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de6f7ac91a
linux/scripts/lib/kdoc/kdoc_parser.py
Jonathan Corbet de6f7ac91a docs: kdoc: Coalesce parameter-list handling 
Callers to output_declaration() always pass the parameter information from
self.entry; remove all of the boilerplate arguments and just get at that
information directly.  Formalize its placement in the KdocItem class.

It would be nice to get rid of parameterlist as well, but that has the
effect of reordering the output of function parameters and struct fields to
match the order in the kerneldoc comment rather than in the declaration.
One could argue about which is more correct, but the ordering has been left
unchanged for now.

Reviewed-by: Mauro Carvalho Chehab <mchehab+huawei@kernel.org>
Signed-off-by: Jonathan Corbet <corbet@lwn.net>
2025-07-15 13:43:16 -06:00

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#!/usr/bin/env python3
# SPDX-License-Identifier: GPL-2.0
# Copyright(c) 2025: Mauro Carvalho Chehab <mchehab@kernel.org>.
#
# pylint: disable=C0301,C0302,R0904,R0912,R0913,R0914,R0915,R0917,R1702
"""
kdoc_parser
===========
Read a C language source or header FILE and extract embedded
documentation comments
"""
import re
from pprint import pformat
from kdoc_re import NestedMatch, KernRe
from kdoc_item import KdocItem
#
# Regular expressions used to parse kernel-doc markups at KernelDoc class.
#
# Let's declare them in lowercase outside any class to make easier to
# convert from the python script.
#
# As those are evaluated at the beginning, no need to cache them
#
# Allow whitespace at end of comment start.
doc_start = KernRe(r'^/\*\*\s*$', cache=False)
doc_end = KernRe(r'\*/', cache=False)
doc_com = KernRe(r'\s*\*\s*', cache=False)
doc_com_body = KernRe(r'\s*\* ?', cache=False)
doc_decl = doc_com + KernRe(r'(\w+)', cache=False)
# @params and a strictly limited set of supported section names
# Specifically:
# Match @word:
# @...:
# @{section-name}:
# while trying to not match literal block starts like "example::"
#
doc_sect = doc_com + \
KernRe(r'\s*(\@[.\w]+|\@\.\.\.|description|context|returns?|notes?|examples?)\s*:([^:].*)?$',
flags=re.I, cache=False)
doc_content = doc_com_body + KernRe(r'(.*)', cache=False)
doc_inline_start = KernRe(r'^\s*/\*\*\s*$', cache=False)
doc_inline_sect = KernRe(r'\s*\*\s*(@\s*[\w][\w\.]*\s*):(.*)', cache=False)
doc_inline_end = KernRe(r'^\s*\*/\s*$', cache=False)
doc_inline_oneline = KernRe(r'^\s*/\*\*\s*(@[\w\s]+):\s*(.*)\s*\*/\s*$', cache=False)
attribute = KernRe(r"__attribute__\s*\(\([a-z0-9,_\*\s\(\)]*\)\)",
flags=re.I | re.S, cache=False)
export_symbol = KernRe(r'^\s*EXPORT_SYMBOL(_GPL)?\s*\(\s*(\w+)\s*\)\s*', cache=False)
export_symbol_ns = KernRe(r'^\s*EXPORT_SYMBOL_NS(_GPL)?\s*\(\s*(\w+)\s*,\s*"\S+"\)\s*', cache=False)
type_param = KernRe(r"\@(\w*((\.\w+)|(->\w+))*(\.\.\.)?)", cache=False)
#
# Tests for the beginning of a kerneldoc block in its various forms.
#
doc_block = doc_com + KernRe(r'DOC:\s*(.*)?', cache=False)
doc_begin_data = KernRe(r"^\s*\*?\s*(struct|union|enum|typedef)\b\s*(\w*)", cache = False)
doc_begin_func = KernRe(str(doc_com) + # initial " * '
r"(?:\w+\s*\*\s*)?" + # type (not captured)
r'(?:define\s+)?' + # possible "define" (not captured)
r'(\w+)\s*(?:\(\w*\))?\s*' + # name and optional "(...)"
r'(?:[-:].*)?$', # description (not captured)
cache = False)
#
# A little helper to get rid of excess white space
#
multi_space = KernRe(r'\s\s+')
def trim_whitespace(s):
return multi_space.sub(' ', s.strip())
class state:
"""
State machine enums
"""
# Parser states
NORMAL = 0 # normal code
NAME = 1 # looking for function name
DECLARATION = 2 # We have seen a declaration which might not be done
BODY = 3 # the body of the comment
SPECIAL_SECTION = 4 # doc section ending with a blank line
PROTO = 5 # scanning prototype
DOCBLOCK = 6 # documentation block
INLINE_NAME = 7 # gathering doc outside main block
INLINE_TEXT = 8 # reading the body of inline docs
name = [
"NORMAL",
"NAME",
"DECLARATION",
"BODY",
"SPECIAL_SECTION",
"PROTO",
"DOCBLOCK",
"INLINE_NAME",
"INLINE_TEXT",
]
SECTION_DEFAULT = "Description" # default section
class KernelEntry:
def __init__(self, config, ln):
self.config = config
self._contents = []
self.sectcheck = ""
self.prototype = ""
self.warnings = []
self.parameterlist = []
self.parameterdescs = {}
self.parametertypes = {}
self.parameterdesc_start_lines = {}
self.section_start_lines = {}
self.sections = {}
self.anon_struct_union = False
self.leading_space = None
# State flags
self.brcount = 0
self.declaration_start_line = ln + 1
#
# Management of section contents
#
def add_text(self, text):
self._contents.append(text)
def contents(self):
return '\n'.join(self._contents) + '\n'
# TODO: rename to emit_message after removal of kernel-doc.pl
def emit_msg(self, log_msg, warning=True):
"""Emit a message"""
if not warning:
self.config.log.info(log_msg)
return
# Delegate warning output to output logic, as this way it
# will report warnings/info only for symbols that are output
self.warnings.append(log_msg)
return
#
# Begin a new section.
#
def begin_section(self, line_no, title = SECTION_DEFAULT, dump = False):
if dump:
self.dump_section(start_new = True)
self.section = title
self.new_start_line = line_no
def dump_section(self, start_new=True):
"""
Dumps section contents to arrays/hashes intended for that purpose.
"""
#
# If we have accumulated no contents in the default ("description")
# section, don't bother.
#
if self.section == SECTION_DEFAULT and not self._contents:
return
name = self.section
contents = self.contents()
if type_param.match(name):
name = type_param.group(1)
self.parameterdescs[name] = contents
self.parameterdesc_start_lines[name] = self.new_start_line
self.sectcheck += name + " "
self.new_start_line = 0
else:
if name in self.sections and self.sections[name] != "":
# Only warn on user-specified duplicate section names
if name != SECTION_DEFAULT:
self.emit_msg(self.new_start_line,
f"duplicate section name '{name}'\n")
# Treat as a new paragraph - add a blank line
self.sections[name] += '\n' + contents
else:
self.sections[name] = contents
self.section_start_lines[name] = self.new_start_line
self.new_start_line = 0
# self.config.log.debug("Section: %s : %s", name, pformat(vars(self)))
if start_new:
self.section = SECTION_DEFAULT
self._contents = []
class KernelDoc:
"""
Read a C language source or header FILE and extract embedded
documentation comments.
"""
# Section names
section_context = "Context"
section_return = "Return"
undescribed = "-- undescribed --"
def __init__(self, config, fname):
"""Initialize internal variables"""
self.fname = fname
self.config = config
# Initial state for the state machines
self.state = state.NORMAL
# Store entry currently being processed
self.entry = None
# Place all potential outputs into an array
self.entries = []
def emit_msg(self, ln, msg, warning=True):
"""Emit a message"""
log_msg = f"{self.fname}:{ln} {msg}"
if self.entry:
self.entry.emit_msg(log_msg, warning)
return
if warning:
self.config.log.warning(log_msg)
else:
self.config.log.info(log_msg)
def dump_section(self, start_new=True):
"""
Dumps section contents to arrays/hashes intended for that purpose.
"""
if self.entry:
self.entry.dump_section(start_new)
# TODO: rename it to store_declaration after removal of kernel-doc.pl
def output_declaration(self, dtype, name, **args):
"""
Stores the entry into an entry array.
The actual output and output filters will be handled elsewhere
"""
item = KdocItem(name, dtype, self.entry.declaration_start_line, **args)
item.warnings = self.entry.warnings
# Drop empty sections
# TODO: improve empty sections logic to emit warnings
sections = self.entry.sections
for section in ["Description", "Return"]:
if section in sections and not sections[section].rstrip():
del sections[section]
item.set_sections(sections, self.entry.section_start_lines)
item.set_params(self.entry.parameterlist, self.entry.parameterdescs,
self.entry.parametertypes,
self.entry.parameterdesc_start_lines)
self.entries.append(item)
self.config.log.debug("Output: %s:%s = %s", dtype, name, pformat(args))
def reset_state(self, ln):
"""
Ancillary routine to create a new entry. It initializes all
variables used by the state machine.
"""
self.entry = KernelEntry(self.config, ln)
# State flags
self.state = state.NORMAL
def push_parameter(self, ln, decl_type, param, dtype,
org_arg, declaration_name):
"""
Store parameters and their descriptions at self.entry.
"""
if self.entry.anon_struct_union and dtype == "" and param == "}":
return # Ignore the ending }; from anonymous struct/union
self.entry.anon_struct_union = False
param = KernRe(r'[\[\)].*').sub('', param, count=1)
if dtype == "" and param.endswith("..."):
if KernRe(r'\w\.\.\.$').search(param):
# For named variable parameters of the form `x...`,
# remove the dots
param = param[:-3]
else:
# Handles unnamed variable parameters
param = "..."
if param not in self.entry.parameterdescs or \
not self.entry.parameterdescs[param]:
self.entry.parameterdescs[param] = "variable arguments"
elif dtype == "" and (not param or param == "void"):
param = "void"
self.entry.parameterdescs[param] = "no arguments"
elif dtype == "" and param in ["struct", "union"]:
# Handle unnamed (anonymous) union or struct
dtype = param
param = "{unnamed_" + param + "}"
self.entry.parameterdescs[param] = "anonymous\n"
self.entry.anon_struct_union = True
# Handle cache group enforcing variables: they do not need
# to be described in header files
elif "__cacheline_group" in param:
# Ignore __cacheline_group_begin and __cacheline_group_end
return
# Warn if parameter has no description
# (but ignore ones starting with # as these are not parameters
# but inline preprocessor statements)
if param not in self.entry.parameterdescs and not param.startswith("#"):
self.entry.parameterdescs[param] = self.undescribed
if "." not in param:
if decl_type == 'function':
dname = f"{decl_type} parameter"
else:
dname = f"{decl_type} member"
self.emit_msg(ln,
f"{dname} '{param}' not described in '{declaration_name}'")
# Strip spaces from param so that it is one continuous string on
# parameterlist. This fixes a problem where check_sections()
# cannot find a parameter like "addr[6 + 2]" because it actually
# appears as "addr[6", "+", "2]" on the parameter list.
# However, it's better to maintain the param string unchanged for
# output, so just weaken the string compare in check_sections()
# to ignore "[blah" in a parameter string.
self.entry.parameterlist.append(param)
org_arg = KernRe(r'\s\s+').sub(' ', org_arg)
self.entry.parametertypes[param] = org_arg
def create_parameter_list(self, ln, decl_type, args,
splitter, declaration_name):
"""
Creates a list of parameters, storing them at self.entry.
"""
# temporarily replace all commas inside function pointer definition
arg_expr = KernRe(r'(\([^\),]+),')
while arg_expr.search(args):
args = arg_expr.sub(r"\1#", args)
for arg in args.split(splitter):
# Strip comments
arg = KernRe(r'\/\*.*\*\/').sub('', arg)
# Ignore argument attributes
arg = KernRe(r'\sPOS0?\s').sub(' ', arg)
# Strip leading/trailing spaces
arg = arg.strip()
arg = KernRe(r'\s+').sub(' ', arg, count=1)
if arg.startswith('#'):
# Treat preprocessor directive as a typeless variable just to fill
# corresponding data structures "correctly". Catch it later in
# output_* subs.
# Treat preprocessor directive as a typeless variable
self.push_parameter(ln, decl_type, arg, "",
"", declaration_name)
elif KernRe(r'\(.+\)\s*\(').search(arg):
# Pointer-to-function
arg = arg.replace('#', ',')
r = KernRe(r'[^\(]+\(\*?\s*([\w\[\]\.]*)\s*\)')
if r.match(arg):
param = r.group(1)
else:
self.emit_msg(ln, f"Invalid param: {arg}")
param = arg
dtype = KernRe(r'([^\(]+\(\*?)\s*' + re.escape(param)).sub(r'\1', arg)
self.push_parameter(ln, decl_type, param, dtype,
arg, declaration_name)
elif KernRe(r'\(.+\)\s*\[').search(arg):
# Array-of-pointers
arg = arg.replace('#', ',')
r = KernRe(r'[^\(]+\(\s*\*\s*([\w\[\]\.]*?)\s*(\s*\[\s*[\w]+\s*\]\s*)*\)')
if r.match(arg):
param = r.group(1)
else:
self.emit_msg(ln, f"Invalid param: {arg}")
param = arg
dtype = KernRe(r'([^\(]+\(\*?)\s*' + re.escape(param)).sub(r'\1', arg)
self.push_parameter(ln, decl_type, param, dtype,
arg, declaration_name)
elif arg:
arg = KernRe(r'\s*:\s*').sub(":", arg)
arg = KernRe(r'\s*\[').sub('[', arg)
args = KernRe(r'\s*,\s*').split(arg)
if args[0] and '*' in args[0]:
args[0] = re.sub(r'(\*+)\s*', r' \1', args[0])
first_arg = []
r = KernRe(r'^(.*\s+)(.*?\[.*\].*)$')
if args[0] and r.match(args[0]):
args.pop(0)
first_arg.extend(r.group(1))
first_arg.append(r.group(2))
else:
first_arg = KernRe(r'\s+').split(args.pop(0))
args.insert(0, first_arg.pop())
dtype = ' '.join(first_arg)
for param in args:
if KernRe(r'^(\*+)\s*(.*)').match(param):
r = KernRe(r'^(\*+)\s*(.*)')
if not r.match(param):
self.emit_msg(ln, f"Invalid param: {param}")
continue
param = r.group(1)
self.push_parameter(ln, decl_type, r.group(2),
f"{dtype} {r.group(1)}",
arg, declaration_name)
elif KernRe(r'(.*?):(\w+)').search(param):
r = KernRe(r'(.*?):(\w+)')
if not r.match(param):
self.emit_msg(ln, f"Invalid param: {param}")
continue
if dtype != "": # Skip unnamed bit-fields
self.push_parameter(ln, decl_type, r.group(1),
f"{dtype}:{r.group(2)}",
arg, declaration_name)
else:
self.push_parameter(ln, decl_type, param, dtype,
arg, declaration_name)
def check_sections(self, ln, decl_name, decl_type, sectcheck):
"""
Check for errors inside sections, emitting warnings if not found
parameters are described.
"""
sects = sectcheck.split()
for sx in range(len(sects)): # pylint: disable=C0200
err = True
for param in self.entry.parameterlist:
if param == sects[sx]:
err = False
break
if err:
if decl_type == 'function':
dname = f"{decl_type} parameter"
else:
dname = f"{decl_type} member"
self.emit_msg(ln,
f"Excess {dname} '{sects[sx]}' description in '{decl_name}'")
def check_return_section(self, ln, declaration_name, return_type):
"""
If the function doesn't return void, warns about the lack of a
return description.
"""
if not self.config.wreturn:
return
# Ignore an empty return type (It's a macro)
# Ignore functions with a "void" return type (but not "void *")
if not return_type or KernRe(r'void\s*\w*\s*$').search(return_type):
return
if not self.entry.sections.get("Return", None):
self.emit_msg(ln,
f"No description found for return value of '{declaration_name}'")
def dump_struct(self, ln, proto):
"""
Store an entry for an struct or union
"""
type_pattern = r'(struct|union)'
qualifiers = [
"__attribute__",
"__packed",
"__aligned",
"____cacheline_aligned_in_smp",
"____cacheline_aligned",
]
definition_body = r'\{(.*)\}\s*' + "(?:" + '|'.join(qualifiers) + ")?"
struct_members = KernRe(type_pattern + r'([^\{\};]+)(\{)([^\{\}]*)(\})([^\{\}\;]*)(\;)')
# Extract struct/union definition
members = None
declaration_name = None
decl_type = None
r = KernRe(type_pattern + r'\s+(\w+)\s*' + definition_body)
if r.search(proto):
decl_type = r.group(1)
declaration_name = r.group(2)
members = r.group(3)
else:
r = KernRe(r'typedef\s+' + type_pattern + r'\s*' + definition_body + r'\s*(\w+)\s*;')
if r.search(proto):
decl_type = r.group(1)
declaration_name = r.group(3)
members = r.group(2)
if not members:
self.emit_msg(ln, f"{proto} error: Cannot parse struct or union!")
return
if self.entry.identifier != declaration_name:
self.emit_msg(ln,
f"expecting prototype for {decl_type} {self.entry.identifier}. Prototype was for {decl_type} {declaration_name} instead\n")
return
args_pattern = r'([^,)]+)'
sub_prefixes = [
(KernRe(r'\/\*\s*private:.*?\/\*\s*public:.*?\*\/', re.S | re.I), ''),
(KernRe(r'\/\*\s*private:.*', re.S | re.I), ''),
# Strip comments
(KernRe(r'\/\*.*?\*\/', re.S), ''),
# Strip attributes
(attribute, ' '),
(KernRe(r'\s*__aligned\s*\([^;]*\)', re.S), ' '),
(KernRe(r'\s*__counted_by\s*\([^;]*\)', re.S), ' '),
(KernRe(r'\s*__counted_by_(le|be)\s*\([^;]*\)', re.S), ' '),
(KernRe(r'\s*__packed\s*', re.S), ' '),
(KernRe(r'\s*CRYPTO_MINALIGN_ATTR', re.S), ' '),
(KernRe(r'\s*____cacheline_aligned_in_smp', re.S), ' '),
(KernRe(r'\s*____cacheline_aligned', re.S), ' '),
# Unwrap struct_group macros based on this definition:
# __struct_group(TAG, NAME, ATTRS, MEMBERS...)
# which has variants like: struct_group(NAME, MEMBERS...)
# Only MEMBERS arguments require documentation.
#
# Parsing them happens on two steps:
#
# 1. drop struct group arguments that aren't at MEMBERS,
# storing them as STRUCT_GROUP(MEMBERS)
#
# 2. remove STRUCT_GROUP() ancillary macro.
#
# The original logic used to remove STRUCT_GROUP() using an
# advanced regex:
#
# \bSTRUCT_GROUP(\(((?:(?>[^)(]+)|(?1))*)\))[^;]*;
#
# with two patterns that are incompatible with
# Python re module, as it has:
#
# - a recursive pattern: (?1)
# - an atomic grouping: (?>...)
#
# I tried a simpler version: but it didn't work either:
# \bSTRUCT_GROUP\(([^\)]+)\)[^;]*;
#
# As it doesn't properly match the end parenthesis on some cases.
#
# So, a better solution was crafted: there's now a NestedMatch
# class that ensures that delimiters after a search are properly
# matched. So, the implementation to drop STRUCT_GROUP() will be
# handled in separate.
(KernRe(r'\bstruct_group\s*\(([^,]*,)', re.S), r'STRUCT_GROUP('),
(KernRe(r'\bstruct_group_attr\s*\(([^,]*,){2}', re.S), r'STRUCT_GROUP('),
(KernRe(r'\bstruct_group_tagged\s*\(([^,]*),([^,]*),', re.S), r'struct \1 \2; STRUCT_GROUP('),
(KernRe(r'\b__struct_group\s*\(([^,]*,){3}', re.S), r'STRUCT_GROUP('),
# Replace macros
#
# TODO: use NestedMatch for FOO($1, $2, ...) matches
#
# it is better to also move those to the NestedMatch logic,
# to ensure that parenthesis will be properly matched.
(KernRe(r'__ETHTOOL_DECLARE_LINK_MODE_MASK\s*\(([^\)]+)\)', re.S), r'DECLARE_BITMAP(\1, __ETHTOOL_LINK_MODE_MASK_NBITS)'),
(KernRe(r'DECLARE_PHY_INTERFACE_MASK\s*\(([^\)]+)\)', re.S), r'DECLARE_BITMAP(\1, PHY_INTERFACE_MODE_MAX)'),
(KernRe(r'DECLARE_BITMAP\s*\(' + args_pattern + r',\s*' + args_pattern + r'\)', re.S), r'unsigned long \1[BITS_TO_LONGS(\2)]'),
(KernRe(r'DECLARE_HASHTABLE\s*\(' + args_pattern + r',\s*' + args_pattern + r'\)', re.S), r'unsigned long \1[1 << ((\2) - 1)]'),
(KernRe(r'DECLARE_KFIFO\s*\(' + args_pattern + r',\s*' + args_pattern + r',\s*' + args_pattern + r'\)', re.S), r'\2 *\1'),
(KernRe(r'DECLARE_KFIFO_PTR\s*\(' + args_pattern + r',\s*' + args_pattern + r'\)', re.S), r'\2 *\1'),
(KernRe(r'(?:__)?DECLARE_FLEX_ARRAY\s*\(' + args_pattern + r',\s*' + args_pattern + r'\)', re.S), r'\1 \2[]'),
(KernRe(r'DEFINE_DMA_UNMAP_ADDR\s*\(' + args_pattern + r'\)', re.S), r'dma_addr_t \1'),
(KernRe(r'DEFINE_DMA_UNMAP_LEN\s*\(' + args_pattern + r'\)', re.S), r'__u32 \1'),
]
# Regexes here are guaranteed to have the end limiter matching
# the start delimiter. Yet, right now, only one replace group
# is allowed.
sub_nested_prefixes = [
(re.compile(r'\bSTRUCT_GROUP\('), r'\1'),
]
for search, sub in sub_prefixes:
members = search.sub(sub, members)
nested = NestedMatch()
for search, sub in sub_nested_prefixes:
members = nested.sub(search, sub, members)
# Keeps the original declaration as-is
declaration = members
# Split nested struct/union elements
#
# This loop was simpler at the original kernel-doc perl version, as
# while ($members =~ m/$struct_members/) { ... }
# reads 'members' string on each interaction.
#
# Python behavior is different: it parses 'members' only once,
# creating a list of tuples from the first interaction.
#
# On other words, this won't get nested structs.
#
# So, we need to have an extra loop on Python to override such
# re limitation.
while True:
tuples = struct_members.findall(members)
if not tuples:
break
for t in tuples:
newmember = ""
maintype = t[0]
s_ids = t[5]
content = t[3]
oldmember = "".join(t)
for s_id in s_ids.split(','):
s_id = s_id.strip()
newmember += f"{maintype} {s_id}; "
s_id = KernRe(r'[:\[].*').sub('', s_id)
s_id = KernRe(r'^\s*\**(\S+)\s*').sub(r'\1', s_id)
for arg in content.split(';'):
arg = arg.strip()
if not arg:
continue
r = KernRe(r'^([^\(]+\(\*?\s*)([\w\.]*)(\s*\).*)')
if r.match(arg):
# Pointer-to-function
dtype = r.group(1)
name = r.group(2)
extra = r.group(3)
if not name:
continue
if not s_id:
# Anonymous struct/union
newmember += f"{dtype}{name}{extra}; "
else:
newmember += f"{dtype}{s_id}.{name}{extra}; "
else:
arg = arg.strip()
# Handle bitmaps
arg = KernRe(r':\s*\d+\s*').sub('', arg)
# Handle arrays
arg = KernRe(r'\[.*\]').sub('', arg)
# Handle multiple IDs
arg = KernRe(r'\s*,\s*').sub(',', arg)
r = KernRe(r'(.*)\s+([\S+,]+)')
if r.search(arg):
dtype = r.group(1)
names = r.group(2)
else:
newmember += f"{arg}; "
continue
for name in names.split(','):
name = KernRe(r'^\s*\**(\S+)\s*').sub(r'\1', name).strip()
if not name:
continue
if not s_id:
# Anonymous struct/union
newmember += f"{dtype} {name}; "
else:
newmember += f"{dtype} {s_id}.{name}; "
members = members.replace(oldmember, newmember)
# Ignore other nested elements, like enums
members = re.sub(r'(\{[^\{\}]*\})', '', members)
self.create_parameter_list(ln, decl_type, members, ';',
declaration_name)
self.check_sections(ln, declaration_name, decl_type, self.entry.sectcheck)
# Adjust declaration for better display
declaration = KernRe(r'([\{;])').sub(r'\1\n', declaration)
declaration = KernRe(r'\}\s+;').sub('};', declaration)
# Better handle inlined enums
while True:
r = KernRe(r'(enum\s+\{[^\}]+),([^\n])')
if not r.search(declaration):
break
declaration = r.sub(r'\1,\n\2', declaration)
def_args = declaration.split('\n')
level = 1
declaration = ""
for clause in def_args:
clause = clause.strip()
clause = KernRe(r'\s+').sub(' ', clause, count=1)
if not clause:
continue
if '}' in clause and level > 1:
level -= 1
if not KernRe(r'^\s*#').match(clause):
declaration += "\t" * level
declaration += "\t" + clause + "\n"
if "{" in clause and "}" not in clause:
level += 1
self.output_declaration(decl_type, declaration_name,
struct=declaration_name,
definition=declaration,
purpose=self.entry.declaration_purpose)
def dump_enum(self, ln, proto):
"""
Stores an enum inside self.entries array.
"""
# Ignore members marked private
proto = KernRe(r'\/\*\s*private:.*?\/\*\s*public:.*?\*\/', flags=re.S).sub('', proto)
proto = KernRe(r'\/\*\s*private:.*}', flags=re.S).sub('}', proto)
# Strip comments
proto = KernRe(r'\/\*.*?\*\/', flags=re.S).sub('', proto)
# Strip #define macros inside enums
proto = KernRe(r'#\s*((define|ifdef|if)\s+|endif)[^;]*;', flags=re.S).sub('', proto)
#
# Parse out the name and members of the enum. Typedef form first.
#
r = KernRe(r'typedef\s+enum\s*\{(.*)\}\s*(\w*)\s*;')
if r.search(proto):
declaration_name = r.group(2)
members = r.group(1).rstrip()
#
# Failing that, look for a straight enum
#
else:
r = KernRe(r'enum\s+(\w*)\s*\{(.*)\}')
if r.match(proto):
declaration_name = r.group(1)
members = r.group(2).rstrip()
#
# OK, this isn't going to work.
#
else:
self.emit_msg(ln, f"{proto}: error: Cannot parse enum!")
return
#
# Make sure we found what we were expecting.
#
if self.entry.identifier != declaration_name:
if self.entry.identifier == "":
self.emit_msg(ln,
f"{proto}: wrong kernel-doc identifier on prototype")
else:
self.emit_msg(ln,
f"expecting prototype for enum {self.entry.identifier}. "
f"Prototype was for enum {declaration_name} instead")
return
if not declaration_name:
declaration_name = "(anonymous)"
#
# Parse out the name of each enum member, and verify that we
# have a description for it.
#
member_set = set()
members = KernRe(r'\([^;)]*\)').sub('', members)
for arg in members.split(','):
if not arg:
continue
arg = KernRe(r'^\s*(\w+).*').sub(r'\1', arg)
self.entry.parameterlist.append(arg)
if arg not in self.entry.parameterdescs:
self.entry.parameterdescs[arg] = self.undescribed
self.emit_msg(ln,
f"Enum value '{arg}' not described in enum '{declaration_name}'")
member_set.add(arg)
#
# Ensure that every described member actually exists in the enum.
#
for k in self.entry.parameterdescs:
if k not in member_set:
self.emit_msg(ln,
f"Excess enum value '%{k}' description in '{declaration_name}'")
self.output_declaration('enum', declaration_name,
enum=declaration_name,
purpose=self.entry.declaration_purpose)
def dump_declaration(self, ln, prototype):
"""
Stores a data declaration inside self.entries array.
"""
if self.entry.decl_type == "enum":
self.dump_enum(ln, prototype)
return
if self.entry.decl_type == "typedef":
self.dump_typedef(ln, prototype)
return
if self.entry.decl_type in ["union", "struct"]:
self.dump_struct(ln, prototype)
return
self.output_declaration(self.entry.decl_type, prototype,
entry=self.entry)
def dump_function(self, ln, prototype):
"""
Stores a function of function macro inside self.entries array.
"""
func_macro = False
return_type = ''
decl_type = 'function'
# Prefixes that would be removed
sub_prefixes = [
(r"^static +", "", 0),
(r"^extern +", "", 0),
(r"^asmlinkage +", "", 0),
(r"^inline +", "", 0),
(r"^__inline__ +", "", 0),
(r"^__inline +", "", 0),
(r"^__always_inline +", "", 0),
(r"^noinline +", "", 0),
(r"^__FORTIFY_INLINE +", "", 0),
(r"__init +", "", 0),
(r"__init_or_module +", "", 0),
(r"__deprecated +", "", 0),
(r"__flatten +", "", 0),
(r"__meminit +", "", 0),
(r"__must_check +", "", 0),
(r"__weak +", "", 0),
(r"__sched +", "", 0),
(r"_noprof", "", 0),
(r"__printf\s*\(\s*\d*\s*,\s*\d*\s*\) +", "", 0),
(r"__(?:re)?alloc_size\s*\(\s*\d+\s*(?:,\s*\d+\s*)?\) +", "", 0),
(r"__diagnose_as\s*\(\s*\S+\s*(?:,\s*\d+\s*)*\) +", "", 0),
(r"DECL_BUCKET_PARAMS\s*\(\s*(\S+)\s*,\s*(\S+)\s*\)", r"\1, \2", 0),
(r"__attribute_const__ +", "", 0),
# It seems that Python support for re.X is broken:
# At least for me (Python 3.13), this didn't work
# (r"""
# __attribute__\s*\(\(
# (?:
# [\w\s]+ # attribute name
# (?:\([^)]*\))? # attribute arguments
# \s*,? # optional comma at the end
# )+
# \)\)\s+
# """, "", re.X),
# So, remove whitespaces and comments from it
(r"__attribute__\s*\(\((?:[\w\s]+(?:\([^)]*\))?\s*,?)+\)\)\s+", "", 0),
]
for search, sub, flags in sub_prefixes:
prototype = KernRe(search, flags).sub(sub, prototype)
# Macros are a special case, as they change the prototype format
new_proto = KernRe(r"^#\s*define\s+").sub("", prototype)
if new_proto != prototype:
is_define_proto = True
prototype = new_proto
else:
is_define_proto = False
# Yes, this truly is vile. We are looking for:
# 1. Return type (may be nothing if we're looking at a macro)
# 2. Function name
# 3. Function parameters.
#
# All the while we have to watch out for function pointer parameters
# (which IIRC is what the two sections are for), C types (these
# regexps don't even start to express all the possibilities), and
# so on.
#
# If you mess with these regexps, it's a good idea to check that
# the following functions' documentation still comes out right:
# - parport_register_device (function pointer parameters)
# - atomic_set (macro)
# - pci_match_device, __copy_to_user (long return type)
name = r'[a-zA-Z0-9_~:]+'
prototype_end1 = r'[^\(]*'
prototype_end2 = r'[^\{]*'
prototype_end = fr'\(({prototype_end1}|{prototype_end2})\)'
# Besides compiling, Perl qr{[\w\s]+} works as a non-capturing group.
# So, this needs to be mapped in Python with (?:...)? or (?:...)+
type1 = r'(?:[\w\s]+)?'
type2 = r'(?:[\w\s]+\*+)+'
found = False
if is_define_proto:
r = KernRe(r'^()(' + name + r')\s+')
if r.search(prototype):
return_type = ''
declaration_name = r.group(2)
func_macro = True
found = True
if not found:
patterns = [
rf'^()({name})\s*{prototype_end}',
rf'^({type1})\s+({name})\s*{prototype_end}',
rf'^({type2})\s*({name})\s*{prototype_end}',
]
for p in patterns:
r = KernRe(p)
if r.match(prototype):
return_type = r.group(1)
declaration_name = r.group(2)
args = r.group(3)
self.create_parameter_list(ln, decl_type, args, ',',
declaration_name)
found = True
break
if not found:
self.emit_msg(ln,
f"cannot understand function prototype: '{prototype}'")
return
if self.entry.identifier != declaration_name:
self.emit_msg(ln,
f"expecting prototype for {self.entry.identifier}(). Prototype was for {declaration_name}() instead")
return
self.check_sections(ln, declaration_name, "function", self.entry.sectcheck)
self.check_return_section(ln, declaration_name, return_type)
if 'typedef' in return_type:
self.output_declaration(decl_type, declaration_name,
function=declaration_name,
typedef=True,
functiontype=return_type,
purpose=self.entry.declaration_purpose,
func_macro=func_macro)
else:
self.output_declaration(decl_type, declaration_name,
function=declaration_name,
typedef=False,
functiontype=return_type,
purpose=self.entry.declaration_purpose,
func_macro=func_macro)
def dump_typedef(self, ln, proto):
"""
Stores a typedef inside self.entries array.
"""
typedef_type = r'((?:\s+[\w\*]+\b){0,7}\s+(?:\w+\b|\*+))\s*'
typedef_ident = r'\*?\s*(\w\S+)\s*'
typedef_args = r'\s*\((.*)\);'
typedef1 = KernRe(r'typedef' + typedef_type + r'\(' + typedef_ident + r'\)' + typedef_args)
typedef2 = KernRe(r'typedef' + typedef_type + typedef_ident + typedef_args)
# Strip comments
proto = KernRe(r'/\*.*?\*/', flags=re.S).sub('', proto)
# Parse function typedef prototypes
for r in [typedef1, typedef2]:
if not r.match(proto):
continue
return_type = r.group(1).strip()
declaration_name = r.group(2)
args = r.group(3)
if self.entry.identifier != declaration_name:
self.emit_msg(ln,
f"expecting prototype for typedef {self.entry.identifier}. Prototype was for typedef {declaration_name} instead\n")
return
decl_type = 'function'
self.create_parameter_list(ln, decl_type, args, ',', declaration_name)
self.output_declaration(decl_type, declaration_name,
function=declaration_name,
typedef=True,
functiontype=return_type,
purpose=self.entry.declaration_purpose)
return
# Handle nested parentheses or brackets
r = KernRe(r'(\(*.\)\s*|\[*.\]\s*);$')
while r.search(proto):
proto = r.sub('', proto)
# Parse simple typedefs
r = KernRe(r'typedef.*\s+(\w+)\s*;')
if r.match(proto):
declaration_name = r.group(1)
if self.entry.identifier != declaration_name:
self.emit_msg(ln,
f"expecting prototype for typedef {self.entry.identifier}. Prototype was for typedef {declaration_name} instead\n")
return
self.output_declaration('typedef', declaration_name,
typedef=declaration_name,
purpose=self.entry.declaration_purpose)
return
self.emit_msg(ln, "error: Cannot parse typedef!")
@staticmethod
def process_export(function_set, line):
"""
process EXPORT_SYMBOL* tags
This method doesn't use any variable from the class, so declare it
with a staticmethod decorator.
"""
# We support documenting some exported symbols with different
# names. A horrible hack.
suffixes = [ '_noprof' ]
# Note: it accepts only one EXPORT_SYMBOL* per line, as having
# multiple export lines would violate Kernel coding style.
if export_symbol.search(line):
symbol = export_symbol.group(2)
elif export_symbol_ns.search(line):
symbol = export_symbol_ns.group(2)
else:
return False
#
# Found an export, trim out any special suffixes
#
for suffix in suffixes:
symbol = symbol.removesuffix(suffix)
function_set.add(symbol)
return True
def process_normal(self, ln, line):
"""
STATE_NORMAL: looking for the /** to begin everything.
"""
if not doc_start.match(line):
return
# start a new entry
self.reset_state(ln)
# next line is always the function name
self.state = state.NAME
def process_name(self, ln, line):
"""
STATE_NAME: Looking for the "name - description" line
"""
#
# Check for a DOC: block and handle them specially.
#
if doc_block.search(line):
if not doc_block.group(1):
self.entry.begin_section(ln, "Introduction")
else:
self.entry.begin_section(ln, doc_block.group(1))
self.entry.identifier = self.entry.section
self.state = state.DOCBLOCK
#
# Otherwise we're looking for a normal kerneldoc declaration line.
#
elif doc_decl.search(line):
self.entry.identifier = doc_decl.group(1)
# Test for data declaration
if doc_begin_data.search(line):
self.entry.decl_type = doc_begin_data.group(1)
self.entry.identifier = doc_begin_data.group(2)
#
# Look for a function description
#
elif doc_begin_func.search(line):
self.entry.identifier = doc_begin_func.group(1)
self.entry.decl_type = "function"
#
# We struck out.
#
else:
self.emit_msg(ln,
f"This comment starts with '/**', but isn't a kernel-doc comment. Refer Documentation/doc-guide/kernel-doc.rst\n{line}")
self.state = state.NORMAL
return
#
# OK, set up for a new kerneldoc entry.
#
self.state = state.BODY
self.entry.identifier = self.entry.identifier.strip(" ")
# if there's no @param blocks need to set up default section here
self.entry.begin_section(ln + 1)
#
# Find the description portion, which *should* be there but
# isn't always.
# (We should be able to capture this from the previous parsing - someday)
#
r = KernRe("[-:](.*)")
if r.search(line):
self.entry.declaration_purpose = trim_whitespace(r.group(1))
self.state = state.DECLARATION
else:
self.entry.declaration_purpose = ""
if not self.entry.declaration_purpose and self.config.wshort_desc:
self.emit_msg(ln,
f"missing initial short description on line:\n{line}")
if not self.entry.identifier and self.entry.decl_type != "enum":
self.emit_msg(ln,
f"wrong kernel-doc identifier on line:\n{line}")
self.state = state.NORMAL
if self.config.verbose:
self.emit_msg(ln,
f"Scanning doc for {self.entry.decl_type} {self.entry.identifier}",
warning=False)
#
# Failed to find an identifier. Emit a warning
#
else:
self.emit_msg(ln, f"Cannot find identifier on line:\n{line}")
#
# Helper function to determine if a new section is being started.
#
def is_new_section(self, ln, line):
if doc_sect.search(line):
self.state = state.BODY
#
# Pick out the name of our new section, tweaking it if need be.
#
newsection = doc_sect.group(1)
if newsection.lower() == 'description':
newsection = 'Description'
elif newsection.lower() == 'context':
newsection = 'Context'
self.state = state.SPECIAL_SECTION
elif newsection.lower() in ["@return", "@returns",
"return", "returns"]:
newsection = "Return"
self.state = state.SPECIAL_SECTION
elif newsection[0] == '@':
self.state = state.SPECIAL_SECTION
#
# Initialize the contents, and get the new section going.
#
newcontents = doc_sect.group(2)
if not newcontents:
newcontents = ""
self.dump_section()
self.entry.begin_section(ln, newsection)
self.entry.leading_space = None
self.entry.add_text(newcontents.lstrip())
return True
return False
#
# Helper function to detect (and effect) the end of a kerneldoc comment.
#
def is_comment_end(self, ln, line):
if doc_end.search(line):
self.dump_section()
# Look for doc_com + <text> + doc_end:
r = KernRe(r'\s*\*\s*[a-zA-Z_0-9:\.]+\*/')
if r.match(line):
self.emit_msg(ln, f"suspicious ending line: {line}")
self.entry.prototype = ""
self.entry.new_start_line = ln + 1
self.state = state.PROTO
return True
return False
def process_decl(self, ln, line):
"""
STATE_DECLARATION: We've seen the beginning of a declaration
"""
if self.is_new_section(ln, line) or self.is_comment_end(ln, line):
return
#
# Look for anything with the " * " line beginning.
#
if doc_content.search(line):
cont = doc_content.group(1)
#
# A blank line means that we have moved out of the declaration
# part of the comment (without any "special section" parameter
# descriptions).
#
if cont == "":
self.state = state.BODY
#
# Otherwise we have more of the declaration section to soak up.
#
else:
self.entry.declaration_purpose = \
trim_whitespace(self.entry.declaration_purpose + ' ' + cont)
else:
# Unknown line, ignore
self.emit_msg(ln, f"bad line: {line}")
def process_special(self, ln, line):
"""
STATE_SPECIAL_SECTION: a section ending with a blank line
"""
#
# If we have hit a blank line (only the " * " marker), then this
# section is done.
#
if KernRe(r"\s*\*\s*$").match(line):
self.entry.begin_section(ln, dump = True)
self.state = state.BODY
return
#
# Not a blank line, look for the other ways to end the section.
#
if self.is_new_section(ln, line) or self.is_comment_end(ln, line):
return
#
# OK, we should have a continuation of the text for this section.
#
if doc_content.search(line):
cont = doc_content.group(1)
#
# If the lines of text after the first in a special section have
# leading white space, we need to trim it out or Sphinx will get
# confused. For the second line (the None case), see what we
# find there and remember it.
#
if self.entry.leading_space is None:
r = KernRe(r'^(\s+)')
if r.match(cont):
self.entry.leading_space = len(r.group(1))
else:
self.entry.leading_space = 0
#
# Otherwise, before trimming any leading chars, be *sure*
# that they are white space. We should maybe warn if this
# isn't the case.
#
for i in range(0, self.entry.leading_space):
if cont[i] != " ":
self.entry.leading_space = i
break
#
# Add the trimmed result to the section and we're done.
#
self.entry.add_text(cont[self.entry.leading_space:])
else:
# Unknown line, ignore
self.emit_msg(ln, f"bad line: {line}")
def process_body(self, ln, line):
"""
STATE_BODY: the bulk of a kerneldoc comment.
"""
if self.is_new_section(ln, line) or self.is_comment_end(ln, line):
return
if doc_content.search(line):
cont = doc_content.group(1)
self.entry.add_text(cont)
else:
# Unknown line, ignore
self.emit_msg(ln, f"bad line: {line}")
def process_inline_name(self, ln, line):
"""STATE_INLINE_NAME: beginning of docbook comments within a prototype."""
if doc_inline_sect.search(line):
self.entry.begin_section(ln, doc_inline_sect.group(1))
self.entry.add_text(doc_inline_sect.group(2).lstrip())
self.state = state.INLINE_TEXT
elif doc_inline_end.search(line):
self.dump_section()
self.state = state.PROTO
elif doc_content.search(line):
self.emit_msg(ln, f"Incorrect use of kernel-doc format: {line}")
self.state = state.PROTO
# else ... ??
def process_inline_text(self, ln, line):
"""STATE_INLINE_TEXT: docbook comments within a prototype."""
if doc_inline_end.search(line):
self.dump_section()
self.state = state.PROTO
elif doc_content.search(line):
self.entry.add_text(doc_content.group(1))
# else ... ??
def syscall_munge(self, ln, proto): # pylint: disable=W0613
"""
Handle syscall definitions
"""
is_void = False
# Strip newlines/CR's
proto = re.sub(r'[\r\n]+', ' ', proto)
# Check if it's a SYSCALL_DEFINE0
if 'SYSCALL_DEFINE0' in proto:
is_void = True
# Replace SYSCALL_DEFINE with correct return type & function name
proto = KernRe(r'SYSCALL_DEFINE.*\(').sub('long sys_', proto)
r = KernRe(r'long\s+(sys_.*?),')
if r.search(proto):
proto = KernRe(',').sub('(', proto, count=1)
elif is_void:
proto = KernRe(r'\)').sub('(void)', proto, count=1)
# Now delete all of the odd-numbered commas in the proto
# so that argument types & names don't have a comma between them
count = 0
length = len(proto)
if is_void:
length = 0 # skip the loop if is_void
for ix in range(length):
if proto[ix] == ',':
count += 1
if count % 2 == 1:
proto = proto[:ix] + ' ' + proto[ix + 1:]
return proto
def tracepoint_munge(self, ln, proto):
"""
Handle tracepoint definitions
"""
tracepointname = None
tracepointargs = None
# Match tracepoint name based on different patterns
r = KernRe(r'TRACE_EVENT\((.*?),')
if r.search(proto):
tracepointname = r.group(1)
r = KernRe(r'DEFINE_SINGLE_EVENT\((.*?),')
if r.search(proto):
tracepointname = r.group(1)
r = KernRe(r'DEFINE_EVENT\((.*?),(.*?),')
if r.search(proto):
tracepointname = r.group(2)
if tracepointname:
tracepointname = tracepointname.lstrip()
r = KernRe(r'TP_PROTO\((.*?)\)')
if r.search(proto):
tracepointargs = r.group(1)
if not tracepointname or not tracepointargs:
self.emit_msg(ln,
f"Unrecognized tracepoint format:\n{proto}\n")
else:
proto = f"static inline void trace_{tracepointname}({tracepointargs})"
self.entry.identifier = f"trace_{self.entry.identifier}"
return proto
def process_proto_function(self, ln, line):
"""Ancillary routine to process a function prototype"""
# strip C99-style comments to end of line
line = KernRe(r"\/\/.*$", re.S).sub('', line)
#
# Soak up the line's worth of prototype text, stopping at { or ; if present.
#
if KernRe(r'\s*#\s*define').match(line):
self.entry.prototype = line
elif not line.startswith('#'): # skip other preprocessor stuff
r = KernRe(r'([^\{]*)')
if r.match(line):
self.entry.prototype += r.group(1) + " "
#
# If we now have the whole prototype, clean it up and declare victory.
#
if '{' in line or ';' in line or KernRe(r'\s*#\s*define').match(line):
# strip comments and surrounding spaces
self.entry.prototype = KernRe(r'/\*.*\*/').sub('', self.entry.prototype).strip()
#
# Handle self.entry.prototypes for function pointers like:
# int (*pcs_config)(struct foo)
# by turning it into
# int pcs_config(struct foo)
#
r = KernRe(r'^(\S+\s+)\(\s*\*(\S+)\)')
self.entry.prototype = r.sub(r'\1\2', self.entry.prototype)
#
# Handle special declaration syntaxes
#
if 'SYSCALL_DEFINE' in self.entry.prototype:
self.entry.prototype = self.syscall_munge(ln,
self.entry.prototype)
else:
r = KernRe(r'TRACE_EVENT|DEFINE_EVENT|DEFINE_SINGLE_EVENT')
if r.search(self.entry.prototype):
self.entry.prototype = self.tracepoint_munge(ln,
self.entry.prototype)
#
# ... and we're done
#
self.dump_function(ln, self.entry.prototype)
self.reset_state(ln)
def process_proto_type(self, ln, line):
"""Ancillary routine to process a type"""
# Strip C99-style comments and surrounding whitespace
line = KernRe(r"//.*$", re.S).sub('', line).strip()
if not line:
return # nothing to see here
# To distinguish preprocessor directive from regular declaration later.
if line.startswith('#'):
line += ";"
#
# Split the declaration on any of { } or ;, and accumulate pieces
# until we hit a semicolon while not inside {brackets}
#
r = KernRe(r'(.*?)([{};])')
for chunk in r.split(line):
if chunk: # Ignore empty matches
self.entry.prototype += chunk
#
# This cries out for a match statement ... someday after we can
# drop Python 3.9 ...
#
if chunk == '{':
self.entry.brcount += 1
elif chunk == '}':
self.entry.brcount -= 1
elif chunk == ';' and self.entry.brcount <= 0:
self.dump_declaration(ln, self.entry.prototype)
self.reset_state(ln)
return
#
# We hit the end of the line while still in the declaration; put
# in a space to represent the newline.
#
self.entry.prototype += ' '
def process_proto(self, ln, line):
"""STATE_PROTO: reading a function/whatever prototype."""
if doc_inline_oneline.search(line):
self.entry.begin_section(ln, doc_inline_oneline.group(1))
self.entry.add_text(doc_inline_oneline.group(2))
self.dump_section()
elif doc_inline_start.search(line):
self.state = state.INLINE_NAME
elif self.entry.decl_type == 'function':
self.process_proto_function(ln, line)
else:
self.process_proto_type(ln, line)
def process_docblock(self, ln, line):
"""STATE_DOCBLOCK: within a DOC: block."""
if doc_end.search(line):
self.dump_section()
self.output_declaration("doc", self.entry.identifier)
self.reset_state(ln)
elif doc_content.search(line):
self.entry.add_text(doc_content.group(1))
def parse_export(self):
"""
Parses EXPORT_SYMBOL* macros from a single Kernel source file.
"""
export_table = set()
try:
with open(self.fname, "r", encoding="utf8",
errors="backslashreplace") as fp:
for line in fp:
self.process_export(export_table, line)
except IOError:
return None
return export_table
#
# The state/action table telling us which function to invoke in
# each state.
#
state_actions = {
state.NORMAL: process_normal,
state.NAME: process_name,
state.BODY: process_body,
state.DECLARATION: process_decl,
state.SPECIAL_SECTION: process_special,
state.INLINE_NAME: process_inline_name,
state.INLINE_TEXT: process_inline_text,
state.PROTO: process_proto,
state.DOCBLOCK: process_docblock,
}
def parse_kdoc(self):
"""
Open and process each line of a C source file.
The parsing is controlled via a state machine, and the line is passed
to a different process function depending on the state. The process
function may update the state as needed.
Besides parsing kernel-doc tags, it also parses export symbols.
"""
prev = ""
prev_ln = None
export_table = set()
try:
with open(self.fname, "r", encoding="utf8",
errors="backslashreplace") as fp:
for ln, line in enumerate(fp):
line = line.expandtabs().strip("\n")
# Group continuation lines on prototypes
if self.state == state.PROTO:
if line.endswith("\\"):
prev += line.rstrip("\\")
if not prev_ln:
prev_ln = ln
continue
if prev:
ln = prev_ln
line = prev + line
prev = ""
prev_ln = None
self.config.log.debug("%d %s: %s",
ln, state.name[self.state],
line)
# This is an optimization over the original script.
# There, when export_file was used for the same file,
# it was read twice. Here, we use the already-existing
# loop to parse exported symbols as well.
#
if (self.state != state.NORMAL) or \
not self.process_export(export_table, line):
# Hand this line to the appropriate state handler
self.state_actions[self.state](self, ln, line)
except OSError:
self.config.log.error(f"Error: Cannot open file {self.fname}")
return export_table, self.entries
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