/* Python interpreter top-level routines, including init/exit */ #include "Python.h" #include "Python-ast.h" #undef Yield /* undefine macro conflicting with */ #include "pycore_ceval.h" #include "pycore_context.h" #include "pycore_coreconfig.h" #include "pycore_fileutils.h" #include "pycore_hamt.h" #include "pycore_pathconfig.h" #include "pycore_pylifecycle.h" #include "pycore_pymem.h" #include "pycore_pystate.h" #include "grammar.h" #include "node.h" #include "token.h" #include "parsetok.h" #include "errcode.h" #include "code.h" #include "symtable.h" #include "ast.h" #include "marshal.h" #include "osdefs.h" #include #ifdef HAVE_SIGNAL_H #include #endif #ifdef MS_WINDOWS #include "malloc.h" /* for alloca */ #endif #ifdef HAVE_LANGINFO_H #include #endif #ifdef MS_WINDOWS #undef BYTE #include "windows.h" extern PyTypeObject PyWindowsConsoleIO_Type; #define PyWindowsConsoleIO_Check(op) (PyObject_TypeCheck((op), &PyWindowsConsoleIO_Type)) #endif _Py_IDENTIFIER(flush); _Py_IDENTIFIER(name); _Py_IDENTIFIER(stdin); _Py_IDENTIFIER(stdout); _Py_IDENTIFIER(stderr); _Py_IDENTIFIER(threading); #ifdef __cplusplus extern "C" { #endif extern grammar _PyParser_Grammar; /* From graminit.c */ /* Forward */ static _PyInitError add_main_module(PyInterpreterState *interp); static _PyInitError init_import_size(void); static _PyInitError init_sys_streams(PyInterpreterState *interp); static _PyInitError init_signals(void); static void call_py_exitfuncs(PyInterpreterState *); static void wait_for_thread_shutdown(void); static void call_ll_exitfuncs(_PyRuntimeState *runtime); int _Py_UnhandledKeyboardInterrupt = 0; _PyRuntimeState _PyRuntime = _PyRuntimeState_INIT; static int runtime_initialized = 0; _PyInitError _PyRuntime_Initialize(void) { /* XXX We only initialize once in the process, which aligns with the static initialization of the former globals now found in _PyRuntime. However, _PyRuntime *should* be initialized with every Py_Initialize() call, but doing so breaks the runtime. This is because the runtime state is not properly finalized currently. */ if (runtime_initialized) { return _Py_INIT_OK(); } runtime_initialized = 1; return _PyRuntimeState_Init(&_PyRuntime); } void _PyRuntime_Finalize(void) { _PyRuntimeState_Fini(&_PyRuntime); runtime_initialized = 0; } int _Py_IsFinalizing(void) { return _PyRuntime.finalizing != NULL; } /* Hack to force loading of object files */ int (*_PyOS_mystrnicmp_hack)(const char *, const char *, Py_ssize_t) = \ PyOS_mystrnicmp; /* Python/pystrcmp.o */ /* PyModule_GetWarningsModule is no longer necessary as of 2.6 since _warnings is builtin. This API should not be used. */ PyObject * PyModule_GetWarningsModule(void) { return PyImport_ImportModule("warnings"); } /* APIs to access the initialization flags * * Can be called prior to Py_Initialize. */ int _Py_IsCoreInitialized(void) { return _PyRuntime.core_initialized; } int Py_IsInitialized(void) { return _PyRuntime.initialized; } /* Global initializations. Can be undone by Py_FinalizeEx(). Don't call this twice without an intervening Py_FinalizeEx() call. When initializations fail, a fatal error is issued and the function does not return. On return, the first thread and interpreter state have been created. Locking: you must hold the interpreter lock while calling this. (If the lock has not yet been initialized, that's equivalent to having the lock, but you cannot use multiple threads.) */ static _PyInitError init_importlib(PyInterpreterState *interp, PyObject *sysmod) { PyObject *importlib; PyObject *impmod; PyObject *value; int verbose = interp->core_config.verbose; /* Import _importlib through its frozen version, _frozen_importlib. */ if (PyImport_ImportFrozenModule("_frozen_importlib") <= 0) { return _Py_INIT_ERR("can't import _frozen_importlib"); } else if (verbose) { PySys_FormatStderr("import _frozen_importlib # frozen\n"); } importlib = PyImport_AddModule("_frozen_importlib"); if (importlib == NULL) { return _Py_INIT_ERR("couldn't get _frozen_importlib from sys.modules"); } interp->importlib = importlib; Py_INCREF(interp->importlib); interp->import_func = PyDict_GetItemString(interp->builtins, "__import__"); if (interp->import_func == NULL) return _Py_INIT_ERR("__import__ not found"); Py_INCREF(interp->import_func); /* Import the _imp module */ impmod = PyInit__imp(); if (impmod == NULL) { return _Py_INIT_ERR("can't import _imp"); } else if (verbose) { PySys_FormatStderr("import _imp # builtin\n"); } if (_PyImport_SetModuleString("_imp", impmod) < 0) { return _Py_INIT_ERR("can't save _imp to sys.modules"); } /* Install importlib as the implementation of import */ value = PyObject_CallMethod(importlib, "_install", "OO", sysmod, impmod); if (value == NULL) { PyErr_Print(); return _Py_INIT_ERR("importlib install failed"); } Py_DECREF(value); Py_DECREF(impmod); return _Py_INIT_OK(); } static _PyInitError init_importlib_external(PyInterpreterState *interp) { PyObject *value; value = PyObject_CallMethod(interp->importlib, "_install_external_importers", ""); if (value == NULL) { PyErr_Print(); return _Py_INIT_ERR("external importer setup failed"); } Py_DECREF(value); return _PyImportZip_Init(interp); } /* Helper functions to better handle the legacy C locale * * The legacy C locale assumes ASCII as the default text encoding, which * causes problems not only for the CPython runtime, but also other * components like GNU readline. * * Accordingly, when the CLI detects it, it attempts to coerce it to a * more capable UTF-8 based alternative as follows: * * if (_Py_LegacyLocaleDetected()) { * _Py_CoerceLegacyLocale(); * } * * See the documentation of the PYTHONCOERCECLOCALE setting for more details. * * Locale coercion also impacts the default error handler for the standard * streams: while the usual default is "strict", the default for the legacy * C locale and for any of the coercion target locales is "surrogateescape". */ int _Py_LegacyLocaleDetected(void) { #ifndef MS_WINDOWS /* On non-Windows systems, the C locale is considered a legacy locale */ /* XXX (ncoghlan): some platforms (notably Mac OS X) don't appear to treat * the POSIX locale as a simple alias for the C locale, so * we may also want to check for that explicitly. */ const char *ctype_loc = setlocale(LC_CTYPE, NULL); return ctype_loc != NULL && strcmp(ctype_loc, "C") == 0; #else /* Windows uses code pages instead of locales, so no locale is legacy */ return 0; #endif } static const char *_C_LOCALE_WARNING = "Python runtime initialized with LC_CTYPE=C (a locale with default ASCII " "encoding), which may cause Unicode compatibility problems. Using C.UTF-8, " "C.utf8, or UTF-8 (if available) as alternative Unicode-compatible " "locales is recommended.\n"; static void emit_stderr_warning_for_legacy_locale(_PyRuntimeState *runtime) { const _PyPreConfig *preconfig = &runtime->preconfig; if (preconfig->coerce_c_locale_warn && _Py_LegacyLocaleDetected()) { PySys_FormatStderr("%s", _C_LOCALE_WARNING); } } typedef struct _CandidateLocale { const char *locale_name; /* The locale to try as a coercion target */ } _LocaleCoercionTarget; static _LocaleCoercionTarget _TARGET_LOCALES[] = { {"C.UTF-8"}, {"C.utf8"}, {"UTF-8"}, {NULL} }; int _Py_IsLocaleCoercionTarget(const char *ctype_loc) { const _LocaleCoercionTarget *target = NULL; for (target = _TARGET_LOCALES; target->locale_name; target++) { if (strcmp(ctype_loc, target->locale_name) == 0) { return 1; } } return 0; } #ifdef PY_COERCE_C_LOCALE static const char C_LOCALE_COERCION_WARNING[] = "Python detected LC_CTYPE=C: LC_CTYPE coerced to %.20s (set another locale " "or PYTHONCOERCECLOCALE=0 to disable this locale coercion behavior).\n"; static void _coerce_default_locale_settings(int warn, const _LocaleCoercionTarget *target) { const char *newloc = target->locale_name; /* Reset locale back to currently configured defaults */ _Py_SetLocaleFromEnv(LC_ALL); /* Set the relevant locale environment variable */ if (setenv("LC_CTYPE", newloc, 1)) { fprintf(stderr, "Error setting LC_CTYPE, skipping C locale coercion\n"); return; } if (warn) { fprintf(stderr, C_LOCALE_COERCION_WARNING, newloc); } /* Reconfigure with the overridden environment variables */ _Py_SetLocaleFromEnv(LC_ALL); } #endif void _Py_CoerceLegacyLocale(int warn) { #ifdef PY_COERCE_C_LOCALE char *oldloc = NULL; oldloc = _PyMem_RawStrdup(setlocale(LC_CTYPE, NULL)); if (oldloc == NULL) { return; } const char *locale_override = getenv("LC_ALL"); if (locale_override == NULL || *locale_override == '\0') { /* LC_ALL is also not set (or is set to an empty string) */ const _LocaleCoercionTarget *target = NULL; for (target = _TARGET_LOCALES; target->locale_name; target++) { const char *new_locale = setlocale(LC_CTYPE, target->locale_name); if (new_locale != NULL) { #if !defined(_Py_FORCE_UTF8_LOCALE) && defined(HAVE_LANGINFO_H) && defined(CODESET) /* Also ensure that nl_langinfo works in this locale */ char *codeset = nl_langinfo(CODESET); if (!codeset || *codeset == '\0') { /* CODESET is not set or empty, so skip coercion */ new_locale = NULL; _Py_SetLocaleFromEnv(LC_CTYPE); continue; } #endif /* Successfully configured locale, so make it the default */ _coerce_default_locale_settings(warn, target); goto done; } } } /* No C locale warning here, as Py_Initialize will emit one later */ setlocale(LC_CTYPE, oldloc); done: PyMem_RawFree(oldloc); #endif } /* _Py_SetLocaleFromEnv() is a wrapper around setlocale(category, "") to * isolate the idiosyncrasies of different libc implementations. It reads the * appropriate environment variable and uses its value to select the locale for * 'category'. */ char * _Py_SetLocaleFromEnv(int category) { char *res; #ifdef __ANDROID__ const char *locale; const char **pvar; #ifdef PY_COERCE_C_LOCALE const char *coerce_c_locale; #endif const char *utf8_locale = "C.UTF-8"; const char *env_var_set[] = { "LC_ALL", "LC_CTYPE", "LANG", NULL, }; /* Android setlocale(category, "") doesn't check the environment variables * and incorrectly sets the "C" locale at API 24 and older APIs. We only * check the environment variables listed in env_var_set. */ for (pvar=env_var_set; *pvar; pvar++) { locale = getenv(*pvar); if (locale != NULL && *locale != '\0') { if (strcmp(locale, utf8_locale) == 0 || strcmp(locale, "en_US.UTF-8") == 0) { return setlocale(category, utf8_locale); } return setlocale(category, "C"); } } /* Android uses UTF-8, so explicitly set the locale to C.UTF-8 if none of * LC_ALL, LC_CTYPE, or LANG is set to a non-empty string. * Quote from POSIX section "8.2 Internationalization Variables": * "4. If the LANG environment variable is not set or is set to the empty * string, the implementation-defined default locale shall be used." */ #ifdef PY_COERCE_C_LOCALE coerce_c_locale = getenv("PYTHONCOERCECLOCALE"); if (coerce_c_locale == NULL || strcmp(coerce_c_locale, "0") != 0) { /* Some other ported code may check the environment variables (e.g. in * extension modules), so we make sure that they match the locale * configuration */ if (setenv("LC_CTYPE", utf8_locale, 1)) { fprintf(stderr, "Warning: failed setting the LC_CTYPE " "environment variable to %s\n", utf8_locale); } } #endif res = setlocale(category, utf8_locale); #else /* !defined(__ANDROID__) */ res = setlocale(category, ""); #endif _Py_ResetForceASCII(); return res; } /* Global initializations. Can be undone by Py_Finalize(). Don't call this twice without an intervening Py_Finalize() call. Every call to _Py_InitializeFromConfig, Py_Initialize or Py_InitializeEx must have a corresponding call to Py_Finalize. Locking: you must hold the interpreter lock while calling these APIs. (If the lock has not yet been initialized, that's equivalent to having the lock, but you cannot use multiple threads.) */ static _PyInitError _Py_Initialize_ReconfigureCore(_PyRuntimeState *runtime, PyInterpreterState **interp_p, const _PyCoreConfig *core_config) { _PyInitError err; PyThreadState *tstate = _PyThreadState_GET(); if (!tstate) { return _Py_INIT_ERR("failed to read thread state"); } PyInterpreterState *interp = tstate->interp; if (interp == NULL) { return _Py_INIT_ERR("can't make main interpreter"); } *interp_p = interp; _PyCoreConfig_Write(core_config, runtime); err = _PyCoreConfig_Copy(&interp->core_config, core_config); if (_Py_INIT_FAILED(err)) { return err; } core_config = &interp->core_config; if (core_config->_install_importlib) { err = _PyCoreConfig_SetPathConfig(core_config); if (_Py_INIT_FAILED(err)) { return err; } } return _Py_INIT_OK(); } static _PyInitError pycore_init_runtime(_PyRuntimeState *runtime, const _PyCoreConfig *core_config) { if (runtime->initialized) { return _Py_INIT_ERR("main interpreter already initialized"); } _PyCoreConfig_Write(core_config, runtime); /* Py_Finalize leaves _Py_Finalizing set in order to help daemon * threads behave a little more gracefully at interpreter shutdown. * We clobber it here so the new interpreter can start with a clean * slate. * * However, this may still lead to misbehaviour if there are daemon * threads still hanging around from a previous Py_Initialize/Finalize * pair :( */ runtime->finalizing = NULL; _PyInitError err = _Py_HashRandomization_Init(core_config); if (_Py_INIT_FAILED(err)) { return err; } err = _PyInterpreterState_Enable(runtime); if (_Py_INIT_FAILED(err)) { return err; } return _Py_INIT_OK(); } static _PyInitError pycore_create_interpreter(_PyRuntimeState *runtime, const _PyCoreConfig *core_config, PyInterpreterState **interp_p) { PyInterpreterState *interp = PyInterpreterState_New(); if (interp == NULL) { return _Py_INIT_ERR("can't make main interpreter"); } *interp_p = interp; _PyInitError err = _PyCoreConfig_Copy(&interp->core_config, core_config); if (_Py_INIT_FAILED(err)) { return err; } core_config = &interp->core_config; PyThreadState *tstate = PyThreadState_New(interp); if (tstate == NULL) return _Py_INIT_ERR("can't make first thread"); (void) PyThreadState_Swap(tstate); /* We can't call _PyEval_FiniThreads() in Py_FinalizeEx because destroying the GIL might fail when it is being referenced from another running thread (see issue #9901). Instead we destroy the previously created GIL here, which ensures that we can call Py_Initialize / Py_FinalizeEx multiple times. */ _PyEval_FiniThreads(&runtime->ceval); /* Auto-thread-state API */ _PyGILState_Init(runtime, interp, tstate); /* Create the GIL */ PyEval_InitThreads(); return _Py_INIT_OK(); } static _PyInitError pycore_init_types(void) { _PyInitError err = _PyTypes_Init(); if (_Py_INIT_FAILED(err)) { return err; } err = _PyUnicode_Init(); if (_Py_INIT_FAILED(err)) { return err; } if (_PyStructSequence_Init() < 0) { return _Py_INIT_ERR("can't initialize structseq"); } if (!_PyLong_Init()) { return _Py_INIT_ERR("can't init longs"); } err = _PyExc_Init(); if (_Py_INIT_FAILED(err)) { return err; } if (!_PyFloat_Init()) { return _Py_INIT_ERR("can't init float"); } if (!_PyContext_Init()) { return _Py_INIT_ERR("can't init context"); } return _Py_INIT_OK(); } static _PyInitError pycore_init_builtins(PyInterpreterState *interp) { PyObject *bimod = _PyBuiltin_Init(); if (bimod == NULL) { return _Py_INIT_ERR("can't initialize builtins modules"); } _PyImport_FixupBuiltin(bimod, "builtins", interp->modules); interp->builtins = PyModule_GetDict(bimod); if (interp->builtins == NULL) { return _Py_INIT_ERR("can't initialize builtins dict"); } Py_INCREF(interp->builtins); _PyInitError err = _PyBuiltins_AddExceptions(bimod); if (_Py_INIT_FAILED(err)) { return err; } return _Py_INIT_OK(); } static _PyInitError pycore_init_import_warnings(PyInterpreterState *interp, PyObject *sysmod) { _PyInitError err = _PyImport_Init(interp); if (_Py_INIT_FAILED(err)) { return err; } err = _PyImportHooks_Init(); if (_Py_INIT_FAILED(err)) { return err; } /* Initialize _warnings. */ if (_PyWarnings_Init() == NULL) { return _Py_INIT_ERR("can't initialize warnings"); } if (interp->core_config._install_importlib) { err = _PyCoreConfig_SetPathConfig(&interp->core_config); if (_Py_INIT_FAILED(err)) { return err; } } /* This call sets up builtin and frozen import support */ if (interp->core_config._install_importlib) { err = init_importlib(interp, sysmod); if (_Py_INIT_FAILED(err)) { return err; } } return _Py_INIT_OK(); } static _PyInitError _Py_InitializeCore_impl(_PyRuntimeState *runtime, PyInterpreterState **interp_p, const _PyCoreConfig *core_config) { PyInterpreterState *interp; _PyCoreConfig_Write(core_config, runtime); _PyInitError err = pycore_init_runtime(runtime, core_config); if (_Py_INIT_FAILED(err)) { return err; } err = pycore_create_interpreter(runtime, core_config, &interp); if (_Py_INIT_FAILED(err)) { return err; } core_config = &interp->core_config; *interp_p = interp; err = pycore_init_types(); if (_Py_INIT_FAILED(err)) { return err; } PyObject *sysmod; err = _PySys_Create(runtime, interp, &sysmod); if (_Py_INIT_FAILED(err)) { return err; } err = pycore_init_builtins(interp); if (_Py_INIT_FAILED(err)) { return err; } err = pycore_init_import_warnings(interp, sysmod); if (_Py_INIT_FAILED(err)) { return err; } /* Only when we get here is the runtime core fully initialized */ runtime->core_initialized = 1; return _Py_INIT_OK(); } _PyInitError _Py_PreInitializeFromPyArgv(const _PyPreConfig *src_config, const _PyArgv *args) { _PyInitError err; err = _PyRuntime_Initialize(); if (_Py_INIT_FAILED(err)) { return err; } _PyRuntimeState *runtime = &_PyRuntime; if (runtime->pre_initialized) { /* If it's already configured: ignored the new configuration */ return _Py_INIT_OK(); } _PyPreConfig config = _PyPreConfig_INIT; if (src_config) { if (_PyPreConfig_Copy(&config, src_config) < 0) { err = _Py_INIT_NO_MEMORY(); goto done; } } err = _PyPreConfig_Read(&config, args); if (_Py_INIT_FAILED(err)) { goto done; } err = _PyPreConfig_Write(&config); if (_Py_INIT_FAILED(err)) { goto done; } runtime->pre_initialized = 1; err = _Py_INIT_OK(); done: _PyPreConfig_Clear(&config); return err; } _PyInitError _Py_PreInitializeFromArgs(const _PyPreConfig *src_config, int argc, char **argv) { _PyArgv args = {.use_bytes_argv = 1, .argc = argc, .bytes_argv = argv}; return _Py_PreInitializeFromPyArgv(src_config, &args); } _PyInitError _Py_PreInitializeFromWideArgs(const _PyPreConfig *src_config, int argc, wchar_t **argv) { _PyArgv args = {.use_bytes_argv = 0, .argc = argc, .wchar_argv = argv}; return _Py_PreInitializeFromPyArgv(src_config, &args); } _PyInitError _Py_PreInitialize(const _PyPreConfig *src_config) { return _Py_PreInitializeFromPyArgv(src_config, NULL); } _PyInitError _Py_PreInitializeFromCoreConfig(const _PyCoreConfig *coreconfig, const _PyArgv *args) { _PyPreConfig config = _PyPreConfig_INIT; if (coreconfig != NULL) { _PyCoreConfig_GetCoreConfig(&config, coreconfig); } return _Py_PreInitializeFromPyArgv(&config, args); /* No need to clear config: _PyCoreConfig_GetCoreConfig() doesn't allocate memory */ } static _PyInitError pyinit_coreconfig(_PyRuntimeState *runtime, _PyCoreConfig *config, const _PyCoreConfig *src_config, const _PyArgv *args, PyInterpreterState **interp_p) { _PyInitError err; if (src_config) { err = _PyCoreConfig_Copy(config, src_config); if (_Py_INIT_FAILED(err)) { return err; } } if (args) { err = _PyCoreConfig_SetPyArgv(config, args); if (_Py_INIT_FAILED(err)) { return err; } } err = _PyCoreConfig_Read(config); if (_Py_INIT_FAILED(err)) { return err; } if (!runtime->core_initialized) { return _Py_InitializeCore_impl(runtime, interp_p, config); } else { return _Py_Initialize_ReconfigureCore(runtime, interp_p, config); } } /* Begin interpreter initialization * * On return, the first thread and interpreter state have been created, * but the compiler, signal handling, multithreading and * multiple interpreter support, and codec infrastructure are not yet * available. * * The import system will support builtin and frozen modules only. * The only supported io is writing to sys.stderr * * If any operation invoked by this function fails, a fatal error is * issued and the function does not return. * * Any code invoked from this function should *not* assume it has access * to the Python C API (unless the API is explicitly listed as being * safe to call without calling Py_Initialize first) */ static _PyInitError _Py_InitializeCore(_PyRuntimeState *runtime, const _PyCoreConfig *src_config, const _PyArgv *args, PyInterpreterState **interp_p) { _PyInitError err; err = _Py_PreInitializeFromCoreConfig(src_config, args); if (_Py_INIT_FAILED(err)) { return err; } _PyCoreConfig local_config = _PyCoreConfig_INIT; err = pyinit_coreconfig(runtime, &local_config, src_config, args, interp_p); _PyCoreConfig_Clear(&local_config); return err; } /* Py_Initialize() has already been called: update the main interpreter configuration. Example of bpo-34008: Py_Main() called after Py_Initialize(). */ static _PyInitError _Py_ReconfigureMainInterpreter(PyInterpreterState *interp) { _PyCoreConfig *core_config = &interp->core_config; PyObject *argv = _PyWstrList_AsList(&core_config->argv); if (argv == NULL) { return _Py_INIT_NO_MEMORY(); \ } int res = PyDict_SetItemString(interp->sysdict, "argv", argv); Py_DECREF(argv); if (res < 0) { return _Py_INIT_ERR("fail to set sys.argv"); } return _Py_INIT_OK(); } /* Update interpreter state based on supplied configuration settings * * After calling this function, most of the restrictions on the interpreter * are lifted. The only remaining incomplete settings are those related * to the main module (sys.argv[0], __main__ metadata) * * Calling this when the interpreter is not initializing, is already * initialized or without a valid current thread state is a fatal error. * Other errors should be reported as normal Python exceptions with a * non-zero return code. */ static _PyInitError _Py_InitializeMainInterpreter(_PyRuntimeState *runtime, PyInterpreterState *interp) { if (!runtime->core_initialized) { return _Py_INIT_ERR("runtime core not initialized"); } /* Configure the main interpreter */ _PyCoreConfig *core_config = &interp->core_config; if (runtime->initialized) { return _Py_ReconfigureMainInterpreter(interp); } if (!core_config->_install_importlib) { /* Special mode for freeze_importlib: run with no import system * * This means anything which needs support from extension modules * or pure Python code in the standard library won't work. */ runtime->initialized = 1; return _Py_INIT_OK(); } if (_PyTime_Init() < 0) { return _Py_INIT_ERR("can't initialize time"); } if (_PySys_InitMain(runtime, interp) < 0) { return _Py_INIT_ERR("can't finish initializing sys"); } _PyInitError err = init_importlib_external(interp); if (_Py_INIT_FAILED(err)) { return err; } /* initialize the faulthandler module */ err = _PyFaulthandler_Init(core_config->faulthandler); if (_Py_INIT_FAILED(err)) { return err; } err = _PyUnicode_InitEncodings(interp); if (_Py_INIT_FAILED(err)) { return err; } if (core_config->install_signal_handlers) { err = init_signals(); if (_Py_INIT_FAILED(err)) { return err; } } if (_PyTraceMalloc_Init(core_config->tracemalloc) < 0) { return _Py_INIT_ERR("can't initialize tracemalloc"); } err = add_main_module(interp); if (_Py_INIT_FAILED(err)) { return err; } err = init_sys_streams(interp); if (_Py_INIT_FAILED(err)) { return err; } /* Initialize warnings. */ PyObject *warnoptions = PySys_GetObject("warnoptions"); if (warnoptions != NULL && PyList_Size(warnoptions) > 0) { PyObject *warnings_module = PyImport_ImportModule("warnings"); if (warnings_module == NULL) { fprintf(stderr, "'import warnings' failed; traceback:\n"); PyErr_Print(); } Py_XDECREF(warnings_module); } runtime->initialized = 1; if (core_config->site_import) { err = init_import_size(); /* Module site */ if (_Py_INIT_FAILED(err)) { return err; } } #ifndef MS_WINDOWS emit_stderr_warning_for_legacy_locale(runtime); #endif return _Py_INIT_OK(); } #undef _INIT_DEBUG_PRINT static _PyInitError init_python(const _PyCoreConfig *config, const _PyArgv *args) { _PyInitError err; err = _PyRuntime_Initialize(); if (_Py_INIT_FAILED(err)) { return err; } _PyRuntimeState *runtime = &_PyRuntime; PyInterpreterState *interp = NULL; err = _Py_InitializeCore(runtime, config, args, &interp); if (_Py_INIT_FAILED(err)) { return err; } config = &interp->core_config; if (!config->_frozen) { err = _Py_InitializeMainInterpreter(runtime, interp); if (_Py_INIT_FAILED(err)) { return err; } } return _Py_INIT_OK(); } _PyInitError _Py_InitializeFromArgs(const _PyCoreConfig *config, int argc, char **argv) { _PyArgv args = {.use_bytes_argv = 1, .argc = argc, .bytes_argv = argv}; return init_python(config, &args); } _PyInitError _Py_InitializeFromWideArgs(const _PyCoreConfig *config, int argc, wchar_t **argv) { _PyArgv args = {.use_bytes_argv = 0, .argc = argc, .wchar_argv = argv}; return init_python(config, &args); } _PyInitError _Py_InitializeFromConfig(const _PyCoreConfig *config) { return init_python(config, NULL); } void Py_InitializeEx(int install_sigs) { _PyInitError err; err = _PyRuntime_Initialize(); if (_Py_INIT_FAILED(err)) { _Py_ExitInitError(err); } _PyRuntimeState *runtime = &_PyRuntime; if (runtime->initialized) { /* bpo-33932: Calling Py_Initialize() twice does nothing. */ return; } _PyCoreConfig config = _PyCoreConfig_INIT; config.install_signal_handlers = install_sigs; err = _Py_InitializeFromConfig(&config); if (_Py_INIT_FAILED(err)) { _Py_ExitInitError(err); } } void Py_Initialize(void) { Py_InitializeEx(1); } #ifdef COUNT_ALLOCS extern void _Py_dump_counts(FILE*); #endif /* Flush stdout and stderr */ static int file_is_closed(PyObject *fobj) { int r; PyObject *tmp = PyObject_GetAttrString(fobj, "closed"); if (tmp == NULL) { PyErr_Clear(); return 0; } r = PyObject_IsTrue(tmp); Py_DECREF(tmp); if (r < 0) PyErr_Clear(); return r > 0; } static int flush_std_files(void) { PyObject *fout = _PySys_GetObjectId(&PyId_stdout); PyObject *ferr = _PySys_GetObjectId(&PyId_stderr); PyObject *tmp; int status = 0; if (fout != NULL && fout != Py_None && !file_is_closed(fout)) { tmp = _PyObject_CallMethodId(fout, &PyId_flush, NULL); if (tmp == NULL) { PyErr_WriteUnraisable(fout); status = -1; } else Py_DECREF(tmp); } if (ferr != NULL && ferr != Py_None && !file_is_closed(ferr)) { tmp = _PyObject_CallMethodId(ferr, &PyId_flush, NULL); if (tmp == NULL) { PyErr_Clear(); status = -1; } else Py_DECREF(tmp); } return status; } /* Undo the effect of Py_Initialize(). Beware: if multiple interpreter and/or thread states exist, these are not wiped out; only the current thread and interpreter state are deleted. But since everything else is deleted, those other interpreter and thread states should no longer be used. (XXX We should do better, e.g. wipe out all interpreters and threads.) Locking: as above. */ int Py_FinalizeEx(void) { int status = 0; _PyRuntimeState *runtime = &_PyRuntime; if (!runtime->initialized) { return status; } // Wrap up existing "threading"-module-created, non-daemon threads. wait_for_thread_shutdown(); // Make any remaining pending calls. _Py_FinishPendingCalls(runtime); /* Get current thread state and interpreter pointer */ PyThreadState *tstate = _PyRuntimeState_GetThreadState(runtime); PyInterpreterState *interp = tstate->interp; /* The interpreter is still entirely intact at this point, and the * exit funcs may be relying on that. In particular, if some thread * or exit func is still waiting to do an import, the import machinery * expects Py_IsInitialized() to return true. So don't say the * runtime is uninitialized until after the exit funcs have run. * Note that Threading.py uses an exit func to do a join on all the * threads created thru it, so this also protects pending imports in * the threads created via Threading. */ call_py_exitfuncs(interp); /* Copy the core config, PyInterpreterState_Delete() free the core config memory */ #ifdef Py_REF_DEBUG int show_ref_count = interp->core_config.show_ref_count; #endif #ifdef Py_TRACE_REFS int dump_refs = interp->core_config.dump_refs; #endif #ifdef WITH_PYMALLOC int malloc_stats = interp->core_config.malloc_stats; #endif /* Remaining threads (e.g. daemon threads) will automatically exit after taking the GIL (in PyEval_RestoreThread()). */ runtime->finalizing = tstate; runtime->initialized = 0; runtime->core_initialized = 0; /* Flush sys.stdout and sys.stderr */ if (flush_std_files() < 0) { status = -1; } /* Disable signal handling */ PyOS_FiniInterrupts(); /* Collect garbage. This may call finalizers; it's nice to call these * before all modules are destroyed. * XXX If a __del__ or weakref callback is triggered here, and tries to * XXX import a module, bad things can happen, because Python no * XXX longer believes it's initialized. * XXX Fatal Python error: Interpreter not initialized (version mismatch?) * XXX is easy to provoke that way. I've also seen, e.g., * XXX Exception exceptions.ImportError: 'No module named sha' * XXX in ignored * XXX but I'm unclear on exactly how that one happens. In any case, * XXX I haven't seen a real-life report of either of these. */ _PyGC_CollectIfEnabled(); #ifdef COUNT_ALLOCS /* With COUNT_ALLOCS, it helps to run GC multiple times: each collection might release some types from the type list, so they become garbage. */ while (_PyGC_CollectIfEnabled() > 0) /* nothing */; #endif /* Destroy all modules */ PyImport_Cleanup(); /* Flush sys.stdout and sys.stderr (again, in case more was printed) */ if (flush_std_files() < 0) { status = -1; } /* Collect final garbage. This disposes of cycles created by * class definitions, for example. * XXX This is disabled because it caused too many problems. If * XXX a __del__ or weakref callback triggers here, Python code has * XXX a hard time running, because even the sys module has been * XXX cleared out (sys.stdout is gone, sys.excepthook is gone, etc). * XXX One symptom is a sequence of information-free messages * XXX coming from threads (if a __del__ or callback is invoked, * XXX other threads can execute too, and any exception they encounter * XXX triggers a comedy of errors as subsystem after subsystem * XXX fails to find what it *expects* to find in sys to help report * XXX the exception and consequent unexpected failures). I've also * XXX seen segfaults then, after adding print statements to the * XXX Python code getting called. */ #if 0 _PyGC_CollectIfEnabled(); #endif /* Disable tracemalloc after all Python objects have been destroyed, so it is possible to use tracemalloc in objects destructor. */ _PyTraceMalloc_Fini(); /* Destroy the database used by _PyImport_{Fixup,Find}Extension */ _PyImport_Fini(); /* Cleanup typeobject.c's internal caches. */ _PyType_Fini(); /* unload faulthandler module */ _PyFaulthandler_Fini(); /* Debugging stuff */ #ifdef COUNT_ALLOCS _Py_dump_counts(stderr); #endif /* dump hash stats */ _PyHash_Fini(); #ifdef Py_REF_DEBUG if (show_ref_count) { _PyDebug_PrintTotalRefs(); } #endif #ifdef Py_TRACE_REFS /* Display all objects still alive -- this can invoke arbitrary * __repr__ overrides, so requires a mostly-intact interpreter. * Alas, a lot of stuff may still be alive now that will be cleaned * up later. */ if (dump_refs) { _Py_PrintReferences(stderr); } #endif /* Py_TRACE_REFS */ /* Clear interpreter state and all thread states. */ PyInterpreterState_Clear(interp); /* Now we decref the exception classes. After this point nothing can raise an exception. That's okay, because each Fini() method below has been checked to make sure no exceptions are ever raised. */ _PyExc_Fini(); /* Sundry finalizers */ PyMethod_Fini(); PyFrame_Fini(); PyCFunction_Fini(); PyTuple_Fini(); PyList_Fini(); PySet_Fini(); PyBytes_Fini(); PyLong_Fini(); PyFloat_Fini(); PyDict_Fini(); PySlice_Fini(); _PyGC_Fini(runtime); _PyWarnings_Fini(interp); _Py_HashRandomization_Fini(); _PyArg_Fini(); PyAsyncGen_Fini(); _PyContext_Fini(); /* Cleanup Unicode implementation */ _PyUnicode_Fini(); _Py_ClearFileSystemEncoding(); /* XXX Still allocated: - various static ad-hoc pointers to interned strings - int and float free list blocks - whatever various modules and libraries allocate */ PyGrammar_RemoveAccelerators(&_PyParser_Grammar); /* Cleanup auto-thread-state */ _PyGILState_Fini(runtime); /* Delete current thread. After this, many C API calls become crashy. */ PyThreadState_Swap(NULL); PyInterpreterState_Delete(interp); #ifdef Py_TRACE_REFS /* Display addresses (& refcnts) of all objects still alive. * An address can be used to find the repr of the object, printed * above by _Py_PrintReferences. */ if (dump_refs) { _Py_PrintReferenceAddresses(stderr); } #endif /* Py_TRACE_REFS */ #ifdef WITH_PYMALLOC if (malloc_stats) { _PyObject_DebugMallocStats(stderr); } #endif call_ll_exitfuncs(runtime); _PyRuntime_Finalize(); return status; } void Py_Finalize(void) { Py_FinalizeEx(); } /* Create and initialize a new interpreter and thread, and return the new thread. This requires that Py_Initialize() has been called first. Unsuccessful initialization yields a NULL pointer. Note that *no* exception information is available even in this case -- the exception information is held in the thread, and there is no thread. Locking: as above. */ static _PyInitError new_interpreter(PyThreadState **tstate_p) { _PyInitError err; err = _PyRuntime_Initialize(); if (_Py_INIT_FAILED(err)) { return err; } _PyRuntimeState *runtime = &_PyRuntime; if (!runtime->initialized) { return _Py_INIT_ERR("Py_Initialize must be called first"); } /* Issue #10915, #15751: The GIL API doesn't work with multiple interpreters: disable PyGILState_Check(). */ _PyGILState_check_enabled = 0; PyInterpreterState *interp = PyInterpreterState_New(); if (interp == NULL) { *tstate_p = NULL; return _Py_INIT_OK(); } PyThreadState *tstate = PyThreadState_New(interp); if (tstate == NULL) { PyInterpreterState_Delete(interp); *tstate_p = NULL; return _Py_INIT_OK(); } PyThreadState *save_tstate = PyThreadState_Swap(tstate); /* Copy the current interpreter config into the new interpreter */ _PyCoreConfig *core_config; if (save_tstate != NULL) { core_config = &save_tstate->interp->core_config; } else { /* No current thread state, copy from the main interpreter */ PyInterpreterState *main_interp = PyInterpreterState_Main(); core_config = &main_interp->core_config; } err = _PyCoreConfig_Copy(&interp->core_config, core_config); if (_Py_INIT_FAILED(err)) { return err; } core_config = &interp->core_config; err = _PyExc_Init(); if (_Py_INIT_FAILED(err)) { return err; } /* XXX The following is lax in error checking */ PyObject *modules = PyDict_New(); if (modules == NULL) { return _Py_INIT_ERR("can't make modules dictionary"); } interp->modules = modules; PyObject *sysmod = _PyImport_FindBuiltin("sys", modules); if (sysmod != NULL) { interp->sysdict = PyModule_GetDict(sysmod); if (interp->sysdict == NULL) { goto handle_error; } Py_INCREF(interp->sysdict); PyDict_SetItemString(interp->sysdict, "modules", modules); if (_PySys_InitMain(runtime, interp) < 0) { return _Py_INIT_ERR("can't finish initializing sys"); } } else if (PyErr_Occurred()) { goto handle_error; } PyObject *bimod = _PyImport_FindBuiltin("builtins", modules); if (bimod != NULL) { interp->builtins = PyModule_GetDict(bimod); if (interp->builtins == NULL) goto handle_error; Py_INCREF(interp->builtins); } else if (PyErr_Occurred()) { goto handle_error; } if (bimod != NULL && sysmod != NULL) { err = _PyBuiltins_AddExceptions(bimod); if (_Py_INIT_FAILED(err)) { return err; } err = _PySys_SetPreliminaryStderr(interp->sysdict); if (_Py_INIT_FAILED(err)) { return err; } err = _PyImportHooks_Init(); if (_Py_INIT_FAILED(err)) { return err; } err = init_importlib(interp, sysmod); if (_Py_INIT_FAILED(err)) { return err; } err = init_importlib_external(interp); if (_Py_INIT_FAILED(err)) { return err; } err = _PyUnicode_InitEncodings(interp); if (_Py_INIT_FAILED(err)) { return err; } err = init_sys_streams(interp); if (_Py_INIT_FAILED(err)) { return err; } err = add_main_module(interp); if (_Py_INIT_FAILED(err)) { return err; } if (core_config->site_import) { err = init_import_size(); if (_Py_INIT_FAILED(err)) { return err; } } } if (PyErr_Occurred()) { goto handle_error; } *tstate_p = tstate; return _Py_INIT_OK(); handle_error: /* Oops, it didn't work. Undo it all. */ PyErr_PrintEx(0); PyThreadState_Clear(tstate); PyThreadState_Swap(save_tstate); PyThreadState_Delete(tstate); PyInterpreterState_Delete(interp); *tstate_p = NULL; return _Py_INIT_OK(); } PyThreadState * Py_NewInterpreter(void) { PyThreadState *tstate = NULL; _PyInitError err = new_interpreter(&tstate); if (_Py_INIT_FAILED(err)) { _Py_ExitInitError(err); } return tstate; } /* Delete an interpreter and its last thread. This requires that the given thread state is current, that the thread has no remaining frames, and that it is its interpreter's only remaining thread. It is a fatal error to violate these constraints. (Py_FinalizeEx() doesn't have these constraints -- it zaps everything, regardless.) Locking: as above. */ void Py_EndInterpreter(PyThreadState *tstate) { PyInterpreterState *interp = tstate->interp; if (tstate != _PyThreadState_GET()) Py_FatalError("Py_EndInterpreter: thread is not current"); if (tstate->frame != NULL) Py_FatalError("Py_EndInterpreter: thread still has a frame"); interp->finalizing = 1; // Wrap up existing "threading"-module-created, non-daemon threads. wait_for_thread_shutdown(); call_py_exitfuncs(interp); if (tstate != interp->tstate_head || tstate->next != NULL) Py_FatalError("Py_EndInterpreter: not the last thread"); PyImport_Cleanup(); PyInterpreterState_Clear(interp); PyThreadState_Swap(NULL); PyInterpreterState_Delete(interp); } /* Add the __main__ module */ static _PyInitError add_main_module(PyInterpreterState *interp) { PyObject *m, *d, *loader, *ann_dict; m = PyImport_AddModule("__main__"); if (m == NULL) return _Py_INIT_ERR("can't create __main__ module"); d = PyModule_GetDict(m); ann_dict = PyDict_New(); if ((ann_dict == NULL) || (PyDict_SetItemString(d, "__annotations__", ann_dict) < 0)) { return _Py_INIT_ERR("Failed to initialize __main__.__annotations__"); } Py_DECREF(ann_dict); if (PyDict_GetItemString(d, "__builtins__") == NULL) { PyObject *bimod = PyImport_ImportModule("builtins"); if (bimod == NULL) { return _Py_INIT_ERR("Failed to retrieve builtins module"); } if (PyDict_SetItemString(d, "__builtins__", bimod) < 0) { return _Py_INIT_ERR("Failed to initialize __main__.__builtins__"); } Py_DECREF(bimod); } /* Main is a little special - imp.is_builtin("__main__") will return * False, but BuiltinImporter is still the most appropriate initial * setting for its __loader__ attribute. A more suitable value will * be set if __main__ gets further initialized later in the startup * process. */ loader = PyDict_GetItemString(d, "__loader__"); if (loader == NULL || loader == Py_None) { PyObject *loader = PyObject_GetAttrString(interp->importlib, "BuiltinImporter"); if (loader == NULL) { return _Py_INIT_ERR("Failed to retrieve BuiltinImporter"); } if (PyDict_SetItemString(d, "__loader__", loader) < 0) { return _Py_INIT_ERR("Failed to initialize __main__.__loader__"); } Py_DECREF(loader); } return _Py_INIT_OK(); } /* Import the site module (not into __main__ though) */ static _PyInitError init_import_size(void) { PyObject *m; m = PyImport_ImportModule("site"); if (m == NULL) { return _Py_INIT_ERR("Failed to import the site module"); } Py_DECREF(m); return _Py_INIT_OK(); } /* Check if a file descriptor is valid or not. Return 0 if the file descriptor is invalid, return non-zero otherwise. */ static int is_valid_fd(int fd) { /* dup() is faster than fstat(): fstat() can require input/output operations, whereas dup() doesn't. There is a low risk of EMFILE/ENFILE at Python startup. Problem: dup() doesn't check if the file descriptor is valid on some platforms. bpo-30225: On macOS Tiger, when stdout is redirected to a pipe and the other side of the pipe is closed, dup(1) succeed, whereas fstat(1, &st) fails with EBADF. FreeBSD has similar issue (bpo-32849). Only use dup() on platforms where dup() is enough to detect invalid FD in corner cases: on Linux and Windows (bpo-32849). */ #if defined(__linux__) || defined(MS_WINDOWS) if (fd < 0) { return 0; } int fd2; _Py_BEGIN_SUPPRESS_IPH fd2 = dup(fd); if (fd2 >= 0) { close(fd2); } _Py_END_SUPPRESS_IPH return (fd2 >= 0); #else struct stat st; return (fstat(fd, &st) == 0); #endif } /* returns Py_None if the fd is not valid */ static PyObject* create_stdio(const _PyCoreConfig *config, PyObject* io, int fd, int write_mode, const char* name, const wchar_t* encoding, const wchar_t* errors) { PyObject *buf = NULL, *stream = NULL, *text = NULL, *raw = NULL, *res; const char* mode; const char* newline; PyObject *line_buffering, *write_through; int buffering, isatty; _Py_IDENTIFIER(open); _Py_IDENTIFIER(isatty); _Py_IDENTIFIER(TextIOWrapper); _Py_IDENTIFIER(mode); const int buffered_stdio = config->buffered_stdio; if (!is_valid_fd(fd)) Py_RETURN_NONE; /* stdin is always opened in buffered mode, first because it shouldn't make a difference in common use cases, second because TextIOWrapper depends on the presence of a read1() method which only exists on buffered streams. */ if (!buffered_stdio && write_mode) buffering = 0; else buffering = -1; if (write_mode) mode = "wb"; else mode = "rb"; buf = _PyObject_CallMethodId(io, &PyId_open, "isiOOOi", fd, mode, buffering, Py_None, Py_None, /* encoding, errors */ Py_None, 0); /* newline, closefd */ if (buf == NULL) goto error; if (buffering) { _Py_IDENTIFIER(raw); raw = _PyObject_GetAttrId(buf, &PyId_raw); if (raw == NULL) goto error; } else { raw = buf; Py_INCREF(raw); } #ifdef MS_WINDOWS /* Windows console IO is always UTF-8 encoded */ if (PyWindowsConsoleIO_Check(raw)) encoding = L"utf-8"; #endif text = PyUnicode_FromString(name); if (text == NULL || _PyObject_SetAttrId(raw, &PyId_name, text) < 0) goto error; res = _PyObject_CallMethodId(raw, &PyId_isatty, NULL); if (res == NULL) goto error; isatty = PyObject_IsTrue(res); Py_DECREF(res); if (isatty == -1) goto error; if (!buffered_stdio) write_through = Py_True; else write_through = Py_False; if (isatty && buffered_stdio) line_buffering = Py_True; else line_buffering = Py_False; Py_CLEAR(raw); Py_CLEAR(text); #ifdef MS_WINDOWS /* sys.stdin: enable universal newline mode, translate "\r\n" and "\r" newlines to "\n". sys.stdout and sys.stderr: translate "\n" to "\r\n". */ newline = NULL; #else /* sys.stdin: split lines at "\n". sys.stdout and sys.stderr: don't translate newlines (use "\n"). */ newline = "\n"; #endif PyObject *encoding_str = PyUnicode_FromWideChar(encoding, -1); if (encoding_str == NULL) { Py_CLEAR(buf); goto error; } PyObject *errors_str = PyUnicode_FromWideChar(errors, -1); if (errors_str == NULL) { Py_CLEAR(buf); Py_CLEAR(encoding_str); goto error; } stream = _PyObject_CallMethodId(io, &PyId_TextIOWrapper, "OOOsOO", buf, encoding_str, errors_str, newline, line_buffering, write_through); Py_CLEAR(buf); Py_CLEAR(encoding_str); Py_CLEAR(errors_str); if (stream == NULL) goto error; if (write_mode) mode = "w"; else mode = "r"; text = PyUnicode_FromString(mode); if (!text || _PyObject_SetAttrId(stream, &PyId_mode, text) < 0) goto error; Py_CLEAR(text); return stream; error: Py_XDECREF(buf); Py_XDECREF(stream); Py_XDECREF(text); Py_XDECREF(raw); if (PyErr_ExceptionMatches(PyExc_OSError) && !is_valid_fd(fd)) { /* Issue #24891: the file descriptor was closed after the first is_valid_fd() check was called. Ignore the OSError and set the stream to None. */ PyErr_Clear(); Py_RETURN_NONE; } return NULL; } /* Initialize sys.stdin, stdout, stderr and builtins.open */ static _PyInitError init_sys_streams(PyInterpreterState *interp) { PyObject *iomod = NULL, *wrapper; PyObject *bimod = NULL; PyObject *m; PyObject *std = NULL; int fd; PyObject * encoding_attr; _PyInitError res = _Py_INIT_OK(); _PyCoreConfig *config = &interp->core_config; /* Check that stdin is not a directory Using shell redirection, you can redirect stdin to a directory, crashing the Python interpreter. Catch this common mistake here and output a useful error message. Note that under MS Windows, the shell already prevents that. */ #ifndef MS_WINDOWS struct _Py_stat_struct sb; if (_Py_fstat_noraise(fileno(stdin), &sb) == 0 && S_ISDIR(sb.st_mode)) { return _Py_INIT_ERR(" is a directory, cannot continue"); } #endif /* Hack to avoid a nasty recursion issue when Python is invoked in verbose mode: pre-import the Latin-1 and UTF-8 codecs */ if ((m = PyImport_ImportModule("encodings.utf_8")) == NULL) { goto error; } Py_DECREF(m); if (!(m = PyImport_ImportModule("encodings.latin_1"))) { goto error; } Py_DECREF(m); if (!(bimod = PyImport_ImportModule("builtins"))) { goto error; } if (!(iomod = PyImport_ImportModule("io"))) { goto error; } if (!(wrapper = PyObject_GetAttrString(iomod, "OpenWrapper"))) { goto error; } /* Set builtins.open */ if (PyObject_SetAttrString(bimod, "open", wrapper) == -1) { Py_DECREF(wrapper); goto error; } Py_DECREF(wrapper); /* Set sys.stdin */ fd = fileno(stdin); /* Under some conditions stdin, stdout and stderr may not be connected * and fileno() may point to an invalid file descriptor. For example * GUI apps don't have valid standard streams by default. */ std = create_stdio(config, iomod, fd, 0, "", config->stdio_encoding, config->stdio_errors); if (std == NULL) goto error; PySys_SetObject("__stdin__", std); _PySys_SetObjectId(&PyId_stdin, std); Py_DECREF(std); /* Set sys.stdout */ fd = fileno(stdout); std = create_stdio(config, iomod, fd, 1, "", config->stdio_encoding, config->stdio_errors); if (std == NULL) goto error; PySys_SetObject("__stdout__", std); _PySys_SetObjectId(&PyId_stdout, std); Py_DECREF(std); #if 1 /* Disable this if you have trouble debugging bootstrap stuff */ /* Set sys.stderr, replaces the preliminary stderr */ fd = fileno(stderr); std = create_stdio(config, iomod, fd, 1, "", config->stdio_encoding, L"backslashreplace"); if (std == NULL) goto error; /* Same as hack above, pre-import stderr's codec to avoid recursion when import.c tries to write to stderr in verbose mode. */ encoding_attr = PyObject_GetAttrString(std, "encoding"); if (encoding_attr != NULL) { const char *std_encoding = PyUnicode_AsUTF8(encoding_attr); if (std_encoding != NULL) { PyObject *codec_info = _PyCodec_Lookup(std_encoding); Py_XDECREF(codec_info); } Py_DECREF(encoding_attr); } PyErr_Clear(); /* Not a fatal error if codec isn't available */ if (PySys_SetObject("__stderr__", std) < 0) { Py_DECREF(std); goto error; } if (_PySys_SetObjectId(&PyId_stderr, std) < 0) { Py_DECREF(std); goto error; } Py_DECREF(std); #endif goto done; error: res = _Py_INIT_ERR("can't initialize sys standard streams"); done: _Py_ClearStandardStreamEncoding(); Py_XDECREF(bimod); Py_XDECREF(iomod); return res; } static void _Py_FatalError_DumpTracebacks(int fd) { fputc('\n', stderr); fflush(stderr); /* display the current Python stack */ _Py_DumpTracebackThreads(fd, NULL, NULL); } /* Print the current exception (if an exception is set) with its traceback, or display the current Python stack. Don't call PyErr_PrintEx() and the except hook, because Py_FatalError() is called on catastrophic cases. Return 1 if the traceback was displayed, 0 otherwise. */ static int _Py_FatalError_PrintExc(int fd) { PyObject *ferr, *res; PyObject *exception, *v, *tb; int has_tb; PyErr_Fetch(&exception, &v, &tb); if (exception == NULL) { /* No current exception */ return 0; } ferr = _PySys_GetObjectId(&PyId_stderr); if (ferr == NULL || ferr == Py_None) { /* sys.stderr is not set yet or set to None, no need to try to display the exception */ return 0; } PyErr_NormalizeException(&exception, &v, &tb); if (tb == NULL) { tb = Py_None; Py_INCREF(tb); } PyException_SetTraceback(v, tb); if (exception == NULL) { /* PyErr_NormalizeException() failed */ return 0; } has_tb = (tb != Py_None); PyErr_Display(exception, v, tb); Py_XDECREF(exception); Py_XDECREF(v); Py_XDECREF(tb); /* sys.stderr may be buffered: call sys.stderr.flush() */ res = _PyObject_CallMethodId(ferr, &PyId_flush, NULL); if (res == NULL) PyErr_Clear(); else Py_DECREF(res); return has_tb; } /* Print fatal error message and abort */ #ifdef MS_WINDOWS static void fatal_output_debug(const char *msg) { /* buffer of 256 bytes allocated on the stack */ WCHAR buffer[256 / sizeof(WCHAR)]; size_t buflen = Py_ARRAY_LENGTH(buffer) - 1; size_t msglen; OutputDebugStringW(L"Fatal Python error: "); msglen = strlen(msg); while (msglen) { size_t i; if (buflen > msglen) { buflen = msglen; } /* Convert the message to wchar_t. This uses a simple one-to-one conversion, assuming that the this error message actually uses ASCII only. If this ceases to be true, we will have to convert. */ for (i=0; i < buflen; ++i) { buffer[i] = msg[i]; } buffer[i] = L'\0'; OutputDebugStringW(buffer); msg += buflen; msglen -= buflen; } OutputDebugStringW(L"\n"); } #endif static void _Py_NO_RETURN fatal_error(const char *prefix, const char *msg, int status) { const int fd = fileno(stderr); static int reentrant = 0; if (reentrant) { /* Py_FatalError() caused a second fatal error. Example: flush_std_files() raises a recursion error. */ goto exit; } reentrant = 1; fprintf(stderr, "Fatal Python error: "); if (prefix) { fputs(prefix, stderr); fputs(": ", stderr); } if (msg) { fputs(msg, stderr); } else { fprintf(stderr, ""); } fputs("\n", stderr); fflush(stderr); /* it helps in Windows debug build */ /* Check if the current thread has a Python thread state and holds the GIL */ PyThreadState *tss_tstate = PyGILState_GetThisThreadState(); if (tss_tstate != NULL) { PyThreadState *tstate = _PyThreadState_GET(); if (tss_tstate != tstate) { /* The Python thread does not hold the GIL */ tss_tstate = NULL; } } else { /* Py_FatalError() has been called from a C thread which has no Python thread state. */ } int has_tstate_and_gil = (tss_tstate != NULL); if (has_tstate_and_gil) { /* If an exception is set, print the exception with its traceback */ if (!_Py_FatalError_PrintExc(fd)) { /* No exception is set, or an exception is set without traceback */ _Py_FatalError_DumpTracebacks(fd); } } else { _Py_FatalError_DumpTracebacks(fd); } /* The main purpose of faulthandler is to display the traceback. This function already did its best to display a traceback. Disable faulthandler to prevent writing a second traceback on abort(). */ _PyFaulthandler_Fini(); /* Check if the current Python thread hold the GIL */ if (has_tstate_and_gil) { /* Flush sys.stdout and sys.stderr */ flush_std_files(); } #ifdef MS_WINDOWS fatal_output_debug(msg); #endif /* MS_WINDOWS */ exit: if (status < 0) { #if defined(MS_WINDOWS) && defined(_DEBUG) DebugBreak(); #endif abort(); } else { exit(status); } } void _Py_NO_RETURN Py_FatalError(const char *msg) { fatal_error(NULL, msg, -1); } void _Py_NO_RETURN _Py_ExitInitError(_PyInitError err) { if (_Py_INIT_IS_EXIT(err)) { exit(err.exitcode); } else if (_Py_INIT_IS_ERROR(err)) { fatal_error(err._func, err.err_msg, 1); } else { Py_FatalError("_Py_ExitInitError() must not be called on success"); } } /* Clean up and exit */ # include "pythread.h" /* For the atexit module. */ void _Py_PyAtExit(void (*func)(PyObject *), PyObject *module) { PyInterpreterState *is = _PyInterpreterState_Get(); /* Guard against API misuse (see bpo-17852) */ assert(is->pyexitfunc == NULL || is->pyexitfunc == func); is->pyexitfunc = func; is->pyexitmodule = module; } static void call_py_exitfuncs(PyInterpreterState *istate) { if (istate->pyexitfunc == NULL) return; (*istate->pyexitfunc)(istate->pyexitmodule); PyErr_Clear(); } /* Wait until threading._shutdown completes, provided the threading module was imported in the first place. The shutdown routine will wait until all non-daemon "threading" threads have completed. */ static void wait_for_thread_shutdown(void) { _Py_IDENTIFIER(_shutdown); PyObject *result; PyObject *threading = _PyImport_GetModuleId(&PyId_threading); if (threading == NULL) { if (PyErr_Occurred()) { PyErr_WriteUnraisable(NULL); } /* else: threading not imported */ return; } result = _PyObject_CallMethodId(threading, &PyId__shutdown, NULL); if (result == NULL) { PyErr_WriteUnraisable(threading); } else { Py_DECREF(result); } Py_DECREF(threading); } #define NEXITFUNCS 32 int Py_AtExit(void (*func)(void)) { if (_PyRuntime.nexitfuncs >= NEXITFUNCS) return -1; _PyRuntime.exitfuncs[_PyRuntime.nexitfuncs++] = func; return 0; } static void call_ll_exitfuncs(_PyRuntimeState *runtime) { while (runtime->nexitfuncs > 0) { /* pop last function from the list */ runtime->nexitfuncs--; void (*exitfunc)(void) = runtime->exitfuncs[runtime->nexitfuncs]; runtime->exitfuncs[runtime->nexitfuncs] = NULL; exitfunc(); } fflush(stdout); fflush(stderr); } void _Py_NO_RETURN Py_Exit(int sts) { if (Py_FinalizeEx() < 0) { sts = 120; } exit(sts); } static _PyInitError init_signals(void) { #ifdef SIGPIPE PyOS_setsig(SIGPIPE, SIG_IGN); #endif #ifdef SIGXFZ PyOS_setsig(SIGXFZ, SIG_IGN); #endif #ifdef SIGXFSZ PyOS_setsig(SIGXFSZ, SIG_IGN); #endif PyOS_InitInterrupts(); /* May imply initsignal() */ if (PyErr_Occurred()) { return _Py_INIT_ERR("can't import signal"); } return _Py_INIT_OK(); } /* Restore signals that the interpreter has called SIG_IGN on to SIG_DFL. * * All of the code in this function must only use async-signal-safe functions, * listed at `man 7 signal` or * http://www.opengroup.org/onlinepubs/009695399/functions/xsh_chap02_04.html. */ void _Py_RestoreSignals(void) { #ifdef SIGPIPE PyOS_setsig(SIGPIPE, SIG_DFL); #endif #ifdef SIGXFZ PyOS_setsig(SIGXFZ, SIG_DFL); #endif #ifdef SIGXFSZ PyOS_setsig(SIGXFSZ, SIG_DFL); #endif } /* * The file descriptor fd is considered ``interactive'' if either * a) isatty(fd) is TRUE, or * b) the -i flag was given, and the filename associated with * the descriptor is NULL or "" or "???". */ int Py_FdIsInteractive(FILE *fp, const char *filename) { if (isatty((int)fileno(fp))) return 1; if (!Py_InteractiveFlag) return 0; return (filename == NULL) || (strcmp(filename, "") == 0) || (strcmp(filename, "???") == 0); } /* Wrappers around sigaction() or signal(). */ PyOS_sighandler_t PyOS_getsig(int sig) { #ifdef HAVE_SIGACTION struct sigaction context; if (sigaction(sig, NULL, &context) == -1) return SIG_ERR; return context.sa_handler; #else PyOS_sighandler_t handler; /* Special signal handling for the secure CRT in Visual Studio 2005 */ #if defined(_MSC_VER) && _MSC_VER >= 1400 switch (sig) { /* Only these signals are valid */ case SIGINT: case SIGILL: case SIGFPE: case SIGSEGV: case SIGTERM: case SIGBREAK: case SIGABRT: break; /* Don't call signal() with other values or it will assert */ default: return SIG_ERR; } #endif /* _MSC_VER && _MSC_VER >= 1400 */ handler = signal(sig, SIG_IGN); if (handler != SIG_ERR) signal(sig, handler); return handler; #endif } /* * All of the code in this function must only use async-signal-safe functions, * listed at `man 7 signal` or * http://www.opengroup.org/onlinepubs/009695399/functions/xsh_chap02_04.html. */ PyOS_sighandler_t PyOS_setsig(int sig, PyOS_sighandler_t handler) { #ifdef HAVE_SIGACTION /* Some code in Modules/signalmodule.c depends on sigaction() being * used here if HAVE_SIGACTION is defined. Fix that if this code * changes to invalidate that assumption. */ struct sigaction context, ocontext; context.sa_handler = handler; sigemptyset(&context.sa_mask); context.sa_flags = 0; if (sigaction(sig, &context, &ocontext) == -1) return SIG_ERR; return ocontext.sa_handler; #else PyOS_sighandler_t oldhandler; oldhandler = signal(sig, handler); #ifdef HAVE_SIGINTERRUPT siginterrupt(sig, 1); #endif return oldhandler; #endif } #ifdef __cplusplus } #endif