# Owner(s): ["oncall: distributed"] import copy import json import os import pickle import random import re import signal import sys import tempfile import threading import time import warnings from contextlib import contextmanager from datetime import datetime, timedelta from enum import auto, Enum from itertools import chain, product from unittest import mock, SkipTest import torch import torch.distributed as c10d if not c10d.is_available() or not c10d.is_nccl_available(): print("c10d NCCL not available, skipping tests", file=sys.stderr) sys.exit(0) from typing import Dict, List import test_c10d_common from test_c10d_common import ConvNet, DoubleGpuNet, gpus_for_rank, ModuleForDdpCommHook import torch.distributed as dist import torch.distributed.algorithms.ddp_comm_hooks.default_hooks as default import torch.distributed.algorithms.ddp_comm_hooks.powerSGD_hook as powerSGD import torch.nn.functional as F import torch.testing._internal.common_utils as common from torch import nn from torch._C._distributed_c10d import OpType from torch.nn.parallel import DistributedDataParallel from torch.testing._internal.common_cuda import TEST_MULTIGPU from torch.testing._internal.common_distributed import ( get_timeout, init_multigpu_helper, MultiProcessTestCase, requires_gloo, requires_nccl, requires_nccl_version, skip_if_lt_x_gpu, skip_if_rocm_multiprocess, TEST_SKIPS, with_dist_debug_levels, with_nccl_blocking_wait, ) from torch.testing._internal.common_utils import ( instantiate_parametrized_tests, parametrize, retry_on_connect_failures, run_tests, skip_but_pass_in_sandcastle, skip_but_pass_in_sandcastle_if, TEST_CUDA, TEST_WITH_DEV_DBG_ASAN, TEST_WITH_ROCM, TestCase, ) if TEST_WITH_DEV_DBG_ASAN: print( "Skip ASAN as torch + multiprocessing spawn have known issues", file=sys.stderr ) sys.exit(0) # bfloat16 is only supported by CUDA 11+ BFLOAT16_AVAILABLE = torch.cuda.is_available() and ( (torch.version.cuda is not None and int(torch.version.cuda.split(".")[0]) >= 11) or torch.version.hip is not None ) class RendezvousEnvTest(TestCase): @retry_on_connect_failures @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_CUDA, "No GPUs available, skipping test") def test_common_errors(self): vars = { "WORLD_SIZE": "1", "RANK": "0", "MASTER_ADDR": "127.0.0.1", "MASTER_PORT": str(common.find_free_port()), } class Env: def __init__(self, vars): self.env_patcher = mock.patch.dict(os.environ, vars, clear=True) def __enter__(self): self.env_patcher.start() def __exit__(self, type, value, traceback): self.env_patcher.stop() def without(d, key): d = d.copy() d.pop(key) return d def withouts(d, keys): d = d.copy() for key in keys: d.pop(key) return d with Env(without(vars, "WORLD_SIZE")): self.assertEqual(None, os.environ.get("WORLD_SIZE")) with self.assertRaisesRegex(ValueError, "WORLD_SIZE expected"): gen = c10d.rendezvous("env://") next(gen) c10d.init_process_group(backend="nccl", world_size=1) self.assertEqual(c10d.get_rank(), 0) self.assertEqual(c10d.get_world_size(), 1) c10d.destroy_process_group() with Env(without(vars, "RANK")): self.assertEqual(None, os.environ.get("RANK")) with self.assertRaisesRegex(ValueError, "RANK expected"): gen = c10d.rendezvous("env://") next(gen) c10d.init_process_group(backend="nccl", rank=0) self.assertEqual(c10d.get_rank(), 0) self.assertEqual(c10d.get_world_size(), 1) c10d.destroy_process_group() with Env(withouts(vars, ["RANK", "WORLD_SIZE"])): self.assertEqual(None, os.environ.get("RANK")) self.assertEqual(None, os.environ.get("WORLD_SIZE")) c10d.init_process_group(backend="nccl", rank=0, world_size=1) self.assertEqual(c10d.get_rank(), 0) self.assertEqual(c10d.get_world_size(), 1) c10d.destroy_process_group() with Env(vars): c10d.init_process_group(backend="nccl") self.assertEqual(c10d.get_rank(), 0) self.assertEqual(c10d.get_world_size(), 1) c10d.destroy_process_group() with Env(without(vars, "MASTER_ADDR")): self.assertEqual(None, os.environ.get("MASTER_ADDR")) with self.assertRaisesRegex(ValueError, "MASTER_ADDR expected"): gen = c10d.rendezvous("env://") next(gen) with Env(without(vars, "MASTER_PORT")): self.assertEqual(None, os.environ.get("MASTER_PORT")) with self.assertRaisesRegex(ValueError, "MASTER_PORT expected"): gen = c10d.rendezvous("env://") next(gen) with Env(without(vars, "WORLD_SIZE")): self.assertEqual(None, os.environ.get("WORLD_SIZE")) gen = c10d.rendezvous(f"env://?world_size={1}") _, _, size = next(gen) self.assertEqual(size, 1) with Env(without(vars, "RANK")): self.assertEqual(None, os.environ.get("RANK")) gen = c10d.rendezvous(f"env://?rank={0}") _, rank, _ = next(gen) self.assertEqual(rank, 0) with Env(withouts(vars, ["RANK", "WORLD_SIZE"])): self.assertEqual(None, os.environ.get("RANK")) self.assertEqual(None, os.environ.get("WORLD_SIZE")) gen = c10d.rendezvous(f"env://?rank={0}&world_size={1}") _, rank, size = next(gen) self.assertEqual(rank, 0) self.assertEqual(size, 1) class TimeoutTest(test_c10d_common.AbstractTimeoutTest, TestCase): @requires_nccl() @retry_on_connect_failures @skip_but_pass_in_sandcastle_if(not TEST_CUDA, "No GPUs available, skipping test") def test_default_store_timeout_nccl(self): self._test_default_store_timeout("nccl") class ProcessGroupNCCLNoGPUTest(TestCase): MAIN_PROCESS_RANK = 0 def setUp(self): self.rank = self.MAIN_PROCESS_RANK self.world_size = 1 self.file = tempfile.NamedTemporaryFile(delete=False) def tearDown(self): pass @requires_nccl() @skip_but_pass_in_sandcastle_if(TEST_CUDA, "GPUs are available, skipping test") def test_init_no_gpus(self): store = c10d.FileStore(self.file.name, self.world_size) with self.assertRaisesRegex( ValueError, "ProcessGroupNCCL is only supported with GPUs, no GPUs found!" ): c10d.ProcessGroupNCCL(store, self.rank, self.world_size) class ProcessGroupNCCLGroupTest(MultiProcessTestCase): def _create_process_group_nccl(self, store, opts, device_id=None): # create nccl processgroup with opts c10d.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, pg_options=opts, device_id=device_id, ) pg = c10d.distributed_c10d._get_default_group() return pg def opts(self, high_priority_stream=False): opts = c10d.ProcessGroupNCCL.Options() opts.is_high_priority_stream = high_priority_stream return opts def setUp(self): super().setUp() # Need to skip return code checking for these tests since the child # processes don't exit cleanly in some cuda versions self.skip_return_code_checks = [ self.test_nan_assert_float16.__wrapped__, self.test_nan_assert_float32.__wrapped__, self.test_nan_assert_float64.__wrapped__, self.test_nan_assert_bfloat16.__wrapped__, ] # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" # self.num_gpus = torch.cuda.device_count() self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass @property def world_size(self): return 2 @property def rank_to_GPU(self): # return rank to GPU map return init_multigpu_helper(self.world_size, "nccl") @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 1 GPU") @skip_if_lt_x_gpu(1) def test_nccl_dist_backend_error(self): store = c10d.FileStore(self.file_name, self.world_size) self._create_process_group_nccl(store, self.opts()) # Both rank 0 and 1 will use the same CUDA device resulting in ncclInvalidUsage with self.assertRaises(dist.DistBackendError) as cm: dist.broadcast(torch.tensor([1, 2, 3]).cuda(), 0) self.assertTrue(isinstance(cm.exception, dist.DistError)) self.assertIsInstance(cm.exception, RuntimeError) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_abort_pg(self): # Disable ASYNC_ERROR_HANDLING for this test to ensure we can programmatically # abort the process group. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" store = c10d.FileStore(self.file_name, self.world_size) self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize state. dist.all_reduce(t) def abortpg(): c10d.distributed_c10d._get_default_group()._get_backend( torch.device(device) )._shutdown() # Initialize DDP to ensure "destroy_process_group" will not call # ProcessGroupNCCL destructor since DDP holds a reference to process group. # Run a single iteration of DDP to initialize state. model = DistributedDataParallel( torch.nn.Linear(10, 10).to(device), device_ids=[device] ) model(t).sum().backward() # Now simulate collective getting stuck and abort gets us unstuck if self.rank == 0: dist.all_reduce(t) # Schedule thread before we get stuck to abort pg. thread = threading.Thread(target=abortpg) thread.start() # We would get stuck here due to d2h if we didn't abort. t_cpu = t.cpu() thread.join() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_close_pg(self): # Disable ASYNC_ERROR_HANDLING for this test to ensure we can programmatically # abort the process group. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize state. pg.allreduce(t) # Destroy pg and validate pg is no longer valid dist.destroy_process_group() with self.assertRaises(dist.DistBackendError): pg.allreduce([t]) del pg CUDA_12_AND_ABOVE = torch.cuda.is_available() and ( torch.version.cuda is not None and int(torch.version.cuda.split(".")[0]) >= 12 ) @requires_nccl() @skip_but_pass_in_sandcastle_if( not (TEST_MULTIGPU and CUDA_12_AND_ABOVE), "NCCL test requires 2+ GPUs and Device side assert could cause unexpected errors in lower versions of CUDA", ) @parametrize( "type", [ torch.float16, torch.float32, torch.float64, torch.bfloat16, torch.float8_e4m3fn, torch.float8_e5m2, ], ) @skip_if_rocm_multiprocess def test_nan_assert(self, type): # Expecting a device-side error when NaN is detected os.environ["TORCH_NCCL_NAN_CHECK"] = "1" store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] size = (10, 10) nan_tensor = torch.full(size, self.rank, dtype=type, device=device) # randomly pick an nan element i = random.randint(0, nan_tensor.size(0) - 1) j = random.randint(0, nan_tensor.size(1) - 1) nan_tensor[i, j] = float("nan") with self.assertRaises(RuntimeError): pg.allreduce(nan_tensor) dist.destroy_process_group() # reset env os.environ["TORCH_NCCL_NAN_CHECK"] = "0" @requires_nccl() @skip_if_lt_x_gpu(2) def test_nan_rank_filter(self): # Putting NaN at recv buffer, program should not fail as NaN checker # should not check on receive buffer os.environ["TORCH_NCCL_NAN_CHECK"] = "1" store = c10d.FileStore(self.file_name, self.world_size) device = torch.device("cuda:%d" % self.rank) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) t = torch.ones(3, 4, dtype=torch.bfloat16, device=device) if self.rank != 0: # Putting NaN at recv buffer t[1, 1] = float("nan") # Against broadcast c10d.broadcast(t, 0) # Against P2P if self.rank == 0: c10d.send(t, 1) elif self.rank == 1: c10d.recv(t, 0) c10d.destroy_process_group() # reset env os.environ["TORCH_NCCL_NAN_CHECK"] = "0" @requires_nccl() @skip_if_lt_x_gpu(2) def test_nan_check(self): # Not expecting an error, NaN check should not make legit code fail os.environ["TORCH_NCCL_NAN_CHECK"] = "1" store = c10d.FileStore(self.file_name, self.world_size) device = torch.device("cuda:%d" % self.rank) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) x = torch.ones((10,), dtype=torch.bfloat16, device=device) * self.rank t = torch.ones(3, 4, dtype=torch.bfloat16, device=device) c10d.broadcast(x, src=0) c10d.all_reduce(t) c10d.barrier() c10d.destroy_process_group() # reset env os.environ["TORCH_NCCL_NAN_CHECK"] = "0" @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_destruct_before_terminate_pg(self): # Disable ASYNC_ERROR_HANDLING for this test to ensure we can programmatically # abort the process group. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize state. pg.allreduce(t) # force destruction before terminating comms, destructor would terminate comms del pg @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_abort_in_destroy_pg(self): # Disable ASYNC_ERROR_HANDLING for this test to ensure we can programmatically # abort the process group. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize state. pg.allreduce(t) # Destroy pg and validate pg is NOT in working condition since # we have shutdown comms dist.destroy_process_group() with self.assertRaises(dist.DistBackendError): pg.allreduce([t]) @requires_nccl() @skip_but_pass_in_sandcastle_if( torch.cuda.device_count() < 2, "NCCL test requires 2+ GPUs" ) def test_close_multi_pg_unordered(self): store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize default PG's communicator. pg.allreduce(t).wait() new_pg1 = c10d.new_group([0, 1]) new_pg2 = c10d.new_group([0, 1]) if self.rank == 0 or self.rank == 1: t1 = torch.rand(10, 10, device=device) t2 = torch.rand(10, 10, device=device) new_pg1.allreduce(t1).wait() new_pg2.allreduce(t2).wait() if self.rank == 0: dist.destroy_process_group(new_pg2) # force destruction of pg2 first del new_pg2 dist.destroy_process_group(new_pg1) del new_pg1 if self.rank == 1: c10d.destroy_process_group(new_pg1) # force destruction of pg1 first del new_pg1 dist.destroy_process_group(new_pg2) del new_pg2 dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if( torch.cuda.device_count() < 2, "NCCL test requires 2+ GPUs" ) def test_abort_in_destroy_multi_pgs(self): store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize default PG's communicator. pg.allreduce(t).wait() new_pg1 = c10d.new_group([0, 1]) new_pg2 = c10d.new_group([0, 1]) t1 = torch.rand(10, 10, device=device) t2 = torch.rand(10, 10, device=device) new_pg1.allreduce(t1).wait() new_pg2.allreduce(t2).wait() backend = pg._get_backend(torch.device(device)) # default PG's backend should have a split count of 2 self.assertEqual(backend.comm_split_count(), 2) # shutdown all NCCL PGs in one shot dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if( torch.cuda.device_count() < 2, "NCCL test requires 2+ GPUs" ) def test_abort_in_destroy_mixed_empty_pgs(self): store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) device = self.rank_to_GPU[self.rank][0] t = torch.rand(10, 10, device=device) # First allreduce to initialize default PG's communicator. pg.allreduce(t).wait() # PG1 is an PG without comms initialized, since we don't call collective on it new_pg1 = c10d.new_group([0, 1]) new_pg2 = c10d.new_group([0, 1]) t2 = torch.rand(10, 10, device=device) new_pg2.allreduce(t2).wait() backend = pg._get_backend(torch.device(device)) # default PG's backend should have a split count of 1 self.assertEqual(backend.comm_split_count(), 1) # shutdown all NCCL PGs in one shot dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if( torch.cuda.device_count() < 2, "NCCL test requires 2+ GPUs" ) def test_file_store_check(self): os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" os.environ["TORCH_NCCL_ENABLE_MONITORING"] = "0" # FileStore check() would be executed os.environ["TORCH_NCCL_DUMP_ON_TIMEOUT"] = "1" os.environ["TORCH_NCCL_HEARTBEAT_TIMEOUT_SEC"] = "0" # self.file_name is created using "delete=False" # e.g., self.file_name = tempfile.NamedTemporaryFile(delete=False).name store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( backend="nccl", rank=self.rank, world_size=self.world_size, store=store ) pg = dist.distributed_c10d._get_default_group() self.assertEqual(pg.rank(), self.rank) self.assertEqual(pg.size(), self.world_size) # give enough time for check() to be executed multiple times time.sleep(2) dist.destroy_process_group() def _check_nccl_timeout(self, expected_timeout): pg = dist.distributed_c10d._get_default_group() options = pg._get_backend(torch.device(f"cuda:{self.rank}")).options self.assertEqual(options._timeout, expected_timeout) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_CUDA, "No GPUs available, skipping test") def test_init_process_group_nccl_timeout(self): # nccl is handled 'specially' inside init_process_group and its options class is different from the options # used by the other PG's. There are specific edge cases for nccl that need to be tested. store = c10d.FileStore(self.file_name, self.world_size) base_opts = dict( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) # test the default value coming from the `init_process_group` kwarg default dist.init_process_group(**base_opts) self._check_nccl_timeout(torch.distributed.constants.default_pg_nccl_timeout) dist.destroy_process_group() # test that `kwarg` timeout takes effect new_timeout = timedelta(seconds=123) dist.init_process_group(**base_opts, timeout=new_timeout) self._check_nccl_timeout(new_timeout) dist.destroy_process_group() # test that timeout value provided via `pg_options` kwarg is ignored and issues warning, # 'timeout' kwarg (or its kwdefault) taking precedence opts = dist.ProcessGroupNCCL.Options() opts._timeout = timedelta(seconds=123) with warnings.catch_warnings(record=True) as w: dist.init_process_group(**base_opts, pg_options=opts) # TODO(whc) i verified that we are indeed emitting this warning, and i can't figure out why i can't catch it. # self.assertEqual(len(w), 1) # self.assertTrue("pg_options._timeout was specified" in str(w[-1].message)) self._check_nccl_timeout(torch.distributed.constants.default_pg_nccl_timeout) dist.destroy_process_group() # test that timeout value provided via `pg_options` kwarg is ignored and issues warning, # 'timeout' kwarg taking precedence opts = dist.ProcessGroupNCCL.Options() opts._timeout = timedelta(seconds=123) dist.init_process_group( **base_opts, pg_options=opts, timeout=timedelta(seconds=1240) ) self._check_nccl_timeout(timedelta(seconds=1240)) dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("backend", [None, "nccl"]) def test_set_nccl_pg_timeout(self, backend): store = c10d.FileStore(self.file_name, self.world_size) opts = dict( backend=backend, store=store, rank=self.rank, world_size=self.world_size, timeout=timedelta(seconds=123), ) dist.init_process_group(**opts) pg = dist.distributed_c10d._get_default_group() pg.allreduce(torch.rand(10).cuda(self.rank)) self._check_nccl_timeout(timedelta(seconds=123)) pg._get_backend(torch.device(f"cuda:{self.rank}"))._set_default_timeout( timedelta(seconds=23) ) self._check_nccl_timeout(timedelta(seconds=23)) pg.allreduce(torch.rand(10).cuda(self.rank)) c10d.distributed_c10d._set_pg_timeout(timedelta(seconds=252), pg) self._check_nccl_timeout(timedelta(seconds=252)) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("backend", [None, "nccl"]) def test_extend_nccl_pg_timeout(self, backend): torch.cuda.set_device(self.rank) store = c10d.FileStore(self.file_name, self.world_size) opts = dict( backend=backend, store=store, rank=self.rank, world_size=self.world_size, timeout=timedelta(seconds=123), ) dist.init_process_group(**opts) pg = dist.distributed_c10d._get_default_group() bankend = pg._get_backend(torch.device(f"cuda:{self.rank}")) w = pg.allreduce(torch.rand(10).cuda(self.rank)) self.assertTrue(bankend._verify_work_timeout(w, timedelta(seconds=123))) w.wait() bankend._set_default_timeout(timedelta(seconds=3)) if self.rank == 0: # Ideally we want to sleep for a very long time, but this is not # feasible in unit test. So this is only a very tiny case. time.sleep(5) pg.allreduce(torch.rand(10).cuda(self.rank)) time.sleep(5) pg.allreduce(torch.rand(5).cuda(self.rank)) w = pg.allreduce(torch.rand(10).cuda(self.rank)) self.assertTrue(bankend._verify_work_timeout(w, timedelta(seconds=3))) w.wait() else: dist.distributed_c10d._add_ephemeral_timeout_for_all_pgs( timedelta(seconds=10) ) w1 = pg.allreduce(torch.rand(10).cuda(self.rank)) w2 = pg.allreduce(torch.rand(5).cuda(self.rank)) self.assertTrue(bankend._verify_work_timeout(w1, timedelta(seconds=13))) self.assertTrue(bankend._verify_work_timeout(w2, timedelta(seconds=13))) w1.wait() dist.distributed_c10d._add_ephemeral_timeout_for_all_pgs( timedelta(seconds=5) ) # Since we are not block wait so use a sync here to leave enough time # for watchdog to reset first timeout extension. torch.cuda.synchronize(torch.device(f"cuda:{self.rank}")) w = pg.allreduce(torch.rand(10).cuda(self.rank)) self.assertTrue(bankend._verify_work_timeout(w, timedelta(seconds=8))) w.wait() @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_comm_split_optimization(self): # Test the optimization of new groups that contain all world # ranks use the "transparent" `ncclCommSplit` optimization. store = c10d.FileStore(self.file_name, self.world_size) pg = self._create_process_group_nccl(store, self.opts()) # Test lazy splitting behavior across each per-device backend. for device in self.rank_to_GPU[self.rank]: backend = pg._get_backend(torch.device(device)) # split doesn't happen unless the original process group has lazily # created communicators, so first verify we haven't split even when # making the new group and running an operation on the original pg. ng = c10d.new_group() tensor = torch.tensor([self.rank]).cuda(device) pg.broadcast(tensor, 0) self.assertEqual(backend.comm_split_count(), 0) # The new group will force a split of the original on first use. ng.broadcast(tensor, 0) self.assertEqual(backend.comm_split_count(), 1) @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @skip_but_pass_in_sandcastle_if( torch.cuda.nccl.version()[-1] == "x", "NCCL test not for NCCLX" ) def test_comm_split_subgroup(self): # Test `ncclCommSplit` for smaller subgroups of the world when # we've passed a specific device_id to init_process_group. store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg = self._create_process_group_nccl(store, self.opts(), device_id=device) backend = pg._get_backend(torch.device(device)) tensor = torch.full((1,), self.rank).cuda(device) original_tensor = tensor.clone() ng = c10d.new_group([0]) # comm split happens eagerly since device_id is passed to init_process_group. self.assertEqual(backend.comm_split_count(), 1) if self.rank == 0: dist.broadcast(tensor, 0, group=ng) # no additional comm split happens after a collective. self.assertEqual(backend.comm_split_count(), 1) self.assertEqual(tensor, original_tensor) dist.destroy_process_group() @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_comm_split_group(self): # Test `ncclCommSplit` for smaller subgroups of the world when # we've passed a specific device_id to init_process_group. store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg = self._create_process_group_nccl(store, self.opts(), device_id=device) backend = pg._get_backend(torch.device(device)) tensor = torch.full((1,), self.rank).cuda(device) ng1 = c10d.split_group(pg, [[0, 1]]) backend1 = pg._get_backend(torch.device(device)) # check basic options are the same between parent and child self.assertEqual(backend.options._timeout, backend1.options._timeout) self.assertEqual( backend.options.is_high_priority_stream, backend1.options.is_high_priority_stream, ) self.assertEqual(ng1.group_desc, "default_pg:split:0") # comm split happens eagerly since device_id is passed to init_process_group. self.assertEqual(backend.comm_split_count(), 1) dist.broadcast(tensor, 0, group=ng1) self.assertEqual(tensor, torch.full((1,), 0)) ng2 = c10d.split_group(pg, [[0, 1]]) self.assertEqual(ng2.group_desc, "default_pg:split:1") self.assertEqual(backend.comm_split_count(), 2) dist.destroy_process_group() @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_non_blocking_init(self): # Test creating a pg using nonblocking mode but not eagerly os.environ["TORCH_NCCL_USE_COMM_NONBLOCKING"] = "1" os.environ["TORCH_NCCL_NONBLOCKING_TIMEOUT"] = "100" store = c10d.FileStore(self.file_name, self.world_size) device = self.rank_to_GPU[self.rank][0] pg = self._create_process_group_nccl(store, self.opts()) backend = pg._get_backend(torch.device(device)) self.assertEqual(backend.comm_split_count(), 0) reduce_tensor = torch.rand(10, 10, device=device) # Run an allreduce, which should trigger a comm init for pg pg.allreduce(reduce_tensor).wait() new_pg = c10d.new_group() # even after pg's collective call, new pg's comm is not initialized until its own collectcive calls self.assertEqual(backend.comm_split_count(), 0) broadcast_tensor = torch.tensor([self.rank]).cuda(device) new_pg.broadcast(broadcast_tensor, 0).wait() self.assertEqual(backend.comm_split_count(), 1) dist.destroy_process_group() @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_non_blocking_with_eager_init(self): # Test creating a pg eagerly with nonblocking mode when # we've passed a specific device_id to init_process_group. os.environ["TORCH_NCCL_USE_COMM_NONBLOCKING"] = "1" os.environ["TORCH_NCCL_NONBLOCKING_TIMEOUT"] = "100" store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") # bound device to triger eager init mode pg = self._create_process_group_nccl(store, self.opts(), device_id=device) backend = pg._get_backend(torch.device(device)) self.assertEqual(backend.comm_split_count(), 0) reduce_tensor = torch.rand(10, 10, device=device) # Run an allreduce, comm should have already started initilizaing, # but allreduce is issued to CUDA STREAM only after the initialization is a success pg.allreduce(reduce_tensor).wait() new_pg = c10d.new_group() # new pg's comm is initialized eagerly self.assertEqual(backend.comm_split_count(), 1) broadcast_tensor = torch.tensor([self.rank]).cuda(device) new_pg.broadcast(broadcast_tensor, 0).wait() self.assertEqual(backend.comm_split_count(), 1) dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_get_uid(self): store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg = self._create_process_group_nccl(store, self.opts(), device_id=device) from torch.distributed.distributed_c10d import _get_process_group_uid self.assertEqual(_get_process_group_uid(pg), 0) pg_2 = c10d.new_group([0, 1]) self.assertEqual(_get_process_group_uid(pg_2), 1) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_set_process_group_desc(self): store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg_default = self._create_process_group_nccl( store, self.opts(), device_id=device ) self.assertEqual(pg_default.group_desc, "default_pg") pg_1 = c10d.new_group([0, 1], group_desc="test_purpose") self.assertEqual(pg_1.group_desc, "test_purpose") pg_2 = c10d.new_group([0, 1]) self.assertEqual(pg_2.group_desc, "undefined") class DistributedDataParallelTest( test_c10d_common.CommonDistributedDataParallelTest, MultiProcessTestCase ): def setUp(self): super().setUp() # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" self._spawn_processes() def _get_process_group(self): store = self._get_store() c10d.init_process_group( "nccl", store=store, rank=self.rank, world_size=self.world_size ) return c10d.distributed_c10d._get_default_group() def _test_nccl_backend( self, devices, device_ids, multi_device=False, gradient_as_bucket_view=False ): process_group = self._get_process_group() self._test_ddp_with_process_group( process_group, devices, device_ids, multi_device, gradient_as_bucket_view ) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_propagate_error_reason(self): # Need to use TORCH_NCCL_BLOCKING_WAIT and not ASYNC_ERROR_HANDLING, # otherwise process will be taken down and we can't check for errors. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" os.environ["TORCH_NCCL_BLOCKING_WAIT"] = "1" # Need to disable TORCH_NCCL_DUMP_ON_TIMEOUT otherwise this test times out os.environ["TORCH_NCCL_DUMP_ON_TIMEOUT"] = "0" store = c10d.FileStore(self.file_name, self.world_size) # provide sufficient timeout to initialize NCCL comm. pg = c10d.ProcessGroupNCCL( store, self.rank, self.world_size, timeout=timedelta(seconds=15) ) pg_gloo = c10d.ProcessGroupGloo(store, self.rank, self.world_size) pg.barrier().wait(timedelta(seconds=5)) # Simulate stuckness in rank 0. if self.rank == 0: pg_gloo.barrier().wait() inp = torch.ones(1).cuda(self.rank) if self.rank != 0: # Time out due to rank 0 not calling into allreduce. with self.assertRaises(dist.DistBackendError): pg.allreduce([inp]).wait(timedelta(seconds=5)) # Now when nonzero rank attempts to use communicator, original failure reason should be logged. try: pg.allreduce([torch.ones(2).cuda(self.rank)]).wait() except dist.DistBackendError as e: self.assertTrue("aborted" in str(e)) else: self.fail("Expected error to be raised!") # Unblock rank 0 pg_gloo.barrier().wait() # TODO: We can also test that if rank 0 attempts to use the communicator, # then we should error out with the info that it was aborted due to # timeout on another rank. Although this would only be the case after # the watchdog has run on the rank, and there is no reliable way # to confirm it has run. @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_backend_multi_device_ids_not_allowed(self): int_devices = list(range(torch.cuda.device_count())) devices = [torch.device("cuda:" + str(i)) for i in int_devices] with self.assertRaisesRegex( ValueError, "device_ids can only be None or contain a single element." ): self._test_nccl_backend(devices, int_devices) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_backend_single_device_module_device_ids_None(self): self._test_nccl_backend(None, None) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_backend_single_device_module_empty_device_ids(self): # This tests the backward compatibility of accepting an empty list as `device_ids`, # although we no longer document this in favor of the default value of `None`, # which is consistent with multi-device modules and CPU modules. self._test_nccl_backend(None, []) @requires_nccl() @skip_if_lt_x_gpu(4) def test_nccl_backend_multi_device_module_device_ids_None(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:2] devices = [torch.device("cuda:" + str(i)) for i in int_devices] self._test_nccl_backend(devices, None, multi_device=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_backend_1gpu_module_device_ids_integer_list(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:1] devices = [torch.device("cuda:" + str(i)) for i in int_devices] self._test_nccl_backend(devices, int_devices) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_backend_1gpu_module_device_ids_torch_device_list(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:1] devices = [torch.device("cuda:" + str(i)) for i in int_devices] self._test_nccl_backend(devices, devices) @requires_nccl() @skip_if_lt_x_gpu(4) def test_nccl_backend_2gpu_module(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:2] devices = [torch.device("cuda:" + str(i)) for i in int_devices] self._test_nccl_backend(devices, None, multi_device=True) @requires_nccl() @skip_if_lt_x_gpu(8) def test_nccl_backend_4gpu_module(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:4] devices = [torch.device("cuda:" + str(i)) for i in int_devices] self._test_nccl_backend(devices, None, multi_device=True) @requires_nccl() @skip_if_lt_x_gpu(4) def test_ddp_multi_device_module_config(self): gpus = gpus_for_rank(self.world_size)[self.rank] self.assertTrue(len(gpus) >= 2, "expecting at least 2 gpus per process") process_group = self._get_process_group() gpus = gpus[:2] model = DoubleGpuNet(gpus) with self.assertRaisesRegex( ValueError, "DistributedDataParallel device_ids and output_device arguments only work with " "single-device/multiple-device GPU modules or CPU modules", ): ddp_model = DistributedDataParallel( model, output_device=gpus[1], process_group=process_group ) with self.assertRaisesRegex( ValueError, "device_ids can only be None or contain a single element." ): ddp_model = DistributedDataParallel( model, device_ids=gpus, process_group=process_group ) with self.assertRaisesRegex( ValueError, "input module must be on the same type of devices" ): model.fc1 = model.fc1.cpu() ddp_model = DistributedDataParallel(model, process_group=process_group) model = model.cpu() with self.assertRaisesRegex( ValueError, "device_ids can only be None or contain a single element." ): ddp_model = DistributedDataParallel( model, device_ids=gpus, process_group=process_group ) def _test_fp16(self, gradient_as_bucket_view=False): process_group = self._get_process_group() gpus = gpus_for_rank(self.world_size)[self.rank] model = nn.Linear(1, 1, bias=False).cuda(gpus[0]).half() nn.init.constant_(model.weight, 1) ddp_model = DistributedDataParallel( model, device_ids=[gpus[0]], process_group=process_group, bucket_cap_mb=0.001, gradient_as_bucket_view=gradient_as_bucket_view, ) # Input 2**15, so that the gradients will overflow with a # world_size of 2, unless we normalize the gradient by the # world_size before the reduction input = torch.tensor([[2**15]]).cuda(gpus[0]).half() # Step model ddp_model.train() output = ddp_model(input) loss = output.sum() loss.backward() self.assertFalse(any(torch.isinf(p.grad).any() for p in ddp_model.parameters())) @requires_nccl() @skip_if_lt_x_gpu(2) def test_fp16(self): self._test_fp16() @requires_nccl() @skip_if_lt_x_gpu(2) def test_fp16_grad_is_view(self): self._test_fp16(gradient_as_bucket_view=True) def _test_arbitrary_forward_return_value(self, gradient_as_bucket_view=False): """ Note: this test can be sped up by only running it on a CPU module once DistributedDataParallel supports them. """ process_group = self._get_process_group() class ForwardReturnValueModule(nn.Module): def __init__(self) -> None: super().__init__() self.fc1 = nn.Linear(2, 10, bias=False) self.fc2 = nn.Linear(10, 4, bias=False) self.fc3 = nn.Linear(4, 4, bias=False) self.relu = nn.ReLU() def forward(self, x, fn): x = self.relu(self.fc1(x)) x = self.relu(self.fc2(x)) # The first softmax does NOT include fc3 in its autograd graph # whereas the second softmax DOES. If we pass only the first # tensor we see in the output to the reducer, it marks the # gradient for fc3 as ready (because it doesn't show up). If # downstream uses of this return value choose to differentiate # against the second output tensor, it would still receive a # gradient and a callback for this tensor, resulting in a crash. return fn( F.softmax(x, dim=1), F.softmax(self.fc3(x), dim=1), ) device_id = gpus_for_rank(self.world_size)[self.rank][0] model = DistributedDataParallel( ForwardReturnValueModule().float().to(device_id), device_ids=[device_id], process_group=process_group, gradient_as_bucket_view=gradient_as_bucket_view, ) batch_size = 4 criterion = nn.CrossEntropyLoss() input = torch.rand([batch_size, 2], dtype=torch.float) target = torch.LongTensor([random.randrange(4) for _ in range(batch_size)]).to( device_id ) # Always run "backward" to ensure the reducer is called by autograd. # If we don't correctly capture the output tensors from the return value, # the reducer won't see a hook for the unused parameter, and throw an error. # The correct capture is what we're testing in this function. def test(box, unbox): output = model(input, fn=box) loss = criterion(unbox(output), target) loss.backward() # Test with identity return value test( box=lambda x, y: (x, y), unbox=lambda obj: obj[1], ) # Test with list return value test( box=lambda x, y: ["foo", x, "bar", y], unbox=lambda obj: obj[3], ) # Test with tuple return value test( box=lambda x, y: ("foo", x, "bar", y), unbox=lambda obj: obj[3], ) # Test with dict return value test( box=lambda x, y: {"foo": "bar", "a": x, "b": y}, unbox=lambda obj: obj["b"], ) # Test with list with dict return value test( box=lambda x, y: ["foo", "bar", {"a": x, "b": y}], unbox=lambda obj: obj[2]["b"], ) # Test with dict with list return value test( box=lambda x, y: {"foo": "bar", "list": [0, x, 1, y]}, unbox=lambda obj: obj["list"][3], ) @requires_nccl() @skip_if_lt_x_gpu(2) def test_arbitrary_forward_return_value(self): self._test_arbitrary_forward_return_value() @requires_nccl() @skip_if_lt_x_gpu(2) def test_arbitrary_forward_return_value_grad_is_view(self): self._test_arbitrary_forward_return_value(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_with_lazy_parameters(self): process_group = self._get_process_group() with self.assertRaisesRegex( RuntimeError, "Modules with uninitialized parameters" ): DistributedDataParallel( torch.nn.LazyLinear(10), process_group=process_group ) def _test_find_unused_parameters_kwarg(self, gradient_as_bucket_view=False): """ Note: this test can be sped up by only running it on a CPU module once DistributedDataParallel supports them. """ torch.cuda.set_device(self.rank) dist.init_process_group( backend="nccl", world_size=self.world_size, rank=self.rank, init_method=f"file://{self.file_name}", ) process_group = c10d.distributed_c10d._get_default_group() class FindUnusedParametersModule(nn.Module): def __init__(self) -> None: super().__init__() self.fc1 = nn.Linear(2, 10, bias=False) self.fc2 = nn.Linear(10, 4, bias=False) self.fc3 = nn.Linear(4, 4, bias=False) self.relu = nn.ReLU() def forward(self, x): x = self.relu(self.fc1(x)) x = self.relu(self.fc2(x)) # Return the fc3 module so that the caller can invoke it # outside of the forward function. While this is bad practice, # we can use it to trigger a reducer error. return (F.softmax(x, dim=1), self.fc3) device_id = gpus_for_rank(self.world_size)[self.rank][0] batch_size = 4 criterion = nn.CrossEntropyLoss() input = torch.rand([batch_size, 2], dtype=torch.float) target = torch.LongTensor([random.randrange(4) for _ in range(batch_size)]).to( device_id ) ddp_model = None def test_find_unused_parameters( find_unused_parameters, test_default=False, gradient_as_bucket_view=False ): if test_default: model = DistributedDataParallel( FindUnusedParametersModule().float().to(device_id), device_ids=[device_id], process_group=process_group, gradient_as_bucket_view=gradient_as_bucket_view, ) else: model = DistributedDataParallel( FindUnusedParametersModule().float().to(device_id), device_ids=[device_id], process_group=process_group, find_unused_parameters=find_unused_parameters, gradient_as_bucket_view=gradient_as_bucket_view, ) nonlocal ddp_model ddp_model = model output, fc3 = model(input) output = fc3(output) loss = criterion(output, target) loss.backward() # First test that finding unused params under these conditions is to # trigger an error when `backward` is called (because fc3 is an unused # parameter and will therefore be marked ready twice). try: test_find_unused_parameters( True, gradient_as_bucket_view=gradient_as_bucket_view ) except Exception as ex: self.assertTrue( str(ex).startswith( "Expected to mark a variable ready only once.", ) ) unused_index = 2 unused_index_str = f"Parameter at index {unused_index}" model = ddp_model.module for module_name, module in model.named_modules(): if module == model.fc3: for parameter_name, _ in module.named_parameters(recurse=False): unused_fqn = f"{module_name}.{parameter_name}" # Only one such parameter in model.fc3, since bias=False break if dist.get_debug_level() != dist.DebugLevel.OFF: unused_index_str += f" with name {unused_fqn}" self.assertTrue(unused_index_str in str(ex)) else: self.fail("Expected exception") dist.barrier(process_group) # Then test that the default behavior can be overridden by setting # `find_unused_parameters=False`. try: test_find_unused_parameters( False, gradient_as_bucket_view=gradient_as_bucket_view ) except Exception as ex: self.fail(f"Unexpected exception: {ex}") # Test find_unused_parameters defaults to False try: test_find_unused_parameters( True, test_default=True, gradient_as_bucket_view=gradient_as_bucket_view ) except Exception as ex: self.fail(f"Unexpected exception: {ex}") # TODO: Combine the following tests once https://github.com/pytorch/pytorch/issues/55967 # is resolved. @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["DETAIL"]) def test_find_unused_parameters_kwarg_debug_detail(self): self._test_find_unused_parameters_kwarg() @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["INFO"]) def test_find_unused_parameters_kwarg_debug_info(self): self._test_find_unused_parameters_kwarg() @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["OFF"]) def test_find_unused_parameters_kwarg_debug_off(self): self._test_find_unused_parameters_kwarg() @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["DETAIL"]) def test_find_unused_parameters_kwarg_grad_is_view_debug_detail(self): self._test_find_unused_parameters_kwarg(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["INFO"]) def test_find_unused_parameters_kwarg_grad_is_view_debug_info(self): self._test_find_unused_parameters_kwarg(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["OFF"]) def test_find_unused_parameters_kwarg_grad_is_view_debug_off(self): self._test_find_unused_parameters_kwarg(gradient_as_bucket_view=True) def _test_multiple_outputs_multiple_backward(self, gradient_as_bucket_view=False): """ Note: this test can be sped up by only running it on a CPU module once DistributedDataParallel supports them. """ process_group = self._get_process_group() class MultipleOutputModule(nn.Module): def __init__(self) -> None: super().__init__() def define_module(): return nn.Sequential( nn.Linear(2, 10, bias=False), nn.ReLU(), nn.Linear(10, 4, bias=False), nn.ReLU(), ) self.module0 = define_module() self.module1 = define_module() def forward(self, x): return ( F.softmax(self.module0(x), dim=1), F.softmax(self.module1(x), dim=1), ) device_id = gpus_for_rank(self.world_size)[self.rank][0] model = DistributedDataParallel( MultipleOutputModule().float().to(device_id), device_ids=[device_id], process_group=process_group, gradient_as_bucket_view=gradient_as_bucket_view, ) batch_size = 4 criterion = nn.CrossEntropyLoss() input = torch.rand([batch_size, 2], dtype=torch.float) target = torch.LongTensor([random.randrange(4) for _ in range(batch_size)]).to( device_id ) # Compute loss and gradients for both outputs output1, output2 = model(input) loss1 = criterion(output1, target) loss1.backward() loss2 = criterion(output2, target) loss2.backward() @requires_nccl() @skip_if_lt_x_gpu(2) def test_multiple_outputs_multiple_backward(self): self._test_multiple_outputs_multiple_backward() @requires_nccl() @skip_if_lt_x_gpu(2) def test_multiple_outputs_multiple_backward_grad_is_view(self): self._test_multiple_outputs_multiple_backward(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_no_grad(self): """ Note: this test can be sped up by only running it on a CPU module once DistributedDataParallel supports them. """ process_group = self._get_process_group() class NoGradModule(nn.Module): def __init__(self) -> None: super().__init__() self.fc1 = nn.Linear(2, 10, bias=False) self.fc2 = nn.Linear(10, 4, bias=False) self.relu = nn.ReLU() def forward(self, x): x = self.relu(self.fc1(x)) x = self.relu(self.fc2(x)) return F.softmax(x, dim=1) device_id = gpus_for_rank(self.world_size)[self.rank][0] model = DistributedDataParallel( NoGradModule().float().to(device_id), device_ids=[device_id], process_group=process_group, ) batch_size = 4 input = torch.rand([batch_size, 2], dtype=torch.float) def check_no_grads(): for p in model.parameters(): self.assertTrue(p.requires_grad) self.assertIsNone(p.grad) # After initialization, no parameter has their gradient set. check_no_grads() # Run `forward` function with torch.no_grad() with torch.no_grad(): output = model(input) self.assertTrue(isinstance(output, torch.Tensor)) # No parameter should have their gradient set. check_no_grads() def _test_accumulate_gradients_module(self, gradient_as_bucket_view=False): # This is NOT the recommended way to implement accumulating grads, but # we would like to make sure DDP does not mess up with the underlying # module. int_devices = gpus_for_rank(self.world_size)[self.rank][:1] devices = [torch.device("cuda:" + str(i)) for i in int_devices] process_group = self._get_process_group() global_batch_size = self.world_size model, ddp_model, input, target = self._prepare_single_device_module( process_group, devices, devices, global_batch_size, gradient_as_bucket_view ) def step_model(model, input, target): model.train() output = model(input) loss = F.mse_loss(output, target.to(output.device)) loss.backward() # ensure accumulate grads works with no_grad with torch.no_grad(): ddp_model.train() ddp_model.module(input) # Check two model parameters over 4 iterations. # Use 4 iterations because we alternate between reducing and # not reducing and want to make sure we switch both ways. for iteration in range(4): step_model(model, input, target) if iteration % 2 == 0: # Skip gradients sync without calling prepare_for_backward step_model( ddp_model.module, input[self.rank : (self.rank + 1)], target[self.rank : (self.rank + 1)], ) for i, j in zip(model.parameters(), ddp_model.parameters()): self.assertNotEqual(i.grad, j.grad) else: step_model( ddp_model, input[self.rank : (self.rank + 1)], target[self.rank : (self.rank + 1)], ) for i, j in zip(model.parameters(), ddp_model.parameters()): self.assertEqual(i.grad, j.grad, rtol=1.3e-06, atol=5e-5) # Shuffle the input so that DDP input is different torch.manual_seed(1337 + iteration) input = input[torch.randperm(global_batch_size)] @requires_nccl() @skip_if_lt_x_gpu(2) def test_accumulate_gradients_module(self): self._test_accumulate_gradients_module() @requires_nccl() @skip_if_lt_x_gpu(2) def test_accumulate_gradients_module_with_grad_is_view(self): self._test_accumulate_gradients_module(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_failure_recovery(self): process_group = self._get_process_group() # need to create a separate file for the recovered FileStore, because # the original one will be deleted when destructing the first FileStore. recovery_filename = self.file_name + "_recovery" if self.rank == 0: # the file will be deleted by the recovered FileStore open(recovery_filename, "w").close() # not necessary to run barrier here, as DDP will synchronize class TestModel(nn.Module): def __init__(self) -> None: super().__init__() self.fc1 = nn.Linear(2, 10, bias=False) self.fc2 = nn.Linear(10, 4, bias=False) self.relu = nn.ReLU() def forward(self, x): x = self.relu(self.fc1(x)) x = self.relu(self.fc2(x)) return F.softmax(x, dim=1) device_id = gpus_for_rank(self.world_size)[self.rank][0] model = TestModel().float().to(device_id) ddp = DistributedDataParallel( model, device_ids=[device_id], process_group=process_group, ) batch_size = 4 criterion = nn.CrossEntropyLoss() input = torch.rand([batch_size, 2], dtype=torch.float) target = torch.LongTensor([random.randrange(4) for _ in range(batch_size)]).to( device_id ) for _ in range(6): output = ddp(input) loss = criterion(output, target) loss.backward() del ddp c10d.destroy_process_group(process_group) store = c10d.FileStore(recovery_filename, self.world_size) c10d.init_process_group( "nccl", store=store, rank=self.rank, world_size=self.world_size ) process_group = c10d.distributed_c10d._get_default_group() ddp = DistributedDataParallel( model, device_ids=[device_id], process_group=process_group, ) input = torch.rand([batch_size, 2], dtype=torch.float) target = torch.LongTensor([random.randrange(4) for _ in range(batch_size)]).to( device_id ) for _ in range(6): output = ddp(input) loss = criterion(output, target) loss.backward() @requires_nccl() @skip_if_lt_x_gpu(2) def test_pass_default_pg(self): dist.init_process_group( "nccl", init_method=f"file://{self.file_name}", world_size=self.world_size, rank=self.rank, ) default_pg = c10d.distributed_c10d._get_default_group() dist.destroy_process_group(default_pg) self.assertFalse(dist.is_initialized()) def _test_grad_layout(self, replica_devices, layer_devs, local_batch_size): process_group = self._get_process_group() global_batch_size = local_batch_size * self.world_size # Carry out some trials with small buckets and some with big buckets. bucketsizes = (0.000001, 25) # Tuples of lists. Each list describes per-layer characteristics for one trial. layer_formats = ( [torch.contiguous_format] * 4, [torch.channels_last] * 2 + [torch.contiguous_format] * 2, [torch.channels_last] * 4, ) layer_dtypes = ( [torch.float] * 4, [torch.float] * 2 + [torch.half] * 2, [torch.half] * 4, ) input_dev = layer_devs[0] if isinstance(layer_devs, list) else layer_devs target_dev = layer_devs[-1] if isinstance(layer_devs, list) else layer_devs input = torch.randn( (global_batch_size, 8, 8, 8), device=input_dev, dtype=torch.float ) target = torch.randn( (global_batch_size, 8, 4, 4), device=target_dev, dtype=torch.float ) local_batch_start = self.rank * local_batch_size local_batch_end = (self.rank + 1) * local_batch_size # Reducer.cpp sneakily creates one "initial bucket" that ignores the "bucket_cap_mb" # argument. The following makes sure the initial bucket also complies. @contextmanager def first_bucket_size(ddp_bucket_mb): old_DEFAULT_FIRST_BUCKET_BYTES = dist._DEFAULT_FIRST_BUCKET_BYTES dist._DEFAULT_FIRST_BUCKET_BYTES = int(ddp_bucket_mb * 1.0e6) try: yield finally: dist._DEFAULT_FIRST_BUCKET_BYTES = old_DEFAULT_FIRST_BUCKET_BYTES with torch.backends.cudnn.flags( enabled=True, deterministic=True, benchmark=False ): for formats, dtypes, bucketsize in product( layer_formats, layer_dtypes, bucketsizes ): with first_bucket_size(bucketsize): model_msg = f"rank = {self.rank} formats = {formats} dtypes = {dtypes} bucketsize = {bucketsize} " try: m = ConvNet(layer_devs, formats, dtypes) m_ddp = DistributedDataParallel( copy.deepcopy(m), device_ids=replica_devices, process_group=process_group, bucket_cap_mb=bucketsize, ) opt = torch.optim.SGD(m.parameters(), lr=0.1) opt_ddp = torch.optim.SGD(m_ddp.parameters(), lr=0.1) has_half = any(p.dtype is torch.half for p in m.parameters()) tol = 1.0e-3 if has_half else 1.0e-5 except BaseException: # Prints case-specific debugging info to narrow down failing case. print( "Caught exception during model creation for " + model_msg, flush=True, ) raise # 3 iters: First iter creates grads, second iter retests after rebucketing, # third iter tries zeroed grads. for it in range(3): iter_msg = f"iter = {it} " + model_msg named_msg = iter_msg try: F.mse_loss(m(input).float(), target).backward() F.mse_loss( m_ddp(input[local_batch_start:local_batch_end]).float(), target[local_batch_start:local_batch_end], ).backward() for i, ((layer_name, m_child), m_ddp_child) in enumerate( zip(m.named_children(), m_ddp.module.children()) ): named_msg = layer_name + ".weight" + " " + iter_msg self.assertTrue( m_child.weight.grad.is_contiguous( memory_format=formats[i] ), named_msg, ) self.assertTrue( m_ddp_child.weight.grad.is_contiguous( memory_format=formats[i] ), named_msg, ) for j, ((param_name, p), p_ddp) in enumerate( zip( m_child.named_parameters(), m_ddp_child.parameters(), ) ): named_msg = ( layer_name + "." + param_name + " " + iter_msg ) self.assertEqual( p.grad, p_ddp.grad, rtol=tol, atol=tol ) opt.step() opt_ddp.step() if it == 0: for p, p_ddp in zip(m.parameters(), m_ddp.parameters()): p.grad = None p_ddp.grad = None else: m.zero_grad() m_ddp.zero_grad() except BaseException: # Makes sure we still get info if an error occurred somewhere other than the asserts. print( "Caught exception during iterations at " + named_msg, flush=True, ) raise @requires_nccl() @skip_if_lt_x_gpu(2) def test_grad_layout_1devicemodule_1replicaperprocess(self): dev0 = torch.device("cuda:" + str(gpus_for_rank(self.world_size)[self.rank][0])) # Tells DDP to use just one device. replica_devices = [dev0] # Tells _test_grad_layout to construct ConvNet with all layers on this process's first assigned device. layer_devs = dev0 local_batch_size = 8 self._test_grad_layout(replica_devices, layer_devs, local_batch_size) @requires_nccl() @skip_if_lt_x_gpu(4) @skip_if_rocm_multiprocess def test_grad_layout_2devicemodule(self): int_devices = gpus_for_rank(self.world_size)[self.rank][:2] dev0 = torch.device("cuda:" + str(int_devices[0])) dev1 = torch.device("cuda:" + str(int_devices[1])) # DDP's default behavior for a multi-device module is "don't replicate." replica_devices = None # Tells _test_grad_layout to constructs this process's ConvNet on 2 devices, with 2 layers on each device. layer_devs = [dev0] * 2 + [dev1] * 2 local_batch_size = 8 self._test_grad_layout(replica_devices, layer_devs, local_batch_size) @requires_nccl() @skip_if_lt_x_gpu(2) def test_param_layout_mismatch_error(self): process_group = self._get_process_group() dev0 = torch.device("cuda:" + str(gpus_for_rank(self.world_size)[self.rank][0])) layer_devs = dev0 layer_formats = ( [torch.contiguous_format] * 4 if self.rank == 0 else [torch.channels_last] * 4 ) layer_dtypes = [torch.float] * 4 m = ConvNet(layer_devs, layer_formats, layer_dtypes) if self.rank == 0: m_ddp = DistributedDataParallel( m, device_ids=[dev0], process_group=process_group ) else: with self.assertRaisesRegex( RuntimeError, ".* appears not to match strides of the same param in process 0", ): m_ddp = DistributedDataParallel( m, device_ids=[dev0], process_group=process_group ) def _gpu_model_with_ddp_comm_hook( self, process_group, hook=None, gradient_as_bucket_view=False, state=None, static_graph=False, ): device_id = gpus_for_rank(self.world_size)[self.rank][0] gpu_model = DistributedDataParallel( ModuleForDdpCommHook().to(device_id), device_ids=[device_id], process_group=process_group, gradient_as_bucket_view=gradient_as_bucket_view, static_graph=static_graph, ) # Register a DDP communication hook if any. if hook is not None: gpu_model.register_comm_hook(state, hook) return gpu_model @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_comm_hook_future_passing_gpu_nccl(self): """ This unit test verifies whether the Future object is passed properly using nccl backend. The hook callback function creates a Future object and sets a value to it. """ process_group = self._get_process_group() # Get GPU model with simple_hook registered. gpu_model = self._gpu_model_with_ddp_comm_hook(process_group, self._simple_hook) # check whether the grads are equal to what simple_hook's then callback returns. # without the comm_hook, result would be 0.25 * torch.ones(2, 2). self._run_and_verify_hook(gpu_model, 8, 2 * torch.ones(2, 2)) def _test_ddp_comm_hook_allreduce_hook_nccl( self, gradient_as_bucket_view=False, static_graph=False ): """ This unit test verifies whether a DDP communication hook that just calls allreduce gives the same result with the case of no hook registered. Without the then callback, the future_value in reducer is no longer a PyObject, and this unit test verifies future_value is properly checked. """ process_group = self._get_process_group() def allreduce_hook( state: object, bucket: dist.GradBucket ) -> torch.futures.Future[torch.Tensor]: tensors = [bucket.buffer() / self.world_size] return ( process_group.allreduce(tensors) .get_future() .then(lambda fut: fut.value()[0]) ) # Get GPU model with allreduce_hook registered. gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, allreduce_hook, gradient_as_bucket_view, static_graph ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) def _test_default_ddp_comm_hooks_nccl(self, gradient_as_bucket_view=False): """ This unit test verifies whether default Python DDP communication hooks ALLREDUCE, FP16_COMPRESS and BF16_COMPRESS, can give the same result with the case of no hook registered. """ process_group = self._get_process_group() # For these default DDP comm hooks, the only state is process group. state = process_group hook_options = [default.allreduce_hook, default.fp16_compress_hook] if ( not TEST_WITH_ROCM and BFLOAT16_AVAILABLE and c10d.is_nccl_available() and torch.cuda.nccl.version() >= (2, 10) ): hook_options.append(default.bf16_compress_hook) for hook in hook_options: # Get GPU model with the hook registered. # The first arg 'process_group' is used for initializing the test environment, # so it cannot be replaced by 'state', although they have the same value. gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, hook, gradient_as_bucket_view, state ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) def _test_fp16_compress_wrapper(self, gradient_as_bucket_view=False): """ This unit test verifies whether wrapping the ALLREDUCE and POWER_SGD hooks with the FP16_WRAPPER can give the same result as when there is no hook registered. """ process_group = self._get_process_group() powerSGD_state = powerSGD.PowerSGDState(process_group=process_group) hook_args = [ (powerSGD.powerSGD_hook, powerSGD_state), (default.allreduce_hook, process_group), ] for hook, state in hook_args: gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, default.fp16_compress_wrapper(hook), gradient_as_bucket_view, state, ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) def _test_bf16_compress_wrapper(self, gradient_as_bucket_view=False): """ This unit test verifies whether wrapping the ALLREDUCE and POWER_SGD hooks with the BF16_WRAPPER can give the same result as when there is no hook registered. """ process_group = self._get_process_group() powerSGD_state = powerSGD.PowerSGDState(process_group=process_group) hook_args = [ (powerSGD.powerSGD_hook, powerSGD_state), (default.allreduce_hook, process_group), ] for hook, state in hook_args: gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, default.bf16_compress_wrapper(hook), gradient_as_bucket_view, state, ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) def _test_powerSGD_ddp_comm_hook_nccl(self, gradient_as_bucket_view=False): """ This unit test verifies whether Python DDP communication hook POWER_SGD can give the same result with the case of no hook registered. """ process_group = self._get_process_group() # Get GPU model with the hook registered. # Test the hook with different algorithmic configs. for use_error_feedback, warm_start, batch_tensors_with_same_shape in product( [True, False], [True, False], [True, False], ): state = powerSGD.PowerSGDState( process_group=process_group, matrix_approximation_rank=1, use_error_feedback=use_error_feedback, warm_start=warm_start, batch_tensors_with_same_shape=batch_tensors_with_same_shape, ) for hook in [powerSGD.powerSGD_hook, powerSGD.batched_powerSGD_hook]: gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, hook, gradient_as_bucket_view, state ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) def _test_builtin_ddp_comm_hooks_nccl(self, gradient_as_bucket_view=False): """ This unit test verifies whether built-in C++ DDP communication hooks ALLREDUCE and FP16_COMPRESS can give the same result with the case of no hook registered. """ process_group = self._get_process_group() for comm_hook_type in [ dist.BuiltinCommHookType.ALLREDUCE, dist.BuiltinCommHookType.FP16_COMPRESS, ]: # Get GPU model with the built-in communication hook. gpu_model = self._gpu_model_with_builtin_ddp_comm_hook( process_group, comm_hook_type, gradient_as_bucket_view ) # check whether the grads are equal to what DDP without hook would return. self._run_and_verify_hook(gpu_model, 8, 0.25 * torch.ones(2, 2)) @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_comm_hook_allreduce_hook_nccl(self): self._test_ddp_comm_hook_allreduce_hook_nccl() @requires_nccl() @skip_if_lt_x_gpu(2) def test_default_ddp_comm_hooks_nccl(self): self._test_default_ddp_comm_hooks_nccl() @requires_nccl() @skip_if_lt_x_gpu(2) def test_fp16_compress_wrapper_nccl(self): self._test_fp16_compress_wrapper() @requires_nccl() @requires_nccl_version((2, 10), "Need NCCL 2.10+ for BF16_COMPRESS") @skip_but_pass_in_sandcastle_if( not BFLOAT16_AVAILABLE, "BFloat16 is only supported by CUDA 11+", ) @skip_if_lt_x_gpu(2) def test_bf16_compress_wrapper_nccl(self): self._test_bf16_compress_wrapper() @requires_nccl() @skip_if_lt_x_gpu(2) def test_builtin_ddp_comm_hooks_nccl(self): self._test_builtin_ddp_comm_hooks_nccl() @requires_nccl() @skip_if_lt_x_gpu(2) def test_powerSGD_ddp_comm_hook_nccl(self): self._test_powerSGD_ddp_comm_hook_nccl() @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_comm_hook_allreduce_hook_nccl_grad_is_view(self): self._test_ddp_comm_hook_allreduce_hook_nccl(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_comm_hook_allreduce_hook_nccl_static_graph(self): self._test_ddp_comm_hook_allreduce_hook_nccl(static_graph=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_default_ddp_comm_hooks_nccl_is_view(self): self._test_default_ddp_comm_hooks_nccl(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_fp16_compress_wrapper_is_view(self): self._test_fp16_compress_wrapper(gradient_as_bucket_view=True) @requires_nccl() @requires_nccl_version((2, 10), "Need NCCL 2.10+ for BF16_COMPRESS") @skip_but_pass_in_sandcastle_if( not BFLOAT16_AVAILABLE, "BFloat16 is only supported by CUDA 11+", ) @skip_if_lt_x_gpu(2) def test_bf16_compress_wrapper_is_view(self): self._test_bf16_compress_wrapper(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_builtin_ddp_comm_hooks_nccl_grad_is_view(self): self._test_builtin_ddp_comm_hooks_nccl(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_powerSGD_ddp_comm_hook_nccl_grad_is_view(self): self._test_powerSGD_ddp_comm_hook_nccl(gradient_as_bucket_view=True) @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_comm_hook_allreduce_with_then_hook_nccl(self): """ This unit test verifies whether a DDP communication hook that calls allreduce and then multiplies the result by ten and divides by two gives the expected result. """ process_group = self._get_process_group() def allreduce_with_then_hook( state: object, bucket: dist.GradBucket ) -> torch.futures.Future[torch.Tensor]: tensors = [bucket.buffer() / self.world_size] fut = process_group.allreduce(tensors).get_future() def mult(fut): # Multiply the result by 10. return 10 * fut.value()[0] def div(fut): # Divide the result by 2. return 0.5 * fut.value() return fut.then(mult).then(div) # Get GPU model with allreduce_with_then_hook registered. gpu_model = self._gpu_model_with_ddp_comm_hook( process_group, allreduce_with_then_hook ) # check whether the grads are equal to what allreduce returns multiplied by 5. # without the comm_hook, result would be still 0.25 * torch.ones(2, 2). self._run_and_verify_hook(gpu_model, 8, 1.25 * torch.ones(2, 2)) class AcceptsParam(torch.nn.Module): def __init__(self, p, factor): super().__init__() self.a = p self.f = factor def forward(self, input): return input + self.a * self.f @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_weight_sharing(self): process_group = self._get_process_group() size = 2048 * 2048 dev = self.rank world = self.world_size p = torch.nn.Parameter(torch.randn(size, requires_grad=True)) for try_set_to_none, use_bucket_view in product((False, True), (False, True)): m = torch.nn.Sequential( self.AcceptsParam(p, dev + 1), self.AcceptsParam(p, dev + 1) ).cuda(dev) m = torch.nn.parallel.DistributedDataParallel( m, bucket_cap_mb=1, gradient_as_bucket_view=use_bucket_view, device_ids=[dev], process_group=process_group, ) for i in range(3): m.zero_grad(set_to_none=try_set_to_none) m(1).sum().backward() # Each param value is multiplied by "rank + 1" twice in forward, so the grad # values produced by a particular rank should be 2. * (rank + 1). # Summing these over ranks and dividing by world size gives the expected result: analytic = torch.full_like( p, 2.0 * (world * (world + 1.0) / 2.0) / world, device=dev ) for name, p in m.named_parameters(): self.assertEqual( p.grad, analytic, "mismatch at " + name + ".grad for " + f"set_to_none = {try_set_to_none}, use_bucket_view = {use_bucket_view}", ) @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_packed_sequence(self): """ Tests that DDP with ``device_ids`` specified can run a forward and backward pass with ``PackedSequence`` s with parity compared to a local version of the model. """ store = c10d.FileStore(self.file_name, self.world_size) process_group = dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) seqs = ["sequence_sequence", "seq", "sequence"] vocab = [""] + sorted({ch for seq in seqs for ch in seq}) vectorized_seqs = [[vocab.index(tok) for tok in seq] for seq in seqs] # Set the seed to make the embedding and LSTM deterministic (even # across ranks since DDP broadcasts parameters from rank 0) torch.manual_seed(0) embed = nn.Embedding(len(vocab), 4) # keep on CPU lstm = nn.LSTM(input_size=4, hidden_size=2, batch_first=True).to(self.rank) lstm_ddp = DistributedDataParallel( copy.deepcopy(lstm), device_ids=[self.rank], process_group=process_group, ) for p1, p2 in zip(lstm.parameters(), lstm_ddp.module.parameters()): self.assertEqual(p1, p2) seq_lengths = torch.LongTensor(list(map(len, vectorized_seqs))) seq_tensor = torch.Tensor( torch.zeros((len(vectorized_seqs), seq_lengths.max())) ).long() for i, (seq, seq_len) in enumerate(zip(vectorized_seqs, seq_lengths)): seq_tensor[i, :seq_len] = torch.LongTensor(seq) seq_lengths, permutation_idx = seq_lengths.sort(0, descending=True) seq_tensor = seq_tensor[permutation_idx] embedded_seq_tensor = embed(seq_tensor) packed_input = torch.nn.utils.rnn.pack_padded_sequence( embedded_seq_tensor, seq_lengths, batch_first=True, ) packed_input_ddp = torch.nn.utils.rnn.pack_padded_sequence( embedded_seq_tensor.detach().clone(), seq_lengths, batch_first=True, ) # Move the input to GPU explicitly for the local model packed_output, (ht, ct) = lstm(packed_input.to(self.rank)) # Let DDP move the input to GPU internally packed_output_ddp, (ht_ddp, ct_ddp) = lstm_ddp(packed_input_ddp) self.assertEqual(packed_output.data, packed_output_ddp.data) self.assertEqual(ht, ht_ddp) self.assertEqual(ct, ct_ddp) packed_output.data.sum().backward() packed_output_ddp.data.sum().backward() for p1, p2 in zip(lstm.parameters(), lstm_ddp.parameters()): self.assertEqual(p1.grad, p2.grad) @requires_nccl() @skip_if_lt_x_gpu(2) def test_channels_last_contig(self): process_group = self._get_process_group() device = torch.device(f"cuda:{self.rank}") tensor = torch.ones((2, 16, 768, 1152), dtype=torch.float32, device=device).to( memory_format=torch.channels_last ) process_group.broadcast([tensor]).wait() @requires_nccl() @skip_if_lt_x_gpu(2) def test_ddp_complex_params(self): class FFTModel(nn.Module): def __init__(self, hin, win, n_features): super().__init__() self.hin = hin self.win = win self.weight = nn.Parameter( torch.ones( (n_features, n_features, hin, win // 2 + 1), dtype=torch.cfloat ) ) def forward(self, x): xc = torch.fft.rfft2( x, s=(self.hin, self.win), dim=(-2, -1), norm="ortho" ) xcw = torch.einsum("nchw,cohw->nohw", xc, self.weight) x = torch.fft.irfft2(xcw, dim=(-2, -1), norm="ortho") return x process_group = self._get_process_group() device_id = gpus_for_rank(self.world_size)[self.rank][0] N, C, H, W = 1, 16, 64, 64 ddp_model = DistributedDataParallel( FFTModel(hin=H, win=W, n_features=C).to(device_id), device_ids=[device_id], process_group=process_group, ) optimizer = torch.optim.Adam(ddp_model.parameters(), lr=0.001) inp = torch.ones((N, C, H, W), dtype=torch.float32) # train step out = ddp_model(inp) loss = torch.sum(out) loss.backward() optimizer.step() torch.cuda.synchronize(device=device_id) class WorkHookTest(MultiProcessTestCase): @property def world_size(self): return 2 def setUp(self): super().setUp() # set TORCH_NCCL_ENABLE_TIMING to enable timing for CUDAEvents # in ProcessGroup Work os.environ["TORCH_NCCL_ENABLE_TIMING"] = "1" self._spawn_processes() def tearDown(self): super().tearDown() del os.environ["TORCH_NCCL_ENABLE_TIMING"] try: os.remove(self.file_name) except OSError: pass def _get_store(self): return dist.FileStore(self.file_name, self.world_size) def _get_process_group(self): store = self._get_store() c10d.init_process_group( "nccl", store=store, rank=self.rank, world_size=self.world_size ) return c10d.distributed_c10d._get_default_group() @requires_nccl() @skip_if_lt_x_gpu(2) def test_on_completion_hook_broadcast(self): pg = self._get_process_group() num_hook_fired = 0 durations: List[float] = [] def hook(work_info: torch._C._distributed_c10d.WorkInfo): nonlocal num_hook_fired, durations num_hook_fired += 1 durations.append(work_info.active_duration.total_seconds()) pg._register_on_completion_hook(hook) tensor = torch.ones([2, 3]).cuda(self.rank) * self.rank pg.broadcast([tensor]).wait() pg.broadcast([tensor]).wait() # N.B.: destroy_process_group is necessary to wait for # all pending works to finish. c10d.destroy_process_group(pg) self.assertEqual(num_hook_fired, 2) self.assertEqual(len(durations), 2) for duration in durations: self.assertTrue(duration > 0) self.assertEqual(tensor, torch.zeros([2, 3]).cuda(self.rank)) @requires_nccl() @skip_if_lt_x_gpu(2) def test_on_completion_hook_mixed_ops(self): pg = self._get_process_group() num_hook_fired = 0 durations: List[float] = [] def hook(work_info: torch._C._distributed_c10d.WorkInfo): nonlocal num_hook_fired, durations num_hook_fired += 1 durations.append(work_info.active_duration.total_seconds()) pg._register_on_completion_hook(hook) tensor = torch.ones([2, 3]).cuda(self.rank) tensor_list = [torch.empty_like(tensor) for _ in range(self.world_size)] # intentionally using async ops. pg.allreduce(tensor) pg.allgather(tensor_list, tensor) pg.allreduce(tensor) # N.B.: destroy_process_group is necessary to wait for # all pending works to finish. c10d.destroy_process_group(pg) self.assertEqual(num_hook_fired, 3) self.assertEqual(len(durations), 3) for duration in durations: self.assertTrue(duration > 0) self.assertEqual( tensor, torch.ones([2, 3]).cuda(self.rank) * self.world_size * self.world_size, ) self.assertEqual( tensor_list, [ torch.ones([2, 3]).cuda(self.rank) * self.world_size for _ in range(self.world_size) ], ) @requires_nccl() @skip_if_lt_x_gpu(2) def test_on_completion_hook_with_ddp(self): pg = self._get_process_group() num_hook_fired: Dict[int, int] = {} durations: Dict[OpType, List[float]] = {} def hook(work_info: torch._C._distributed_c10d.WorkInfo): nonlocal num_hook_fired, durations op_type = work_info.op_type if op_type not in num_hook_fired: num_hook_fired[op_type] = 0 durations[op_type] = [] num_hook_fired[op_type] += 1 durations[op_type].append(work_info.active_duration.total_seconds()) pg._register_on_completion_hook(hook) nlayers = 10 net = nn.Sequential( *[nn.Linear(1000, 1000, bias=False) for _ in range(nlayers)] ).to(self.rank) ddp = DistributedDataParallel( net, device_ids=[self.rank], process_group=pg, bucket_cap_mb=1, ) pg._wait_for_pending_works() # DDP is expected to synchronize model parameter by broadcasting # from rank0 to other ranks. However, this is DDP's internal implementation, # which is subject to change in future versions. self.assertTrue(num_hook_fired[OpType.BROADCAST] > 0) ctor_allreduce = ( num_hook_fired[OpType.ALLREDUCE] if OpType.ALLREDUCE in num_hook_fired else 0 ) x = torch.zeros(2, 1000).cuda(self.rank) ddp(x).sum().backward() c10d.destroy_process_group(pg) self.assertTrue(OpType.ALLREDUCE in num_hook_fired) # The number of allreduce ops depend on DDP internal implementation, but # there should be at least one allreduce. self.assertTrue(num_hook_fired[OpType.ALLREDUCE] - ctor_allreduce > 0) self.assertTrue(all(duration > 0 for duration in chain(*(durations.values())))) # Not testing FSDP due to https://github.com/pytorch/pytorch/issues/90848. # We cannot disable workCleanupLoop() as hooks are fired in that thread. @requires_nccl() @skip_if_lt_x_gpu(2) def test_on_completion_hook_all_gather_object(self): torch.cuda.set_device(self.rank) pg = self._get_process_group() num_hook_fired: Dict[int, int] = {} durations: Dict[OpType, List[float]] = {} def hook(work_info: torch._C._distributed_c10d.WorkInfo): nonlocal num_hook_fired, durations op_type = work_info.op_type if op_type not in num_hook_fired: num_hook_fired[op_type] = 0 durations[op_type] = [] num_hook_fired[op_type] += 1 durations[op_type].append(work_info.active_duration.total_seconds()) pg._register_on_completion_hook(hook) obj = {"rank": self.rank, "world_size": self.world_size} obj_list = [None for _ in range(self.world_size)] c10d.all_gather_object(obj_list, obj, group=pg) for r, o in enumerate(obj_list): self.assertTrue(isinstance(o, dict)) self.assertTrue(set(o.keys()), {"rank", "world_size"}) self.assertEqual(o["rank"], r) self.assertEqual(o["world_size"], self.world_size) c10d.destroy_process_group(pg) self.assertTrue(OpType.ALLGATHER in num_hook_fired) self.assertEqual(len(num_hook_fired), 1) # two allgathers, one for size and another for values self.assertEqual(num_hook_fired[OpType.ALLGATHER], 2) self.assertTrue(all(duration > 0 for duration in durations[OpType.ALLGATHER])) @requires_nccl() @skip_if_lt_x_gpu(2) def test_on_completion_hook_seq(self): pg = self._get_process_group() num_hook_fired = 0 seq: int = -1 work: int = 0 def hook(work_info: torch._C._distributed_c10d.WorkInfo): nonlocal num_hook_fired, seq num_hook_fired += 1 seq = work_info.seq pg._register_on_completion_hook(hook) tensor = torch.ones([2, 3]).cuda(self.rank) * self.rank work_count = 3 for i in range(work_count): work += 1 pg.broadcast([tensor]).wait() # N.B.: destroy_process_group is necessary to wait for # all pending works to finish. c10d.destroy_process_group(pg) self.assertEqual(num_hook_fired, work_count) self.assertEqual(work, seq) class NcclErrorHandlingTest(MultiProcessTestCase): def setUp(self): super().setUp() # Need to skip return code checking for these tests since the child # processes don't exit cleanly. self.skip_return_code_checks = [ self.test_nccl_errors_blocking_abort.__wrapped__, self.test_nccl_errors_blocking_sigkill.__wrapped__, self.test_nccl_errors_blocking_sigterm.__wrapped__, self.test_nccl_errors_blocking_nonzero_exit.__wrapped__, ] # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass @property def op_timeout_sec(self): return 3 @property def world_size(self): return 3 @property def blocking_wait_error_msg(self): return "timeout" def _run_all_reduce(self, pg): pg.allreduce(torch.rand(10).cuda(self.rank)) @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess @skip_but_pass_in_sandcastle("Test does not pass when run locally") def test_nccl_errors_nonblocking(self): # Note: we unset and restore TORCH_NCCL_ASYNC_ERROR_HANDLING for this test # since test_c10d_common runs with async error handling by default, but this # tests behavior when it is not enabled. prev_nccl_async_error_handling = os.environ.get( "TORCH_NCCL_ASYNC_ERROR_HANDLING", None ) os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "0" store = c10d.FileStore(self.file_name, self.world_size) process_group = c10d.ProcessGroupNCCL(store, self.rank, self.world_size) process_group.allreduce(torch.rand(10).cuda(self.rank)) if self.rank == 0: # This allreduce does not block Python thread as allreduce enqueues # the cuda operation, and then wait only blocks the current cuda # stream. work = process_group.allreduce(torch.rand(10).cuda(self.rank)) work.wait() # Now the work scheduled next should hang forever since the previous # allreduce will never complete. t = threading.Thread(target=self._run_all_reduce, args=(process_group,)) t.daemon = True t.start() t.join(int(get_timeout(self.id()) / 5)) self.assertTrue(t.is_alive()) if prev_nccl_async_error_handling is not None: os.environ[ "TORCH_NCCL_ASYNC_ERROR_HANDLING" ] = prev_nccl_async_error_handling def _test_nccl_errors_blocking(self, func): store = c10d.FileStore(self.file_name, self.world_size) process_group = c10d.ProcessGroupNCCL( store, self.rank, self.world_size, timeout=timedelta(seconds=10), ) process_group.allreduce(torch.rand(10).cuda(self.rank)) if self.rank == 0: work = process_group.allreduce(torch.rand(10).cuda(self.rank)) with self.assertRaisesRegex(dist.DistBackendError, ""): # It seems the error message would be different depending on # whether the test is run on CI machine and devGPU. Skipping # the error message check to make both sides happy. work.wait(timeout=timedelta(seconds=self.op_timeout_sec)) # Run some GPU operations to make sure cuda has not gotten stuck. # It was observed cuda could get stuck if NCCL communicators were # not properly aborted before throwing RuntimeError. a = torch.rand(10).cuda(self.rank) elif self.rank == 1: # Clean up structures (ex: files for FileStore before going down) del process_group func() @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess def test_nccl_errors_blocking_clean_exit(self): self._test_nccl_errors_blocking(lambda: sys.exit(0)) @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess def test_nccl_errors_blocking_nonzero_exit(self): self._test_nccl_errors_blocking(lambda: sys.exit(1)) @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess @skip_but_pass_in_sandcastle( "Frequently times out see https://github.com/pytorch/pytorch/issues/58920" ) def test_nccl_errors_blocking_abort(self): self._test_nccl_errors_blocking(lambda: os.abort()) @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess def test_nccl_errors_blocking_sigkill(self): self._test_nccl_errors_blocking(lambda: os.kill(os.getpid(), signal.SIGKILL)) @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) @skip_if_rocm_multiprocess def test_nccl_errors_blocking_sigterm(self): self._test_nccl_errors_blocking(lambda: os.kill(os.getpid(), signal.SIGTERM)) @with_nccl_blocking_wait @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(3) def test_nccl_blocking_wait_with_barrier(self): store = c10d.FileStore(self.file_name, self.world_size) process_group = c10d.ProcessGroupNCCL( store, self.rank, self.world_size, timeout=timedelta(seconds=10), ) process_group.barrier().wait() if self.rank == 0: with self.assertRaisesRegex(dist.DistBackendError, ""): # It seems the error message would be different depending on # whether the test is run on CI machine and devGPU. Skipping # the error message check to make both sides happy. process_group.barrier().wait( timeout=timedelta(seconds=self.op_timeout_sec) ) def _run_invalid_nccl_blocking_wait_env(self, val): os.environ["TORCH_NCCL_BLOCKING_WAIT"] = val store = c10d.FileStore(self.file_name, self.world_size) with self.assertRaises(RuntimeError): process_group = c10d.ProcessGroupNCCL(store, self.rank, self.world_size) @requires_nccl() @skip_if_lt_x_gpu(3) def test_invalid_nccl_blocking_wait_env(self): self._run_invalid_nccl_blocking_wait_env("abc") self._run_invalid_nccl_blocking_wait_env("-1") self._run_invalid_nccl_blocking_wait_env("2147483647") self._run_invalid_nccl_blocking_wait_env("4294967295") @with_nccl_blocking_wait @requires_nccl() @requires_gloo() @skip_if_lt_x_gpu(3) def test_nccl_timeout(self): store = c10d.FileStore(self.file_name, self.world_size) # Initialize process_group. process_group = c10d.ProcessGroupNCCL( store, self.rank, self.world_size, timeout=timedelta(seconds=10) ) # Control gloo pg used as go-ahead signal/barrier # to coordinate btwn ranks. pg_gloo = c10d.ProcessGroupGloo(store, self.rank, self.world_size) failed_collective_timeout = timedelta(milliseconds=100) process_group.allreduce(torch.rand(10).cuda(self.rank)).wait( timeout=timedelta(seconds=5) ) if self.rank == 0: # This should timeout in about 1 second. # Watchdog may abort timed out work resulting in NCCL error instead of operation timed out. with self.assertRaisesRegex( dist.DistBackendError, self.blocking_wait_error_msg ): process_group.allreduce(torch.rand(10).cuda(self.rank)).wait( timeout=failed_collective_timeout ) # Now do a barrier to tell other rank to go ahead. pg_gloo.barrier().wait() else: # Wait on rank 0 to fail. try: pg_gloo.barrier().wait() except Exception as e: raise ValueError( f"Rank {self.rank} barrier timed out waiting for rank 0 with error: {str(e)}" ) from e class CommTest(test_c10d_common.AbstractCommTest, MultiProcessTestCase): @property def device(self): return f"cuda:{self.rank}" def setUp(self): super().setUp() # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass def _test_broadcast_coalesced(self, process_group, device, root_rank): half = torch.float16 # No support for float16 for CPU tensors if device == torch.device("cpu"): half = torch.float32 target = torch.arange(60, dtype=half, device=device).chunk(5) target += torch.arange(60, dtype=torch.float32, device=device).chunk(5) target += torch.arange(60, dtype=half, device=device).chunk(5) target += torch.arange(60, dtype=torch.float64, device=device).chunk(5) target += torch.arange(60, dtype=half, device=device).chunk(5) target += torch.arange(60, dtype=torch.float32, device=device).chunk(5) # The tensors to pass to broadcast are identical to the target # only on the process that is the root of the broadcast. if self.rank == root_rank: tensors = [tensor.clone() for tensor in target] else: tensors = [torch.zeros_like(tensor) for tensor in target] if self.rank != root_rank: self.assertNotEqual(tensors, target) c10d._broadcast_coalesced( process_group, tensors, buffer_size=256, src=root_rank ) if self.rank != root_rank: self.assertEqual(tensors, target) @requires_nccl() @skip_if_lt_x_gpu(2) def test_broadcast_coalesced_nccl(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) process_group = c10d.distributed_c10d._get_default_group() device = torch.device("cuda:%d" % self.rank) ranks = [0, 1] for root_rank in ranks: self._test_broadcast_coalesced(process_group, device, root_rank) @requires_nccl() @skip_if_lt_x_gpu(2) def test_all_reduce_coalesced_nccl(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) process_group = c10d.distributed_c10d._get_default_group() device = torch.device("cuda:%d" % self.rank) tensors = [ torch.full((60 + i,), self.rank + 1 + i, device=device, dtype=torch.float) for i in range(5) ] torch.distributed.all_reduce_coalesced(tensors, group=process_group) for i, t in enumerate(tensors): self.assertEqual( t, torch.full_like( t, self.world_size * (i + (self.world_size + 1.0) / 2.0) ), ) @requires_nccl() @skip_if_lt_x_gpu(2) def test_all_reduce_coalesced_nccl_float8_errors(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) process_group = c10d.distributed_c10d._get_default_group() device = torch.device("cuda:%d" % self.rank) tensors = [ torch.full( (60 + i,), self.rank + 1 + i, device=device, dtype=torch.float ).to(torch.float8_e4m3fn) for i in range(5) ] with self.assertRaisesRegex( RuntimeError, "Float8 dtypes are not currenlty supported for NCCL reductions", ): torch.distributed.all_reduce_coalesced(tensors, group=process_group) @requires_nccl() @skip_if_lt_x_gpu(2) def test_all_reduce_coalesced_manager_nccl(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=self.world_size ) process_group = c10d.distributed_c10d._get_default_group() device = torch.device("cuda:%d" % self.rank) tensors = [ torch.full((60 + i,), self.rank + 1 + i, device=device, dtype=torch.float) for i in range(5) ] with torch.distributed._coalescing_manager( group=process_group, device=device, async_ops=True ) as cm: for tensor in tensors: torch.distributed.all_reduce(tensor) self.assertEqual(len(cm.works), 1) cm.wait() for i, t in enumerate(tensors): self.assertEqual( t, torch.full_like( t, self.world_size * (i + (self.world_size + 1.0) / 2.0) ), ) @requires_nccl() @skip_if_lt_x_gpu(2) @skip_if_rocm_multiprocess def test_intra_node_comm_all_reduce(self): from torch._C._distributed_c10d import _get_intra_node_comm_usage_counter from torch.testing._internal.common_cuda import SM80OrLater for peer in range(self.world_size): if peer == self.rank: continue if not torch._C._cuda_canDeviceAccessPeer(self.rank, peer): raise SkipTest("Test requires p2p access") if not SM80OrLater: raise SkipTest("Test requires sm>=80") store = c10d.FileStore(self.file_name, self.world_size) os.environ["ENABLE_INTRA_NODE_COMM"] = "1" os.environ["TEST_INTRA_NODE_COMM"] = "1" torch.cuda.set_device(self.rank) c10d.init_process_group( backend="nccl", rank=self.rank, world_size=self.world_size, store=store ) expect = self.world_size * (self.world_size - 1) // 2 # IntraNodeComm currently only supports sum and bf16. # Verify that it is not used in the next two configurations. t = torch.full((4 * 1024 // 2,), self.rank).cuda() c10d.all_reduce(t, c10d.ReduceOp.SUM) self.assertTrue(t.eq(expect).all()) self.assertEqual(_get_intra_node_comm_usage_counter(), 0) t = torch.full((4 * 1024 // 2,), self.rank, dtype=torch.bfloat16).cuda() c10d.all_reduce(t, c10d.ReduceOp.AVG) self.assertEqual(_get_intra_node_comm_usage_counter(), 0) # Verify that IntraNodeComm is used up to 10MB t = torch.full((4 * 1024 // 2,), self.rank, dtype=torch.bfloat16).cuda() c10d.all_reduce(t, c10d.ReduceOp.SUM) self.assertTrue(t.eq(expect).all()) self.assertEqual(_get_intra_node_comm_usage_counter(), 1) t = torch.full((512 * 1024 // 2,), self.rank, dtype=torch.bfloat16).cuda() c10d.all_reduce(t, c10d.ReduceOp.SUM) self.assertTrue(t.eq(expect).all()) self.assertEqual(_get_intra_node_comm_usage_counter(), 2) t = torch.full((10 * 1024**2 // 2,), self.rank, dtype=torch.bfloat16).cuda() c10d.all_reduce(t, c10d.ReduceOp.SUM) self.assertTrue(t.eq(expect).all()) self.assertEqual(_get_intra_node_comm_usage_counter(), 3) # Verify that IntraNodeComm is not used beyond 10MB t = torch.full( (10 * 1024**2 // 2 + 1,), self.rank, dtype=torch.bfloat16 ).cuda() c10d.all_reduce(t, c10d.ReduceOp.SUM) self.assertTrue(t.eq(expect).all()) self.assertEqual(_get_intra_node_comm_usage_counter(), 3) c10d.destroy_process_group() @requires_nccl() @skip_if_lt_x_gpu(2) def test_sequence_num_set_default_pg_nccl(self): torch.cuda.set_device(self.rank) self._test_sequence_num_set_default_pg(backend="nccl") @skip_if_lt_x_gpu(2) @requires_nccl() def test_sequence_num_incremented_nccl_default(self): self._test_sequence_num_incremented_default_group("nccl") @skip_if_lt_x_gpu(4) @requires_nccl() def test_sequence_num_incremented_nccl_subgroup(self): if self.world_size < 4: return skip_but_pass_in_sandcastle("Test requires world_size of at least 4") self._test_sequence_num_incremented_subgroup("nccl") @requires_nccl() @skip_if_lt_x_gpu(2) def test_sequence_num_set_nccl_new_group(self): torch.cuda.set_device(self.rank) self._test_sequence_num_set_new_group(backend="nccl") def _test_pass_nccl_options(self, pg_opts): store = c10d.FileStore(self.file_name, self.world_size) # Test init_process_group accepts options dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, pg_options=pg_opts, ) # Test with new_group pg = c10d.new_group([0, 1], pg_options=pg_opts) # test the process group works as expected t = torch.tensor([self.rank + 1] * 10).cuda(self.rank) pg.allreduce(t).wait() expected_tensor = torch.tensor([3] * 10).cuda(self.rank) self.assertEqual(expected_tensor, t) @requires_nccl() @skip_if_lt_x_gpu(2) def test_pass_nccl_options_high_priority_stream(self): pg_opts = c10d.ProcessGroupNCCL.Options() pg_opts.is_high_priority_stream = True self._test_pass_nccl_options(pg_opts) @requires_nccl() @requires_nccl_version( (2, 18), "Need NCCL 2.17+ for configuring NCCL communicators" ) @skip_if_lt_x_gpu(2) def test_pass_nccl_options_config(self): pg_opts = c10d.ProcessGroupNCCL.Options() pg_opts.config.max_ctas = 4 pg_opts.config.min_ctas = 2 pg_opts.config.cga_cluster_size = 2 pg_opts.config.net_name = "Socket" pg_opts.config.split_share = 1 nccl_debug_file = tempfile.NamedTemporaryFile() os.environ["NCCL_DEBUG"] = "INFO" os.environ["NCCL_DEBUG_FILE"] = nccl_debug_file.name # Tests functionality when passing nccl config self._test_pass_nccl_options(pg_opts) # Tests if comms were configured nccl_debug_file_content = nccl_debug_file.read() max_ctas = re.search(rb"Max CTAs.*(\d+)|$", nccl_debug_file_content).group(1) min_ctas = re.search(rb"Min CTAs.*(\d+)|$", nccl_debug_file_content).group(1) split_share = re.search( rb"Split share.*(\d+)|$", nccl_debug_file_content ).group(1) cga_cluster_size = re.search( rb"CGA cluster.*(\d+)|$", nccl_debug_file_content ).group(1) net_name = re.search( rb"Using network.([a-zA-z]+)|$", nccl_debug_file_content ).group(1) self.assertEqual(pg_opts.config.max_ctas, int(max_ctas)) self.assertEqual(pg_opts.config.min_ctas, int(min_ctas)) self.assertEqual(pg_opts.config.cga_cluster_size, int(cga_cluster_size)) self.assertEqual(pg_opts.config.net_name, net_name.decode()) self.assertEqual(pg_opts.config.split_share, int(split_share)) @requires_nccl() @skip_if_lt_x_gpu(4) def test_nccl_barrier(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", rank=self.rank, world_size=self.world_size, store=store ) t = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) c10d.all_reduce(t) expected_tensor = torch.tensor([3] * 10).cuda(2 * self.rank) self.assertEqual(expected_tensor, t) # Test with new_group pg = c10d.new_group([0, 1]) t = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) pg.allreduce(t).wait() self.assertEqual(expected_tensor, t) pg = c10d.new_group([0]) if self.rank == 0: t = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) expected_tensor = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) pg.allreduce(t).wait() self.assertEqual(expected_tensor, t) pg = c10d.new_group([1]) if self.rank == 1: t = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) expected_tensor = torch.tensor([self.rank + 1] * 10).cuda(2 * self.rank) pg.allreduce(t).wait() self.assertEqual(expected_tensor, t) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_barrier_device_ids(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", rank=self.rank, world_size=self.world_size, store=store ) c10d.barrier(device_ids=[self.rank]) @requires_nccl() @skip_if_lt_x_gpu(2) def test_nccl_barrier_device_ids_function_argument(self): store = c10d.FileStore(self.file_name, self.world_size) c10d.init_process_group( backend="nccl", rank=self.rank, world_size=self.world_size, store=store ) with self.assertRaisesRegex(TypeError, "Invalid function argument"): c10d.barrier(device_ids=self.rank) @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["DETAIL"]) def test_nccl_warn_not_in_group_debug_detail(self): self._test_warn_not_in_group(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["INFO"]) def test_nccl_warn_not_in_group_debug_info(self): self._test_warn_not_in_group(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) @with_dist_debug_levels(levels=["OFF"]) def test_nccl_warn_not_in_group_debug_off(self): self._test_warn_not_in_group(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) def test_nncl_rank_membership(self): self._test_rank_membership(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) def test_tensor_dtype_mismatch(self): self._test_tensor_dtype_mismatch(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) def test_tensor_dtype_complex(self): self._test_tensor_dtype_complex(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(2) def test_reduce_scatter_base_k(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) output_tensor = torch.zeros(2, dtype=torch.int64).to(self.rank) input_tensors = torch.arange(self.world_size * 2, dtype=torch.int64).to( self.rank ) input_tensors = torch.reshape(input_tensors, (self.world_size, 2)) dist.reduce_scatter_tensor(output_tensor, input_tensors) self.assertEqual(output_tensor, input_tensors[self.rank] * self.world_size) @requires_nccl() @skip_if_lt_x_gpu(2) def test_reduce_scatter_tensor_coalesced(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) output_tensors = torch.zeros(2, 2).to(self.rank) input_tensors = [torch.ones(2, 2).to(self.rank) for _ in range(self.world_size)] with dist._coalescing_manager(): for i in range(self.world_size): dist.reduce_scatter_tensor(output_tensors[i], input_tensors[i]) self.assertEqual(output_tensors, input_tensors[self.rank] * self.world_size) @requires_nccl() @skip_if_lt_x_gpu(2) def test_reduce_scatter_base_k_float8_errors(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) output_tensor = ( torch.zeros(2, dtype=torch.float32).to(torch.float8_e4m3fn).to(self.rank) ) input_tensors = ( torch.arange(self.world_size * 2, dtype=torch.float32) .to(torch.float8_e4m3fn) .to(self.rank) ) input_tensors = torch.reshape(input_tensors, (self.world_size, 2)) with self.assertRaisesRegex( RuntimeError, "Float8 dtypes are not currenlty supported for NCCL reductions", ): dist.reduce_scatter_tensor(output_tensor, input_tensors) @requires_nccl() @skip_if_lt_x_gpu(2) def test_reduce_scatter_tensor_coalesced_float8_errors(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) output_tensors = torch.zeros(2, 2).to(torch.float8_e5m2).to(self.rank) input_tensors = [ torch.ones(2, 2).to(torch.float8_e5m2).to(self.rank) for _ in range(self.world_size) ] with self.assertRaisesRegex( RuntimeError, "Float8 dtypes are not currenlty supported for NCCL reductions", ): with dist._coalescing_manager(): for i in range(self.world_size): dist.reduce_scatter_tensor(output_tensors[i], input_tensors[i]) self.assertEqual(output_tensors, input_tensors[self.rank]) class SetDeviceMethod(Enum): TORCH_CUDA_SET = auto() # torch.cuda.set_device COLLECTIVE_ARGUMENT = auto() # broadcast_object_list(device=) class NcclProcessGroupWithDispatchedCollectivesTests( test_c10d_common.ProcessGroupWithDispatchedCollectivesTests ): @requires_nccl() @skip_if_lt_x_gpu(1) def test_collectives(self): self._test_collectives(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(1) def test_allreduce_coalesced(self): self._test_allreduce_coalesced(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(1) def test_all_to_all_single(self): self._test_all_to_all_single(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(1) def test_allgather_base(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) device = "cuda" tensor = torch.ones(10, 10, device=torch.device(device)) output_tensor = torch.zeros(10, 10, device=torch.device(device)) dist.all_gather_into_tensor(output_tensor, tensor) self.assertEqual(output_tensor, tensor) @requires_nccl() @skip_if_lt_x_gpu(1) @parametrize("float8_dtype", [torch.float8_e4m3fn, torch.float8_e5m2]) def test_allgather_float8(self, float8_dtype): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) device = "cuda" tensor = torch.ones(10, 16, device=torch.device(device)).to(float8_dtype) output_tensor = torch.zeros(10, 16, device=torch.device(device)).to( float8_dtype ) dist.all_gather_into_tensor(output_tensor, tensor) self.assertEqual(output_tensor.view(torch.float32), tensor.view(torch.float32)) instantiate_parametrized_tests(NcclProcessGroupWithDispatchedCollectivesTests) class LargeCommTest(test_c10d_common.AbstractLargeCommTest, MultiProcessTestCase): def setUp(self): super().setUp() # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass @property def device(self): return self.rank @requires_nccl() @skip_if_lt_x_gpu(4) def test_new_group_local_sync(self): self._test_new_group_local_sync(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(4) def test_new_group_local_sync_sanity_check(self): self._test_new_group_local_sync_sanity_check(backend="nccl") @requires_nccl() @skip_if_lt_x_gpu(4) def test_new_group_local_sync_duplicated_pg(self): self._test_new_group_local_sync_duplicate_pg(backend="nccl") def _init_two_pg2_subgroups(self, world_size: int = 4): if world_size != 4: raise NotImplementedError( f"need world size of 4 to get 2 subgroup PGs, but got world size of {world_size}" ) store = c10d.FileStore(self.file_name, world_size) c10d.init_process_group( backend="nccl", store=store, rank=self.rank, world_size=world_size ) # every rank creates the same sub groups # including unused sub groups in the current rank a_group = c10d.new_group([0, 1]) b_group = c10d.new_group([2, 3]) return a_group if self.rank < 2 else b_group @requires_nccl() @skip_if_lt_x_gpu(4) def test_gather_subgroup(self): world_size = 4 if self.rank >= world_size: # just easier to write the test for exactly 4 gpus, even if this test class increased to 8gpu later return subgroup = self._init_two_pg2_subgroups(world_size) device = torch.device("cuda:%d" % self.rank) input = torch.ones((10,), device=device) * self.rank if self.rank == 0 or self.rank == 2: gather_list = [torch.empty_like(input) for _ in range(subgroup.size())] torch.distributed.gather( input, gather_list=gather_list, dst=self.rank, group=subgroup, async_op=False, ) for src in range(len(gather_list)): expected = (torch.ones_like(input) * self.rank) + src self.assertEqual(gather_list[src], expected) else: torch.distributed.gather( input, gather_list=None, dst=self.rank - 1, group=subgroup, async_op=False, ) @requires_nccl() @skip_if_lt_x_gpu(4) def test_gather_object_subgroup(self): world_size = 4 if self.rank >= world_size: # just easier to write the test for exactly 4 gpus, even if this test class increased to 8gpu later return subgroup = self._init_two_pg2_subgroups(world_size) # discrepancy #1 # have to set device or else gather_object gets wrong device from 'current_device = _get_pg_default_device(group) torch.cuda.set_device(self.rank) input = {"rank": self.rank} if self.rank == 0 or self.rank == 2: # discrepancy #2 # another weird thing- what's the point of making me specify some empty objects in my list? # empty list should be valid imo. (but it throws an error) gather_list = [{}, {}] torch.distributed.gather_object( input, object_gather_list=gather_list, dst=self.rank, group=subgroup ) for src in range(len(gather_list)): self.assertEqual(gather_list[src]["rank"], self.rank + src) else: torch.distributed.gather_object( input, object_gather_list=None, dst=self.rank - 1, group=subgroup ) @requires_nccl() @skip_if_lt_x_gpu(4) def test_reduce_subgroup(self): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) device = torch.device("cuda:%d" % self.rank) x = torch.ones((10,), device=device) * self.rank if self.rank == 0 or self.rank == 2: expected = x + torch.ones((10,), device=device) * (self.rank + 1) c10d.reduce(x, dst=self.rank, group=subgroup, async_op=False) self.assertEqual(x, expected) else: c10d.reduce(x, dst=self.rank - 1, group=subgroup, async_op=False) @requires_nccl() @skip_if_lt_x_gpu(4) @parametrize("async_op", [True, False]) def test_send_recv_subgroup(self, async_op): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) device = torch.device("cuda:%d" % self.rank) if self.rank == 0 or self.rank == 2: x = torch.empty((10,), device=device) if async_op: c10d.irecv(x, src=self.rank + 1, group=subgroup).wait() else: c10d.recv(x, src=self.rank + 1, group=subgroup) expected = torch.ones((10,), device=device) * (self.rank + 1) self.assertEqual(x, expected) else: x = torch.ones((10,), device=device) * self.rank if async_op: c10d.isend(x, dst=self.rank - 1, group=subgroup).wait() else: c10d.send(x, dst=self.rank - 1, group=subgroup) @requires_nccl() @skip_if_lt_x_gpu(4) def test_broadcast_subgroup(self): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) device = torch.device("cuda:%d" % self.rank) if self.rank == 0 or self.rank == 2: x = torch.empty((10,), device=device) c10d.broadcast(x, src=self.rank + 1, group=subgroup) expected = torch.ones((10,), device=device) * (self.rank + 1) self.assertEqual(x, expected) else: x = torch.ones((10,), device=device) * self.rank c10d.broadcast(x, src=self.rank, group=subgroup) @requires_nccl() @skip_if_lt_x_gpu(4) @parametrize( "set_device", [SetDeviceMethod.TORCH_CUDA_SET, SetDeviceMethod.COLLECTIVE_ARGUMENT], ) def test_send_recv_object_list_subgroup(self, set_device: SetDeviceMethod): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) if set_device == SetDeviceMethod.TORCH_CUDA_SET: torch.cuda.set_device(self.rank) device = None else: device = torch.device("cuda:%d" % self.rank) if self.rank == 0 or self.rank == 2: x = [{}] c10d.recv_object_list(x, src=self.rank + 1, group=subgroup, device=device) expected = [{"rank": self.rank + 1}] self.assertEqual(x, expected) else: x = [{"rank": self.rank}] c10d.send_object_list(x, dst=self.rank - 1, group=subgroup, device=device) @requires_nccl() @skip_if_lt_x_gpu(4) @parametrize( "set_device", [SetDeviceMethod.TORCH_CUDA_SET, SetDeviceMethod.COLLECTIVE_ARGUMENT], ) def test_broadcast_object_list_subgroup(self, set_device: SetDeviceMethod): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) if set_device == SetDeviceMethod.TORCH_CUDA_SET: torch.cuda.set_device(self.rank) device = None else: device = torch.device("cuda:%d" % self.rank) if self.rank == 0 or self.rank == 2: x = [{}] c10d.broadcast_object_list( x, src=self.rank + 1, group=subgroup, device=device ) expected = [{"rank": self.rank + 1}] self.assertEqual(x, expected) else: x = [{"rank": self.rank}] c10d.broadcast_object_list(x, src=self.rank, group=subgroup, device=device) @requires_nccl() @skip_if_lt_x_gpu(4) def test_scatter_subgroup(self): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) device = torch.device("cuda:%d" % self.rank) x = torch.empty((10,), device=device) expected = torch.ones((10,), device=device) * self.rank if self.rank == 0 or self.rank == 2: c10d.scatter(x, scatter_list=None, src=self.rank + 1, group=subgroup) else: scatter_list = [ torch.ones((10,), device=device) * (self.rank - 1), torch.ones((10,), device=device) * self.rank, ] c10d.scatter(x, scatter_list=scatter_list, src=self.rank, group=subgroup) self.assertEqual(x, expected) @requires_nccl() @skip_if_lt_x_gpu(4) def test_scatter_object_list_subgroup(self): world_size = 4 if self.rank >= world_size: return subgroup = self._init_two_pg2_subgroups(world_size) torch.cuda.set_device(self.rank) scatter_object_output_list = [None] expected = [{"rank": self.rank}] if self.rank == 0 or self.rank == 2: c10d.scatter_object_list( scatter_object_output_list=scatter_object_output_list, scatter_object_input_list=None, src=self.rank + 1, group=subgroup, ) else: scatter_object_input_list = [ {"rank": self.rank - 1}, {"rank": self.rank}, ] c10d.scatter_object_list( scatter_object_output_list=scatter_object_output_list, scatter_object_input_list=scatter_object_input_list, src=self.rank, group=subgroup, ) self.assertEqual(scatter_object_output_list, expected) instantiate_parametrized_tests(LargeCommTest) class SparseCollective(MultiProcessTestCase): @property def world_size(self): return 1 def setUp(self): super().setUp() # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" # self.num_gpus = torch.cuda.device_count() self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass class ToyModel(nn.Module): def __init__(self, rank, vocab_size, embedding_dim): super().__init__() self.embedding = nn.Embedding(vocab_size, embedding_dim, sparse=True).to( rank ) self.linear = nn.Linear(embedding_dim, 1).to(rank) def forward(self, inputs): embedded = self.embedding(inputs) # embedded shape: (batch_size, sequence_length, embedding_dim) flattened = torch.mean(embedded, dim=1) # flattened shape: (batch_size, embedding_dim) output = self.linear(flattened) # output shape: (batch_size, 1) return output @requires_nccl() @skip_if_lt_x_gpu(1) def test_ddp_set_sparse_metadata(self): store = dist.FileStore(self.file_name, self.world_size) dist.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, ) vocab_size = 5 model = SparseCollective.ToyModel( self.rank, vocab_size=vocab_size, embedding_dim=10 ) ddp_model = DistributedDataParallel(model) inputs = torch.tensor([[1, 0, 0], [0, 0, 0], [0, 0, 0]]).to(self.rank) # set sparse metadata on the DDP model indices = torch.Tensor(list(range(vocab_size))) ddp_model._set_sparse_metadata({"embedding.weight": indices}) # forward pass try: output = ddp_model(inputs) loss = output.sum() # backward pass loss.backward() self.assertTrue(ddp_model.module.embedding.weight.grad.indices, indices) except RuntimeError as e: if "NCCL does not support all_reduce with sparse tensors" in str(e): pass else: # Rethrow the exception if it's a different error raise class NCCLTraceTestBase(MultiProcessTestCase): def setUp(self): super().setUp() os.environ[ "TORCH_NCCL_ENABLE_TIMING" ] = "0" # see 'timing_enabled' parametrized tests os.environ["TORCH_NCCL_TRACE_BUFFER_SIZE"] = "1000" os.environ["TORCH_NCCL_DUMP_ON_TIMEOUT"] = "1" self.tempdir = tempfile.TemporaryDirectory() os.environ["TORCH_NCCL_DEBUG_INFO_TEMP_FILE"] = self._trace_basename() os.environ["TORCH_NCCL_DEBUG_INFO_PIPE_FILE"] = self._trace_basename() self._spawn_processes() @classmethod def _run( cls, parent_conn, rank: int, test_name: str, file_name: str, parent_pipe, **kwargs, ) -> None: cls.parent = parent_conn super()._run(rank, test_name, file_name, parent_pipe) @property def local_device(self): return torch.device("cuda", self.rank_to_GPU[self.rank][0]) def _join_processes(self, fn): # We need to patch sys.exit() as skip_if will use sys.exit() and # the exit code from the this process will not be catched. with mock.patch("sys.exit") as exit_mock: fn() super()._join_processes(fn) def _spawn_processes(self) -> None: proc = torch.multiprocessing.get_context("spawn").Process self.children_pipes = [] parent_pipes = [] for i in range(self.world_size): parent_conn, child_conn = torch.multiprocessing.Pipe() self.children_pipes.append(child_conn) parent_pipes.append(parent_conn) piter = iter(parent_pipes) def wrap(*positional, args, **kwargs): args = (next(piter), *args) return proc(*positional, args=args, **kwargs) self._start_processes(wrap) def _create_process_group_nccl(self): store = dist.FileStore(self.file_name, self.world_size) c10d.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store ) pg = c10d.distributed_c10d._get_default_group() return pg def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass @property def world_size(self): return 2 @property def rank_to_GPU(self): # return rank to GPU map return init_multigpu_helper(self.world_size, "nccl") def _trace_basename(self): # we pass the base to the env, and the dump util will append rank return os.path.join(self.tempdir.name, "trace_") def _trace_name(self, rank): return self._trace_basename() + str(rank) def started_or_scheduled(self, timing_enabled): return "started" if timing_enabled else "scheduled" class NCCLTraceTest(NCCLTraceTestBase): def _verify_trace(self, t, include_collectives, timing_enabled, is_json): ver = t["version"] self.assertEqual(ver, "2.4") pg_config = t["pg_config"] self.assertEqual(len(pg_config), 1) default_pg_info = pg_config["0"] self.assertIn("name", default_pg_info) self.assertIn("desc", default_pg_info) self.assertIn("ranks", default_pg_info) pg_status = t["pg_status"] self.assertEqual(len(pg_status), 1) self.assertEqual(str(pg_status["0"]["last_enqueued_collective"]), "2") self.assertEqual(str(pg_status["0"]["last_completed_collective"]), "2") self.assertEqual( str(pg_status["0"]["last_started_collective"]), "2" if timing_enabled else "-1", ) global_ranks = pg_config["0"]["ranks"] self.assertEqual(len(json.loads(global_ranks)), self.world_size) if include_collectives: self.assertEqual(len(t["entries"]), 2) t = t["entries"] last = t[-1] self.assertEqual(last["process_group"], ("0", "default_pg")) self.assertEqual(last["state"], "completed") s = last["time_discovered_started_ns"] f = last["time_discovered_completed_ns"] self.assertEqual(last["record_id"], 1) self.assertIsNotNone(f) if timing_enabled: self.assertIsNotNone(s) self.assertTrue(s <= f) # we don't collect stack traces in JSON at the moment if not is_json: self.assertIn("test_c10d_nccl.py", str(last["frames"])) self.assertEqual(last["input_sizes"], ((3, 4),)) self.assertEqual(last["input_dtypes"], ["Float"]) self.assertEqual(last["output_sizes"], ((3, 4),)) self.assertEqual(last["output_dtypes"], ["Float"]) self.assertEqual(last["collective_seq_id"], 2) self.assertEqual(last["timeout_ms"], 600000) now = datetime.now() event_created_time = datetime.fromtimestamp( last["time_created_ns"] / 1000000000 ) before_test = now - timedelta(minutes=1) self.assertTrue(before_test < event_created_time < now) if timing_enabled: # very loose bounds, measured 0.036 ms on devgpu self.assertTrue(0 < last["duration_ms"] < 100) else: self.assertTrue("duration_ms" not in last) else: self.assertTrue("entries" not in t) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("timing_enabled", [True, False]) @parametrize("include_collectives", [True, False]) def test_short_json(self, timing_enabled, include_collectives): if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() device = self.local_device a = torch.full((3, 4), float(self.rank), device=device) for i in range(2): f = pg.allreduce(a) f.wait() torch.cuda.synchronize(device=device) # gah ok so now the duration_ms is populated best-effort since it can only happen outside "dump()" api time.sleep(1) t = json.loads( torch._C._distributed_c10d._dump_nccl_trace_json( includeCollectives=include_collectives ) ) self._verify_trace(t, include_collectives, timing_enabled, True) dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("timing_enabled", [True, False]) @parametrize("include_collectives", [True, False]) def test_short_pickle(self, timing_enabled, include_collectives): if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() device = self.local_device a = torch.full((3, 4), float(self.rank), device=device) for i in range(2): f = pg.allreduce(a) f.wait() torch.cuda.synchronize(device=device) # gah ok so now the duration_ms is populated best-effort since it can only happen outside "dump()" api time.sleep(1) t = pickle.loads( torch._C._distributed_c10d._dump_nccl_trace( includeCollectives=include_collectives ) ) self._verify_trace( t, include_collectives=include_collectives, timing_enabled=timing_enabled, is_json=True, ) dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_dump_pipe(self): def open_file_with_timeout(file_path, mode, timeout=1.0): start_time = time.time() while time.time() - start_time < timeout: if os.path.exists(file_path): return open(file_path, mode) time.sleep(0.1) raise FileNotFoundError if self.rank == self.MAIN_PROCESS_RANK: for c in self.children_pipes: self.assertEqual(c.recv(), "next") dump_file = self._trace_name(rank=0) pipe_file = dump_file + ".pipe" with open_file_with_timeout(pipe_file, "w") as f: f.write("1\n") with open_file_with_timeout(dump_file, "rb", timeout=10.0) as f: self.assertTrue("all_reduce" in str(pickle.load(f))) for c in self.children_pipes: c.send("next") return pg = self._create_process_group_nccl() device = self.local_device a = torch.full((3, 4), float(self.rank), device=device) for i in range(2): f = pg.allreduce(a) f.wait() torch.cuda.synchronize(device=device) self.parent.send("next") self.parent.recv() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_long(self): os.environ["TORCH_NCCL_TRACE_BUFFER_SIZE"] = "10" if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() device = self.local_device a = torch.full((3, 4), float(self.rank), device=device) for i in range(2): # test some other primitives to make sure # their strings are valid xs = [torch.ones(3, 4, device=device)] pg.broadcast(xs).wait() pg.allreduce(xs).wait() pg.reduce(xs).wait() ys = [[torch.empty(3, 4, device=device) for _ in range(self.world_size)]] pg.allgather(ys, xs).wait() pg.reduce_scatter(xs, ys).wait() f = pg.allreduce(a) f.wait() torch.cuda.synchronize(device=device) t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) t = t["entries"] self.assertEqual(len(t), 10) first = t[0] last = t[-1] self.assertEqual(last["profiling_name"], "nccl:all_reduce") self.assertEqual(last["state"], "completed") self.assertIn("test_c10d_nccl.py", str(last["frames"])) self.assertEqual(last["input_sizes"], ((3, 4),)) self.assertEqual(last["input_dtypes"], ["Float"]) self.assertEqual(last["output_sizes"], ((3, 4),)) self.assertEqual(last["output_dtypes"], ["Float"]) self.assertEqual(last["timeout_ms"], 600000) self.assertEqual(last["collective_seq_id"] - first["collective_seq_id"], 9) dist.destroy_process_group() @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") def test_trace_while_all_works_retired(self): os.environ["TORCH_NCCL_TRACE_BUFFER_SIZE"] = "10" if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() device = self.local_device # send more works than the buffer size to overwrite the previous entry for i in range(12): a = [torch.ones(3, 4, device=device)] pg.broadcast(a).wait() torch.cuda.synchronize(device=device) # wait for all works to be retired pg._wait_for_pending_works() t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) t = t["entries"] self.assertEqual(len(t), 10) last = t[-1] self.assertEqual(last["retired"], True) self.assertEqual(last["state"], "completed") @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("timing_enabled", [True, False]) @parametrize("only_active", [True, False]) def test_trace_while_active(self, timing_enabled, only_active): if self.rank == self.MAIN_PROCESS_RANK: for c in self.children_pipes: self.assertEqual(c.recv(), "next") for c in self.children_pipes: c.send("next") return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() device = self.local_device with torch.cuda.device(device): a = torch.full((3, 4), float(self.rank), device=device) pg.allreduce(a).wait() e = torch.cuda.Event() e.record() if self.rank != 0: pg.allreduce(a).wait() e.synchronize() t = pickle.loads( torch._C._distributed_c10d._dump_nccl_trace(onlyActive=only_active) ) t = t["entries"] if only_active: if self.rank == 0: self.assertEqual(len(t), 0) else: self.assertEqual(len(t), 1) if not only_active: if self.rank == 0: self.assertEqual(t[-1]["profiling_name"], "nccl:all_reduce") self.assertEqual(t[-1]["collective_seq_id"], 1) self.assertEqual(t[-1]["state"], "completed") else: self.assertEqual(t[-1]["profiling_name"], "nccl:all_reduce") self.assertEqual(t[-1]["collective_seq_id"], 2) self.assertEqual( t[-1]["state"], self.started_or_scheduled(timing_enabled) ) self.parent.send("next") self.assertEqual("next", self.parent.recv()) if self.rank == 0: pg.allreduce(a).wait() torch.cuda.synchronize(device=device) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize("timing_enabled", [True, False]) def test_trace_while_stuck(self, timing_enabled): if self.rank == self.MAIN_PROCESS_RANK: for c in self.children_pipes: self.assertEqual(c.recv(), "next") for c in self.children_pipes: c.send("next") return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() device = self.local_device with torch.cuda.device(device): a = torch.full((3, 4), float(self.rank), device=device) pg.allreduce(a).wait() e = torch.cuda.Event() e.record() def gather_trace(): e.synchronize() # give the other thread some time to fill the cuda buffer time.sleep(5) t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) t = t["entries"] self.assertEqual(t[-1]["profiling_name"], "nccl:all_reduce") if self.rank == 0: self.assertEqual(t[-1]["collective_seq_id"], 1) self.assertEqual(t[-1]["state"], "completed") else: self.assertEqual(t[-1]["collective_seq_id"], 2) self.assertEqual( t[-1]["state"], self.started_or_scheduled(timing_enabled) ) self.assertIsNone(t[-1]["time_discovered_completed_ns"]) # this will eventually cause the missing rank 0 # to continue which will unblock the non-zero ranks self.parent.send("next") if self.rank != 0: pg.allreduce(a).wait() th = threading.Thread(target=gather_trace) th.start() # fill the cuda buffer, at around 1024 events # this will stall for i in range(2000): a = a + a th.join() else: gather_trace() self.assertEqual("next", self.parent.recv()) if self.rank == 0: pg.allreduce(a).wait() torch.cuda.synchronize(device=device) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize( "op_sizes_per_coalesce", [ [(2, 3)], [(2, 3), (5, 5), (1,)], ], ) @parametrize("timing_enabled", [True, False]) def test_batched_send_recv(self, op_sizes_per_coalesce, timing_enabled): """ 'WorkEnqueue' was skipped for isendirecv, leading to segfault on dump_entries when update_state tried to use a destructed Work obj's cuda events """ if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() num_coalesced_ops = 20 ops_per_coalesce = len(op_sizes_per_coalesce) for i in range(num_coalesced_ops): ops = [] for input_sizes in op_sizes_per_coalesce: tensor = torch.zeros(input_sizes).to(self.local_device) if self.rank == 0: ops.append(dist.P2POp(dist.irecv, tensor, 1)) elif self.rank == 1: tensor *= 2 ops.append(dist.P2POp(dist.isend, tensor, 0)) dist.batch_isend_irecv(ops).pop().wait() torch.cuda.synchronize(device=self.local_device) if timing_enabled: # wait for watchdog thread to process the queue of works time.sleep(1) t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) self.assertEqual(len(t["entries"]), num_coalesced_ops * (ops_per_coalesce + 1)) expected_record_id = 0 expected_seq = 1 expected_op_id = 1 for seq in range(num_coalesced_ops): first_op = seq * (ops_per_coalesce + 1) coalesced_op = first_op + ops_per_coalesce for p2p_op_idx, input_sizes in zip( range(first_op, coalesced_op, 1), op_sizes_per_coalesce ): # the indivudal ops inside the coalescing group the individual op metadata, # but not the timing info coming from the actual coalesced kernel profiling_name = ( "nccl:recv 0<-1" if self.rank == 0 else "nccl:send 1->0" ) self.assertEqual( t["entries"][p2p_op_idx]["record_id"], expected_record_id ) expected_record_id += 1 self.assertEqual( t["entries"][p2p_op_idx]["profiling_name"], profiling_name ) self.assertEqual( t["entries"][p2p_op_idx]["collective_seq_id"], expected_seq ) self.assertEqual(t["entries"][p2p_op_idx]["op_id"], expected_op_id) expected_op_id += 1 self.assertEqual(t["entries"][p2p_op_idx]["input_sizes"], [input_sizes]) self.assertEqual( t["entries"][p2p_op_idx]["output_sizes"], [input_sizes] ) # duration doesn't get tagged onto individual ops yet, nor is their state updated self.assertEqual(t["entries"][p2p_op_idx]["state"], "scheduled") self.assertTrue("duration_ms" not in t["entries"][p2p_op_idx]) # the coalesced op has no metadata but indicates that coalescing was used, # and accurately reflects the timing and state info for the whole group self.assertEqual( t["entries"][coalesced_op]["record_id"], expected_record_id ) expected_record_id += 1 self.assertEqual( t["entries"][coalesced_op]["profiling_name"], "nccl:coalesced" ) self.assertEqual( t["entries"][coalesced_op]["collective_seq_id"], expected_seq ) expected_seq += 1 self.assertEqual(t["entries"][coalesced_op]["state"], "completed") self.assertEqual(t["entries"][coalesced_op]["input_sizes"], []) self.assertEqual(t["entries"][coalesced_op]["output_sizes"], []) if timing_enabled: duration = t["entries"][coalesced_op]["duration_ms"] self.assertTrue(0.001 < duration < 10000, duration) else: self.assertTrue("duration_ms" not in t["entries"][coalesced_op]) self.assertEqual(t["entries"][coalesced_op]["timeout_ms"], 600000) @requires_nccl() @skip_but_pass_in_sandcastle_if(not TEST_MULTIGPU, "NCCL test requires 2+ GPUs") @parametrize( "op_sizes", [ [(2, 3)], [(2, 3), (5, 5), (1,)], ], ) @parametrize("timing_enabled", [True, False]) def test_individual_send_recv(self, op_sizes, timing_enabled): """ 'WorkEnqueue' was skipped for isendirecv, leading to segfault on dump_entries when update_state tried to use a destructed Work obj's cuda events """ if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() num_repeats = 10 ops_per_repeat = len(op_sizes) for i in range(num_repeats): for input_sizes in op_sizes: tensor = torch.zeros(input_sizes).to(self.local_device) if self.rank == 0: dist.recv(tensor, 1) elif self.rank == 1: tensor *= 2 dist.send(tensor, 0) torch.cuda.synchronize(device=self.local_device) if timing_enabled: # wait for watchdog thread to process the queue of works time.sleep(1) t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) self.assertEqual(len(t["entries"]), num_repeats * (ops_per_repeat)) expected_seq = 1 expected_op_id = 1 for seq in range(num_repeats * ops_per_repeat): input_sizes = op_sizes[seq % ops_per_repeat] profiling_name = "nccl:recv 0<-1" if self.rank == 0 else "nccl:send 1->0" self.assertEqual(t["entries"][seq]["profiling_name"], profiling_name) self.assertEqual(t["entries"][seq]["p2p_seq_id"], expected_seq) expected_seq += 1 self.assertEqual(t["entries"][seq]["op_id"], expected_op_id) expected_op_id += 1 self.assertEqual(t["entries"][seq]["input_sizes"], [input_sizes]) self.assertEqual(t["entries"][seq]["output_sizes"], [input_sizes]) self.assertEqual(t["entries"][seq]["state"], "completed") if timing_enabled: duration = t["entries"][seq]["duration_ms"] self.assertTrue(0.001 < duration < 10000, duration) else: self.assertTrue("duration_ms" not in t["entries"][seq]) # TODO(whc) support and test coalesced collectives that use the c++ start/end group thingy instead of python # coalescing manager # TODO(whc) test out other ops (And combinations of ops, if that's valid?) @requires_nccl() @skip_if_lt_x_gpu(2) @parametrize("timing_enabled", [True, False]) def test_coalescing_manager_collective(self, timing_enabled): """ The coalescing manager api works by accumulating operations in python via a contextmanager, and then making one call into c++ to an _coalesced API. It has limited support for ops and has been added recently to avoid overheads of making individual py-cpp calls. This complicates flight recording.. For now, flight recording of coalescing_manager collectives is less detailed than cpp coalesced collectives. """ if self.rank == self.MAIN_PROCESS_RANK: return pg = self._create_process_group_nccl() if timing_enabled: pg._enable_collectives_timing() output_tensors = torch.zeros(2, 2).to(self.rank) input_tensors = [torch.ones(2, 2).to(self.rank) for _ in range(self.world_size)] # TODO(whc) make this work with bigger world or something self.assertEqual(self.world_size, 2, self.world_size) with dist._coalescing_manager(): for i in range(self.world_size): dist.reduce_scatter_tensor(output_tensors[i], input_tensors[i]) self.assertEqual(output_tensors, input_tensors[self.rank] * self.world_size) torch.cuda.synchronize(device=self.rank) if timing_enabled: # wait for watchdog thread to process the queue of works time.sleep(1) t = pickle.loads(torch._C._distributed_c10d._dump_nccl_trace()) self.assertEqual( len(t["entries"]), 1 ) # one for the reduce_scatter_tensor_coalesced, one for the endCoalescing self.assertEqual( t["entries"][0]["profiling_name"], "nccl:reduce_scatter_tensor_coalesced" ) self.assertEqual(t["entries"][0]["collective_seq_id"], 1) self.assertEqual(t["entries"][0]["input_sizes"], [[2, 2], [2, 2]]) self.assertEqual( t["entries"][0]["output_sizes"], [ [ 2, ], [ 2, ], ], ) self.assertEqual(t["entries"][0]["state"], "completed") if timing_enabled: duration = t["entries"][0]["duration_ms"] self.assertTrue(0.001 < duration < 10000, duration) else: self.assertTrue("duration_ms" not in t["entries"][0]) def check_if_test_is_skipped(fn): def wrapper(self, *args, **kwargs): for skip in TEST_SKIPS.values(): if self.processes[0].exitcode == skip.exit_code: return MultiProcessTestCase._check_return_codes(self, *args, **kwargs) return fn(self, *args, **kwargs) return wrapper class NCCLTraceTestDumpOnTimeoutBase(NCCLTraceTestBase): timeout_sec = 1 def _create_process_group_nccl(self): store = dist.FileStore(self.file_name, self.world_size) c10d.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, timeout=timedelta(seconds=NCCLTraceTestDumpOnTimeoutBase.timeout_sec), ) pg = c10d.distributed_c10d._get_default_group() return pg @check_if_test_is_skipped def _check_return_codes(self, elapsed_time): # the base test infra assumes processes exit with matching return codes, # but we want rank0 to abort and rank1 to exit cleanly in this test self.assertEqual(self.processes[0].exitcode, -6) self.assertEqual(self.processes[1].exitcode, 0) def _wait_process(self, rank, timeout): try: self.processes[rank].join(timeout) return self.processes[rank].exitcode except TimeoutError: return None @skip_but_pass_in_sandcastle class NCCLTraceTestDumpOnTimeout(NCCLTraceTestDumpOnTimeoutBase): @requires_nccl() @skip_if_lt_x_gpu(2) @parametrize("timing_enabled", [True, False]) def test_timeout_dumps(self, timing_enabled): # dump on heartbeatmonitor thread os.environ["TORCH_NCCL_COORD_CHECK_MILSEC"] = "1000" # need rank0 to crash before looking for its output file os.environ["TORCH_NCCL_HEARTBEAT_TIMEOUT_SEC"] = "1" if self.rank == self.MAIN_PROCESS_RANK: # wait for rank0 to crash before looking for its output file # we rely on rank0 holding off its abort long enough to dump the debug info self.assertEqual(self._wait_process(0, timeout=90), -6) with open(self._trace_name(rank=0), "rb") as f: t = pickle.load(f) t = t["entries"] self.assertEqual(len(t), 2) self.assertEqual(t[0]["collective_seq_id"], 1) self.assertEqual(t[0]["state"], "completed") self.assertEqual(t[1]["collective_seq_id"], 2) self.assertEqual( t[1]["state"], self.started_or_scheduled(timing_enabled) ) self.assertFalse(os.path.exists(self._trace_name(rank=1))) return pg = self._create_process_group_nccl() if timing_enabled: # we force disabled timing in setup, since there is no 'disable' function pg._enable_collectives_timing() device = self.local_device with torch.cuda.device(device): a = torch.full((3, 4), float(self.rank), device=device) pg.allreduce(a).wait() if self.rank == 0: pg.allreduce(a).wait() # rank 0 will crash before it passes the sync, but rank1 will exit quickly and cleanly torch.cuda.synchronize(device=device) instantiate_parametrized_tests(ProcessGroupNCCLGroupTest) instantiate_parametrized_tests(NCCLTraceTestDumpOnTimeout) instantiate_parametrized_tests(NCCLTraceTest) @skip_but_pass_in_sandcastle class NCCLTraceTestTimeoutDumpOnStuckRanks(NCCLTraceTestDumpOnTimeoutBase): @check_if_test_is_skipped def _check_return_codes(self, elapsed_time): # the base test infra assumes processes exit with matching return codes, # but we want rank0 to abort and rank1 to exit cleanly in this test self.assertEqual(self.processes[0].exitcode, -6) self.assertEqual(self.processes[1].exitcode, -6) @requires_nccl() @skip_if_lt_x_gpu(2) def test_timeout_dumps_on_stuck_ranks(self): # need rank0 to crash quicker after detecting timeout os.environ["TORCH_NCCL_HEARTBEAT_TIMEOUT_SEC"] = "1" # restore this env var to its prior default in case another test changed it os.environ["TORCH_NCCL_COORD_CHECK_MILSEC"] = "1000" if self.rank == self.MAIN_PROCESS_RANK: # wait for both rank0 and 1 to crash before looking for both ranks' output # file, and we rely on rank1 to sleep long enough to dump the debug info. self.assertEqual(self._wait_process(0, timeout=90), -6) self.assertEqual(self._wait_process(1, timeout=90), -6) self.assertTrue(os.path.exists(self._trace_name(rank=1))) self.assertTrue(os.path.exists(self._trace_name(rank=0))) with open(self._trace_name(rank=0), "rb") as f: t = pickle.load(f) t = t["entries"] self.assertEqual(len(t), 2) with open(self._trace_name(rank=1), "rb") as f: t = pickle.load(f) t = t["entries"] self.assertEqual(len(t), 1) self.assertEqual(t[0]["collective_seq_id"], 1) self.assertEqual(t[0]["state"], "completed") return pg = self._create_process_group_nccl() device = self.local_device with torch.cuda.device(device): a = torch.full((3, 4), float(self.rank), device=device) pg.allreduce(a).wait() if self.rank == 0: pg.allreduce(a).wait() # rank 0 will get stuck, timeout and then signal a timeout to all ranks. torch.cuda.synchronize(device=device) if self.rank == 1: # Force rank 1 to idle so that it will eventually timeout as well after # getting the global signal to dump the debugging info. time.sleep(600) @skip_but_pass_in_sandcastle class NcclErrorDumpTest(NCCLTraceTestBase): def _wait_process(self, rank, timeout): try: self.processes[rank].join(timeout) return self.processes[rank].exitcode except TimeoutError: return None @check_if_test_is_skipped def _check_return_codes(self, elapsed_time): # the base test infra assumes processes exit with matching return codes, # but we want rank0 to abort with exception and rank1 to exit with exit 1 self.assertEqual(self.processes[0].exitcode, -6) self.assertEqual(self.processes[1].exitcode, 1) @requires_nccl() @requires_nccl_version((2, 4, 0), "Need NCCL 2.4+ for error checking") @skip_if_lt_x_gpu(2) @skip_if_rocm_multiprocess def test_nccl_errors_dump(self): os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" os.environ["TORCH_NCCL_TRACE_BUFFER_SIZE"] = "1000" os.environ["TORCH_NCCL_DUMP_ON_TIMEOUT"] = "1" # need rank0 to dump before abort os.environ["TORCH_NCCL_HEARTBEAT_TIMEOUT_SEC"] = "5" if self.rank == self.MAIN_PROCESS_RANK: # wait for both rank0 and 1 to crash before looking for dump self.assertEqual(self._wait_process(0, timeout=90), -6) self.assertEqual(self._wait_process(1, timeout=90), 1) # verify that the trace file exists for rank0 self.assertTrue(os.path.exists(self._trace_name(rank=0))) return store = c10d.FileStore(self.file_name, self.world_size) process_group = c10d.ProcessGroupNCCL( store, self.rank, self.world_size, timeout=timedelta(seconds=10), ) process_group.allreduce(torch.rand(10).cuda(self.rank)) if self.rank == 0: work = process_group.allreduce(torch.rand(10).cuda(self.rank)) # expect an error to be raised with self.assertRaisesRegex(dist.DistBackendError, ""): # Block the current stream on the NCCL stream work.wait() # Run some GPU operations a = torch.rand(10).cuda(self.rank) elif self.rank == 1: # Clean up structures (ex: files for FileStore before going down) del process_group sys.exit(1) # tests that needs to be run with a larger world size class ProcessGroupNCCLLargerScaleTest(MultiProcessTestCase): def _create_process_group_nccl(self, store, opts, device_id=None): # create nccl processgroup with opts c10d.init_process_group( "nccl", world_size=self.world_size, rank=self.rank, store=store, pg_options=opts, device_id=device_id, ) pg = c10d.distributed_c10d._get_default_group() return pg def opts(self, high_priority_stream=False): opts = c10d.ProcessGroupNCCL.Options() opts.is_high_priority_stream = high_priority_stream return opts def setUp(self): super().setUp() # TORCH_NCCL_BLOCKING_WAIT overrides TORCH_NCCL_ASYNC_ERROR_HANDLING hence tests # that use TORCH_NCCL_BLOCKING_WAIT will test it as expected. os.environ["TORCH_NCCL_ASYNC_ERROR_HANDLING"] = "1" # self.num_gpus = torch.cuda.device_count() self._spawn_processes() def tearDown(self): super().tearDown() try: os.remove(self.file_name) except OSError: pass @property def world_size(self): return 8 @property def rank_to_GPU(self): # return rank to GPU map return init_multigpu_helper(self.world_size, "nccl") @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_if_lt_x_gpu(8) def test_comm_split_group_larger_scale(self): store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg = self._create_process_group_nccl(store, self.opts(), device_id=device) backend = pg._get_backend(torch.device(device)) tensor = torch.full((1,), self.rank).cuda(device) ng1 = c10d.split_group(pg, [[0, 1], [2, 3, 4, 5, 6, 7]]) backend1 = ng1._get_backend(torch.device(device)) # comm split happens eagerly since device_id is passed to init_process_group. self.assertEqual(backend.comm_split_count(), 1) # dist.broadcast take Source rank on global process group if self.rank < 2: dist.broadcast(tensor, 0, group=ng1) self.assertEqual(tensor, torch.full((1,), 0)) else: dist.broadcast(tensor, 2, group=ng1) self.assertEqual(tensor, torch.full((1,), 2)) # test split with only one colored group, other ranks should be no color split. ng2 = c10d.split_group(pg, [[5, 6, 7]]) self.assertEqual(backend.comm_split_count(), 2) if self.rank >= 5: tensor2 = torch.full((1,), self.rank).cuda(device) dist.broadcast(tensor2, 7, group=ng2) self.assertEqual(tensor2, torch.full((1,), 7)) else: self.assertEqual(ng2, None) # a barrier and a cuda sync before destroying all pgs. dist.barrier(pg) torch.cuda.synchronize() dist.destroy_process_group() @requires_nccl_version((2, 18), "Need NCCL 2.18+ for ncclCommSplit") @skip_if_lt_x_gpu(8) def test_comm_recursive_split_group(self): store = c10d.FileStore(self.file_name, self.world_size) device = torch.device(f"cuda:{self.rank}") pg = self._create_process_group_nccl(store, self.opts(), device_id=device) backend = pg._get_backend(torch.device(device)) # split the default PG into 2 subgroups, each subgroup (ng1) has 4 ranks. tensor1 = torch.full((1,), self.rank).cuda(device) ng1 = c10d.split_group(pg, [[0, 1, 2, 3], [4, 5, 6, 7]]) backend1 = ng1._get_backend(torch.device(device)) if self.rank < 4: dist.broadcast(tensor1, 0, group=ng1) self.assertEqual(tensor1, torch.full((1,), 0)) else: dist.broadcast(tensor1, 4, group=ng1) self.assertEqual(tensor1, torch.full((1,), 4)) # comm split happens eagerly since device_id is passed to init_process_group. self.assertEqual(backend.comm_split_count(), 1) self.assertEqual(backend1.comm_split_count(), 0) # further split ng1 into 2 subgroups, each subgroup (ng2) has 2 ranks. tensor2 = torch.full((1,), self.rank).cuda(device) ng2 = c10d.split_group(ng1, [[0, 1], [2, 3]]) backend2 = ng2._get_backend(torch.device(device)) self.assertEqual(backend.comm_split_count(), 1) self.assertEqual(backend1.comm_split_count(), 1) self.assertEqual(backend2.comm_split_count(), 0) # execute collective calls within each 2-rank pg if self.rank == 0 or self.rank == 1: dist.broadcast(tensor2, 1, group=ng2) self.assertEqual(tensor2, torch.full((1,), 1)) if self.rank == 2 or self.rank == 3: dist.broadcast(tensor2, 2, group=ng2) self.assertEqual(tensor2, torch.full((1,), 2)) if self.rank == 4 or self.rank == 5: dist.broadcast(tensor2, 5, group=ng2) self.assertEqual(tensor2, torch.full((1,), 5)) if self.rank == 6 or self.rank == 7: dist.broadcast(tensor2, 6, group=ng2) self.assertEqual(tensor2, torch.full((1,), 6)) # a barrier and a cuda sync before destroying all pgs. dist.barrier(pg) torch.cuda.synchronize() dist.destroy_process_group() if __name__ == "__main__": assert ( not torch.cuda._initialized ), "test_distributed must not have initialized CUDA context on main process" run_tests()