# SPDX-License-Identifier: Apache-2.0 # SPDX-FileCopyrightText: Copyright contributors to the vLLM project import ast import contextvars import dataclasses import hashlib import json import operator import os import pprint import time from collections.abc import Callable, Generator, Sequence from contextlib import contextmanager from copy import deepcopy from functools import partial from typing import Any import torch import torch.fx as fx from torch._dispatch.python import enable_python_dispatcher from torch._logging._internal import trace_structured import vllm.envs as envs from vllm.config import CompilationConfig, CUDAGraphMode, VllmConfig from vllm.config.compilation import DynamicShapesType from vllm.config.utils import Range, hash_factors from vllm.logger import init_logger from vllm.logging_utils import lazy from vllm.platforms import current_platform from vllm.tracing import instrument, instrument_manual from vllm.utils.import_utils import resolve_obj_by_qualname from .compiler_interface import ( CompilerInterface, EagerAdaptor, InductorAdaptor, InductorStandaloneAdaptor, is_compile_cache_enabled, ) from .counter import compilation_counter from .partition_rules import ( inductor_partition_rule_context, should_split, ) from .passes.inductor_pass import InductorPass, pass_context # from .passes.pass_manager import PostGradPassManager logger = init_logger(__name__) def make_copy_and_call( sym_tensor_indices: list[int], input_buffers: list[torch.Tensor | None], callable_fn: Callable[..., Any], ) -> Callable[..., Any]: """Create a wrapper that copies inputs to static buffers before calling. This is used for cudagraph input copying where we need to copy dynamic tensors to static buffers before invoking the compiled graph. Args: sym_tensor_indices: Indices of tensors with symbolic shapes input_buffers: List of static buffers (can contain None for lazy init) callable_fn: The compiled function to call Returns: A wrapper function that copies inputs and calls the compiled function """ def copy_and_call(*args: Any) -> Any: list_args = list(args) for i, index in enumerate(sym_tensor_indices): runtime_tensor = list_args[index] runtime_shape = runtime_tensor.shape[0] # lazy initialization of buffer on first call if input_buffers[i] is None: input_buffers[i] = runtime_tensor.clone() static_tensor = input_buffers[i][:runtime_shape] # type: ignore[index] static_tensor.copy_(runtime_tensor) list_args[index] = static_tensor return callable_fn(*list_args) return copy_and_call def make_compiler(compilation_config: CompilationConfig) -> CompilerInterface: assert not envs.VLLM_USE_MEGA_AOT_ARTIFACT or envs.VLLM_USE_STANDALONE_COMPILE, ( "VLLM_USE_MEGA_AOT_ARTIFACT=1 requires VLLM_USE_STANDALONE_COMPILE=1" ) if compilation_config.backend == "inductor": # Use standalone compile only if requested, version is new enough, # and the symbol actually exists in this PyTorch build. if envs.VLLM_USE_STANDALONE_COMPILE and hasattr( torch._inductor, "standalone_compile" ): logger.debug("Using InductorStandaloneAdaptor") return InductorStandaloneAdaptor( compilation_config.compile_cache_save_format ) else: logger.debug("Using InductorAdaptor") return InductorAdaptor() elif compilation_config.backend == "eager": logger.debug("Using EagerAdaptor") return EagerAdaptor() else: logger.debug("Using custom backend: %s", compilation_config.backend) compiler = resolve_obj_by_qualname(current_platform.get_compile_backend())() assert isinstance(compiler, CompilerInterface) return compiler class CompilerManager: """ A manager to manage the compilation process, including caching the compiled graph, loading the compiled graph, and compiling the graph. The cache is a dict mapping `(runtime_shape, graph_index, backend_name)` to `any_data` returned from the compiler. When serializing the cache, we save it to a Python file for readability. We don't use json here because json doesn't support int as key. """ def __init__(self, compilation_config: CompilationConfig) -> None: self.cache: dict[tuple[Range, int, str], Any] = dict() self.is_cache_updated = False self.compilation_config = compilation_config self.compiler = make_compiler(compilation_config) self.loaded_artifacts: dict[str, Any] = {} def compute_hash(self, vllm_config: VllmConfig) -> str: return self.compiler.compute_hash(vllm_config) @contextmanager def compile_context(self, compile_range: Range) -> Generator[None, None, None]: """Provide compilation context for the duration of compilation to set any torch global properties we want to scope to a single Inductor compilation (e.g. partition rules, pass context).""" with pass_context(compile_range): if self.compilation_config.use_inductor_graph_partition: with inductor_partition_rule_context( self.compilation_config.splitting_ops ): yield else: yield def initialize_cache( self, cache_dir: str, disable_cache: bool = False, prefix: str = "" ) -> None: """ Initialize the cache directory for the compiler. The organization of the cache directory is as follows: cache_dir=/path/to/hash_str/rank_i_j/prefix/ inside cache_dir, there will be: - vllm_compile_cache.py - computation_graph.py - transformed_code.py for multiple prefixes, they can share the same base cache dir of /path/to/hash_str/rank_i_j/ , to store some common compilation artifacts. """ self.disable_cache = disable_cache self.cache_dir = cache_dir self.cache_file_path = os.path.join(cache_dir, "vllm_compile_cache.py") if not disable_cache and os.path.exists(self.cache_file_path): # load the cache from the file with open(self.cache_file_path) as f: # we use ast.literal_eval to parse the data # because it is a safe way to parse Python literals. # do not use eval(), it is unsafe. cache = ast.literal_eval(f.read()) def check_type(value: Any, ty: type) -> None: if not isinstance(value, ty): raise TypeError(f"Expected {ty} but got {type(value)} for {value}") def parse_key(key: Any) -> tuple[Range, int, str]: range_tuple, graph_index, compiler_name = key check_type(graph_index, int) check_type(compiler_name, str) if isinstance(range_tuple, tuple): start, end = range_tuple check_type(start, int) check_type(end, int) range_tuple = Range(start=start, end=end) check_type(range_tuple, Range) return range_tuple, graph_index, compiler_name self.cache = {parse_key(key): value for key, value in cache.items()} self.compiler.initialize_cache( cache_dir=cache_dir, disable_cache=disable_cache, prefix=prefix ) def save_to_file(self) -> None: if self.disable_cache or not self.is_cache_updated: return printer = pprint.PrettyPrinter(indent=4) data = printer.pformat(self.cache) with open(self.cache_file_path, "w") as f: f.write(data) def load( self, graph: fx.GraphModule, example_inputs: list[Any], graph_index: int, compile_range: Range, ) -> Callable[..., Any] | None: if (compile_range, graph_index, self.compiler.name) not in self.cache: return None handle = self.cache[(compile_range, graph_index, self.compiler.name)] compiled_graph = self.compiler.load( handle, graph, example_inputs, graph_index, compile_range ) logger.debug( "Directly load the %s-th graph for compile range %sfrom %s via handle %s", graph_index, str(compile_range), self.compiler.name, handle, ) return compiled_graph @instrument(span_name="Compile graph") def compile( self, graph: fx.GraphModule, example_inputs: list[Any], additional_inductor_config: dict[str, Any], compilation_config: CompilationConfig, compile_range: Range, graph_index: int = 0, num_graphs: int = 1, ) -> Any: if graph_index == 0: # before compiling the first graph, record the start time global compilation_start_time compilation_start_time = time.perf_counter() compilation_counter.num_backend_compilations += 1 compiled_graph = None # try to load from the cache compiled_graph = self.load(graph, example_inputs, graph_index, compile_range) if compiled_graph is not None: if graph_index == num_graphs - 1: # after loading the last graph for this shape, record the time. # there can be multiple graphs due to piecewise compilation. elapsed = time.perf_counter() - compilation_start_time compilation_config.compilation_time += elapsed logger.info_once( "Directly load the compiled graph(s) for compile range %s " "from the cache, took %.3f s", str(compile_range), elapsed, scope="local", ) return compiled_graph # no compiler cached the graph, or the cache is disabled, # we need to compile it if isinstance(self.compiler, InductorAdaptor): # Let compile_fx generate a key for us maybe_key = None else: maybe_key = "artifact_compile_range_" maybe_key += f"{compile_range.start}_{compile_range.end}" maybe_key += f"_subgraph_{graph_index}" with self.compile_context(compile_range): # There is a compilation time optimization here. # # If the (input metadata, graph, compiler config) are the same, then # we want to avoid compiling the same artifact again. If we didn't # do this optimization, the backend compilation (InductorAdaptor or # InductorStandaloneAdaptor) # is able to cache hit and produce an artifact faster if it was # already created, but it is still a duplicate artifact that # requires unnecessary things e.g. disk IO. # # The optimization is: If the backend compilation cache hits, # then do an early return from the backend compilation and look up # which of the previous in-memory artifacts we created to reuse. # # We implemented this by monkey-patching torch (torch does not # easily expose the cache_key function), but in the future torch # should expose the cache_key function that we can just call # directly before invoking backend compilation. cache_key = None orig = torch._functorch._aot_autograd.autograd_cache.autograd_cache_key def autograd_cache_key(*args, **kwargs): result = orig(*args, **kwargs) if result is None: return None nonlocal cache_key cache_key = result[0] if cache_key in self.loaded_artifacts: raise StopCompiling() return result from unittest.mock import patch with ( # Graphs that are isometric (different node names but same # structure) should be treated as the same. torch._functorch.config.patch(autograd_cache_normalize_inputs=True), patch( "torch._functorch._aot_autograd.autograd_cache.autograd_cache_key", autograd_cache_key, ), ): try: compiled_graph, handle = self.compiler.compile( graph, example_inputs, additional_inductor_config, compile_range, maybe_key, ) except StopCompiling: assert cache_key is not None return self.loaded_artifacts[cache_key] if cache_key is not None and compiled_graph is not None: self.loaded_artifacts[cache_key] = compiled_graph assert compiled_graph is not None, "Failed to compile the graph" # store the artifact in the cache if is_compile_cache_enabled(additional_inductor_config) and handle is not None: self.cache[(compile_range, graph_index, self.compiler.name)] = handle compilation_counter.num_cache_entries_updated += 1 self.is_cache_updated = True if graph_index == 0: # adds some info logging for the first graph logger.info_once( "Cache the graph of compile range %s for later use", str(compile_range), ) logger.debug( "Store the %s-th graph for compile range%s from %s via handle %s", graph_index, str(compile_range), self.compiler.name, handle, ) # after compiling the last graph, record the end time if graph_index == num_graphs - 1: elapsed = time.perf_counter() - compilation_start_time compilation_config.compilation_time += elapsed logger.info_once( "Compiling a graph for compile range %s takes %.2f s", str(compile_range), elapsed, scope="local", ) return compiled_graph class StopCompiling(BaseException): pass @dataclasses.dataclass class SplitItem: submod_name: str graph_id: int is_splitting_graph: bool graph: fx.GraphModule def split_graph( graph: fx.GraphModule, splitting_ops: list[str] ) -> tuple[fx.GraphModule, list[SplitItem]]: # split graph by ops subgraph_id = 0 node_to_subgraph_id: dict[fx.Node, int] = {} split_op_graphs: list[int] = [] for node in graph.graph.nodes: if node.op in ("output", "placeholder"): continue # Check if this is a getitem operation on a node from an earlier subgraph. # If so, assign it to the same subgraph as its input to avoid passing entire # tuple as input to submodules, which is against standalone_compile and # AoTAutograd input requirement. if node.op == "call_function" and node.target == operator.getitem: # Assign this getitem to the same subgraph as its input input_node = node.args[0] if input_node.op != "placeholder": assert input_node in node_to_subgraph_id node_to_subgraph_id[node] = node_to_subgraph_id[input_node] continue if should_split(node, splitting_ops): subgraph_id += 1 node_to_subgraph_id[node] = subgraph_id split_op_graphs.append(subgraph_id) # keep consecutive splitting ops together # (we know node.next exists because node isn't the last (output) node) if should_split(node.next, splitting_ops): # this will get incremented by the next node subgraph_id -= 1 else: subgraph_id += 1 else: node_to_subgraph_id[node] = subgraph_id # `keep_original_order` is important! # otherwise pytorch might reorder the nodes and # the semantics of the graph will change when we # have mutations in the graph split_gm = torch.fx.passes.split_module.split_module( graph, None, lambda node: node_to_subgraph_id[node], keep_original_order=True ) outputs = [] names = [name for (name, module) in split_gm.named_modules()] for name in names: if "." in name or name == "": # recursive child module or the root module continue module = getattr(split_gm, name) graph_id = int(name.replace("submod_", "")) outputs.append(SplitItem(name, graph_id, (graph_id in split_op_graphs), module)) # sort by integer graph_id, rather than string name outputs.sort(key=lambda x: x.graph_id) return split_gm, outputs compilation_start_time = 0.0 def wrap_with_cudagraph_if_needed( piecewise_backend: Any, vllm_config: VllmConfig, compilation_config: CompilationConfig, is_first_graph: bool, is_last_graph: bool, ) -> Any: """ Wrap a piecewise backend with CUDA graph wrapper if needed. This function is shared between VllmBackend and construct_serializable_fn_from_inductor_cache. Args: piecewise_backend: The backend to wrap vllm_config: The vLLM configuration compilation_config: The compilation configuration is_first_graph: Whether this is the first graph in the sequence is_last_graph: Whether this is the last graph in the sequence Returns: The wrapped backend if CUDA graphs are enabled, otherwise the original backend """ if ( not compilation_config.cudagraph_mode.has_piecewise_cudagraphs() or compilation_config.use_inductor_graph_partition ): return piecewise_backend # We're using Dynamo-based piecewise splitting, so we wrap # the whole subgraph with a static graph wrapper. from .cuda_graph import CUDAGraphOptions # resolve the static graph wrapper class (e.g. CUDAGraphWrapper # class) as platform dependent. static_graph_wrapper_class = resolve_obj_by_qualname( current_platform.get_static_graph_wrapper_cls() ) # Always assign PIECEWISE runtime mode to the # CUDAGraphWrapper for piecewise_backend, to distinguish # it from the FULL cudagraph runtime mode, no matter it # is wrapped on a full or piecewise fx graph. return static_graph_wrapper_class( runnable=piecewise_backend, vllm_config=vllm_config, runtime_mode=CUDAGraphMode.PIECEWISE, cudagraph_options=CUDAGraphOptions( debug_log_enable=is_first_graph, gc_disable=not is_first_graph, weak_ref_output=is_last_graph, ), ) class PiecewiseCompileInterpreter(torch.fx.Interpreter): # type: ignore[misc] """Code adapted from `torch.fx.passes.shape_prop.ShapeProp`. It runs the given graph with fake inputs, and compile some submodules specified by `compile_submod_names` with the given compilation configs. NOTE: the order in `compile_submod_names` matters, because it will be used to determine the order of the compiled piecewise graphs. The first graph will handle logging, and the last graph has some special cudagraph output handling. Note: This class shares similar logic with reconstruct_serializable_fn_from_mega_artifact in caching.py. Both create PiecewiseBackend instances and wrap them with cudagraph. The key difference is: - reconstruct_serializable_fn_from_mega_artifact: PiecewiseBackend receives pre-compiled runnables (compiled_runnables is set, graph is None) - this class: PiecewiseBackend receives the FX graph to compile (graph is set, compiled_runnables is None) If modifying the backend creation/wrapping logic, consider updating both. """ def __init__( self, module: torch.fx.GraphModule, compile_submod_names: list[str], vllm_config: VllmConfig, vllm_backend: "VllmBackend", ) -> None: super().__init__(module) from torch._guards import detect_fake_mode self.fake_mode = detect_fake_mode() self.compile_submod_names = compile_submod_names self.compilation_config = vllm_config.compilation_config self.vllm_config = vllm_config self.vllm_backend = vllm_backend # When True, it annoyingly dumps the torch.fx.Graph on errors. self.extra_traceback = False @instrument(span_name="Inductor compilation") def run(self, *args: Any) -> Any: # maybe instead just assert inputs are fake? fake_args = [ self.fake_mode.from_tensor(t) if isinstance(t, torch.Tensor) else t for t in args ] with self.fake_mode, enable_python_dispatcher(): return super().run(*fake_args) def call_module( self, target: torch.fx.node.Target, args: tuple[torch.fx.node.Argument, ...], kwargs: dict[str, Any], ) -> Any: assert isinstance(target, str) gm = getattr(self.module, target) outputs = gm.graph.output_node().args[0] output = fx.map_arg(outputs, lambda node: node.meta["example_value"]) if target in self.compile_submod_names: index = self.compile_submod_names.index(target) submod = self.fetch_attr(target) sym_shape_indices = [ i for i, x in enumerate(args) if isinstance(x, torch.SymInt) ] # Lazy import here to avoid circular import from torch._inductor.compile_fx import graph_returns_tuple from .piecewise_backend import PiecewiseBackend piecewise_backend = PiecewiseBackend( submod, self.vllm_config, index, len(self.compile_submod_names), sym_shape_indices, self.vllm_backend, graph_returns_tuple(submod), submod_name=target, ) self.module.__dict__[target] = wrap_with_cudagraph_if_needed( piecewise_backend, self.vllm_config, self.compilation_config, piecewise_backend.is_first_graph, piecewise_backend.is_last_graph, ) compilation_counter.num_piecewise_capturable_graphs_seen += 1 return output # the tag for the part of model being compiled, # e.g. backbone/eagle_head model_tag: str = "backbone" model_is_encoder: bool = False _on_compilation_complete_callback: contextvars.ContextVar[Callable[[], None] | None] = ( contextvars.ContextVar("on_compilation_complete_callback", default=None) ) @contextmanager def set_on_compilation_complete( callback: Callable[[], None], ) -> Generator[None, None, None]: token = _on_compilation_complete_callback.set(callback) try: yield finally: _on_compilation_complete_callback.reset(token) @contextmanager def set_model_tag(tag: str, is_encoder: bool = False) -> Generator[None, None, None]: """Context manager to set the model tag.""" global model_tag global model_is_encoder assert tag != model_tag, ( f"Model tag {tag} is the same as the current tag {model_tag}." ) old_tag = model_tag old_is_encoder = model_is_encoder model_tag = tag model_is_encoder = is_encoder try: yield finally: model_tag = old_tag model_is_encoder = old_is_encoder class VllmBackend: """The compilation backend for `torch.compile` with vLLM. It is used for compilation mode of `CompilationMode.VLLM_COMPILE`, where we customize the compilation. The major work of this backend is to split the graph into piecewise graphs, and pass them to the piecewise backend. This backend also adds the PostGradPassManager to Inductor config, which handles the post-grad passes. """ vllm_config: VllmConfig compilation_config: CompilationConfig _called: bool = False # the graph we compiled graph: fx.GraphModule # the stiching graph module for all the piecewise graphs split_gm: fx.GraphModule piecewise_graphs: list[SplitItem] returned_callable: Callable[..., Any] # Inductor passes to run on the graph pre-defunctionalization post_grad_passes: Sequence[Callable[..., Any]] compiler_manager: CompilerManager # Copy of CompilationConfig.inductor_compile_config + # an entry for PostGradPassManager inductor_config: dict[str, Any] def __init__( self, vllm_config: VllmConfig, prefix: str = "", is_encoder: bool = False, ) -> None: # if the model is initialized with a non-empty prefix, # then usually it's enough to use that prefix, # e.g. language_model, vision_model, etc. # when multiple parts are initialized as independent # models, we need to use the model_tag to distinguish # them, e.g. backbone (default), eagle_head, etc. self.prefix = prefix or model_tag # Mark compilation for encoder. self.is_encoder = is_encoder or model_is_encoder # Passes to run on the graph post-grad. # self.pass_manager = resolve_obj_by_qualname( # current_platform.get_pass_manager_cls() # )() self.pass_key = current_platform.pass_key self.vllm_config = vllm_config self.compilation_config = vllm_config.compilation_config self.compiler_manager: CompilerManager = CompilerManager( self.compilation_config ) # Deepcopy the inductor config to detach the post-grad custom pass # from CompilationConfig. # We want to avoid PostGradPassManager in CompilationConfig because # in future we need PostGradPassManager.uuid() to be executed # only at compile time. self.inductor_config = deepcopy(self.compilation_config.inductor_compile_config) # `torch.compile` is JIT compiled, so we don't need to # do anything here def collect_standalone_compile_artifacts( self, ) -> tuple[Any, dict[str, list[int]] | None, dict[str, bool] | None]: """Collect inductor cache artifacts from all piecewise backends. Returns: tuple: (standalone_compile_artifacts, sym_shape_indices_map, returns_tuple_map) - standalone_compile_artifacts: StandaloneCompiledArtifacts with compiled artifacts - sym_shape_indices_map: dict mapping submod_name to sym_shape_indices - returns_tuple_map: dict mapping submod_name to returns_tuple """ if not envs.VLLM_USE_MEGA_AOT_ARTIFACT: return None, None, None from .caching import StandaloneCompiledArtifacts from .piecewise_backend import PiecewiseBackend standalone_compile_artifacts = StandaloneCompiledArtifacts() sym_shape_indices_map = {} returns_tuple_map = {} for name, _ in self.split_gm.named_children(): # get the actual attribute (shadowed by PiecewiseBackend in __dict__) child = getattr(self.split_gm, name) # unwrap the static graph wrapper class if applicable piecewise_backend = child.runnable if hasattr(child, "runnable") else child if not isinstance(piecewise_backend, PiecewiseBackend): continue submod_name = name sym_shape_indices_map[submod_name] = piecewise_backend.sym_shape_indices returns_tuple_map[submod_name] = piecewise_backend.returns_tuple for shape_str, bytes_data in piecewise_backend.to_bytes().items(): standalone_compile_artifacts.insert(submod_name, shape_str, bytes_data) logger.debug( "collected artifact for %s shape %s (%d bytes)", submod_name, shape_str, len(bytes_data), ) logger.info( "collected artifacts: %d entries, %d artifacts, %d bytes total", standalone_compile_artifacts.num_entries(), standalone_compile_artifacts.num_artifacts(), standalone_compile_artifacts.size_bytes(), ) logger.debug( "standalone compile artifact keys: %s", list(standalone_compile_artifacts.submodule_bytes.keys()), ) return standalone_compile_artifacts, sym_shape_indices_map, returns_tuple_map def configure_post_pass(self) -> None: # self.pass_manager.configure(self.vllm_config) # Post-grad custom passes are run using the post_grad_custom_post_pass # hook. If a pass for that hook exists, add it to the pass manager. if self.pass_key in self.inductor_config: if isinstance(self.inductor_config[self.pass_key], PostGradPassManager): raise ValueError( "PostGradPassManager can not be kept in CompilationConfig." ) else: # Config should automatically wrap all inductor passes assert isinstance( self.compilation_config.inductor_compile_config[self.pass_key], InductorPass, ) self.pass_manager.add( self.compilation_config.inductor_compile_config[self.pass_key] ) self.inductor_config[self.pass_key] = self.pass_manager def _log_compilation_config(self): """Log vLLM compilation config for TORCH_TRACE/tlparse.""" cc = self.compilation_config pass_cfg = cc.pass_config # Helper to convert lists to comma-separated strings for tlparse display def list_to_str(lst: list | None) -> str: if lst is None: return "" return ", ".join(str(x) for x in lst) # Get enabled passes by introspecting dataclass fields enabled_passes = [ f.name for f in dataclasses.fields(pass_cfg) if isinstance(getattr(pass_cfg, f.name), bool) and getattr(pass_cfg, f.name) ] trace_structured( "artifact", metadata_fn=lambda: { "name": "vllm_compilation_config", "encoding": "json", }, payload_fn=lambda: json.dumps( { "model": self.vllm_config.model_config.model, "prefix": self.prefix, "mode": str(cc.mode), "backend": cc.backend, "custom_ops": list_to_str(cc.custom_ops), "splitting_ops": list_to_str(cc.splitting_ops), "cudagraph_mode": str(cc.cudagraph_mode), "compile_sizes": list_to_str(cc.compile_sizes), "compile_ranges_split_points": list_to_str( cc.compile_ranges_split_points ), "use_inductor_graph_partition": cc.use_inductor_graph_partition, "inductor_passes": list_to_str(list(cc.inductor_passes.keys())), "enabled_passes": list_to_str(enabled_passes), "dynamic_shapes_type": str(cc.dynamic_shapes_config.type), "dynamic_shapes_evaluate_guards": cc.dynamic_shapes_config.evaluate_guards, # noqa: E501 } ), ) def __call__(self, graph: fx.GraphModule, example_inputs: Sequence[Any]) -> Any: from .caching import ( VllmSerializableFunction, ) vllm_config = self.vllm_config self._log_compilation_config() # Minimal hashing here with existing utilities, reused below. env_factors = envs.compile_factors() env_hash = hash_factors(env_factors) # Compute config/compiler/code hashes once and reuse config_hash = vllm_config.compute_hash() compiler_hash = self.compiler_manager.compute_hash(vllm_config) forward_code_files = list(sorted(self.compilation_config.traced_files)) logger.debug( "Traced files (to be considered for compilation cache):\n%s", lazy(lambda: "\n".join(forward_code_files)), ) hash_content = [] for filepath in forward_code_files: hash_content.append(filepath) if filepath == "": # This means the function was dynamically generated, with # e.g. exec(). We can't actually check these. continue try: with open(filepath) as f: hash_content.append(f.read()) except (OSError, UnicodeDecodeError): logger.warning("Failed to read file %s", filepath) continue code_hash = hashlib.sha256("\n".join(hash_content).encode()).hexdigest() # Clear after consumption self.compilation_config.traced_files.clear() if not self.compilation_config.cache_dir: # no provided cache dir, generate one based on the known factors # that affects the compilation. if none of the factors change, # the cache dir will be the same so that we can reuse the compiled # graph. factors = [env_hash, config_hash, code_hash, compiler_hash] # Use SHA-256 for cache key hashing to be consistent across # compute_hash functions. Truncate for a short cache dir name. hash_key = hashlib.sha256(str(factors).encode()).hexdigest()[:10] cache_dir = os.path.join( envs.VLLM_CACHE_ROOT, "torch_compile_cache", hash_key ) self.compilation_config.cache_dir = cache_dir cache_dir = self.compilation_config.cache_dir os.makedirs(cache_dir, exist_ok=True) self.compilation_config.cache_dir = cache_dir rank = vllm_config.parallel_config.rank dp_rank = vllm_config.parallel_config.data_parallel_index local_cache_dir = os.path.join(cache_dir, f"rank_{rank}_{dp_rank}", self.prefix) os.makedirs(local_cache_dir, exist_ok=True) self.compilation_config.local_cache_dir = local_cache_dir # Honors opt-outs such as CompilationMode.NONE or VLLM_DISABLE_COMPILE_CACHE. disable_cache = not is_compile_cache_enabled(self.inductor_config) if disable_cache: logger.info_once("vLLM's torch.compile cache is disabled.", scope="local") else: logger.info_once( "Using cache directory: %s for vLLM's torch.compile", local_cache_dir, scope="local", ) self.compiler_manager.initialize_cache( local_cache_dir, disable_cache, self.prefix ) # Reuses existing cache key logger.debug( "torch.compile cache factors: env=%s cfg=%s comp=%s code=%s dir=%s", env_hash, config_hash, compiler_hash, code_hash, local_cache_dir, ) # Persist and log only hash-relevant factors together. try: logger.debug( "Compile env factors (raw):\n%s\nVllm config hash: %s", lazy(partial(pprint.pformat, env_factors, width=120)), config_hash, ) meta_path = os.path.join(local_cache_dir, "cache_key_factors.json") if not os.path.exists(meta_path): with open(meta_path, "w") as f: json.dump( { "env": env_factors, # raw factors used for env_hash "config_hash": config_hash, "code_hash": code_hash, "compiler_hash": compiler_hash, }, f, indent=2, sort_keys=True, ) except Exception: # Best-effort only; metadata write failures are non-fatal. logger.warning( ( "Could not write compile cache metadata at %s; continuing without " "metadata. Compiled cache remains valid; diagnostics may be " "limited." ), local_cache_dir, exc_info=True, ) # when dynamo calls the backend, it means the bytecode # transform and analysis are done compilation_counter.num_graphs_seen += 1 from .monitor import torch_compile_start_time dynamo_time = time.perf_counter() - torch_compile_start_time logger.info_once( "Dynamo bytecode transform time: %.2f s", dynamo_time, scope="local" ) self.compilation_config.compilation_time += dynamo_time # Record Dynamo time in tracing if available start_time = int(torch_compile_start_time * 1e9) attributes = {"dynamo.time_seconds": dynamo_time} instrument_manual("Dynamo bytecode transform", start_time, None, attributes) # we control the compilation process, each instance can only be # called once assert not self._called, "VllmBackend can only be called once" self.graph = graph self.configure_post_pass() if self.compilation_config.use_inductor_graph_partition: # Let Inductor decide partitioning; avoid FX-level pre-splitting. fx_split_ops: list[str] = [] else: fx_split_ops = self.compilation_config.splitting_ops or [] self.split_gm, self.piecewise_graphs = split_graph(graph, fx_split_ops) # keep a split_gm copy from BEFORE the interpreter replaces # submodules with PiecewiseBackend -- used for serialization original_split_gm = None if envs.VLLM_USE_MEGA_AOT_ARTIFACT: original_split_gm = deepcopy(self.split_gm) from torch._dynamo.utils import lazy_format_graph_code # depyf will hook lazy_format_graph_code and dump the graph # for debugging, no need to print the graph here lazy_format_graph_code("before split", self.graph) lazy_format_graph_code("after split", self.split_gm) # Log the piecewise split graph for TORCH_TRACE/tlparse trace_structured( "graph_dump", metadata_fn=lambda: {"name": "vllm_piecewise_split_graph"}, payload_fn=lambda: self.split_gm.print_readable(print_output=False), ) compilation_counter.num_piecewise_graphs_seen += len(self.piecewise_graphs) submod_names_to_compile = [ item.submod_name for item in self.piecewise_graphs if not item.is_splitting_graph ] # Extract fake values from the graph to use them when needed. all_fake_values = [] for i in graph.graph.find_nodes(op="placeholder"): all_fake_values.append(i.meta["example_value"]) fake_args = [ all_fake_values[i] if isinstance(t, torch.Tensor) else t for i, t in enumerate(example_inputs) ] # propagate the split graph to the piecewise backend, # compile submodules with symbolic shapes PiecewiseCompileInterpreter( self.split_gm, submod_names_to_compile, self.vllm_config, self ).run(*fake_args) from torch._guards import detect_fake_mode fake_mode = detect_fake_mode() if ( self.compilation_config.dynamic_shapes_config.evaluate_guards and self.compilation_config.dynamic_shapes_config.type == DynamicShapesType.BACKED ): from torch.utils._sympy.value_ranges import ValueRanges # Drop counter-0/1 specializations guards; for backed dynamic shapes, # torch.compile will specialize for 0/1 inputs or otherwise guards that # shape is >= 2. This is because it's really hard not to hit a check # against 0/1. When we evaluate shape guards, we exclude checking those # guards (We would fail always otherwise). # We avoid that by updating the ranges of backed sizes when the min is # 2 for any, we assume it's 0. for s, r in fake_mode.shape_env.var_to_range.items(): if r.lower == 2: fake_mode.shape_env.var_to_range[s] = ValueRanges(0, r.upper) graph_path = os.path.join(local_cache_dir, "computation_graph.py") if not os.path.exists(graph_path): # code adapted from # https://github.com/thuml/depyf/blob/dab831108a752d1facc00acdd6d4243891845c37/depyf/explain/patched_lazy_format_graph_code.py#L30 # use `print_readable` because it can include submodules src = ( "from __future__ import annotations\nimport torch\n" + self.split_gm.print_readable(print_output=False) ) src = src.replace("", "GraphModule") with open(graph_path, "w") as f: f.write(src) logger.debug_once( "Computation graph saved to %s", graph_path, scope="local" ) self._called = True graph_to_serialize = ( original_split_gm if envs.VLLM_USE_MEGA_AOT_ARTIFACT else self.graph ) if ( self.compilation_config.cudagraph_mode == CUDAGraphMode.NONE or not self.compilation_config.cudagraph_copy_inputs ): return VllmSerializableFunction( graph_to_serialize, example_inputs, self.prefix, self.split_gm, is_encoder=self.is_encoder, vllm_backend=self, ) # index of tensors that have symbolic shapes (batch size) # for weights and static buffers, they will have concrete shapes. # symbolic shape only happens for input tensors. from torch.fx.experimental.symbolic_shapes import is_symbolic sym_tensor_indices = [ i for i, x in enumerate(fake_args) if isinstance(x, torch._subclasses.fake_tensor.FakeTensor) and any(is_symbolic(d) for d in x.size()) ] # compiler managed cudagraph input buffers # we assume the first run with symbolic shapes # has the maximum size among all the tensors copy_and_call = make_copy_and_call( sym_tensor_indices, [example_inputs[x].clone() for x in sym_tensor_indices], self.split_gm, ) return VllmSerializableFunction( graph_to_serialize, example_inputs, self.prefix, copy_and_call, is_encoder=self.is_encoder, vllm_backend=self, sym_tensor_indices=sym_tensor_indices, )