from __future__ import annotations try: import _imp as imp except ImportError: import imp import importlib import sys try: # Only for this purpose, it's irrelevant if `os` was already patched. # https://github.com/eventlet/eventlet/pull/661 from os import register_at_fork except ImportError: register_at_fork = None import eventlet __all__ = ["inject", "import_patched", "monkey_patch", "is_monkey_patched"] __exclude = {"__builtins__", "__file__", "__name__"} class SysModulesSaver: """Class that captures some subset of the current state of sys.modules. Pass in an iterator of module names to the constructor.""" def __init__(self, module_names=()): self._saved = {} imp.acquire_lock() self.save(*module_names) def save(self, *module_names): """Saves the named modules to the object.""" for modname in module_names: self._saved[modname] = sys.modules.get(modname, None) def restore(self): """Restores the modules that the saver knows about into sys.modules. """ try: for modname, mod in self._saved.items(): if mod is not None: sys.modules[modname] = mod else: try: del sys.modules[modname] except KeyError: pass finally: imp.release_lock() def inject(module_name, new_globals, *additional_modules): """Base method for "injecting" greened modules into an imported module. It imports the module specified in *module_name*, arranging things so that the already-imported modules in *additional_modules* are used when *module_name* makes its imports. **Note:** This function does not create or change any sys.modules item, so if your greened module use code like 'sys.modules["your_module_name"]', you need to update sys.modules by yourself. *new_globals* is either None or a globals dictionary that gets populated with the contents of the *module_name* module. This is useful when creating a "green" version of some other module. *additional_modules* should be a collection of two-element tuples, of the form (, ). If it's not specified, a default selection of name/module pairs is used, which should cover all use cases but may be slower because there are inevitably redundant or unnecessary imports. """ patched_name = "__patched_module_" + module_name if patched_name in sys.modules: # returning already-patched module so as not to destroy existing # references to patched modules return sys.modules[patched_name] if not additional_modules: # supply some defaults additional_modules = ( _green_os_modules() + _green_select_modules() + _green_socket_modules() + _green_thread_modules() + _green_time_modules() ) # _green_MySQLdb()) # enable this after a short baking-in period # after this we are gonna screw with sys.modules, so capture the # state of all the modules we're going to mess with, and lock saver = SysModulesSaver([name for name, m in additional_modules]) saver.save(module_name) # Cover the target modules so that when you import the module it # sees only the patched versions for name, mod in additional_modules: sys.modules[name] = mod # Remove the old module from sys.modules and reimport it while # the specified modules are in place sys.modules.pop(module_name, None) # Also remove sub modules and reimport. Use copy the keys to list # because of the pop operations will change the content of sys.modules # within th loop for imported_module_name in list(sys.modules.keys()): if imported_module_name.startswith(module_name + "."): sys.modules.pop(imported_module_name, None) try: module = __import__(module_name, {}, {}, module_name.split(".")[:-1]) if new_globals is not None: # Update the given globals dictionary with everything from this new module for name in dir(module): if name not in __exclude: new_globals[name] = getattr(module, name) # Keep a reference to the new module to prevent it from dying sys.modules[patched_name] = module finally: saver.restore() # Put the original modules back return module def import_patched(module_name, *additional_modules, **kw_additional_modules): """Imports a module in a way that ensures that the module uses "green" versions of the standard library modules, so that everything works nonblockingly. The only required argument is the name of the module to be imported. """ return inject( module_name, None, *additional_modules + tuple(kw_additional_modules.items()) ) def patch_function(func, *additional_modules): """Decorator that returns a version of the function that patches some modules for the duration of the function call. This is deeply gross and should only be used for functions that import network libraries within their function bodies that there is no way of getting around.""" if not additional_modules: # supply some defaults additional_modules = ( _green_os_modules() + _green_select_modules() + _green_socket_modules() + _green_thread_modules() + _green_time_modules() ) def patched(*args, **kw): saver = SysModulesSaver() for name, mod in additional_modules: saver.save(name) sys.modules[name] = mod try: return func(*args, **kw) finally: saver.restore() return patched def _original_patch_function(func, *module_names): """Kind of the contrapositive of patch_function: decorates a function such that when it's called, sys.modules is populated only with the unpatched versions of the specified modules. Unlike patch_function, only the names of the modules need be supplied, and there are no defaults. This is a gross hack; tell your kids not to import inside function bodies!""" def patched(*args, **kw): saver = SysModulesSaver(module_names) for name in module_names: sys.modules[name] = original(name) try: return func(*args, **kw) finally: saver.restore() return patched def original(modname): """This returns an unpatched version of a module; this is useful for Eventlet itself (i.e. tpool).""" # note that it's not necessary to temporarily install unpatched # versions of all patchable modules during the import of the # module; this is because none of them import each other, except # for threading which imports thread original_name = "__original_module_" + modname if original_name in sys.modules: return sys.modules.get(original_name) # re-import the "pure" module and store it in the global _originals # dict; be sure to restore whatever module had that name already saver = SysModulesSaver((modname,)) sys.modules.pop(modname, None) # some rudimentary dependency checking -- fortunately the modules # we're working on don't have many dependencies so we can just do # some special-casing here deps = {"threading": "_thread", "queue": "threading"} if modname in deps: dependency = deps[modname] saver.save(dependency) sys.modules[dependency] = original(dependency) try: real_mod = __import__(modname, {}, {}, modname.split(".")[:-1]) if modname in ("Queue", "queue") and not hasattr(real_mod, "_threading"): # tricky hack: Queue's constructor in <2.7 imports # threading on every instantiation; therefore we wrap # it so that it always gets the original threading real_mod.Queue.__init__ = _original_patch_function( real_mod.Queue.__init__, "threading" ) # save a reference to the unpatched module so it doesn't get lost sys.modules[original_name] = real_mod finally: saver.restore() return sys.modules[original_name] already_patched = {} def _unmonkey_patch_asyncio(unmonkeypatch_refs_to_this_module): """ When using asyncio hub, we want the asyncio modules to use the original, blocking APIs. So un-monkeypatch references to the given module name, e.g. "select". """ to_unpatch = unmonkeypatch_refs_to_this_module original_module = original(to_unpatch) # Lower down for asyncio modules, we will switch their imported modules to # original ones instead of the green ones they probably have. This won't # fix "from socket import whatev" but asyncio doesn't seem to do that in # ways we care about for Python 3.8 to 3.13, with the one exception of # get_ident() in some older versions. if to_unpatch == "_thread": import asyncio.base_futures if hasattr(asyncio.base_futures, "get_ident"): asyncio.base_futures = original_module.get_ident # Asyncio uses these for its blocking thread pool: if to_unpatch in ("threading", "queue"): try: import concurrent.futures.thread except RuntimeError: # This happens in weird edge cases where asyncio hub is started at # shutdown. Not much we can do if this happens. pass else: if to_unpatch == "threading": concurrent.futures.thread.threading = original_module if to_unpatch == "queue": concurrent.futures.thread.queue = original_module # Patch asyncio modules: for module_name in [ "asyncio.base_events", "asyncio.base_futures", "asyncio.base_subprocess", "asyncio.base_tasks", "asyncio.constants", "asyncio.coroutines", "asyncio.events", "asyncio.exceptions", "asyncio.format_helpers", "asyncio.futures", "asyncio", "asyncio.locks", "asyncio.log", "asyncio.mixins", "asyncio.protocols", "asyncio.queues", "asyncio.runners", "asyncio.selector_events", "asyncio.sslproto", "asyncio.staggered", "asyncio.streams", "asyncio.subprocess", "asyncio.taskgroups", "asyncio.tasks", "asyncio.threads", "asyncio.timeouts", "asyncio.transports", "asyncio.trsock", "asyncio.unix_events", ]: try: module = importlib.import_module(module_name) except ImportError: # The list is from Python 3.13, so some modules may not be present # in older versions of Python: continue if getattr(module, to_unpatch, None) is sys.modules[to_unpatch]: setattr(module, to_unpatch, original_module) def _unmonkey_patch_asyncio_all(): """ Unmonkey-patch all referred-to modules in asyncio. """ for module_name, _ in sum([ _green_os_modules(), _green_select_modules(), _green_socket_modules(), _green_thread_modules(), _green_time_modules(), _green_builtins(), _green_subprocess_modules(), ], []): _unmonkey_patch_asyncio(module_name) original("selectors").select = original("select") def monkey_patch(**on): """Globally patches certain system modules to be greenthread-friendly. The keyword arguments afford some control over which modules are patched. If no keyword arguments are supplied, all possible modules are patched. If keywords are set to True, only the specified modules are patched. E.g., ``monkey_patch(socket=True, select=True)`` patches only the select and socket modules. Most arguments patch the single module of the same name (os, time, select). The exceptions are socket, which also patches the ssl module if present; and thread, which patches thread, threading, and Queue. It's safe to call monkey_patch multiple times. """ # Workaround for import cycle observed as following in monotonic # RuntimeError: no suitable implementation for this system # see https://github.com/eventlet/eventlet/issues/401#issuecomment-325015989 # # Make sure the hub is completely imported before any # monkey-patching, or we risk recursion if the process of importing # the hub calls into monkey-patched modules. eventlet.hubs.get_hub() accepted_args = { "os", "select", "socket", "thread", "time", "psycopg", "MySQLdb", "builtins", "subprocess", } # To make sure only one of them is passed here assert not ("__builtin__" in on and "builtins" in on) try: b = on.pop("__builtin__") except KeyError: pass else: on["builtins"] = b default_on = on.pop("all", None) for k in on.keys(): if k not in accepted_args: raise TypeError( "monkey_patch() got an unexpected " "keyword argument %r" % k ) if default_on is None: default_on = True not in on.values() for modname in accepted_args: if modname == "MySQLdb": # MySQLdb is only on when explicitly patched for the moment on.setdefault(modname, False) if modname == "builtins": on.setdefault(modname, False) on.setdefault(modname, default_on) import threading original_rlock_type = type(threading.RLock()) modules_to_patch = [] for name, modules_function in [ ("os", _green_os_modules), ("select", _green_select_modules), ("socket", _green_socket_modules), ("thread", _green_thread_modules), ("time", _green_time_modules), ("MySQLdb", _green_MySQLdb), ("builtins", _green_builtins), ("subprocess", _green_subprocess_modules), ]: if on[name] and not already_patched.get(name): modules_to_patch += modules_function() already_patched[name] = True if on["psycopg"] and not already_patched.get("psycopg"): try: from eventlet.support import psycopg2_patcher psycopg2_patcher.make_psycopg_green() already_patched["psycopg"] = True except ImportError: # note that if we get an importerror from trying to # monkeypatch psycopg, we will continually retry it # whenever monkey_patch is called; this should not be a # performance problem but it allows is_monkey_patched to # tell us whether or not we succeeded pass _threading = original("threading") imp.acquire_lock() try: for name, mod in modules_to_patch: orig_mod = sys.modules.get(name) if orig_mod is None: orig_mod = __import__(name) for attr_name in mod.__patched__: patched_attr = getattr(mod, attr_name, None) if patched_attr is not None: setattr(orig_mod, attr_name, patched_attr) deleted = getattr(mod, "__deleted__", []) for attr_name in deleted: if hasattr(orig_mod, attr_name): delattr(orig_mod, attr_name) if name == "threading" and register_at_fork: # The whole post-fork processing in stdlib threading.py, # implemented in threading._after_fork(), is based on the # assumption that threads don't survive fork(). However, green # threads do survive fork, and that's what threading.py is # tracking when using eventlet, so there's no need to do any # post-fork cleanup in this case. # # So, we wipe out _after_fork()'s code so it does nothing. We # can't just override it because it has already been registered # with os.register_after_fork(). def noop(): pass orig_mod._after_fork.__code__ = noop.__code__ inject("threading", {})._after_fork.__code__ = noop.__code__ finally: imp.release_lock() import importlib._bootstrap thread = original("_thread") # importlib must use real thread locks, not eventlet.Semaphore importlib._bootstrap._thread = thread # Issue #185: Since Python 3.3, threading.RLock is implemented in C and # so call a C function to get the thread identifier, instead of calling # threading.get_ident(). Force the Python implementation of RLock which # calls threading.get_ident() and so is compatible with eventlet. import threading threading.RLock = threading._PyRLock # Issue #508: Since Python 3.7 queue.SimpleQueue is implemented in C, # causing a deadlock. Replace the C implementation with the Python one. import queue queue.SimpleQueue = queue._PySimpleQueue # Green existing locks _after_ patching modules, since patching modules # might involve imports that create new locks: for name, _ in modules_to_patch: if name == "threading": _green_existing_locks(original_rlock_type) def is_monkey_patched(module): """Returns True if the given module is monkeypatched currently, False if not. *module* can be either the module itself or its name. Based entirely off the name of the module, so if you import a module some other way than with the import keyword (including import_patched), this might not be correct about that particular module.""" return ( module in already_patched or getattr(module, "__name__", None) in already_patched ) def _green_existing_locks(rlock_type): """Make locks created before monkey-patching safe. RLocks rely on a Lock and on Python 2, if an unpatched Lock blocks, it blocks the native thread. We need to replace these with green Locks. This was originally noticed in the stdlib logging module.""" import gc import os import eventlet.green.thread # We're monkey-patching so there can't be any greenlets yet, ergo our thread # ID is the only valid owner possible. tid = eventlet.green.thread.get_ident() # Now, upgrade all instances: def upgrade(old_lock): return _convert_py3_rlock(old_lock, tid) _upgrade_instances(sys.modules, rlock_type, upgrade) # Report if there are RLocks we couldn't upgrade. For cases where we're # using coverage.py in parent process, and more generally for tests in # general, this is difficult to ensure, so just don't complain in that case. if "PYTEST_CURRENT_TEST" in os.environ: return # On older Pythons (< 3.10), gc.get_objects() won't return any RLock # instances, so this warning won't get logged on older Pythons. However, # it's a useful warning, so we try to do it anyway for the benefit of those # users on 3.10 or later. gc.collect() remaining_rlocks = 0 for o in gc.get_objects(): try: if isinstance(o, rlock_type): remaining_rlocks += 1 except ReferenceError as exc: import logging import traceback logger = logging.Logger("eventlet") logger.error( "Not increase rlock count, an exception of type " + type(exc).__name__ + "occurred with the message '" + str(exc) + "'. Traceback details: " + traceback.format_exc() ) if remaining_rlocks: try: import _frozen_importlib except ImportError: pass else: for o in gc.get_objects(): # This can happen in Python 3.12, at least, if monkey patch # happened as side-effect of importing a module. try: if not isinstance(o, rlock_type): continue except ReferenceError as exc: import logging import traceback logger = logging.Logger("eventlet") logger.error( "No decrease rlock count, an exception of type " + type(exc).__name__ + "occurred with the message '" + str(exc) + "'. Traceback details: " + traceback.format_exc() ) continue # if ReferenceError, skip this object and continue with the next one. if _frozen_importlib._ModuleLock in map(type, gc.get_referrers(o)): remaining_rlocks -= 1 del o if remaining_rlocks: import logging logger = logging.Logger("eventlet") logger.error( "{} RLock(s) were not greened,".format(remaining_rlocks) + " to fix this error make sure you run eventlet.monkey_patch() " + "before importing any other modules." ) def _upgrade_instances(container, klass, upgrade, visited=None, old_to_new=None): """ Starting with a Python object, find all instances of ``klass``, following references in ``dict`` values, ``list`` items, and attributes. Once an object is found, replace all instances with ``upgrade(found_object)``, again limited to the criteria above. In practice this is used only for ``threading.RLock``, so we can assume instances are hashable. """ if visited is None: visited = {} # map id(obj) to obj if old_to_new is None: old_to_new = {} # map old klass instance to upgrade(old) # Handle circular references: visited[id(container)] = container def upgrade_or_traverse(obj): if id(obj) in visited: return None if isinstance(obj, klass): if obj in old_to_new: return old_to_new[obj] else: new = upgrade(obj) old_to_new[obj] = new return new else: _upgrade_instances(obj, klass, upgrade, visited, old_to_new) return None if isinstance(container, dict): for k, v in list(container.items()): new = upgrade_or_traverse(v) if new is not None: container[k] = new if isinstance(container, list): for i, v in enumerate(container): new = upgrade_or_traverse(v) if new is not None: container[i] = new try: container_vars = vars(container) except TypeError: pass else: # If we get here, we're operating on an object that could # be doing strange things. If anything bad happens, error and # warn the eventlet user to monkey_patch earlier. try: for k, v in list(container_vars.items()): new = upgrade_or_traverse(v) if new is not None: setattr(container, k, new) except: import logging logger = logging.Logger("eventlet") logger.exception( "An exception was thrown while monkey_patching for eventlet. " "to fix this error make sure you run eventlet.monkey_patch() " "before importing any other modules.", exc_info=True, ) def _convert_py3_rlock(old, tid): """ Convert a normal RLock to one implemented in Python. This is necessary to make RLocks work with eventlet, but also introduces bugs, e.g. https://bugs.python.org/issue13697. So more of a downgrade, really. """ import threading from eventlet.green.thread import allocate_lock new = threading._PyRLock() if not hasattr(new, "_block") or not hasattr(new, "_owner"): # These will only fail if Python changes its internal implementation of # _PyRLock: raise RuntimeError( "INTERNAL BUG. Perhaps you are using a major version " + "of Python that is unsupported by eventlet? Please file a bug " + "at https://github.com/eventlet/eventlet/issues/new" ) new._block = allocate_lock() acquired = False while old._is_owned(): old.release() new.acquire() acquired = True if old._is_owned(): new.acquire() acquired = True if acquired: new._owner = tid return new def _green_os_modules(): from eventlet.green import os return [("os", os)] def _green_select_modules(): from eventlet.green import select modules = [("select", select)] from eventlet.green import selectors modules.append(("selectors", selectors)) return modules def _green_socket_modules(): from eventlet.green import socket try: from eventlet.green import ssl return [("socket", socket), ("ssl", ssl)] except ImportError: return [("socket", socket)] def _green_subprocess_modules(): from eventlet.green import subprocess return [("subprocess", subprocess)] def _green_thread_modules(): from eventlet.green import Queue from eventlet.green import thread from eventlet.green import threading return [("queue", Queue), ("_thread", thread), ("threading", threading)] def _green_time_modules(): from eventlet.green import time return [("time", time)] def _green_MySQLdb(): try: from eventlet.green import MySQLdb return [("MySQLdb", MySQLdb)] except ImportError: return [] def _green_builtins(): try: from eventlet.green import builtin return [("builtins", builtin)] except ImportError: return [] def slurp_properties(source, destination, ignore=[], srckeys=None): """Copy properties from *source* (assumed to be a module) to *destination* (assumed to be a dict). *ignore* lists properties that should not be thusly copied. *srckeys* is a list of keys to copy, if the source's __all__ is untrustworthy. """ if srckeys is None: srckeys = source.__all__ destination.update( { name: getattr(source, name) for name in srckeys if not (name.startswith("__") or name in ignore) } ) if __name__ == "__main__": sys.argv.pop(0) monkey_patch() with open(sys.argv[0]) as f: code = compile(f.read(), sys.argv[0], "exec") exec(code)