# mypy: allow-untyped-defs import getpass import inspect import os import re import sys import tempfile from os.path import abspath, dirname from typing import Any, Callable, Dict, Optional, Set, Type, TYPE_CHECKING, Union import torch def is_fbcode(): return not hasattr(torch.version, "git_version") # to configure logging for dynamo, aot, and inductor # use the following API in the torch._logging module # torch._logging.set_logs(dynamo=, aot=, inductor) # or use the environment variable TORCH_LOGS="dynamo,aot,inductor" (use a prefix + to indicate higher verbosity) # see this design doc for more detailed info # Design doc: https://docs.google.com/document/d/1ZRfTWKa8eaPq1AxaiHrq4ASTPouzzlPiuquSBEJYwS8/edit# # the name of a file to write the logs to # [@compile_ignored: debug] log_file_name: Optional[str] = None # [@compile_ignored: debug] Verbose will print full stack traces on warnings and errors verbose = os.environ.get("TORCHDYNAMO_VERBOSE", "0") == "1" # [@compile_ignored: runtime_behaviour] verify the correctness of optimized backend verify_correctness = False # need this many ops to create an FX graph minimum_call_count = 1 # turn on/off DCE pass dead_code_elimination = True # disable (for a function) when cache reaches this size # controls the maximum number of cache entries with a guard on same ID_MATCH'd # object. It also controls the maximum size of cache entries if they don't have # any ID_MATCH'd guards. # [@compile_ignored: runtime_behaviour] cache_size_limit = 8 # [@compile_ignored: runtime_behaviour] safeguarding to prevent horrible recomps accumulated_cache_size_limit = 256 # [@compile_ignored: runtime_behaviour] skip tracing recursively if cache limit is hit skip_code_recursive_on_cache_limit_hit = True # whether or not to specialize on int inputs. This only has an effect with # dynamic_shapes; when dynamic_shapes is False, we ALWAYS specialize on int # inputs. Note that assume_static_by_default will also cause ints to get # specialized, so this is mostly useful for export, where we want inputs # to be dynamic, but accesses to ints should NOT get promoted into inputs. specialize_int = False # Whether or not to specialize on float inputs. Dynamo will always promote # float inputs into Tensor inputs, but at the moment, backends inconsistently # support codegen on float (this is to be fixed). specialize_float = True # legacy config, does nothing now! dynamic_shapes = True use_lazy_graph_module = ( os.environ.get("TORCH_COMPILE_USE_LAZY_GRAPH_MODULE", "1") == "1" ) # This is a temporarily flag, which changes the behavior of dynamic_shapes=True. # When assume_static_by_default is True, we only allocate symbols for shapes marked dynamic via mark_dynamic. # NOTE - this flag can be removed once we can run dynamic_shapes=False w/ the mark_dynamic API # see [Note - on the state of mark_dynamic] assume_static_by_default = True # This flag changes how dynamic_shapes=True works, and is meant to be used in conjunction # with assume_static_by_default=True. # With this flag enabled, we always compile a frame as fully static for the first time, and, if we fail # any guards due to wobbles in shape, we recompile with *all* the wobbled shapes as being marked dynamic. automatic_dynamic_shapes = True # This flag changes how the shapes of parameters are treated. # If this flag is set to True, then the shapes of torch.nn.Parameter as well as of torch.Tensor are attempted to be dynamic # If this flag is set to False, then the shapes of torch.nn.Parameter are assumed to be static, # while the shapes of torch.Tensor are assumed to be dynamic. force_parameter_static_shapes = True # This flag ensures that the shapes of a nn module are always assumed to be static # If the flag is set to True, then the shapes of a nn.module are assumed to be static # If the flag is set to False, then the shapes of a nn.module can be dynamic force_nn_module_property_static_shapes = True # Typically, if you mark_dynamic a dimension, we will error if the dimension # actually ended up getting specialized. This knob changes the behavior so # that we don't error at all. This is helpful for our CI where I'm using a # heuristic to mark batch dimensions as dynamic and the heuristic may get it # wrong. allow_ignore_mark_dynamic = False # Set this to False to assume nn.Modules() contents are immutable (similar assumption as freezing) guard_nn_modules = True # Uses CPython internal dictionary tags to detect mutation. There is some # overlap between guard_nn_modules_using_dict_tags and guard_nn_modules flag. # guard_nn_modules unspecializes the nn module instance and adds guard for each # relevant member of the nn modules. On the other hand, # guard_nn_modules_using_dict_tags specializes on each nn module instance but # uses low overhead dict version matching to detect mutations, obviating the # need to guard on members of the nn modules. With # guard_nn_modules_using_dict_tags, the guard_nn_modules is not really required # but kept around for debugging and discussing unspecializing nn module # variables. # TODO(janimesh, voz): Remove both of these flags (or atleast guard_nn_modules) # once we have reached stability for the guard_nn_modules_using_dict_tags. guard_nn_modules_using_dict_tags = True # This feature doesn't really work. We offer this flag for experimental # purposes / if you want to help us build out support. # # torchdynamo has limited support for tensor subclasses that implement # __torch_function__ see [Note: __torch_function__] in torch_function.py. # Our current support is limited to tensor subclasses # that DO NOT store metadata on the tensor (in general, dynamo does not # support Python code that stores extra attributes on tensors at present). # If your tensor subclass purely changes function call behavior via # __torch_function__, you can allow torchdynamo to trace into it by # adding it to traceable_tensor_subclasses. We don't do any safety checks, # so it is up to you to ensure that your subclass is well behaved. See also # https://github.com/pytorch/torchdynamo/issues/1948 # # We do NOT currently support __torch_dispatch__. The implementation is # currently buggy, the main show stopper for nontrivial use is # https://github.com/pytorch/torchdynamo/issues/1952 traceable_tensor_subclasses: Set[Type[Any]] = set() # Suppress errors in torch._dynamo.optimize, instead forcing a fallback to eager. # This is a good way to get your model to work one way or another, but you may # lose optimization opportunities this way. Devs, if your benchmark model is failing # this way, you should figure out why instead of suppressing it. suppress_errors = bool(os.environ.get("TORCHDYNAMO_SUPPRESS_ERRORS", False)) # Record and write an execution record of the current frame to a file # if an exception is encountered # @compile_ignored[debug] replay_record_enabled = os.environ.get("TORCH_COMPILE_REPLAY_RECORD", "0") == "1" # Rewrite assert statement in python with torch._assert rewrite_assert_with_torch_assert = True # Disable dynamo disable = os.environ.get("TORCH_COMPILE_DISABLE", False) # [@compile_ignored: runtime_behaviour] Get a cprofile trace of Dynamo cprofile = os.environ.get("TORCH_COMPILE_CPROFILE", False) # legacy config, does nothing now! skipfiles_inline_module_allowlist: Dict[Any, Any] = {} # If a string representing a PyTorch module is in this ignorelist, # the `allowed_functions.is_allowed` function will not consider it # when creating a list of PyTorch functions that will appear in # FX IR. allowed_functions_module_string_ignorelist = { "torch.distributions", "torch.testing", "torch._refs", "torch._prims", "torch._decomp", } # Debug Flag to try minifier at different stages. Possible values are {None, "aot", "dynamo"} # None - Minifier is switched off # dynamo - Runs minifier on the TorchDynamo produced graphs, if compilation fails # aot - Runs minifier on the Aot Autograd produced graphs, if compilation fails # [@compile_ignored: debug] repro_after = os.environ.get("TORCHDYNAMO_REPRO_AFTER", None) # Compiler compilation debug info # 1: Dumps the original graph out to repro.py if compilation fails # 2: Dumps a minifier_launcher.py if compilation fails. # 3: Always dumps a minifier_launcher.py. Good for segfaults. # 4: Dumps a minifier_launcher.py if the accuracy fails. # [@compile_ignored: debug] repro_level = int(os.environ.get("TORCHDYNAMO_REPRO_LEVEL", 2)) # By default, we try to detect accuracy failure by running both forward # and backward of a torchdynamo produced graph (if you are using repro_after # 'dynamo'). This setting forces us to only test the forward graph and # not the backward graph. This can be helpful if you're trying to debug # an inference only problem, but the minifier seems to be choking on the # backwards step # TODO: Detect this situation automatically so the user doesn't need # to manually configure this # [@compile_ignored: debug] repro_forward_only = os.environ.get("TORCHDYNAMO_REPRO_FORWARD_ONLY") == "1" # The tolerance we should use when testing if a compiled graph # has diverged so that we should treat it as an accuracy failure # [@compile_ignored: debug] repro_tolerance = 1e-3 # Whether to ignore non-floating point values when checking accuracy. # Checking accuracy of non-floating point values such as boolean tensors # can lead to false positives. # [@compile_ignored: debug] repro_ignore_non_fp = os.environ.get("TORCHDYNAMO_REPRO_IGNORE_NON_FP") == "1" # If True, when testing if two models are the same, we will test them against # a third fp64 reference and only report a problem if the RMSE relative to the # fp64 is greater. However, this will use more memory; you may disable this # if memory usage is too high. # [@compile_ignored: runtime_behaviour] same_two_models_use_fp64 = True # Not all backends support scalars. Some calls on torch.Tensor (like .item()) return a scalar type. # When this flag is set to False, we introduce a graph break instead of capturing. # This requires dynamic_shapes to be True. capture_scalar_outputs = os.environ.get("TORCHDYNAMO_CAPTURE_SCALAR_OUTPUTS") == "1" # Not all backends support operators that have dynamic output shape (e.g., # nonzero, unique). When this flag is set to False, we introduce a graph # break instead of capturing. This requires dynamic_shapes to be True. # If you set this to True, you probably also want capture_scalar_outputs # (these are separated for historical reasons). capture_dynamic_output_shape_ops = ( os.environ.get("TORCHDYNAMO_CAPTURE_DYNAMIC_OUTPUT_SHAPE_OPS", "0") == "1" ) # hybrid backed unbacked symints prefer_deferred_runtime_asserts_over_guards = False # For complex dynamic shapes guards that we're unable to specify with dynamo/export's # range constraints + dims + derived dims language, we raise constraint violation # errors or specialize by default. If set to True, this flag avoids crashing/specialization, # and allows complex guards as runtime assertions in the graph. allow_complex_guards_as_runtime_asserts = False # By default, dynamo will treat all ints as backed SymInts, which means (1) it # will wait to see the int change over multiple runs before generalizing and # (2) it will still always 0/1 specialize an int. When true, this knob # forces dynamo to treat _length_per_key and _offset_per_key on # KeyedJaggedTensor from torchrec as size-like unbacked SymInts, so that # they (1) generalize immediately and (2) unsoundly never compare equal to # 0/1. This is not on by default as AOTAutograd/Inductor cannot currently # compile this code; however, this can be useful for export. force_unspec_int_unbacked_size_like_on_torchrec_kjt = False # Should almost always be true in prod. This relaxes the requirement that cond's true_fn and # false_fn produces code with identical guards. enforce_cond_guards_match = True # Specify how to optimize a compiled DDP module. The flag accepts a boolean # value or a string. There are 4 modes. # 1. "ddp_optimizer" (or True): with "ddp_ptimizer", Dynamo will automatically # split model graph into pieces to match DDP bucket sizes to allow DDP # comm/compute overlap. # 2. "python_reducer" (experimental): this optimization requires the usage # of compiled_autograd. With "python_reducer", DDP will disable the C++ reducer # and use the Python reducer to allow compiled_autograd to trace the # communication and allow comm/compute overlap without graph-breaks. # 3. "python_reducer_without_compiled_forward" (experimental): this mode is # similar to "python_reducer". One should only use this optimization mode # when compiled_autograd is used but the DDP module is not compiled. # 4. "no_optimization" (or False): Dynamo won't split the model graph, nor # will Python reducer be used. With this mode, there will be no graph-breaks # and the original DDP C++ reducer will be used. There will no comm/compute # overlap. This mode CANNOT be used with compiled_autograd. # Note that to avoid breaking the existing usage, mode 1 and mode 4 can be # specified with a boolean value. True is using ddp_optimizer and False is # no optimization. optimize_ddp: Union[bool, str] = True # By default, Dynamo emits runtime asserts (e.g. torch._check, torch._check_is_size) in the graph. # In some cases those asserts could be performance costly # E.g. torch._check(tensor[0].item() > 2) for tensor on cuda will require cuda sync. # Setting this to True keeps them hinting to symbolic shapes engine, # but not be emitted in the graph. do_not_emit_runtime_asserts: bool = ( os.environ.get("TORCH_DYNAMO_DO_NOT_EMIT_RUNTIME_ASSERTS", "0") == "1" ) _ddp_optimization_mode = [ "ddp_optimizer", "python_reducer", # experimental mode "python_reducer_without_compiled_forward", # experimental mode "no_optimization", ] def _get_optimize_ddp_mode(): m = sys.modules[__name__] if isinstance(m.optimize_ddp, bool): if m.optimize_ddp: mode = "ddp_optimizer" else: mode = "no_optimization" elif isinstance(m.optimize_ddp, str): mode = m.optimize_ddp else: raise ValueError(f"Invalid type, {type(optimize_ddp)=}") assert mode in m._ddp_optimization_mode, f"Invalid mode {mode=}" return mode # Skip tracing the torchrec files added to trace_rules.FBCODE_SKIP_DIRS skip_torchrec = True # No longer used optimize_ddp_lazy_compile = False # Whether to skip guarding on FSDP-managed modules skip_fsdp_guards = True # Whether to apply torch._dynamo.disable() to FSDP2 hooks. # Defaults to True. If Traceable FSDP2 is used, set this to False. skip_fsdp_hooks = True # Make dynamo skip guarding on hooks on nn modules # Note: unsafe: if your model actually has hooks and you remove them, or doesn't and you add them, # dynamo will not notice and will execute whichever version you first compiled. skip_nnmodule_hook_guards = True # If True, raises exception if TorchDynamo is called with a context manager raise_on_ctx_manager_usage = True # If True, raise when aot autograd is unsafe to use raise_on_unsafe_aot_autograd = False # If true, error if you torch.jit.trace over a dynamo-optimized function. # If false, silently suppress dynamo error_on_nested_jit_trace = True # If true, error with a better message if we symbolically trace over a # dynamo-optimized function. If false, silently suppress dynamo. error_on_nested_fx_trace = True # Disables graph breaking on rnn. YMMV with backends. allow_rnn = False # If true, enables feature that captures PyTorch sparsity in the # exported FX graph. This flag should become the default eventually # and be removed, but currently provides a way to fall back to old # graph breaking behavior. capture_sparse_compute = False if is_fbcode() else True # If true, error if we try to compile a function that has # been seen before. # [@compile_ignored: runtime_behaviour] error_on_recompile = False # [@compile_ignored: debug] Whether to report any guard failures (deprecated: does not do anything) report_guard_failures = True # [@compile_ignored: debug] root folder of the project base_dir = dirname(dirname(dirname(abspath(__file__)))) # Trace through NumPy or graphbreak trace_numpy = True # Default NumPy dtypes when tracing with torch.compile # We default to 64bits. For efficiency, one may want to change these to float32 numpy_default_float = "float64" numpy_default_complex = "complex128" numpy_default_int = "int64" # use numpy's PRNG if True, pytorch otherwise use_numpy_random_stream = False # Use C++ guard manager enable_cpp_guard_manager = os.environ.get("TORCHDYNAMO_CPP_GUARD_MANAGER", "1") == "1" # Inline inbuilt nn modules inline_inbuilt_nn_modules = not is_fbcode() # When set, total compile time instruction count is recorded using # torch._dynamo.utilsCompileTimeInstructionCounter. record_compile_time_instruction_count = False def default_debug_dir_root(): # [@compile_ignored: debug] DEBUG_DIR_VAR_NAME = "TORCH_COMPILE_DEBUG_DIR" if DEBUG_DIR_VAR_NAME in os.environ: return os.path.join(os.environ[DEBUG_DIR_VAR_NAME], "torch_compile_debug") elif is_fbcode(): return os.path.join( tempfile.gettempdir(), getpass.getuser(), "torch_compile_debug" ) else: return os.path.join(os.getcwd(), "torch_compile_debug") # [@compile_ignored: debug] debug_dir_root = default_debug_dir_root() # [@compile_ignored: debug] _save_config_ignore = { "repro_after", "repro_level", # workaround: "cannot pickle PyCapsule" "constant_functions", # workaround: "cannot pickle module" "skipfiles_inline_module_allowlist", } # for backend="cudagraphs", mutations on input be sent to the cudagraph backend # or replayed in aot_autograd epilogue. default is False because mutation on inputs # can prevent cudagraphing. cudagraph_backend_keep_input_mutation = False # enable cudagraph support for mutated inputs from prior cudagraph pool cudagraph_backend_support_input_mutation = False # When True, only ops that have the torch.Tag.pt2_compliant tag # will be allowed into the graph; all other ops will be disallowed # and will fall back to eager-mode PyTorch. Useful to ensure # correctness of custom ops. only_allow_pt2_compliant_ops = False capture_autograd_function = True # enable/disable dynamo tracing for `torch.func` transforms capture_func_transforms = True # If to log Dynamo compilation metrics into log files (for OSS) and Scuba tables (for fbcode). log_compilation_metrics = True # A set of logging functions which will be reordered to the end of graph breaks, # allowing dynamo to construct larget graph. Note that there are some # limitations to this, such as how it does not correctly print objects that were # mutated after the print statement. reorderable_logging_functions: Set[Callable[[Any], None]] = set() # simulates what would happen if we didn't have support for BUILD_SET opcode, # used for testing inject_BUILD_SET_unimplemented_TESTING_ONLY = False _autograd_backward_strict_mode_banned_ops = [ "stride", "requires_grad", "storage_offset", "layout", "data", ] _autograd_backward_strict_mode_banned_ops.extend( [name for name, _ in inspect.getmembers(torch.Tensor) if re.match(r"^is_.*", name)] ) # Enables caching of dispatches to fake tensors. fake_tensor_cache_enabled = ( os.environ.get("TORCH_FAKE_TENSOR_DISPATCH_CACHE", "1") == "1" ) # Enables cross checking between the fake tensor cache and dispatch. fake_tensor_cache_crosscheck_enabled = ( os.environ.get("TORCH_FAKE_TENSOR_DISPATCH_CACHE_CROSSCHECK", "0") == "1" ) # Enables the Compiled Autograd engine to trace .backward() calls made under torch.compile(). # Note: AOT Autograd will still trace joint graphs. compiled_autograd = False # Enables use of collectives *during* compilation to synchronize behavior # across ranks. Today, this is used solely to modify automatic_dynamic_shapes # behavior, making it so that we infer that if an input is dynamic by # inspecting whether or not its input size varies across ranks. Because # this synchronization uses collectives, all ranks must run compilation at # the same time; ranks must not diverge with graph breaks. This can be most # reliably achieved by ensuring PT2 only is run on SPMD programs. If this # invariant is inviolated, you will likely deadlock NCCL and encounter a # NCCL timeout. enable_compiler_collectives = os.environ.get("TORCH_COMPILER_COLLECTIVES", "0") == "1" if TYPE_CHECKING: from torch.utils._config_typing import * # noqa: F401, F403 def _make_closure_patcher(**changes): ... from torch.utils._config_module import install_config_module install_config_module(sys.modules[__name__])