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cd68559d0451185f8521912c23e77b83d76b87cf
pytorch/torch/_inductor/utils.py
anwang cd68559d04 [Inductor] Support native Inductor as backend for MTIA (#158526) 
This diff/PR includes the changes to support native Inductor integration for MTIA. The goal is to support `torch.compile(backend="inductor")` for MTIA. Inductor should generate code(triton kernel + python wrapper code) similar to CUDA. And the triton kernels can be launched eagerly.

The changes include:
- Add MTIA device interfaces used by Dynamo and Inductor, including APIs on device, stream, event, etc.
- Add required torch.mtia APIs, like is_bf16_supported, memory_allocated, set_stream_by_id, etc.
- MTIA specific codegen logic, for example, loading MTIA dynamic_library.
- Other necessary changes to integrate with Inductor codegn, following other devices like CUDA, XPU.
- Integrate with the [empty_strided_mtia](https://www.internalfb.com/code/fbsource/[0d017d3a4a1bdff7253f9c66a9f38e77bd62166b]/fbcode/caffe2/aten/src/ATen/native/mtia/EmptyTensor.cpp?lines=49%2C63%2C71%2C74%2C78) API that we’ve added for the new MTIA ATen backend.
- A change in Inductor runtime to avoid re-initialize MTIADriver.
- BUCK changes to include ATen-mtia in Inductor, and to use -USE_MTIA preprocessor flag.
- Update `test_mnist_e2e.py` to cover native Inductor as backend, using the `--use_native_inductor` flag.
- Add a personal script(`scripts/anwang/run_native_inductor_script.py`) for testing purpose.

Note:
- This approach(option 3) aims to provide a pytorch native approach of Inductor integration for MTIA, minimizing the onboarding overhead. The downside of this approach is that it doesn't leverage MTIA specific graph optimization, and is limited to eagerly launch overhead.
- MTIA will support another approach(option 2) to provide best performance, based on WrapperFxCodegen. We should be able to reuse the fundamental changes of this diff for option 2, like the device interfaces, steam/event APIs, etc, especially as WrapperFxCodegen inherits PythonWrapperCodegen.

Internal:
References:
- [post for context](https://fb.workplace.com/groups/mtiasw/permalink/1718377262384606/)
- [Inductor integration discussion(option 1/2/3)](https://docs.google.com/document/d/1p6363OXtVIRv1hPoaKlRSK3j-iir3QIbDd5bjyqCNig/edit?tab=t.0#heading=h.7s4ns6wcnhmb)
- [Project design doc(option 3)](https://docs.google.com/document/d/1jXUmhgoV9WvkMf-bcY3Od_kK9K_RDOdgHdt1LoQ5Tc4/edit?tab=t.0#heading=h.y43gwdqlv46w)
- [early prototying diff](https://www.internalfb.com/diff/D75110196)
- [MPS integration PR](https://github.com/pytorch/pytorch/pull/153959)
- [empty_strided_xpu PR](https://github.com/pytorch/pytorch/pull/126678)

Differential Revision: [D78458745](https://our.internmc.facebook.com/intern/diff/D78458745/)

Pull Request resolved: https://github.com/pytorch/pytorch/pull/158526
Approved by: https://github.com/blaine-rister, https://github.com/jansel, https://github.com/eellison
2025-07-26 08:16:34 +00:00

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from __future__ import annotations
import collections
import contextlib
import dataclasses
import enum
import functools
import importlib
import inspect
import io
import itertools
import logging
import math
import operator
import os
import platform
import re
import shutil
import statistics
import sys
import tempfile
import textwrap
import time
import unittest
from collections.abc import (
Collection,
Generator,
Iterator,
Mapping,
MutableMapping,
MutableSet,
)
from datetime import datetime
from io import StringIO
from typing import (
Any,
Callable,
cast,
Generic,
Literal,
NamedTuple,
Optional,
Protocol,
TYPE_CHECKING,
TypeVar,
Union,
)
from typing_extensions import (
Concatenate,
dataclass_transform,
ParamSpec,
Self,
TypeAlias,
TypeGuard,
)
from unittest import mock
import sympy
import torch
from torch._inductor.analysis.device_info import datasheet_tops
from torch._inductor.runtime.hints import DeviceProperties
from torch.utils._dtype_abbrs import dtype_abbrs
from torch.utils._ordered_set import OrderedSet
from torch.utils._pytree import tree_flatten, tree_map_only
OPTIMUS_EXCLUDE_POST_GRAD = [
"activation_quantization_aten_pass",
"inductor_autotune_lookup_table",
]
from torch.fx.experimental.symbolic_shapes import (
free_symbols,
free_unbacked_symbols,
IterateExprs,
ShapeEnv,
)
if TYPE_CHECKING:
from collections.abc import Iterable, Sequence, ValuesView
from torch import SymBool, SymFloat, SymInt
from torch._prims_common import ELEMENTWISE_TYPE_PROMOTION_KIND
from torch.fx import GraphModule
from torch.fx.node import Node
from .codegen.common import WorkspaceArg
from .codegen.wrapper import PythonWrapperCodegen
from .graph import GraphLowering
from .ir import Buffer, ExternKernel, IRNode, Layout, Operation, ReinterpretView
from .output_code import CompiledFxGraph
from .scheduler import BaseSchedulerNode, SchedulerBuffer
GPU_TYPES = ["cuda", "mps", "xpu", "mtia"]
T = TypeVar("T")
# defines here before import torch._dynamo is for avoiding circular import
# when get_gpu_type is imported from dynamo
@functools.cache
def get_gpu_type() -> str:
avail_gpus = [x for x in GPU_TYPES if getattr(torch, x).is_available()]
assert len(avail_gpus) <= 1
gpu_type = "cuda" if len(avail_gpus) == 0 else avail_gpus.pop()
return gpu_type
from torch._dynamo.device_interface import get_interface_for_device
from torch._dynamo.utils import detect_fake_mode
from torch.autograd import DeviceType
from torch.autograd.profiler_util import EventList
from torch.fx.passes.graph_transform_observer import GraphTransformObserver
from torch.fx.passes.shape_prop import ShapeProp
from torch.utils._sympy.functions import (
CeilDiv,
CleanDiv,
FloorDiv,
Identity,
ModularIndexing,
)
from torch.utils._sympy.symbol import make_symbol, SymT
from torch.utils._sympy.value_ranges import bound_sympy, ValueRanges
from . import config
from .runtime.runtime_utils import ceildiv as runtime_ceildiv
_IS_WINDOWS = sys.platform == "win32"
log = logging.getLogger(__name__)
_T = TypeVar("_T")
VarRanges = dict[sympy.Expr, sympy.Expr]
InputType = Optional[Union[torch.Tensor, int, torch.SymInt]]
GPU_KERNEL_BIN_EXTS = {"cuda": ".cubin", "xpu": ".spv"}
GPU_ALIGN_BYTES = 16
ALIGNMENT = 16
TMA_ALIGNMENT = 16
TMA_DESCRIPTOR_SIZE = 128
ALIGN_BYTES = 64
assert (ALIGN_BYTES & (ALIGN_BYTES - 1)) == 0 and ALIGN_BYTES >= 8, "must be power of 2"
def _align(nbytes: int) -> int:
"""Round up to the nearest multiple of ALIGN_BYTES"""
return (nbytes + ALIGN_BYTES - 1) & -ALIGN_BYTES
def _is_aligned(v: sympy.Expr) -> bool:
"""v can be statically proven to be a multiple of ALIGN_BYTES"""
if isinstance(v, (sympy.Add, sympy.Max)):
return all(map(_is_aligned, v.args))
return isinstance(v, align) or sympy.gcd(v, ALIGN_BYTES) == ALIGN_BYTES
class align(sympy.Function):
"""Symbolically round up to the nearest multiple of ALIGN_BYTES"""
nargs = (1,)
is_integer = True
@classmethod
def eval(cls, value: sympy.Expr) -> Optional[sympy.Expr]:
if isinstance(value, (int, sympy.Integer)):
return _align(int(value))
if _is_aligned(value):
return value
@dataclasses.dataclass(frozen=True)
class GraphPartitionMap:
"""
Mapping from the partition info (e.g., input/output) to the graph info
"""
# a unique id of graph partition
id: int
# map partition input/output indices to graph input/output indices. None indicates
# a partition input/output is not a graph input/output.
input_index_mapping: list[Optional[int]]
output_index_mapping: list[Optional[int]]
# name of constants read/written by the graph partition
constant_names: list[str]
def fp8_bench(fn: Callable[[], Any], warmup: int = 25, rep: int = 100) -> float:
"""
Returns benchmark results by examining torch profiler events.
This could be more accurate as it doesn't count CPU side overhead.
However, this also requires manually excluding irrelevant event, e.g.
vectorized_elementwise_kernel which is used to fill L2 cache,
various CUDA events, etc, so could also be fragile.
"""
fn()
torch.cuda.synchronize()
cache = torch.empty(int(256e6 // 4), dtype=torch.float16, device="cuda")
# Estimate the runtime of the function
start_event = torch.cuda.Event(enable_timing=True)
end_event = torch.cuda.Event(enable_timing=True)
start_event.record()
for _ in range(5):
cache.zero_()
fn()
end_event.record()
torch.cuda.synchronize()
estimate_ms = start_event.elapsed_time(end_event) / 5
# compute number of warmup and repeat
n_warmup = max(1, int(warmup / estimate_ms))
n_repeat = max(1, int(rep / estimate_ms))
# Warm-up
for _ in range(n_warmup):
fn()
start_event = [torch.cuda.Event(enable_timing=True) for _ in range(n_repeat)]
end_event = [torch.cuda.Event(enable_timing=True) for _ in range(n_repeat)]
with torch.profiler.profile(
activities=[
torch.profiler.ProfilerActivity.CUDA,
]
) as p:
torch.cuda.synchronize()
for i in range(n_repeat):
cache.zero_()
start_event[i].record()
with torch.cuda.nvtx.range("RunCudaModule"):
fn()
end_event[i].record()
torch.cuda.synchronize()
times = torch.tensor(
[s.elapsed_time(e) for s, e in zip(start_event, end_event)]
)
res = torch.mean(times).item()
log.debug("raw events")
log.debug(p.key_averages().table(sort_by="self_device_time_total", row_limit=-1))
filtered_events = EventList(
[
event
for event in p.events()
if (
event.device_type == DeviceType.CUDA
and re.match(r"fused_abs_max_\d", event.name) is not None
)
]
)
if filtered_events:
res -= (
statistics.mean(event.device_time_total for event in filtered_events)
/ 1000.0
)
log.debug("profiling results: %s ms", res)
return res
def do_bench_using_profiling(
fn: Callable[[], Any], warmup: int = 25, rep: int = 100
) -> float:
"""
Returns benchmark results by examining torch profiler events.
This could be more accurate as it doesn't count CPU side overhead.
However, this also requires manually excluding irrelevant event, e.g.
vectorized_elementwise_kernel which is used to fill L2 cache,
various CUDA events, etc, so could also be fragile.
"""
fn()
torch.cuda.synchronize()
cache = torch.empty(int(256e6 // 4), dtype=torch.int, device="cuda")
# Estimate the runtime of the function
start_event = torch.cuda.Event(enable_timing=True)
end_event = torch.cuda.Event(enable_timing=True)
start_event.record()
for _ in range(5):
cache.zero_()
fn()
end_event.record()
torch.cuda.synchronize()
estimate_ms = start_event.elapsed_time(end_event) / 5
# compute number of warmup and repeat
n_warmup = max(1, int(warmup / estimate_ms))
n_repeat = max(1, int(rep / estimate_ms))
# Warm-up
for _ in range(n_warmup):
fn()
torch.cuda.synchronize()
with torch.profiler.profile(
activities=[
torch.profiler.ProfilerActivity.CUDA,
]
) as p:
# Benchmark
for i in range(n_repeat):
# we clear the L2 cache before each run
cache.zero_()
# record time of `fn`
fn()
# Record clocks
torch.cuda.synchronize()
log.debug("raw events")
log.debug(p.key_averages().table(sort_by="self_device_time_total", row_limit=-1))
filtered_events = EventList(
[
event
for event in p.events()
if event.device_type == DeviceType.CUDA and event.name != "Context Sync"
]
)
if len(filtered_events) % n_repeat != 0:
raise RuntimeError(
"Failed to divide all profiling events into #repeat groups. "
"#CUDA events: %d, #repeats: %s",
len(filtered_events),
n_repeat,
)
num_event_per_group = len(filtered_events) / n_repeat
actual_events = EventList(
[
event
for i, event in enumerate(filtered_events)
if i % num_event_per_group != 0
]
)
actual_events._build_tree()
actual_events = actual_events.key_averages()
log.debug("profiling time breakdown")
log.debug(actual_events.table(row_limit=-1))
res = sum(event.device_time_total for event in actual_events) / 1000.0 / n_repeat
log.debug("profiling results: %s ms", res)
return res
@functools.cache
def has_torchvision_roi_align() -> bool:
try:
from torchvision.ops import roi_align # noqa: F401
torch._C._dispatch_has_kernel_for_dispatch_key("torchvision::nms", "Meta")
return roi_align is not None and hasattr(
getattr(torch.ops, "torchvision", None), "roi_align"
)
except ImportError:
return False
except RuntimeError as e:
assert "torchvision::nms does not exist" in str(e)
return False
def decode_device(device: Union[Optional[torch.device], str]) -> torch.device:
if device is None:
return torch.tensor(0.0).device # default device
if isinstance(device, str):
device = torch.device(device)
if device.type not in ("cpu", "meta") and device.index is None:
device_interface = get_interface_for_device(device.type)
return torch.device(device.type, index=device_interface.Worker.current_device())
return device
def sympy_product(it: Iterable[sympy.Expr]) -> sympy.Expr:
return functools.reduce(operator.mul, it, sympy.S.One)
def sympy_dot(seq1: Sequence[sympy.Expr], seq2: Sequence[sympy.Expr]) -> sympy.Expr:
assert len(seq1) == len(seq2)
return sympy.expand(sum(a * b for a, b in zip(seq1, seq2)))
def unique(it: Iterable[_T]) -> ValuesView[_T]:
return {id(x): x for x in it}.values()
def ceildiv(
number: Union[int, sympy.Expr], denom: Union[int, sympy.Expr]
) -> Union[int, sympy.Expr]:
if isinstance(number, sympy.Expr) or isinstance(denom, sympy.Expr):
return CeilDiv(sympy.sympify(number), sympy.sympify(denom))
# TODO: There is a bug in a call to this function, to repro:
# python benchmarks/dynamo/huggingface.py --inductor -d cuda --accuracy
# --amp --only YituTechConvBert --dynamic-shapes
assert isinstance(number, int) and isinstance(denom, int), (
f"{number}: {type(number)}, {denom}: {type(denom)}"
)
return runtime_ceildiv(number, denom)
def _type_of(key: Optional[torch.dtype]) -> str:
# Use the function here to get rid of dependencies on the Triton during the codegen.
# Refer to Triton implementation here:
# https://github.com/triton-lang/triton/blob/98b5945d2aef679e00ebca8e07c35c3658ec76de/python/triton/runtime/jit.py#L238
# `None` is nullptr. Implicitly convert to *i8.
if key is None:
return "*i8"
dtype_str = str(key).split(".")[-1]
tys = {
"bool": "i1",
"float8e4nv": "fp8e4nv",
"float8e5": "fp8e5",
"float8e4b15": "fp8e4b15",
"float8e4b15x4": "fp8e4b15x4",
"float8_e4m3fn": "fp8e4nv",
"float8_e5m2": "fp8e5",
# TODO: remove when support is added in triton
# https://github.com/triton-lang/triton/issues/6054
"float8_e8m0fnu": "u8",
"float4_e2m1fn_x2": "u8",
"float16": "fp16",
"bfloat16": "bf16",
"float32": "fp32",
"float64": "fp64",
"int8": "i8",
"int16": "i16",
"int32": "i32",
"int64": "i64",
"uint8": "u8",
"uint16": "u16",
"uint32": "u32",
"uint64": "u64",
}
# reinterpret can create triton type
tys.update({v: v for v in list(tys.values())})
return key if isinstance(key, str) else f"*{tys[dtype_str]}"
def convert_shape_to_inductor(
lst: Iterable[Union[int, torch.SymInt]],
) -> list[sympy.Expr]:
"""
Gets the shape and stride of a tensor. For non-symbolic tensors, this is
trivial. But for symbolic tensors, we need to map from SymIntNode into
sympy.Expr.
"""
return [sympy.sympify(i) for i in lst]
def convert_to_symint(i: Union[int, sympy.Expr]) -> Union[int, torch.SymInt]:
"""
Like convert_shape_to_symint, but operates on a single expression.
"""
from .virtualized import V
return (
i
if isinstance(i, int)
else (
int(i)
if isinstance(i, sympy.Integer)
else V.graph.sizevars.shape_env.create_symintnode(i, hint=None)
)
)
def convert_shape_to_symint(
lst: Iterable[Union[int, sympy.Expr]],
) -> list[Union[int, torch.SymInt]]:
"""
Takes a list of shapes from Inductor and converts them into symints (or just
ints if all shapes are static).
"""
return [convert_to_symint(i) for i in lst]
def is_view(op: torch._ops.OpOverload) -> bool:
"""
Does this op overload have aliasing
"""
return any(a.alias_info is not None for a in op._schema.arguments)
def is_pointwise_use(
use: Node,
is_pointwise_fn: Callable[[torch._ops.OpOverload], bool] = lambda _: False,
) -> bool:
"""
Do all uses of this op have torch.Tag.pointwise or return True for optional `is_pointwise_fn`
Uses in views ops will follow the views uses
"""
if not use.op == "call_function":
return False
if not (
isinstance(use.target, torch._ops.OpOverload) or use.target is operator.getitem
):
return False
target = cast(torch._ops.OpOverload, use.target)
if target is operator.getitem or is_view(target):
return all(is_pointwise_use(u, is_pointwise_fn) for u in use.users)
return torch.Tag.pointwise in target.tags or is_pointwise_fn(target)
def gen_gm_and_inputs(
target: Any, args: list[Any], kwargs: dict[str, Any]
) -> tuple[GraphModule, list[torch.Tensor]]:
g = torch.fx.Graph()
graph_args: list[torch.Tensor] = []
def add_tensor_arg(arg: torch.Tensor) -> Node:
graph_args.append(arg)
return g.placeholder(f"arg{len(graph_args)}")
node = g.call_function(
target, *tree_map_only(torch.Tensor, add_tensor_arg, (args, kwargs))
)
if (
len(target._schema.returns) == 1
and str(target._schema.returns[0].type) == "Tensor"
):
node = (node,) # type: ignore[assignment]
g.output(node)
gm = torch.fx.GraphModule({}, g)
return gm, graph_args
def synchronize(device: str = "cuda") -> None:
if device == "cpu":
return
device_interface = get_interface_for_device(device)
if device_interface.is_available():
device_interface.synchronize()
def timed(
model: Callable[..., Any],
example_inputs: Sequence[Any],
times: int = 1,
device: str = "cuda",
) -> float:
synchronize(device)
torch.manual_seed(1337)
t0 = time.perf_counter()
for _ in range(times):
result = model(*example_inputs)
synchronize(device)
t1 = time.perf_counter()
# GC the result after timing
assert result is not None # type: ignore[possibly-undefined]
return t1 - t0
def print_performance(
model: Callable[..., Any],
example_inputs: Sequence[Any] = (),
times: int = 10,
repeat: int = 10,
baseline: float = 1.0,
device: str = "cuda",
) -> float:
timings = torch.tensor(
[timed(model, example_inputs, times, device) for _ in range(repeat)]
)
took = torch.median(timings) / times
print(f"{took / baseline:.6f}")
return took.item()
def precompute_method(obj: Any, method: str) -> None:
"""Replace obj.method() with a new method that returns a precomputed constant."""
result = getattr(obj, method)()
setattr(obj, method, lambda: result)
def precompute_methods(obj: Any, methods: list[str]) -> None:
"""Replace methods with new methods that returns a precomputed constants."""
for method in methods:
precompute_method(obj, method)
def cmp(a: int, b: int) -> int:
return int(a > b) - int(a < b)
def pad_listlike(x: Union[int, Sequence[int]], size: int) -> Sequence[int]:
if isinstance(x, int):
return [x] * size
if len(x) == 1:
return type(x)([x[0]]) * size # type: ignore[call-arg, operator, return-value]
return x
# Used to ensure that iterating over a set is deterministic
def tuple_sorted(x: tuple[_T, ...]) -> list[_T]:
if len(x) == 0:
return []
def sort_func(elem: _T) -> str:
if isinstance(elem, str):
return elem
from .scheduler import BaseSchedulerNode
assert isinstance(elem, BaseSchedulerNode)
return elem.get_name()
return sorted(x, key=sort_func)
P = ParamSpec("P")
RV = TypeVar("RV", covariant=True)
class CachedMethod(Protocol, Generic[P, RV]):
@staticmethod
def clear_cache(cache: Any) -> None: ...
def __call__(self, *args: P.args, **kwargs: P.kwargs) -> RV: ...
# See https://github.com/python/mypy/issues/13222#issuecomment-1193073470 to understand the type signature
def cache_on_self(fn: Callable[Concatenate[Any, P], RV]) -> CachedMethod[P, RV]:
name = fn.__name__
key = f"__{name}_cache"
# wrapper is likely on the hot path, compile a specialized version of it
ctx = {"fn": fn}
exec(
f"""\
def {name}_cache_on_self(self):
try:
return self.{key}
except AttributeError:
pass
rv = fn(self)
object.__setattr__(self, "{key}", rv)
return rv
""".lstrip(),
ctx,
)
wrapper = functools.wraps(fn)(ctx[f"{name}_cache_on_self"])
def clear_cache(self: Any) -> None:
if hasattr(self, key):
delattr(self, key)
wrapper.clear_cache = clear_cache # type: ignore[attr-defined]
return wrapper # type: ignore[return-value]
def aggregate_origins(
node_schedule: Union[Sequence[BaseSchedulerNode], ExternKernel],
) -> OrderedSet[Node]:
from . import ir
if isinstance(node_schedule, list):
return functools.reduce(
operator.or_,
[
node.node.origins
for node in node_schedule
if hasattr(node, "node") and node.node
],
OrderedSet(),
)
elif isinstance(node_schedule, ir.ExternKernel):
return node_schedule.origins
else:
return OrderedSet()
def get_fused_kernel_name(
node_schedule: Sequence[BaseSchedulerNode],
descriptive_names: Literal[True, "torch", "original_aten", "inductor_node"],
) -> str:
all_origins = aggregate_origins(node_schedule)
if descriptive_names == "original_aten":
# Bases the kernel name off of the top-level aten operator (i.e. pre-decompositions)
sources = [
origin.meta["original_aten"]._overloadpacket.__name__
for origin in all_origins
if origin.op == "call_function"
and "original_aten" in origin.meta
and origin.meta["original_aten"] is not None
]
sources = sorted(OrderedSet(sources))
elif descriptive_names == "torch":
# Bases the kernel name off of the top-level "torch" operator (i.e. post-dynamo graph)
sources = []
for origin in all_origins:
if origin.op == "call_function" and "source_fn_stack" in origin.meta:
source_fn = origin.meta["source_fn_stack"][-1]
if isinstance(source_fn[1], str):
sources.append(source_fn[1])
else:
sources.append(source_fn[1].__name__)
sources = sorted(OrderedSet(sources))
elif descriptive_names == "inductor_node":
sources = [
origin.name for origin in all_origins if origin.op == "call_function"
]
else:
raise NotImplementedError
sources = sources
return "_".join(["fused"] + sources)
def get_kernel_metadata(
node_schedule: Union[Sequence[BaseSchedulerNode], ExternKernel],
wrapper: PythonWrapperCodegen,
) -> tuple[str, str]:
"""
Retrieves metadata information for a kernel.
Args:
node_schedule (Union[Sequence[BaseSchedulerNode], ExternKernel]):
Either a sequence of BaseSchedulerNode objects or an ExternKernel instance.
wrapper (PythonWrapperCodegen):
An instance of PythonWrapperCodegen, used to define the code comment format.
Returns:
tuple[str, str]:
A tuple containing two strings:
- The first string represents the kernel's metadata.
- The second string represent the kernel's detailed metadata.
"""
all_origins = aggregate_origins(node_schedule)
inductor_nodes = [origin for origin in all_origins if origin.op == "call_function"]
from_node_dict = collections.defaultdict(list)
original_aten_dict = collections.defaultdict(list)
# Attempt to sort `inductor_nodes` topologically. Note that the case
# where `inductor_nodes` contains nodes from multiple graph instances
# is not supported. An example of this is conditional statements.
single_graph = None
if len(inductor_nodes):
unique_graphs = OrderedSet(n.graph for n in inductor_nodes)
if len(unique_graphs) == 1:
single_graph = inductor_nodes[0].graph
# create a map of idx -> node and cache it
if not hasattr(single_graph, "_inductor_kernel_metadata_node_to_idx_map"):
node_to_idx_map = {n: idx for idx, n in enumerate(single_graph.nodes)}
single_graph._inductor_kernel_metadata_node_to_idx_map = node_to_idx_map # type: ignore[attr-defined]
inductor_nodes.sort(
key=lambda n: single_graph._inductor_kernel_metadata_node_to_idx_map[n] # type: ignore[attr-defined]
)
for node in inductor_nodes:
if "original_aten" in node.meta and node.meta["original_aten"] is not None:
key = str(node.meta["original_aten"]._overloadpacket)
original_aten_dict[key].append(node.name)
if "from_node" in node.meta:
key = node.meta["from_node"][0].name
from_node_dict[key].append(node.name)
sort_str = "Topologically Sorted" if single_graph is not None else "Unsorted"
metadata = (
f"{wrapper.comment} {sort_str} Source Nodes: [{', '.join(from_node_dict.keys())}], "
f"Original ATen: [{', '.join(original_aten_dict.keys())}]"
)
# trace back to original node here
detailed_metadata = [f"{wrapper.comment} Source node to ATen node mapping:"]
for original_node, nodes in sorted(from_node_dict.items()):
detailed_metadata.append(
f"{wrapper.comment} {original_node} => {', '.join(sorted(nodes))}"
)
# print the aot_autograd graph fragment
if single_graph is not None:
from . import ir
detailed_metadata.append(f"{wrapper.comment} Graph fragment:")
all_reads: OrderedSet[str] = OrderedSet()
all_writes: list[str] = []
if not isinstance(node_schedule, ir.ExternKernel):
from .virtualized import V
def get_buffer_info(
buffer: Union[ir.TensorBox, ir.Buffer, ir.TorchBindObject], rw_name: str
) -> tuple[str, ir.Layout | None]:
if isinstance(buffer, ir.TensorBox) and isinstance(
buffer.data, ir.StorageBox
):
origin_node = buffer.data.data.origin_node
else:
origin_node = buffer.origin_node
if origin_node is None:
# use the read/write name if no origin node is found
name = rw_name
else:
name = origin_node.name
try:
layout = buffer.get_layout()
except NotImplementedError:
layout = None
return name, layout
def stringify_shape(shape: Iterable[int]) -> str:
return f"[{', '.join([str(x) for x in shape])}]"
def stringfy_layout(layout: ir.Layout | None) -> str:
if layout is None:
return ""
shape_annotation = f"{stringify_shape(layout.size)}"
stride_annotation = f"{stringify_shape(layout.stride)}"
device_annotation = f"{layout.device}"
return (
f'"{dtype_abbrs[layout.dtype]}{shape_annotation}'
f'{stride_annotation}{device_annotation}"'
)
for n in node_schedule:
if not hasattr(n, "read_writes") or n.read_writes is None:
continue
if hasattr(n.read_writes, "reads") and n.read_writes.reads is not None:
for r in n.read_writes.reads:
# Remove the dupricated inputs
if r.name in all_reads:
continue
all_reads.add(r.name)
buffer = V.graph.try_get_buffer(r.name)
if buffer is None:
continue
input_name, layout = get_buffer_info(buffer, r.name)
detailed_metadata.append(
f"{wrapper.comment} %{input_name} : Tensor "
f"{stringfy_layout(layout)} = PlaceHolder[target={input_name}]"
)
if (
hasattr(n.read_writes, "writes")
and n.read_writes.writes is not None
):
for w in n.read_writes.writes:
buffer = V.graph.try_get_buffer(w.name)
if buffer is None:
continue
output_name, _ = get_buffer_info(buffer, w.name)
all_writes.append("%" + output_name)
for node in inductor_nodes:
detailed_metadata.append(f"{wrapper.comment} {node.format_node()}")
detailed_metadata.append(f"{wrapper.comment} return {','.join(all_writes)}")
return metadata, "\n".join(detailed_metadata)
def dominated_nodes(
initial_queue: Iterable[torch.fx.Node],
skip_filter: Optional[Callable[[Any], bool]] = None,
) -> OrderedSet[torch.fx.Node]:
"""Returns the set of nodes whose values depend on those within initial_queue"""
initial_queue = list(initial_queue)
dominated_set = OrderedSet(initial_queue)
while initial_queue:
node = initial_queue.pop()
for user in node.users:
if skip_filter and skip_filter(user):
continue
if user not in dominated_set:
dominated_set.add(user)
initial_queue.append(user)
return dominated_set
def gather_origins(
args: Sequence[IRNode], kwargs: dict[str, IRNode]
) -> OrderedSet[torch.fx.Node]:
from . import ir
def is_unrealized_node(n: IRNode) -> bool:
if isinstance(n, ir.TensorBox):
return is_unrealized_node(n.data)
if isinstance(n, ir.StorageBox):
return is_unrealized_node(n.data)
return isinstance(n, ir.IRNode) and not ir.IRNode.is_realized_node(n)
# kwargs and args may include a container of node, for example torch.cat([t1, t2])
# flatten them before search the unrealized nodes
kwargs_flatten, _ = tree_flatten(kwargs)
kwargs_origins = [val.origins for val in kwargs_flatten if is_unrealized_node(val)]
args_flatten, _ = tree_flatten(args)
args_origins = [val.origins for val in args_flatten if is_unrealized_node(val)]
return OrderedSet(itertools.chain(*args_origins, *kwargs_origins))
def sympy_str(expr: sympy.Expr) -> str:
"""
Normal sympy str is very slow, this is a lot faster. The result are
somewhat worse, as it doesn't do as much simplification. So don't
use this for final codegen.
"""
def is_neg_lead(expr: sympy.Expr) -> bool:
return (
isinstance(expr, sympy.Mul) and len(expr.args) == 2 and expr.args[0] == -1
)
def sympy_str_add(expr: sympy.Expr) -> str:
if isinstance(expr, sympy.Add):
# Special case 'a - b'. Note that 'a - b - c' will still appear as
# 'a + -1 * b + -1 * c'.
if len(expr.args) == 2 and is_neg_lead(expr.args[1]):
return f"{sympy_str_mul(expr.args[0])} - {sympy_str_mul(expr.args[1].args[1])}"
else:
return " + ".join(map(sympy_str_mul, expr.args))
else:
return sympy_str_mul(expr)
def sympy_str_mul(expr: sympy.Expr) -> str:
if isinstance(expr, sympy.Mul):
if is_neg_lead(expr):
# Special case '-a'. Note that 'a * -b' will still appear as
# '-1 * a * b'.
return f"-{sympy_str_atom(expr.args[1])}"
else:
return " * ".join(map(sympy_str_atom, expr.args))
else:
return sympy_str_atom(expr)
def sympy_str_atom(expr: sympy.Expr) -> str:
if isinstance(expr, sympy.Symbol):
return expr.name
elif isinstance(expr, (sympy.Add, sympy.Mul)):
return f"({sympy_str_add(expr)})"
elif isinstance(expr, (ModularIndexing, CleanDiv, FloorDiv, Identity)):
return f"{expr.func.__name__}({', '.join(map(sympy_str, expr.args))})"
else:
return str(expr)
return sympy_str_add(expr)
def get_bounds_index_expr(index: sympy.Expr) -> ValueRanges[Any]:
from .virtualized import V
# If this expression does not come from an FX node, we compute its bounds
if (
config.compute_all_bounds
and (fx_node := getattr(V.interpreter, "current_node", None))
and fx_node.target != "index_expr"
):
return bound_sympy(index)
else:
return ValueRanges.unknown()
def prefix_is_reduction(prefix: str) -> bool:
return prefix[0] == "r"
def sympy_index_symbol_with_prefix(prefix: SymT, idx: int) -> sympy.Symbol:
"""
Used to generate an integer-nonnegative symbol.
"""
# This should never be used for creating shape/stride symbols, as those
# should all be allocated before Inductor.
assert prefix != SymT.SIZE
# NOTE: shape symbols are positive (> 0), but index variables are only
# non-negative (>= 0).
return make_symbol(prefix, idx, integer=True, nonnegative=True)
def generate_assert(check: bool) -> bool:
return (check or config.debug_index_asserts) and config.assert_indirect_indexing
def sympy_index_symbol(name: str) -> sympy.Symbol:
"""
Used to generate an integer-nonnegative symbol.
"""
# This should never be used for creating shape/stride symbols, as those
# should all be allocated before Inductor.
assert name[0] != "s"
# NOTE: shape symbols are positive (> 0), but index variables are only
# non-negative (>= 0).
return sympy.Symbol(name, integer=True, nonnegative=True)
def sympy_subs(expr: sympy.Expr, replacements: dict[sympy.Expr, Any]) -> sympy.Expr:
"""
When the passed replacement symbol v is a string, it is converted to a symbol with name v that
have the same replaced expression integer and nonnegative properties.
"""
def to_symbol(
replaced: sympy.Expr, replacement: Union[sympy.Expr, str]
) -> sympy.Symbol:
assert isinstance(replaced, sympy.Expr)
if isinstance(replacement, str):
return sympy.Symbol(
replacement,
integer=replaced.is_integer, # type: ignore[attr-defined]
nonnegative=replaced.is_nonnegative, # type: ignore[attr-defined]
)
else:
return replacement
# xreplace is faster than subs, but is way more picky
return sympy.sympify(expr).xreplace(
{k: to_symbol(k, v) for k, v in replacements.items()}
)
def is_symbolic(a: Any) -> TypeGuard[Union[torch.SymInt, torch.Tensor]]:
return isinstance(a, torch.SymInt) or (
isinstance(a, torch.Tensor)
and any(is_symbolic(x) for x in itertools.chain(a.size(), a.stride()))
)
def any_is_symbolic(*args: Any) -> bool:
return any(is_symbolic(a) for a in args)
def get_first_incompatible_cudagraph_node(
gm: torch.fx.GraphModule,
) -> Optional[torch.fx.Node]:
from torch.fx.experimental.symbolic_shapes import free_unbacked_symbols
forbidden_set = OrderedSet(
[
"aten._fused_moving_avg_obs_fq_helper.default",
"aten._fused_moving_avg_obs_fq_helper_functional.default",
"fbgemm.dense_to_jagged.default",
"fbgemm.jagged_to_padded_dense.default",
"run_and_save_rng_state",
"run_with_rng_state",
"aten._local_scalar_dense",
# Technically, it's not necessary to ban this, because an
# assert_scalar with constant arguments can be validly run
# with CUDA graphs, but the operator is also pointless with
# constant arguments, so might as well ban
"aten._assert_scalar",
]
)
if torch.are_deterministic_algorithms_enabled():
forbidden_set.update(
(
"aten._unsafe_index_put.default",
"aten._unsafe_masked_index_put_accumulate.default",
"aten.index_put.default",
"aten.index_put_.default",
"aten.scatter.src",
"aten.scatter.reduce",
"aten.scatter.value_reduce",
"aten.scatter_add_",
"aten.scatter_add.default",
"aten.scatter_reduce.two",
"aten.scatter_reduce_.two",
"aten.scatter_reduce.two_out",
)
)
for node in gm.graph.nodes:
if str(node.target) in forbidden_set:
return node
if (
not torch._inductor.config.graph_partition
and isinstance(node.target, torch._ops.OpOverload)
and torch._C.Tag.cudagraph_unsafe in node.target.tags # type: ignore[attr-defined]
):
# skip cudagraph if a cudagraph_unsafe op is detected.
# graph_partition helps by splitting on this cudagraph_unsafe
# op and cudagraphifying the subgraphs.
return node
if (val := node.meta.get("val")) is not None and free_unbacked_symbols(val):
return node
return None
def output_node(gm: torch.fx.GraphModule) -> Node:
"""Get the output node from an FX graph"""
last_node = next(iter(reversed(gm.graph.nodes)))
assert last_node.op == "output"
return last_node
def get_all_devices(gm: torch.fx.GraphModule) -> OrderedSet[torch.device]:
placeholder_nodes = gm.graph.find_nodes(op="placeholder")
input_devices: OrderedSet[torch.device] = OrderedSet(
node.meta["val"].device
for node in placeholder_nodes
if isinstance(node.meta.get("val"), torch.Tensor)
)
out_arg = output_node(gm).args[0] # type: ignore[union-attr]
out_args = out_arg if isinstance(out_arg, tuple) else (out_arg,)
out_devices: OrderedSet[torch.device] = OrderedSet(
arg.meta["val"].device
for arg in out_args
if isinstance(arg, torch.fx.Node)
and isinstance(arg.meta.get("val"), torch.Tensor)
)
return input_devices | out_devices
import gc
def unload_xpu_triton_pyds() -> None:
# unload __triton_launcher.pyd
for module_name in list(sys.modules.keys()):
if not module_name.startswith("torch._inductor.runtime.compile_tasks."):
continue
m = sys.modules[module_name]
for attr_name in m.__dict__.keys():
if attr_name.startswith("triton_"):
kernel = getattr(m, attr_name)
if isinstance(
kernel, torch._inductor.runtime.triton_heuristics.CachingAutotuner
):
for result in kernel.compile_results:
if isinstance(
result,
torch._inductor.runtime.triton_heuristics.TritonCompileResult,
):
result.kernel.run.mod.__del__()
del sys.modules[module_name]
# unload spirv_utils.pyd
if "triton.runtime.driver" in sys.modules:
mod = sys.modules["triton.runtime.driver"]
del type(mod.driver.active.utils).instance
del mod.driver.active.utils
gc.collect()
_registered_caches: list[Any] = []
def clear_on_fresh_cache(obj: Any) -> Any:
"""
Use this decorator to register any caches that should be cache_clear'd
with fresh_cache().
"""
if not hasattr(obj, "cache_clear") or not callable(obj.cache_clear):
raise AttributeError(f"{obj} does not have a cache_clear method")
_registered_caches.append(obj)
return obj
def clear_caches() -> None:
"""
Clear all registered caches.
"""
for obj in _registered_caches:
obj.cache_clear()
@contextlib.contextmanager
def fresh_cache(
cache_entries: Optional[dict[str, Any]] = None,
dir: Optional[str] = None,
delete: bool = True,
) -> Iterator[None]:
"""
Contextmanager that provides a clean tmp cachedir for pt2 caches.
Optionally, pass a dict as 'cache_entries' to get a list of filenames and sizes
generated with this cache instance.
"""
clear_caches()
from torch._inductor.cpp_builder import normalize_path_separator
inductor_cache_dir = normalize_path_separator(tempfile.mkdtemp(dir=dir))
try:
with mock.patch.dict(
os.environ, {"TORCHINDUCTOR_CACHE_DIR": inductor_cache_dir}
):
log.debug("Using inductor cache dir %s", inductor_cache_dir)
triton_cache_dir = normalize_path_separator(
os.path.join(inductor_cache_dir, "triton")
)
with mock.patch.dict(os.environ, {"TRITON_CACHE_DIR": triton_cache_dir}):
yield
if isinstance(cache_entries, dict):
assert len(cache_entries) == 0, "expected empty cache_entries dict"
if os.path.exists(triton_cache_dir):
files = os.listdir(triton_cache_dir)
cache_entries.update(
{
f: os.path.getsize(os.path.join(triton_cache_dir, f))
for f in files
if ".lock" not in f
}
)
if delete:
if is_windows() and torch.xpu.is_available():
unload_xpu_triton_pyds()
shutil.rmtree(
inductor_cache_dir,
# Let's not fail if we can't clean up the temp dir. Also note that for
# Windows, we can't delete the loaded modules because the module binaries
# are open.
ignore_errors=is_windows(),
onerror=lambda func, path, exc_info: log.warning(
"Failed to remove temporary cache dir at %s",
inductor_cache_dir,
exc_info=exc_info,
),
)
except Exception:
log.warning("on error, temporary cache dir kept at %s", inductor_cache_dir)
raise
finally:
clear_caches()
# Deprecated functions -- only keeping them for BC reasons
clear_on_fresh_inductor_cache = clear_on_fresh_cache
clear_inductor_caches = clear_caches
fresh_inductor_cache = fresh_cache
def argsort(seq: Sequence[Any]) -> list[int]:
# preserve original order for equal strides
getter = seq.__getitem__
a_r = range(len(seq))
return list(reversed(sorted(a_r, key=getter, reverse=True))) # noqa: C413
def argsort_sym(
shape_env: ShapeEnv, seq: Sequence[Union[int, torch.SymInt, sympy.Expr]]
) -> list[int]:
def cmp(a: tuple[int, sympy.Expr], b: tuple[int, sympy.Expr]) -> int:
a_idx, a_val = a
b_idx, b_val = b
def evaluate(expr: Union[bool, torch.SymInt, sympy.Expr]) -> bool:
if isinstance(expr, bool):
return expr
return shape_env.evaluate_expr(expr, size_oblivious=True)
if evaluate(a_val < b_val):
return -1
if evaluate(a_val > b_val):
return 1
# If strides are the same, prefer the original order.
# (this matches argsort's algorithm).
# For strides = [2048, 2048, 16, 1], this is
# [3, 2, 1, 0].
if a_idx < b_idx:
return 1
if a_idx > b_idx:
return -1
return 0
# Strategy: convert all symints to sympy.Expr, then use a custom comparator
exprs = [
(idx, s.node.expr if isinstance(s, torch.SymInt) else s)
for idx, s in enumerate(seq)
]
exprs = sorted(exprs, key=functools.cmp_to_key(cmp))
result = [idx for idx, _ in exprs]
return result
@functools.lru_cache(8)
def get_dtype_size(dtype: torch.dtype) -> int:
# TODO: Investigate why uint64 tensor creation causes overflow error:
# Workaround for RuntimeError in memory size calculation, but underlying cause unclear
if dtype == torch.uint64:
return 8
return torch.empty((), dtype=dtype).element_size()
class LineContext(NamedTuple):
context: Any
@dataclasses.dataclass
class ValueWithLineMap:
value: str
line_map: list[tuple[int, LineContext]]
class IndentedBuffer:
tabwidth = 4
def __init__(self, initial_indent: int = 0) -> None:
self._lines: list[Union[DeferredLineBase, LineContext, str]] = []
self._indent = initial_indent
@contextlib.contextmanager
def set_tabwidth(self, tabwidth: int) -> Iterator[None]:
prev = self.tabwidth
try:
self.tabwidth = tabwidth
yield
finally:
self.tabwidth = prev
def getvaluewithlinemap(self) -> ValueWithLineMap:
buf = StringIO()
p = 1
linemap: list[tuple[int, LineContext]] = []
for li in self._lines:
if isinstance(li, DeferredLineBase):
line = li()
if line is None:
continue
elif isinstance(li, LineContext):
linemap.append((p, li.context))
continue
else:
line = li
assert isinstance(line, str)
buf.write(line)
buf.write("\n")
p += 1 + line.count("\n")
return ValueWithLineMap(buf.getvalue(), linemap)
def getvalue(self) -> str:
return self.getvaluewithlinemap().value
def getrawvalue(self) -> str:
buf = StringIO()
for li in self._lines:
if isinstance(li, DeferredLineBase):
line = li()
if line is None:
continue
elif isinstance(li, LineContext):
continue
else:
line = li
assert isinstance(line, str)
# backslash implies line continuation
if line.endswith("\\"):
buf.write(line[:-1])
else:
buf.write(line)
buf.write("\n")
return buf.getvalue()
def clear(self) -> None:
self._lines.clear()
def __bool__(self) -> bool:
return bool(self._lines)
def prefix(self) -> str:
return " " * (self._indent * self.tabwidth)
def newline(self) -> None:
self.writeline("\n")
def writeline(self, line: Union[LineContext, DeferredLineBase, str]) -> None:
if isinstance(line, LineContext):
self._lines.append(line)
elif isinstance(line, DeferredLineBase):
self._lines.append(line.with_prefix(self.prefix()))
elif line.strip():
self._lines.append(f"{self.prefix()}{line}")
else:
self._lines.append("")
def writelines(
self, lines: Sequence[Union[LineContext, DeferredLineBase, str]]
) -> None:
for line in lines:
self.writeline(line)
def indent(self, offset: int = 1) -> contextlib.AbstractContextManager[None]:
@contextlib.contextmanager
def ctx() -> Iterator[None]:
self._indent += offset
try:
yield
finally:
self._indent -= offset
return ctx()
def do_indent(self, offset: int = 1) -> None:
self._indent += offset
def do_unindent(self, offset: int = 1) -> None:
self._indent -= offset
def splice(
self, other_code: Union[IndentedBuffer, str], strip: bool = False
) -> None:
if isinstance(other_code, IndentedBuffer):
dedent = float("inf")
for line in other_code._lines:
if not isinstance(line, LineContext) and line:
dedent = min(dedent, len(line) - len(line.lstrip()))
if math.isinf(dedent):
dedent = 0
for line in other_code._lines:
if isinstance(line, LineContext):
self._lines.append(line)
else:
IndentedBuffer.writeline(self, line[int(dedent) :])
else:
other_code = textwrap.dedent(other_code)
if strip:
other_code = other_code.lstrip()
if not other_code:
return
other_code = other_code.rstrip()
for s in other_code.split("\n"):
self.writeline(s)
def map(self, func: Callable[[Any], Any]) -> IndentedBuffer:
res = IndentedBuffer(initial_indent=self._indent)
res._lines = [func(line) for line in self._lines]
return res
def __repr__(self) -> str:
return f"{type(self)}({self.getvalue()})"
def __add__(self, other: Self) -> IndentedBuffer:
assert self._indent == other._indent
res = IndentedBuffer(initial_indent=self._indent)
# TODO(rec): or should this be self.__class__(initial_indent=self._indent)?
res.writelines(self._lines)
res.writelines(other._lines)
return res
class FakeIndentedBuffer(IndentedBuffer):
def __init__(self) -> None:
super().__init__()
def __getattribute__(self, name: str) -> Any:
if name == "__class__": # Allow access to the class attribute
return object.__getattribute__(self, name)
raise RuntimeError(
f"Tried to call self.{name} on FakeIndentedBuffer. This buffer"
"is currently used on TritonTemplateKernel to prevent actual"
"writes to the body without explicitly specifying the body with"
"`TritonTemplateKernel.set_subgraph_body(name)`"
)
@contextlib.contextmanager
def restore_stdout_stderr() -> Iterator[None]:
initial_stdout, initial_stderr = sys.stdout, sys.stderr
try:
yield
finally:
sys.stdout, sys.stderr = initial_stdout, initial_stderr
class DeferredLineBase:
"""A line that can be 'unwritten' at a later time"""
def __init__(self, line: str):
if not line.strip():
line = ""
self.line = line
def __call__(self) -> Union[str, None]:
"""Returns either self.line or None to indicate the line has been 'unwritten'"""
raise NotImplementedError
def _new_line(self, line: str) -> Self:
"""Returns a new deferred line with the same condition"""
raise NotImplementedError
def with_prefix(self, prefix: str) -> Self:
return self._new_line(f"{prefix}{self.line}")
def lstrip(self) -> Self:
return self._new_line(self.line.lstrip())
def __getitem__(self, index: Union[int, slice]) -> Self:
return self._new_line(self.line[index])
def __bool__(self) -> bool:
return bool(self.line)
def __len__(self) -> int:
return len(self.line)
class DelayReplaceLine(DeferredLineBase):
"""At end of codegen call `line.replace(key, value_fn())`"""
def __init__(self, key: str, value_fn: Callable[[], str], line: str):
super().__init__(line)
self.key = key
self.value_fn = value_fn
def __call__(self) -> str:
return self.line.replace(self.key, self.value_fn())
def _new_line(self, line: str) -> DelayReplaceLine:
return DelayReplaceLine(self.key, self.value_fn, line)
@functools.cache
def is_big_gpu(index_or_device: Union[int, torch.device] = 0) -> bool:
if isinstance(index_or_device, torch.device):
device = index_or_device
else:
device = torch.device(get_gpu_type(), index_or_device)
prop = DeviceProperties.create(device)
# SM logic is not relevant to ROCm gpus
# Arbitrarily skipping the older models
if torch.version.hip:
assert prop.major is not None
if prop.major < 9 or prop.major == 10:
log.warning("GPU arch does not support max_autotune_gemm mode usage")
return False
return True
min_sms = 16 if device.type == "xpu" else 68 # 3080
avail_sms = prop.multi_processor_count
if avail_sms < min_sms:
log.warning(
"Not enough SMs to use max_autotune_gemm mode",
extra={"min_sms": min_sms, "avail_sms": avail_sms},
)
return False
return True
@functools.lru_cache
def get_max_num_sms() -> int:
return torch.cuda.get_device_properties("cuda").multi_processor_count
def get_num_sms() -> int:
"""Handle experimental carveout if set otherwise return hardware SM count"""
# TODO we need to properly guard on this global
carveout = torch._C._get_sm_carveout_experimental()
return get_max_num_sms() - (carveout if carveout is not None else 0)
def get_tma_workspace_arg(
num_tma_descriptors: int,
device: torch.device,
num_programs: Optional[int] = None,
) -> WorkspaceArg:
"""Builds and returns a WorkspaceArg for the device side TMA workspace buffer."""
from .codegen.common import WorkspaceArg, WorkspaceZeroMode
if num_programs is None:
num_programs = get_num_sms()
zero_mode = WorkspaceZeroMode.from_bool(False)
size = num_programs * num_tma_descriptors * TMA_DESCRIPTOR_SIZE
return WorkspaceArg(
count=size,
zero_mode=zero_mode,
device=device,
outer_name=WorkspaceArg.unique_name(),
)
def _use_template_for_gpu(
layout: Layout, allowed_layout_dtypes: list[torch.dtype]
) -> bool:
if layout.dtype not in allowed_layout_dtypes:
log.debug(
"Not using template since dtype %s is not in allowed layout dtypes %s",
layout.dtype,
allowed_layout_dtypes,
)
return (
is_gpu(layout.device.type)
and layout.dtype in allowed_layout_dtypes
and is_big_gpu(layout.device)
)
def _use_autotune_backend(backend: str) -> bool:
return backend.upper() in [
x.strip() for x in config.max_autotune_gemm_backends.upper().split(",")
]
def _use_conv_autotune_backend(backend: str) -> bool:
return backend.upper() in [
x.strip() for x in config.max_autotune_conv_backends.upper().split(",")
]
def use_triton_template(
layout: Layout, *, enable_int32: bool = False, enable_float8: bool = False
) -> bool:
from .codegen.common import BackendFeature, has_backend_feature
layout_dtypes = [torch.float16, torch.bfloat16, torch.float32]
if enable_int32:
layout_dtypes = [torch.float16, torch.bfloat16, torch.float32, torch.int32]
if enable_float8:
layout_dtypes.extend([torch.float8_e4m3fn, torch.float8_e5m2])
return (
(
(
is_gpu(layout.device.type)
and _use_template_for_gpu(layout, layout_dtypes)
)
or (layout.device.type == "cpu" and layout.dtype in layout_dtypes)
)
and (config.max_autotune or config.max_autotune_gemm)
and _use_autotune_backend("TRITON")
and has_backend_feature(layout.device, BackendFeature.TRITON_TEMPLATES)
)
def can_use_tma(*matrices: IRNode, add_guards: bool = False) -> bool:
"""
Return True iff *all* supplied tensors satisfy the CUDA-12.9 TMA constraints
that Triton relies on today.
* https://docs.nvidia.com/cuda/cuda-driver-api/group__CUDA__TENSOR__MEMORY.html
A tensor is accepted when:
* 2 ≤ rank ≤ 5
* dtype ∈ {FP16, BF16, FP8-E4M3FN}
* Every logical size ≥ 2
* Base pointer 16-byte aligned
* All "outer" dims have 16-byte aligned strides
* The “inner” dim has stride 1 (contiguous)
* For FP8 tensors, inner dim ≥ 32
"""
from torch.utils._triton import has_triton_tma_device
from .virtualized import V
def _aligned(expr_bytes: Union[int, sympy.Expr]) -> bool:
return V.graph.sizevars.statically_known_multiple_of(expr_bytes, TMA_ALIGNMENT)
def _is_tma_compatible(x: IRNode) -> bool:
sizes = x.get_size()
strides = x.get_stride()
rank = len(sizes)
dtype = x.get_dtype()
itemsize = dtype.itemsize
# 2 ≤ rank ≤ 5
if rank < 2 or rank > 5:
return False
# dtype ∈ {FP16, BF16, FP8-E4M3FN}
if dtype not in (torch.float16, torch.bfloat16, torch.float8_e4m3fn):
return False
# Base pointer 16-byte aligned
if x.get_name() in V.graph.unaligned_buffers:
return False
if add_guards:
sizes_i = V.graph.sizevars.guard_int_seq(sizes)
strides_i = V.graph.sizevars.guard_int_seq(strides)
else:
sizes_i = [V.graph.sizevars.symbolic_hint(s) for s in sizes]
strides_i = [V.graph.sizevars.symbolic_hint(st) for st in strides]
# Every logical size ≥ 2
if any(not V.graph.sizevars.statically_known_geq(s, 2) for s in sizes_i):
return False
# Find the single contiguous (“inner”) dim
inner = [
i
for i, st in enumerate(strides_i)
if V.graph.sizevars.statically_known_equals(st, 1)
]
if len(inner) != 1:
return False
inner_idx = inner[0]
# All "outer" dims must have 16-byte aligned strides
for i, st in enumerate(strides_i):
if i == inner_idx:
continue
if not _aligned(st * itemsize):
return False
# Inner dim byte width must still be a multiple of 16 B
inner_dim = sizes_i[inner_idx]
if not _aligned(inner_dim * itemsize):
return False
# FP8 special case: inner ≥ 32
if dtype == torch.float8_e4m3fn and not V.graph.sizevars.statically_known_geq(
inner_dim, 32
):
return False
return True
return has_triton_tma_device() and all(_is_tma_compatible(m) for m in matrices)
def use_triton_tma_template(*matrices: IRNode, add_guards: bool = False) -> bool:
return (
can_use_tma(*matrices, add_guards=add_guards)
and config.triton.enable_persistent_tma_matmul
)
def use_cutlass_template(layout: Layout, m: int, n: int, k: int) -> bool:
from .virtualized import V
gemm_size = V.graph.sizevars.size_hint(m * n * k, fallback=-1)
if gemm_size <= 0 or gemm_size < config.cuda.cutlass_backend_min_gemm_size:
return False
from .codegen.cuda.cutlass_utils import try_import_cutlass
# Do not use cutlass template on ROCm
if torch.version.hip:
return False
# output dtype
# FP32 not supported: https://github.com/pytorch/pytorch/issues/145952
layout_dtypes = [torch.float16, torch.bfloat16, torch.int32]
res = (
_use_template_for_gpu(layout, layout_dtypes)
and (config.max_autotune or config.max_autotune_gemm)
and _use_autotune_backend("CUTLASS")
)
if res:
if not try_import_cutlass():
log.warning(
"Failed to import CUTLASS lib. Please check whether "
"_inductor.config.cuda.cutlass_dir %s is set correctly. "
"Skipping CUTLASS backend for now.",
config.cuda.cutlass_dir,
)
return False
return res
def _use_cutlass_for_op(op_name: str) -> bool:
"""Check if CUTLASS should be used for the given operation."""
enabled_ops = config.cuda.cutlass_enabled_ops.upper()
if enabled_ops == "ALL":
return True
return op_name.upper() in [x.strip() for x in enabled_ops.split(",")]
_IntLike: TypeAlias = Union[int, sympy.Expr]
@functools.cache
def use_decompose_k_choice(m: _IntLike, n: _IntLike, k: _IntLike) -> bool:
from torch._inductor.virtualized import V
decompose_k_threshold = config.triton.decompose_k_threshold
return (
not torch.version.hip
and V.graph.sizevars.statically_known_true(
sympy.And(
sympy.Ge(k, decompose_k_threshold * m),
sympy.Ge(k, decompose_k_threshold * n),
)
)
and not V.graph.aot_mode # TODO: Support AOTI for decomposeK
and not V.graph.cpp_wrapper
)
@functools.cache
def get_k_splits(m: _IntLike, n: _IntLike, k: _IntLike) -> list[int]:
# To limit compile time
k_splits_limit = config.triton.num_decompose_k_splits
# Hand-tuned
default_k_splits = [16, 32, 64, 128, 256]
# If k is a sympy expression, we can't do any splitting
if isinstance(k, sympy.Expr) and not k.is_number:
return default_k_splits
elif k_splits_limit == 0:
return []
if (isinstance(m, sympy.Expr) and not m.is_number) or (
isinstance(n, sympy.Expr) and not n.is_number
):
max_k_split = 256
else:
max_k_split = min(k // m, k // n)
min_k_split = 2
# Get all divisors of k, k has to be divisible by kPart
divisors = sympy.divisors(k)
divisors = [
divisor
for divisor in divisors
if divisor <= max_k_split and divisor >= min_k_split
]
pow_of_2_divisors, mul_of_32_divisors, rest_of_splits = [], [], []
for d in divisors:
kPart = k // d
# Smaller than 128 might not even fit in a single tile, BLOCK_K can be 128
if kPart < 128:
continue
# Power of 2 divisors are best performing, conform to hardware
if (kPart & kPart - 1) == 0 and kPart >= 128:
pow_of_2_divisors.append(d)
# Else check if creates a multiple of 32
elif kPart % 32 == 0:
mul_of_32_divisors.append(d)
# otherwise, take the smallest values
else:
rest_of_splits.append(d)
if config.max_autotune_gemm_search_space == "EXHAUSTIVE":
return pow_of_2_divisors + mul_of_32_divisors + rest_of_splits
best_splits = pow_of_2_divisors + mul_of_32_divisors + rest_of_splits
# Otherwise, conform results to k_splits_limit
return best_splits[:k_splits_limit]
@functools.cache
def _rocm_native_device_arch_name(device: str) -> str:
return torch.cuda.get_device_properties(device).gcnArchName
@functools.cache
def try_import_ck_lib() -> tuple[
Optional[str], Callable[[], list[Any]], Callable[[], list[Any]], type[Any]
]:
try:
import ck4inductor # type: ignore[import]
from ck4inductor.universal_gemm.gen_instances import ( # type: ignore[import]
gen_ops_library,
gen_ops_preselected,
)
from ck4inductor.universal_gemm.op import ( # type: ignore[import]
CKGemmOperation,
)
package_dirname = os.path.dirname(ck4inductor.__file__)
except ImportError:
def gen_ops_library() -> list[Any]:
return []
def gen_ops_preselected() -> list[Any]:
return []
class CKGemmOperation: # type: ignore[no-redef]
pass
package_dirname = None
return package_dirname, gen_ops_library, gen_ops_preselected, CKGemmOperation
def use_ck_template(layout: Layout) -> bool:
# config knobs check 1
if not (config.max_autotune or config.max_autotune_gemm):
return False
# platform check
if not torch.version.hip:
return False
# tensors must be on GPU
if not layout.device.type == "cuda":
return False
# hardware check
# if config arch list is not specified, get the native arch from the device properties
native_arch = _rocm_native_device_arch_name(layout.device)
requested_archs = {k.split(":")[0]: k for k in config.rocm.arch} or {
native_arch.split(":")[0]: native_arch
}
requested_supported_archs = [
requested_archs[k]
for k in requested_archs.keys() & config.rocm.ck_supported_arch
]
if not requested_supported_archs:
return False
# supported input dtypes
if layout.dtype not in [torch.float16, torch.bfloat16, torch.float32]:
return False
ck_package_dirname, _, _, _ = try_import_ck_lib()
if not ck_package_dirname:
log.warning("Please pip install Composable Kernel package")
return False
if config.is_fbcode():
config.rocm.ck_dir = ck_package_dirname
if not config.rocm.ck_dir:
log.warning("Please set TORCHINDUCTOR_CK_DIR env variable")
return False
if ck_package_dirname != config.rocm.ck_dir:
log.warning("Invalid path to CK library")
return False
return True
def use_ck_gemm_template(layout: Layout, m: int, n: int, k: int) -> bool:
from .virtualized import V
return (
_use_autotune_backend("CK")
and use_ck_template(layout)
and V.graph.sizevars.size_hint(m * n * k, fallback=-1) > 0
)
def use_ck_tile_gemm_template(layout: Layout, m: int, n: int, k: int) -> bool:
from .virtualized import V
return (
_use_autotune_backend("CKTILE")
and use_ck_template(layout)
and V.graph.sizevars.size_hint(m * n * k, fallback=-1) > 0
)
def use_ck_conv_template(layout: Layout) -> bool:
return _use_conv_autotune_backend("CK") and use_ck_template(layout)
def _use_template_for_cpu(layout: Layout) -> bool:
return (
config.max_autotune or config.max_autotune_gemm
) and layout.device.type == "cpu"
def use_cpp_bmm_template(
layout: Layout, mat1: Union[ReinterpretView, Buffer], mat2: IRNode
) -> bool:
from .ir import Layout
assert isinstance(mat1.layout, Layout)
return (
use_cpp_gemm_template(layout, mat1, mat2, require_constant_mat2=False)
and mat1.layout.is_contiguous()
)
def use_cpp_gemm_template(
layout: Layout,
mat1: IRNode,
mat2: IRNode,
mat2_transposed: bool = False,
require_constant_mat2: bool = True,
is_woq_int4: bool = False,
q_group_size: Optional[int] = None,
) -> bool:
from . import ir
from .codegen.cpp_micro_gemm import create_micro_gemm
from .codegen.cpp_utils import get_gemm_template_output_and_compute_dtype
from .kernel.mm_common import mm_args
if not _use_template_for_cpu(layout) or not _use_autotune_backend("CPP"):
return False
if not config.cpp.weight_prepack:
return False
int8_gemm = mat1.get_dtype() in [torch.uint8, torch.int8]
layout_dtypes = [torch.float32, torch.bfloat16, torch.half, torch.uint8]
m, n, k, layout, mat1, mat2 = mm_args(
mat1,
mat2,
out_dtype=layout.dtype if int8_gemm else None,
mat2_transposed=mat2_transposed,
use_4x2_dim=is_woq_int4,
)
# TODO(jgong5): support dynamic shapes for n or k
if has_free_symbols((n, k)):
return False
if isinstance(mat2, ir.BaseView):
mat2 = mat2.unwrap_view()
output_dtype, _ = get_gemm_template_output_and_compute_dtype(mat1.get_dtype())
micro_gemm = create_micro_gemm(
"micro_gemm",
m,
n,
k,
input_dtype=mat1.get_dtype(),
input2_dtype=mat2.get_dtype(),
output_dtype=output_dtype,
num_threads=parallel_num_threads(),
use_ref=not is_woq_int4,
q_group_size=q_group_size,
)
def is_last_dim_stride1(x: IRNode) -> bool:
x.freeze_layout()
return x.get_stride()[-1] == 1
return (
layout.dtype in layout_dtypes
and micro_gemm is not None
and is_last_dim_stride1(mat1) # TODO(jgong5): support transposed input
and isinstance(mat2, ir.StorageBox)
and (mat2.is_module_buffer() or not require_constant_mat2)
)
def use_aten_gemm_kernels() -> bool:
return not (
config.max_autotune or config.max_autotune_gemm
) or _use_autotune_backend("ATEN")
class DebugDirManager:
counter = itertools.count(0)
prev_debug_name: str
def __init__(self) -> None:
self.id = next(DebugDirManager.counter)
def __enter__(self) -> None:
self.prev_debug_name = torch._dynamo.config.debug_dir_root
self.new_name = f"{self.prev_debug_name}_tmp_{self.id}"
torch._dynamo.config.debug_dir_root = self.new_name
def __exit__(self, *args: Any) -> None:
shutil.rmtree(self.new_name)
torch._dynamo.config.debug_dir_root = self.prev_debug_name
def run_and_get_code(
fn: Callable[P, _T],
*args: P.args,
**kwargs: P.kwargs,
) -> tuple[_T, list[str]]:
from .graph import GraphLowering
source_codes: list[str] = []
def save_output_code(code: str) -> None:
source_codes.append(code)
with mock.patch.object(GraphLowering, "save_output_code", save_output_code):
torch._dynamo.reset()
result = fn(*args, **kwargs)
return result, source_codes
def run_and_get_kernels(
fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs
) -> tuple[_T, list[str]]:
result, source_codes = run_and_get_code(fn, *args, **kwargs)
kernels = []
for code in source_codes:
kernels.extend(re.findall(r"'''.*?'''", code, re.DOTALL))
return result, kernels
def run_fw_bw_and_get_code(fn: Callable[..., Any]) -> tuple[Any, list[str]]:
def run_with_backward() -> Any:
result = fn()
result.sum().backward()
return result
return run_and_get_code(run_with_backward)
def get_code(fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs) -> list[str]:
"""Get the inductor-generated code, but skip any actual compilation or running."""
from .graph import GraphLowering
source_codes: list[str] = []
def save_output_code(code: str) -> None:
source_codes.append(code)
def patched_compile_to_module(self: GraphLowering) -> Any:
class DummyModule:
"""This is empty to replace the generated triton module"""
def __init__(self) -> None:
pass
def call(self, *args: Any, **kwargs: Any) -> None:
# Don't do anything when called
pass
wrapper_code, kernel_code = (
self.codegen_with_cpp_wrapper() if self.cpp_wrapper else self.codegen()
)
# Skip all the actual compiling.
save_output_code(wrapper_code.value)
if kernel_code:
save_output_code(kernel_code.value)
return DummyModule()
with (
mock.patch.object(
GraphLowering, "compile_to_module", patched_compile_to_module
),
mock.patch.object(GraphLowering, "save_output_code", save_output_code),
):
torch._dynamo.reset()
# Note the return here is None
_ = fn(*args, **kwargs)
return source_codes
def get_triton_code(fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs) -> str:
source_codes = get_code(fn, *args, **kwargs)
# Can have two outputs if backwards was eagerly compiled
assert 1 <= len(source_codes) <= 2, (
f"expected one or two code outputs got {len(source_codes)}"
)
return source_codes[0]
def run_and_get_triton_code(
fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs
) -> str:
_, source_codes = run_and_get_code(fn, *args, **kwargs)
# Can have two outputs if backwards was eagerly compiled
assert 1 <= len(source_codes) <= 2, (
f"expected one or two code outputs got {len(source_codes)}"
)
return source_codes[0]
def run_and_get_graph_lowering(
fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs
) -> tuple[Any, list[GraphLowering]]:
from torch._inductor.graph import GraphLowering
from torch._inductor.output_code import CompiledFxGraph
real_init = CompiledFxGraph.__init__
graph_lowerings = []
def fake_init(*args: Any, **kwargs: Any) -> None:
real_init(*args, **kwargs)
graph = args[2]
assert isinstance(graph, GraphLowering)
graph_lowerings.append(graph)
with mock.patch.object(CompiledFxGraph, "__init__", fake_init):
result = fn(*args, **kwargs)
return result, graph_lowerings
@contextlib.contextmanager
def override_lowering(
aten_op: Callable[..., Any], override_fn: Callable[..., Any]
) -> Iterator[None]:
"""
Override the lowering of aten_op with override_fn.
The first argument of override_fn is the original lowering fn.
"""
from torch._inductor import lowering
orig_fn = lowering.lowerings[aten_op]
try:
lowering.lowerings[aten_op] = functools.partial(override_fn, orig_fn)
yield
finally:
lowering.lowerings[aten_op] = orig_fn
def add_scheduler_init_hook(
pre_fn: Callable[..., Any], post_fn: Optional[Callable[..., Any]] = None
) -> Any:
"""
Add hook functions to be called at the beginning and end of Scheduler.__init__.
Used for unit tests.
"""
from torch._inductor.scheduler import Scheduler
orig_fn = Scheduler.__init__
def wrapper(scheduler: Any, nodes: Any) -> Any:
pre_fn(scheduler, nodes)
out = orig_fn(scheduler, nodes)
if post_fn:
post_fn(scheduler, nodes)
return out
return unittest.mock.patch.object(Scheduler, "__init__", wrapper)
def developer_warning(msg: str) -> None:
"""
Warnings that will be actionable for PyTorch developers, but not
end users. Allows us to easily disable them in stable releases but
keep them on for nightly builds.
"""
if config.developer_warnings:
log.warning(msg)
else:
log.info(msg)
def get_benchmark_name() -> Optional[str]:
"""
An experimental API used only when config.benchmark_kernel is true.
The benchmark name is only available at codegen time. So we can not
directly call it in benchmark_all_kernels which is run after codegen.
The function assumes the argument after --only is the benchmark name.
It works for torchbench.py/hugginface.py/timm_models.py. But for ad-hoc
scripts, this function may return None.
There are 2 flavors of --only argument we need handle:
1. --only model_name
2. --only=model_name
"""
try:
idx = sys.argv.index("--only")
if (
idx + 1 < len(sys.argv)
and len(sys.argv[idx + 1]) > 0
and sys.argv[idx + 1][0] != "-"
):
return sys.argv[idx + 1]
except ValueError:
pass
for arg in sys.argv:
if arg.startswith("--only="):
return arg[len("--only=") :]
return None
def is_ones(items: Sequence[Any]) -> bool:
return all(x == 1 for x in items)
def is_zeros(items: Sequence[Any]) -> bool:
return all(x == 0 for x in items)
def is_cpu_device(inputs: Sequence[torch.Tensor]) -> bool:
return all(
item.device == torch.device("cpu")
for item in inputs
if isinstance(item, torch.Tensor)
)
def get_sympy_Expr_dtype(val: sympy.Expr) -> torch.dtype:
assert isinstance(val, sympy.Expr), (
"only support sympy.Expr as input to get_sympy_Expr_dtype"
)
if val.is_integer: # type: ignore[attr-defined]
return torch.int64
else:
return torch.float64
@contextlib.contextmanager
def maybe_profile(should_profile: bool, *args: Any, **kwargs: Any) -> Iterator[Any]:
if should_profile:
with torch.profiler.profile(*args, **kwargs) as p:
yield p
else:
yield
def parallel_num_threads() -> int:
threads = config.cpp.threads
if threads < 1:
threads = torch.get_num_threads()
return threads
@functools.cache
def get_backend_num_stages() -> int:
from .runtime.triton_helpers import get_backend_options
options = get_backend_options()
return options.get("num_stages", 2 if torch.version.hip else 3)
@functools.cache
def get_device_tflops(dtype: torch.dtype) -> float:
"""
We don't want to throw errors in this function. First check to see if the device is in device_info.py,
then fall back to the inaccurate triton estimation.
"""
ds_tops = datasheet_tops(dtype, is_tf32=torch.backends.cuda.matmul.allow_tf32)
if ds_tops is not None:
return ds_tops
from triton.testing import get_max_simd_tflops, get_max_tensorcore_tflops
SM80OrLater = torch.cuda.is_available() and torch.cuda.get_device_capability() >= (
8,
0,
)
assert dtype in (torch.float16, torch.bfloat16, torch.float32)
if inspect.signature(get_max_simd_tflops).parameters.get("clock_rate"):
# Triton API change in https://github.com/triton-lang/triton/pull/2293
from torch._utils_internal import max_clock_rate
sm_clock = max_clock_rate()
if dtype in (torch.float16, torch.bfloat16) and SM80OrLater:
return get_max_tensorcore_tflops(dtype, sm_clock)
if torch.backends.cuda.matmul.allow_tf32:
return get_max_tensorcore_tflops(torch.float32, sm_clock)
else:
return get_max_simd_tflops(torch.float32, sm_clock)
else:
if dtype in (torch.float16, torch.bfloat16) and SM80OrLater:
return get_max_tensorcore_tflops(dtype)
if torch.backends.cuda.matmul.allow_tf32:
return get_max_tensorcore_tflops(torch.float32)
else:
return get_max_simd_tflops(torch.float32)
@functools.cache
def get_gpu_dram_gbps() -> int:
from triton.testing import get_dram_gbps
return get_dram_gbps()
def get_gpu_shared_memory() -> int:
from triton.runtime import driver
return driver.active.utils.get_device_properties(0).get("max_shared_mem", 0)
def is_welford_reduction(reduction_type: str) -> bool:
return reduction_type.startswith("welford")
def reduction_num_outputs(reduction_type: str) -> int:
if is_welford_reduction(reduction_type):
return 3
elif reduction_type == "online_softmax_reduce":
return 2
else:
return 1
def is_linux() -> bool:
return platform.system() == "Linux"
def is_windows() -> bool:
return sys.platform == "win32"
def has_free_symbols(itr: Iterable[Any]) -> bool:
return any(isinstance(x, sympy.Expr) and not x.is_number for x in itr)
def is_dynamic(*args: Any) -> bool:
from . import ir
for t in args:
if isinstance(
t, (ir.TensorBox, ir.StorageBox, ir.BaseView, ir.ComputedBuffer, ir.Buffer)
):
if has_free_symbols(t.maybe_get_size() or ()) or has_free_symbols(
t.maybe_get_stride() or ()
):
return True
elif not isinstance(t, ir.IRNode):
continue
else:
raise TypeError(f"unexpected type for is_dynamic {type(t)}")
return False
# Placeholder strings used in triton codegen.
class Placeholder(enum.Enum):
# The placeholder for the actual name of a triton kernel.
# e.g. for "def triton_" it would be "triton_"
KERNEL_NAME = "KERNEL_NAME"
# The descriptive name of the triton kernel; when unique_kernel_names = False, this
# placeholder will be replaced with a string with more information.
DESCRIPTIVE_NAME = "DESCRIPTIVE_NAME"
def pass_execution_and_save(
func: Callable[..., Any], gm: GraphModule, inp: Sequence[Any], msg: str
) -> None:
from .pattern_matcher import stable_topological_sort
with tempfile.NamedTemporaryFile(
mode="w",
encoding="utf-8",
delete=False,
) as f:
before_io = io.StringIO()
after_io = io.StringIO()
ShapeProp(gm=gm, fake_mode=detect_fake_mode(inp)).propagate(*inp)
print(f"Before:\n{gm.graph}", file=f)
print(gm.graph, file=before_io)
start_time = datetime.now()
with GraphTransformObserver(gm, msg):
func(gm.graph)
time_elapsed = datetime.now() - start_time
# recompile graph
stable_topological_sort(gm.graph)
gm.graph.lint()
gm.recompile()
print(f"After:\n{gm.graph}", file=f)
print(gm.graph, file=after_io)
t = before_io.getvalue() == after_io.getvalue()
log.info(
"%s, save before/after graph to %s, graph before/after are the same = %s, time elapsed = %s",
msg,
f.name,
t,
time_elapsed,
)
def is_multi_outputs_template(input_buf: Optional[Union[Buffer, Operation]]) -> bool:
"""
Check if input buffer is a multi-outputs template buffer
"""
from . import ir
return isinstance(input_buf, ir.CppTemplateBuffer) and isinstance(
input_buf.layout, ir.MultiOutputLayout
)
def is_output_of_multi_outputs_template(
input_buf: Optional[Union[Buffer, Operation]],
) -> bool:
"""
Check if input buffer is a output of multi-outputs template buffer
"""
from . import ir
return (
isinstance(input_buf, ir.MultiOutput)
and len(input_buf.inputs) == 1
and is_multi_outputs_template(input_buf.inputs[0]) # type: ignore[arg-type]
)
def is_collective(
node: Optional[Union[Node, Operation]],
op: Optional[torch._ops.OperatorBase] = None,
) -> bool:
if node is None:
return False
from . import ir
return (
isinstance(node, ir._CollectiveKernel)
and not isinstance(node, ir._WaitKernel)
and (op is None or node.op_overload is op)
) or (
# TODO: this is a temporary solution to ensure that we can identify torchrec's
# communication ops. But in order to allow better communication and computation
# overlap, torchrec's communication ops should be not used.
type(node) == ir.FallbackKernel
and (
# NOTE: the `hasattr()` check is to bypass errors such as the following:
# AttributeError: '_OpNamespace' 'torchrec' object has no attribute 'all_to_all_single'
(
hasattr(torch.ops.torchrec, "all_to_all_single")
and node.op_overload == torch.ops.torchrec.all_to_all_single.default
)
or (
hasattr(torch.ops.torchrec, "all_gather_into_tensor")
and node.op_overload
== torch.ops.torchrec.all_gather_into_tensor.default
)
or (
hasattr(torch.ops.torchrec, "reduce_scatter_tensor")
and node.op_overload == torch.ops.torchrec.reduce_scatter_tensor.default
)
)
)
def is_wait(node: Optional[Union[IRNode, Operation]]) -> bool:
from . import ir
return type(node) == ir._WaitKernel
def contains_collective(snode: BaseSchedulerNode) -> bool:
from torch._inductor.scheduler import GroupedSchedulerNode
if isinstance(snode, GroupedSchedulerNode):
return any(contains_collective(x) for x in snode.snodes)
return is_collective(snode.node)
def contains_wait(snode: BaseSchedulerNode) -> bool:
from torch._inductor.scheduler import GroupedSchedulerNode
if isinstance(snode, GroupedSchedulerNode):
return any(contains_wait(x) for x in snode.snodes)
else:
return is_wait(snode.node)
def is_fallback_op(
node: Optional[Operation],
op: Union[torch._ops.OpOverload, Collection[torch._ops.OpOverload]],
) -> bool:
from . import ir
if isinstance(op, torch._ops.OpOverload):
op = [op]
return isinstance(node, ir.FallbackKernel) and node.op_overload in op
def buf_name_to_fused_snode(
buf_name: str, name_to_buf: dict[str, Any], name_to_fused_node: dict[str, Any]
) -> Any:
return name_to_fused_node[name_to_buf[buf_name].defining_op.get_name()]
def find_recursive_deps_of_node(
snode: BaseSchedulerNode,
collected_node_set: MutableSet[BaseSchedulerNode],
name_to_buf: dict[str, SchedulerBuffer],
name_to_fused_node: dict[str, BaseSchedulerNode],
criteria_cb: Callable[[Any], bool] = lambda snode: False,
) -> None:
if criteria_cb(snode):
return
collected_node_set.add(snode)
for dep in snode.unmet_dependencies:
defining_op_for_dep = buf_name_to_fused_snode(
dep.name, name_to_buf, name_to_fused_node
)
if defining_op_for_dep in collected_node_set:
continue
find_recursive_deps_of_node(
defining_op_for_dep,
collected_node_set,
name_to_buf,
name_to_fused_node,
criteria_cb=criteria_cb,
)
def find_recursive_users_of_node(
snode: BaseSchedulerNode,
collected_node_set: MutableSet[BaseSchedulerNode],
name_to_buf: dict[str, SchedulerBuffer],
name_to_fused_node: dict[str, BaseSchedulerNode],
criteria_cb: Callable[[Any], bool] = lambda snode: False,
) -> None:
if criteria_cb(snode):
return
collected_node_set.add(snode)
for o in snode.get_outputs():
for user in o.users:
assert user.node is not None
if user.node.get_name() == "OUTPUT":
continue
if user.node.get_name() not in name_to_fused_node:
continue
user_op = name_to_fused_node[user.node.get_name()]
if user_op in collected_node_set:
continue
find_recursive_users_of_node(
user_op,
collected_node_set,
name_to_buf,
name_to_fused_node,
criteria_cb=criteria_cb,
)
def num_fw_fixed_arguments(dynamo_gm_num_inputs: int, aot_fw_gm_num_inputs: int) -> int:
"Computes the number of inputs to the aot fw graph which have fixed addresses (params and buffers)"
num_rng_seed_offset_inputs = (
2 if torch._functorch.config.functionalize_rng_ops else 0
)
# AOT won't lift any parameters if we're inlining NN Modules
# however desugaring subclasses will still add arguments
# resulted in extra fixed inputs https://github.com/pytorch/pytorch/issues/130502
return aot_fw_gm_num_inputs - dynamo_gm_num_inputs - num_rng_seed_offset_inputs
def count_tangents(fx_g: torch.fx.GraphModule) -> int:
"""
Infers which inputs are static for a backwards graph
"""
def is_saved_tensor(x: Node) -> bool:
return (
"tangents" not in x.name
and "bwd_seed" not in x.name
and "bwd_base_offset" not in x.name
and "bwd_rng_state" not in x.name
)
arg_count = 0
static_arg_idxs = []
for n in fx_g.graph.nodes:
if n.op == "placeholder":
if is_saved_tensor(n):
static_arg_idxs.append(arg_count)
arg_count += 1
assert static_arg_idxs == list(range(len(static_arg_idxs)))
return len(static_arg_idxs)
@dataclasses.dataclass
class BoxedBool:
value: bool
def __bool__(self) -> bool:
return self.value
@staticmethod
def disable(obj: Any) -> Union[BoxedBool, bool]:
if isinstance(obj, BoxedBool):
obj.value = False
return obj
return False
@contextlib.contextmanager
def collect_defined_kernels(kernel_list: list[str]) -> Iterator[None]:
from .codegen.wrapper import PythonWrapperCodegen
orig_define_kernel = PythonWrapperCodegen.define_kernel
def define_kernel(
self: PythonWrapperCodegen,
kernel_name: str,
kernel_code: str,
metadata: Optional[str] = None,
gpu: bool = True,
cpp_definition: Optional[str] = None,
) -> Any:
kernel_list.append(kernel_code)
return orig_define_kernel(
self, kernel_name, kernel_code, metadata, gpu, cpp_definition
)
with mock.patch.object(PythonWrapperCodegen, "define_kernel", define_kernel):
yield
def get_cloned_parameter_buffer_name(name: str) -> str:
return name + "__original__"
def is_gpu(device: Optional[str]) -> bool:
return device in GPU_TYPES
def device_need_guard(device: str) -> bool:
return device != "mps" and is_gpu(device) # TODO: MPS does not expose streams now
def needs_fallback_due_to_atomic_add_limitations(dtype: torch.dtype) -> bool:
# tl.atomic add has bfloat16 support in fbcode
# but not in OSS https://github.com/pytorch/pytorch/issues/97016
# we will fallback until the code is upstreamed to OSS
if (
config.is_fbcode()
and dtype == torch.bfloat16
and torch.cuda.is_available()
and torch.cuda.get_device_capability() >= (9, 0)
and config.bfloat16_atomic_adds_enabled
):
return False
else:
return dtype in OrderedSet([torch.int64, torch.bool, torch.bfloat16])
def use_scatter_fallback(
op_overload: torch._ops.OpOverload,
reduction_type: Optional[str],
self_dtype: torch.dtype,
src_dtype: torch.dtype,
src_device_type: str,
src_is_tensor: bool,
) -> bool:
if (
op_overload.overloadpacket
in (torch.ops.aten.scatter_reduce_, torch.ops.aten.scatter_reduce)
and reduction_type is None
):
return False
reduce_ty = (
"add" if op_overload.overloadpacket == torch.ops.aten.scatter_ else "sum"
)
return (
reduction_type not in (None, reduce_ty)
or (
src_is_tensor
and is_gpu(src_device_type)
and needs_fallback_due_to_atomic_add_limitations(src_dtype)
)
or (
op_overload.overloadpacket == torch.ops.aten.scatter_reduce_
and reduction_type == "sum"
and src_is_tensor
and src_device_type == "cpu"
and config.cpp.fallback_scatter_reduce_sum
and (config.cpp.dynamic_threads or parallel_num_threads() != 1)
)
or (reduction_type == reduce_ty and self_dtype in (torch.bool, torch.int64))
or torch.are_deterministic_algorithms_enabled()
)
def dump_node_schedule(node_schedule: Sequence[BaseSchedulerNode]) -> None:
"""
An API that can be used in pdb to dump a node_schedule.
Right mainly dump the read/write dependencies but can add more as needed.
"""
from torch._inductor.codegen.simd import DisableReduction, EnableReduction
from torch._inductor.scheduler import SchedulerNode
print(f"Node schedule with {len(node_schedule)} nodes")
for idx, node in enumerate(node_schedule):
print(f" {idx:3}:")
if node is EnableReduction:
print("enable reduction")
elif node is DisableReduction:
print("disable reduction")
elif isinstance(node, SchedulerNode):
is_red = node.is_reduction()
print(f"{'red' if is_red else 'pw'} scheduler node")
if is_red:
assert node.node is not None
print(f"original reduction hint {node.node.data.reduction_hint}") # type: ignore[attr-defined]
print("ReadDep:")
for dep in node.read_writes.reads:
print(dep)
print("WriteDep:")
for dep in node.read_writes.writes:
print(dep)
else:
raise RuntimeError(f"Unrecognized node type: {type(node)}")
def tensor_is_aligned(tensor: torch.Tensor) -> bool:
# See Note: [Input Alignment handling in Inductor]
# Right now, we don't try to guard on the alignment of the storage offset.
# When this comment was written, non-symbolic storage_offsets are not guarded on
# but symbolic storage_offsets are. For consistency, we suppress guard creation
# upon performing this check: that ensures that we don't add recompiles when we
# add this logic.
from torch.fx.experimental.symbolic_shapes import statically_known_true
return statically_known_true(
(tensor.storage_offset() * get_dtype_size(tensor.dtype)) % GPU_ALIGN_BYTES == 0
)
def should_assume_input_aligned(example_input: torch.Tensor) -> bool:
# See Note: [Input Alignment handling in Inductor]
# right now, we only care about alignment for cuda tensors.
if not is_gpu(example_input.device.type):
return False
return config.assume_aligned_inputs or tensor_is_aligned(example_input)
def maybe_get_suppress_shape_guards_ctx() -> contextlib.AbstractContextManager[None]:
# Try to get TracingContext.try_get().fake_mode.shape_env.suppress_guards()
# If it's not available, return a nullcontext.
# If we're dealing with cudagraphs, we might not have a tracing_context
tracing_context = torch._guards.TracingContext.try_get()
if not tracing_context:
return contextlib.nullcontext()
# In standalone inductor compile mode, we might not have a shape_env attached to the fake mode
if not tracing_context.fake_mode or not tracing_context.fake_mode.shape_env:
return contextlib.nullcontext()
shape_env = tracing_context.fake_mode.shape_env
return shape_env.suppress_guards()
def run_and_get_cpp_code(
fn: Callable[P, _T], *args: P.args, **kwargs: P.kwargs
) -> tuple[_T, str]:
# We use the patch context manager instead of using it as a decorator.
# In this way, we can ensure that the attribute is patched and unpatched correctly
# even if this run_and_get_cpp_code function is called multiple times.
with unittest.mock.patch.object(config, "debug", True):
torch._dynamo.reset()
import io
import logging
log_capture_string = io.StringIO()
ch = logging.StreamHandler(log_capture_string)
from torch._inductor.codecache import output_code_log
output_code_log.addHandler(ch)
prev_level = output_code_log.level
output_code_log.setLevel(logging.DEBUG)
result = fn(*args, **kwargs)
s = log_capture_string.getvalue()
output_code_log.setLevel(prev_level)
output_code_log.removeHandler(ch)
return result, s
def shape_env_from_inputs(inputs: Sequence[InputType]) -> Optional[ShapeEnv]:
fake_mode = detect_fake_mode(inputs)
# TODO(voz): It would be nice to enable this assert, but there are lots of tests that
# pass in real inputs for now.
# if len(inputs) > 0:
# assert fake_mode is not None, breakpoint()
if fake_mode is not None:
return fake_mode.shape_env
# When there are no tensor inputs, get shape_env from the first SymInt.
for input in inputs:
if isinstance(input, torch.SymInt):
return input.node.shape_env
# TODO(voz): Should we always have one anyway?
return None
def align_inputs_from_check_idxs(
model: Callable[[list[InputType]], _T],
inputs_to_check: Sequence[int],
mutated_input_idxs: OrderedSet[int],
) -> Callable[[list[InputType]], _T]:
if len(inputs_to_check) == 0:
return model
def run(new_inputs: list[InputType]) -> Any:
old_tensors, new_tensors = copy_misaligned_inputs(
new_inputs, inputs_to_check, mutated_input_idxs
)
out = model(new_inputs)
# If a mutated tensor was cloned to be aligned, we need to reflect back the mutation to the
# original tensor.
if len(old_tensors):
torch._foreach_copy_(old_tensors, new_tensors)
return out
return run
def clone_preserve_strides(x: torch.Tensor) -> torch.Tensor:
if 0 in x.size():
# Short-circuits if the shape has no elements
needed_size = 0
else:
needed_size = (
sum((shape - 1) * stride for shape, stride in zip(x.size(), x.stride())) + 1
)
buffer = torch.as_strided(x, (needed_size,), (1,)).clone()
return torch.as_strided(buffer, x.size(), x.stride())
def copy_misaligned_inputs(
new_inputs: list[InputType],
check_inputs_idxs: Sequence[int],
return_pair_idxs: Optional[OrderedSet[int]] = None,
) -> tuple[list[torch.Tensor], list[torch.Tensor]]:
"""
Clones misaligned tensors which we inferred were aligned. Returns a tuple of [old_tensors], [new_tensors] for every
cloned tensor which is in `return_pair_idxs`.
"""
old_tensors: list[torch.Tensor] = []
new_tensors: list[torch.Tensor] = []
# hoist above loop because this is on the hot path
ret_pair_defined = return_pair_idxs is not None
for i in check_inputs_idxs:
_inp = new_inputs[i]
assert isinstance(_inp, torch.Tensor), (
f"Expected tensors only, but got: {type(_inp)}"
)
if _inp.data_ptr() % ALIGNMENT:
new_inputs[i] = clone_preserve_strides(_inp)
if ret_pair_defined and i in return_pair_idxs: # type: ignore[operator]
old_tensors.append(_inp)
new_tensors.append(new_inputs[i]) # type: ignore[arg-type]
return old_tensors, new_tensors
def remove_unaligned_input_idxs(
inputs: Sequence[InputType],
static_input_idxs: Sequence[int],
) -> Sequence[int]:
"""
We require all inputs to be aligned, so introduce a copy for any
that aren't.
"""
aligned_static_input_idxs = []
for idx in static_input_idxs:
input = inputs[idx]
if isinstance(input, torch.Tensor) and (input.data_ptr() % ALIGNMENT) == 0:
aligned_static_input_idxs.append(idx)
if len(aligned_static_input_idxs) != len(static_input_idxs):
return aligned_static_input_idxs
return static_input_idxs
def expr_fits_within_32bit(e: sympy.Expr) -> bool:
from .virtualized import V
int_max = torch.iinfo(torch.int32).max
size_hint = V.graph.sizevars.size_hint
has_hint = V.graph.sizevars.shape_env.has_hint
# Allow for unhinted e as long as we can still statically prove
# (e.g., via ValueRanges) that it is still in bounds
if V.graph.sizevars.statically_known_true(e <= int_max):
return True
# Otherwise, the hint MUST exist and be in range
return has_hint(e) and size_hint(e) <= int_max
def set_tracing_context_output_strides(
example_inputs: Sequence[Any], compiled_graph: CompiledFxGraph
) -> None:
# Return the output strides to the caller via TracingContext
context = torch._guards.TracingContext.try_get()
if context is not None and context.output_strides is not None:
assert len(context.output_strides) == 0
shape_env = shape_env_from_inputs(example_inputs)
assert compiled_graph.output_strides is not None
for exprs in compiled_graph.output_strides:
if exprs is None:
context.output_strides.append(None)
else:
fakify_first_call = False
if ctx := torch._guards.TracingContext.try_get():
fakify_first_call = ctx.fakify_first_call
def map_expr(e: Any) -> Union[float, int, SymInt, SymFloat, SymBool]:
if shape_env is None:
return int(e)
if fakify_first_call:
return shape_env.deserialize_symexpr(e)
return shape_env.evaluate_symexpr(e)
context.output_strides.append(
tuple(map_expr(e) for e in exprs) # type: ignore[misc]
)
def should_use_remote_fx_graph_cache() -> bool:
if config.fx_graph_remote_cache is not None:
return config.fx_graph_remote_cache
if not config.is_fbcode():
return False
if torch._utils_internal.is_fb_unit_test():
return False
try:
from torch._inductor.fb.remote_cache import REMOTE_CACHE_VERSION
except ModuleNotFoundError:
return False
return REMOTE_CACHE_VERSION >= torch._utils_internal.justknobs_getval_int(
"pytorch/remote_cache:fx_graph_memcache_version"
)
def normalize_name(name: str) -> str:
return re.sub(r"[^a-zA-Z0-9_]", "_", name)
# correct cases where Triton types names don't match PyTorch
_triton_type_mapping = {
"tl.bool": "tl.int1",
"tl.float8_e4m3fn": "tl.float8e4nv",
"tl.float8_e5m2": "tl.float8e5",
"tl.float8_e4m3fnuz": "tl.float8e4b8",
"tl.float8_e5m2fnuz": "tl.float8e5b16",
# TODO: remove when support is added in triton
# https://github.com/triton-lang/triton/issues/6054
"tl.float8_e8m0fnu": "tl.uint8",
"tl.float4_e2m1fn_x2": "tl.uint8",
}
_torch_triton_mapping = {v: k for k, v in _triton_type_mapping.items()}
_triton_type_re = re.compile(r"^.*[.]")
def triton_type(dtype: torch.dtype) -> str:
"""Convert torch.dtype to triton type"""
triton_type_name = _triton_type_re.sub("tl.", str(dtype))
return _triton_type_mapping.get(triton_type_name, triton_type_name)
def triton_type_to_torch(dtype: str) -> torch.dtype:
adjusted_type = _torch_triton_mapping.get(dtype, dtype)
type_name = adjusted_type.replace("tl.", "")
out_dtype = getattr(torch, type_name)
assert isinstance(out_dtype, torch.dtype)
return out_dtype
def is_same_tensor(data: torch.Tensor, value: torch.Tensor) -> bool:
return (
not data.is_mkldnn
and data.size() == value.size()
and data.stride() == value.stride()
and data.dtype == value.dtype
and data.device == value.device
and data.untyped_storage().data_ptr() == value.untyped_storage().data_ptr()
and data.storage_offset() == value.storage_offset()
)
def is_same_mkldnn_tensor(data: torch.Tensor, value: torch.Tensor) -> bool:
return (
data.is_mkldnn
and data.size() == value.size()
and data.dtype == value.dtype
and data.device == value.device
and torch.ops.mkldnn.data_ptr(data) == torch.ops.mkldnn.data_ptr(value)
)
@functools.cache
def boolean_ops() -> tuple[str, ...]:
return (
"isinf",
"isnan",
"logical_not",
"logical_and",
"signbit",
"and_",
"le",
"lt",
"ge",
"gt",
"eq",
"ne",
"or_", # TODO should remove this op
"xor",
)
@dataclasses.dataclass
class OpDtypeRule:
type_promotion_kind: ELEMENTWISE_TYPE_PROMOTION_KIND
override_return_dtype: Optional[torch.dtype]
op_dtype_propagation_rules: dict[str, OpDtypeRule] = {}
def register_op_dtype_propagation_rules(
name: str,
type_promotion_kind: ELEMENTWISE_TYPE_PROMOTION_KIND,
override_return_dtype: Optional[torch.dtype],
) -> None:
op_dtype_propagation_rules[name] = OpDtypeRule(
type_promotion_kind, override_return_dtype
)
op_requires_libdevice_fp64: OrderedSet[str] = OrderedSet()
def register_op_requires_libdevice_fp64(name: str) -> None:
op_requires_libdevice_fp64.add(name)
def get_current_backend() -> str:
from torch._inductor.virtualized import V
device_str = V.graph.get_current_device_or_throw().type
if device_str == "cpu":
return config.cpu_backend
elif device_str == "mps":
return "mps"
else:
return config.cuda_backend
def upcast_compute_type(dtype: torch.dtype) -> torch.dtype:
"""Maybe upcast [b]float16 to float32"""
if (
dtype in (torch.float16, torch.bfloat16)
and config.triton.codegen_upcast_to_fp32
and get_current_backend() == "triton"
):
return torch.float32
return dtype
KeyType = TypeVar("KeyType")
ValType = TypeVar("ValType")
class ScopedDict(MutableMapping[KeyType, ValType]):
"""
A dictionary-like object that allows for scoped updates. It maintains
an original dictionary and a set of new items that can override
the original items within the scope. The original dictionary is
unmodified.
"""
def __init__(self, original_dict: Mapping[KeyType, ValType]):
self.original_dict = original_dict
self.new_items: dict[KeyType, ValType] = {}
def __getitem__(self, key: KeyType) -> ValType:
if key in self.new_items:
return self.new_items[key]
return self.original_dict[key]
def __setitem__(self, key: KeyType, value: ValType) -> None:
self.new_items[key] = value
def __contains__(self, key: object) -> bool:
return key in self.new_items or key in self.original_dict
def get(self, key: KeyType, default: Optional[ValType] = None) -> Optional[ValType]: # type: ignore[override]
if key in self.new_items:
return self.new_items[key]
return self.original_dict.get(key, default)
def __len__(self) -> int:
n = len(self.original_dict)
for k in self.new_items:
if k not in self.original_dict:
n += 1
return n
def __iter__(self) -> Iterator[KeyType]:
yield from self.original_dict
for k in self.new_items:
if k not in self.original_dict:
yield k
def __bool__(self) -> bool:
return bool(self.original_dict or self.new_items)
def __delitem__(self, key: KeyType) -> None:
raise NotImplementedError
@dataclass_transform(frozen_default=True)
def ir_dataclass(cls: Optional[type[Any]] = None, /, *, frozen: bool = True) -> Any:
def wrap(cls: _T) -> _T:
if sys.version_info >= (3, 10):
return dataclasses.dataclass(cls, kw_only=True, frozen=frozen) # type: ignore[call-overload]
else:
# Polyfill for python=3.9. kw_only simply introduces an extra check
# that only kwargs are used (and is not available on 3.9)
return dataclasses.dataclass(cls, frozen=frozen)
if cls is None:
return wrap
return wrap(cls)
def get_donated_idxs() -> Optional[list[int]]:
tracing_context = torch._guards.TracingContext.try_get()
if tracing_context is not None and tracing_context.fw_metadata:
return tracing_context.fw_metadata.bw_donated_idxs
return None
class TritonAttrsDescriptorVersion(enum.Enum):
V0_NO_TRITON = 0
V1_COMPILER = 1 # triton.compiler.compiler.AttrsDescriptor
V2_BACKENDS = 2 # triton.backends.compiler.AttrsDescriptor
V3_BACKENDS_TUPLE = (
3 # triton.backends.compiler.AttrsDescriptor, but with tuple support
)
V4_DICT = 4 # a raw dict
@functools.cache
def get_triton_attrs_descriptor_version() -> TritonAttrsDescriptorVersion:
if importlib.util.find_spec("triton") is None:
return TritonAttrsDescriptorVersion.V0_NO_TRITON
import triton.backends.compiler
import triton.compiler.compiler
if hasattr(triton.backends.compiler, "AttrsDescriptor"):
# Triton 3.2.0
# AttrsDescriptor was moved from triton.compiler.compiler to triton.backends.compiler.
# AttrsDescriptor and its serialization format were also changed.
# TODO: implement V3_BACKENDS_TUPLE
# On Dec 9, 2024, tuple support (triton #5220) was implemented and breaks handling.
# We don't have a way to detect this (and haven't implemented this version)
return TritonAttrsDescriptorVersion.V2_BACKENDS
elif hasattr(triton.compiler.compiler, "AttrsDescriptor"):
# Triton 3.0.0
return TritonAttrsDescriptorVersion.V1_COMPILER
else:
# After Jan 1, 2025
# AttrsDescriptor was removed and replaced with a raw dict.
return TritonAttrsDescriptorVersion.V4_DICT
def triton_version_uses_attrs_dict() -> bool:
return get_triton_attrs_descriptor_version() == TritonAttrsDescriptorVersion.V4_DICT
def is_cudagraph_unsafe_op(node: Operation) -> bool:
"""
Returns True if the node is an op that is not cudagraphable.
Usually only custom ops have this tag.
"""
from . import ir
if not isinstance(node, ir.FallbackKernel):
return False
if (
isinstance(node.op_overload, torch._ops.OpOverload)
and torch._C.Tag.cudagraph_unsafe in node.op_overload.tags # type: ignore[attr-defined]
):
return True
return False
def get_ld_library_path() -> str:
path = os.environ.get("LD_LIBRARY_PATH", "")
if config.is_fbcode():
from libfb.py.parutil import get_runtime_path
runtime_path = get_runtime_path()
if runtime_path:
lib_path = os.path.join(runtime_path, "runtime", "lib")
path = os.pathsep.join([lib_path, path]) if path else lib_path
return path
def is_codegen_graph_partition_subgraph(wrapper: PythonWrapperCodegen) -> bool:
from torch._inductor.codegen.wrapper import SubgraphPythonWrapperCodegen
return (
isinstance(wrapper, SubgraphPythonWrapperCodegen)
and wrapper.partition_signatures is not None
)
def dtype_from_size(size: int) -> torch.dtype:
from .virtualized import V
if V.graph.sizevars.statically_known_lt(
size, 2**31
) and V.graph.sizevars.statically_known_geq(size, -(2**31)):
return torch.int32
else:
return torch.int64
SUPPORTED_MKLDNN_DEVICES = ("cpu", "xpu")
def is_mkldnn_bf16_supported(device_type: str) -> bool:
"""
Returns True if the device supports MKL-DNN BF16.
"""
if device_type == "cpu":
return torch.ops.mkldnn._is_mkldnn_bf16_supported()
elif "xpu" in device_type:
# match "xpu", "xpu:0", "xpu:1", etc.
return True
return False
def is_mkldnn_fp16_supported(device_type: str) -> bool:
"""
Returns True if the device supports MKL-DNN FP16.
"""
if device_type == "cpu":
return torch.ops.mkldnn._is_mkldnn_fp16_supported()
elif "xpu" in device_type:
# match "xpu", "xpu:0", "xpu:1", etc.
return True
return False
def tabulate_2d(elements: Sequence[Sequence[T]], headers: Sequence[T]) -> str:
widths = [len(str(e)) for e in headers]
for row in elements:
assert len(row) == len(headers)
for i, e in enumerate(row):
widths[i] = max(widths[i], len(str(e)))
lines = []
# Need nested {} for string formatting; ignore SET_LINTER here
lines.append("|".join(f" {h:{w}} " for h, w in zip(headers, widths))) # noqa: set_linter
# widths whitespace horizontal separators
total_width = sum(widths) + (len(widths) * 2) + (len(widths) - 1)
lines.append("-" * total_width)
for row in elements:
lines.append("|".join(f" {e:{w}} " for e, w in zip(row, widths))) # noqa: set_linter
return "\n".join(lines)
def zip_dicts(
dict1: Mapping[KeyType, ValType],
dict2: Mapping[KeyType, ValType],
d1_default: ValType | None = None,
d2_default: ValType | None = None,
) -> Generator[tuple[KeyType, ValType | None, ValType | None], None, None]:
"""
Zip two dictionaries together, replacing missing keys with default values.
Args:
dict1 (dict): The first dictionary.
dict2 (dict): The second dictionary.
d1_default (Any): the default value for the first dictionary
d2_default (Any): the default value for the second dictionary
Yields:
tuple: A tuple containing the key, the value from dict1 (or d1_default if missing),
and the value from dict2 (or d2_default if missing).
"""
# Find the union of all keys
all_keys = OrderedSet(dict1.keys()) | OrderedSet(dict2.keys())
# Iterate over all keys
for key in all_keys:
# Get the values from both dictionaries, or default if missing
value1 = dict1.get(key)
value2 = dict2.get(key)
yield (
key,
value1 if value1 is not None else d1_default,
value2 if value2 is not None else d2_default,
)
def maybe_aoti_standalone_config(config_patches: dict[str, Any]) -> dict[str, Any]:
"""
Ensures the configuration is internally consistent for standalone AOTInductor.
If `aot_inductor.compile_standalone` is set to True in the provided
`config_patches` (or falls back to the global config), this function ensures
that the following configs are also enabled:
- `aot_inductor.package_cpp_only`
Args:
config_patches (dict[str, Any]): A dictionary of user-provided config
overrides for AOTInductor compilation.
Returns:
dict[str, Any]: The possibly-updated `config_patches` dictionary.
"""
compile_standalone = config_patches.get(
"aot_inductor.compile_standalone", config.aot_inductor.compile_standalone
)
if compile_standalone:
package_cpp_only = config_patches.get(
"aot_inductor.package_cpp_only", config.aot_inductor.package_cpp_only
)
if package_cpp_only is None:
config_patches = {**config_patches, "aot_inductor.package_cpp_only": True}
elif not package_cpp_only:
raise RuntimeError(
"compile_standalone=True requires package_cpp_only=True. "
"Please set aot_inductor.package_cpp_only=True in your inductor config."
)
return config_patches
def is_valid_aoti_model_name() -> bool:
"""
Validates if a model name is suitable for use in code generation.
"""
from torch._inductor import config
model_name = config.aot_inductor.model_name_for_generated_files
if model_name is None:
return True
if not isinstance(model_name, str):
raise ValueError("Invalid AOTI model name: Model name must be a string")
if model_name == "":
return True
# Can only contain alphanumeric characters and underscores
if not re.match(r"^[a-zA-Z_][a-zA-Z0-9_]*$", model_name):
raise ValueError(
"Invalid AOTI model name: Model name can only contain letters, numbers, and underscores"
)
return True
def aoti_model_name_from_config() -> str:
from torch._inductor import config
model_name = config.aot_inductor.model_name_for_generated_files
model_name = "aoti_model" if model_name is None else model_name
return model_name
def get_free_symbols(x: IterateExprs, unbacked_only: bool) -> OrderedSet[sympy.Symbol]:
if unbacked_only:
return free_unbacked_symbols(x)
else:
return free_symbols(x)
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