cef/tools/cef_parser.py

2126 lines
65 KiB
Python

# Copyright (c) 2011 The Chromium Embedded Framework Authors. All rights
# reserved. Use of this source code is governed by a BSD-style license that
# can be found in the LICENSE file.
from __future__ import absolute_import
from date_util import *
from file_util import *
import os
import re
import shutil
import string
import sys
import textwrap
import time
def notify(msg):
""" Display a message. """
sys.stdout.write(' NOTE: ' + msg + '\n')
def wrap_text(text, indent='', maxchars=80):
""" Wrap the text to the specified number of characters. If
necessary a line will be broken and wrapped after a word.
"""
result = ''
lines = textwrap.wrap(text, maxchars - len(indent))
for line in lines:
result += indent + line + '\n'
return result
def is_base_class(clsname):
""" Returns true if |clsname| is a known base (root) class in the object
hierarchy.
"""
return clsname == 'CefBaseRefCounted' or clsname == 'CefBaseScoped'
def get_capi_file_name(cppname):
""" Convert a C++ header file name to a C API header file name. """
return cppname[:-2] + '_capi.h'
def get_capi_name(cppname, isclassname, prefix=None):
""" Convert a C++ CamelCaps name to a C API underscore name. """
result = ''
lastchr = ''
for chr in cppname:
# add an underscore if the current character is an upper case letter
# and the last character was a lower case letter
if len(result) > 0 and not chr.isdigit() \
and chr.upper() == chr \
and not lastchr.upper() == lastchr:
result += '_'
result += chr.lower()
lastchr = chr
if isclassname:
result += '_t'
if not prefix is None:
if prefix[0:3] == 'cef':
# if the prefix name is duplicated in the function name
# remove that portion of the function name
subprefix = prefix[3:]
pos = result.find(subprefix)
if pos >= 0:
result = result[0:pos] + result[pos + len(subprefix):]
result = prefix + '_' + result
return result
def get_wrapper_type_enum(cppname):
""" Returns the wrapper type enumeration value for the specified C++ class
name. """
return 'WT_' + get_capi_name(cppname, False)[4:].upper()
def get_prev_line(body, pos):
""" Retrieve the start and end positions and value for the line immediately
before the line containing the specified position.
"""
end = body.rfind('\n', 0, pos)
start = body.rfind('\n', 0, end) + 1
line = body[start:end]
return {'start': start, 'end': end, 'line': line}
def get_comment(body, name):
""" Retrieve the comment for a class or function. """
result = []
pos = body.find(name)
in_block_comment = False
while pos > 0:
data = get_prev_line(body, pos)
line = data['line'].strip()
pos = data['start']
if len(line) == 0:
break
# single line /*--cef()--*/
elif line[0:2] == '/*' and line[-2:] == '*/':
continue
# start of multi line /*--cef()--*/
elif in_block_comment and line[0:2] == '/*':
in_block_comment = False
continue
# end of multi line /*--cef()--*/
elif not in_block_comment and line[-2:] == '*/':
in_block_comment = True
continue
elif in_block_comment:
continue
elif line[0:3] == '///':
# keep the comment line including any leading spaces
result.append(line[3:])
else:
break
result.reverse()
return result
def validate_comment(file, name, comment):
""" Validate the comment array returned by get_comment(). """
# Verify that the comment contains beginning and ending '///' as required by
# Doxygen (the leading '///' from each line will already have been removed by
# the get_comment() logic).
if len(comment) < 3 or len(comment[0]) != 0 or len(comment[-1]) != 0:
raise Exception('Missing or incorrect comment in %s for: %s' % \
(file, name))
def format_comment(comment, indent, translate_map=None, maxchars=80):
""" Return the comments array as a formatted string. """
if not translate_map is None:
# Replace longest keys first in translation.
translate_keys = sorted(
translate_map.keys(), key=lambda item: (-len(item), item))
result = ''
wrapme = ''
hasemptyline = False
for line in comment:
# if the line starts with a leading space, remove that space
if not line is None and len(line) > 0 and line[0] == ' ':
line = line[1:]
didremovespace = True
else:
didremovespace = False
if line is None or len(line) == 0 or line[0] == ' ':
# the previous paragraph, if any, has ended
if len(wrapme) > 0:
if not translate_map is None:
# apply the translation
for key in translate_keys:
wrapme = wrapme.replace(key, translate_map[key])
# output the previous paragraph
result += wrap_text(wrapme, indent + '/// ', maxchars)
wrapme = ''
if not line is None:
if len(line) == 0 or line[0] == ' ':
# blank lines or anything that's further indented should be
# output as-is
result += indent + '///'
if len(line) > 0:
if didremovespace:
result += ' ' + line
else:
result += line
result += '\n'
else:
# add to the current paragraph
wrapme += line + ' '
else:
# output an empty line
hasemptyline = True
result += '\n'
if len(wrapme) > 0:
if not translate_map is None:
# apply the translation
for key in translate_map.keys():
wrapme = wrapme.replace(key, translate_map[key])
# output the previous paragraph
result += wrap_text(wrapme, indent + '/// ', maxchars)
if hasemptyline:
# an empty line means a break between comments, so the comment is
# probably a section heading and should have an extra line before it
result = '\n' + result
return result
def format_translation_changes(old, new):
""" Return a comment stating what is different between the old and new
function prototype parts.
"""
changed = False
result = ''
# normalize C API attributes
oldargs = [x.replace('struct _', '') for x in old['args']]
oldretval = old['retval'].replace('struct _', '')
newargs = [x.replace('struct _', '') for x in new['args']]
newretval = new['retval'].replace('struct _', '')
# check if the prototype has changed
oldset = set(oldargs)
newset = set(newargs)
if len(oldset.symmetric_difference(newset)) > 0:
changed = True
result += '\n // WARNING - CHANGED ATTRIBUTES'
# in the implementation set only
oldonly = oldset.difference(newset)
for arg in oldonly:
result += '\n // REMOVED: ' + arg
# in the current set only
newonly = newset.difference(oldset)
for arg in newonly:
result += '\n // ADDED: ' + arg
# check if the return value has changed
if oldretval != newretval:
changed = True
result += '\n // WARNING - CHANGED RETURN VALUE'+ \
'\n // WAS: '+old['retval']+ \
'\n // NOW: '+new['retval']
if changed:
result += '\n #pragma message("Warning: " __FILE__ ": '+new['name']+ \
' prototype has changed")\n'
return result
def format_translation_includes(header, body):
""" Return the necessary list of includes based on the contents of the
body.
"""
result = ''
# <algorithm> required for VS2013.
if body.find('std::min') > 0 or body.find('std::max') > 0:
result += '#include <algorithm>\n'
if body.find('cef_api_hash(') > 0:
result += '#include "include/cef_api_hash.h"\n'
if body.find('template_util::has_valid_size(') > 0:
result += '#include "libcef_dll/template_util.h"\n'
# identify what CppToC classes are being used
p = re.compile('([A-Za-z0-9_]{1,})CppToC')
list = sorted(set(p.findall(body)))
for item in list:
directory = ''
if not is_base_class(item):
cls = header.get_class(item)
dir = cls.get_file_directory()
if not dir is None:
directory = dir + '/'
result += '#include "libcef_dll/cpptoc/'+directory+ \
get_capi_name(item[3:], False)+'_cpptoc.h"\n'
# identify what CToCpp classes are being used
p = re.compile('([A-Za-z0-9_]{1,})CToCpp')
list = sorted(set(p.findall(body)))
for item in list:
directory = ''
if not is_base_class(item):
cls = header.get_class(item)
dir = cls.get_file_directory()
if not dir is None:
directory = dir + '/'
result += '#include "libcef_dll/ctocpp/'+directory+ \
get_capi_name(item[3:], False)+'_ctocpp.h"\n'
if body.find('shutdown_checker') > 0:
result += '#include "libcef_dll/shutdown_checker.h"\n'
if body.find('transfer_') > 0:
result += '#include "libcef_dll/transfer_util.h"\n'
return result
def str_to_dict(str):
""" Convert a string to a dictionary. If the same key has multiple values
the values will be stored in a list. """
dict = {}
parts = str.split(',')
for part in parts:
part = part.strip()
if len(part) == 0:
continue
sparts = part.split('=')
if len(sparts) > 2:
raise Exception('Invalid dictionary pair format: ' + part)
name = sparts[0].strip()
if len(sparts) == 2:
val = sparts[1].strip()
else:
val = True
if name in dict:
# a value with this name already exists
curval = dict[name]
if not isinstance(curval, list):
# convert the string value to a list
dict[name] = [curval]
dict[name].append(val)
else:
dict[name] = val
return dict
def dict_to_str(dict):
""" Convert a dictionary to a string. """
str = []
for name in dict.keys():
if not isinstance(dict[name], list):
if dict[name] is True:
# currently a bool value
str.append(name)
else:
# currently a string value
str.append(name + '=' + dict[name])
else:
# currently a list value
for val in dict[name]:
str.append(name + '=' + val)
return ','.join(str)
# regex for matching comment-formatted attributes
_cre_attrib = '/\*--cef\(([A-Za-z0-9_ ,=:\n]{0,})\)--\*/'
# regex for matching class and function names
_cre_cfname = '([A-Za-z0-9_]{1,})'
# regex for matching class and function names including path separators
_cre_cfnameorpath = '([A-Za-z0-9_\/]{1,})'
# regex for matching function return values
_cre_retval = '([A-Za-z0-9_<>:,\*\&]{1,})'
# regex for matching typedef value and name combination
_cre_typedef = '([A-Za-z0-9_<>:,\*\&\s]{1,})'
# regex for matching function return value and name combination
_cre_func = '([A-Za-z][A-Za-z0-9_<>:,\*\&\s]{1,})'
# regex for matching virtual function modifiers + arbitrary whitespace
_cre_vfmod = '([\sA-Za-z0-9_]{0,})'
# regex for matching arbitrary whitespace
_cre_space = '[\s]{1,}'
# regex for matching optional virtual keyword
_cre_virtual = '(?:[\s]{1,}virtual){0,1}'
# Simple translation types. Format is:
# 'cpp_type' : ['capi_type', 'capi_default_value']
_simpletypes = {
'void': ['void', ''],
'void*': ['void*', 'NULL'],
'int': ['int', '0'],
'int16': ['int16', '0'],
'uint16': ['uint16', '0'],
'int32': ['int32', '0'],
'uint32': ['uint32', '0'],
'int64': ['int64', '0'],
'uint64': ['uint64', '0'],
'double': ['double', '0'],
'float': ['float', '0'],
'float*': ['float*', 'NULL'],
'long': ['long', '0'],
'unsigned long': ['unsigned long', '0'],
'long long': ['long long', '0'],
'size_t': ['size_t', '0'],
'bool': ['int', '0'],
'char': ['char', '0'],
'char* const': ['char* const', 'NULL'],
'cef_color_t': ['cef_color_t', '0'],
'cef_json_parser_error_t': ['cef_json_parser_error_t', 'JSON_NO_ERROR'],
'CefAudioParameters': ['cef_audio_parameters_t', 'CefAudioParameters()'],
'CefBaseTime': ['cef_basetime_t', 'CefBaseTime()'],
'CefBoxLayoutSettings': [
'cef_box_layout_settings_t', 'CefBoxLayoutSettings()'
],
'CefCompositionUnderline': [
'cef_composition_underline_t', 'CefCompositionUnderline()'
],
'CefCursorHandle': ['cef_cursor_handle_t', 'kNullCursorHandle'],
'CefCursorInfo': ['cef_cursor_info_t', 'CefCursorInfo()'],
'CefDraggableRegion': ['cef_draggable_region_t', 'CefDraggableRegion()'],
'CefEventHandle': ['cef_event_handle_t', 'kNullEventHandle'],
'CefInsets': ['cef_insets_t', 'CefInsets()'],
'CefKeyEvent': ['cef_key_event_t', 'CefKeyEvent()'],
'CefMainArgs': ['cef_main_args_t', 'CefMainArgs()'],
'CefMouseEvent': ['cef_mouse_event_t', 'CefMouseEvent()'],
'CefPoint': ['cef_point_t', 'CefPoint()'],
'CefPopupFeatures': ['cef_popup_features_t', 'CefPopupFeatures()'],
'CefRange': ['cef_range_t', 'CefRange()'],
'CefRect': ['cef_rect_t', 'CefRect()'],
'CefScreenInfo': ['cef_screen_info_t', 'CefScreenInfo()'],
'CefSize': ['cef_size_t', 'CefSize()'],
'CefTouchEvent': ['cef_touch_event_t', 'CefTouchEvent()'],
'CefTouchHandleState': [
'cef_touch_handle_state_t', 'CefTouchHandleState()'
],
'CefThreadId': ['cef_thread_id_t', 'TID_UI'],
'CefTime': ['cef_time_t', 'CefTime()'],
'CefWindowHandle': ['cef_window_handle_t', 'kNullWindowHandle'],
}
def get_function_impls(content, ident, has_impl=True):
""" Retrieve the function parts from the specified contents as a set of
return value, name, arguments and body. Ident must occur somewhere in
the value.
"""
# extract the functions
find_regex = '\n' + _cre_func + '\((.*?)\)([A-Za-z0-9_\s]{0,})'
if has_impl:
find_regex += '\{(.*?)\n\}'
else:
find_regex += '(;)'
p = re.compile(find_regex, re.MULTILINE | re.DOTALL)
list = p.findall(content)
# build the function map with the function name as the key
result = []
for retval, argval, vfmod, body in list:
if retval.find(ident) < 0:
# the identifier was not found
continue
# remove the identifier
retval = retval.replace(ident, '')
retval = retval.strip()
# Normalize the delimiter.
retval = retval.replace('\n', ' ')
# retrieve the function name
parts = retval.split(' ')
name = parts[-1]
del parts[-1]
retval = ' '.join(parts)
# parse the arguments
args = []
if argval != 'void':
for v in argval.split(','):
v = v.strip()
if len(v) > 0:
args.append(v)
result.append({
'retval': retval.strip(),
'name': name,
'args': args,
'vfmod': vfmod.strip(),
'body': body if has_impl else '',
})
return result
def get_next_function_impl(existing, name):
result = None
for item in existing:
if item['name'] == name:
result = item
existing.remove(item)
break
return result
def get_copyright(full=False, translator=True):
if full:
result = \
"""// Copyright (c) $YEAR$ Marshall A. Greenblatt. All rights reserved.
//
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following disclaimer
// in the documentation and/or other materials provided with the
// distribution.
// * Neither the name of Google Inc. nor the name Chromium Embedded
// Framework nor the names of its contributors may be used to endorse
// or promote products derived from this software without specific prior
// written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
"""
else:
result = \
"""// Copyright (c) $YEAR$ The Chromium Embedded Framework Authors. All rights
// reserved. Use of this source code is governed by a BSD-style license that
// can be found in the LICENSE file.
"""
if translator:
result += \
"""//
// ---------------------------------------------------------------------------
//
// This file was generated by the CEF translator tool. If making changes by
// hand only do so within the body of existing method and function
// implementations. See the translator.README.txt file in the tools directory
// for more information.
//
// $hash=$$HASH$$$
//
"""
# add the copyright year
return result.replace('$YEAR$', get_year())
class obj_header:
""" Class representing a C++ header file. """
def __init__(self):
self.filenames = []
self.typedefs = []
self.funcs = []
self.classes = []
self.root_directory = None
def set_root_directory(self, root_directory):
""" Set the root directory. """
self.root_directory = root_directory
def get_root_directory(self):
""" Get the root directory. """
return self.root_directory
def add_directory(self, directory, excluded_files=[]):
""" Add all header files from the specified directory. """
files = get_files(os.path.join(directory, '*.h'))
for file in files:
if len(excluded_files) == 0 or \
not os.path.split(file)[1] in excluded_files:
self.add_file(file)
def add_file(self, filepath):
""" Add a header file. """
if self.root_directory is None:
filename = os.path.split(filepath)[1]
else:
filename = os.path.relpath(filepath, self.root_directory)
filename = filename.replace('\\', '/')
# read the input file into memory
self.add_data(filename, read_file(filepath))
def add_data(self, filename, data):
""" Add header file contents. """
added = False
# remove space from between template definition end brackets
data = data.replace("> >", ">>")
# extract global typedefs
p = re.compile('\ntypedef' + _cre_space + _cre_typedef + ';',
re.MULTILINE | re.DOTALL)
list = p.findall(data)
if len(list) > 0:
# build the global typedef objects
for value in list:
pos = value.rfind(' ')
if pos < 0:
raise Exception('Invalid typedef: ' + value)
alias = value[pos + 1:].strip()
value = value[:pos].strip()
self.typedefs.append(obj_typedef(self, filename, value, alias))
# extract global functions
p = re.compile('\n' + _cre_attrib + '\n' + _cre_func + '\((.*?)\)',
re.MULTILINE | re.DOTALL)
list = p.findall(data)
if len(list) > 0:
added = True
# build the global function objects
for attrib, retval, argval in list:
comment = get_comment(data, retval + '(' + argval + ');')
validate_comment(filename, retval, comment)
self.funcs.append(
obj_function(self, filename, attrib, retval, argval, comment))
# extract includes
p = re.compile('\n#include \"include/' + _cre_cfnameorpath + '.h')
includes = p.findall(data)
# extract forward declarations
p = re.compile('\nclass' + _cre_space + _cre_cfname + ';')
forward_declares = p.findall(data)
# extract empty classes
p = re.compile('\n' + _cre_attrib + '\nclass' + _cre_space + _cre_cfname +
_cre_space + ':' + _cre_space + 'public' + _cre_virtual +
_cre_space + _cre_cfname + _cre_space + '{};',
re.MULTILINE | re.DOTALL)
list = p.findall(data)
if len(list) > 0:
added = True
# build the class objects
for attrib, name, parent_name in list:
# Style may place the ':' on the next line.
comment = get_comment(data, name + ' :')
if len(comment) == 0:
comment = get_comment(data, name + "\n")
validate_comment(filename, name, comment)
self.classes.append(
obj_class(self, filename, attrib, name, parent_name, "", comment,
includes, forward_declares))
# Remove empty classes from |data| so we don't mess up the non-empty
# class search that follows.
data = p.sub('', data)
# extract classes
p = re.compile('\n' + _cre_attrib + '\nclass' + _cre_space + _cre_cfname +
_cre_space + ':' + _cre_space + 'public' + _cre_virtual +
_cre_space + _cre_cfname + _cre_space + '{(.*?)\n};',
re.MULTILINE | re.DOTALL)
list = p.findall(data)
if len(list) > 0:
added = True
# build the class objects
for attrib, name, parent_name, body in list:
# Style may place the ':' on the next line.
comment = get_comment(data, name + ' :')
if len(comment) == 0:
comment = get_comment(data, name + "\n")
validate_comment(filename, name, comment)
self.classes.append(
obj_class(self, filename, attrib, name, parent_name, body, comment,
includes, forward_declares))
if added:
# a global function or class was read from the header file
self.filenames.append(filename)
def __repr__(self):
result = ''
if len(self.typedefs) > 0:
strlist = []
for cls in self.typedefs:
strlist.append(str(cls))
result += "\n".join(strlist) + "\n\n"
if len(self.funcs) > 0:
strlist = []
for cls in self.funcs:
strlist.append(str(cls))
result += "\n".join(strlist) + "\n\n"
if len(self.classes) > 0:
strlist = []
for cls in self.classes:
strlist.append(str(cls))
result += "\n".join(strlist)
return result
def get_file_names(self):
""" Return the array of header file names. """
return self.filenames
def get_typedefs(self):
""" Return the array of typedef objects. """
return self.typedefs
def get_funcs(self, filename=None):
""" Return the array of function objects. """
if filename is None:
return self.funcs
else:
# only return the functions in the specified file
res = []
for func in self.funcs:
if func.get_file_name() == filename:
res.append(func)
return res
def get_classes(self, filename=None):
""" Return the array of class objects. """
if filename is None:
return self.classes
else:
# only return the classes in the specified file
res = []
for cls in self.classes:
if cls.get_file_name() == filename:
res.append(cls)
return res
def get_class(self, classname, defined_structs=None):
""" Return the specified class or None if not found. """
for cls in self.classes:
if cls.get_name() == classname:
return cls
elif not defined_structs is None:
defined_structs.append(cls.get_capi_name())
return None
def get_class_names(self):
""" Returns the names of all classes in this object. """
result = []
for cls in self.classes:
result.append(cls.get_name())
return result
def get_base_class_name(self, classname):
""" Returns the base (root) class name for |classname|. """
cur_cls = self.get_class(classname)
while True:
parent_name = cur_cls.get_parent_name()
if is_base_class(parent_name):
return parent_name
else:
parent_cls = self.get_class(parent_name)
if parent_cls is None:
break
cur_cls = self.get_class(parent_name)
return None
def get_types(self, list):
""" Return a dictionary mapping data types to analyzed values. """
for cls in self.typedefs:
cls.get_types(list)
for cls in self.classes:
cls.get_types(list)
def get_alias_translation(self, alias):
""" Return a translation of alias to value based on typedef
statements. """
for cls in self.typedefs:
if cls.alias == alias:
return cls.value
return None
def get_analysis(self, value, named=True):
""" Return an analysis of the value based the header file context. """
return obj_analysis([self], value, named)
def get_defined_structs(self):
""" Return a list of already defined structure names. """
return [
'cef_print_info_t', 'cef_window_info_t', 'cef_base_ref_counted_t',
'cef_base_scoped_t'
]
def get_capi_translations(self):
""" Return a dictionary that maps C++ terminology to C API terminology.
"""
# strings that will be changed in C++ comments
map = {
'class': 'structure',
'Class': 'Structure',
'interface': 'structure',
'Interface': 'Structure',
'true': 'true (1)',
'false': 'false (0)',
'empty': 'NULL',
'method': 'function'
}
# add mappings for all classes and functions
funcs = self.get_funcs()
for func in funcs:
map[func.get_name() + '()'] = func.get_capi_name() + '()'
classes = self.get_classes()
for cls in classes:
map[cls.get_name()] = cls.get_capi_name()
funcs = cls.get_virtual_funcs()
for func in funcs:
map[func.get_name() + '()'] = func.get_capi_name() + '()'
funcs = cls.get_static_funcs()
for func in funcs:
map[func.get_name() + '()'] = func.get_capi_name() + '()'
return map
class obj_class:
""" Class representing a C++ class. """
def __init__(self, parent, filename, attrib, name, parent_name, body, comment,
includes, forward_declares):
if not isinstance(parent, obj_header):
raise Exception('Invalid parent object type')
self.parent = parent
self.filename = filename
self.attribs = str_to_dict(attrib)
self.name = name
self.parent_name = parent_name
self.comment = comment
self.includes = includes
self.forward_declares = forward_declares
# extract typedefs
p = re.compile(
'\n' + _cre_space + 'typedef' + _cre_space + _cre_typedef + ';',
re.MULTILINE | re.DOTALL)
list = p.findall(body)
# build the typedef objects
self.typedefs = []
for value in list:
pos = value.rfind(' ')
if pos < 0:
raise Exception('Invalid typedef: ' + value)
alias = value[pos + 1:].strip()
value = value[:pos].strip()
self.typedefs.append(obj_typedef(self, filename, value, alias))
# extract static functions
p = re.compile('\n' + _cre_space + _cre_attrib + '\n' + _cre_space +
'static' + _cre_space + _cre_func + '\((.*?)\)',
re.MULTILINE | re.DOTALL)
list = p.findall(body)
# build the static function objects
self.staticfuncs = []
for attrib, retval, argval in list:
comment = get_comment(body, retval + '(' + argval + ')')
validate_comment(filename, retval, comment)
self.staticfuncs.append(
obj_function_static(self, attrib, retval, argval, comment))
# extract virtual functions
p = re.compile(
'\n' + _cre_space + _cre_attrib + '\n' + _cre_space + 'virtual' +
_cre_space + _cre_func + '\((.*?)\)' + _cre_vfmod,
re.MULTILINE | re.DOTALL)
list = p.findall(body)
# build the virtual function objects
self.virtualfuncs = []
for attrib, retval, argval, vfmod in list:
comment = get_comment(body, retval + '(' + argval + ')')
validate_comment(filename, retval, comment)
self.virtualfuncs.append(
obj_function_virtual(self, attrib, retval, argval, comment,
vfmod.strip()))
def __repr__(self):
result = '/* ' + dict_to_str(
self.attribs) + ' */ class ' + self.name + "\n{"
if len(self.typedefs) > 0:
result += "\n\t"
strlist = []
for cls in self.typedefs:
strlist.append(str(cls))
result += "\n\t".join(strlist)
if len(self.staticfuncs) > 0:
result += "\n\t"
strlist = []
for cls in self.staticfuncs:
strlist.append(str(cls))
result += "\n\t".join(strlist)
if len(self.virtualfuncs) > 0:
result += "\n\t"
strlist = []
for cls in self.virtualfuncs:
strlist.append(str(cls))
result += "\n\t".join(strlist)
result += "\n};\n"
return result
def get_file_name(self):
""" Return the C++ header file name. Includes the directory component,
if any. """
return self.filename
def get_capi_file_name(self):
""" Return the CAPI header file name. Includes the directory component,
if any. """
return get_capi_file_name(self.filename)
def get_file_directory(self):
""" Return the file directory component, if any. """
pos = self.filename.rfind('/')
if pos >= 0:
return self.filename[:pos]
return None
def get_name(self):
""" Return the class name. """
return self.name
def get_capi_name(self):
""" Return the CAPI structure name for this class. """
return get_capi_name(self.name, True)
def get_parent_name(self):
""" Return the parent class name. """
return self.parent_name
def get_parent_capi_name(self):
""" Return the CAPI structure name for the parent class. """
return get_capi_name(self.parent_name, True)
def has_parent(self, parent_name):
""" Returns true if this class has the specified class anywhere in its
inheritance hierarchy. """
# Every class has a known base class as the top-most parent.
if is_base_class(parent_name) or parent_name == self.parent_name:
return True
if is_base_class(self.parent_name):
return False
cur_cls = self.parent.get_class(self.parent_name)
while True:
cur_parent_name = cur_cls.get_parent_name()
if is_base_class(cur_parent_name):
break
elif cur_parent_name == parent_name:
return True
cur_cls = self.parent.get_class(cur_parent_name)
return False
def get_comment(self):
""" Return the class comment as an array of lines. """
return self.comment
def get_includes(self):
""" Return the list of classes that are included from this class'
header file. """
return self.includes
def get_forward_declares(self):
""" Return the list of classes that are forward declared for this
class. """
return self.forward_declares
def get_attribs(self):
""" Return all attributes as a dictionary. """
return self.attribs
def has_attrib(self, name):
""" Return true if the specified attribute exists. """
return name in self.attribs
def get_attrib(self, name):
""" Return the first or only value for specified attribute. """
if name in self.attribs:
if isinstance(self.attribs[name], list):
# the value is a list
return self.attribs[name][0]
else:
# the value is a string
return self.attribs[name]
return None
def get_attrib_list(self, name):
""" Return all values for specified attribute as a list. """
if name in self.attribs:
if isinstance(self.attribs[name], list):
# the value is already a list
return self.attribs[name]
else:
# convert the value to a list
return [self.attribs[name]]
return None
def get_typedefs(self):
""" Return the array of typedef objects. """
return self.typedefs
def has_typedef_alias(self, alias):
""" Returns true if the specified typedef alias is defined in the scope
of this class declaration. """
for typedef in self.typedefs:
if typedef.get_alias() == alias:
return True
return False
def get_static_funcs(self):
""" Return the array of static function objects. """
return self.staticfuncs
def get_virtual_funcs(self):
""" Return the array of virtual function objects. """
return self.virtualfuncs
def get_types(self, list):
""" Return a dictionary mapping data types to analyzed values. """
for cls in self.typedefs:
cls.get_types(list)
for cls in self.staticfuncs:
cls.get_types(list)
for cls in self.virtualfuncs:
cls.get_types(list)
def get_alias_translation(self, alias):
for cls in self.typedefs:
if cls.alias == alias:
return cls.value
return None
def get_analysis(self, value, named=True):
""" Return an analysis of the value based on the class definition
context.
"""
return obj_analysis([self, self.parent], value, named)
def is_library_side(self):
""" Returns true if the class is implemented by the library. """
return self.attribs['source'] == 'library'
def is_client_side(self):
""" Returns true if the class is implemented by the client. """
return self.attribs['source'] == 'client'
class obj_typedef:
""" Class representing a typedef statement. """
def __init__(self, parent, filename, value, alias):
if not isinstance(parent, obj_header) \
and not isinstance(parent, obj_class):
raise Exception('Invalid parent object type')
self.parent = parent
self.filename = filename
self.alias = alias
self.value = self.parent.get_analysis(value, False)
def __repr__(self):
return 'typedef ' + self.value.get_type() + ' ' + self.alias + ';'
def get_file_name(self):
""" Return the C++ header file name. """
return self.filename
def get_capi_file_name(self):
""" Return the CAPI header file name. """
return get_capi_file_name(self.filename)
def get_alias(self):
""" Return the alias. """
return self.alias
def get_value(self):
""" Return an analysis of the value based on the class or header file
definition context.
"""
return self.value
def get_types(self, list):
""" Return a dictionary mapping data types to analyzed values. """
name = self.value.get_type()
if not name in list:
list[name] = self.value
class obj_function:
""" Class representing a function. """
def __init__(self, parent, filename, attrib, retval, argval, comment):
self.parent = parent
self.filename = filename
self.attribs = str_to_dict(attrib)
self.retval = obj_argument(self, retval)
self.name = self.retval.remove_name()
self.comment = comment
# build the argument objects
self.arguments = []
arglist = argval.split(',')
argindex = 0
while argindex < len(arglist):
arg = arglist[argindex]
if arg.find('<') >= 0 and arg.find('>') == -1:
# We've split inside of a template type declaration. Join the
# next argument with this argument.
argindex += 1
arg += ',' + arglist[argindex]
arg = arg.strip()
if len(arg) > 0:
argument = obj_argument(self, arg)
if argument.needs_attrib_count_func() and \
argument.get_attrib_count_func() is None:
raise Exception("A 'count_func' attribute is required "+ \
"for the '"+argument.get_name()+ \
"' parameter to "+self.get_qualified_name())
self.arguments.append(argument)
argindex += 1
if self.retval.needs_attrib_default_retval() and \
self.retval.get_attrib_default_retval() is None:
raise Exception("A 'default_retval' attribute is required for "+ \
self.get_qualified_name())
def __repr__(self):
return '/* ' + dict_to_str(self.attribs) + ' */ ' + self.get_cpp_proto()
def get_file_name(self):
""" Return the C++ header file name. """
return self.filename
def get_capi_file_name(self):
""" Return the CAPI header file name. """
return get_capi_file_name(self.filename)
def get_name(self):
""" Return the function name. """
return self.name
def get_qualified_name(self):
""" Return the fully qualified function name. """
if isinstance(self.parent, obj_header):
# global function
return self.name
else:
# member function
return self.parent.get_name() + '::' + self.name
def get_capi_name(self, prefix=None):
""" Return the CAPI function name. """
if 'capi_name' in self.attribs:
return self.attribs['capi_name']
return get_capi_name(self.name, False, prefix)
def get_comment(self):
""" Return the function comment as an array of lines. """
return self.comment
def get_attribs(self):
""" Return all attributes as a dictionary. """
return self.attribs
def has_attrib(self, name):
""" Return true if the specified attribute exists. """
return name in self.attribs
def get_attrib(self, name):
""" Return the first or only value for specified attribute. """
if name in self.attribs:
if isinstance(self.attribs[name], list):
# the value is a list
return self.attribs[name][0]
else:
# the value is a string
return self.attribs[name]
return None
def get_attrib_list(self, name):
""" Return all values for specified attribute as a list. """
if name in self.attribs:
if isinstance(self.attribs[name], list):
# the value is already a list
return self.attribs[name]
else:
# convert the value to a list
return [self.attribs[name]]
return None
def get_retval(self):
""" Return the return value object. """
return self.retval
def get_arguments(self):
""" Return the argument array. """
return self.arguments
def get_types(self, list):
""" Return a dictionary mapping data types to analyzed values. """
for cls in self.arguments:
cls.get_types(list)
def get_capi_parts(self, defined_structs=[], isimpl=False, prefix=None):
""" Return the parts of the C API function definition. """
retval = ''
dict = self.retval.get_type().get_capi(defined_structs)
if dict['format'] == 'single':
retval = dict['value']
name = self.get_capi_name(prefix)
args = []
if isinstance(self, obj_function_virtual):
# virtual functions get themselves as the first argument
str = 'struct _' + self.parent.get_capi_name() + '* self'
if isinstance(self, obj_function_virtual) and self.is_const():
# const virtual functions get const self pointers
str = 'const ' + str
args.append(str)
elif not isimpl and len(self.arguments) == 0:
args.append('void')
if len(self.arguments) > 0:
for cls in self.arguments:
type = cls.get_type()
dict = type.get_capi(defined_structs)
if dict['format'] == 'single':
args.append(dict['value'])
elif dict['format'] == 'multi-arg':
# add an additional argument for the size of the array
type_name = type.get_name()
if type.is_const():
# for const arrays pass the size argument by value
args.append('size_t ' + type_name + 'Count')
else:
# for non-const arrays pass the size argument by address
args.append('size_t* ' + type_name + 'Count')
args.append(dict['value'])
return {'retval': retval, 'name': name, 'args': args}
def get_capi_proto(self, defined_structs=[], isimpl=False, prefix=None):
""" Return the prototype of the C API function. """
parts = self.get_capi_parts(defined_structs, isimpl, prefix)
result = parts['retval']+' '+parts['name']+ \
'('+', '.join(parts['args'])+')'
return result
def get_cpp_parts(self, isimpl=False):
""" Return the parts of the C++ function definition. """
retval = str(self.retval)
name = self.name
args = []
if len(self.arguments) > 0:
for cls in self.arguments:
args.append(str(cls))
if isimpl and isinstance(self, obj_function_virtual):
# enumeration return values must be qualified with the class name
# if the type is defined in the class declaration scope.
type = self.get_retval().get_type()
if type.is_result_struct() and type.is_result_struct_enum() and \
self.parent.has_typedef_alias(retval):
retval = self.parent.get_name() + '::' + retval
return {'retval': retval, 'name': name, 'args': args}
def get_cpp_proto(self, classname=None):
""" Return the prototype of the C++ function. """
parts = self.get_cpp_parts()
result = parts['retval'] + ' '
if not classname is None:
result += classname + '::'
result += parts['name'] + '(' + ', '.join(parts['args']) + ')'
if isinstance(self, obj_function_virtual) and self.is_const():
result += ' const'
return result
def is_same_side(self, other_class_name):
""" Returns true if this function is on the same side (library or
client) and the specified class. """
if isinstance(self.parent, obj_class):
# this function is part of a class
this_is_library_side = self.parent.is_library_side()
header = self.parent.parent
else:
# this function is global
this_is_library_side = True
header = self.parent
if is_base_class(other_class_name):
other_is_library_side = False
else:
other_class = header.get_class(other_class_name)
if other_class is None:
raise Exception('Unknown class: ' + other_class_name)
other_is_library_side = other_class.is_library_side()
return other_is_library_side == this_is_library_side
class obj_function_static(obj_function):
""" Class representing a static function. """
def __init__(self, parent, attrib, retval, argval, comment):
if not isinstance(parent, obj_class):
raise Exception('Invalid parent object type')
obj_function.__init__(self, parent, parent.filename, attrib, retval, argval,
comment)
def __repr__(self):
return 'static ' + obj_function.__repr__(self) + ';'
def get_capi_name(self, prefix=None):
""" Return the CAPI function name. """
if prefix is None:
# by default static functions are prefixed with the class name
prefix = get_capi_name(self.parent.get_name(), False)
return obj_function.get_capi_name(self, prefix)
class obj_function_virtual(obj_function):
""" Class representing a virtual function. """
def __init__(self, parent, attrib, retval, argval, comment, vfmod):
if not isinstance(parent, obj_class):
raise Exception('Invalid parent object type')
obj_function.__init__(self, parent, parent.filename, attrib, retval, argval,
comment)
if vfmod == 'const':
self.isconst = True
else:
self.isconst = False
def __repr__(self):
return 'virtual ' + obj_function.__repr__(self) + ';'
def is_const(self):
""" Returns true if the method declaration is const. """
return self.isconst
class obj_argument:
""" Class representing a function argument. """
def __init__(self, parent, argval):
if not isinstance(parent, obj_function):
raise Exception('Invalid parent object type')
self.parent = parent
self.type = self.parent.parent.get_analysis(argval)
def __repr__(self):
result = ''
if self.type.is_const():
result += 'const '
result += self.type.get_type()
if self.type.is_byref():
result += '&'
elif self.type.is_byaddr():
result += '*'
if self.type.has_name():
result += ' ' + self.type.get_name()
return result
def get_name(self):
""" Return the name for this argument. """
return self.type.get_name()
def remove_name(self):
""" Remove and return the name value. """
name = self.type.get_name()
self.type.name = None
return name
def get_type(self):
""" Return an analysis of the argument type based on the class
definition context.
"""
return self.type
def get_types(self, list):
""" Return a dictionary mapping data types to analyzed values. """
name = self.type.get_type()
if not name in list:
list[name] = self.type
def needs_attrib_count_func(self):
""" Returns true if this argument requires a 'count_func' attribute. """
# A 'count_func' attribute is required for non-const non-string vector
# attribute types
return self.type.has_name() and \
self.type.is_result_vector() and \
not self.type.is_result_vector_string() and \
not self.type.is_const()
def get_attrib_count_func(self):
""" Returns the count function for this argument. """
# The 'count_func' attribute value format is name:function
if not self.parent.has_attrib('count_func'):
return None
name = self.type.get_name()
vals = self.parent.get_attrib_list('count_func')
for val in vals:
parts = val.split(':')
if len(parts) != 2:
raise Exception("Invalid 'count_func' attribute value for "+ \
self.parent.get_qualified_name()+': '+val)
if parts[0].strip() == name:
return parts[1].strip()
return None
def needs_attrib_default_retval(self):
""" Returns true if this argument requires a 'default_retval' attribute.
"""
# A 'default_retval' attribute is required for enumeration return value
# types.
return not self.type.has_name() and \
self.type.is_result_struct() and \
self.type.is_result_struct_enum()
def get_attrib_default_retval(self):
""" Returns the defualt return value for this argument. """
return self.parent.get_attrib('default_retval')
def get_arg_type(self):
""" Returns the argument type as defined in translator.README.txt. """
if not self.type.has_name():
raise Exception('Cannot be called for retval types')
# simple or enumeration type
if (self.type.is_result_simple() and \
self.type.get_type() != 'bool') or \
(self.type.is_result_struct() and \
self.type.is_result_struct_enum()):
if self.type.is_byref():
if self.type.is_const():
return 'simple_byref_const'
return 'simple_byref'
elif self.type.is_byaddr():
return 'simple_byaddr'
return 'simple_byval'
# boolean type
if self.type.get_type() == 'bool':
if self.type.is_byref():
return 'bool_byref'
elif self.type.is_byaddr():
return 'bool_byaddr'
return 'bool_byval'
# structure type
if self.type.is_result_struct() and self.type.is_byref():
if self.type.is_const():
return 'struct_byref_const'
return 'struct_byref'
# string type
if self.type.is_result_string() and self.type.is_byref():
if self.type.is_const():
return 'string_byref_const'
return 'string_byref'
# *ptr type
if self.type.is_result_ptr():
prefix = self.type.get_result_ptr_type_prefix()
same_side = self.parent.is_same_side(self.type.get_ptr_type())
if self.type.is_byref():
if same_side:
return prefix + 'ptr_same_byref'
return prefix + 'ptr_diff_byref'
if same_side:
return prefix + 'ptr_same'
return prefix + 'ptr_diff'
if self.type.is_result_vector():
# all vector types must be passed by reference
if not self.type.is_byref():
return 'invalid'
if self.type.is_result_vector_string():
# string vector type
if self.type.is_const():
return 'string_vec_byref_const'
return 'string_vec_byref'
if self.type.is_result_vector_simple():
if self.type.get_vector_type() != 'bool':
# simple/enumeration vector types
if self.type.is_const():
return 'simple_vec_byref_const'
return 'simple_vec_byref'
# boolean vector types
if self.type.is_const():
return 'bool_vec_byref_const'
return 'bool_vec_byref'
if self.type.is_result_vector_ptr():
# *ptr vector types
prefix = self.type.get_result_vector_ptr_type_prefix()
same_side = self.parent.is_same_side(self.type.get_ptr_type())
if self.type.is_const():
if same_side:
return prefix + 'ptr_vec_same_byref_const'
return prefix + 'ptr_vec_diff_byref_const'
if same_side:
return prefix + 'ptr_vec_same_byref'
return prefix + 'ptr_vec_diff_byref'
# string single map type
if self.type.is_result_map_single():
if not self.type.is_byref():
return 'invalid'
if self.type.is_const():
return 'string_map_single_byref_const'
return 'string_map_single_byref'
# string multi map type
if self.type.is_result_map_multi():
if not self.type.is_byref():
return 'invalid'
if self.type.is_const():
return 'string_map_multi_byref_const'
return 'string_map_multi_byref'
return 'invalid'
def get_retval_type(self):
""" Returns the retval type as defined in translator.README.txt. """
if self.type.has_name():
raise Exception('Cannot be called for argument types')
# unsupported modifiers
if self.type.is_const() or self.type.is_byref() or \
self.type.is_byaddr():
return 'invalid'
# void types don't have a return value
if self.type.get_type() == 'void':
return 'none'
if (self.type.is_result_simple() and \
self.type.get_type() != 'bool') or \
(self.type.is_result_struct() and self.type.is_result_struct_enum()):
return 'simple'
if self.type.get_type() == 'bool':
return 'bool'
if self.type.is_result_string():
return 'string'
if self.type.is_result_ptr():
prefix = self.type.get_result_ptr_type_prefix()
if self.parent.is_same_side(self.type.get_ptr_type()):
return prefix + 'ptr_same'
else:
return prefix + 'ptr_diff'
return 'invalid'
def get_retval_default(self, for_capi):
""" Returns the default return value based on the retval type. """
# start with the default retval attribute, if any.
retval = self.get_attrib_default_retval()
if not retval is None:
if for_capi:
# apply any appropriate C API translations.
if retval == 'true':
return '1'
if retval == 'false':
return '0'
return retval
# next look at the retval type value.
type = self.get_retval_type()
if type == 'simple':
return self.get_type().get_result_simple_default()
elif type == 'bool':
if for_capi:
return '0'
return 'false'
elif type == 'string':
if for_capi:
return 'NULL'
return 'CefString()'
elif type == 'refptr_same' or type == 'refptr_diff' or \
type == 'rawptr_same' or type == 'rawptr_diff':
if for_capi:
return 'NULL'
return 'nullptr'
elif type == 'ownptr_same' or type == 'ownptr_diff':
if for_capi:
return 'NULL'
return 'CefOwnPtr<' + self.type.get_ptr_type() + '>()'
return ''
class obj_analysis:
""" Class representing an analysis of a data type value. """
def __init__(self, scopelist, value, named):
self.value = value
self.result_type = 'unknown'
self.result_value = None
self.result_default = None
self.ptr_type = None
# parse the argument string
partlist = value.strip().split()
if named == True:
# extract the name value
self.name = partlist[-1]
del partlist[-1]
else:
self.name = None
if len(partlist) == 0:
raise Exception('Invalid argument value: ' + value)
# check const status
if partlist[0] == 'const':
self.isconst = True
del partlist[0]
else:
self.isconst = False
if len(partlist) == 0:
raise Exception('Invalid argument value: ' + value)
# combine the data type
self.type = ' '.join(partlist)
# extract the last character of the data type
endchar = self.type[-1]
# check if the value is passed by reference
if endchar == '&':
self.isbyref = True
self.type = self.type[:-1]
else:
self.isbyref = False
# check if the value is passed by address
if endchar == '*':
self.isbyaddr = True
self.type = self.type[:-1]
else:
self.isbyaddr = False
# see if the value is directly identifiable
if self._check_advanced(self.type) == True:
return
# not identifiable, so look it up
translation = None
for scope in scopelist:
if not isinstance(scope, obj_header) \
and not isinstance(scope, obj_class):
raise Exception('Invalid scope object type')
translation = scope.get_alias_translation(self.type)
if not translation is None:
break
if translation is None:
raise Exception('Failed to translate type: ' + self.type)
# the translation succeeded so keep the result
self.result_type = translation.result_type
self.result_value = translation.result_value
def _check_advanced(self, value):
# check for vectors
if value.find('std::vector') == 0:
self.result_type = 'vector'
val = value[12:-1].strip()
self.result_value = [self._get_basic(val)]
self.result_value[0]['vector_type'] = val
return True
# check for maps
if value.find('std::map') == 0:
self.result_type = 'map'
vals = value[9:-1].split(',')
if len(vals) == 2:
self.result_value = [
self._get_basic(vals[0].strip()),
self._get_basic(vals[1].strip())
]
return True
# check for multimaps
if value.find('std::multimap') == 0:
self.result_type = 'multimap'
vals = value[14:-1].split(',')
if len(vals) == 2:
self.result_value = [
self._get_basic(vals[0].strip()),
self._get_basic(vals[1].strip())
]
return True
# check for basic types
basic = self._get_basic(value)
if not basic is None:
self.result_type = basic['result_type']
self.result_value = basic['result_value']
if 'ptr_type' in basic:
self.ptr_type = basic['ptr_type']
if 'result_default' in basic:
self.result_default = basic['result_default']
return True
return False
def _get_basic(self, value):
# check for string values
if value == "CefString":
return {'result_type': 'string', 'result_value': None}
# check for simple direct translations
if value in _simpletypes.keys():
return {
'result_type': 'simple',
'result_value': _simpletypes[value][0],
'result_default': _simpletypes[value][1],
}
# check if already a C API structure
if value[-2:] == '_t':
return {'result_type': 'structure', 'result_value': value}
# check for CEF reference pointers
p = re.compile('^CefRefPtr<(.*?)>$', re.DOTALL)
list = p.findall(value)
if len(list) == 1:
return {
'result_type': 'refptr',
'result_value': get_capi_name(list[0], True) + '*',
'ptr_type': list[0]
}
# check for CEF owned pointers
p = re.compile('^CefOwnPtr<(.*?)>$', re.DOTALL)
list = p.findall(value)
if len(list) == 1:
return {
'result_type': 'ownptr',
'result_value': get_capi_name(list[0], True) + '*',
'ptr_type': list[0]
}
# check for CEF raw pointers
p = re.compile('^CefRawPtr<(.*?)>$', re.DOTALL)
list = p.findall(value)
if len(list) == 1:
return {
'result_type': 'rawptr',
'result_value': get_capi_name(list[0], True) + '*',
'ptr_type': list[0]
}
# check for CEF structure types
if value[0:3] == 'Cef' and value[-4:] != 'List':
return {
'result_type': 'structure',
'result_value': get_capi_name(value, True)
}
return None
def __repr__(self):
return '(' + self.result_type + ') ' + str(self.result_value)
def has_name(self):
""" Returns true if a name value exists. """
return (not self.name is None)
def get_name(self):
""" Return the name. """
return self.name
def get_value(self):
""" Return the C++ value (type + name). """
return self.value
def get_type(self):
""" Return the C++ type. """
return self.type
def get_ptr_type(self):
""" Return the C++ class type referenced by a CefRefPtr. """
if self.is_result_vector() and self.is_result_vector_ptr():
# return the vector RefPtr type
return self.result_value[0]['ptr_type']
# return the basic RefPtr type
return self.ptr_type
def get_vector_type(self):
""" Return the C++ class type referenced by a std::vector. """
if self.is_result_vector():
return self.result_value[0]['vector_type']
return None
def is_const(self):
""" Returns true if the argument value is constant. """
return self.isconst
def is_byref(self):
""" Returns true if the argument is passed by reference. """
return self.isbyref
def is_byaddr(self):
""" Returns true if the argument is passed by address. """
return self.isbyaddr
def is_result_simple(self):
""" Returns true if this is a simple argument type. """
return (self.result_type == 'simple')
def get_result_simple_type_root(self):
""" Return the simple structure or basic type name. """
return self.result_value
def get_result_simple_type(self):
""" Return the simple type. """
result = ''
if self.is_const():
result += 'const '
result += self.result_value
if self.is_byaddr() or self.is_byref():
result += '*'
return result
def get_result_simple_default(self):
""" Return the default value fo the basic type. """
return self.result_default
def is_result_ptr(self):
""" Returns true if this is a *Ptr type. """
return self.is_result_refptr() or self.is_result_ownptr() or \
self.is_result_rawptr()
def get_result_ptr_type_root(self):
""" Return the *Ptr type structure name. """
return self.result_value[:-1]
def get_result_ptr_type(self, defined_structs=[]):
""" Return the *Ptr type. """
result = ''
if not self.result_value[:-1] in defined_structs:
result += 'struct _'
result += self.result_value
if self.is_byref() or self.is_byaddr():
result += '*'
return result
def get_result_ptr_type_prefix(self):
""" Returns the *Ptr type prefix. """
if self.is_result_refptr():
return 'ref'
if self.is_result_ownptr():
return 'own'
if self.is_result_rawptr():
return 'raw'
raise Exception('Not a pointer type')
def is_result_refptr(self):
""" Returns true if this is a RefPtr type. """
return (self.result_type == 'refptr')
def is_result_ownptr(self):
""" Returns true if this is a OwnPtr type. """
return (self.result_type == 'ownptr')
def is_result_rawptr(self):
""" Returns true if this is a RawPtr type. """
return (self.result_type == 'rawptr')
def is_result_struct(self):
""" Returns true if this is a structure type. """
return (self.result_type == 'structure')
def is_result_struct_enum(self):
""" Returns true if this struct type is likely an enumeration. """
# structure values that are passed by reference or address must be
# structures and not enumerations
if not self.is_byref() and not self.is_byaddr():
return True
return False
def get_result_struct_type(self, defined_structs=[]):
""" Return the structure or enumeration type. """
result = ''
is_enum = self.is_result_struct_enum()
if not is_enum:
if self.is_const():
result += 'const '
if not self.result_value in defined_structs:
result += 'struct _'
result += self.result_value
if not is_enum:
result += '*'
return result
def is_result_string(self):
""" Returns true if this is a string type. """
return (self.result_type == 'string')
def get_result_string_type(self):
""" Return the string type. """
if not self.has_name():
# Return values are string structs that the user must free. Use
# the name of the structure as a hint.
return 'cef_string_userfree_t'
elif not self.is_const() and (self.is_byref() or self.is_byaddr()):
# Parameters passed by reference or address. Use the normal
# non-const string struct.
return 'cef_string_t*'
# Const parameters use the const string struct.
return 'const cef_string_t*'
def is_result_vector(self):
""" Returns true if this is a vector type. """
return (self.result_type == 'vector')
def is_result_vector_string(self):
""" Returns true if this is a string vector. """
return self.result_value[0]['result_type'] == 'string'
def is_result_vector_simple(self):
""" Returns true if this is a string vector. """
return self.result_value[0]['result_type'] == 'simple'
def is_result_vector_ptr(self):
""" Returns true if this is a *Ptr vector. """
return self.is_result_vector_refptr() or \
self.is_result_vector_ownptr() or \
self.is_result_vector_rawptr()
def get_result_vector_ptr_type_prefix(self):
""" Returns the *Ptr type prefix. """
if self.is_result_vector_refptr():
return 'ref'
if self.is_result_vector_ownptr():
return 'own'
if self.is_result_vector_rawptr():
return 'raw'
raise Exception('Not a pointer type')
def is_result_vector_refptr(self):
""" Returns true if this is a RefPtr vector. """
return self.result_value[0]['result_type'] == 'refptr'
def is_result_vector_ownptr(self):
""" Returns true if this is a OwnPtr vector. """
return self.result_value[0]['result_type'] == 'ownptr'
def is_result_vector_rawptr(self):
""" Returns true if this is a RawPtr vector. """
return self.result_value[0]['result_type'] == 'rawptr'
def get_result_vector_type_root(self):
""" Return the vector structure or basic type name. """
return self.result_value[0]['result_value']
def get_result_vector_type(self, defined_structs=[]):
""" Return the vector type. """
if not self.has_name():
raise Exception('Cannot use vector as a return type')
type = self.result_value[0]['result_type']
value = self.result_value[0]['result_value']
result = {}
if type == 'string':
result['value'] = 'cef_string_list_t'
result['format'] = 'single'
return result
if type == 'simple':
str = value
if self.is_const():
str += ' const'
str += '*'
result['value'] = str
elif type == 'refptr' or type == 'ownptr' or type == 'rawptr':
str = ''
if not value[:-1] in defined_structs:
str += 'struct _'
str += value
if self.is_const():
str += ' const'
str += '*'
result['value'] = str
else:
raise Exception('Unsupported vector type: ' + type)
# vector values must be passed as a value array parameter
# and a size parameter
result['format'] = 'multi-arg'
return result
def is_result_map(self):
""" Returns true if this is a map type. """
return (self.result_type == 'map' or self.result_type == 'multimap')
def is_result_map_single(self):
""" Returns true if this is a single map type. """
return (self.result_type == 'map')
def is_result_map_multi(self):
""" Returns true if this is a multi map type. """
return (self.result_type == 'multimap')
def get_result_map_type(self, defined_structs=[]):
""" Return the map type. """
if not self.has_name():
raise Exception('Cannot use map as a return type')
if self.result_value[0]['result_type'] == 'string' \
and self.result_value[1]['result_type'] == 'string':
if self.result_type == 'map':
return {'value': 'cef_string_map_t', 'format': 'single'}
elif self.result_type == 'multimap':
return {'value': 'cef_string_multimap_t', 'format': 'multi'}
raise Exception('Only mappings of strings to strings are supported')
def get_capi(self, defined_structs=[]):
""" Format the value for the C API. """
result = ''
format = 'single'
if self.is_result_simple():
result += self.get_result_simple_type()
elif self.is_result_ptr():
result += self.get_result_ptr_type(defined_structs)
elif self.is_result_struct():
result += self.get_result_struct_type(defined_structs)
elif self.is_result_string():
result += self.get_result_string_type()
elif self.is_result_map():
resdict = self.get_result_map_type(defined_structs)
if resdict['format'] == 'single' or resdict['format'] == 'multi':
result += resdict['value']
else:
raise Exception('Unsupported map type')
elif self.is_result_vector():
resdict = self.get_result_vector_type(defined_structs)
if resdict['format'] != 'single':
format = resdict['format']
result += resdict['value']
if self.has_name():
result += ' ' + self.get_name()
return {'format': format, 'value': result}
# test the module
if __name__ == "__main__":
import pprint
import sys
# verify that the correct number of command-line arguments are provided
if len(sys.argv) != 2:
sys.stderr.write('Usage: ' + sys.argv[0] + ' <directory>')
sys.exit()
pp = pprint.PrettyPrinter(indent=4)
# create the header object
header = obj_header()
header.add_directory(sys.argv[1])
# output the type mapping
types = {}
header.get_types(types)
pp.pprint(types)
sys.stdout.write('\n')
# output the parsed C++ data
sys.stdout.write(str(header))
# output the C API formatted data
defined_names = header.get_defined_structs()
result = ''
# global functions
funcs = header.get_funcs()
if len(funcs) > 0:
for func in funcs:
result += func.get_capi_proto(defined_names, True) + ';\n'
result += '\n'
classes = header.get_classes()
for cls in classes:
# virtual functions are inside a structure
result += 'struct ' + cls.get_capi_name() + '\n{\n'
funcs = cls.get_virtual_funcs()
if len(funcs) > 0:
for func in funcs:
result += '\t' + func.get_capi_proto(defined_names, True) + ';\n'
result += '}\n\n'
defined_names.append(cls.get_capi_name())
# static functions become global
funcs = cls.get_static_funcs()
if len(funcs) > 0:
for func in funcs:
result += func.get_capi_proto(defined_names, True) + ';\n'
result += '\n'
sys.stdout.write(result)