_enabled):
(
model_graphed[0],
model_graphed[1],
relu_graphed,
loss_fn_graphed,
) = torch.cuda.make_graphed_callables(
(model_graphed[0], model_graphed[1], relu_control, loss_fn_control),
(
({"x": x, "unused_input": unused_input},),
(h,),
(y_pred,),
(y_pred, y),
),
allow_unused_input=allow_unused_input,
)
real_inputs = [torch.rand_like(x) for _ in range(10)]
real_targets = [torch.rand_like(y) for _ in range(10)]
for m, opt, relu, loss_fn in zip(
(model_graphed, model_control),
(opt_graphed, opt_control),
(relu_graphed, relu_control),
(loss_fn_graphed, loss_fn_control),
):
# Resets RNC states before iterations for graphed and ungraphed models,
# so dropout math should be bitwise identical for both.
torch.manual_seed(5)
torch.cuda.manual_seed(5)
for data, target in zip(real_inputs, real_targets):
opt.zero_grad(set_to_none=True)
with torch.cuda.amp.autocast(with_amp, cache_enabled=cache_enabled):
y_pred = m({"x": data, "unused_input": unused_input})["output"]
y_pred = relu(y_pred)
loss = loss_fn(y_pred, target)
loss.backward()
opt.step()
for p, pc in zip(model_graphed.parameters(), model_control.parameters()):
self.assertEqual(p, pc)
# We graphed the models in training mode. Eval should still run ungraphed.
model_graphed.eval()
model_control.eval()
self.assertEqual(
model_graphed({"x": real_inputs[0]}), model_control({"x": real_inputs[0]})
)
def _test_graphed_optimizer(self, steps_warmup, steps_train, optimizer_ctor, kwargs):
for actually_do_graphs in (True, False):
params = [torch.randn((i + 5, i + 5), device="cuda") for i in range(2)]
params_control = [p.clone().requires_grad_() for p in params]
params_graphed = [p.clone().requires_grad_() for p in params]
grads = [[torch.randn_like(p) for p in params] for _ in range(steps_warmup + steps_train)]
# Control (capturable=False)
opt = optimizer_ctor(params_control, capturable=False, **kwargs)
for i in range(steps_warmup + steps_train):
for j, p in enumerate(params_control):
p.grad = grads[i][j]
opt.step()
# capturable=True
opt = optimizer_ctor(params_graphed, capturable=True, **kwargs)
for i in range(steps_warmup):
for j, p in enumerate(params_graphed):
p.grad = grads[i][j]
opt.step()
if actually_do_graphs:
g = torch.cuda.CUDAGraph()
with torch.cuda.graph(g):
opt.step()
for i in range(steps_train):
if actually_do_graphs:
for j, p in enumerate(params_graphed):
p.grad.copy_(grads[i + steps_warmup][j])
g.replay()
else:
# Passing capturable=True to the constructor and running without graphs should still be
# numerically correct, even if it's not ideal for performance.
for j, p in enumerate(params_graphed):
p.grad = grads[i + steps_warmup][j]
opt.step()
for p_control, p_graphed in zip(params_control, params_graphed):
self.assertEqual(p_control, p_graphed)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_adam_adamw(self):
# Needs generalization if we want to extend this test to non-Adam-like optimizers.
cases = [
(optimizer_ctor, {"lr": 0.1, "betas": (0.8, 0.7), "foreach": foreach, "amsgrad": amsgrad})
for optimizer_ctor, foreach, amsgrad in product(
(torch.optim.Adam, torch.optim.AdamW), (False, True), (False, True),)
] + [
(optimizer_ctor, {"lr": 0.1, "betas": (0.8, 0.7), "fused": True, "amsgrad": amsgrad})
for optimizer_ctor, amsgrad in product((torch.optim.Adam, torch.optim.AdamW), (False, True))
]
for optimizer_ctor, kwargs in cases:
with self.subTest(optimizer_ctor=optimizer_ctor, kwargs=kwargs):
self._test_graphed_optimizer(3, 2, optimizer_ctor, kwargs)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_adam_adamw_with_explicitly_capturable_param_groups(self):
# mimicking `_test_graphed_optimizer` maladroitly to pass two param_groups to optimizer.__init__
n_warmup, n_replay = 3, 2
for optimizer, second_param_group_capturable in product((torch.optim.Adam, torch.optim.AdamW), (True, False)):
ref_p1, param1 = [torch.nn.Parameter(torch.ones(1, device="cuda")) for _ in range(2)]
ref_p2, param2 = [torch.nn.Parameter(torch.ones(1, device="cuda")) for _ in range(2)]
grads1, grads2 = [[torch.randn_like(param1) for _ in range(n_warmup + n_replay)] for _ in range(2)]
ref_grads1, ref_grads2 = [[t.clone() for t in tensors] for tensors in (grads1, grads2)]
params = [
{"params": [param1], "capturable": True},
{"params": [param2], "capturable": second_param_group_capturable},
]
opt = optimizer(params)
opt_ = optimizer([
{"params": [ref_p1], "capturable": False},
{"params": [ref_p2], "capturable": False},
])
for i in range(n_warmup + n_replay):
ref_p1.grad = ref_grads1[i]
ref_p2.grad = ref_grads2[i]
opt_.step()
for i in range(n_warmup):
param1.grad = grads1[i]
param2.grad = grads2[i]
opt.step()
g = torch.cuda.CUDAGraph()
if not second_param_group_capturable:
with self.assertRaisesRegex(RuntimeError, "Attempting CUDA graph"):
with torch.cuda.graph(g):
opt.step()
else:
with torch.cuda.graph(g):
opt.step()
for i in range(n_replay):
param1.grad.copy_(grads1[n_warmup + i])
param2.grad.copy_(grads2[n_warmup + i])
g.replay()
self.assertEqual(ref_p1, param1)
self.assertEqual(ref_p2, param2)
@unittest.skipIf((not TEST_GRAPH), "CUDA >= 11.0 or ROCM >= 5.3 required for graphs")
def test_graph_scaling_fused_optimizers(self):
cases = [
(optimizer_ctor, {"lr": 0.1, "betas": (0.8, 0.7), "fused": True, "amsgrad": amsgrad})
for optimizer_ctor, amsgrad in product((torch.optim.Adam, torch.optim.AdamW), (False, True))
]
steps_warmup = 3
steps_train = 2
for OptClass, kwargs in cases:
for actually_do_graphs in (True, False):
params = [torch.randn((i + 5, i + 5), device="cuda") for i in range(2)]
params_control = [p.clone().requires_grad_() for p in params]
params_graphed = [p.clone().requires_grad_() for p in params]
# `GradScaler` in-place updates gradients thus it's necessary to duplicate gradients.
grads = [[torch.randn_like(p) for p in params] for _ in range(steps_warmup + steps_train)]
with torch.no_grad():
grads_control = [[g.clone() for g in gs] for gs in grads]
grads_graphed = [[g.clone() for g in gs] for gs in grads]
# Gradient Scaler
scaler_for_control = torch.cuda.amp.GradScaler(init_scale=128.0)
with torch.no_grad():
scaler_for_control._lazy_init_scale_growth_tracker(torch.device("cuda"))
scaler_for_graphed = torch.cuda.amp.GradScaler()
scaler_for_graphed.load_state_dict(scaler_for_control.state_dict())
with torch.no_grad():
scaler_for_graphed._lazy_init_scale_growth_tracker(torch.device("cuda"))
# Control (capturable=False)
opt = OptClass(params_control, capturable=False, **kwargs)
for i in range(steps_warmup + steps_train):
for j, p in enumerate(params_control):
p.grad = grads_control[i][j]
scaler_for_control.step(opt)
scaler_for_control.update()
# capturable=True
opt = OptClass(params_graphed, capturable=True, **kwargs)
for i in range(steps_warmup):
for j, p in enumerate(params_graphed):
p.grad = grads_graphed[i][j]
scaler_for_graphed.step(opt)
scaler_for_graphed.update()
if actually_do_graphs:
g = torch.cuda.CUDAGraph()
with torch.cuda.graph(g):
scaler_for_graphed.step(opt)
scaler_for_graphed.update()
for i in range(steps_train):
if actually_do_graphs:
for j, p in enumerate(params_graphed):
p.grad.copy_(grads_graphed[i + steps_warmup][j])
g.replay()
else:
# Passing capturable=True to the constructor and running without graphs should still be
# numerically correct, even if it's not ideal for performance.
for j, p in enumerate(params_graphed):
p.grad = grads_graphed[i + steps_warmup][j]
scaler_for_graphed.step(opt)
scaler_for_graphed.update()
for p_control, p_graphed in zip(params_control, params_graphed):
self.assertEqual(p_control, p_graphed)
def test_batch_norm_gather_stats(self):
input = torch.randn(1, 3, 3, 3, device='cuda')
mean, invstd = torch.batch_norm_gather_stats(
input, mean=torch.ones(2, 3, device='cuda'), invstd=torch.ones(2, 3, device='cuda'),
running_mean=None, running_var=None , momentum=.1, eps=1e-5, count=2
)
self.assertEqual(mean, torch.ones(3, device='cuda'))
self.assertEqual(invstd, torch.ones(3, device='cuda'))
@unittest.skipIf(not TEST_MULTIGPU, "Test needs multiple GPUs")
def test_cuda_device_memory_allocated(self):
from torch.cuda import memory_allocated
device_count = torch.cuda.device_count()
current_alloc = [memory_allocated(idx) for idx in range(device_count)]
x = torch.ones(10, device="cuda:0")
self.assertTrue(memory_allocated(0) > current_alloc[0])
self.assertTrue(all(memory_allocated(torch.cuda.device(idx)) == current_alloc[idx] for idx in range(1, device_count)))
def test_matmul_memory_use(self):
def get_max_used():
torch.cuda.synchronize()
val = torch.cuda.max_memory_allocated()
torch.cuda.reset_peak_memory_stats()
return val
a = torch.rand(1, 32, 32, device="cuda")
b = torch.rand(24, 32, 1, device="cuda")
get_max_used()
torch.matmul(a, b)
matmul_mem = get_max_used()
a = a.expand(24, 32, 32)
torch.matmul(a, b)
matmul_expand_mem = get_max_used()
torch.bmm(a, b)
bmm_mem = get_max_used()
self.assertEqual(matmul_expand_mem, matmul_mem)
self.assertEqual(bmm_mem, matmul_mem)
@unittest.skipIf(not TEST_WITH_ROCM, "ROCm-only test")
def test_rocm_backward_pass_guard(self):
# The test exercises a ROCm-specific feature.
class MyFunction(torch.autograd.Function):
@staticmethod
def forward(ctx, tensor, constant):
self.assertFalse(torch._C._rocm_is_backward_pass())
ctx.constant = constant
return tensor * constant
@staticmethod
def backward(ctx, grad_output):
self.assertTrue(torch._C._rocm_is_backward_pass())
return grad_output * ctx.constant, None
class MyModule(torch.nn.Module):
def __init__(self):
super().__init__()
self.a = torch.nn.Parameter(torch.randn(()))
def forward(self, x):
return MyFunction.apply(x, self.a)
model = MyModule()
criterion = torch.nn.MSELoss(reduction='sum')
optimizer = torch.optim.SGD(model.parameters(), lr=1e-6)
x = torch.randn(5, 5)
result = model(x)
loss = criterion(result, x)
optimizer.zero_grad()
loss.backward()
optimizer.step()
@unittest.skipIf(TEST_MULTIGPU, "Testing on one GPU is sufficient")
def test_lazy_init(self):
""" Validate that no CUDA calls are made during `import torch` call"""
from subprocess import check_output
VISIBLE_DEVICES = "HIP_VISIBLE_DEVICES" if TEST_WITH_ROCM else "CUDA_VISIBLE_DEVICES"
test_script = f"import os; import torch;os.environ['{VISIBLE_DEVICES}']='32';print(torch.cuda.device_count())"
rc = check_output([sys.executable, '-c', test_script]).decode("ascii").strip()
self.assertEqual(rc, "0")
class TestCudaComm(TestCase):
def _test_broadcast(self, input):
if not TEST_MULTIGPU:
raise unittest.SkipTest("only one GPU detected")
# test regular
results = comm.broadcast(input, (0, 1))
for i, t in enumerate(results):
self.assertEqual(t.get_device(), i)
self.assertEqual(t, input)
if input.is_cuda and input.get_device() == i: # test not copying on same device
self.assertEqual(t.data_ptr(), input.data_ptr())
# test out=
for inplace in [True, False]:
if inplace:
outputs = [torch.empty_like(input, device=0), torch.empty_like(input, device=1)]
else:
outputs = [input.cuda(0), torch.empty_like(input, device=1)]
results = comm.broadcast(input, out=outputs)
for r, o in zip(results, outputs):
self.assertIs(r, o)
for i, t in enumerate(results):
self.assertEqual(t.get_device(), i)
self.assertEqual(t, input)
# test error msg
with self.assertRaisesRegex(RuntimeError, r"Exactly one of 'devices' and 'out'"):
comm.broadcast(input, (0, 1), out=outputs)
with self.assertRaisesRegex(RuntimeError,
r"Expected all output tensors to be CUDA tensors, but output tensor at index 1"):
comm.broadcast(input, out=[input.cuda(0), input.cpu()])
with self.assertRaisesRegex(RuntimeError,
r"Expected all output tensors to have same shape as the source .+ at index 1"):
comm.broadcast(input, out=[input.cuda(0), input.cuda(1).unsqueeze(0)])
def test_broadcast_cpu(self):
self._test_broadcast(torch.randn(5, 5))
def test_broadcast_gpu(self):
self._test_broadcast(torch.randn(5, 5).cuda())
def _test_broadcast_coalesced(self, tensors, buffer_size):
b_tensors = [comm.broadcast(t, (0, 1)) for t in tensors]
for (_, bt), t in zip(b_tensors, tensors):
self.assertEqual(bt.get_device(), 1)
self.assertEqual(bt, t)
self.assertIsInstance(bt, type(t))
bc_tensors = comm.broadcast_coalesced(tensors, (0, 1), buffer_size=buffer_size)
bc_tensors_t = list(zip(*bc_tensors))
self.assertEqual(b_tensors, bc_tensors_t)
for (_, bt), (_, bct) in zip(b_tensors, bc_tensors_t):
self.assertEqual(bt.get_device(), bct.get_device())
self.assertIsInstance(bct, type(bt))
# check that tensors on device[0] are returned as-is
for out_tensors in (b_tensors, bc_tensors_t):
for inp_t, (out_t, _) in zip(tensors, out_tensors):
self.assertIs(inp_t, out_t)
# check that the tensors not on device[0] have different version counters
# NOTE [ Version Counter in comm.*_coalesced ]
versions = [t._version for _, t in bc_tensors_t]
for old_version, (_, t) in zip(versions, bc_tensors_t):
self.assertEqual(t._version, old_version)
t.zero_()
self.assertEqual(t._version, old_version + 1)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
# Note: fails sometimes on the CI, passes on dual gfx906
def test_broadcast_coalesced(self):
numel = 5
num_bytes = numel * 8
tensors = [
self.genSparseTensor((2, 3), 2, 1, False, 'cuda', torch.float64)[0],
torch.randn(numel).long().cuda(),
torch.randn(numel).cuda(),
self.genSparseTensor((2, 3), 2, 10, False, 'cuda', torch.float64)[0],
self.genSparseTensor((2, 3), 2, 5, False, 'cuda', torch.float64)[0],
self.genSparseTensor((3, 3), 2, 7, False, 'cuda', torch.int64)[0],
self.genSparseTensor((2, 3), 2, 2, False, 'cuda', torch.float32)[0],
torch.randn(numel).long().cuda(),
torch.randn(numel).long().cuda(),
self.genSparseTensor((2, 7), 2, 3, False, 'cuda', torch.int64)[0],
torch.randn(numel * 2).int().cuda(), # int is 2x shorter
torch.randn(numel).cuda(),
]
self._test_broadcast_coalesced(tensors, num_bytes * 5 // 2)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_broadcast_coalesced_dense_only(self):
numel = 5
num_bytes = numel * 8
tensors = [
torch.randn(numel).long().cuda(),
torch.randn(numel).cuda(),
torch.randn(numel).long().cuda(),
torch.randn(numel).long().cuda(),
torch.randn(numel * 2).int().cuda(), # int is 2x shorter
torch.randn(numel).cuda(),
]
self._test_broadcast_coalesced(tensors, num_bytes * 5 // 2)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_broadcast_coalesced_empty_tensors(self):
tensors = [
torch.tensor([]).byte().cuda(),
torch.randn(5).cuda(),
torch.randn(5).double().cuda()
]
self._test_broadcast_coalesced(tensors, 256)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_reduce_add(self):
x = torch.randn(5, 5)
y = torch.randn(5, 5)
x_cuda = x.cuda(0)
y_cuda = y.cuda(1)
result = comm.reduce_add((x_cuda, y_cuda))
self.assertEqual(result.get_device(), 0)
self.assertEqual(result.cpu(), x + y)
def _test_reduce_add_coalesced(self, tensors, buffer_size):
dup_tensors = [tensors, [t.cuda(1) for t in tensors]]
r_tensors = [comm.reduce_add(t) for t in zip(*dup_tensors)]
for r, t in zip(r_tensors, tensors):
self.assertEqualTypeString(r, t)
self.assertEqual(r.coalesce() if r.is_sparse else r, t * 2)
rc_tensors = comm.reduce_add_coalesced(dup_tensors, buffer_size=buffer_size)
self.assertEqual(r_tensors, rc_tensors)
for r, rc in zip(r_tensors, rc_tensors):
self.assertEqualTypeString(rc, r)
# Since we have both cuda:0 and cuda:1 inputs, the outputs must be new.
# We can check that they have different version counters.
# NOTE [ Version Counter in comm.*_coalesced ]
versions = [t._version for t in rc_tensors]
for old_version, t in zip(versions, rc_tensors):
self.assertEqual(t._version, old_version)
t.zero_()
self.assertEqual(t._version, old_version + 1)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_reduce_add_coalesced(self):
numel = 5
num_bytes = numel * 8
tensors = [
self.genSparseTensor((2, 3), 2, 1, False, 'cuda', torch.float64)[0],
torch.randn(numel).long().cuda(),
torch.randn(numel).cuda(),
self.genSparseTensor((2, 3), 2, 10, False, 'cuda', torch.float64)[0],
self.genSparseTensor((2, 3), 2, 5, False, 'cuda', torch.float64)[0],
self.genSparseTensor((3, 3), 2, 7, False, 'cuda', torch.int64)[0],
self.genSparseTensor((2, 3), 2, 2, False, 'cuda', torch.float32)[0],
torch.randn(numel).long().cuda(),
torch.randn(numel).long().cuda(),
self.genSparseTensor((2, 7), 2, 3, False, 'cuda', torch.int64)[0],
torch.randn(numel * 2).int().cuda(), # int is 2x shorter
torch.randn(numel).cuda(),
]
self._test_reduce_add_coalesced(tensors, num_bytes * 5 // 2)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_reduce_add_coalesced_dense_only(self):
numel = 5
num_bytes = numel * 8
tensors = [
torch.randn(numel).long().cuda(),
torch.randn(numel).cuda(),
torch.randn(numel).long().cuda(),
torch.randn(numel).long().cuda(),
torch.randn(numel * 2).int().cuda(), # int is 2x shorter
torch.randn(numel).cuda(),
]
self._test_reduce_add_coalesced(tensors, num_bytes * 5 // 2)
def _test_scatter(self, input, chunk_sizes=None, dim=0):
if not TEST_MULTIGPU:
raise unittest.SkipTest("only one GPU detected")
if chunk_sizes is None:
ref_chunk_sizes = tuple(repeat(input.size(dim) // 2, 2))
else:
ref_chunk_sizes = chunk_sizes
# test regular
result = comm.scatter(input, (0, 1), chunk_sizes, dim)
self.assertEqual(len(result), 2)
chunk_start = 0
for i, r in enumerate(result):
chunk_end = chunk_start + ref_chunk_sizes[i]
index = [slice(None, None) for _ in range(input.dim())]
index[dim] = slice(chunk_start, chunk_end)
self.assertEqual(r, input[tuple(index)], atol=0, rtol=0)
chunk_start = chunk_end
if r.device == input.device:
self.assertEqual(r.data_ptr(), input.data_ptr()) # for target @ same device, a view should be returned
# test out
out = [torch.empty_like(t) for t in result]
result = comm.scatter(input, dim=dim, out=out)
self.assertEqual(len(result), 2)
chunk_start = 0
for i, r in enumerate(result):
self.assertIs(r, out[i])
chunk_end = chunk_start + ref_chunk_sizes[i]
index = [slice(None, None) for _ in range(input.dim())]
index[dim] = slice(chunk_start, chunk_end)
self.assertEqual(r, input[tuple(index)], atol=0, rtol=0)
chunk_start = chunk_end
# test error msg
if chunk_sizes is not None:
with self.assertRaisesRegex(RuntimeError, r"Expected devices and chunk_sizes to be of same length"):
comm.scatter(input, [0 for _ in range(len(chunk_sizes) + 1)], dim=dim, chunk_sizes=chunk_sizes)
with self.assertRaisesRegex(RuntimeError, r"'devices' must not be specified"):
comm.scatter(input, (0, 1), dim=dim, out=out)
with self.assertRaisesRegex(RuntimeError, r"Expected at least one device to scatter to"):
comm.scatter(input, (), dim=dim)
with self.assertRaisesRegex(RuntimeError, r"Expected at least one output tensor to scatter to"):
comm.scatter(input, dim=dim, out=[])
with self.assertRaisesRegex(RuntimeError,
r"Expected all output tensors to be CUDA tensors, but output tensor at index 0"):
comm.scatter(input, dim=dim, out=([out[0].cpu()] + out[1:]))
with self.assertRaisesRegex(RuntimeError, r"Output tensor at index 0 has incorrect shape"):
comm.scatter(input, dim=dim, out=([out[0].unsqueeze(0)] + out[1:]))
with self.assertRaisesRegex(RuntimeError, r"Total size for output tensors along scatter dim \d+ does not match"):
index = [slice(None, None) for _ in range(input.dim())]
index[dim] = slice(1, None)
comm.scatter(input, dim=dim, out=([out[0][tuple(index)]] + out[1:]))
def test_scatter_cpu(self):
self._test_scatter(torch.randn(4, 4), dim=0)
def test_scatter_cpu_dim(self):
self._test_scatter(torch.randn(4, 4), dim=1)
def test_scatter_cpu_neg_dim(self):
self._test_scatter(torch.randn(4, 4), dim=-2)
def test_scatter_cpu_sizes(self):
self._test_scatter(torch.randn(6, 4), chunk_sizes=(2, 4))
def test_scatter_gpu(self):
self._test_scatter(torch.randn(4, 4).cuda(), dim=0)
def test_scatter_gpu_dim(self):
self._test_scatter(torch.randn(4, 4).cuda(), dim=1)
def test_scatter_gpu_neg_dim(self):
self._test_scatter(torch.randn(4, 4).cuda(), dim=-2)
def test_scatter_gpu_sizes(self):
self._test_scatter(torch.randn(6, 4).cuda(), chunk_sizes=(2, 4))
def _test_gather(self, dim):
if not TEST_MULTIGPU:
raise unittest.SkipTest("only one GPU detected")
x = torch.randn(2, 5, device=0)
y = torch.randn(2, 5, device=1)
expected_size = list(x.size())
expected_size[dim] += y.size(dim)
expected_size = torch.Size(expected_size)
destinations = [None, torch.device('cuda:0'), torch.device('cpu')]
if torch.cuda.device_count() > 2:
destinations.append(torch.device('cuda:2'))
with torch.cuda.device(1):
for destination in destinations:
if destination is None:
expected_device = torch.device('cuda', torch.cuda.current_device())
else:
expected_device = destination
for use_out in [True, False]:
if use_out:
out = torch.empty(expected_size, device=expected_device)
result = comm.gather((x, y), dim, out=out)
self.assertIs(out, result)
else:
result = comm.gather((x, y), dim, destination=destination)
self.assertEqual(result.device, expected_device)
self.assertEqual(result.size(), expected_size)
index = [slice(None, None), slice(None, None)]
index[dim] = slice(0, x.size(dim))
self.assertEqual(result[tuple(index)], x)
index[dim] = slice(x.size(dim), x.size(dim) + y.size(dim))
self.assertEqual(result[tuple(index)], y)
# test error msg
with self.assertRaisesRegex(RuntimeError, r"'destination' must not be specified"):
comm.gather((x, y), dim, destination='cpu', out=torch.empty(expected_size, device='cpu'))
with self.assertRaisesRegex(RuntimeError, r"Expected at least one tensor to gather from"):
comm.gather(())
with self.assertRaisesRegex(RuntimeError, r"Expected all input tensors to be CUDA tensors, "):
comm.gather((x.cpu(), y))
with self.assertRaisesRegex(RuntimeError, r"Expected all input tensors to have the same number of dimensions"):
comm.gather((x, y.unsqueeze(0)))
with self.assertRaisesRegex(RuntimeError, r"Input tensor at index 1 has invalid shape"):
if dim in [0, -2]:
comm.gather((x, y[:, 1:]), dim=dim)
elif dim in [1, -1]:
comm.gather((x, y[1:, :]), dim=dim)
def test_gather(self):
self._test_gather(0)
def test_gather_dim(self):
self._test_gather(1)
def test_gather_neg_dim(self):
self._test_gather(-1)
@unittest.skipIf(not TEST_MULTIGPU, "only one GPU detected")
def test_memory_format_scatter_gather(self):
nhwc = torch.randn((10, 3, 32, 32), device='cpu').contiguous(memory_format=torch.channels_last)
results = torch.cuda.comm.scatter(nhwc, (0, 1), None, 0)
for result in results:
self.assertFalse(result.is_contiguous())
self.assertTrue(result.is_contiguous(memory_format=torch.channels_last))
gathered = torch.cuda.comm.gather(results)
self.assertTrue(gathered.is_contiguous(memory_format=torch.channels_last))
def test_matmul_device_mismatch(self):
cpu = torch.rand((10, 10))
cuda = cpu.cuda()
with self.assertRaisesRegex(RuntimeError, "Expected all tensors to be on the same device"):
cpu @ cuda
with self.assertRaisesRegex(RuntimeError, "Expected all tensors to be on the same device"):
cuda @ cpu
for s, m1, m2 in product((cpu, cuda), repeat=3):
if s.device == m1.device == m2.device:
torch.addmm(s, m1, m2)
else:
with self.assertRaisesRegex(RuntimeError, "Expected all tensors to be on the same device"):
torch.addmm(s, m1, m2)
@unittest.skipIf(not TEST_MULTIGPU, "Test needs multiple GPUs")
def test_scatter_namedtuple(self):
# tests ability to scatter namedtuples and retrieve a list where each
# element is of the expected namedtuple type.
fields = ("a", "b")
TestNamedTupleInput_0 = collections.namedtuple("NamedTuple", fields)
num_gpus = torch.cuda.device_count()
a = torch.rand(num_gpus * 2, device=0)
b = torch.rand(num_gpus * 2, device=0)
a_tensors_for_gpu = [a[2 * i : 2 * i + 2].to(i) for i in range(num_gpus)]
b_tensors_for_gpu = [b[2 * i : 2 * i + 2].to(i) for i in range(num_gpus)]
inp = TestNamedTupleInput_0(a, b)
target_gpus = [torch.device(i) for i in range(num_gpus)]
scatter_out = scatter_gather.scatter(inp, target_gpus)
for i, x in enumerate(scatter_out):
self.assertTrue(isinstance(x, type(inp)))
self.assertEqual(x._fields, fields)
expected_a = a_tensors_for_gpu[i]
expected_b = b_tensors_for_gpu[i]
self.assertEqual(expected_a, x.a)
self.assertEqual(expected_b, x.b)
class TestNamedTupleInput_1(NamedTuple):
a: torch.tensor
b: torch.tensor
a = torch.rand(num_gpus * 2, device=0)
b = torch.rand(num_gpus * 2, device=0)
a_tensors_for_gpu = [a[2 * i : 2 * i + 2].to(i) for i in range(num_gpus)]
b_tensors_for_gpu = [b[2 * i : 2 * i + 2].to(i) for i in range(num_gpus)]
inp = TestNamedTupleInput_1(a, b)
scatter_out = scatter_gather.scatter(inp, target_gpus)
for i, x in enumerate(scatter_out):
self.assertTrue(isinstance(x, type(inp)))
self.assertEqual(x._fields, fields)
expected_a = a_tensors_for_gpu[i]
expected_b = b_tensors_for_gpu[i]
self.assertEqual(expected_a, x.a)
self.assertEqual(expected_b, x.b)
@unittest.skipIf(not TEST_MULTIGPU, "Test needs multiple GPUs")
def test_gather_namedtuple(self):
# tests ability to gather a list of namedtuples and return a namedtuple where each
# element is of the expected tensor type.
fields = ['a', 'b']
TestNamedTupleInput_0 = collections.namedtuple('NamedTuple', fields)
num_gpus = torch.cuda.device_count()
a = torch.rand(num_gpus * 2, device=0)
b = torch.rand(num_gpus * 2, device=1)
out1 = TestNamedTupleInput_0(a, b)
a = torch.rand(num_gpus * 2, device=1)
b = torch.rand(num_gpus * 2, device=0)
out2 = TestNamedTupleInput_0(a, b)
outputs = [out1, out2]
out = scatter_gather.gather(outputs, 'cpu') # test on CPU
for i, x in enumerate(out):
self.assertTrue(isinstance(x, type(out2[-1]))) # x must be a tensor
cat = torch.cat((outputs[0][i].to('cpu'), outputs[1][i].to('cpu')))
self.assertTrue(torch.equal(x, cat))
out = scatter_gather.gather(outputs, 0) # test on GPU
for i, x in enumerate(out):
self.assertTrue(isinstance(x, type(out2[-1])))
cat = torch.cat((outputs[0][i].to(0), outputs[1][i].to(0)))
self.assertTrue(torch.equal(x, cat))
class TestNamedTupleInput_1(NamedTuple):
a: torch.tensor
b: torch.tensor
a = torch.rand(num_gpus * 2, device=0)
b = torch.rand(num_gpus * 2, device=1)
out1 = TestNamedTupleInput_1(a, b)
a = torch.rand(num_gpus * 2, device=1)
b = torch.rand(num_gpus * 2, device=0)
out2 = TestNamedTupleInput_1(a, b)
outputs = [out1, out2]
out = scatter_gather.gather(outputs, 0) # test on GPU
for i, x in enumerate(out):
self.assertTrue(isinstance(x, type(out2[-1])))
cat = torch.cat((outputs[0][i].to(0), outputs[1][i].to(0)))
self.assertTrue(torch.equal(x, cat))
out = scatter_gather.gather(outputs, 'cpu') # test on CPU
for i, x in enumerate(out):
self.assertTrue(isinstance(x, type(out2[-1])))
cat = torch.cat((outputs[0][i].to('cpu'), outputs[1][i].to('cpu')))
self.assertTrue(torch.equal(x, cat))
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "setContextRecorder not supported by CUDAMallocAsync")
def test_memory_snapshot(self):
try:
torch.cuda.memory.empty_cache()
torch.cuda.memory._record_memory_history(True)
x = torch.rand(311, 411, device='cuda')
# create a bunch of tensors that all will tile into the
# same segment to exercise the history merging code
# 512B is the minimum block size,
# so we allocate all the tensors to this size to make sure
# they tile evenly
tensors = [torch.rand(128, device='cuda') for _ in range(1000)]
while tensors:
del tensors[randint(0, len(tensors) - 1)]
# exercise the history trimming code
torch.rand(128 * 5, device='cuda')
ss = torch.cuda.memory._snapshot()
found_it = False
for seg in ss['segments']:
for b in seg['blocks']:
if 'history' in b:
for h in b['history']:
if h['real_size'] == 311 * 411 * 4:
self.assertTrue('test_cuda' in h['frames'][0]['filename'])
found_it = True
self.assertTrue(found_it)
if not IS_WINDOWS:
with tempfile.NamedTemporaryFile() as f:
torch.cuda.memory._save_segment_usage(f.name)
with open(f.name, 'r') as f2:
self.assertTrue('test_cuda.py' in f2.read())
del x
torch.cuda.empty_cache()
ss = torch.cuda.memory._snapshot()
self.assertTrue(ss['device_traces'][0][-1]['action'] == 'segment_free')
finally:
torch.cuda.memory._record_memory_history(False)
@unittest.skipIf(not IS_LINUX, "linux only cpp unwinding")
def test_direct_traceback(self):
from torch._C._profiler import gather_traceback, symbolize_tracebacks
c = gather_traceback(True, True, True)
r, = symbolize_tracebacks([c])
r = str(r)
self.assertTrue("test_cuda.py" in r)
self.assertTrue("unwind" in r)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "setContextRecorder not supported by CUDAMallocAsync")
@unittest.skipIf(not IS_LINUX, "cpp contexts are linux only")
def test_memory_snapshot_with_cpp(self):
try:
torch.cuda.memory.empty_cache()
torch.cuda.memory._record_memory_history(True, record_context_cpp=True)
x = torch.rand(311, 411, device='cuda')
ss = torch.cuda.memory._snapshot()['segments']
found_it = False
for seg in ss:
for b in seg['blocks']:
if 'history' in b:
for h in b['history']:
if h['real_size'] == 311 * 411 * 4:
self.assertTrue('::rand' in str(h['frames']))
found_it = True
self.assertTrue(found_it)
finally:
torch.cuda.memory._record_memory_history(False)
@skipIfRocm
def test_memory_profiler_viz(self):
with torch.profiler.profile(
with_stack=True,
profile_memory=True,
record_shapes=True
) as prof:
x = torch.rand(128, 128, device='cuda')
x * x + x * x
plot = profile_plot(prof)
self.assertTrue("test_cuda.py" in plot)
self.assertTrue("test_memory_profiler_viz" in plot)
self.assertTrue('"elements_category": [' in plot)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "setContextRecorder not supported by CUDAMallocAsync")
@unittest.skipIf(not IS_LINUX, "cpp contexts are linux only")
def test_memory_plots(self):
for record_context, cpp in ((True, IS_LINUX), (True, False), (False, False)):
try:
torch.cuda.memory.empty_cache()
torch.cuda.memory._record_memory_history(
True,
record_context=record_context,
trace_alloc_max_entries=1000000,
trace_alloc_record_context=True,
record_context_cpp=cpp)
def run():
x = torch.rand(128, 128, device='cuda')
x * x + x * x
run()
ss = torch.cuda.memory._snapshot()
tplot = trace_plot(ss)
self.assertTrue(record_context == ("test_memory_plots" in tplot))
self.assertTrue(cpp == ("::rand" in tplot))
self.assertTrue(str(128 * 128 * 4) in tplot)
splot = segment_plot(ss)
self.assertTrue(record_context == ("test_memory_plots" in splot))
self.assertTrue(str(128 * 128 * 4) in splot)
self.assertTrue(cpp == ("::rand" in splot))
torch.cuda.memory._record_memory_history(False)
finally:
torch.cuda.memory._record_memory_history(False)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "setContextRecorder not supported by CUDAMallocAsync")
def test_memory_snapshot_script(self):
try:
torch.cuda.memory.empty_cache()
torch.cuda.memory._record_memory_history(True)
@torch.jit.script
def foo():
return torch.rand(311, 411, device='cuda')
x = foo()
ss = torch.cuda.memory._snapshot()['segments']
found_it = False
for seg in ss:
for b in seg['blocks']:
if 'history' in b:
for h in b['history']:
if h['real_size'] == 311 * 411 * 4:
self.assertTrue(h['frames'][0]['name'] == 'foo')
found_it = True
self.assertTrue(found_it)
finally:
torch.cuda.memory._record_memory_history(False)
def test_allocator_settings(self):
def power2_div(size, div_factor):
pow2 = 1
while pow2 < size:
pow2 = pow2 * 2
if pow2 == size:
return pow2
step = pow2 / 2 / div_factor
ret = pow2 / 2
while ret < size:
ret = ret + step
return ret
torch.cuda.memory.empty_cache()
key_allocated = 'active_bytes.all.allocated' if not TEST_CUDAMALLOCASYNC else 'allocated_bytes.all.current'
key_requested = 'requested_bytes.all.allocated'
nelems = 21 * 1024 * 1024
nbytes = 4 * nelems # floats are 4 bytes
nelems_big = 100 * 1024 * 1024
nbytes_big = 4 * nelems_big # floats are 4 bytes
start_mem = torch.cuda.memory_stats()[key_allocated]
torch.cuda.memory._set_allocator_settings("")
x = torch.rand(nelems, device='cuda')
# test roundup_power2_divisions single value syntax
reg_mem = torch.cuda.memory_stats()[key_allocated]
start_requested = torch.cuda.memory_stats()[key_requested]
torch.cuda.memory._set_allocator_settings("roundup_power2_divisions:4")
y = torch.rand(nelems, device='cuda')
pow2_div4_mem = torch.cuda.memory_stats()[key_allocated]
current_requested = torch.cuda.memory_stats()[key_requested]
self.assertTrue(reg_mem - start_mem == nbytes)
if not TEST_CUDAMALLOCASYNC:
# not supported with the cudaMallocAsync backend
self.assertTrue(pow2_div4_mem - reg_mem == power2_div(nbytes, 4))
self.assertTrue(current_requested - start_requested == nbytes)
torch.cuda.memory._set_allocator_settings("garbage_collection_threshold:0.5")
torch.cuda.memory._set_allocator_settings("garbage_collection_threshold:0.5,max_split_size_mb:40")
# should have reset the power2 divisions now
torch.cuda.memory.empty_cache()
start_mem = torch.cuda.memory_stats()[key_allocated]
z = torch.rand(nelems, device='cuda')
reg_mem = torch.cuda.memory_stats()[key_allocated]
self.assertTrue(reg_mem - start_mem == nbytes)
# roundup_power2_divisions knob array syntax
torch.cuda.memory.empty_cache()
torch.cuda.memory._set_allocator_settings(
"garbage_collection_threshold:0.5,roundup_power2_divisions:[64:8,128:2,256:2,512:2,1024:1,>:1]")
start_mem = torch.cuda.memory_stats()[key_allocated]
w = torch.rand(nelems, device='cuda')
pow2_div8_mem = torch.cuda.memory_stats()[key_allocated]
if not TEST_CUDAMALLOCASYNC:
# not supported with the cudaMallocAsync backend
self.assertTrue(pow2_div8_mem - start_mem == power2_div(nbytes, 8))
torch.cuda.memory.empty_cache()
start_mem = torch.cuda.memory_stats()[key_allocated]
v = torch.rand(nelems_big, device='cuda')
pow2_div2_mem = torch.cuda.memory_stats()[key_allocated]
if not TEST_CUDAMALLOCASYNC:
# not supported with the cudaMallocAsync backend
self.assertTrue(pow2_div2_mem - start_mem == power2_div(nbytes_big, 2))
with self.assertRaises(RuntimeError):
torch.cuda.memory._set_allocator_settings("foo:1,bar:2")
with self.assertRaises(RuntimeError):
torch.cuda.memory._set_allocator_settings("garbage_collection_threshold:1.2")
with self.assertRaises(RuntimeError):
torch.cuda.memory._set_allocator_settings("max_split_size_mb:2")
def test_raises_oom(self):
with self.assertRaises(torch.cuda.OutOfMemoryError):
torch.empty(1024 * 1024 * 1024 * 1024, device='cuda')
@unittest.skipIf(not IS_LINUX, 'cpp traces only on linux')
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "setContextRecorder not supported by CUDAMallocAsync")
def test_cpp_memory_snapshot_pickle(self):
from torch.utils.cpp_extension import load_inline
source = """
#include <torch/csrc/cuda/memory_snapshot.h>
py::object do_snapshot() {
std::string data = torch::cuda::_memory_snapshot_pickled();
return py::bytes(data);
}
void record(bool e, bool ctx) {
torch::cuda::_record_memory_history(e, ctx, 10, ctx, ctx);
}
"""
m = load_inline(name='snapshot', cpp_sources=[source], functions=['do_snapshot', 'record'])
for ctx in (False, True):
try:
m.record(True, ctx)
@torch.jit.script
def the_script_fn():
return torch.rand(311, 411, device='cuda')
def run():
t = the_script_fn()
return pickle.loads(m.do_snapshot())
mem = run()
found = False
for s in mem['segments']:
for b in s['blocks']:
if b['state'] == 'active_allocated' and 'history' in b:
history = b['history']
if history and history[0]['real_size'] == 311 * 411 * 4:
if ctx:
frame_text = str(history[0]['frames'])
# C++ frame
self.assertTrue('::rand' in frame_text)
# script frame
self.assertTrue('the_script_fn' in frame_text)
# python frame
self.assertTrue('case.py' in frame_text)
found = True
last_action = mem['device_traces'][0][-1]
self.assertTrue(last_action['action'] == 'alloc')
self.assertTrue(last_action['size'] == 311 * 411 * 4)
self.assertTrue(found)
finally:
m.record(False, False)
@unittest.skipIf(TEST_CUDAMALLOCASYNC, "temporarily disabled")
def test_notifies_oom(self):
x = False
def cb(device, alloc, device_alloc, device_free):
nonlocal x
x = True
torch._C._cuda_attach_out_of_memory_observer(cb)
with self.assertRaises(torch.cuda.OutOfMemoryError):
torch.empty(1024 * 1024 * 1024 * 1024, device='cuda')
self.assertTrue(x)
@unittest.skipIf(TEST_PYNVML, "pynvml is not available")
def test_nvml_get_handler(self):
self.assertTrue(torch.cuda._get_pynvml_handler() is not None)
@unittest.skipIf(TEST_PYNVML, "pynvml is not available")
def test_temperature(self):
self.assertTrue(0 <= torch.cuda.temperature() <= 150)
@unittest.skipIf(TEST_PYNVML, "pynvml is not available")
def test_power_draw(self):
self.assertTrue(torch.cuda.power_draw() >= 0)
@unittest.skipIf(TEST_PYNVML, "pynvml is not available")
def test_clock_speed(self):
self.assertTrue(torch.cuda.clock_rate() >= 0)
MIN_BLOCK_SIZE = 512
SMALL_SIZE = 1048576
SMALL_BUFFER = 2097152
LARGE_BUFFER = 20971520
def get_cudagraph_segments(pool_id):
segments = torch.cuda.memory_snapshot()
return [segment for segment in segments if segment["segment_pool_id"] == pool_id]
def get_all_cudagraph_segments():
segments = torch.cuda.memory_snapshot()
return [segment for segment in segments if segment["segment_pool_id"] != (0, 0)]
def cudagraphify(fn, inputs, pool=None):
torch.cuda.synchronize()
stream = torch.cuda.Stream()
stream.wait_stream(torch.cuda.current_stream())
with torch.cuda.stream(stream):
fn(*inputs)
stream.synchronize()
torch.cuda.current_stream().wait_stream(stream)
torch.cuda.synchronize()
graph = torch.cuda.CUDAGraph()
with torch.cuda.graph(graph, stream=stream, pool=pool):
static_outputs = fn(*inputs)
return graph, static_outputs
def int8_cuda(size):
return torch.ones([size], device="cuda", dtype=torch.uint8)
def live_blocks(pool_id):
blocks = 0
seg = get_cudagraph_segments(pool_id)
for segment in get_cudagraph_segments(pool_id):
for block in segment["blocks"]:
blocks += block["state"] == "active_allocated"
return blocks
def tensor_metadata(x):
return {
"nbytes": x.untyped_storage().nbytes(),
"data_ptr": x.untyped_storage().data_ptr(),
"size": x.shape,
"stride": x.stride(),
"dtype": x.dtype,
"device": x.device,
"storage_offset": x.storage_offset(),
}
def reconstruct_from_tensor_metadata(metadata):
s = torch._C._construct_storage_from_data_pointer(
metadata["data_ptr"], metadata["device"], metadata["nbytes"]
)
t = torch.empty([0], device=metadata["device"], dtype=metadata["dtype"])
t.set_(
source=s,
storage_offset=metadata["storage_offset"],
size=metadata["size"],
stride=metadata["stride"],
)
return t
@unittest.skipIf(TEST_CUDAMALLOCASYNC or TEST_WITH_ROCM, "NYI")
class TestBlockStateAbsorption(TestCase):
def checkCheckpointedBlock(self, before_block, after_block):
for field in ("size", "state"):
self.assertEqual(before_block[field], after_block[field])
def checkCheckpointedState(self, before_segments, after_segments):
# after may contain additional segments, but all of the segments in before
# should be exactly equivalent to after
after_ptr_to_segment = {segment["address"] : segment for segment in after_segments}
for before_segment in before_segments:
self.assertTrue(before_segment["address"] in after_ptr_to_segment)
after_segment = after_ptr_to_segment[before_segment["address"]]
for field in ("device", "total_size", "allocated_size", "active_size", "segment_type", "segment_pool_id"):
self.assertEqual(before_segment[field], after_segment[field])
self.assertEqual(len(before_segment["blocks"]), len(after_segment["blocks"]))
for before_block, after_block in zip(before_segment["blocks"], after_segment["blocks"]):
self.checkCheckpointedBlock(before_block, after_block)
@staticmethod
def setCheckpointPoolState(device, state, stale_storages_ptr, storages_deleters=None):
stale_storages_ptr = [t.untyped_storage()._cdata for t in stale_storages_ptr]
storages_deleters = [] if not storages_deleters else [t.untyped_storage()._cdata for t in storages_deleters]
torch._C._cuda_setCheckpointPoolState(device, state, stale_storages_ptr, storages_deleters)
def checkFunction(self, fn, inputs, pool=None):
graph, outputs = cudagraphify(fn, inputs, pool=pool)
pool_id = graph.pool()
device = outputs[0].device.index
segments_before_checkpoint = get_cudagraph_segments(pool_id)
state = torch._C._cuda_getCheckpointState(device, pool_id)
self.setCheckpointPoolState(device, state, [], [])
self.checkCheckpointedState(segments_before_checkpoint, get_cudagraph_segments(pool_id))
def setUp(self):
super().setUp()
self.segment_length = len(get_all_cudagraph_segments())
def tearDown(self):
torch.cuda.synchronize()
gc.collect()
torch.cuda.empty_cache()
self.assertEqual(len(get_all_cudagraph_segments()), self.segment_length)
super().tearDown()
def test_simple(self):
def foo():
x = torch.zeros([SMALL_SIZE * 8], device="cuda", dtype=torch.uint8)
x = x + x
x1 = int8_cuda(SMALL_SIZE) + int8_cuda(SMALL_SIZE) + int8_cuda(SMALL_SIZE)
y = int8_cuda(SMALL_SIZE) + x1
z = int8_cuda(SMALL_SIZE)
return x, y, z
self.checkFunction(foo, [])
def test_allocated_in_middle_of_segment(self):
def foo():
small_buffers = [int8_cuda(MIN_BLOCK_SIZE) for _ in range(11)]
return small_buffers[5].add_(2)
self.checkFunction(foo, [])
def test_multiple_middle_allocations(self):
def foo():
small_buffers = [int8_cuda(MIN_BLOCK_SIZE) for _ in range(11)]
return small_buffers[5], small_buffers[8]
self.checkFunction(foo, [])
def test_middle_allocations_contiguous(self):
def foo():
small_buffers = [int8_cuda(MIN_BLOCK_SIZE) for _ in range(11)]
return small_buffers[5], small_buffers[6]
self.checkFunction(foo, [])
def test_additional_free_following_checkpoint(self):
def foo():
return int8_cuda(MIN_BLOCK_SIZE),
def foo2():
return int8_cuda(MIN_BLOCK_SIZE),
graph, outputs = cudagraphify(foo, [])
pool_id = graph.pool()
segments_before_checkpoint = get_cudagraph_segments(pool_id)
state = torch._C._cuda_getCheckpointState(outputs[0].device.index, pool_id)
graph2, outputs2 = cudagraphify(foo2, [], pool=graph.pool())
self.setCheckpointPoolState(outputs[0].device.index, state, outputs2, [])
del outputs2
self.checkCheckpointedState(segments_before_checkpoint, get_cudagraph_segments(pool_id))
# TODO: re-enable
# def test_additional_free_error(self):
# def foo():
# return int8_cuda(MIN_BLOCK_SIZE),
# def foo2():
# return int8_cuda(MIN_BLOCK_SIZE),
# graph, outputs = cudagraphify(foo, [])
# pool_id = graph.pool()
# segments_before_checkpoint = get_cudagraph_segments(pool_id)
# state = torch._C._cuda_getCheckpointState(outputs[0].device.index, pool_id)
# graph2, outputs2 = cudagraphify(foo2, [], pool=graph.pool())
# with self.assertRaisesRegex(Exception, "being manually freed must be passed"):
# self.setCheckpointPoolState(outputs[0].device.index, state, [], [])
def test_tensor_dies_after_checkpoint(self):
def foo():
return int8_cuda(MIN_BLOCK_SIZE), int8_cuda(MIN_BLOCK_SIZE)
graph, outputs = cudagraphify(foo, [])
pool_id = graph.pool()
device = outputs[0].device.index
segments_before_checkpoint = get_cudagraph_segments(pool_id)
state = torch._C._cuda_getCheckpointState(outputs[0].device.index, pool_id)
output_data_ptrs = [output.data_ptr() for output in outputs]
del outputs
self.setCheckpointPoolState(device, state, [], [])
self.assertEqual(live_blocks(pool_id), 2)
torch._C._cuda_cudaCachingAllocator_raw_delete(output_data_ptrs[0])
self.assertEqual(live_blocks(pool_id), 1)
torch._C._cuda_cudaCachingAllocator_raw_delete(output_data_ptrs[1])
self.assertEqual(live_blocks(pool_id), 0)
def test_assigning_back_deleter_fns_to_tensor(self):
def foo(x):
return int8_cuda(SMALL_BUFFER) + x, int8_cuda(SMALL_BUFFER) + x, int8_cuda(LARGE_BUFFER) + x
inp = torch.tensor([1], device="cuda")
graph, outputs = cudagraphify(foo, [inp])
pool_id = graph.pool()
graph.replay()
device = outputs[0].device.index
for i in range(len(outputs)):
self.assertTrue(outputs[i].mean(dtype=torch.float) == 2)
state = torch._C._cuda_getCheckpointState(outputs[0].device.index, pool_id)
output_ptrs = [output.untyped_storage().data_ptr() for output in outputs]
ten_metadata = [tensor_metadata(t) for t in outputs]
self.assertEqual(live_blocks(pool_id), 3)
del outputs
self.assertEqual(live_blocks(pool_id), 0)
reconstructed_tensors = [reconstruct_from_tensor_metadata(metadata) for metadata in ten_metadata]
for i in range(len(reconstructed_tensors)):
self.assertTrue(reconstructed_tensors[i].mean(dtype=torch.float) == 2)
inp.add_(1)
graph.replay()
for i in range(len(reconstructed_tensors)):
self.assertTrue(reconstructed_tensors[i].mean(dtype=torch.float) == 3)
self.setCheckpointPoolState(device, state, [], [reconstructed_tensors[0], reconstructed_tensors[1]])
self.assertEqual(live_blocks(pool_id), 3)
reconstructed_tensors[0] = None
self.assertEqual(live_blocks(pool_id), 2)
reconstructed_tensors[1] = None
self.assertEqual(live_blocks(pool_id), 1)
# should not change, we did not pass it in to swap data ptrs
reconstructed_tensors[2] = None
self.assertEqual(live_blocks(pool_id), 1)
torch._C._cuda_cudaCachingAllocator_raw_delete(output_ptrs[2])
self.assertEqual(live_blocks(pool_id), 0)
@skipIfNoTorchVision
def test_resnet(self):
import torchvision
m = torchvision.models.resnet50()
m.eval()
m = m.cuda()
inp = torch.rand([1, 3, 255, 255], device="cuda")
self.checkFunction(m, [inp])
def test_allocate_in_thread_to_pool(self):
def foo():
return torch.rand([4], device="cuda")
pool = torch.cuda.graph_pool_handle()
graph, outputs = cudagraphify(foo, [], pool=pool)
device = outputs[0].device.index
del outputs
@contextlib.contextmanager
def _use_cuda_memory_pool_manager(device, mem_pool):
"""
Context manager to use cuda graph pool for new allocations. If you use this manager
all cudagraph tensors in use should be reflected in the allocator or they will be overwritten.
existing_graph should already have been used in a capture, and the mem_pool must already exist.
"""
torch.cuda.synchronize()
stream = torch.cuda.Stream()
stream.wait_stream(torch.cuda.current_stream())
stream_context = torch.cuda.stream(stream)
stream_context.__enter__()
torch._C._cuda_beginAllocateCurrentStreamToPool(device, mem_pool)
try:
yield
finally:
torch._C._cuda_endAllocateCurrentStreamToPool(device)
torch._C._cuda_releasePool(device, mem_pool)
stream_context.__exit__(None, None, None)
segments = get_cudagraph_segments(pool)
self.assertEqual(len(get_cudagraph_segments(pool)), 1)
def use_pool():
def alloc_three():
a = int8_cuda(LARGE_BUFFER)
b = int8_cuda(LARGE_BUFFER)
c = a + b
with _use_cuda_memory_pool_manager(device, pool):
# three allocations
for _ in range(10):
alloc_three()
# three more allocations not in pool
alloc_three()
def no_pool():
# two allocations
for _ in range(10):
a = int8_cuda(LARGE_BUFFER)
b = int8_cuda(LARGE_BUFFER)
del a, b
graph_thread = threading.Thread(target=use_pool)
no_graph_thread = threading.Thread(target=no_pool)
graph_thread.start()
no_graph_thread.start()
graph_thread.join()
no_graph_thread.join()
self.assertEqual(len(get_cudagraph_segments(pool)), 4)
del graph
torch.cuda.synchronize()
gc.collect()
torch.cuda.empty_cache()
self.assertEqual(len(get_cudagraph_segments(pool)), 0)
instantiate_parametrized_tests(TestCuda)
if __name__ == '__main__':
run_tests()
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