Traktor/myenv/Lib/site-packages/torch/jit/frontend.py

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2024-05-23 01:57:24 +02:00
import ast
import dataclasses
import inspect
import re
import string
import sys
from collections import namedtuple
from textwrap import dedent
from typing import List, Tuple # noqa: F401
import torch
import torch.jit.annotations
from torch import _jit_internal
from torch._C._jit_tree_views import (
Apply,
Assert,
Assign,
Attribute,
AugAssign,
BinOp,
Break,
ClassDef,
Const,
Continue,
Decl,
Def,
Delete,
DictComp,
DictLiteral,
Dots,
EmptyTypeAnnotation,
ExprStmt,
FalseLiteral,
For,
Ident,
If,
ListComp,
ListLiteral,
NoneLiteral,
Param,
Pass,
Property,
Raise,
Return,
Select,
SliceExpr,
Starred,
Stmt,
StringLiteral,
Subscript,
TernaryIf,
TrueLiteral,
TupleLiteral,
UnaryOp,
Var,
While,
With,
WithItem,
)
from torch._jit_internal import ( # noqa: F401
_is_drop_fn,
FunctionModifiers,
is_static_fn,
should_drop,
)
from torch._sources import (
get_source_lines_and_file,
make_source_context,
parse_def,
ParsedDef as _ParsedDef,
)
from torch.jit._dataclass_impls import DATACLASS_MAGIC_METHODS
from torch.jit._monkeytype_config import get_qualified_name, monkeytype_trace
_IS_ASTUNPARSE_INSTALLED = False
try:
import astunparse # type: ignore[import]
_IS_ASTUNPARSE_INSTALLED = True
except ImportError:
pass
# Borrowed from cPython implementation
# https://github.com/python/cpython/blob/561612d8456cfab5672c9b445521113b847bd6b3/Lib/textwrap.py#L411#
_reserved_prefix = "__jit"
_reserved_names = {"print"}
_identifier_chars = set(string.ascii_lowercase + string.ascii_uppercase + string.digits)
def is_reserved_name(name):
return name.startswith(_reserved_prefix) or name in _reserved_names
pretty_node_names = {
ast.FunctionDef: "function definitions",
ast.For: "for loops",
ast.Delete: "del statements",
ast.ClassDef: "class definitions",
ast.With: "with statements",
ast.Raise: "raise statements",
ast.Assert: "assertions",
ast.Import: "import statements",
ast.ImportFrom: "import statements",
ast.Global: "global variables",
ast.Break: "break statements",
ast.Continue: "continue statements",
}
node_start_tokens = {
ast.FunctionDef: "def",
ast.For: "for",
ast.Delete: "del",
ast.ClassDef: "class",
ast.With: "with",
ast.Raise: "raise",
ast.Assert: "assert",
ast.Import: "import",
ast.ImportFrom: "from",
ast.Global: "global",
ast.Break: "break",
ast.Continue: "continue",
}
pretty_node_names.update(
{
ast.AsyncFunctionDef: "async function definitions",
ast.AsyncFor: "async for loops",
ast.AsyncWith: "async with statements",
ast.Try: "try blocks",
ast.Nonlocal: "nonlocal variables",
}
)
node_start_tokens.update(
{
ast.AsyncFunctionDef: "async def",
ast.AsyncFor: "async for",
ast.AsyncWith: "async with",
ast.Try: "try",
ast.Nonlocal: "nonlocal",
}
)
pretty_node_names.update(
{
ast.AnnAssign: "annotated assignments",
}
)
# NB: no specific token for AnnAssign
class FrontendError(Exception):
def __init__(self, source_range, msg):
self.source_range = source_range
self.msg = msg
# This has to be instantiated here so the ErrorReport is accurate to the
# call stack when the FrontendError was raised
self.error_report = torch._C.ErrorReport(self.source_range)
def __str__(self):
return self.msg + self.error_report.what().lstrip()
class NotSupportedError(FrontendError):
pass
class UnsupportedNodeError(NotSupportedError):
def __init__(self, ctx, offending_node, reason=""):
# If we don't have a specific token, we default to length of 1
node_type = type(offending_node)
range_len = len(node_start_tokens.get(node_type, " "))
source_range = ctx.make_range(
offending_node.lineno,
offending_node.col_offset,
offending_node.col_offset + range_len,
)
feature_name = pretty_node_names.get(node_type, node_type.__name__)
msg = f"{feature_name} {reason + ' ' if reason else ''}aren't supported"
super().__init__(source_range, msg)
class FrontendTypeError(FrontendError):
pass
def build_withitems(ctx, items):
items = [build_withitem(ctx, i) for i in items]
return list(items)
def build_stmts(ctx, stmts):
stmts = [build_stmt(ctx, s) for s in stmts]
return list(filter(None, stmts))
def get_class_properties(cls, self_name):
"""
Get a list of Property objects representing the properties of a class.
Args:
cls: The class to get properties of.
self_name: The name of the class that the properties should belong to.
Returns:
A list of Property objects corresponding to the properties of cls. Property
here refers to the subclass of TreeView.
"""
props = inspect.getmembers(cls, predicate=lambda m: isinstance(m, property))
# Any property that should not compiled must be in this list on the Module.
unused_properties = getattr(cls, "__jit_unused_properties__", [])
# Create Property TreeView objects from inspected property objects.
properties = []
for prop in props:
if prop[0] not in unused_properties and not should_drop(prop[1].fget):
getter = get_jit_def(
prop[1].fget, f"__{prop[0]}_getter", self_name=self_name
)
setter = (
get_jit_def(prop[1].fset, f"__{prop[0]}_setter", self_name=self_name)
if prop[1].fset
else None
)
properties.append(
Property(getter.range(), Ident(getter.range(), prop[0]), getter, setter)
)
return properties
def get_class_assigns(ctx, cls_ast):
assigns = []
def maybe_build_assign(builder, entry):
nonlocal assigns
try:
assigns.append(builder(ctx, entry))
except NotSupportedError:
pass
for entry in cls_ast.body:
if isinstance(entry, ast.Assign):
maybe_build_assign(StmtBuilder.build_Assign, entry)
elif isinstance(entry, ast.AnnAssign):
maybe_build_assign(StmtBuilder.build_AnnAssign, entry)
return assigns
def get_jit_class_def(cls, self_name):
# Get defs for each method within the current class independently
# TODO: proper overriding analysis when implementing class inheritance
methods = inspect.getmembers(
cls,
predicate=lambda m: (inspect.ismethod(m) or inspect.isfunction(m))
and not is_static_fn(cls, m.__name__)
and m.__name__ in cls.__dict__
and not _is_drop_fn(m),
)
def is_classmethod(fn):
return inspect.ismethod(fn) and getattr(fn, "__self__", None) == cls
# Get and parse the source code for this class
sourcelines, file_lineno, filename = get_source_lines_and_file(
cls, torch._C.ErrorReport.call_stack()
)
source = "".join(sourcelines)
dedent_src = dedent(source)
py_ast = ast.parse(dedent_src)
class_ast = py_ast.body[0]
assert isinstance(class_ast, ast.ClassDef)
# Special case for dataclasses. In general we need access to the source code for
# an object in order to JIT compile it. But the dataclasses module dynamically synthesizes
# magic methods for classes, and we can't get the source code for these methods. As a
# workaround, we synthesize TorchScript-friendly implementations ourselves.
if dataclasses.is_dataclass(cls):
# Detect whether the user manually implemented any of the magic methods. If they did,
# we don't want to synthesize/override them.
overrides = {
method.name
for method in class_ast.body
if isinstance(method, ast.FunctionDef)
and method.name in DATACLASS_MAGIC_METHODS
}
for i, (name, _) in enumerate(methods):
# Is this a magic method we can synthesize?
synthesizer_fn = DATACLASS_MAGIC_METHODS.get(name)
if synthesizer_fn and name not in overrides:
parsed_def = synthesizer_fn(cls)
methods[i] = name, parsed_def
func = getattr(cls, name)
_jit_internal.loader.cache(func, parsed_def.source)
method_defs = [
get_jit_def(obj, name, self_name=self_name, is_classmethod=is_classmethod(obj))
for (name, obj) in methods
]
properties = get_class_properties(cls, self_name)
leading_whitespace_len = len(source.split("\n", 1)[0]) - len(
dedent_src.split("\n", 1)[0]
)
ctx = make_source_context(
source, filename, file_lineno, leading_whitespace_len, False
)
assigns = get_class_assigns(ctx, class_ast)
return build_class_def(ctx, class_ast, method_defs, properties, self_name, assigns)
def get_jit_def(fn, def_name, self_name=None, is_classmethod=False):
"""
Build a JIT AST (TreeView) from the given function.
Args:
fn: A function object to compile or a pre-parsed ParsedDef object
def_name: The name to give to the resulting AST object. This is not
always the same as `fn.__name__`, for example:
def _forward(self):
...
forward = _forward
In this case, the `__name__` attribute of the function object is "_forward",
but we want the result AST to have the name "forward".
self_name: If this function is a method, what the type name of `self` is.
"""
parsed_def = parse_def(fn) if not isinstance(fn, _ParsedDef) else fn
type_line = torch.jit.annotations.get_type_line(parsed_def.source)
fn_def = parsed_def.ast.body[0]
if is_classmethod:
arg_name = fn_def.args.args[0].arg
# Insert a statement that assigns the first argument to the class
assign_stmt = ast.parse(f"{arg_name} = {self_name}").body[0]
fn_def.body.insert(0, assign_stmt)
# Swap out the function signature and body if it is unused
if should_drop(fn):
unused_fn_def = ast.parse(
'def unused_fn(self: Any):\n\traise RuntimeError("Cannot call @unused methods")'
)
if len(unused_fn_def.body) != 1 or not isinstance(
unused_fn_def.body[0], ast.FunctionDef
):
raise RuntimeError(
f"Expected a single top-level function: {parsed_def.filename}:{parsed_def.file_lineno}"
)
unused_def = unused_fn_def.body[0]
fn_def.body = unused_def.body
# kwarg/vararg not supported by `build_def`
fn_def.args.kwarg = fn_def.args.vararg = None
for arg in fn_def.args.args + fn_def.args.kwonlyargs:
# Replace potentially unsupported type annotations by "Any"
arg.annotation = unused_def.args.args[0].annotation
if _is_drop_fn(fn):
# Dropping potentially unsupported return type annotation for jit._drop
fn_def.returns = None
fn_def.type_comment = None
# If MonkeyType is installed, get all the consolidated type traces
# for the arguments from type_trace_db
type_trace_db = torch.jit._script._get_type_trace_db()
pdt_arg_types = None
if monkeytype_trace and not isinstance(fn, _ParsedDef): # type: ignore[truthy-function]
qualname = get_qualified_name(fn)
pdt_arg_types = type_trace_db.get_args_types(qualname)
return build_def(
parsed_def.ctx,
fn_def,
type_line,
def_name,
self_name=self_name,
pdt_arg_types=pdt_arg_types,
)
# TODO: more robust handling of recognizing ignore context manager
def is_torch_jit_ignore_context_manager(stmt):
# checks if the statement is torch.jit.ignore context manager
if isinstance(stmt.items[0].context_expr, ast.Call):
# extract torch part
function = stmt.items[0].context_expr.func
if isinstance(function, ast.Attribute):
attr_name = function.attr
attr_value = function.value
if attr_name == "_IgnoreContextManager" and isinstance(
attr_value, ast.Attribute
):
# there should be at most two nested attributes (e.g torch.jit._IgnoreContextManager)
if attr_value.attr == "jit" and isinstance(attr_value.value, ast.Name):
if attr_value.value.id == "torch":
return True
return False
class Builder:
def __call__(self, ctx, node):
method = getattr(self, "build_" + node.__class__.__name__, None)
if method is None:
raise UnsupportedNodeError(ctx, node)
return method(ctx, node)
def build_class_def(ctx, py_def, methods, properties, self_name, assigns):
r = ctx.make_range(
py_def.lineno, py_def.col_offset, py_def.col_offset + len("class")
)
return ClassDef(
Ident(r, self_name), [Stmt(method) for method in methods], properties, assigns
)
def build_def(ctx, py_def, type_line, def_name, self_name=None, pdt_arg_types=None):
body = py_def.body
r = ctx.make_range(py_def.lineno, py_def.col_offset, py_def.col_offset + len("def"))
param_list = build_param_list(ctx, py_def.args, self_name, pdt_arg_types)
return_type = None
if getattr(py_def, "returns", None) is not None:
return_type = build_expr(ctx, py_def.returns)
decl = Decl(r, param_list, return_type)
is_method = self_name is not None
if type_line is not None:
type_comment_decl = torch._C.parse_type_comment(type_line)
decl = torch._C.merge_type_from_type_comment(decl, type_comment_decl, is_method)
return Def(Ident(r, def_name), decl, build_stmts(ctx, body))
_vararg_kwarg_err = (
"Compiled functions can't take variable number of arguments "
"or use keyword-only arguments with defaults"
)
def build_param_list(ctx, py_args, self_name, pdt_arg_types=None):
if py_args.kwarg is not None:
expr = py_args.kwarg
ctx_range = ctx.make_range(
expr.lineno, expr.col_offset - 1, expr.col_offset + len(expr.arg)
)
raise NotSupportedError(ctx_range, _vararg_kwarg_err)
if py_args.vararg is not None:
expr = py_args.vararg
ctx_range = ctx.make_range(
expr.lineno, expr.col_offset - 1, expr.col_offset + len(expr.arg)
)
raise NotSupportedError(ctx_range, _vararg_kwarg_err)
if len(py_args.kw_defaults) > 0:
# kw_defaults is a list of the values for the kwargs (which default to None),
# so they don't actually have line numbers.
for arg in py_args.kw_defaults:
if arg is not None:
ctx_range = build_expr(ctx, arg).range()
raise NotSupportedError(ctx_range, _vararg_kwarg_err)
# List of Tuple of args and type as inferred by profile directed typing
arg_and_types = [
(
arg,
pdt_arg_types[arg.arg]
if pdt_arg_types and bool(pdt_arg_types[arg.arg])
else None,
)
for arg in py_args.args
]
arg_and_types_kwonlyargs = [
(
arg,
pdt_arg_types[arg.arg]
if pdt_arg_types and bool(pdt_arg_types[arg.arg])
else None,
)
for arg in py_args.kwonlyargs
]
result = [
build_param(ctx, arg, self_name, kwarg_only=False, pdt_arg_type=arg_type)
for arg, arg_type in arg_and_types
]
result += [
build_param(ctx, arg, self_name, kwarg_only=True, pdt_arg_type=arg_type)
for arg, arg_type in arg_and_types_kwonlyargs
]
return result
def build_param(ctx, py_arg, self_name, kwarg_only, pdt_arg_type=None):
# NB: In Python3 py_arg is a pair of (str arg, expr? annotation)
name = py_arg.arg
r = ctx.make_range(py_arg.lineno, py_arg.col_offset, py_arg.col_offset + len(name))
if getattr(py_arg, "annotation", None) is not None:
annotation_expr = build_expr(ctx, py_arg.annotation)
elif pdt_arg_type:
annotation_expr = Var(Ident(r, pdt_arg_type))
elif self_name is not None and name == "self":
annotation_expr = Var(Ident(r, self_name))
else:
annotation_expr = EmptyTypeAnnotation(r)
return Param(annotation_expr, Ident(r, name), kwarg_only)
def build_ignore_context_manager(ctx, stmt):
InputType = namedtuple("InputType", ["name", "ann"])
OutputType = namedtuple("OutputType", ["name", "ann"])
def process_ins_outs(args):
# parse the context manager to figure out inputs and outputs
# with their annotated types
# TODO: add input, output validator
inputs = []
outputs = []
for arg in args:
var_name = arg.arg
var_ann = arg.value.value
var_decl_type, var_ann = var_ann.split(":")
if var_decl_type == "inp":
inputs.append(InputType(var_name, var_ann))
if var_decl_type == "out":
outputs.append(OutputType(var_name, var_ann))
return inputs, outputs
def create_unique_name_ext(ctx, stmt):
# extension will be based on the full path filename plus
# the line number of original context manager
fn = re.sub(r"[^a-zA-Z0-9_]", "_", ctx.filename)
return f"{fn}_{stmt.lineno}"
def build_return_ann_stmt(outputs):
return_type_ann = ""
return_statement_str = "return "
if len(outputs) == 0:
return_type_ann += " -> None"
if len(outputs) == 1:
return_type_ann = " -> " + outputs[0].ann
return_statement_str += outputs[0].name
if len(outputs) > 1:
return_type_ann = " -> Tuple"
return_type_ann += "[" + ", ".join([var.ann for var in outputs]) + "]"
return_statement_str += ", ".join([var.name for var in outputs])
return return_type_ann, return_statement_str
def build_args(args):
return ", ".join([arg.name for arg in args])
inputs, outputs = process_ins_outs(stmt.items[0].context_expr.keywords)
# build the replacement function str with given inputs and outputs
ignore_function_name = "func_ignore_" + create_unique_name_ext(ctx, stmt)
ignore_function_str = "\ndef " + ignore_function_name
ignore_function_str += (
"(" + ", ".join([var.name + " :" + var.ann for var in inputs]) + ")"
)
return_ann, return_stmt = build_return_ann_stmt(outputs)
ignore_function_str += return_ann + ": pass"
# first create the functionDef object from just declaration
ignore_function = ast.parse(ignore_function_str).body[0]
# dump the body of context manager to dummy function
ignore_function.body = stmt.body # type: ignore[attr-defined]
# insert return statement to the function
return_stmt = ast.parse(return_stmt).body[0]
ignore_function.body.append(return_stmt) # type: ignore[attr-defined]
# registers the custom function in the global context
ignore_func_str = "@torch.jit.ignore\n" + astunparse.unparse(ignore_function)
ignore_func_str += f'\nglobals()["{ignore_function_name}"] = {ignore_function_name}'
exec(ignore_func_str) # noqa: P204
# build the statements as:
# <out_1>, <out_2>, ... = torch.jit.frontend.<func>(<in_1>, <in_2>)
assign_str_lhs = build_args(outputs)
# this function will be registered in torch.jit.frontend module by default
assign_str_rhs = (
f"torch.jit.frontend.{ignore_function_name}(" + build_args(inputs) + ")"
)
if len(outputs) > 0:
assign_str = assign_str_lhs + " = " + assign_str_rhs
else:
assign_str = assign_str_rhs
assign_ast = ast.parse(assign_str).body[0]
return assign_ast
def get_default_args(fn):
if fn is None:
return {}
signature = inspect.signature(fn)
return {
k: v.default
for k, v in signature.parameters.items()
if v.default is not inspect.Parameter.empty
}
def get_default_args_for_class(cls):
"""
Get default arguments for all methods in a class (except for static methods).
Args:
cls: type - The class type to inspect for default arguments.
Returns:
A Dict[str, Dict[str, Any]] which maps each method name to a Dict[str, Any]
that maps each argument name to its default value.
"""
# Get methods (except static methods because those are compiled separately as
# if they were independent script functions).
methods = inspect.getmembers(
cls,
predicate=lambda m: (inspect.ismethod(m) or inspect.isfunction(m))
and not is_static_fn(cls, m.__name__)
and m.__name__ in cls.__dict__,
)
# Get method defaults. Property defaults do not need to be considered
# because setters cannot be invoked without a value.
defaults = {
method_name: get_default_args(method_impl)
for method_name, method_impl in methods
}
return defaults
class WithItemBuilder(Builder):
@staticmethod
def build_withitem(ctx, item):
lineno = item.context_expr.lineno
start = item.context_expr.col_offset
end = start + len(pretty_node_names[ast.With])
op_vars = item.optional_vars
r = ctx.make_range(lineno, start, end)
return WithItem(
r,
build_expr(ctx, item.context_expr),
build_expr(ctx, op_vars) if op_vars else None,
)
class StmtBuilder(Builder):
augassign_map = {
ast.Add: "+",
ast.Sub: "-",
ast.Mult: "*",
ast.Div: "/",
ast.Mod: "%",
ast.BitOr: "|",
ast.BitAnd: "&",
ast.BitXor: "^",
ast.LShift: "<<",
ast.RShift: ">>",
ast.Pow: "**",
}
@staticmethod
def build_Expr(ctx, stmt):
value = stmt.value
if value.__class__.__name__ == "Str":
# If a statement is a string literal expression,
# then it is a docstring. Just ignore it.
return None
else:
return ExprStmt(build_expr(ctx, value))
@staticmethod
def build_Assign(ctx, stmt):
rhs = build_expr(ctx, stmt.value)
lhs = [build_expr(ctx, x) for x in stmt.targets]
return Assign(lhs, rhs)
@staticmethod
def build_AnnAssign(ctx, stmt):
if stmt.value is None:
raise UnsupportedNodeError(ctx, stmt, reason="without assigned value")
# Disallow type annotations on instance attributes outside of __init__
if (
type(stmt.target) == ast.Attribute
and stmt.target.value.id == "self" # type: ignore[attr-defined]
and ctx.funcname != "__init__"
):
start = stmt.col_offset
end = start + len(f"self.{stmt.target.attr}")
if hasattr(stmt.annotation, "id"):
end += len(f": {stmt.annotation.id}")
sr = ctx.make_range(stmt.lineno, start, end)
raise ValueError(
"Type annotations on instance attributes must be declared in "
f"__init__, not '{ctx.funcname}': {sr}"
)
rhs = build_expr(ctx, stmt.value)
lhs = build_expr(ctx, stmt.target)
the_type = build_expr(ctx, stmt.annotation)
return Assign([lhs], rhs, the_type)
@staticmethod
def build_Delete(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("del"))
return Delete(r, [build_expr(ctx, target) for target in stmt.targets])
@staticmethod
def build_Return(ctx, stmt):
r = ctx.make_range(
stmt.lineno, stmt.col_offset, stmt.col_offset + len("return")
)
return Return(r, None if stmt.value is None else build_expr(ctx, stmt.value))
@staticmethod
def build_Raise(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("raise"))
expr = build_expr(ctx, stmt.exc)
return Raise(r, expr)
@staticmethod
def build_Assert(ctx, stmt):
r = ctx.make_range(
stmt.lineno, stmt.col_offset, stmt.col_offset + len("assert")
)
test = build_expr(ctx, stmt.test)
msg = build_expr(ctx, stmt.msg) if stmt.msg is not None else None
return Assert(r, test, msg)
@staticmethod
def build_AugAssign(ctx, stmt):
lhs = build_expr(ctx, stmt.target)
rhs = build_expr(ctx, stmt.value)
op = type(stmt.op)
if op in StmtBuilder.augassign_map:
op_token = StmtBuilder.augassign_map[op]
else:
raise NotSupportedError(
find_before(ctx, rhs.range().start, "=", offsets=(-1, 0)),
"unsupported kind of augmented assignment: " + op.__name__,
)
return AugAssign(lhs, op_token, rhs)
@staticmethod
def build_While(ctx, stmt):
if stmt.orelse:
# TODO: try to recover the location of else:? Python doesn't give us useful
# annotations in this case
raise NotSupportedError(
None, "else branches of while loops aren't supported"
)
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("while"))
return While(r, build_expr(ctx, stmt.test), build_stmts(ctx, stmt.body))
@staticmethod
def build_For(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("for"))
if stmt.orelse:
raise NotSupportedError(r, "else branches of for loops aren't supported")
return For(
r,
[build_expr(ctx, stmt.target)],
[build_expr(ctx, stmt.iter)],
build_stmts(ctx, stmt.body),
)
@staticmethod
def build_If(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("if"))
return If(
r,
build_expr(ctx, stmt.test),
build_stmts(ctx, stmt.body),
build_stmts(ctx, stmt.orelse),
)
@staticmethod
def build_Print(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("print"))
if stmt.dest:
raise NotSupportedError(
r, "print statements with non-default destinations aren't supported"
)
args = [build_expr(ctx, val) for val in stmt.values]
return ExprStmt(Apply(Var(Ident(r, "print")), args, []))
@staticmethod
def build_Pass(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("pass"))
return Pass(r)
@staticmethod
def build_Break(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("break"))
return Break(r)
@staticmethod
def build_Continue(ctx, stmt):
r = ctx.make_range(
stmt.lineno, stmt.col_offset, stmt.col_offset + len("continue")
)
return Continue(r)
@staticmethod
def build_With(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset + len("with"))
# Handle ignore context manager
if is_torch_jit_ignore_context_manager(stmt):
if not _IS_ASTUNPARSE_INSTALLED:
raise RuntimeError(
"torch.jit._IgnoreContextManager requires installing Python library `astunparse`, \
please install it in your Python environment"
)
assign_ast = build_ignore_context_manager(ctx, stmt)
return build_stmt(ctx, assign_ast)
return With(r, build_withitems(ctx, stmt.items), build_stmts(ctx, stmt.body))
class ExprBuilder(Builder):
binop_map = {
ast.Add: "+",
ast.Sub: "-",
ast.Mult: "*",
ast.Div: "/",
ast.Pow: "**",
ast.Mod: "%",
ast.FloorDiv: "//",
ast.BitAnd: "&",
ast.BitXor: "^",
ast.BitOr: "|",
ast.LShift: "<<",
ast.RShift: ">>",
}
binop_map[ast.MatMult] = "@"
unop_map = {
ast.Not: "not",
ast.USub: "-",
ast.Invert: "~",
}
boolop_map = {
ast.And: "and",
ast.Or: "or",
}
cmpop_map = {
ast.Eq: "==",
ast.NotEq: "!=",
ast.LtE: "<=",
ast.Lt: "<",
ast.GtE: ">=",
ast.Gt: ">",
ast.Is: "is",
ast.IsNot: "is not",
ast.In: "in",
ast.NotIn: "not in",
}
@staticmethod
def build_Attribute(ctx, expr):
base = build_expr(ctx, expr.value)
# expr.attr is just a string, so it's not annotated in any way, so we have
# to build the range manually
source = ctx.source.encode("utf-8")
def get_char(index):
return chr(source[index])
start_pos = base.range().end + 1
while get_char(start_pos) in string.whitespace: # Skip whitespace
start_pos += 1
end_pos = start_pos + len(expr.attr)
name_range = ctx.make_raw_range(start_pos, end_pos)
return Select(base, Ident(name_range, expr.attr))
@staticmethod
def build_Call(ctx, expr):
func = build_expr(ctx, expr.func)
args = [build_expr(ctx, py_arg) for py_arg in expr.args]
if hasattr(expr, "starargs") and expr.starargs:
stararg_expr = build_expr(ctx, expr.starargs)
args += [Starred(stararg_expr.range(), stararg_expr)]
kwargs = []
for kw in expr.keywords:
kw_expr = build_expr(ctx, kw.value)
# XXX: we could do a better job at figuring out the range for the name here
if not kw.arg:
raise NotSupportedError(
kw_expr.range(), "keyword-arg expansion is not supported"
)
kwargs.append(Attribute(Ident(kw_expr.range(), kw.arg), kw_expr))
return Apply(func, args, kwargs)
@staticmethod
def build_Ellipsis(ctx, expr):
r = ctx.make_range(
expr.lineno, expr.col_offset, expr.col_offset + 3
) # len("...") == 3
return Dots(r)
@staticmethod
def build_Name(ctx, expr):
r = ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + len(expr.id))
if expr.id.startswith(_reserved_prefix):
raise NotSupportedError(
r,
"names of variables used in JIT-ed functions "
"can't start with " + _reserved_prefix,
)
if expr.id == "True":
return TrueLiteral(r)
elif expr.id == "False":
return FalseLiteral(r)
elif expr.id == "None":
return NoneLiteral(r)
elif expr.id == "Ellipsis":
return Dots(r)
return Var(Ident(r, expr.id))
@staticmethod
def build_NameConstant(ctx, expr):
r = ctx.make_range(
expr.lineno, expr.col_offset, expr.col_offset + len(str(expr.value))
)
if expr.value is True:
return TrueLiteral(r)
elif expr.value is False:
return FalseLiteral(r)
elif expr.value is None:
return NoneLiteral(r)
elif expr.value == Ellipsis:
return Dots(r)
else:
raise ValueError("Name constant value unsupported: " + str(expr.value))
@staticmethod
def build_BinOp(ctx, expr):
lhs = build_expr(ctx, expr.left)
rhs = build_expr(ctx, expr.right)
op = type(expr.op)
if op == ast.Div and not ctx.uses_true_division:
err_range = ctx.make_raw_range(lhs.range().end, rhs.range().start)
raise FrontendError(
err_range,
"Division of ints in TorchScript uses Python 3 true "
"division semantics. Please put `from __future__ "
"import division` at the top of your file",
)
op_token = ExprBuilder.binop_map.get(op)
if op_token is None:
err_range = ctx.make_raw_range(lhs.range().end, rhs.range().start)
raise NotSupportedError(
err_range, "unsupported binary operator: " + op.__name__
)
return BinOp(op_token, lhs, rhs)
@staticmethod
def build_UnaryOp(ctx, expr):
sub_expr = build_expr(ctx, expr.operand)
op = type(expr.op)
op_token = ExprBuilder.unop_map.get(op)
if op_token is None:
raise NotSupportedError(
expr.range(), "unsupported unary operator: " + op.__name__
)
r = ctx.make_range(
expr.lineno, expr.col_offset, expr.col_offset + len(op_token)
)
return UnaryOp(r, op_token, sub_expr)
@staticmethod
def build_BoolOp(ctx, expr):
if len(expr.values) < 2:
raise AssertionError(
"expected at least 2 values in BoolOp, but got " + str(len(expr.values))
)
sub_exprs = [build_expr(ctx, sub_expr) for sub_expr in expr.values]
op = type(expr.op)
op_token = ExprBuilder.boolop_map.get(op)
if op_token is None:
err_range = ctx.make_raw_range(
sub_exprs[0].range().end, sub_exprs[1].range().start
)
raise NotSupportedError(
err_range, "unsupported boolean operator: " + op.__name__
)
lhs = sub_exprs[0]
for rhs in sub_exprs[1:]:
lhs = BinOp(op_token, lhs, rhs)
return lhs
@staticmethod
def build_IfExp(ctx, expr):
return TernaryIf(
build_expr(ctx, expr.test),
build_expr(ctx, expr.body),
build_expr(ctx, expr.orelse),
)
@staticmethod
def build_Compare(ctx, expr):
operands = [build_expr(ctx, e) for e in [expr.left] + list(expr.comparators)]
result = None
for lhs, op_, rhs in zip(operands, expr.ops, operands[1:]):
op = type(op_)
op_token = ExprBuilder.cmpop_map.get(op)
r = ctx.make_raw_range(lhs.range().end, rhs.range().start)
if op_token is None:
raise NotSupportedError(
r, "unsupported comparison operator: " + op.__name__
)
if op == ast.NotIn:
# NB: `not in` is just `not( in )`, so we don't introduce new tree view
# but just make it a nested call in our tree view structure
in_expr = BinOp("in", lhs, rhs)
cmp_expr = UnaryOp(r, "not", in_expr)
else:
cmp_expr = BinOp(op_token, lhs, rhs)
if result is None:
result = cmp_expr
else:
result = BinOp("and", result, cmp_expr)
return result
@staticmethod
def build_Subscript(ctx, expr):
def build_SliceExpr(ctx, base, slice_expr):
lower = (
build_expr(ctx, slice_expr.lower)
if slice_expr.lower is not None
else None
)
upper = (
build_expr(ctx, slice_expr.upper)
if slice_expr.upper is not None
else None
)
step = (
build_expr(ctx, slice_expr.step)
if slice_expr.step is not None
else None
)
return SliceExpr(base.range(), lower, upper, step)
def build_Index(ctx, base, index_expr):
if isinstance(index_expr.value, ast.Tuple):
raise NotSupportedError(
base.range(),
"slicing multiple dimensions with tuples not supported yet",
)
return build_expr(ctx, index_expr.value)
def build_ExtSlice(ctx, base, extslice):
sub_exprs = []
for expr in extslice.dims:
sub_type = type(expr)
if sub_type is ast.Index:
sub_exprs.append(build_Index(ctx, base, expr))
elif sub_type is ast.Slice:
sub_exprs.append(build_SliceExpr(ctx, base, expr))
elif sub_type is ast.Ellipsis:
sub_exprs.append(Dots(base.range()))
else:
raise NotSupportedError(
base.range(),
f"slicing multiple dimensions with {sub_type} not supported",
)
return sub_exprs
base = build_expr(ctx, expr.value)
sub_type = type(expr.slice)
if sub_type is ast.Index:
if isinstance(expr.slice.value, ast.Tuple):
# N-dimensional indexing using Tuple: x[(i, j, k)] is equivalent to x[i, j, k]
# XXX: Indexing using a list is **different**! It triggers advanced indexing.
indices = [
build_expr(ctx, index_expr) for index_expr in expr.slice.value.elts
]
if not indices:
# `col_offset` is an int, but `end_col_offset` is
# `Optional[int]`. The magic number is here to make
# sure we can parse `()` on any machine
r = ctx.make_range(
expr.lineno,
expr.slice.value.col_offset,
expr.slice.value.col_offset + 2,
)
tup = TupleLiteral(r, [])
indices.append(tup)
return Subscript(base, indices)
else:
return Subscript(base, [build_expr(ctx, expr.slice.value)])
elif sub_type is ast.Slice:
return Subscript(base, [build_SliceExpr(ctx, base, expr.slice)])
elif sub_type is ast.ExtSlice:
return Subscript(base, build_ExtSlice(ctx, base, expr.slice))
elif sys.version_info >= (
3,
9,
): # In Python3.9 array indicies are not wrapped in ast.Index
if sub_type is ast.Tuple:
# N-dimensional indexing using Tuple: x[(i, j, k)] is equivalent to x[i, j, k]
indices = []
for index_expr in expr.slice.elts:
if isinstance(index_expr, ast.Slice):
indices.append(build_SliceExpr(ctx, base, index_expr))
else:
indices.append(build_expr(ctx, index_expr))
# Special-case logic for `typing.Tuple[()]`
if not indices:
# See note above r.e. magic number
r = ctx.make_range(
expr.lineno, expr.slice.col_offset, expr.slice.col_offset + 2
)
tup = TupleLiteral(r, [])
indices.append(tup)
return Subscript(base, indices)
return Subscript(base, [build_expr(ctx, expr.slice)])
else: # Ellipsis (can only happen in Python 2)
raise NotSupportedError(base.range(), "ellipsis is not supported")
@staticmethod
def build_List(ctx, expr):
return ListLiteral(
ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + 1),
[build_expr(ctx, e) for e in expr.elts],
)
@staticmethod
def build_Tuple(ctx, expr):
return TupleLiteral(
ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + 1),
[build_expr(ctx, e) for e in expr.elts],
)
@staticmethod
def build_Dict(ctx, expr):
range = ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + 1)
if expr.keys and not expr.keys[0]:
raise NotSupportedError(
range, "Dict expansion (e.g. `{**dict}`) is not supported"
)
return DictLiteral(
range,
[build_expr(ctx, e) for e in expr.keys],
[build_expr(ctx, e) for e in expr.values],
)
@staticmethod
def build_Num(ctx, expr):
value = str(expr.value)
r = ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + len(value))
return Const(r, value)
@staticmethod
def build_Constant(ctx, expr):
value = expr.value
if value is None or isinstance(value, bool):
# NB: this check has to happen before the int check because bool is
# a subclass of int
return ExprBuilder.build_NameConstant(ctx, expr)
if isinstance(value, (int, float, complex)):
return ExprBuilder.build_Num(ctx, expr)
elif isinstance(value, str):
return ExprBuilder.build_Str(ctx, expr)
elif isinstance(value, type(Ellipsis)):
return ExprBuilder.build_Ellipsis(ctx, expr)
else:
error_range = ctx.make_range(
expr.lineno, expr.col_offset, expr.col_offset + len(str(value))
)
raise FrontendError(error_range, "Unknown Constant expression type")
@staticmethod
def build_Str(ctx, expr):
value = str(expr.value)
r = ctx.make_range(
expr.lineno, expr.col_offset, expr.col_offset + len(value) + 1
)
return StringLiteral(r, value)
@staticmethod
def build_JoinedStr(ctx, expr):
s = ""
args = []
for value in expr.values:
r = ctx.make_range(value.lineno, value.col_offset, value.col_offset + 1)
if isinstance(value, ast.FormattedValue):
if value.conversion != -1:
raise NotSupportedError(r, "Don't support conversion in JoinedStr")
if value.format_spec is not None:
raise NotSupportedError(r, "Don't support formatting in JoinedStr")
s += "{}"
args.append(build_expr(ctx, value.value))
elif isinstance(value, ast.Str):
s += value.s
else:
raise NotSupportedError(r, "Unsupported value in JoinedStr")
r = ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + 1)
return Apply(Select(StringLiteral(r, s), Ident(r, "format")), args, [])
@staticmethod
def build_ListComp(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset)
if len(stmt.generators) != 1:
raise NotSupportedError(r, "Only a single generator is currently supported")
if len(stmt.generators[0].ifs) != 0:
raise NotSupportedError(r, "Comprehension ifs are not supported yet")
elt_expr = build_expr(ctx, stmt.elt)
target_expr = build_expr(ctx, stmt.generators[0].target)
iter_expr = build_expr(ctx, stmt.generators[0].iter)
return ListComp(r, elt_expr, target_expr, iter_expr)
@staticmethod
def build_GeneratorExp(ctx, stmt):
# Convert Generator expression to ListComp
return ExprBuilder.build_ListComp(ctx, stmt)
@staticmethod
def build_DictComp(ctx, stmt):
r = ctx.make_range(stmt.lineno, stmt.col_offset, stmt.col_offset)
if len(stmt.generators) != 1:
raise NotSupportedError(r, "Only a single generator is currently supported")
if len(stmt.generators[0].ifs) != 0:
raise NotSupportedError(r, "Comprehension ifs are not supported yet")
key_expr = build_expr(ctx, stmt.key)
value_expr = build_expr(ctx, stmt.value)
target_expr = build_expr(ctx, stmt.generators[0].target)
iter_expr = build_expr(ctx, stmt.generators[0].iter)
return DictComp(r, key_expr, value_expr, target_expr, iter_expr)
@staticmethod
def build_Starred(ctx, expr):
r = ctx.make_range(expr.lineno, expr.col_offset, expr.col_offset + 1)
return Starred(r, build_expr(ctx, expr.value))
build_expr = ExprBuilder()
build_stmt = StmtBuilder()
build_withitem = WithItemBuilder()
def find_before(ctx, pos, substr, offsets=(0, 0)):
new_pos = ctx.source[:pos].rindex(substr)
return ctx.make_raw_range(new_pos + offsets[0], new_pos + len(substr) + offsets[1])