# This is Kconfiglib, a Python library for scripting, debugging, and extracting # information from Kconfig-based configuration systems. To view the # documentation, run # # $ pydoc kconfiglib # # or, if you prefer HTML, # # $ pydoc -w kconfiglib # # The examples/ subdirectory contains examples, to be run with e.g. # # $ make scriptconfig SCRIPT=Kconfiglib/examples/print_tree.py # # Look in kconfigtest.py for the test suite. """ Kconfiglib is a Python library for scripting and extracting information from Kconfig-based configuration systems. Features include the following: - Symbol values and properties can be looked up and values assigned programmatically. - .config files can be read and written. - Expressions can be evaluated in the context of a Kconfig configuration. - Relations between symbols can be quickly determined, such as finding all symbols that reference a particular symbol. - Symbol values are automatically cached and reevaluated only when needed. - Highly compatible with the C Kconfig implementation: * Generates a .config file that is character-for-character identical (modulo header) to the one generated by the C implementation (mconf) when fed each architecture/defconfig pair in the kernel and asked to generate a configuration. This includes nonsensical pairings such as powerpc with arch/x86/configs/x86_64_defconfig, for a total of 9096 combinations as of Linux 2.6.38-rc3. * Also generates a .config that is character-for-character identical to the one generated by mconf for all architectures when no .config is supplied. * The 'make allyesconfig' and 'make allnoconfig' implementations in the generate output character-for-character identical to the C implementation for all architectures. For the Linux kernel, scripts are run using $ make scriptconfig SCRIPT= This ensures that needed environment variables (SRCARCH, ARCH, srctree, KERNELVERSION, etc.) are set up correctly. Alternative architectures can be specified like for other 'make *config' targets: $ make scriptconfig ARCH=mips SCRIPT= The script will receive the name of the Kconfig file to load in sys.argv[1]. As of Linux 2.6.38-rc3 this is always "Kconfig" from the kernel top-level directory. To get an interactive Python prompt with Kconfiglib preloaded and a Config object 'c' created, use $ make iscriptconfig [ARCH=] Kconfiglib requires Python 2. For (i)scriptconfig the command to run the Python interpreter can be passed in the environment variable PYTHONCMD (defaults to 'python'; PyPy works too and is a bit faster). Look in the examples/ subdirectory for examples. Look in kconfigtest.py for the test suite. Credits: Written by Ulf "Ulfalizer" Magnusson Send bug reports, suggestions (any missing APIs that would make your life easier?) and other feedback to kconfiglib@gmail.com .""" # If you have Psyco installed (32-bit installations, Python <= 2.6 only), # setting this to True (right here, not at runtime) might give a nice speedup. # (22% faster for parsing arch/x86/Kconfig and 58% faster for evaluating all # symbols in it without a .config on my Core Duo.) use_psyco = False import os import re import string import sys class Config(): """Represents a Kconfig configuration.""" # # Public interface # def __init__(self, filename = "Kconfig", base_dir = "$srctree", print_warnings = True, print_undef_assign = False): """Creates a new Config object, representing a Kconfig configuration. Raises Kconfig_Syntax_Error on syntax errors. filename (default: "Kconfig") -- The base Kconfig file of the configuration. For the Linux kernel, this should usually be be "Kconfig" from the top-level directory, as environment variables will make sure the right Kconfig is included from there (usually arch/ "foo bar" if FOO has the value "foo"). Returns None in case of no defconfig file. Setting 'option defconfig_list' on multiple symbols currently results in undefined behavior. If the environment variable 'srctree' was set when the Config was created, get_defconfig_filename() will first look relative to that directory before looking in the current directory. See Config.__init__().""" if self.defconfig_sym is None: return None for (filename, cond_expr) in self.defconfig_sym.def_exprs: if self._eval_expr(cond_expr) == "y": filename = self._expand_sym_refs(filename) # We first look in $srctree. os.path.join() won't work here as # an absolute path in filename would override $srctree. srctree_filename = os.path.normpath(self.srctree + "/" + filename) if os.path.exists(srctree_filename): return srctree_filename if os.path.exists(filename): return filename return None def get_symbol(self, name): """Returns the symbol with name 'name', or None if no such symbol appears in the configuration. An alternative shorthand is conf[name], where conf is a Config instance, though that will instead raise KeyError if the symbol does not exist.""" return self.syms.get(name) def get_top_level_items(self): """Returns a list containing the items (symbols, menus, choice statements and comments) at the top level of the configuration -- that is, all items that do not appear within a menu or choice. The items appear in the same order as within the configuration.""" return self.top_block.get_items() def get_symbols(self, all_symbols = True): """Returns a list of symbols from the configuration. An alternative for iterating over all defined symbols (in the order of definition) is for sym in config: ... which relies on Config implementing __iter__() and is equivalent to for sym in config.get_symbols(False): ... all_symbols (default: True) -- If True, all symbols - including special and undefined symbols - will be included in the result, in an undefined order. If False, only symbols actually defined and not merely referred to in the configuration will be included in the result, and will appear in the order that they are defined within the Kconfig configuration files.""" return self.syms.values() if all_symbols else self.kconfig_syms def get_choices(self): """Returns a list containing all choice statements in the configuration, in the order they appear in the Kconfig files.""" return self.choices def get_menus(self): """Returns a list containing all menus in the configuration, in the order they appear in the Kconfig files.""" return self.menus def get_comments(self): """Returns a list containing all comments in the configuration, in the order they appear in the Kconfig files.""" return self.comments def eval(self, s): """Returns the value of the expression 's' -- where 's' is represented as a string -- in the context of the configuration. Raises Kconfig_Syntax_Error if syntax errors are detected in 's'. For example, if FOO and BAR are tristate symbols at least one of which has the value "y", then config.eval("y && (FOO || BAR)") => "y" This functions always yields a tristate value. To get the value of non-bool, non-tristate symbols, use calc_value(). The result of this function is consistent with how evaluation works for conditional expressions in the configuration as well as in the C implementation. "m" and m are rewritten as '"m" && MODULES' and 'm && MODULES', respectively, and a result of "m" will get promoted to "y" if we're running without modules.""" return self._eval_expr(self._parse_expr(self._tokenize(s, True), # Feed None, # Current symbol or choice s)) # line def get_config_header(self): """Returns the (uncommented) textual header of the .config file most recently loaded with load_config(). Returns None if no .config file has been loaded or if the most recently loaded .config file has no header. The header comprises all lines up to but not including the first line that either 1. Does not start with "#" 2. Has the form "# CONFIG_FOO is not set." """ return self.config_header def get_base_dir(self): """Returns the base directory for 'source' statements, passed as an argument to Config.__init__().""" return self.base_dir def set_print_warnings(self, print_warnings): """Determines whether warnings related to this configuration (for things like attempting to assign illegal values to symbols) should be printed to stderr. print_warnings -- True if warnings should be printed, otherwise False.""" self.print_warnings = print_warnings def set_print_undef_assign(self, print_undef_assign): """Determines whether informational messages related to assignments to undefined symbols should be printed to stderr for this configuration. print_undef_assign -- If True, such messages will be printed.""" self.print_undef_assign = print_undef_assign def __getitem__(self, key): """Returns the symbol with name 'name'. Raises KeyError if the symbol does not appear in the configuration.""" return self.syms[key] def __iter__(self): """Convenience function for iterating over the set of all defined symbols in the configuration, used like for sym in conf: ... The iteration happens in the order of definition within the Kconfig configuration files. Symbols only referred to but not defined will not be included, nor will the special symbols n, m, and y. If you want to include such symbols as well, see config.get_symbols().""" return iter(self.kconfig_syms) def reset(self): """Resets the values of all symbols, as if Config.load_config() or Symbol.set_value() had never been called.""" for sym in self.syms.itervalues(): sym._reset_no_recursive_invalidate() def __str__(self): """Returns a string containing various information about the Config.""" return _sep_lines("Configuration", "File : " + self.filename, "Base directory : " + self.base_dir, "Value of $ARCH at creation time : " + ("(not set)" if self.arch is None else self.arch), "Value of $SRCARCH at creation time : " + ("(not set)" if self.srcarch is None else self.srcarch), "Source tree (derived from $srctree;", "defaults to '.' if $srctree isn't set) : " + self.srctree, "Most recently loaded .config : " + ("(no .config loaded)" if self.config_filename is None else self.config_filename), "Print warnings : " + bool_str[self.print_warnings], "Print assignments to undefined symbols : " + bool_str[self.print_undef_assign]) # # Private methods # def _invalidate_all(self): for sym in self.syms.itervalues(): sym._invalidate() def _tokenize(self, s, for_eval = False, filename = None, linenr = None): """Returns a _Feed instance containing tokens derived from the string 's'. Registers any new symbols encountered (via _sym_lookup()). (I experimented with a regular expression implementation, but it came out 5% _slower_ and wouldn't have been as flexible.) for_eval -- True when parsing an expression for a call to Config.eval(), in which case we should not treat the first token specially nor register new symbols.""" tokens = [] previous = None strlen = len(s) append = tokens.append # The current index in the string being tokenized i = 0 if not for_eval: # The initial word on a line is parsed specially. Let # command_chars = [A-Za-z0-9_]. Then # - leading non-command_chars characters on the line are ignored, and # - the first token consists the following one or more command_chars # characters. # This is why things like "----help--" are accepted. # Ignore leading non-command_chars characters while i < strlen and s[i] not in command_chars: # We need to look out for comments if s[i] == "#": return _Feed([]) i += 1 keyword_start = i # Locate the end of the keyword while i < strlen and s[i] in command_chars: i += 1 keyword_lexeme = s[keyword_start:i] # Blank line? if keyword_lexeme == "": return _Feed([]) keyword = keywords.get(keyword_lexeme) if keyword is None: # We expect a keyword as the first token _tokenization_error(s, strlen, filename, linenr) append(keyword) previous = keyword # Main tokenization loop (handles tokens past the first one) while i < strlen: c = s[i] if c.isspace(): i += 1 continue elif c == "=": append(T_EQUAL) i += 1 elif c == "!": if i + 1 >= strlen: _tokenization_error(s, strlen, filename, linenr) if s[i + 1] == "=": append(T_UNEQUAL) i += 2 else: append(T_NOT) i += 1 elif c == "(": append(T_OPEN_PAREN) i += 1 elif c == ")": append(T_CLOSE_PAREN) i += 1 elif c == "&": if i + 1 >= strlen: # Invalid characters are ignored continue if s[i + 1] != "&": # Invalid characters are ignored i += 1 continue append(T_AND) i += 2 elif c == "|": if i + 1 >= strlen: # Invalid characters are ignored continue if s[i + 1] != "|": # Invalid characters are ignored i += 1 continue append(T_OR) i += 2 elif c == '"' or c == "'": quote = c value = "" i += 1 while True: if i >= strlen: _tokenization_error(s, strlen, filename, linenr) c = s[i] if c == quote: break elif c == "\\": if i + 1 >= strlen: _tokenization_error(s, strlen, filename, linenr) value += s[i + 1] i += 2 else: value += c i += 1 i += 1 append(value) elif c == "#": break elif c not in sym_chars: # Invalid characters are ignored i += 1 continue else: # Symbol or keyword name_start = i # Locate the end of the symbol/keyword i += 1 while i < strlen and s[i] in sym_chars: i += 1 name = s[name_start:i] keyword = keywords.get(name) if keyword is not None: append(keyword) # What would ordinarily be considered a name is treated as a # string after certain tokens. elif previous in string_lex: append(name) else: # We're dealing with a symbol. _sym_lookup() will take care # of allocating a new Symbol instance if it's the first # time we see it. sym = self._sym_lookup(name, not for_eval) if previous in (T_CONFIG, T_MENUCONFIG): # If the previous token is T_CONFIG ("config"), we're # tokenizing the first line of a symbol definition, and # should remember this as a location where the symbol # is defined. sym.def_locations.append((filename, linenr)) else: # Otherwise, it's a reference to the symbol sym.ref_locations.append((filename, linenr)) append(sym) previous = tokens[-1] return _Feed(tokens) # # Parsing # # Expression grammar: # # -> # '=' # '!=' # '(' ')' # '!' # '&&' # '||' def _parse_expr(self, feed, cur_sym_or_choice, line, filename = None, linenr = None, transform_m = True): """Parse an expression from the tokens in 'feed' using a simple top-down approach. The result has the form (, ). feed -- _Feed instance containing the tokens for the expression. cur_sym_or_choice -- The symbol or choice currently being parsed, or None if we're not parsing a symbol or choice. Used for recording references to symbols. line -- The line containing the expression being parsed. filename (default: None) -- The file containing the expression. linenr (default: None) -- The line number containing the expression. transform_m (default: False) -- Determines if 'm' should be rewritten to 'm && MODULES' -- see parse_val_and_cond().""" # Use instance variables to avoid having to pass these as arguments # through the top-down parser in _parse_expr_2(), which is tedious and # obfuscates the code. A profiler run shows no noticeable performance # difference. self.parse_expr_cur_sym_or_choice = cur_sym_or_choice self.parse_expr_line = line self.parse_expr_filename = filename self.parse_expr_linenr = linenr self.parse_expr_transform_m = transform_m return self._parse_expr_2(feed) def _parse_expr_2(self, feed): or_terms = [self._parse_or_term(feed)] # Keep parsing additional terms while the lookahead is '||' while feed.check(T_OR): or_terms.append(self._parse_or_term(feed)) return or_terms[0] if len(or_terms) == 1 else (OR, or_terms) def _parse_or_term(self, feed): and_terms = [self._parse_factor(feed)] # Keep parsing additional terms while the lookahead is '&&' while feed.check(T_AND): and_terms.append(self._parse_factor(feed)) return and_terms[0] if len(and_terms) == 1 else (AND, and_terms) def _parse_factor(self, feed): if feed.check(T_OPEN_PAREN): expr_parse = self._parse_expr_2(feed) if not feed.check(T_CLOSE_PAREN): _parse_error(self.parse_expr_line, "missing end parenthesis.", self.parse_expr_filename, self.parse_expr_linenr) return expr_parse if feed.check(T_NOT): return (NOT, self._parse_factor(feed)) sym_or_string = feed.get_next() if not isinstance(sym_or_string, (Symbol, str)): _parse_error(self.parse_expr_line, "malformed expression.", self.parse_expr_filename, self.parse_expr_linenr) if self.parse_expr_cur_sym_or_choice is not None and \ isinstance(sym_or_string, Symbol): self.parse_expr_cur_sym_or_choice.referenced_syms.add(sym_or_string) if feed.peek_next() not in (T_EQUAL, T_UNEQUAL): if self.parse_expr_transform_m and (sym_or_string is self.m or sym_or_string == "m"): return (AND, ["m", self._sym_lookup("MODULES")]) return sym_or_string relation = EQUAL if (feed.get_next() == T_EQUAL) else UNEQUAL sym_or_string_2 = feed.get_next() if sym_or_string is self.m: sym_or_string = "m" if sym_or_string_2 is self.m: sym_or_string_2 = "m" return (relation, sym_or_string, sym_or_string_2) def _parse_file(self, filename, parent, deps, visible_if_deps): """Parse the Kconfig file 'filename'. The result is a _Block with all items from the file.""" line_feeder = _FileFeed(_get_lines(filename), filename) return self._parse_block(line_feeder, None, parent, deps, visible_if_deps) def _parse_block(self, line_feeder, end_marker, parent, deps, visible_if_deps = None): """Parses a block, which is the contents of either a file or an if, menu, or choice statement. end_marker -- The token that ends the block, e.g. T_ENDIF ("endif") for if's. None for files. parent -- The enclosing menu, choice or if, or None if we're at the top level. deps -- Dependencies from enclosing menus, choices and if's. visible_if_deps (default: None) -- 'visible if' dependencies from enclosing menus.""" block = _Block() filename = line_feeder.get_filename() while True: # Do we already have a tokenized line that we determined wasn't # part of whatever we were parsing earlier? See comment in # Config.__init__(). if self.end_line is not None: assert self.end_line_tokens is not None tokens = self.end_line_tokens tokens.go_to_start() line = self.end_line linenr = line_feeder.get_linenr() self.end_line = None self.end_line_tokens = None else: line = line_feeder.get_next() if line is None: if end_marker is not None: raise Kconfig_Syntax_Error, ( "Unexpected end of file {0}." .format(line_feeder.get_filename())) return block linenr = line_feeder.get_linenr() tokens = self._tokenize(line, False, filename, linenr) if tokens.is_empty(): continue t0 = tokens.get_next() # Have we reached the end of the block? if t0 == end_marker: return block elif t0 in (T_CONFIG, T_MENUCONFIG): # The tokenizer will automatically allocate a new Symbol object # for any new names it encounters, so we don't need to worry # about that here. sym = tokens.get_next() # Symbols defined in multiple places get the parent of their # first definition. However, for symbols whose parents are choice # statements, the choice statement takes precedence. if not sym.is_defined_ or isinstance(parent, Choice): sym.parent = parent sym.is_defined_ = True self.kconfig_syms.append(sym) block.add_item(sym) self._parse_properties(line_feeder, sym, deps, visible_if_deps) elif t0 == T_MENU: menu = Menu() self.menus.append(menu) menu.config = self menu.parent = parent menu.title = tokens.get_next() menu.filename = filename menu.linenr = linenr # Parse properties and contents self._parse_properties(line_feeder, menu, deps, visible_if_deps) menu.block = self._parse_block(line_feeder, T_ENDMENU, menu, menu.dep_expr, self._make_and(visible_if_deps, menu.visible_if_expr)) block.add_item(menu) elif t0 == T_IF: # If statements are treated as syntactic sugar for adding # dependencies to enclosed items and do not have an explicit # object representation. dep_expr = self._parse_expr(tokens, None, line, filename, linenr) if_block = self._parse_block(line_feeder, T_ENDIF, parent, self._make_and(dep_expr, deps), visible_if_deps) block.add_items_from_block(if_block) elif t0 == T_CHOICE: # We support named choices already_defined = False name = None if len(tokens) > 1 and isinstance(tokens[1], str): name = tokens[1] already_defined = name in self.named_choices if already_defined: choice = self.named_choices[name] else: choice = Choice() self.choices.append(choice) if name is not None: choice.name = name self.named_choices[name] = choice choice.config = self choice.parent = parent choice.def_locations.append((filename, linenr)) # Parse properties and contents self._parse_properties(line_feeder, choice, deps, visible_if_deps) choice.block = self._parse_block(line_feeder, T_ENDCHOICE, choice, None, visible_if_deps) choice._determine_actual_items() # If no type is set for the choice, its type is that of the first # choice item if choice.type == UNKNOWN: for item in choice.get_actual_items(): if item.get_type() != UNKNOWN: choice.type = item.get_type() break # Each choice item of UNKNOWN type gets the type of the choice for item in choice.get_actual_items(): if item.type == UNKNOWN: item.type = choice.type # For named choices defined in multiple locations, only record # at the first definition if not already_defined: block.add_item(choice) elif t0 == T_COMMENT: comment = Comment() comment.config = self comment.parent = parent comment.filename = filename comment.linenr = linenr comment.text = tokens.get_next() self._parse_properties(line_feeder, comment, deps, visible_if_deps) block.add_item(comment) self.comments.append(comment) elif t0 == T_SOURCE: kconfig_file = tokens.get_next() f = os.path.join(self.base_dir, self._expand_sym_refs(kconfig_file)) if not os.path.exists(f): raise IOError, ('{0}:{1}: sourced file "{2}" not found. Perhaps ' 'base_dir (argument to Config.__init__(), currently ' '"{3}") is set to the wrong value.' .format(filename, linenr, kconfig_file, self.base_dir)) file_block = self._parse_file(f, parent, deps, visible_if_deps) block.add_items_from_block(file_block) elif t0 == T_MAINMENU: text = tokens.get_next() if self.mainmenu_text is not None: self._warn("overriding 'mainmenu' text. " 'Old value: "{0}", new value: "{1}".' .format(self.mainmenu_text, text), filename, linenr) self.mainmenu_text = text else: _parse_error(line, "unrecognized construct.", filename, linenr) def _parse_properties(self, line_feeder, stmt, deps, visible_if_deps): """Parsing of properties for symbols, menus, choices, and comments.""" def parse_val_and_cond(tokens, line, filename, linenr): """Parses ' if ' constructs, where the 'if' part is optional. Returns a tuple containing the parsed expressions, with None as the second element if the 'if' part is missing.""" val = self._parse_expr(tokens, stmt, line, filename, linenr, False) if tokens.check(T_IF): return (val, self._parse_expr(tokens, stmt, line, filename, linenr)) return (val, None) # In case the symbol is defined in multiple locations, we need to # remember what prompts, defaults, and selects are new for this # definition, as "depends on" should only apply to the local # definition. new_prompt = None new_def_exprs = [] new_selects = [] # Dependencies from 'depends on' statements depends_on_expr = None while True: line = line_feeder.get_next() if line is None: break filename = line_feeder.get_filename() linenr = line_feeder.get_linenr() tokens = self._tokenize(line, False, filename, linenr) if tokens.is_empty(): continue t0 = tokens.get_next() if t0 == T_HELP: # Find first non-empty line and get its indentation line_feeder.remove_while(str.isspace) line = line_feeder.get_next() if line is None: stmt.help = "" break indent = _indentation(line) # If the first non-empty lines has zero indent, there is no # help text if indent == 0: stmt.help = "" line_feeder.go_back() break help_lines = [_deindent(line, indent)] # The help text goes on till the first non-empty line with less # indent while True: line = line_feeder.get_next() if (line is None) or \ (not line.isspace() and _indentation(line) < indent): stmt.help = "".join(help_lines) break help_lines.append(_deindent(line, indent)) if line is None: break line_feeder.go_back() elif t0 == T_PROMPT: # 'prompt' properties override each other within a single # definition of a symbol, but additional prompts can be added # by defining the symbol multiple times; hence 'new_prompt' # instead of 'prompt'. new_prompt = parse_val_and_cond(tokens, line, filename, linenr) elif t0 == T_DEFAULT: new_def_exprs.append(parse_val_and_cond(tokens, line, filename, linenr)) elif t0 == T_DEPENDS: if not tokens.check(T_ON): _parse_error(line, 'expected "on" after "depends".', filename, linenr) parsed_deps = self._parse_expr(tokens, stmt, line, filename, linenr) if isinstance(stmt, (Menu, Comment)): stmt.dep_expr = self._make_and(stmt.dep_expr, parsed_deps) else: depends_on_expr = self._make_and(depends_on_expr, parsed_deps) elif t0 == T_VISIBLE: if not tokens.check(T_IF): _parse_error(line, 'expected "if" after "visible".', filename, linenr) if not isinstance(stmt, Menu): _parse_error(line, "'visible if' is only valid for menus.", filename, linenr) parsed_deps = self._parse_expr(tokens, stmt, line, filename, linenr) stmt.visible_if_expr = self._make_and(stmt.visible_if_expr, parsed_deps) elif t0 == T_SELECT: target = tokens.get_next() stmt.referenced_syms.add(target) stmt.selected_syms.add(target) if tokens.check(T_IF): new_selects.append((target, self._parse_expr(tokens, stmt, line, filename, linenr))) else: new_selects.append((target, None)) elif t0 in (T_BOOL, T_TRISTATE, T_INT, T_HEX, T_STRING): stmt.type = token_to_type[t0] if len(tokens) > 1: new_prompt = parse_val_and_cond(tokens, line, filename, linenr) elif t0 == T_RANGE: lower = tokens.get_next() upper = tokens.get_next() if tokens.check(T_IF): stmt.ranges.append((lower, upper, self._parse_expr(tokens, stmt, line, filename, linenr))) else: stmt.ranges.append((lower, upper, None)) elif t0 == T_DEF_BOOL: stmt.type = BOOL if len(tokens) > 1: new_def_exprs.append(parse_val_and_cond(tokens, line, filename, linenr)) elif t0 == T_DEF_TRISTATE: stmt.type = TRISTATE if len(tokens) > 1: new_def_exprs.append(parse_val_and_cond(tokens, line, filename, linenr)) elif t0 == T_OPTIONAL: if not isinstance(stmt, Choice): _parse_error(line, '"optional" is only valid for choices.', filename, linenr) stmt.optional = True elif t0 == T_OPTION: if tokens.check(T_ENV) and tokens.check(T_EQUAL): env_var = tokens.get_next() stmt.is_special_ = True stmt.is_from_env = True if env_var not in os.environ: self._warn(""" The symbol {0} references the non-existent environment variable {1} and will get the empty string as its value. You could set it in os.environ before calling Config() or make sure it is exported before invoking the script by running e.g. $ export {1}= $ python foo.py or $ {1}= python foo.py If you're using kconfiglib via 'make scriptconfig' it should have set up the environment correctly for you. If you still got this message, that might be an error, and you should e-mail kconfiglib@gmail.com. .""" .format(stmt.get_name(), env_var), filename, linenr) stmt.cached_value = "" else: stmt.cached_value = os.environ[env_var] elif tokens.check(T_DEFCONFIG_LIST): self.defconfig_sym = stmt elif tokens.check(T_MODULES): self._warn("the 'modules' option is not supported. " "Let me know if this is a problem for you; " "it shouldn't be that hard to implement.", filename, linenr) else: _parse_error(line, "unrecognized option.", filename, linenr) else: # See comment in Config.__init__() self.end_line = line self.end_line_tokens = tokens break # Propagate dependencies from enclosing menus and if's. # For menus and comments.. if isinstance(stmt, (Menu, Comment)): stmt.orig_deps = stmt.dep_expr stmt.deps_from_containing = deps stmt.dep_expr = self._make_and(stmt.dep_expr, deps) stmt.all_referenced_syms = \ stmt.referenced_syms.union(self._get_expr_syms(deps)) # For symbols and choices.. else: # See comment for 'menu_dep' stmt.menu_dep = depends_on_expr # Propagate dependencies specified with 'depends on' to any new # default expressions, prompts, and selections. ("New" since a # symbol might be defined in multiple places and the dependencies # should only apply to the local definition.) new_def_exprs = [(val_expr, self._make_and(cond_expr, depends_on_expr)) for (val_expr, cond_expr) in new_def_exprs] new_selects = [(target, self._make_and(cond_expr, depends_on_expr)) for (target, cond_expr) in new_selects] if new_prompt is not None: prompt, cond_expr = new_prompt # 'visible if' dependencies from enclosing menus get propagated # to prompts if visible_if_deps is not None: cond_expr = self._make_and(cond_expr, visible_if_deps) new_prompt = (prompt, self._make_and(cond_expr, depends_on_expr)) # We save the original expressions -- before any menu and if # conditions have been propagated -- so these can be retrieved # later. stmt.orig_def_exprs.extend(new_def_exprs) if new_prompt is not None: stmt.orig_prompts.append(new_prompt) # Only symbols can select if isinstance(stmt, Symbol): stmt.orig_selects.extend(new_selects) # Save dependencies from enclosing menus and if's stmt.deps_from_containing = deps # The set of symbols referenced directly by the symbol/choice plus # all symbols referenced by enclosing menus and if's. stmt.all_referenced_syms \ = stmt.referenced_syms.union(self._get_expr_syms(deps)) # Propagate dependencies from enclosing menus and if's stmt.def_exprs.extend([(val_expr, self._make_and(cond_expr, deps)) for (val_expr, cond_expr) in new_def_exprs]) for (target, cond) in new_selects: target.rev_dep = self._make_or(target.rev_dep, self._make_and(stmt, self._make_and(cond, deps))) if new_prompt is not None: prompt, cond_expr = new_prompt stmt.prompts.append((prompt, self._make_and(cond_expr, deps))) # # Symbol table manipulation # def _sym_lookup(self, name, add_sym_if_not_exists = True): """Fetches the symbol 'name' from the symbol table, optionally adding it if it does not exist (this is usually what we want).""" if name in self.syms: return self.syms[name] new_sym = Symbol() new_sym.config = self new_sym.name = name if add_sym_if_not_exists: self.syms[name] = new_sym else: # This warning is generated while evaluating an expression # containing undefined symbols using Config.eval() self._warn("no symbol {0} in configuration".format(name)) return new_sym # # Evaluation of symbols and expressions # def _eval_expr(self, expr): """Evaluates an expression and returns one of the tristate values "n", "m" or "y".""" res = self._eval_expr_2(expr) # Promote "m" to "y" if we're running without modules. Internally, "m" # is often rewritten to "m" && MODULES by both the C implementation and # kconfiglib, which takes care of cases where "m" should be false if # we're running without modules. if res == "m" and not self._has_modules(): return "y" return res def _eval_expr_2(self, expr): if expr is None: return "y" if isinstance(expr, (str, Symbol)): val = self._get_str_value(expr) # Expressions always have a tristate value return val if val in ("y", "m") else "n" first_expr = expr[0] if first_expr == OR: res = "n" for subexpr in expr[1]: ev = self._eval_expr_2(subexpr) # Return immediately upon discovering a "y" term if ev == "y": return "y" if ev == "m": res = "m" # 'res' is either "n" or "m" here; we already handled the # short-circuiting "y" case in the loop. return res if first_expr == AND: res = "y" for subexpr in expr[1]: ev = self._eval_expr_2(subexpr) # Return immediately upon discovering an "n" term if ev == "n": return "n" if ev == "m": res = "m" # 'res' is either "m" or "y" here; we already handled the # short-circuiting "n" case in the loop. return res if first_expr == NOT: ev = self._eval_expr_2(expr[1]) if ev == "y": return "n" return "y" if (ev == "n") else "m" if first_expr == EQUAL: return "y" if (self._get_str_value(expr[1]) == self._get_str_value(expr[2])) else "n" if first_expr == UNEQUAL: return "y" if (self._get_str_value(expr[1]) != self._get_str_value(expr[2])) else "n" _internal_error("Internal error while evaluating expression: " "unknown operation {0}.".format(first_expr)) def _get_str_value(self, obj): if isinstance(obj, str): return obj # obj is a Symbol return obj.calc_value() def _eval_min(self, e1, e2): e1_eval = self._eval_expr(e1) e2_eval = self._eval_expr(e2) return e1_eval if tri_less(e1_eval, e2_eval) else e2_eval def _eval_max(self, e1, e2): e1_eval = self._eval_expr(e1) e2_eval = self._eval_expr(e2) return e1_eval if tri_greater(e1_eval, e2_eval) else e2_eval # # Construction of expressions # # These functions as well as the _eval_min/max() functions above equate # None with "y", which is usually what we want, but needs to be kept in # mind. def _make_or(self, e1, e2): # Perform trivial simplification and avoid None's (which # correspond to y's) if "y" in (e1, e2) or None in (e1, e2): return "y" if e1 == "n": return e2 if e2 == "n": return e1 # Prefer to merge/update argument list if possible instead of creating # a new OR node if isinstance(e1, tuple) and e1[0] == OR: if isinstance(e2, tuple) and e2[0] == OR: return (OR, e1[1] + e2[1]) return (OR, e1[1] + [e2]) if isinstance(e2, tuple) and e2[0] == OR: return (OR, e2[1] + [e1]) return (OR, [e1, e2]) # Note: returns None if e1 == e2 == None def _make_and(self, e1, e2): if "n" in (e1, e2): return "n" if e1 in (None, "y"): return e2 if e2 in (None, "y"): return e1 # Prefer to merge/update argument list if possible instead of creating # a new AND node if isinstance(e1, tuple) and e1[0] == AND: if isinstance(e2, tuple) and e2[0] == AND: return (AND, e1[1] + e2[1]) return (AND, e1[1] + [e2]) if isinstance(e2, tuple) and e2[0] == AND: return (AND, e2[1] + [e1]) return (AND, [e1, e2]) # # Methods related to the MODULES symbol # def _has_modules(self): modules_sym = self.syms.get("MODULES") return (modules_sym is not None) and (modules_sym.calc_value() == "y") # # Dependency tracking # def _build_dep(self): """Populates the dep dictionary, linking a symbol to the symbols that immediately depend on it.""" for sym in self.syms.itervalues(): self.dep[sym] = set() def add_expr_deps(e, sym): for s in self._get_expr_syms(e): self.dep[s].add(sym) # The directly dependent symbols of a symbol are: # - Any symbols whose prompt or default value depends on the symbol # - Any symbols whose rev_dep (select condition) depends on the symbol # - Any symbols that belong to the same choice statement as the symbol # (these won't be included in 'dep' as that makes the dependency # graph unwieldy, but Symbol._get_dependent() will include them) # - Any symbols in a choice statement that depends on the symbol for sym in self.syms.itervalues(): for (_, e) in sym.prompts: add_expr_deps(e, sym) for (v, e) in sym.def_exprs: add_expr_deps(v, sym) add_expr_deps(e, sym) add_expr_deps(sym.rev_dep, sym) if sym.is_choice_item(): choice = sym.parent for (_, e) in choice.prompts: add_expr_deps(e, sym) for (_, e) in choice.def_exprs: add_expr_deps(e, sym) def _get_expr_syms(self, expr): """Returns the set() of symbols appearing in expr.""" if expr is None or isinstance(expr, str): return set() if isinstance(expr, Symbol): return set((expr,)) elif expr[0] in (OR, AND): res = set() for subres in [self._get_expr_syms(e) for e in expr[1]]: res.update(subres) return res elif expr[0] == NOT: return self._get_expr_syms(expr[1]) elif expr[0] in (EQUAL, UNEQUAL): res = set() (_, v1, v2) = expr if isinstance(v1, Symbol): res.add(v1) if isinstance(v2, Symbol): res.add(v2) return res else: _internal_error("Internal error while fetching symbols from an expression with " "token stream {0}.".format(expr)) def _expr_val_str(self, expr, no_value_str = "(none)", get_val_instead_of_eval = False): # Since values are valid expressions, _expr_to_str() will get a nice # string representation for those as well. if expr is None: return no_value_str if get_val_instead_of_eval: if isinstance(expr, str): return _expr_to_str(expr) val = expr.calc_value() else: val = self._eval_expr(expr) return "{0} (value: {1})".format(_expr_to_str(expr), _expr_to_str(val)) def _expand_sym_refs(self, s): """Expands $-references to symbols in 's' to symbol values, or to the empty string for undefined symbols.""" while True: sym_ref_re_match = sym_ref_re.search(s) if sym_ref_re_match is None: return s sym_name = sym_ref_re_match.group(0)[1:] sym = self.syms.get(sym_name) expansion = "" if sym is None else sym.calc_value() s = s[:sym_ref_re_match.start()] + \ expansion + \ s[sym_ref_re_match.end():] def _get_sym_or_choice_str(self, sc): """Symbols and choices have many properties in common, so we factor out common __str__() stuff here. "sc" is short for "symbol or choice".""" # As we deal a lot with string representations here, use some # convenient shorthand: s = _expr_to_str # # Common symbol/choice properties # user_value_str = "(no user value)" if sc.user_val is None else s(sc.user_val) visibility_str = s(sc.get_visibility()) # Build prompts string if sc.prompts == []: prompts_str = " (no prompts)" else: prompts_str_rows = [] for (prompt, cond_expr) in sc.orig_prompts: if cond_expr is None: prompts_str_rows.append(' "{0}"'.format(prompt)) else: prompts_str_rows.append(' "{0}" if '.format(prompt) + self._expr_val_str(cond_expr)) prompts_str = "\n".join(prompts_str_rows) # Build locations string if sc.def_locations == []: locations_str = "(no locations)" else: locations_str = " ".join(["{0}:{1}".format(filename, linenr) for (filename, linenr) in sc.def_locations]) # Build additional-dependencies-from-menus-and-if's string additional_deps_str = " " + self._expr_val_str(sc.deps_from_containing, "(no additional dependencies)") # # Symbol-specific stuff # if isinstance(sc, Symbol): # Build value string value_str = s(sc.calc_value()) # Build ranges string if isinstance(sc, Symbol): if sc.ranges == []: ranges_str = " (no ranges)" else: ranges_str_rows = [] for (l, u, cond_expr) in sc.ranges: if cond_expr is None: ranges_str_rows.append(" [{0}, {1}]".format(s(l), s(u))) else: ranges_str_rows.append(" [{0}, {1}] if {2}" .format(s(l), s(u), self._expr_val_str(cond_expr))) ranges_str = "\n".join(ranges_str_rows) # Build default values string if sc.def_exprs == []: defaults_str = " (no default values)" else: defaults_str_rows = [] for (val_expr, cond_expr) in sc.orig_def_exprs: row_str = " " + self._expr_val_str(val_expr, "(none)", sc.get_type() == STRING) defaults_str_rows.append(row_str) defaults_str_rows.append(" Condition: " + self._expr_val_str(cond_expr)) defaults_str = "\n".join(defaults_str_rows) # Build selects string if sc.orig_selects == []: selects_str = " (no selects)" else: selects_str_rows = [] for (target, cond_expr) in sc.orig_selects: if cond_expr is None: selects_str_rows.append(" {0}".format(target.name)) else: selects_str_rows.append(" {0} if ".format(target.name) + self._expr_val_str(cond_expr)) selects_str = "\n".join(selects_str_rows) # Build reverse dependencies string if sc.rev_dep == "n": rev_dep_str = " (no reverse dependencies)" else: rev_dep_str = " " + self._expr_val_str(sc.rev_dep) res = _sep_lines("Symbol " + (sc.name if sc.name is not None else "(no name)"), "Type : " + typename[sc.type], "Value : " + value_str, "User value : " + user_value_str, "Visibility : " + visibility_str, "Is choice item : " + bool_str[sc.is_choice_item()], "Is defined : " + bool_str[sc.is_defined_], "Is from env. : " + bool_str[sc.is_from_environment()], "Is special : " + bool_str[sc.is_special_] + "\n") if sc.has_ranges(): res += _sep_lines("Ranges:", ranges_str + "\n") res += _sep_lines("Prompts:", prompts_str, "Default values:", defaults_str, "Selects:", selects_str, "Reverse dependencies:", rev_dep_str, "Additional dependencies from enclosing menus and if's:", additional_deps_str, "Locations: " + locations_str) return res # # Choice-specific stuff # # Build name string (for named choices) if sc.get_name() is None: name_str = "(no name)" else: name_str = sc.get_name() # Build selected symbol string sel = sc.get_selection() if sel is None: sel_str = "(no selection)" else: sel_str = sel.get_name() # Build mode string mode_str = s(sc.calc_mode()) # Build default values string if sc.def_exprs == []: defaults_str = " (no default values)" else: defaults_str_rows = [] for (sym, cond_expr) in sc.orig_def_exprs: if cond_expr is None: defaults_str_rows.append(" {0}".format(sym.get_name())) else: defaults_str_rows.append(" {0} if ".format(sym.get_name()) + self._expr_val_str(cond_expr)) defaults_str = "\n".join(defaults_str_rows) # Build contained symbols string names = [sym.get_name() for sym in sc.get_actual_items()] if names == []: syms_string = "(empty)" else: syms_string = " ".join(names) return _sep_lines("Choice", "Name (for named choices): " + name_str, "Type : " + typename[sc.type], "Selected symbol : " + sel_str, "User value : " + user_value_str, "Mode : " + mode_str, "Visibility : " + visibility_str, "Optional : " + bool_str[sc.optional], "Prompts:", prompts_str, "Defaults:", defaults_str, "Choice symbols:", " " + syms_string, "Additional dependencies from enclosing menus and if's:", additional_deps_str, "Locations: " + locations_str) def _expr_depends_on(self, expr, sym): """Reimplementation of expr_depends_symbol() from mconf.c. Used to determine if a submenu should be implicitly created, which influences what items inside choice statements are considered choice items.""" if expr is None: return False def rec(expr): if isinstance(expr, str): return False if isinstance(expr, Symbol): return expr is sym if expr[0] in (EQUAL, UNEQUAL): return self._eq_to_sym(expr) is sym if expr[0] == AND: for and_expr in expr[1]: if rec(and_expr): return True return False return rec(expr) def _eq_to_sym(self, eq): """_expr_depends_on() helper. For (in)equalities of the form sym = y/m or sym != n, returns sym. For other (in)equalities, returns None.""" (relation, left, right) = eq left = self._transform_n_m_y(left) right = self._transform_n_m_y(right) # Make sure the symbol (if any) appears to the left if not isinstance(left, Symbol): left, right = right, left if not isinstance(left, Symbol): return None if (relation == EQUAL and right in ("m", "y")) or \ (relation == UNEQUAL and right == "n"): return left return None def _transform_n_m_y(self, item): """_eq_to_sym() helper. Translates the symbols n, m, and y to their string equivalents.""" if item is self.n: return "n" if item is self.m: return "m" if item is self.y: return "y" return item def _warn(self, msg, filename = None, linenr = None): """For printing warnings to stderr.""" if self.print_warnings: self._warn_or_undef_assign(msg, WARNING, filename, linenr) def _undef_assign(self, msg, filename = None, linenr = None): """For printing informational messages related to assignments to undefined variables to stderr.""" if self.print_undef_assign: self._warn_or_undef_assign(msg, UNDEF_ASSIGN, filename, linenr) def _warn_or_undef_assign(self, msg, msg_type, filename, linenr): if filename is not None: sys.stderr.write("{0}:".format(_clean_up_path(filename))) if linenr is not None: sys.stderr.write("{0}:".format(linenr)) if msg_type == WARNING: sys.stderr.write("warning: ") elif msg_type == UNDEF_ASSIGN: sys.stderr.write("info: ") else: _internal_error('Internal error while printing warning: unknown warning type "{0}".' .format(msg_type)) sys.stderr.write(msg + "\n") # # Constants and functions related to types, parsing, evaluation and printing, # put globally to unclutter the Config class a bit. # # Tokens (T_OR, T_AND, T_NOT, T_OPEN_PAREN, T_CLOSE_PAREN, T_EQUAL, T_UNEQUAL, T_MAINMENU, T_MENU, T_ENDMENU, T_SOURCE, T_CHOICE, T_ENDCHOICE, T_COMMENT, T_CONFIG, T_MENUCONFIG, T_HELP, T_IF, T_ENDIF, T_DEPENDS, T_ON, T_OPTIONAL, T_PROMPT, T_DEFAULT, T_BOOL, T_TRISTATE, T_HEX, T_INT, T_STRING, T_DEF_BOOL, T_DEF_TRISTATE, T_SELECT, T_RANGE, T_OPTION, T_ENV, T_DEFCONFIG_LIST, T_MODULES, T_VISIBLE) = range(0, 38) # Keyword to token map keywords = { "mainmenu" : T_MAINMENU, "menu" : T_MENU, "endmenu" : T_ENDMENU, "endif" : T_ENDIF, "endchoice" : T_ENDCHOICE, "source" : T_SOURCE, "choice" : T_CHOICE, "config" : T_CONFIG, "comment" : T_COMMENT, "menuconfig" : T_MENUCONFIG, "help" : T_HELP, "if" : T_IF, "depends" : T_DEPENDS, "on" : T_ON, "optional" : T_OPTIONAL, "prompt" : T_PROMPT, "default" : T_DEFAULT, "bool" : T_BOOL, "boolean" : T_BOOL, "tristate" : T_TRISTATE, "int" : T_INT, "hex" : T_HEX, "def_bool" : T_DEF_BOOL, "def_tristate" : T_DEF_TRISTATE, "string" : T_STRING, "select" : T_SELECT, "range" : T_RANGE, "option" : T_OPTION, "env" : T_ENV, "defconfig_list" : T_DEFCONFIG_LIST, "modules" : T_MODULES, "visible" : T_VISIBLE } # Strings to use for True and False bool_str = { False : "false", True : "true" } # Tokens after which identifier-like lexemes are treated as strings. T_CHOICE # is included to avoid symbols being registered for named choices. string_lex = (T_BOOL, T_TRISTATE, T_INT, T_HEX, T_STRING, T_CHOICE, T_PROMPT, T_MENU, T_COMMENT, T_SOURCE, T_MAINMENU) # Characters that may appear in symbol names sym_chars = frozenset(string.ascii_letters + string.digits + "._/-") # Characters that might be the first significant character on a line. Other # characters are ignored at the beginning of a line. command_chars = frozenset(string.ascii_letters + string.digits + "_"); # Regular expressions for parsing .config files set_re = re.compile(r"CONFIG_(\w+)=(.*)") unset_re = re.compile(r"# CONFIG_(\w+) is not set") # Regular expression for finding $-references to symbols in strings sym_ref_re = re.compile(r"\$[A-Za-z_]+") # Integers representing symbol types UNKNOWN, BOOL, TRISTATE, STRING, HEX, INT = range(0, 6) # Strings to use for types typename = { UNKNOWN : "unknown", BOOL : "bool", TRISTATE : "tristate", STRING : "string", HEX : "hex", INT : "int" } # Token to type mapping token_to_type = { T_BOOL : BOOL, T_TRISTATE : TRISTATE, T_STRING : STRING, T_INT : INT, T_HEX : HEX } # Default values for symbols of different types (the value the symbol gets if # it is not assigned a user value and none of its 'default' clauses kick in) default_value = { BOOL : "n", TRISTATE : "n", STRING : "", INT : "", HEX : "" } # Indicates that no item is selected in a choice statement NO_SELECTION = 0 # Integers representing expression types OR, AND, NOT, EQUAL, UNEQUAL = range(0, 5) # Map from tristate values to integers tri_to_int = { "n" : 0, "m" : 1, "y" : 2 } # Printing-related stuff op_to_str = { AND : " && ", OR : " || ", EQUAL : " = ", UNEQUAL : " != " } precedence = { OR : 0, AND : 1, NOT : 2 } # Types of informational messages WARNING = 0 UNDEF_ASSIGN = 1 def _intersperse(lst, op): """_expr_to_str() helper. Gets the string representation of each expression in lst and produces a list where op has been inserted between the elements.""" if lst == []: return "" res = [] def handle_sub_expr(expr): no_parens = isinstance(expr, (str, Symbol)) or \ expr[0] in (EQUAL, UNEQUAL) or \ precedence[op] <= precedence[expr[0]] if not no_parens: res.append("(") res.extend(_expr_to_str_rec(expr)) if not no_parens: res.append(")") op_str = op_to_str[op] handle_sub_expr(lst[0]) for expr in lst[1:]: res.append(op_str) handle_sub_expr(expr) return res def _expr_to_str(expr): s = "".join(_expr_to_str_rec(expr)) return s def _sym_str_string(sym_or_str): if isinstance(sym_or_str, str): return '"{0}"'.format(sym_or_str) return sym_or_str.name def _expr_to_str_rec(expr): if expr is None: return [""] if isinstance(expr, (Symbol, str)): return [_sym_str_string(expr)] if expr[0] in (OR, AND): return _intersperse(expr[1], expr[0]) if expr[0] == NOT: need_parens = not isinstance(expr[1], (str, Symbol)) res = ["!"] if need_parens: res.append("(") res.extend(_expr_to_str_rec(expr[1])) if need_parens: res.append(")") return res if expr[0] in (EQUAL, UNEQUAL): return [_sym_str_string(expr[1]), op_to_str[expr[0]], _sym_str_string(expr[2])] class _Block: """Represents a list of items (symbols, menus, choice statements and comments) appearing at the top-level of a file or witin a menu, choice or if statement.""" def __init__(self): self.items = [] def get_items(self): return self.items def add_item(self, item): self.items.append(item) def add_items_from_block(self, block): self.items.extend(block.items) def _make_conf(self): # Collect the substrings in a list and later use join() instead of += # to build the final .config contents. With older Python versions, this # yields linear instead of quadratic complexity. strings = [] for item in self.items: strings.extend(item._make_conf()) return strings def add_depend_expr(self, expr): for item in self.items: item.add_depend_expr(expr) class Item(): """Base class for symbols and other Kconfig constructs. Subclasses are Symbol, Choice, Menu, and Comment.""" def is_symbol(self): """Returns True if the item is a symbol, otherwise False. Short for isinstance(item, kconfiglib.Symbol).""" return isinstance(self, Symbol) def is_choice(self): """Returns True if the item is a choice, otherwise False. Short for isinstance(item, kconfiglib.Choice).""" return isinstance(self, Choice) def is_menu(self): """Returns True if the item is a menu, otherwise False. Short for isinstance(item, kconfiglib.Menu).""" return isinstance(self, Menu) def is_comment(self): """Returns True if the item is a comment, otherwise False. Short for isinstance(item, kconfiglib.Comment).""" return isinstance(self, Comment) class _HasVisibility(): """Base class for elements that have a "visibility" that acts as an upper limit on the values a user can set for them. Subclasses are Symbol and Choice.""" def __init__(self): self.cached_visibility = None self.prompts = [] def _invalidate(self): self.cached_visibility = None def _calc_visibility(self): if self.cached_visibility is None: vis = "n" for (prompt, cond_expr) in self.prompts: vis = self.config._eval_max(vis, cond_expr) if isinstance(self, Symbol) and self.is_choice_item(): vis = self.config._eval_min(vis, self.parent._calc_visibility()) # Promote "m" to "y" if we're dealing with a non-tristate if vis == "m" and self.type != TRISTATE: vis = "y" self.cached_visibility = vis return self.cached_visibility class Symbol(Item, _HasVisibility): """Represents a configuration symbol.""" # # Public interface # def calc_value(self): """Calculate and return the value of the symbol.""" if self.cached_value is not None: return self.cached_value self.write_to_conf = False # The following means that what to the user looks like a reference to # an undefined symbol will actually get treated like a string whose # value is the symbol name, which can be a bit unexpected. if self.type == UNKNOWN: self.cached_value = self.name return self.name new_val = default_value[self.type] vis = self._calc_visibility() if self.type in (BOOL, TRISTATE): # The visibility and mode (modules-only or single-selection) of # choice items will be taken into account in self._calc_visibility() if self.is_choice_item(): if vis != "n": choice = self.parent mode = choice.calc_mode() self.write_to_conf = (mode != "n") if mode == "y": new_val = "y" if (choice.get_selection() is self) else "n" elif mode == "m": if self.user_val in ("m", "y"): new_val = "m" else: use_defaults = True if vis != "n": # If the symbol is visible and has a user value, use that. # Otherwise, look at defaults. self.write_to_conf = True if self.user_val is not None: new_val = self.config._eval_min(self.user_val, vis) use_defaults = False if use_defaults: for (val_expr, cond_expr) in self.def_exprs: cond_eval = self.config._eval_expr(cond_expr) if cond_eval != "n": self.write_to_conf = True new_val = self.config._eval_min(val_expr, cond_eval) break # Reverse dependencies take precedence rev_dep_val = self.config._eval_expr(self.rev_dep) if rev_dep_val != "n": self.write_to_conf = True new_val = self.config._eval_max(new_val, rev_dep_val) # Promote "m" to "y" for booleans if new_val == "m" and self.type == BOOL: new_val = "y" elif self.type == STRING: use_defaults = True if vis != "n": self.write_to_conf = True if self.user_val is not None: new_val = self.user_val use_defaults = False if use_defaults: for (val_expr, cond_expr) in self.def_exprs: if self.config._eval_expr(cond_expr) != "n": self.write_to_conf = True new_val = self.config._get_str_value(val_expr) break elif self.type in (HEX, INT): active_range = None use_defaults = True # TODO: HEX case should only accept hex and dec numbers for(l, u, cond_expr) in self.ranges: if self.config._eval_expr(cond_expr) != "n": l_str = self.config._get_str_value(l) u_str = self.config._get_str_value(u) if self.type == INT: if not _is_dec(l_str): l_str = "0" if not _is_dec(u_str): u_str = "0" active_range = (int(l_str), int(u_str)) else: # self.type == HEX if not _is_hex(l_str): l_str = "0x0" if not _is_hex(u_str): u_str = "0x0" active_range = (int(l_str, 16), int(u_str, 16)) break if vis != "n": self.write_to_conf = True if self.user_val is not None: if self.type == INT: if _is_dec(self.user_val): num = int(self.user_val) if active_range is None or \ active_range[0] <= num <= active_range[1]: use_defaults = False new_val = self.user_val else: # HEX if _is_hex(self.user_val): num = int(self.user_val, 16) if active_range is None or \ active_range[0] <= num <= active_range[1]: use_defaults = False new_val = self.user_val if use_defaults: for (val_expr, cond_expr) in self.def_exprs: if self.config._eval_expr(cond_expr) != "n": self.write_to_conf = True # Kconfig allows arbitrary string values for hex/int. # (Possibly a bug, but we still emulate it.) new_val = self.config._get_str_value(val_expr) if self.type == INT: if _is_dec(new_val): new_val_num = int(new_val) elif self.type == HEX: if _is_hex(new_val): new_val_num = int(new_val, 16) if new_val_num is not None: if active_range is not None: l_num, u_num = active_range was_clamped = False if new_val_num < l_num: new_val_num = l_num was_clamped = True elif new_val_num > u_num: new_val_num = u_num was_clamped = True if was_clamped: new_val = (str(new_val_num) if self.type == INT else hex(new_val_num)) break self.cached_value = new_val return new_val def calc_default_value(self): """Calculates the value the symbol would get purely from defaults, ignoring visibility (assumed to be "y"), reverse dependencies (selects), user values and dependencies from enclosing menus and if's. Returns None if no default would kick in.""" for (val_expr, cond_expr) in self.orig_def_exprs: cond_eval = self.config._eval_expr(cond_expr) if cond_eval != "n": return self.config._eval_expr(val_expr) return None def set_value(self, v): """Sets the (user) value of the symbol. Equal in effect to assigning the value to the symbol within a .config file. Use get_lower/upper_bound() to find the range of valid values for bool and tristate symbols; setting values outside this range will cause the user value to differ from the result of Symbol.calc_value(). Any value that is valid for the type (bool, tristate, etc.) will end up being reflected in Symbol.get_user_value() though. Any symbols dependent on the symbol are (recursively) invalidated, so things should just work with regards to dependencies. v -- The value to give to the symbol.""" self._set_value_no_invalidate(v, False) # There might be something more efficient you could do here, but play # it safe. if self.name == "MODULES": self.config._invalidate_all() return self._invalidate() self._invalidate_dependent() def reset(self): """Resets the value of the symbol, as if the symbol had never gotten a (user) value via Config.load_config() or Symbol.set_value(). Dependent symbols are recursively invalidated.""" self._reset_no_recursive_invalidate() self._invalidate_dependent() def get_user_value(self): """Returns the value assigned to the symbol in a .config or via Symbol.set_value() (provided the value was valid for the type of the symbol). Returns None in case of no user value.""" return self.user_val def get_name(self): """Returns the name of the symbol.""" return self.name def get_upper_bound(self): """For string/hex/int symbols and for bool and tristate symbols that cannot be modified (see is_modifiable()), returns None. Otherwise, returns the highest value the symbol can be set to with Symbol.set_value() (that will not be truncated): one of "m" or "y", arranged from lowest to highest. This corresponds to the highest value the symbol could be given in e.g. the 'make menuconfig' interface. See also the tri_less*() and tri_greater*() functions, which could come in handy.""" if self.type not in (BOOL, TRISTATE): return None rev_dep = self.config._eval_expr(self.rev_dep) # A bool selected to "m" gets promoted to "y" if self.type == BOOL and rev_dep == "m": rev_dep = "y" vis = self._calc_visibility() if (tri_to_int[vis] - tri_to_int[rev_dep]) > 0: return vis return None def get_lower_bound(self): """For string/hex/int symbols and for bool and tristate symbols that cannot be modified (see is_modifiable()), returns None. Otherwise, returns the lowest value the symbol can be set to with Symbol.set_value() (that will not be truncated): one of "n" or "m", arranged from lowest to highest. This corresponds to the lowest value the symbol could be given in e.g. the 'make menuconfig' interface. See also the tri_less*() and tri_greater*() functions, which could come in handy.""" if self.type not in (BOOL, TRISTATE): return None rev_dep = self.config._eval_expr(self.rev_dep) # A bool selected to "m" gets promoted to "y" if self.type == BOOL and rev_dep == "m": rev_dep = "y" if (tri_to_int[self._calc_visibility()] - tri_to_int[rev_dep]) > 0: return rev_dep return None def get_assignable_values(self): """For string/hex/int symbols and for bool and tristate symbols that cannot be modified (see is_modifiable()), returns the empty list. Otherwise, returns a list containing the tristate values that can be assigned to the symbol (that won't be truncated). Usage example: if "m" in sym.get_assignable_values(): sym.set_value("m") This is basically a more convenient interface to get_lower/upper_bound() when wanting to test if a particular tristate value can be assigned.""" if self.type not in (BOOL, TRISTATE): return [] rev_dep = self.config._eval_expr(self.rev_dep) # A bool selected to "m" gets promoted to "y" if self.type == BOOL and rev_dep == "m": rev_dep = "y" res = ["n", "m", "y"][tri_to_int[rev_dep] : tri_to_int[self._calc_visibility()] + 1] return res if len(res) > 1 else [] def get_type(self): """Returns the type of the symbol: one of UNKNOWN, BOOL, TRISTATE, STRING, HEX, or INT. These are defined at the top level of the module, so you'd do something like if sym.get_type() == kconfiglib.STRING: ...""" return self.type def get_visibility(self): """Returns the visibility of the symbol: one of "n", "m" or "y". For bool and tristate symbols, this is an upper bound on the value users can set for the symbol. For other types of symbols, a visibility of "n" means the user value will be ignored. A visibility of "n" corresponds to not being visible in the 'make *config' interfaces.""" return self._calc_visibility() def get_parent(self): """Returns the menu or choice statement that contains the symbol, or None if the symbol is at the top level. Note that if statements are treated as syntactic sugar and do not have an explicit class representation.""" return self.parent def get_sibling_symbols(self, include_self = False): """Returns a list containing all symbols that are in the same menu or choice statement as the symbol, or that are also at the top level in case the symbol is at the top level. include_self (default: False) -- True if the symbol itself should be included in the result, otherwise False.""" return [item for item in self.get_sibling_items(include_self) if isinstance(item, Symbol)] def get_sibling_items(self, include_self = False): """Returns a list containing all items (symbols, menus, choice statements and comments) that are in the same menu or choice statement as the symbol, or that are also at the top level in case the symbol is at the top level. The items appear in the same order as within the configuration. include_self (default: False) -- True if the symbol itself should be included in the result, otherwise False.""" if self.parent is None: items = self.config.get_top_level_items() else: items = self.parent.get_items() if include_self: return items return [item for item in items if item is not self] def get_referenced_symbols(self, refs_from_enclosing = False): """Returns the set() of all symbols referenced by this symbol. For example, the symbol defined by config FOO bool prompt "foo" if A && B default C if D depends on E select F if G references the symbols A through G. refs_from_enclosing (default: False) -- If True, the symbols referenced by enclosing menus and if's will be included in the result.""" return self.all_referenced_syms if refs_from_enclosing else self.referenced_syms def get_selected_symbols(self): """Returns the set() of all symbols X for which this symbol has a 'select X' or 'select X if Y' (regardless of whether Y is satisfied or not). This is a subset of the symbols returned by get_referenced_symbols().""" return self.selected_syms def get_help(self): """Returns the help text of the symbol, or None if the symbol has no help text.""" return self.help def get_config(self): """Returns the Config instance that represents the configuration this symbol is from.""" return self.config def get_def_locations(self): """Returns a list of (filename, linenr) tuples, where filename (string) and linenr (int) represent a location where the symbol is defined. For the vast majority of symbols this list will only contain one element. For the following Kconfig, FOO would get two entries: the lines marked with *. config FOO * bool "foo prompt 1" config FOO * bool "foo prompt 2" """ return self.def_locations def get_ref_locations(self): """Returns a list of (filename, linenr) tuples, where filename (string) and linenr (int) represent a location where the symbol is referenced in the configuration. For example, the lines marked by * would be included for FOO below: config A bool default BAR || FOO * config B tristate depends on FOO * default m if FOO * if FOO * config A bool "A" endif config FOO (definition not included) bool """ return self.ref_locations def is_modifiable(self): """Returns True if the value of the symbol could be modified by calling Symbol.set_value() and False otherwise. For bools and tristates, this corresponds to the symbol being visible in the 'make menuconfig' interface and not already being pinned to a specific value (e.g. because it is selected by another symbol). For strings and numbers, this corresponds to just being visible.""" if self.is_special_: return False if self.type in (BOOL, TRISTATE): rev_dep = self.config._eval_expr(self.rev_dep) # A bool selected to "m" gets promoted to "y" if self.type == BOOL and rev_dep == "m": rev_dep = "y" return (tri_to_int[self._calc_visibility()] - tri_to_int[rev_dep]) > 0 return self._calc_visibility() != "n" def is_defined(self): """Returns False if the symbol is referred to in the Kconfig but never actually defined, otherwise True.""" return self.is_defined_ def is_special(self): """Returns True if the symbol is one of the special symbols n, m or y, or gets its value from the environment. Otherwise, returns False.""" return self.is_special_ def is_from_environment(self): """Returns True if the symbol gets its value from the environment. Otherwise, returns False.""" return self.is_from_env def has_ranges(self): """Returns True if the symbol is of type INT or HEX and has ranges that limits what values it can take on, otherwise False.""" return self.ranges != [] def is_choice_item(self): """Returns True if the symbol is in a choice statement and is an actual choice item (see Choice.get_actual_items()); otherwise, returns False.""" return self.is_choice_item_ def is_choice_selection(self): """Returns True if the symbol is contained in a choice statement and is the selected item, otherwise False. Equivalent to 'sym.is_choice_item() and sym.get_parent().get_selection() is sym'.""" return self.is_choice_item_ and \ self.parent.get_selection() is self def __str__(self): """Returns a string containing various information about the symbol.""" return self.config._get_sym_or_choice_str(self) # # Private methods # def __init__(self): """Symbol constructor -- not intended to be called directly by kconfiglib clients.""" # Set default values _HasVisibility.__init__(self) self.config = None self.parent = None self.name = None self.type = UNKNOWN self.def_exprs = [] self.ranges = [] self.rev_dep = "n" # The prompt, default value and select conditions without any # dependencies from menus or if's propagated to them self.orig_prompts = [] self.orig_def_exprs = [] self.orig_selects = [] # Dependencies inherited from containing menus and if's self.deps_from_containing = None self.help = None # The set of symbols referenced by this symbol (see # get_referenced_symbols()) self.referenced_syms = set() # The set of symbols selected by this symbol (see # get_selected_symbols()) self.selected_syms = set() # Like 'referenced_syms', but includes symbols from # dependencies inherited from enclosing menus and if's self.all_referenced_syms = set() # This is set to True for "actual" choice items. See # Choice._determine_actual_items(). The trailing underscore avoids a # collision with is_choice_item(). self.is_choice_item_ = False # This records only dependencies specified with 'depends on'. Needed # when determining actual choice items (hrrrr...). See also # Choice._determine_actual_items(). self.menu_dep = None # See Symbol.get_ref/def_locations(). self.def_locations = [] self.ref_locations = [] self.user_val = None # Flags # Should the symbol get an entry in .config? self.write_to_conf = False # Stores the calculated value to avoid unnecessary recalculation self.cached_value = None # Does the symbol have an entry in the Kconfig file? The Trailing # underscore avoids a collision with is_defined(). self.is_defined_ = False # Does the symbol get its value in some special way, e.g. from the # environment or by being one of the special symbols n, m, and y? If # so, the value is stored in self.cached_value, which is never # invalidated. The trailing underscore avoids a collision with # is_special(). self.is_special_ = False # Does the symbol get its value from the environment? self.is_from_env = False # See Choice._make_conf() self.already_written = False def _invalidate(self): if self.is_special_: return if self.is_choice_item(): self.parent._invalidate() _HasVisibility._invalidate(self) self.write_to_conf = False self.cached_value = None def _invalidate_dependent(self): for sym in self._get_dependent(): sym._invalidate() def _set_value_no_invalidate(self, v, suppress_load_warnings): """Like set_value(), but does not invalidate any symbols. suppress_load_warnings -- some warnings don't make sense when loading a .config that do make sense when manually invoking set_value(). This flag is set to True to suppress such warnings.""" if self.is_special_: if self.is_from_env: self.config._warn('attempt to assign the value "{0}" to the ' 'symbol {1}, which gets its value from the ' 'environment. Assignment ignored.' .format(v, self.name)) else: self.config._warn('attempt to assign the value "{0}" to the ' 'special symbol {1}. Assignment ignored.' .format(v, self.name)) return if not self.is_defined_: filename, linenr = self.ref_locations[0] self.config._undef_assign('attempt to assign the value "{0}" to {1}, ' "which is referenced at {2}:{3} but never " "defined. Assignment ignored." .format(v, self.name, filename, linenr)) return # Check if the value is valid for our type valid = ( self.type == BOOL and v in ("n", "y") ) or \ ( self.type == TRISTATE and v in ("n", "m", "y") ) or \ ( self.type == STRING ) or \ ( self.type == INT and _is_dec(v) ) or \ ( self.type == HEX and _is_hex(v) ) if not valid: self.config._warn('the value "{0}" is invalid for {1}, which has type {2}. ' "Assignment ignored." .format(v, self.name, typename[self.type])) return if self.prompts == [] and not suppress_load_warnings: self.config._warn('assigning "{0}" to the symbol {1} which lacks ' 'prompts and thus has visibility "n". The assignment ' 'will have no effect.' .format(v, self.name)) self.user_val = v if self.is_choice_item() and self.type in (BOOL, TRISTATE): choice = self.parent if v == "y": choice.user_val = self choice.user_mode = "y" elif v == "m": choice.user_val = None choice.user_mode = "m" def _reset_no_recursive_invalidate(self): self._invalidate() self.user_val = None if self.is_choice_item(): self.parent._reset() def _should_write(self): # This check shouldn't be necessary as write_to_conf is never modified # in calc_value() for special symbols, but just to be on the safe side: if self.is_special_: return False # Symbols defined in multiple locations only get one entry in the # .config. if self.already_written: return False # write_to_conf is determined in calc_value(), so we need to call that # first self.calc_value() return self.write_to_conf def _make_conf(self): if not self._should_write(): return [] self.already_written = True if self.type in (BOOL, TRISTATE): if self.calc_value() in ("m", "y"): return ["CONFIG_{0}={1}".format(self.name, self.calc_value())] return ["# CONFIG_{0} is not set".format(self.name)] elif self.type == STRING: return ['CONFIG_{0}="{1}"'.format(self.name, self.calc_value())] elif self.type in (INT, HEX): return ["CONFIG_{0}={1}".format(self.name, self.calc_value())] else: _internal_error('Internal error while creating .config: unknown type "{0}".' .format(self.type)) def _get_dependent(self): """Returns the list of symbols that should be invalidated if the value of the symbol changes.""" res = set() def rec(sym, ignore_choice = False): for s in self.config.dep[sym]: if s not in res: res.add(s) rec(s) # Handle choices specially to avoid lots of hopping around between # choice items (which all depend on each other) while calculating # dependencies if sym.is_choice_item() and not ignore_choice: choice = sym.get_parent() for s in choice.get_actual_items(): if s not in res and s is not self: res.add(s) rec(s, True) rec(self) return res def _has_auto_menu_dep_on(self, on): """See Choice._determine_actual_items().""" if not isinstance(self.parent, Choice): _internal_error("Attempt to determine auto menu dependency for symbol ouside of choice.") if self.prompts == []: # If we have no prompt, use the menu dependencies instead (what was # specified with 'depends on') return self.menu_dep is not None and \ self.config._expr_depends_on(self.menu_dep, on) for (_, cond_expr) in self.prompts: if self.config._expr_depends_on(cond_expr, on): return True return False class Menu(Item): """Represents a menu statement.""" # # Public interface # def get_depends_on_visibility(self): """Returns the visibility the menu gets from 'depends on' conditions. This is propagated to subitems.""" return self.config._eval_expr(self.dep_expr) def get_visible_if_visibility(self): """Returns the visibility the menu gets from its 'visible if' condition. "y" if the menu has no 'visible if' condition.""" return self.config._eval_expr(self.visible_if_expr) def get_items(self, recursive = False): """Returns a list containing the items (symbols, menus, choice statements and comments) in in the menu, in the same order that the items appear within the menu. recursive (default: False) -- True if items contained in items within the menu should be included recursively (preorder).""" if not recursive: return self.block.get_items() res = [] for item in self.block.get_items(): res.append(item) if isinstance(item, Menu): res.extend(item.get_items(True)) elif isinstance(item, Choice): res.extend(item.get_items()) return res def get_symbols(self, recursive = False): """Returns a list containing the symbols in the menu, in the same order that they appear within the menu. recursive (default: False) -- True if symbols contained in items within the menu should be included recursively.""" return [item for item in self.get_items(recursive) if isinstance(item, Symbol)] def get_title(self): """Returns the title text of the menu.""" return self.title def get_parent(self): """Returns the menu or choice statement that contains the menu, or None if the menu is at the top level. Note that if statements are treated as syntactic sugar and do not have an explicit class representation.""" return self.parent def get_referenced_symbols(self, refs_from_enclosing = False): """See Symbol.get_referenced_symbols().""" return self.all_referenced_syms if refs_from_enclosing else self.referenced_syms def get_location(self): """Returns the location of the menu as a (filename, linenr) tuple, where filename is a string and linenr an int.""" return (self.filename, self.linenr) def __str__(self): """Returns a string containing various information about the menu.""" depends_on_str = self.config._expr_val_str(self.orig_deps, "(no dependencies)") visible_if_str = self.config._expr_val_str(self.visible_if_expr, "(no dependencies)") additional_deps_str = " " + self.config._expr_val_str(self.deps_from_containing, "(no additional dependencies)") return _sep_lines("Menu", "Title : " + self.title, "'depends on' dependencies : " + depends_on_str, "'visible if' dependencies : " + visible_if_str, "Additional dependencies from enclosing menus and if's:", additional_deps_str, "Location: {0}:{1}".format(self.filename, self.linenr)) # # Private methods # def __init__(self): """Menu constructor -- not intended to be called directly by kconfiglib clients.""" self.config = None self.parent = None self.title = None self.block = None self.dep_expr = None # Dependency expression without dependencies from enclosing menus and # if's propagated self.orig_deps = None # Dependencies inherited from containing menus and if's self.deps_from_containing = None # The 'visible if' expression self.visible_if_expr = None # The set of symbols referenced by this menu (see # get_referenced_symbols()) self.referenced_syms = set() # Like 'referenced_syms', but includes symbols from # dependencies inherited from enclosing menus and if's self.all_referenced_syms = None self.filename = None self.linenr = None def _make_conf(self): item_conf = self.block._make_conf() if self.config._eval_expr(self.dep_expr) != "n" and \ self.config._eval_expr(self.visible_if_expr) != "n": return ["\n#\n# {0}\n#".format(self.title)] + item_conf return item_conf class Choice(Item, _HasVisibility): """Represents a choice statement. A choice can be in one of three modes: "n" - The choice is not visible and no symbols can be selected. "m" - Any number of symbols can be set to "m". The rest will be "n". This is safe since potentially conflicting options don't actually get compiled into the kernel simultaneously with "m". "y" - One symbol will be "y" while the rest are "n". Only tristate choices can be in "m" mode, and the visibility of the choice is an upper bound on the mode, so that e.g. a choice that depends on a symbol with value "m" will be in "m" mode. The mode changes automatically when a value is assigned to a symbol within the choice.""" # # Public interface # def get_selection(self): """Returns the symbol selected (either by the user or through defaults), or None if either no symbol is selected or the mode is not "y".""" if self.cached_selection is not None: if self.cached_selection == NO_SELECTION: return None return self.cached_selection if self.calc_mode() != "y": return self._cache_ret(None) # User choice available? if self.user_val is not None and \ self.user_val._calc_visibility() == "y": return self._cache_ret(self.user_val) if self.optional: return self._cache_ret(None) return self._cache_ret(self.get_selection_from_defaults()) def get_selection_from_defaults(self): """Like Choice.get_selection(), but acts as if no symbol has been selected by the user and no 'optional' flag is in effect.""" if self.actual_items == []: return None for (symbol, cond_expr) in self.def_exprs: if self.config._eval_expr(cond_expr) != "n": chosen_symbol = symbol break else: chosen_symbol = self.actual_items[0] # Is the chosen symbol visible? if chosen_symbol._calc_visibility() != "n": return chosen_symbol # Otherwise, pick the first visible symbol for sym in self.actual_items: if sym._calc_visibility() != "n": return sym return None def get_user_selection(self): """If the choice is in "y" mode and has a user-selected symbol, returns that symbol. Otherwise, returns None.""" return self.user_val def get_name(self): """For named choices, returns the name. Returns None for unnamed choices. No named choices appear anywhere in the kernel Kconfig files as of Linux 2.6.38-rc3.""" return self.name def get_help(self): """Returns the help text of the choice, or None if the choice has no help text.""" return self.help def get_type(self): """Returns the type of the choice. See Symbol.get_type().""" return self.type def get_items(self): """Gets all items contained in the choice in the same order as within the configuration ("items" instead of "symbols" since choices and comments might appear within choices. This only happens in one place as of Linux 2.6.38-rc3, in drivers/usb/gadget/Kconfig).""" return self.block.get_items() def get_actual_items(self): """A quirk (perhaps better described as a bug) of kconfig is that you can put items within a choice that will not be considered members of the choice insofar as selection is concerned. This happens for example if one symbol within a choice 'depends on' the symbol preceding it, or if you put non-symbol items within choices. This function gets a list of the "proper" elements of the choice in the order they appears in the choice, excluding such items.""" return self.actual_items def get_parent(self): """Returns the menu or choice statement that contains the choice, or None if the choice is at the top level. Note that if statements are treated as syntactic sugar and do not have an explicit class representation.""" return self.parent def get_referenced_symbols(self, refs_from_enclosing = False): """See Symbol.get_referenced_symbols().""" return self.all_referenced_syms if refs_from_enclosing else self.referenced_syms def get_def_locations(self): """Returns a list of (filename, linenr) tuples, where filename (string) and linenr (int) represent a location where the choice is defined. For the vast majority of choices this list will only contain one element, but its possible for named choices to be defined in multiple locations.""" return self.def_locations def get_visibility(self): """Returns the visibility of the choice statement: one of "n", "m" or "y". This acts as an upper limit on the mode of the choice (though bool choices can only have the mode "y"). See the class documentation for an explanation of modes.""" return self._calc_visibility() def calc_mode(self): """Returns the mode of the choice. See the class documentation for an explanation of modes.""" minimum_mode = "n" if self.optional else "m" mode = self.user_mode if self.user_mode is not None else minimum_mode mode = self.config._eval_min(mode, self._calc_visibility()) # Promote "m" to "y" for boolean choices if mode == "m" and self.type == BOOL: return "y" return mode def is_optional(self): """Returns True if the symbol has the optional flag set (and so will default to "n" mode). Otherwise, returns False.""" return self.optional def __str__(self): """Returns a string containing various information about the choice statement.""" return self.config._get_sym_or_choice_str(self) # # Private methods # def __init__(self): """Choice constructor -- not intended to be called directly by kconfiglib clients.""" _HasVisibility.__init__(self) self.config = None self.parent = None self.name = None # Yes, choices can be named self.type = UNKNOWN self.def_exprs = [] self.help = None self.optional = False self.block = None # The prompts and default values without any dependencies from # enclosing menus or if's propagated self.orig_prompts = [] self.orig_def_exprs = [] # Dependencies inherited from containing menus and if's self.deps_from_containing = None # We need to filter out symbols that appear within the choice block but # are not considered choice items (see # Choice._determine_actual_items()) This list holds the "actual" choice # items. self.actual_items = [] # The set of symbols referenced by this choice (see # get_referenced_symbols()) self.referenced_syms = set() # Like 'referenced_syms', but includes symbols from # dependencies inherited from enclosing menus and if's self.all_referenced_syms = set() # See Choice.get_def_locations() self.def_locations = [] self.user_val = None self.user_mode = None self.cached_selection = None def _determine_actual_items(self): """If a symbol's visibility depends on the preceding symbol within a choice, it is no longer viewed as a choice item (quite possibly a bug, but some things consciously use it.. ugh. It stems from automatic submenu creation). In addition, it's possible to have choices and comments within choices, and those shouldn't be considered as choice items either. Only drivers/usb/gadget/Kconfig seems to depend on any of this. This method computes the "actual" items in the choice and sets the is_choice_item_ flag on them (retrieved via is_choice_item()). Don't let this scare you: an earlier version simply checked for a sequence of symbols where all symbols after the first appeared in the 'depends on' expression of the first, and that worked fine. The added complexity is to be future-proof in the event that drivers/usb/gadget/Kconfig turns even more sinister. It might very well be overkilling things (especially if that file is refactored ;).""" items = self.block.get_items() # Items might depend on each other in a tree structure, so we need a # stack to keep track of the current tentative parent stack = [] for item in items: if not isinstance(item, Symbol): stack = [] continue while stack != []: if item._has_auto_menu_dep_on(stack[-1]): # The item should not be viewed as a choice item, so don't # set item.is_choice_item_. stack.append(item) break else: stack.pop() else: item.is_choice_item_ = True self.actual_items.append(item) stack.append(item) def _cache_ret(self, selection): # As None is used to indicate the lack of a cached value we can't use # that to cache the fact that the choice has no selection. Instead, we # use the symbolic constant NO_SELECTION. if selection is None: self.cached_selection = NO_SELECTION else: self.cached_selection = selection return selection def _get_user_mode(self): return self.user_mode def _invalidate(self): _HasVisibility._invalidate(self) self.cached_selection = None def _reset(self): self._invalidate() self.user_val = None self.user_mode = None def _make_conf(self): return self.block._make_conf() class Comment(Item): """Represents a comment statement.""" # # Public interface # def get_text(self): """Returns the text of the comment.""" return self.text def get_parent(self): """Returns the menu or choice statement that contains the comment, or None if the comment is at the top level. Note that if statements are treated as syntactic sugar and do not have an explicit class representation.""" return self.parent def get_referenced_symbols(self, refs_from_enclosing = False): """See Symbol.get_referenced_symbols().""" return self.all_referenced_syms if refs_from_enclosing else self.referenced_syms def get_location(self): """Returns the location of the comment as a (filename, linenr) tuple, where filename is a string and linenr an int.""" return (self.filename, self.linenr) def __str__(self): """Returns a string containing various information about the comment.""" dep_str = self.config._expr_val_str(self.orig_deps, "(no dependencies)") additional_deps_str = " " + self.config._expr_val_str(self.deps_from_containing, "(no additional dependencies)") return _sep_lines("Comment", "Text: " + str(self.text), "Dependencies: " + dep_str, "Additional dependencies from enclosing menus and if's:", additional_deps_str, "Location: {0}:{1}".format(self.filename, self.linenr)) # # Private methods # def __init__(self): """Comment constructor -- not intended to be called directly by kconfiglib clients.""" self.config = None self.parent = None self.text = None self.dep_expr = None # Dependency expression without dependencies from enclosing menus and # if's propagated self.orig_deps = None # Dependencies inherited from containing menus and if's self.deps_from_containing = None # The set of symbols referenced by this comment (see # get_referenced_symbols()) self.referenced_syms = set() # Like 'referenced_syms', but includes symbols from # dependencies inherited from enclosing menus and if's self.all_referenced_syms = None self.filename = None self.linenr = None def _make_conf(self): if self.config._eval_expr(self.dep_expr) != "n": return ["\n#\n# {0}\n#".format(self.text)] return [] class _Feed: """Class for working with sequences in a stream-like fashion; handy for tokens.""" def __init__(self, items): self.items = items self.length = len(self.items) self.i = 0 def get_next(self): if self.i >= self.length: return None item = self.items[self.i] self.i += 1 return item def peek_next(self): return None if self.i >= self.length else self.items[self.i] def go_to_start(self): self.i = 0 def __getitem__(self, index): return self.items[index] def __len__(self): return len(self.items) def is_empty(self): return self.items == [] def is_at_end(self): return self.i >= self.length def check(self, token): """Check if the next token is 'token'. If so, remove it from the token feed and return True. Otherwise, leave it in and return False.""" if self.i >= self.length: return None if self.items[self.i] == token: self.i += 1 return True return False def remove_while(self, pred): while self.i < self.length and pred(self.items[self.i]): self.i += 1 def go_back(self): if self.i <= 0: _internal_error("Attempt to move back in Feed while already at the beginning.") self.i -= 1 class _FileFeed(_Feed): """Feed subclass that keeps track of the current filename and line number.""" def __init__(self, lines, filename): self.filename = _clean_up_path(filename) _Feed.__init__(self, lines) def get_filename(self): return self.filename def get_linenr(self): return self.i # # Misc. public global utility functions # def tri_less(v1, v2): """Returns True if the tristate v1 is less than the tristate v2, where "n", "m" and "y" are ordered from lowest to highest. Otherwise, returns False.""" return tri_to_int[v1] < tri_to_int[v2] def tri_less_eq(v1, v2): """Returns True if the tristate v1 is less than or equal to the tristate v2, where "n", "m" and "y" are ordered from lowest to highest. Otherwise, returns False.""" return tri_to_int[v1] <= tri_to_int[v2] def tri_greater(v1, v2): """Returns True if the tristate v1 is greater than the tristate v2, where "n", "m" and "y" are ordered from lowest to highest. Otherwise, returns False.""" return tri_to_int[v1] > tri_to_int[v2] def tri_greater_eq(v1, v2): """Returns True if the tristate v1 is greater than or equal to the tristate v2, where "n", "m" and "y" are ordered from lowest to highest. Otherwise, returns False.""" return tri_to_int[v1] >= tri_to_int[v2] # # Helper functions, mostly related to text processing # def _strip_quotes(s, line, filename, linenr): """Removes any quotes surrounding 's' if it has them; otherwise returns 's' unmodified.""" s = s.strip() if s[0] == '"' or s[0] == "'": if len(s) < 2 or s[-1] != s[0]: _parse_error(line, "malformed string literal", filename, linenr) return s[1:-1] return s def _indentation(line): """Returns the indentation of the line, treating tab stops as being spaced 8 characters apart.""" if line.isspace(): _internal_error("Attempt to take indentation of blank line.") indent = 0 for c in line: if c == " ": indent += 1 elif c == "\t": # Go to the next tab stop indent = (indent + 8) & ~7 else: return indent def _deindent(line, indent): """Deindent 'line' by 'indent' spaces.""" line = line.expandtabs() if len(line) <= indent: return line return line[indent:] def _is_hex(s): return _is_base_n(s, 16) def _is_dec(s): return _is_base_n(s, 10) def _is_base_n(s, n): try: int(s, n) return True except ValueError: return False def _sep_lines(*args): """Returns a string comprised of all arguments, with newlines inserted between them.""" return "\n".join(args) def _comment(s): """Returns a new string with "# " inserted before each line in 's'.""" return "\n".join(["# " + line for line in s.splitlines()]) def _get_lines(filename): """Returns a list of lines from 'filename', joining any line ending in \\ with the following line.""" with open(filename, "r") as f: lines = [] accum = "" while True: line = f.readline() if line == "": return lines if line.endswith("\\\n"): accum += line[:-2] else: accum += line lines.append(accum) accum = "" def _strip_trailing_slash(path): """Removes any trailing slash from 'path'.""" return path[:-1] if path.endswith("/") else path def _clean_up_path(path): """Strips any initial "./" and trailing slash from 'path'.""" if path.startswith("./"): path = path[2:] return _strip_trailing_slash(path) # # Error handling # class Kconfig_Syntax_Error(Exception): """Exception raised for syntax errors.""" pass class Internal_Error(Exception): """Exception raised for internal errors.""" pass def _tokenization_error(s, index, filename, linenr): if filename is not None: assert linenr is not None sys.stderr.write("{0}:{1}:\n".format(filename, linenr)) if s.endswith("\n"): s = s[:-1] # Calculate the visual offset corresponding to index 'index' in 's' # assuming tabstops are spaced 8 characters apart vis_index = 0 for c in s[:index]: if c == "\t": vis_index = (vis_index + 8) & ~7 else: vis_index += 1 # Don't output actual tabs to be independent of how the terminal renders # them s = s.expandtabs() raise Kconfig_Syntax_Error, ( _sep_lines("Error during tokenization at location indicated by caret.\n", s, " " * vis_index + "^\n")) def _parse_error(s, msg, filename, linenr): error_str = "" if filename is not None: assert linenr is not None error_str += "{0}:{1}: ".format(filename, linenr) if s.endswith("\n"): s = s[:-1] error_str += 'Error while parsing "{0}"'.format(s) if msg is None: error_str += "." else: error_str += ": " + msg raise Kconfig_Syntax_Error, error_str def _internal_error(msg): msg += "\nSorry! You may want to send an email to kconfiglib@gmail.com " \ "to tell me about this. Include the message above and the stack " \ "trace and describe what you were doing." raise Internal_Error, msg if use_psyco: import psyco Config._tokenize = psyco.proxy(Config._tokenize) Config._eval_expr = psyco.proxy(Config._eval_expr) _indentation = psyco.proxy(_indentation) _get_lines = psyco.proxy(_get_lines)