# 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 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 wrap_code(code, indent = ' ', maxchars = 80, splitchars = '(=,'): """ Wrap the code lines to the specified number of characters. If necessary a line will be broken and wrapped after one of the split characters. """ output = '' # normalize line endings code = code.replace("\r\n", "\n") # break the code chunk into lines lines = string.split(code, '\n') for line in lines: if len(line) <= maxchars: # line is short enough that it doesn't need to be wrapped output += line + '\n' continue # retrieve the whitespace at the beginning of the line for later use # as padding ws = '' for char in line: if char.isspace(): ws += char else: break # iterate over all characters in the string keeping track of where the # last valid break character was found and wrapping the line # accordingly lastsplit = 0 nextsplit = -1 splitct = 0 pos = 0 for char in line: if splitchars.find(char) >= 0: # a new split position has been found nextsplit = pos size = pos - lastsplit + 1 if splitct > 0: size += len(ws) + len(indent) if size >= maxchars: # the line is too long section = line[lastsplit:nextsplit+1] if len(section) > 0: # output the line portion between the last split and the # next split if splitct > 0: # start a new line and trim the line section output += '\n'+ws+indent section = string.strip(section) output += section lastsplit = nextsplit + 1 splitct += 1 pos += 1 if len(line) - lastsplit > 0: # output the remainder of the line section = line[lastsplit:] if splitct > 0: # start a new line and trim the line section output += '\n'+ws+indent section = string.strip(section) output += section output += '\n' return output 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 string.upper(chr) == chr \ and not string.upper(lastchr) == lastchr: result += '_' result += string.lower(chr) 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_prev_line(body, pos): """ Retrieve the start and end positions and value for the line immediately before the line containing the specified position. """ end = string.rfind(body, '\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) while pos > 0: data = get_prev_line(body, pos) line = string.strip(data['line']) pos = data['start'] if len(line) == 0: # check if the next previous line is a comment prevdata = get_prev_line(body, pos) if string.strip(prevdata['line'])[0:2] == '//': result.append(None) else: break elif line[0:2] == '/*': continue elif line[0:2] == '//': # keep the comment line including any leading spaces result.append(line[2:]) else: break result.reverse() return result def format_comment(comment, indent, translate_map = None, maxchars = 80): """ Return the comments array as a formatted string. """ 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[0:1] == ' ': line = line[1:] didremovespace = True else: didremovespace = False if line is None or len(line) == 0 or line[0:1] == ' ' \ or line[0:1] == '/': # the previous paragraph, if any, has ended 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) wrapme = '' if not line is None: if len(line) == 0 or line[0:1] == ' ' or line[0:1] == '/': # 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(body): """ Return the necessary list of includes based on the contents of the body. """ result = '' # 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: result += '#include "libcef_dll/cpptoc/'+ \ 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: result += '#include "libcef_dll/ctocpp/'+ \ get_capi_name(item[3:], False)+'_ctocpp.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. """ dict = {} parts = string.split(str, ',') for part in parts: part = string.strip(part) if len(part) == 0: continue sparts = string.split(part, '=') if len(sparts) != 2: raise Exception('Invalid dictionary pair format: '+part) dict[string.strip(sparts[0])] = string.strip(sparts[1]) return dict def dict_to_str(dict): """ Convert a dictionary to a string. """ str = [] for name in dict.keys(): str.append(name+'='+dict[name]) return string.join(str, ',') # regex for matching comment-formatted attributes _cre_attrib = '/\*--cef\(([A-Za-z0-9_ ,=]{0,})\)--\*/' # regex for matching class and function names _cre_cfname = '([A-Za-z0-9_]{1,})' # regex for matching typedef values and function return values _cre_retval = '([A-Za-z0-9_<>:,\*\&]{1,})' # regex for matching function return value and name combination _cre_func = '([A-Za-z][A-Za-z0-9_<>:,\*\& ]{1,})' # regex for matching virtual function modifiers _cre_vfmod = '([A-Za-z0-9_]{0,})' # regex for matching arbitrary whitespace _cre_space = '[\s]{1,}' def get_function_impls(content, ident): """ 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 p = re.compile('\n'+_cre_func+'\((.*?)\)([A-Za-z0-9_\s]{0,})'+ '\{(.*?)\n\}', 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 = string.replace(retval, ident, '') retval = string.strip(retval) # retrieve the function name parts = string.split(retval, ' ') name = parts[-1] del parts[-1] retval = string.join(parts, ' ') # parse the arguments args = [] for v in string.split(argval, ','): v = string.strip(v) if len(v) > 0: args.append(v) result.append({ 'retval' : string.strip(retval), 'name' : name, 'args' : args, 'vfmod' : string.strip(vfmod), 'body' : body }) 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 class obj_header: """ Class representing a C++ header file. """ def __init__(self, filename): self.filename = filename; # read the input file into memory data = read_file(filename) # remove space from between template definition end brackets data = data.replace("> >", ">>") # extract global typedefs p = re.compile('\ntypedef'+_cre_space+_cre_retval+ _cre_space+_cre_cfname+';', re.MULTILINE | re.DOTALL) list = p.findall(data) # build the global typedef objects self.typedefs = [] for value, alias in list: self.typedefs.append(obj_typedef(self, value, alias)) # extract global functions p = re.compile('\n'+_cre_attrib+'\n'+_cre_func+'\((.*?)\)', re.MULTILINE | re.DOTALL) list = p.findall(data) # build the global function objects self.funcs = [] for attrib, retval, argval in list: comment = get_comment(data, retval+'('+argval+');') self.funcs.append(obj_function(self, attrib, retval, argval, comment)) # extract classes p = re.compile('\n'+_cre_attrib+ '\nclass'+_cre_space+_cre_cfname+_cre_space+ ':'+_cre_space+'public'+_cre_space+'virtual'+ _cre_space+'CefBase'+ '\n{(.*?)};', re.MULTILINE | re.DOTALL) list = p.findall(data) # build the class objects self.classes = [] for attrib, name, body in list: comment = get_comment(data, name+' : public virtual CefBase') self.classes.append( obj_class(self, attrib, name, body, comment)) def __repr__(self): result = '' if len(self.typedefs) > 0: strlist = [] for cls in self.typedefs: strlist.append(str(cls)) result += string.join(strlist, "\n") + "\n\n" if len(self.funcs) > 0: strlist = [] for cls in self.funcs: strlist.append(str(cls)) result += string.join(strlist, "\n") + "\n\n" if len(self.classes) > 0: strlist = [] for cls in self.classes: strlist.append(str(cls)) result += string.join(strlist, "\n") return result def get_file_name(self): """ Return the file name. """ return self.filename def get_typedefs(self): """ Return the array of typedef objects. """ return self.typedefs def get_funcs(self): """ Return the array of function objects. """ return self.funcs def get_classes(self): """ Return the array of class objects. """ return self.classes 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_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 names already defined structure names. """ return ['cef_print_info_t', 'cef_window_info_t', 'cef_handler_menuinfo_t', 'cef_base_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, attrib, name, body, comment): if not isinstance(parent, obj_header): raise Exception('Invalid parent object type') self.parent = parent self.attribs = str_to_dict(attrib) self.name = name self.comment = comment # extract typedefs p = re.compile('\n'+_cre_space+'typedef'+_cre_space+_cre_retval+ _cre_space+_cre_cfname+';', re.MULTILINE | re.DOTALL) list = p.findall(body) # build the typedef objects self.typedefs = [] for value, alias in list: self.typedefs.append(obj_typedef(self, 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+')') 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_space+_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+')') self.virtualfuncs.append( obj_function_virtual(self, attrib, retval, argval, comment, vfmod)) 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 += string.join(strlist, "\n\t") if len(self.staticfuncs) > 0: result += "\n\t" strlist = [] for cls in self.staticfuncs: strlist.append(str(cls)) result += string.join(strlist, "\n\t") if len(self.virtualfuncs) > 0: result += "\n\t" strlist = [] for cls in self.virtualfuncs: strlist.append(str(cls)) result += string.join(strlist, "\n\t") result += "\n};\n" return result 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_comment(self): """ Return the class comment as an array of lines. """ return self.comment def get_attribs(self): """ Return the class attributes as a dictionary. """ return self.attribs; def get_typedefs(self): """ Return the array of typedef objects. """ return self.typedefs; 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, value, alias): if not isinstance(parent, obj_header) \ and not isinstance(parent, obj_class): raise Exception('Invalid parent object type') self.parent = parent self.alias = alias self.value = self.parent.get_analysis(value, False) def __repr__(self): return 'typedef '+self.value.get_type()+' '+self.alias+';' 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, attrib, retval, argval, comment): self.parent = parent 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 = string.split(argval, ',') for arg in arglist: arg = string.strip(arg) if len(arg) > 0: self.arguments.append(obj_argument(self, arg)) def __repr__(self): return '/* '+dict_to_str(self.attribs)+' */ '+self.get_cpp_proto() def get_name(self): """ Return the function name. """ return 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 the function attributes as a dictionary. """ return self.attribs 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 = [], 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) 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 = type.get_name() if type[-1] == 's': type = type[:-1] args.append('size_t '+type+'Count') args.append(dict['value']) elif dict['format'] == 'multi-func': # change the function to return one value of the # required type based on an index parameter type = type.get_name() if type[-1] == 's': type = type[:-1] args.append('int '+type+'Index') retval = dict['value'] return { 'retval' : retval, 'name' : name, 'args' : args } def get_capi_proto(self, defined_structs = [], prefix = None): """ Return the prototype of the C API function. """ parts = self.get_capi_parts(defined_structs, prefix) result = parts['retval']+' '+parts['name']+ \ '('+string.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 type = self.get_retval().get_type() if type.is_result_struct() and not type.is_byref() \ and not type.is_byaddr(): 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']+'('+string.join(parts['args'], ', ')+')' if isinstance(self, obj_function_virtual) and self.is_const(): result += ' const' return result 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, 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, 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 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 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 # parse the argument string partlist = string.split(string.strip(value)) 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 # combine the data type self.type = string.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] self.result_value = [ self._get_basic(val) ] return True # check for maps if value.find('std::map') == 0: self.result_type = 'map' vals = string.split(value[9:-1], ',') if len(vals) == 2: self.result_value = [ self._get_basic(string.strip(vals[0])), self._get_basic(string.strip(vals[1])) ] 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'] 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 simpletypes = { 'void' : 'void', 'int' : 'int', 'int64' : 'int64', 'uint64' : 'uint64', 'double' : 'double', 'long' : 'long', 'unsigned long' : 'unsigned long', 'size_t' : 'size_t', 'time_t' : 'time_t', 'bool' : 'int', 'CefCursorHandle' : 'cef_cursor_handle_t', 'CefWindowHandle' : 'cef_window_handle_t', 'CefRect' : 'cef_rect_t', 'CefThreadId' : 'cef_thread_id_t', 'CefTime' : 'cef_time_t', } if value in simpletypes.keys(): return { 'result_type' : 'simple', 'result_value' : simpletypes[value] } # 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)+'*' } # 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 name. """ return self.value def get_type(self): """ Return the type. """ return self.type 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(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 is_result_refptr(self): """ Returns true if this is a reference pointer type. """ return (self.result_type == 'refptr') def get_result_refptr_type(self, defined_structs = []): """ Return the refptr 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 is_result_struct(self): """ Returns true if this is a structure type. """ return (self.result_type == 'structure') def get_result_struct_type(self, defined_structs = []): """ Return the structure or enumeration type. """ result = '' # structure values that are passed by reference or address must be # structures and not enumerations if self.is_byref() or self.is_byaddr(): if self.is_const(): result += 'const ' if not self.result_value in defined_structs: result += 'struct _' else: result += 'enum ' result += self.result_value if self.is_byref() or self.is_byaddr(): 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 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': result['value'] = value elif type == 'refptr': str = '' if not value[:-1] in defined_structs: str += 'struct _' str += value if self.is_const(): str += ' const*' result['value'] = str else: raise Exception('Unsupported vector type: '+type) if self.is_const(): # const vector values must be passed as the value array parameter # and a size parameter result['format'] = 'multi-arg' else: # non-const vector values must be passed as one function to get the # size and another function to get the element at a specified index result['format'] = 'multi-func' return result def is_result_map(self): """ Returns true if this is a map type. """ return (self.result_type == 'map') 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': return { 'value' : 'cef_string_map_t', 'format' : 'single' } 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_refptr(): result += self.get_result_refptr_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': result += resdict['value'] else: raise Exception('Only single-value map types are supported') 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() and format != 'multi-func': 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]+' ') sys.exit() pp = pprint.PrettyPrinter(indent=4) # create the header object header = obj_header(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(wrap_code(str(header), '\t')) # 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)+';\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)+';\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)+';\n' result += '\n' sys.stdout.write(wrap_code(result, '\t'))