# mypy: allow-untyped-defs from __future__ import annotations import contextlib import dataclasses import enum import functools import logging import re import threading import traceback import unittest.mock import weakref from abc import abstractmethod from contextlib import contextmanager from dataclasses import dataclass from typing import ( Any, Callable, Generic, NamedTuple, Optional, TYPE_CHECKING, TypeVar, Union, ) import torch from torch.utils import _pytree as pytree from torch.utils._backport_slots import dataclass_slots from torch.utils._traceback import CapturedTraceback, format_frame from torch.utils.weak import WeakTensorKeyDictionary log = logging.getLogger(__name__) if TYPE_CHECKING: import sympy """ torch._guards is the definitional source of truth for general purpose guard structures. An important thing to keep in mind here is the preservation of layering. There should be no dynamo notions, and no guard installation notions here. """ COMPILE_ID_PATTERN = re.compile(r"^(?P\d+)/(?P\d+)$") CA_COMPILE_ID_PATTERN = re.compile( r"^!(?P\d+)(?:/(?P\d+)/(?P\d+))?$" ) # [Note: Updating CompiledId] # # CompiledId represents a unique program-level identifier, and we want to keep that # property as the codebase evolves. This property is relied on even outside of the pytorch # repo, e.g. tlparse or other internal tooling. The in-memory format can be freely changed, # as those dependencies only consume the string serialization. # # The string form should be: # 1. Program-level uid: CompileId can uniquely identify a compiled graph. # 2. Storage efficient: This object is logged in nearly every entry. We should elide symbols when possible. # 3. Compact: The string form is directly displayed by some tools. Special symbols are okay. # TODO: mark as kw_only=True once we drop support for bool: return self in (GuardSource.GLOBAL_FSDP_MODULE, GuardSource.LOCAL_FSDP_MODULE) def is_specialized_nn_module(self) -> bool: import torch._dynamo.config as config if config._unsafe_skip_fsdp_module_guards: return ( self in ( GuardSource.GLOBAL_SPECIALIZED_NN_MODULE, GuardSource.LOCAL_SPECIALIZED_NN_MODULE, ) or self.is_fsdp_module() ) return self in ( GuardSource.GLOBAL_SPECIALIZED_NN_MODULE, GuardSource.LOCAL_SPECIALIZED_NN_MODULE, ) def is_unspecialized_nn_module(self) -> bool: return self in ( GuardSource.GLOBAL_UNSPECIALIZED_NN_MODULE, GuardSource.LOCAL_UNSPECIALIZED_NN_MODULE, GuardSource.GLOBAL_UNSPECIALIZED_BUILTIN_NN_MODULE, GuardSource.LOCAL_UNSPECIALIZED_BUILTIN_NN_MODULE, ) def is_unspecialized_builtin_nn_module(self) -> bool: return self in ( GuardSource.GLOBAL_UNSPECIALIZED_BUILTIN_NN_MODULE, GuardSource.LOCAL_UNSPECIALIZED_BUILTIN_NN_MODULE, ) def is_local(self): return self in ( GuardSource.LOCAL, GuardSource.LOCAL_SPECIALIZED_NN_MODULE, GuardSource.LOCAL_FSDP_MODULE, GuardSource.LOCAL_UNSPECIALIZED_NN_MODULE, GuardSource.LOCAL_UNSPECIALIZED_BUILTIN_NN_MODULE, ) """ Base class for a "GuardBuilder" role. The GuardBuilderBase role is to represent a scope within which to build a guard. The name is a little confusing, as its not a builder, but for the sake of avoiding a lot of renames and keeping the original reference to torchdynamo's GuardBuilder. Note: create_fn is invoked with a GuardBuilderBase and a Guard. A GuardBuilder is chosen based on GuardSource's select function. There is value in keeping this GuardBuilderBase empty to keep layering clean. """ class GuardBuilderBase: pass @dataclasses.dataclass(frozen=True) class SLoc: framework_loc: Optional[Union[traceback.FrameSummary, str]] maybe_user_loc: Optional[str] def __str__(self): floc = ( self.framework_loc if isinstance(self.framework_loc, str) else format_frame(self.framework_loc) ) if self.maybe_user_loc is not None: return f"{self.maybe_user_loc} ({floc})" else: return f"({floc})" class ShapeGuard(NamedTuple): expr: sympy.logic.boolalg.Boolean sloc: SLoc size_oblivious: bool @dataclass_slots @dataclasses.dataclass class Guard: # originating_source is the source that called the make_guard method to # construct this guard object. The property name specifies what exactly it # is the guard is guarding on. The meaning of the name is dependent on the # create_fn; you must look at the use-site inside create_fn to know what # name means. # # That being said, although you might think this is just a "name", name is # usually an arbitrary Python expression that will be evaluated with all # globals (and locals, if you create a LOCAL guard) to extract the Python # object that we want to perform guard tests on. This evaluation # typically happens in GuardBuilder.eval. In these cases, name is # typically produced by originating_source.name() (not to be confused with # GuardSource - the property source). # # Occasionally, name is not a valid Python expression; sometimes # it is meaningless. Example create_fns that are like this include # GRAD_MODE and SHAPE_ENV. originating_source: Source create_fn: Callable[[GuardBuilderBase, Guard], None] # Export only. These values are written to at time of guard check_fn creation. guard_types: Optional[list[str]] = None code_list: Optional[list[str]] = None obj_weakref: Optional[object] = None guarded_class_weakref: Optional[type] = None stack: Optional[CapturedTraceback] = None user_stack: Optional[traceback.StackSummary] = None _hash: Optional[int] = None def __hash__(self): if self._hash is None: self._hash = hash((self.name, self.source, id(self.create_fn))) return self._hash def sort_key(self): # Put the duplicate input guards at the end. The duplicate guards have # two sources while guard.name only considers one source. is_duplicate_input = ( isinstance(self.create_fn, functools.partial) and self.create_fn.func is torch._dynamo.guards.GuardBuilder.DUPLICATE_INPUT ) return ( is_duplicate_input, self.source.value if self.source else -1, len(self.name), self.name, self.inner_create_fn().__code__.co_firstlineno, ) def __lt__(self, other): return self.sort_key() < other.sort_key() def inner_create_fn(self): if isinstance(self.create_fn, functools.partial): return self.create_fn.func else: return self.create_fn @property def name(self) -> str: return self.originating_source.name() @property def source(self) -> GuardSource: return self.originating_source.guard_source() @staticmethod def weakref_to_str(obj_weakref): """ This is a workaround of a Python weakref bug. `obj_weakref` is instance returned by `weakref.ref`, `str(obj_weakref)` is buggy if the original obj overrides __getattr__, e.g: class MyConfig(dict): def __getattr__(self, x): return self[x] obj = MyConfig(offset=5) obj_weakref = weakref.ref(obj) str(obj_weakref) # raise error: KeyError: '__name__' """ if isinstance(obj_weakref, weakref.ReferenceType): obj = obj_weakref() if obj is not None: return f"" else: return f"" else: return str(obj_weakref) def __repr__(self): s = f""" {self.source.name.lower() if self.source else ""} {repr(self.name)} {self.inner_create_fn().__name__} {{ 'guard_types': {self.guard_types}, 'code': {self.code_list}, 'obj_weakref': {self.weakref_to_str(self.obj_weakref)} 'guarded_class': {self.guarded_class_weakref} }} """ return s def __str__(self): output = f"Name: {repr(self.name)}\n" source = self.source.name.lower() if self.source else "" output += f" Source: {source}\n" output += f" Create Function: {self.inner_create_fn().__name__}\n" output += f" Guard Types: {self.guard_types}\n" output += f" Code List: {self.code_list}\n" output += f" Object Weakref: {self.weakref_to_str(self.obj_weakref)}\n" output += f" Guarded Class Weakref: {self.guarded_class_weakref}\n" return output def create(self, builder: GuardBuilderBase): try: return self.create_fn(builder, self) except Exception: log.exception("Error while creating guard:\n%s", str(self).rstrip()) if self.stack: log.error("Created at:\n%s", "".join(self.stack.format()[-4:]).rstrip()) raise def is_specialized_nn_module(self): return self.source.is_specialized_nn_module() def is_fsdp_module(self): return self.source.is_fsdp_module() def is_local(self): return self.source.is_local() def set_export_info(self, guard_type, guarded_class, code_list, obj_weakref): if not self.guard_types: self.guard_types = [] self.guard_types.append(guard_type) assert self.guarded_class_weakref in ( guarded_class, None, ), "Guarded class id must be identical, or None" self.guarded_class_weakref = guarded_class if not self.code_list: self.code_list = code_list else: self.code_list.extend(code_list) # Some objects are ephemeral, e.g., list[slice(1, 2)]. If we have # multiple guards on the same object, the weakref can die between the # invocation of set_export_info calls. So a dead weakref is also # acceptable. assert ( self.obj_weakref in (obj_weakref, None) or callable(self.obj_weakref) and self.obj_weakref() is None ), "Guarded object must be identical, None or ephemeral (dead weakref)" self.obj_weakref = obj_weakref T = TypeVar("T") """ Parent structure for guard env expressions. A GuardEnvExpr can have any subtype. Note: All subtypes must be handled exhaustively in torch._dynamo.guards._parse_guard_env_guards to avoid a RuntimeError. """ @dataclasses.dataclass class GuardEnvExpr: pass """ A class representing a pair of duplicate inputs. input_pos_a and input_pos_b are input positions we have deduped. """ @dataclasses.dataclass class DuplicateInputs(GuardEnvExpr): input_source_a: Source input_source_b: Source def __post_init__(self): assert self.input_source_a != self.input_source_b """ A class representing storage overlap relations among inputs that aliases the same storage. Given that a set of tensors alias the same storage, this guard checks whether they actually have overlapping storages. While non_overlapping_sources represent input tensors that definitely don't have any storage overlapping with any other input, overlapping_sources represent tensors that either: 1. Do overlap some other input tensor 2. Might not overlap some other input tensor, but we are not sure """ @dataclasses.dataclass class StorageOverlap(GuardEnvExpr): overlapping_sources: list[Source] non_overlapping_sources: list[Source] """ Checkpointable is an interface for driving state snapshotting, left purposely vague for now. copy_graphstate() -> T, a somewhat legacy name, is expected to emit a snapshot of any type that can also be taken in at restore_graphstate(T) calls. When to snapshot, is, at the moment, an implementation detail of upstream callers. Checkpointable does not provide any garuantees around consistency, idempotency, or safety of calling its APIs, yet. In the future, it will have a closer coupling to a generic Checkpoint management system. """ class Checkpointable(Generic[T]): @abstractmethod def copy_graphstate(self) -> T: ... @abstractmethod def restore_graphstate(self, state: T): ... class GuardsCheckpointState: """ The GuardCheckpointState - it is the T of Checkpointable[T] for GuardsContext """ dynamo_guards: set[Guard] = set() def __init__(self, dynamo_guards): self.dynamo_guards = dynamo_guards def diff(self, other): """ Produces a delta against another GuardsCheckpointState. Returns None if no delta is found, otherwise, return a set() of mismatched Guard type objects. """ r = self.dynamo_guards.difference(other.dynamo_guards) if len(r) == 0: return None return r def __eq__(self, other): return self.diff(other) is None class ModuleContextCheckpointState: nn_modules: dict[str, torch.nn.Module] = {} def __init__(self, nn_modules): self.nn_modules = nn_modules def diff(self, other): """ Produces a delta against another ModuleContextCheckpointState. Returns None if no delta is found, otherwise, return a set() of mismatched module key names. """ r = set(self.nn_modules.keys()).difference(set(other.nn_modules.keys())) if len(r) == 0: return None return r def __eq__(self, other): return self.diff(other) is None class ModuleContext(Checkpointable[ModuleContextCheckpointState]): def __init__(self) -> None: self.nn_modules: dict[str, Any] = {} def copy_graphstate(self): return ModuleContextCheckpointState(dict(self.nn_modules)) def restore_graphstate(self, state): assert isinstance(state, ModuleContextCheckpointState) self.nn_modules = state.nn_modules class GlobalContextCheckpointState: global_state: dict[str, tuple[Callable, ...]] = {} def __init__(self, global_states): self.global_state = global_states def diff(self, other): """ Produces a delta against another GlobalContextCheckpointState. Returns None if no delta is found, otherwise, return a set() of mismatched global key names. """ r = set(self.global_state.keys()).difference(set(other.global_state.keys())) if len(r) == 0: return None return r def __eq__(self, other): return self.diff(other) is None class GlobalContext(Checkpointable[GlobalContextCheckpointState]): """ This keeps track of the global torch state during tracing of a function. For example, torch.is_grad_enabled. """ _supported_global_states = { "grad_enabled", "torch_function_enabled", "autocast_enabled", "autocast_cpu_enabled", "autocast_gpu_dtype", "autocast_cpu_dtype", "autocast_cache_enabled", } def __init__(self) -> None: self.global_state: dict[str, tuple[Callable, ...]] = {} def copy_graphstate(self): return GlobalContextCheckpointState(dict(self.global_state)) def restore_graphstate(self, state): assert isinstance(state, GlobalContextCheckpointState) self.global_state = state.global_state assert ( len(self.global_state) == len(self._supported_global_states) and set(self.global_state.keys()) == self._supported_global_states ), "Global state mismatch" for func, args in self.global_state.values(): func(args) """ A GuardsContext is a checkpointable representation of all the guards in the current tracing context. It's lifecycle is bound 1:1 to the tracing context, and it should never be instantiated directly outside of it. For passing around internal state representations of this object, prefer to extract them with copy_graphstate to produce a GuardsCheckpointState. """ # Like a Set[Guard] but will record the user stack on all guards at the # time they were installed at their destination class GuardsSet: def __init__(self, inner=None): if inner is None: inner = set() self.inner = inner def __iter__(self): return iter(self.inner) def __len__(self): return len(self.inner) # Subtraction along with bool is typically used to determine the delta of # added guards between checkpoints for higher order ops def __sub__(self, other): return GuardsSet(self.inner - other.inner) def __bool__(self): return bool(self.inner) def add(self, guard: Guard, *, collect_debug_stack=True, skip=0): if guard in self.inner: return if collect_debug_stack: if guard.stack is None: guard.stack = CapturedTraceback.extract(skip=1 + skip) if guard.user_stack is None: guard.user_stack = TracingContext.extract_stack() self.inner.add(guard) def update(self, *others: set[Guard]): for o in others: for g in o: self.add(g, skip=1) def remove_guards_with_source(self, source): """Delete all guards with a given source""" self.inner = {g for g in self.inner if g.originating_source != source} class GuardsContext(Checkpointable[GuardsCheckpointState]): def __init__(self) -> None: self.dynamo_guards: GuardsSet = GuardsSet() self.aotautograd_guards: list[GuardEnvExpr] = [] def copy_graphstate(self): return GuardsCheckpointState(set(self.dynamo_guards.inner)) def restore_graphstate(self, state): # NB: "steals" the passed in state assert isinstance(state, GuardsCheckpointState) self.dynamo_guards = GuardsSet(state.dynamo_guards) class HopSubgraphCache: @abstractmethod def add_dynamo_identifier(self, cache_key: str, identifier: str): ... @abstractmethod def get_dynamo_identifier(self, cache_key: str) -> Optional[str]: ... @abstractmethod def add_autograd_key_entry(self, identifier: str, key: Callable): ... @abstractmethod def get_autograd_key_entry(self, identifier: str): ... @abstractmethod def add_proxy_dispatch_entry(self, identifier: str, key: Callable): ... @abstractmethod def get_proxy_dispatch_entry(self, identifier: str): ... class InvokeSubgraphCache(HopSubgraphCache): def __init__(self) -> None: self.autograd_cache: dict[str, Callable] = {} self.proxy_dispatch_cache: dict[str, Callable] = {} self.dynamo_identifiers: dict[str, str] = {} def add_dynamo_identifier(self, cache_key: str, identifier: str): self.dynamo_identifiers[cache_key] = identifier def get_dynamo_identifier(self, cache_key: str) -> Optional[str]: return self.dynamo_identifiers.get(cache_key, None) def add_autograd_key_entry(self, identifier: str, key: Callable): self.autograd_cache[identifier] = key def get_autograd_key_entry(self, identifier: str): return self.autograd_cache.get(identifier, None) def add_proxy_dispatch_entry(self, identifier: str, key: Callable): self.proxy_dispatch_cache[identifier] = key def get_proxy_dispatch_entry(self, identifier: str): return self.proxy_dispatch_cache.get(identifier, None) class HopDispatchSetCache: def __init__(self) -> None: # Delayed import to avoid circular dependency from torch._higher_order_ops.invoke_subgraph import invoke_subgraph self.hop_cache_map = {invoke_subgraph: InvokeSubgraphCache()} def get_cache( self, op: torch._ops.HigherOrderOperator ) -> Optional[HopSubgraphCache]: if op not in self.hop_cache_map: return None return self.hop_cache_map[op] # type: ignore[index] _TLS = threading.local() """ TracingContext is the source of truth for all currently accumulated information needed to trace. Its lifecycle is kept 1:1 when using TorchDynamo, but other systems are open to managing their own TracingContext with that in mind. The purpose of TracingContext is not to be a dumping ground, or god object, but rather to avoid having to plumb complex subsystems across multiple verticals. Ex: A common example is guard accumulation between dynamo, shape_env, aot_autograd, and inductor. Accessing the current tracing context via TracingContext.get() allows users to accumulate their own guards for processing, without needing to know how to plumb objects back up to where frame interpretation happened. Note that you can end up with multiple TracingContext for a single compilation of a frame, as we reset the TracingContext whenever we restart analysis. CompileContext is a more overarching context that encompasses multiple restarts. """ class CompileContext: @staticmethod def get() -> CompileContext: assert _TLS.compile_context is not None return _TLS.compile_context @staticmethod def try_get() -> Optional[CompileContext]: return getattr(_TLS, "compile_context", None) def __init__(self, compile_id): assert compile_id is None or isinstance(compile_id, CompileId) self.compile_id: Optional[CompileId] = compile_id self.attempt = 0 # Verbose ShapeEnv guards produced. self.shape_env_guards: list[str] = [] @staticmethod def current_compile_id(): self = CompileContext.try_get() if self is None: return None return self.compile_id @staticmethod def current_trace_id(): self = CompileContext.try_get() if self is None: return None if self.compile_id is None: return None return TraceId(self.compile_id, self.attempt) class TracingContext: """ Provides the currently installed TracingContext, or None. Note that it is a staticmethod, and invocations outside of `with tracing()` (see below), are valid but will return None. """ @staticmethod def try_get() -> Optional[TracingContext]: return getattr(_TLS, "tracing_context", None) @staticmethod def get() -> TracingContext: if ctx := TracingContext.try_get(): return ctx raise RuntimeError( "TracingContext.get() must be called within an ongoing trace." ) def __init__(self, fake_mode): self.guards_context = GuardsContext() self.module_context = ModuleContext() self.global_context = GlobalContext() self.fake_mode = fake_mode self.frame_summary_stack = [] # This is morally part of frame_summary_stack, but it is kept separate # for clarity. As we process a frame, this variable gets updated # to keep track of what line we are in the function. We make a # function call, this gets cleared and the frame location is pushed # to frame_summary_stack (prepping this variable for the inner frame's # progress) self.loc_in_frame = None # this is only set after aot_autograd self.fw_metadata = None # this is only set after aot_autograd self.aot_graph_name = None self.params_flat = None self.params_flat_unwrap_subclasses = None self.params_unwrapped_to_flat_index = None # this is for extended return calling convention from backend # compiler to aot_autograd # Per output, what the compiler specified stride of the output is, # or None if no stride is known. This is always the HINT, it # is never a SymInt (it would be better if it was a SymInt, but # I can't conveniently get this from Inductor atm. Also, be # careful not to accidentally induce guards on the SymInt if # you ever do change this in aot_autograd.py; you should check # on permutations preferentially.) self.output_strides: Optional[list[Optional[tuple[int, ...]]]] = None # When this is True, whenever we encounter an int in Dynamo tracing, # we will (1) force unspec it and (2) force it as a size-like unbacked # integer. This is currently used when processing certain lists of # ints that are known to be size-like and may have 0/1 entries that we # must not specialize on. self.force_unspec_int_unbacked_size_like = False # See note [Tensor Fakification and Symbol Caching] self.tensor_to_context = WeakTensorKeyDictionary() # If this true, Aot Autograd will return output Fake Tensors with appropiate # meta on the first invocation # see note: [Returning Fake Tensors on First AOT Autograd Call] self.fakify_first_call = False self.hop_dispatch_set_cache = HopDispatchSetCache() def clear(self): # Look at the note in output_graph.py in function `save_global_state` # for the context on clearing global context. self.global_context.global_state = {} @staticmethod @contextmanager def patch(**kwargs): prior = {} ctx = TracingContext.get() for key in kwargs.keys(): # KeyError on invalid entry prior[key] = getattr(ctx, key) for key, val in kwargs.items(): setattr(ctx, key, val) try: yield finally: for key, val in prior.items(): setattr(ctx, key, val) @staticmethod def extract_stack(): self = TracingContext.try_get() if self is None: return traceback.StackSummary() stack = self.frame_summary_stack if self.loc_in_frame is not None: stack = stack + [self.loc_in_frame] return traceback.StackSummary.from_list(stack) # Call this when you want to call into some code that isn't necessarily # associated with the current frame state @staticmethod @contextlib.contextmanager def clear_frame(): tc = TracingContext.get() with ( unittest.mock.patch.object(tc, "frame_summary_stack", []), unittest.mock.patch.object(tc, "loc_in_frame", None), ): try: yield except Exception as e: # Prevent real_stack from getting attached # # The invariant is that if an Exception as real_stack, we've # appropriately attached a user stack and we no longer need to # attach anything. Because we cannot conveniently interpose # when an exception is thrown, we instead interpose everywhere # we set what the user stack is set (using the context # manager). However, our compiler stack does "tail calls" # (when it calls into user compiler), at which point the # parent exception frames would incorrectly attach an # incorrect frame. # # However, if, somehow, someone raised an exception with this # scope that had a stack (for example, because they are # restoring the user stack state appropriately as they process # node by node), we should respect it. Thus, we cannot # unconditionally set None. if not hasattr(e, "real_stack"): e.real_stack = None # type: ignore[attr-defined] raise @staticmethod @contextlib.contextmanager def current_frame(frame_summary): # frame_summary can be None to solely take advantage of real_stack # attachment to thrown exceptions tc = TracingContext.get() if frame_summary is not None: tc.frame_summary_stack.append(frame_summary) old = tc.loc_in_frame tc.loc_in_frame = None try: yield except Exception as e: if not hasattr(e, "real_stack"): e.real_stack = tc.extract_stack() # type: ignore[attr-defined] raise finally: if frame_summary is not None: tc.frame_summary_stack.pop() tc.loc_in_frame = old @staticmethod @contextlib.contextmanager def report_output_strides(): tc = TracingContext.try_get() if tc is None: yield None return old_output_strides = tc.output_strides tc.output_strides = [] try: yield tc.output_strides finally: tc.output_strides = old_output_strides @staticmethod def set_current_loc(filename, lineno, frame_name): TracingContext.get().loc_in_frame = traceback.FrameSummary( filename, lineno, frame_name, lookup_line=False ) @contextmanager def compile_context(context: Optional[CompileContext]): old_context = getattr(_TLS, "compile_context", None) _TLS.compile_context = context try: yield context finally: _TLS.compile_context = old_context @contextmanager def tracing(context: Optional[TracingContext]): """ This function installs the passed in tracing context as a dynamic scoped global variable. Calls to TracingContext.get() while not under a `with tracing()` context will return None. """ old_context = getattr(_TLS, "tracing_context", None) _TLS.tracing_context = context try: yield context except Exception as e: if not hasattr(e, "real_stack") and context is not None: e.real_stack = context.extract_stack() # type: ignore[attr-defined] raise finally: if ( context is not None and context.fake_mode is not None and context.fake_mode.shape_env is not None ): context.fake_mode.shape_env.cleanup() _TLS.tracing_context = old_context # Subclasses can be found in torch/_dynamo/source.py # TODO(voz): Consider a toplevel torch/_source.py @dataclasses.dataclass(frozen=True) class Source: def is_dict_key(self): return False def is_ephemeral(self): return False def reconstruct(self, codegen): raise NotImplementedError def guard_source(self) -> GuardSource: raise NotImplementedError def name(self) -> str: raise NotImplementedError def make_guard(self, fn) -> Guard: if self.guard_source() is GuardSource.CONSTANT: raise NotImplementedError return Guard(self, fn) def is_specialized_nn_module(self) -> bool: return self.guard_source().is_specialized_nn_module() def subguards_allowed(self): """True if you can guard on attributes of this""" return self.guard_source() != GuardSource.SYNTHETIC_LOCAL # Subclasses can be found in torch/_dynamo/source.py @dataclasses.dataclass(frozen=True) class ChainedSource(Source): base: Source def is_dict_key(self): # Recurse until you either hit a ConstDictKey or a Source return self.base.is_dict_key() def is_ephemeral(self): return self.base.is_ephemeral() def get_base(self) -> Source: current: Source = self while isinstance(current, ChainedSource): current = current.base return current def detect_fake_mode(inputs: Any = None): """ Attempts to "detect" what the current fake mode is. If there is one ambiently available from TracingContext, we preferentially use that. Otherwise, we heuristically detect the fake mode via the following sources, in order of priority: - Currently active fake mode on stack - Fake mode associated with passed in tensors (inputs does not have to be flattened) """ from torch._subclasses.fake_tensor import FakeTensor, FakeTensorMode fake_modes = [] if context := TracingContext.try_get(): fake_mode = context.fake_mode if fake_mode is not None: fake_modes.append((fake_mode, "tracing context", 0)) from torch.utils._python_dispatch import _get_current_dispatch_mode_stack for i, m in enumerate(reversed(_get_current_dispatch_mode_stack())): if isinstance(m, FakeTensorMode): fake_modes.append((m, "active fake mode", i)) flat_inputs = pytree.tree_leaves(inputs) for i, flat_input in enumerate(flat_inputs): if isinstance(flat_input, FakeTensor): fake_modes.append((flat_input.fake_mode, "fake tensor input", i)) if fake_modes: fake_mode, desc1, i1 = fake_modes[0] for m, desc2, i2 in fake_modes[1:]: assert fake_mode is m, ( f"fake mode ({fake_mode}) from {desc1} {i1} doesn't match mode ({m}) from {desc2} {i2}\n\n" f"fake mode from {desc1} {i1} allocated at:\n{fake_mode.stack}\n" f"fake mode from {desc2} {i2} allocated at:\n{m.stack}" ) return fake_mode else: return None def active_fake_mode(): """ Inspects the dispatch mode stack for an active fake mode and returns it. Returns None if no fake mode is active. """ from torch._subclasses.fake_tensor import FakeTensorMode from torch.utils._python_dispatch import _get_current_dispatch_mode_stack for _, m in enumerate(reversed(_get_current_dispatch_mode_stack())): if isinstance(m, FakeTensorMode): return m return None