""" BitBake code parser Parses actual code (i.e. python and shell) for functions and in-line expressions. Used mainly to determine dependencies on other functions and variables within the BitBake metadata. Also provides a cache for this information in order to speed up processing. (Not to be confused with the code that parses the metadata itself, see lib/bb/parse/ for that). NOTE: if you change how the parsers gather information you will almost certainly need to increment CodeParserCache.CACHE_VERSION below so that any existing codeparser cache gets invalidated. Additionally you'll need to increment __cache_version__ in cache.py in order to ensure that old recipe caches don't trigger "Taskhash mismatch" errors. """ import ast import sys import codegen import logging import pickle import bb.pysh as pysh import os.path import bb.utils, bb.data import hashlib from itertools import chain from bb.pysh import pyshyacc, pyshlex, sherrors from bb.cache import MultiProcessCache logger = logging.getLogger('BitBake.CodeParser') def bbhash(s): return hashlib.md5(s.encode("utf-8")).hexdigest() def check_indent(codestr): """If the code is indented, add a top level piece of code to 'remove' the indentation""" i = 0 while codestr[i] in ["\n", "\t", " "]: i = i + 1 if i == 0: return codestr if codestr[i-1] == "\t" or codestr[i-1] == " ": if codestr[0] == "\n": # Since we're adding a line, we need to remove one line of any empty padding # to ensure line numbers are correct codestr = codestr[1:] return "if 1:\n" + codestr return codestr # Basically pickle, in python 2.7.3 at least, does badly with data duplication # upon pickling and unpickling. Combine this with duplicate objects and things # are a mess. # # When the sets are originally created, python calls intern() on the set keys # which significantly improves memory usage. Sadly the pickle/unpickle process # doesn't call intern() on the keys and results in the same strings being duplicated # in memory. This also means pickle will save the same string multiple times in # the cache file. # # By having shell and python cacheline objects with setstate/getstate, we force # the object creation through our own routine where we can call intern (via internSet). # # We also use hashable frozensets and ensure we use references to these so that # duplicates can be removed, both in memory and in the resulting pickled data. # # By playing these games, the size of the cache file shrinks dramatically # meaning faster load times and the reloaded cache files also consume much less # memory. Smaller cache files, faster load times and lower memory usage is good. # # A custom getstate/setstate using tuples is actually worth 15% cachesize by # avoiding duplication of the attribute names! class SetCache(object): def __init__(self): self.setcache = {} def internSet(self, items): new = [] for i in items: new.append(sys.intern(i)) s = frozenset(new) h = hash(s) if h in self.setcache: return self.setcache[h] self.setcache[h] = s return s codecache = SetCache() class pythonCacheLine(object): def __init__(self, refs, execs, contains): self.refs = codecache.internSet(refs) self.execs = codecache.internSet(execs) self.contains = {} for c in contains: self.contains[c] = codecache.internSet(contains[c]) def __getstate__(self): return (self.refs, self.execs, self.contains) def __setstate__(self, state): (refs, execs, contains) = state self.__init__(refs, execs, contains) def __hash__(self): l = (hash(self.refs), hash(self.execs)) for c in sorted(self.contains.keys()): l = l + (c, hash(self.contains[c])) return hash(l) def __repr__(self): return " ".join([str(self.refs), str(self.execs), str(self.contains)]) class shellCacheLine(object): def __init__(self, execs): self.execs = codecache.internSet(execs) def __getstate__(self): return (self.execs) def __setstate__(self, state): (execs) = state self.__init__(execs) def __hash__(self): return hash(self.execs) def __repr__(self): return str(self.execs) class CodeParserCache(MultiProcessCache): cache_file_name = "bb_codeparser.dat" # NOTE: you must increment this if you change how the parsers gather information, # so that an existing cache gets invalidated. Additionally you'll need # to increment __cache_version__ in cache.py in order to ensure that old # recipe caches don't trigger "Taskhash mismatch" errors. CACHE_VERSION = 9 def __init__(self): MultiProcessCache.__init__(self) self.pythoncache = self.cachedata[0] self.shellcache = self.cachedata[1] self.pythoncacheextras = self.cachedata_extras[0] self.shellcacheextras = self.cachedata_extras[1] # To avoid duplication in the codeparser cache, keep # a lookup of hashes of objects we already have self.pythoncachelines = {} self.shellcachelines = {} def newPythonCacheLine(self, refs, execs, contains): cacheline = pythonCacheLine(refs, execs, contains) h = hash(cacheline) if h in self.pythoncachelines: return self.pythoncachelines[h] self.pythoncachelines[h] = cacheline return cacheline def newShellCacheLine(self, execs): cacheline = shellCacheLine(execs) h = hash(cacheline) if h in self.shellcachelines: return self.shellcachelines[h] self.shellcachelines[h] = cacheline return cacheline def init_cache(self, d): # Check if we already have the caches if self.pythoncache: return MultiProcessCache.init_cache(self, d) # cachedata gets re-assigned in the parent self.pythoncache = self.cachedata[0] self.shellcache = self.cachedata[1] def create_cachedata(self): data = [{}, {}] return data codeparsercache = CodeParserCache() def parser_cache_init(d): codeparsercache.init_cache(d) def parser_cache_save(): codeparsercache.save_extras() def parser_cache_savemerge(): codeparsercache.save_merge() Logger = logging.getLoggerClass() class BufferedLogger(Logger): def __init__(self, name, level=0, target=None): Logger.__init__(self, name) self.setLevel(level) self.buffer = [] self.target = target def handle(self, record): self.buffer.append(record) def flush(self): for record in self.buffer: if self.target.isEnabledFor(record.levelno): self.target.handle(record) self.buffer = [] class PythonParser(): getvars = (".getVar", ".appendVar", ".prependVar") getvarflags = (".getVarFlag", ".appendVarFlag", ".prependVarFlag") containsfuncs = ("bb.utils.contains", "base_contains") containsanyfuncs = ("bb.utils.contains_any", "bb.utils.filter") execfuncs = ("bb.build.exec_func", "bb.build.exec_task") def warn(self, func, arg): """Warn about calls of bitbake APIs which pass a non-literal argument for the variable name, as we're not able to track such a reference. """ try: funcstr = codegen.to_source(func) argstr = codegen.to_source(arg) except TypeError: self.log.debug(2, 'Failed to convert function and argument to source form') else: self.log.debug(1, self.unhandled_message % (funcstr, argstr)) def visit_Call(self, node): name = self.called_node_name(node.func) if name and (name.endswith(self.getvars) or name.endswith(self.getvarflags) or name in self.containsfuncs or name in self.containsanyfuncs): if isinstance(node.args[0], ast.Str): varname = node.args[0].s if name in self.containsfuncs and isinstance(node.args[1], ast.Str): if varname not in self.contains: self.contains[varname] = set() self.contains[varname].add(node.args[1].s) elif name in self.containsanyfuncs and isinstance(node.args[1], ast.Str): if varname not in self.contains: self.contains[varname] = set() self.contains[varname].update(node.args[1].s.split()) elif name.endswith(self.getvarflags): if isinstance(node.args[1], ast.Str): self.references.add('%s[%s]' % (varname, node.args[1].s)) else: self.warn(node.func, node.args[1]) else: self.references.add(varname) else: self.warn(node.func, node.args[0]) elif name and name.endswith(".expand"): if isinstance(node.args[0], ast.Str): value = node.args[0].s d = bb.data.init() parser = d.expandWithRefs(value, self.name) self.references |= parser.references self.execs |= parser.execs for varname in parser.contains: if varname not in self.contains: self.contains[varname] = set() self.contains[varname] |= parser.contains[varname] elif name in self.execfuncs: if isinstance(node.args[0], ast.Str): self.var_execs.add(node.args[0].s) else: self.warn(node.func, node.args[0]) elif name and isinstance(node.func, (ast.Name, ast.Attribute)): self.execs.add(name) def called_node_name(self, node): """Given a called node, return its original string form""" components = [] while node: if isinstance(node, ast.Attribute): components.append(node.attr) node = node.value elif isinstance(node, ast.Name): components.append(node.id) return '.'.join(reversed(components)) else: break def __init__(self, name, log): self.name = name self.var_execs = set() self.contains = {} self.execs = set() self.references = set() self.log = BufferedLogger('BitBake.Data.PythonParser', logging.DEBUG, log) self.unhandled_message = "in call of %s, argument '%s' is not a string literal" self.unhandled_message = "while parsing %s, %s" % (name, self.unhandled_message) def parse_python(self, node, lineno=0, filename=""): if not node or not node.strip(): return h = bbhash(str(node)) if h in codeparsercache.pythoncache: self.references = set(codeparsercache.pythoncache[h].refs) self.execs = set(codeparsercache.pythoncache[h].execs) self.contains = {} for i in codeparsercache.pythoncache[h].contains: self.contains[i] = set(codeparsercache.pythoncache[h].contains[i]) return if h in codeparsercache.pythoncacheextras: self.references = set(codeparsercache.pythoncacheextras[h].refs) self.execs = set(codeparsercache.pythoncacheextras[h].execs) self.contains = {} for i in codeparsercache.pythoncacheextras[h].contains: self.contains[i] = set(codeparsercache.pythoncacheextras[h].contains[i]) return # We can't add to the linenumbers for compile, we can pad to the correct number of blank lines though node = "\n" * int(lineno) + node code = compile(check_indent(str(node)), filename, "exec", ast.PyCF_ONLY_AST) for n in ast.walk(code): if n.__class__.__name__ == "Call": self.visit_Call(n) self.execs.update(self.var_execs) codeparsercache.pythoncacheextras[h] = codeparsercache.newPythonCacheLine(self.references, self.execs, self.contains) class ShellParser(): def __init__(self, name, log): self.funcdefs = set() self.allexecs = set() self.execs = set() self.log = BufferedLogger('BitBake.Data.%s' % name, logging.DEBUG, log) self.unhandled_template = "unable to handle non-literal command '%s'" self.unhandled_template = "while parsing %s, %s" % (name, self.unhandled_template) def parse_shell(self, value): """Parse the supplied shell code in a string, returning the external commands it executes. """ h = bbhash(str(value)) if h in codeparsercache.shellcache: self.execs = set(codeparsercache.shellcache[h].execs) return self.execs if h in codeparsercache.shellcacheextras: self.execs = set(codeparsercache.shellcacheextras[h].execs) return self.execs self._parse_shell(value) self.execs = set(cmd for cmd in self.allexecs if cmd not in self.funcdefs) codeparsercache.shellcacheextras[h] = codeparsercache.newShellCacheLine(self.execs) return self.execs def _parse_shell(self, value): try: tokens, _ = pyshyacc.parse(value, eof=True, debug=False) except pyshlex.NeedMore: raise sherrors.ShellSyntaxError("Unexpected EOF") self.process_tokens(tokens) def process_tokens(self, tokens): """Process a supplied portion of the syntax tree as returned by pyshyacc.parse. """ def function_definition(value): self.funcdefs.add(value.name) return [value.body], None def case_clause(value): # Element 0 of each item in the case is the list of patterns, and # Element 1 of each item in the case is the list of commands to be # executed when that pattern matches. words = chain(*[item[0] for item in value.items]) cmds = chain(*[item[1] for item in value.items]) return cmds, words def if_clause(value): main = chain(value.cond, value.if_cmds) rest = value.else_cmds if isinstance(rest, tuple) and rest[0] == "elif": return chain(main, if_clause(rest[1])) else: return chain(main, rest) def simple_command(value): return None, chain(value.words, (assign[1] for assign in value.assigns)) token_handlers = { "and_or": lambda x: ((x.left, x.right), None), "async": lambda x: ([x], None), "brace_group": lambda x: (x.cmds, None), "for_clause": lambda x: (x.cmds, x.items), "function_definition": function_definition, "if_clause": lambda x: (if_clause(x), None), "pipeline": lambda x: (x.commands, None), "redirect_list": lambda x: ([x.cmd], None), "subshell": lambda x: (x.cmds, None), "while_clause": lambda x: (chain(x.condition, x.cmds), None), "until_clause": lambda x: (chain(x.condition, x.cmds), None), "simple_command": simple_command, "case_clause": case_clause, } def process_token_list(tokens): for token in tokens: if isinstance(token, list): process_token_list(token) continue name, value = token try: more_tokens, words = token_handlers[name](value) except KeyError: raise NotImplementedError("Unsupported token type " + name) if more_tokens: self.process_tokens(more_tokens) if words: self.process_words(words) process_token_list(tokens) def process_words(self, words): """Process a set of 'words' in pyshyacc parlance, which includes extraction of executed commands from $() blocks, as well as grabbing the command name argument. """ words = list(words) for word in list(words): wtree = pyshlex.make_wordtree(word[1]) for part in wtree: if not isinstance(part, list): continue if part[0] in ('`', '$('): command = pyshlex.wordtree_as_string(part[1:-1]) self._parse_shell(command) if word[0] in ("cmd_name", "cmd_word"): if word in words: words.remove(word) usetoken = False for word in words: if word[0] in ("cmd_name", "cmd_word") or \ (usetoken and word[0] == "TOKEN"): if "=" in word[1]: usetoken = True continue cmd = word[1] if cmd.startswith("$"): self.log.debug(1, self.unhandled_template % cmd) elif cmd == "eval": command = " ".join(word for _, word in words[1:]) self._parse_shell(command) else: self.allexecs.add(cmd) break