/* API for managing interactions between isolated interpreters */ #include "Python.h" #include "pycore_ceval.h" // _Py_simple_func #include "pycore_crossinterp.h" // struct _xid #include "pycore_initconfig.h" // _PyStatus_OK() #include "pycore_namespace.h" //_PyNamespace_New() #include "pycore_pyerrors.h" // _PyErr_Clear() #include "pycore_pystate.h" // _PyInterpreterState_GET() #include "pycore_typeobject.h" // _PyType_GetModuleName() #include "pycore_weakref.h" // _PyWeakref_GET_REF() /***************************/ /* cross-interpreter calls */ /***************************/ int _Py_CallInInterpreter(PyInterpreterState *interp, _Py_simple_func func, void *arg) { if (interp == _PyThreadState_GetCurrent()->interp) { return func(arg); } // XXX Emit a warning if this fails? _PyEval_AddPendingCall(interp, (_Py_pending_call_func)func, arg, 0); return 0; } int _Py_CallInInterpreterAndRawFree(PyInterpreterState *interp, _Py_simple_func func, void *arg) { if (interp == _PyThreadState_GetCurrent()->interp) { int res = func(arg); PyMem_RawFree(arg); return res; } // XXX Emit a warning if this fails? _PyEval_AddPendingCall(interp, func, arg, _Py_PENDING_RAWFREE); return 0; } /**************************/ /* cross-interpreter data */ /**************************/ _PyCrossInterpreterData * _PyCrossInterpreterData_New(void) { _PyCrossInterpreterData *xid = PyMem_RawMalloc( sizeof(_PyCrossInterpreterData)); if (xid == NULL) { PyErr_NoMemory(); } return xid; } void _PyCrossInterpreterData_Free(_PyCrossInterpreterData *xid) { PyInterpreterState *interp = PyInterpreterState_Get(); _PyCrossInterpreterData_Clear(interp, xid); PyMem_RawFree(xid); } /* exceptions */ static PyStatus _init_not_shareable_error_type(PyInterpreterState *interp) { const char *name = "_interpreters.NotShareableError"; PyObject *base = PyExc_ValueError; PyObject *ns = NULL; PyObject *exctype = PyErr_NewException(name, base, ns); if (exctype == NULL) { PyErr_Clear(); return _PyStatus_ERR("could not initialize NotShareableError"); } interp->xi.PyExc_NotShareableError = exctype; return _PyStatus_OK(); } static void _fini_not_shareable_error_type(PyInterpreterState *interp) { Py_CLEAR(interp->xi.PyExc_NotShareableError); } static PyObject * _get_not_shareable_error_type(PyInterpreterState *interp) { assert(interp->xi.PyExc_NotShareableError != NULL); return interp->xi.PyExc_NotShareableError; } /* defining cross-interpreter data */ static inline void _xidata_init(_PyCrossInterpreterData *data) { // If the value is being reused // then _xidata_clear() should have been called already. assert(data->data == NULL); assert(data->obj == NULL); *data = (_PyCrossInterpreterData){0}; data->interpid = -1; } static inline void _xidata_clear(_PyCrossInterpreterData *data) { // _PyCrossInterpreterData only has two members that need to be // cleaned up, if set: "data" must be freed and "obj" must be decref'ed. // In both cases the original (owning) interpreter must be used, // which is the caller's responsibility to ensure. if (data->data != NULL) { if (data->free != NULL) { data->free(data->data); } data->data = NULL; } Py_CLEAR(data->obj); } void _PyCrossInterpreterData_Init(_PyCrossInterpreterData *data, PyInterpreterState *interp, void *shared, PyObject *obj, xid_newobjectfunc new_object) { assert(data != NULL); assert(new_object != NULL); _xidata_init(data); data->data = shared; if (obj != NULL) { assert(interp != NULL); // released in _PyCrossInterpreterData_Clear() data->obj = Py_NewRef(obj); } // Ideally every object would know its owning interpreter. // Until then, we have to rely on the caller to identify it // (but we don't need it in all cases). data->interpid = (interp != NULL) ? interp->id : -1; data->new_object = new_object; } int _PyCrossInterpreterData_InitWithSize(_PyCrossInterpreterData *data, PyInterpreterState *interp, const size_t size, PyObject *obj, xid_newobjectfunc new_object) { assert(size > 0); // For now we always free the shared data in the same interpreter // where it was allocated, so the interpreter is required. assert(interp != NULL); _PyCrossInterpreterData_Init(data, interp, NULL, obj, new_object); data->data = PyMem_RawMalloc(size); if (data->data == NULL) { return -1; } data->free = PyMem_RawFree; return 0; } void _PyCrossInterpreterData_Clear(PyInterpreterState *interp, _PyCrossInterpreterData *data) { assert(data != NULL); // This must be called in the owning interpreter. assert(interp == NULL || data->interpid == -1 || data->interpid == interp->id); _xidata_clear(data); } /* using cross-interpreter data */ static int _check_xidata(PyThreadState *tstate, _PyCrossInterpreterData *data) { // data->data can be anything, including NULL, so we don't check it. // data->obj may be NULL, so we don't check it. if (data->interpid < 0) { _PyErr_SetString(tstate, PyExc_SystemError, "missing interp"); return -1; } if (data->new_object == NULL) { _PyErr_SetString(tstate, PyExc_SystemError, "missing new_object func"); return -1; } // data->free may be NULL, so we don't check it. return 0; } static crossinterpdatafunc _lookup_getdata_from_registry( PyInterpreterState *, PyObject *); static crossinterpdatafunc _lookup_getdata(PyInterpreterState *interp, PyObject *obj) { /* Cross-interpreter objects are looked up by exact match on the class. We can reassess this policy when we move from a global registry to a tp_* slot. */ return _lookup_getdata_from_registry(interp, obj); } crossinterpdatafunc _PyCrossInterpreterData_Lookup(PyObject *obj) { PyInterpreterState *interp = _PyInterpreterState_GET(); return _lookup_getdata(interp, obj); } static inline void _set_xid_lookup_failure(PyInterpreterState *interp, PyObject *obj, const char *msg) { PyObject *exctype = _get_not_shareable_error_type(interp); assert(exctype != NULL); if (msg != NULL) { assert(obj == NULL); PyErr_SetString(exctype, msg); } else if (obj == NULL) { PyErr_SetString(exctype, "object does not support cross-interpreter data"); } else { PyErr_Format(exctype, "%S does not support cross-interpreter data", obj); } } int _PyObject_CheckCrossInterpreterData(PyObject *obj) { PyInterpreterState *interp = _PyInterpreterState_GET(); crossinterpdatafunc getdata = _lookup_getdata(interp, obj); if (getdata == NULL) { if (!PyErr_Occurred()) { _set_xid_lookup_failure(interp, obj, NULL); } return -1; } return 0; } int _PyObject_GetCrossInterpreterData(PyObject *obj, _PyCrossInterpreterData *data) { PyThreadState *tstate = _PyThreadState_GetCurrent(); #ifdef Py_DEBUG // The caller must hold the GIL _Py_EnsureTstateNotNULL(tstate); #endif PyInterpreterState *interp = tstate->interp; // Reset data before re-populating. *data = (_PyCrossInterpreterData){0}; data->interpid = -1; // Call the "getdata" func for the object. Py_INCREF(obj); crossinterpdatafunc getdata = _lookup_getdata(interp, obj); if (getdata == NULL) { Py_DECREF(obj); if (!PyErr_Occurred()) { _set_xid_lookup_failure(interp, obj, NULL); } return -1; } int res = getdata(tstate, obj, data); Py_DECREF(obj); if (res != 0) { return -1; } // Fill in the blanks and validate the result. data->interpid = interp->id; if (_check_xidata(tstate, data) != 0) { (void)_PyCrossInterpreterData_Release(data); return -1; } return 0; } PyObject * _PyCrossInterpreterData_NewObject(_PyCrossInterpreterData *data) { return data->new_object(data); } static int _call_clear_xidata(void *data) { _xidata_clear((_PyCrossInterpreterData *)data); return 0; } static int _xidata_release(_PyCrossInterpreterData *data, int rawfree) { if ((data->data == NULL || data->free == NULL) && data->obj == NULL) { // Nothing to release! if (rawfree) { PyMem_RawFree(data); } else { data->data = NULL; } return 0; } // Switch to the original interpreter. PyInterpreterState *interp = _PyInterpreterState_LookUpID(data->interpid); if (interp == NULL) { // The interpreter was already destroyed. // This function shouldn't have been called. // XXX Someone leaked some memory... assert(PyErr_Occurred()); if (rawfree) { PyMem_RawFree(data); } return -1; } // "Release" the data and/or the object. if (rawfree) { return _Py_CallInInterpreterAndRawFree(interp, _call_clear_xidata, data); } else { return _Py_CallInInterpreter(interp, _call_clear_xidata, data); } } int _PyCrossInterpreterData_Release(_PyCrossInterpreterData *data) { return _xidata_release(data, 0); } int _PyCrossInterpreterData_ReleaseAndRawFree(_PyCrossInterpreterData *data) { return _xidata_release(data, 1); } /* registry of {type -> crossinterpdatafunc} */ /* For now we use a global registry of shareable classes. An alternative would be to add a tp_* slot for a class's crossinterpdatafunc. It would be simpler and more efficient. */ static inline struct _xidregistry * _get_global_xidregistry(_PyRuntimeState *runtime) { return &runtime->xi.registry; } static inline struct _xidregistry * _get_xidregistry(PyInterpreterState *interp) { return &interp->xi.registry; } static inline struct _xidregistry * _get_xidregistry_for_type(PyInterpreterState *interp, PyTypeObject *cls) { struct _xidregistry *registry = _get_global_xidregistry(interp->runtime); if (cls->tp_flags & Py_TPFLAGS_HEAPTYPE) { registry = _get_xidregistry(interp); } return registry; } static int _xidregistry_add_type(struct _xidregistry *xidregistry, PyTypeObject *cls, crossinterpdatafunc getdata) { struct _xidregitem *newhead = PyMem_RawMalloc(sizeof(struct _xidregitem)); if (newhead == NULL) { return -1; } *newhead = (struct _xidregitem){ // We do not keep a reference, to avoid keeping the class alive. .cls = cls, .refcount = 1, .getdata = getdata, }; if (cls->tp_flags & Py_TPFLAGS_HEAPTYPE) { // XXX Assign a callback to clear the entry from the registry? newhead->weakref = PyWeakref_NewRef((PyObject *)cls, NULL); if (newhead->weakref == NULL) { PyMem_RawFree(newhead); return -1; } } newhead->next = xidregistry->head; if (newhead->next != NULL) { newhead->next->prev = newhead; } xidregistry->head = newhead; return 0; } static struct _xidregitem * _xidregistry_remove_entry(struct _xidregistry *xidregistry, struct _xidregitem *entry) { struct _xidregitem *next = entry->next; if (entry->prev != NULL) { assert(entry->prev->next == entry); entry->prev->next = next; } else { assert(xidregistry->head == entry); xidregistry->head = next; } if (next != NULL) { next->prev = entry->prev; } Py_XDECREF(entry->weakref); PyMem_RawFree(entry); return next; } static void _xidregistry_clear(struct _xidregistry *xidregistry) { struct _xidregitem *cur = xidregistry->head; xidregistry->head = NULL; while (cur != NULL) { struct _xidregitem *next = cur->next; Py_XDECREF(cur->weakref); PyMem_RawFree(cur); cur = next; } } static void _xidregistry_lock(struct _xidregistry *registry) { if (registry->mutex != NULL) { PyThread_acquire_lock(registry->mutex, WAIT_LOCK); } } static void _xidregistry_unlock(struct _xidregistry *registry) { if (registry->mutex != NULL) { PyThread_release_lock(registry->mutex); } } static struct _xidregitem * _xidregistry_find_type(struct _xidregistry *xidregistry, PyTypeObject *cls) { struct _xidregitem *cur = xidregistry->head; while (cur != NULL) { if (cur->weakref != NULL) { // cur is/was a heap type. PyObject *registered = _PyWeakref_GET_REF(cur->weakref); if (registered == NULL) { // The weakly ref'ed object was freed. cur = _xidregistry_remove_entry(xidregistry, cur); continue; } assert(PyType_Check(registered)); assert(cur->cls == (PyTypeObject *)registered); assert(cur->cls->tp_flags & Py_TPFLAGS_HEAPTYPE); Py_DECREF(registered); } if (cur->cls == cls) { return cur; } cur = cur->next; } return NULL; } int _PyCrossInterpreterData_RegisterClass(PyTypeObject *cls, crossinterpdatafunc getdata) { if (!PyType_Check(cls)) { PyErr_Format(PyExc_ValueError, "only classes may be registered"); return -1; } if (getdata == NULL) { PyErr_Format(PyExc_ValueError, "missing 'getdata' func"); return -1; } int res = 0; PyInterpreterState *interp = _PyInterpreterState_GET(); struct _xidregistry *xidregistry = _get_xidregistry_for_type(interp, cls); _xidregistry_lock(xidregistry); struct _xidregitem *matched = _xidregistry_find_type(xidregistry, cls); if (matched != NULL) { assert(matched->getdata == getdata); matched->refcount += 1; goto finally; } res = _xidregistry_add_type(xidregistry, cls, getdata); finally: _xidregistry_unlock(xidregistry); return res; } int _PyCrossInterpreterData_UnregisterClass(PyTypeObject *cls) { int res = 0; PyInterpreterState *interp = _PyInterpreterState_GET(); struct _xidregistry *xidregistry = _get_xidregistry_for_type(interp, cls); _xidregistry_lock(xidregistry); struct _xidregitem *matched = _xidregistry_find_type(xidregistry, cls); if (matched != NULL) { assert(matched->refcount > 0); matched->refcount -= 1; if (matched->refcount == 0) { (void)_xidregistry_remove_entry(xidregistry, matched); } res = 1; } _xidregistry_unlock(xidregistry); return res; } static crossinterpdatafunc _lookup_getdata_from_registry(PyInterpreterState *interp, PyObject *obj) { PyTypeObject *cls = Py_TYPE(obj); struct _xidregistry *xidregistry = _get_xidregistry_for_type(interp, cls); _xidregistry_lock(xidregistry); struct _xidregitem *matched = _xidregistry_find_type(xidregistry, cls); crossinterpdatafunc func = matched != NULL ? matched->getdata : NULL; _xidregistry_unlock(xidregistry); return func; } /* cross-interpreter data for builtin types */ // bytes struct _shared_bytes_data { char *bytes; Py_ssize_t len; }; static PyObject * _new_bytes_object(_PyCrossInterpreterData *data) { struct _shared_bytes_data *shared = (struct _shared_bytes_data *)(data->data); return PyBytes_FromStringAndSize(shared->bytes, shared->len); } static int _bytes_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { if (_PyCrossInterpreterData_InitWithSize( data, tstate->interp, sizeof(struct _shared_bytes_data), obj, _new_bytes_object ) < 0) { return -1; } struct _shared_bytes_data *shared = (struct _shared_bytes_data *)data->data; if (PyBytes_AsStringAndSize(obj, &shared->bytes, &shared->len) < 0) { _PyCrossInterpreterData_Clear(tstate->interp, data); return -1; } return 0; } // str struct _shared_str_data { int kind; const void *buffer; Py_ssize_t len; }; static PyObject * _new_str_object(_PyCrossInterpreterData *data) { struct _shared_str_data *shared = (struct _shared_str_data *)(data->data); return PyUnicode_FromKindAndData(shared->kind, shared->buffer, shared->len); } static int _str_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { if (_PyCrossInterpreterData_InitWithSize( data, tstate->interp, sizeof(struct _shared_str_data), obj, _new_str_object ) < 0) { return -1; } struct _shared_str_data *shared = (struct _shared_str_data *)data->data; shared->kind = PyUnicode_KIND(obj); shared->buffer = PyUnicode_DATA(obj); shared->len = PyUnicode_GET_LENGTH(obj); return 0; } // int static PyObject * _new_long_object(_PyCrossInterpreterData *data) { return PyLong_FromSsize_t((Py_ssize_t)(data->data)); } static int _long_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { /* Note that this means the size of shareable ints is bounded by * sys.maxsize. Hence on 32-bit architectures that is half the * size of maximum shareable ints on 64-bit. */ Py_ssize_t value = PyLong_AsSsize_t(obj); if (value == -1 && PyErr_Occurred()) { if (PyErr_ExceptionMatches(PyExc_OverflowError)) { PyErr_SetString(PyExc_OverflowError, "try sending as bytes"); } return -1; } _PyCrossInterpreterData_Init(data, tstate->interp, (void *)value, NULL, _new_long_object); // data->obj and data->free remain NULL return 0; } // float static PyObject * _new_float_object(_PyCrossInterpreterData *data) { double * value_ptr = data->data; return PyFloat_FromDouble(*value_ptr); } static int _float_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { if (_PyCrossInterpreterData_InitWithSize( data, tstate->interp, sizeof(double), NULL, _new_float_object ) < 0) { return -1; } double *shared = (double *)data->data; *shared = PyFloat_AsDouble(obj); return 0; } // None static PyObject * _new_none_object(_PyCrossInterpreterData *data) { // XXX Singleton refcounts are problematic across interpreters... return Py_NewRef(Py_None); } static int _none_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { _PyCrossInterpreterData_Init(data, tstate->interp, NULL, NULL, _new_none_object); // data->data, data->obj and data->free remain NULL return 0; } // bool static PyObject * _new_bool_object(_PyCrossInterpreterData *data) { if (data->data){ Py_RETURN_TRUE; } Py_RETURN_FALSE; } static int _bool_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { _PyCrossInterpreterData_Init(data, tstate->interp, (void *) (Py_IsTrue(obj) ? (uintptr_t) 1 : (uintptr_t) 0), NULL, _new_bool_object); // data->obj and data->free remain NULL return 0; } // tuple struct _shared_tuple_data { Py_ssize_t len; _PyCrossInterpreterData **data; }; static PyObject * _new_tuple_object(_PyCrossInterpreterData *data) { struct _shared_tuple_data *shared = (struct _shared_tuple_data *)(data->data); PyObject *tuple = PyTuple_New(shared->len); if (tuple == NULL) { return NULL; } for (Py_ssize_t i = 0; i < shared->len; i++) { PyObject *item = _PyCrossInterpreterData_NewObject(shared->data[i]); if (item == NULL){ Py_DECREF(tuple); return NULL; } PyTuple_SET_ITEM(tuple, i, item); } return tuple; } static void _tuple_shared_free(void* data) { struct _shared_tuple_data *shared = (struct _shared_tuple_data *)(data); #ifndef NDEBUG int64_t interpid = PyInterpreterState_GetID(_PyInterpreterState_GET()); #endif for (Py_ssize_t i = 0; i < shared->len; i++) { if (shared->data[i] != NULL) { assert(shared->data[i]->interpid == interpid); _PyCrossInterpreterData_Release(shared->data[i]); PyMem_RawFree(shared->data[i]); shared->data[i] = NULL; } } PyMem_Free(shared->data); PyMem_RawFree(shared); } static int _tuple_shared(PyThreadState *tstate, PyObject *obj, _PyCrossInterpreterData *data) { Py_ssize_t len = PyTuple_GET_SIZE(obj); if (len < 0) { return -1; } struct _shared_tuple_data *shared = PyMem_RawMalloc(sizeof(struct _shared_tuple_data)); if (shared == NULL){ PyErr_NoMemory(); return -1; } shared->len = len; shared->data = (_PyCrossInterpreterData **) PyMem_Calloc(shared->len, sizeof(_PyCrossInterpreterData *)); if (shared->data == NULL) { PyErr_NoMemory(); return -1; } for (Py_ssize_t i = 0; i < shared->len; i++) { _PyCrossInterpreterData *data = _PyCrossInterpreterData_New(); if (data == NULL) { goto error; // PyErr_NoMemory already set } PyObject *item = PyTuple_GET_ITEM(obj, i); int res = -1; if (!_Py_EnterRecursiveCallTstate(tstate, " while sharing a tuple")) { res = _PyObject_GetCrossInterpreterData(item, data); _Py_LeaveRecursiveCallTstate(tstate); } if (res < 0) { PyMem_RawFree(data); goto error; } shared->data[i] = data; } _PyCrossInterpreterData_Init( data, tstate->interp, shared, obj, _new_tuple_object); data->free = _tuple_shared_free; return 0; error: _tuple_shared_free(shared); return -1; } // registration static void _register_builtins_for_crossinterpreter_data(struct _xidregistry *xidregistry) { // None if (_xidregistry_add_type(xidregistry, (PyTypeObject *)PyObject_Type(Py_None), _none_shared) != 0) { Py_FatalError("could not register None for cross-interpreter sharing"); } // int if (_xidregistry_add_type(xidregistry, &PyLong_Type, _long_shared) != 0) { Py_FatalError("could not register int for cross-interpreter sharing"); } // bytes if (_xidregistry_add_type(xidregistry, &PyBytes_Type, _bytes_shared) != 0) { Py_FatalError("could not register bytes for cross-interpreter sharing"); } // str if (_xidregistry_add_type(xidregistry, &PyUnicode_Type, _str_shared) != 0) { Py_FatalError("could not register str for cross-interpreter sharing"); } // bool if (_xidregistry_add_type(xidregistry, &PyBool_Type, _bool_shared) != 0) { Py_FatalError("could not register bool for cross-interpreter sharing"); } // float if (_xidregistry_add_type(xidregistry, &PyFloat_Type, _float_shared) != 0) { Py_FatalError("could not register float for cross-interpreter sharing"); } // tuple if (_xidregistry_add_type(xidregistry, &PyTuple_Type, _tuple_shared) != 0) { Py_FatalError("could not register tuple for cross-interpreter sharing"); } } /* registry lifecycle */ static void _xidregistry_init(struct _xidregistry *registry) { if (registry->initialized) { return; } registry->initialized = 1; if (registry->global) { // We manage the mutex lifecycle in pystate.c. assert(registry->mutex != NULL); // Registering the builtins is cheap so we don't bother doing it lazily. assert(registry->head == NULL); _register_builtins_for_crossinterpreter_data(registry); } else { // Within an interpreter we rely on the GIL instead of a separate lock. assert(registry->mutex == NULL); // There's nothing else to initialize. } } static void _xidregistry_fini(struct _xidregistry *registry) { if (!registry->initialized) { return; } registry->initialized = 0; _xidregistry_clear(registry); if (registry->global) { // We manage the mutex lifecycle in pystate.c. assert(registry->mutex != NULL); } else { // There's nothing else to finalize. // Within an interpreter we rely on the GIL instead of a separate lock. assert(registry->mutex == NULL); } } /*************************/ /* convenience utilities */ /*************************/ static const char * _copy_string_obj_raw(PyObject *strobj) { const char *str = PyUnicode_AsUTF8(strobj); if (str == NULL) { return NULL; } char *copied = PyMem_RawMalloc(strlen(str)+1); if (copied == NULL) { PyErr_NoMemory(); return NULL; } strcpy(copied, str); return copied; } static int _release_xid_data(_PyCrossInterpreterData *data, int rawfree) { PyObject *exc = PyErr_GetRaisedException(); int res = rawfree ? _PyCrossInterpreterData_Release(data) : _PyCrossInterpreterData_ReleaseAndRawFree(data); if (res < 0) { /* The owning interpreter is already destroyed. */ _PyCrossInterpreterData_Clear(NULL, data); // XXX Emit a warning? PyErr_Clear(); } PyErr_SetRaisedException(exc); return res; } /***********************/ /* exception snapshots */ /***********************/ static int _excinfo_init_type(struct _excinfo_type *info, PyObject *exc) { /* Note that this copies directly rather than into an intermediate struct and does not clear on error. If we need that then we should have a separate function to wrap this one and do all that there. */ PyObject *strobj = NULL; PyTypeObject *type = Py_TYPE(exc); if (type->tp_flags & _Py_TPFLAGS_STATIC_BUILTIN) { assert(_Py_IsImmortal((PyObject *)type)); info->builtin = type; } else { // Only builtin types are preserved. info->builtin = NULL; } // __name__ strobj = PyType_GetName(type); if (strobj == NULL) { return -1; } info->name = _copy_string_obj_raw(strobj); Py_DECREF(strobj); if (info->name == NULL) { return -1; } // __qualname__ strobj = PyType_GetQualName(type); if (strobj == NULL) { return -1; } info->qualname = _copy_string_obj_raw(strobj); Py_DECREF(strobj); if (info->name == NULL) { return -1; } // __module__ strobj = _PyType_GetModuleName(type); if (strobj == NULL) { return -1; } info->module = _copy_string_obj_raw(strobj); Py_DECREF(strobj); if (info->name == NULL) { return -1; } return 0; } static void _excinfo_clear_type(struct _excinfo_type *info) { if (info->builtin != NULL) { assert(info->builtin->tp_flags & _Py_TPFLAGS_STATIC_BUILTIN); assert(_Py_IsImmortal((PyObject *)info->builtin)); } if (info->name != NULL) { PyMem_RawFree((void *)info->name); } if (info->qualname != NULL) { PyMem_RawFree((void *)info->qualname); } if (info->module != NULL) { PyMem_RawFree((void *)info->module); } *info = (struct _excinfo_type){NULL}; } static void _excinfo_normalize_type(struct _excinfo_type *info, const char **p_module, const char **p_qualname) { if (info->name == NULL) { assert(info->builtin == NULL); assert(info->qualname == NULL); assert(info->module == NULL); // This is inspired by TracebackException.format_exception_only(). *p_module = NULL; *p_qualname = NULL; return; } const char *module = info->module; const char *qualname = info->qualname; if (qualname == NULL) { qualname = info->name; } assert(module != NULL); if (strcmp(module, "builtins") == 0) { module = NULL; } else if (strcmp(module, "__main__") == 0) { module = NULL; } *p_qualname = qualname; *p_module = module; } static void _PyXI_excinfo_Clear(_PyXI_excinfo *info) { _excinfo_clear_type(&info->type); if (info->msg != NULL) { PyMem_RawFree((void *)info->msg); } *info = (_PyXI_excinfo){{NULL}}; } static PyObject * _PyXI_excinfo_format(_PyXI_excinfo *info) { const char *module, *qualname; _excinfo_normalize_type(&info->type, &module, &qualname); if (qualname != NULL) { if (module != NULL) { if (info->msg != NULL) { return PyUnicode_FromFormat("%s.%s: %s", module, qualname, info->msg); } else { return PyUnicode_FromFormat("%s.%s", module, qualname); } } else { if (info->msg != NULL) { return PyUnicode_FromFormat("%s: %s", qualname, info->msg); } else { return PyUnicode_FromString(qualname); } } } else if (info->msg != NULL) { return PyUnicode_FromString(info->msg); } else { Py_RETURN_NONE; } } static const char * _PyXI_excinfo_InitFromException(_PyXI_excinfo *info, PyObject *exc) { assert(exc != NULL); if (PyErr_GivenExceptionMatches(exc, PyExc_MemoryError)) { _PyXI_excinfo_Clear(info); return NULL; } const char *failure = NULL; if (_excinfo_init_type(&info->type, exc) < 0) { failure = "error while initializing exception type snapshot"; goto error; } // Extract the exception message. PyObject *msgobj = PyObject_Str(exc); if (msgobj == NULL) { failure = "error while formatting exception"; goto error; } info->msg = _copy_string_obj_raw(msgobj); Py_DECREF(msgobj); if (info->msg == NULL) { failure = "error while copying exception message"; goto error; } return NULL; error: assert(failure != NULL); _PyXI_excinfo_Clear(info); return failure; } static void _PyXI_excinfo_Apply(_PyXI_excinfo *info, PyObject *exctype) { PyObject *formatted = _PyXI_excinfo_format(info); PyErr_SetObject(exctype, formatted); Py_DECREF(formatted); } static PyObject * _PyXI_excinfo_TypeAsObject(_PyXI_excinfo *info) { PyObject *ns = _PyNamespace_New(NULL); if (ns == NULL) { return NULL; } int empty = 1; if (info->type.name != NULL) { PyObject *name = PyUnicode_FromString(info->type.name); if (name == NULL) { goto error; } int res = PyObject_SetAttrString(ns, "__name__", name); Py_DECREF(name); if (res < 0) { goto error; } empty = 0; } if (info->type.qualname != NULL) { PyObject *qualname = PyUnicode_FromString(info->type.qualname); if (qualname == NULL) { goto error; } int res = PyObject_SetAttrString(ns, "__qualname__", qualname); Py_DECREF(qualname); if (res < 0) { goto error; } empty = 0; } if (info->type.module != NULL) { PyObject *module = PyUnicode_FromString(info->type.module); if (module == NULL) { goto error; } int res = PyObject_SetAttrString(ns, "__module__", module); Py_DECREF(module); if (res < 0) { goto error; } empty = 0; } if (empty) { Py_CLEAR(ns); } return ns; error: Py_DECREF(ns); return NULL; } static PyObject * _PyXI_excinfo_AsObject(_PyXI_excinfo *info) { PyObject *ns = _PyNamespace_New(NULL); if (ns == NULL) { return NULL; } int res; PyObject *type = _PyXI_excinfo_TypeAsObject(info); if (type == NULL) { if (PyErr_Occurred()) { goto error; } type = Py_NewRef(Py_None); } res = PyObject_SetAttrString(ns, "type", type); Py_DECREF(type); if (res < 0) { goto error; } PyObject *msg = info->msg != NULL ? PyUnicode_FromString(info->msg) : Py_NewRef(Py_None); if (msg == NULL) { goto error; } res = PyObject_SetAttrString(ns, "msg", msg); Py_DECREF(msg); if (res < 0) { goto error; } PyObject *formatted = _PyXI_excinfo_format(info); if (formatted == NULL) { goto error; } res = PyObject_SetAttrString(ns, "formatted", formatted); Py_DECREF(formatted); if (res < 0) { goto error; } return ns; error: Py_DECREF(ns); return NULL; } /***************************/ /* short-term data sharing */ /***************************/ /* error codes */ static int _PyXI_ApplyErrorCode(_PyXI_errcode code, PyInterpreterState *interp) { assert(!PyErr_Occurred()); switch (code) { case _PyXI_ERR_NO_ERROR: // fall through case _PyXI_ERR_UNCAUGHT_EXCEPTION: // There is nothing to apply. #ifdef Py_DEBUG Py_UNREACHABLE(); #endif return 0; case _PyXI_ERR_OTHER: // XXX msg? PyErr_SetNone(PyExc_RuntimeError); break; case _PyXI_ERR_NO_MEMORY: PyErr_NoMemory(); break; case _PyXI_ERR_ALREADY_RUNNING: assert(interp != NULL); assert(_PyInterpreterState_IsRunningMain(interp)); _PyInterpreterState_FailIfRunningMain(interp); break; case _PyXI_ERR_MAIN_NS_FAILURE: PyErr_SetString(PyExc_RuntimeError, "failed to get __main__ namespace"); break; case _PyXI_ERR_APPLY_NS_FAILURE: PyErr_SetString(PyExc_RuntimeError, "failed to apply namespace to __main__"); break; case _PyXI_ERR_NOT_SHAREABLE: _set_xid_lookup_failure(interp, NULL, NULL); break; default: #ifdef Py_DEBUG Py_UNREACHABLE(); #else PyErr_Format(PyExc_RuntimeError, "unsupported error code %d", code); #endif } assert(PyErr_Occurred()); return -1; } /* shared exceptions */ static const char * _PyXI_InitError(_PyXI_error *error, PyObject *excobj, _PyXI_errcode code) { if (error->interp == NULL) { error->interp = PyInterpreterState_Get(); } const char *failure = NULL; if (code == _PyXI_ERR_UNCAUGHT_EXCEPTION) { // There is an unhandled exception we need to propagate. failure = _PyXI_excinfo_InitFromException(&error->uncaught, excobj); if (failure != NULL) { // We failed to initialize error->uncaught. // XXX Print the excobj/traceback? Emit a warning? // XXX Print the current exception/traceback? if (PyErr_ExceptionMatches(PyExc_MemoryError)) { error->code = _PyXI_ERR_NO_MEMORY; } else { error->code = _PyXI_ERR_OTHER; } PyErr_Clear(); } else { error->code = code; } assert(error->code != _PyXI_ERR_NO_ERROR); } else { // There is an error code we need to propagate. assert(excobj == NULL); assert(code != _PyXI_ERR_NO_ERROR); error->code = code; _PyXI_excinfo_Clear(&error->uncaught); } return failure; } PyObject * _PyXI_ApplyError(_PyXI_error *error) { if (error->code == _PyXI_ERR_UNCAUGHT_EXCEPTION) { // Raise an exception that proxies the propagated exception. return _PyXI_excinfo_AsObject(&error->uncaught); } else if (error->code == _PyXI_ERR_NOT_SHAREABLE) { // Propagate the exception directly. _set_xid_lookup_failure(error->interp, NULL, error->uncaught.msg); } else { // Raise an exception corresponding to the code. assert(error->code != _PyXI_ERR_NO_ERROR); (void)_PyXI_ApplyErrorCode(error->code, error->interp); if (error->uncaught.type.name != NULL || error->uncaught.msg != NULL) { // __context__ will be set to a proxy of the propagated exception. PyObject *exc = PyErr_GetRaisedException(); _PyXI_excinfo_Apply(&error->uncaught, PyExc_RuntimeError); PyObject *exc2 = PyErr_GetRaisedException(); PyException_SetContext(exc, exc2); PyErr_SetRaisedException(exc); } } assert(PyErr_Occurred()); return NULL; } /* shared namespaces */ /* Shared namespaces are expected to have relatively short lifetimes. This means dealloc of a shared namespace will normally happen "soon". Namespace items hold cross-interpreter data, which must get released. If the namespace/items are cleared in a different interpreter than where the items' cross-interpreter data was set then that will cause pending calls to be used to release the cross-interpreter data. The tricky bit is that the pending calls can happen sufficiently later that the namespace/items might already be deallocated. This is a problem if the cross-interpreter data is allocated as part of a namespace item. If that's the case then we must ensure the shared namespace is only cleared/freed *after* that data has been released. */ typedef struct _sharednsitem { const char *name; _PyCrossInterpreterData *data; // We could have a "PyCrossInterpreterData _data" field, so it would // be allocated as part of the item and avoid an extra allocation. // However, doing so adds a bunch of complexity because we must // ensure the item isn't freed before a pending call might happen // in a different interpreter to release the XI data. } _PyXI_namespace_item; static int _sharednsitem_is_initialized(_PyXI_namespace_item *item) { if (item->name != NULL) { return 1; } return 0; } static int _sharednsitem_init(_PyXI_namespace_item *item, PyObject *key) { item->name = _copy_string_obj_raw(key); if (item->name == NULL) { assert(!_sharednsitem_is_initialized(item)); return -1; } item->data = NULL; assert(_sharednsitem_is_initialized(item)); return 0; } static int _sharednsitem_has_value(_PyXI_namespace_item *item, int64_t *p_interpid) { if (item->data == NULL) { return 0; } if (p_interpid != NULL) { *p_interpid = item->data->interpid; } return 1; } static int _sharednsitem_set_value(_PyXI_namespace_item *item, PyObject *value) { assert(_sharednsitem_is_initialized(item)); assert(item->data == NULL); item->data = PyMem_RawMalloc(sizeof(_PyCrossInterpreterData)); if (item->data == NULL) { PyErr_NoMemory(); return -1; } if (_PyObject_GetCrossInterpreterData(value, item->data) != 0) { PyMem_RawFree(item->data); item->data = NULL; // The caller may want to propagate PyExc_NotShareableError // if currently switched between interpreters. return -1; } return 0; } static void _sharednsitem_clear_value(_PyXI_namespace_item *item) { _PyCrossInterpreterData *data = item->data; if (data != NULL) { item->data = NULL; int rawfree = 1; (void)_release_xid_data(data, rawfree); } } static void _sharednsitem_clear(_PyXI_namespace_item *item) { if (item->name != NULL) { PyMem_RawFree((void *)item->name); item->name = NULL; } _sharednsitem_clear_value(item); } static int _sharednsitem_copy_from_ns(struct _sharednsitem *item, PyObject *ns) { assert(item->name != NULL); assert(item->data == NULL); PyObject *value = PyDict_GetItemString(ns, item->name); // borrowed if (value == NULL) { if (PyErr_Occurred()) { return -1; } // When applied, this item will be set to the default (or fail). return 0; } if (_sharednsitem_set_value(item, value) < 0) { return -1; } return 0; } static int _sharednsitem_apply(_PyXI_namespace_item *item, PyObject *ns, PyObject *dflt) { PyObject *name = PyUnicode_FromString(item->name); if (name == NULL) { return -1; } PyObject *value; if (item->data != NULL) { value = _PyCrossInterpreterData_NewObject(item->data); if (value == NULL) { Py_DECREF(name); return -1; } } else { value = Py_NewRef(dflt); } int res = PyDict_SetItem(ns, name, value); Py_DECREF(name); Py_DECREF(value); return res; } struct _sharedns { Py_ssize_t len; _PyXI_namespace_item *items; }; static _PyXI_namespace * _sharedns_new(void) { _PyXI_namespace *ns = PyMem_RawCalloc(sizeof(_PyXI_namespace), 1); if (ns == NULL) { PyErr_NoMemory(); return NULL; } *ns = (_PyXI_namespace){ 0 }; return ns; } static int _sharedns_is_initialized(_PyXI_namespace *ns) { if (ns->len == 0) { assert(ns->items == NULL); return 0; } assert(ns->len > 0); assert(ns->items != NULL); assert(_sharednsitem_is_initialized(&ns->items[0])); assert(ns->len == 1 || _sharednsitem_is_initialized(&ns->items[ns->len - 1])); return 1; } #define HAS_COMPLETE_DATA 1 #define HAS_PARTIAL_DATA 2 static int _sharedns_has_xidata(_PyXI_namespace *ns, int64_t *p_interpid) { // We expect _PyXI_namespace to always be initialized. assert(_sharedns_is_initialized(ns)); int res = 0; _PyXI_namespace_item *item0 = &ns->items[0]; if (!_sharednsitem_is_initialized(item0)) { return 0; } int64_t interpid0 = -1; if (!_sharednsitem_has_value(item0, &interpid0)) { return 0; } if (ns->len > 1) { // At this point we know it is has at least partial data. _PyXI_namespace_item *itemN = &ns->items[ns->len-1]; if (!_sharednsitem_is_initialized(itemN)) { res = HAS_PARTIAL_DATA; goto finally; } int64_t interpidN = -1; if (!_sharednsitem_has_value(itemN, &interpidN)) { res = HAS_PARTIAL_DATA; goto finally; } assert(interpidN == interpid0); } res = HAS_COMPLETE_DATA; *p_interpid = interpid0; finally: return res; } static void _sharedns_clear(_PyXI_namespace *ns) { if (!_sharedns_is_initialized(ns)) { return; } // If the cross-interpreter data were allocated as part of // _PyXI_namespace_item (instead of dynamically), this is where // we would need verify that we are clearing the items in the // correct interpreter, to avoid a race with releasing the XI data // via a pending call. See _sharedns_has_xidata(). for (Py_ssize_t i=0; i < ns->len; i++) { _sharednsitem_clear(&ns->items[i]); } PyMem_RawFree(ns->items); ns->items = NULL; ns->len = 0; } static void _sharedns_free(_PyXI_namespace *ns) { _sharedns_clear(ns); PyMem_RawFree(ns); } static int _sharedns_init(_PyXI_namespace *ns, PyObject *names) { assert(!_sharedns_is_initialized(ns)); assert(names != NULL); Py_ssize_t len = PyDict_CheckExact(names) ? PyDict_Size(names) : PySequence_Size(names); if (len < 0) { return -1; } if (len == 0) { PyErr_SetString(PyExc_ValueError, "empty namespaces not allowed"); return -1; } assert(len > 0); // Allocate the items. _PyXI_namespace_item *items = PyMem_RawCalloc(sizeof(struct _sharednsitem), len); if (items == NULL) { PyErr_NoMemory(); return -1; } // Fill in the names. Py_ssize_t i = -1; if (PyDict_CheckExact(names)) { Py_ssize_t pos = 0; for (i=0; i < len; i++) { PyObject *key; if (!PyDict_Next(names, &pos, &key, NULL)) { // This should not be possible. assert(0); goto error; } if (_sharednsitem_init(&items[i], key) < 0) { goto error; } } } else if (PySequence_Check(names)) { for (i=0; i < len; i++) { PyObject *key = PySequence_GetItem(names, i); if (key == NULL) { goto error; } int res = _sharednsitem_init(&items[i], key); Py_DECREF(key); if (res < 0) { goto error; } } } else { PyErr_SetString(PyExc_NotImplementedError, "non-sequence namespace not supported"); goto error; } ns->items = items; ns->len = len; assert(_sharedns_is_initialized(ns)); return 0; error: for (Py_ssize_t j=0; j < i; j++) { _sharednsitem_clear(&items[j]); } PyMem_RawFree(items); assert(!_sharedns_is_initialized(ns)); return -1; } void _PyXI_FreeNamespace(_PyXI_namespace *ns) { if (!_sharedns_is_initialized(ns)) { return; } int64_t interpid = -1; if (!_sharedns_has_xidata(ns, &interpid)) { _sharedns_free(ns); return; } if (interpid == PyInterpreterState_GetID(_PyInterpreterState_GET())) { _sharedns_free(ns); } else { // If we weren't always dynamically allocating the cross-interpreter // data in each item then we would need to using a pending call // to call _sharedns_free(), to avoid the race between freeing // the shared namespace and releasing the XI data. _sharedns_free(ns); } } _PyXI_namespace * _PyXI_NamespaceFromNames(PyObject *names) { if (names == NULL || names == Py_None) { return NULL; } _PyXI_namespace *ns = _sharedns_new(); if (ns == NULL) { return NULL; } if (_sharedns_init(ns, names) < 0) { PyMem_RawFree(ns); if (PySequence_Size(names) == 0) { PyErr_Clear(); } return NULL; } return ns; } #ifndef NDEBUG static int _session_is_active(_PyXI_session *); #endif static void _propagate_not_shareable_error(_PyXI_session *); int _PyXI_FillNamespaceFromDict(_PyXI_namespace *ns, PyObject *nsobj, _PyXI_session *session) { // session must be entered already, if provided. assert(session == NULL || _session_is_active(session)); assert(_sharedns_is_initialized(ns)); for (Py_ssize_t i=0; i < ns->len; i++) { _PyXI_namespace_item *item = &ns->items[i]; if (_sharednsitem_copy_from_ns(item, nsobj) < 0) { _propagate_not_shareable_error(session); // Clear out the ones we set so far. for (Py_ssize_t j=0; j < i; j++) { _sharednsitem_clear_value(&ns->items[j]); } return -1; } } return 0; } // All items are expected to be shareable. static _PyXI_namespace * _PyXI_NamespaceFromDict(PyObject *nsobj, _PyXI_session *session) { // session must be entered already, if provided. assert(session == NULL || _session_is_active(session)); if (nsobj == NULL || nsobj == Py_None) { return NULL; } if (!PyDict_CheckExact(nsobj)) { PyErr_SetString(PyExc_TypeError, "expected a dict"); return NULL; } _PyXI_namespace *ns = _sharedns_new(); if (ns == NULL) { return NULL; } if (_sharedns_init(ns, nsobj) < 0) { if (PyDict_Size(nsobj) == 0) { PyMem_RawFree(ns); PyErr_Clear(); return NULL; } goto error; } if (_PyXI_FillNamespaceFromDict(ns, nsobj, session) < 0) { goto error; } return ns; error: assert(PyErr_Occurred() || (session != NULL && session->error_override != NULL)); _sharedns_free(ns); return NULL; } int _PyXI_ApplyNamespace(_PyXI_namespace *ns, PyObject *nsobj, PyObject *dflt) { for (Py_ssize_t i=0; i < ns->len; i++) { if (_sharednsitem_apply(&ns->items[i], nsobj, dflt) != 0) { return -1; } } return 0; } /**********************/ /* high-level helpers */ /**********************/ /* enter/exit a cross-interpreter session */ static void _enter_session(_PyXI_session *session, PyInterpreterState *interp) { // Set here and cleared in _exit_session(). assert(!session->own_init_tstate); assert(session->init_tstate == NULL); assert(session->prev_tstate == NULL); // Set elsewhere and cleared in _exit_session(). assert(!session->running); assert(session->main_ns == NULL); // Set elsewhere and cleared in _capture_current_exception(). assert(session->error_override == NULL); // Set elsewhere and cleared in _PyXI_ApplyCapturedException(). assert(session->error == NULL); // Switch to interpreter. PyThreadState *tstate = PyThreadState_Get(); PyThreadState *prev = tstate; if (interp != tstate->interp) { tstate = PyThreadState_New(interp); tstate->_whence = _PyThreadState_WHENCE_EXEC; // XXX Possible GILState issues? session->prev_tstate = PyThreadState_Swap(tstate); assert(session->prev_tstate == prev); session->own_init_tstate = 1; } session->init_tstate = tstate; session->prev_tstate = prev; } static void _exit_session(_PyXI_session *session) { PyThreadState *tstate = session->init_tstate; assert(tstate != NULL); assert(PyThreadState_Get() == tstate); // Release any of the entered interpreters resources. if (session->main_ns != NULL) { Py_CLEAR(session->main_ns); } // Ensure this thread no longer owns __main__. if (session->running) { _PyInterpreterState_SetNotRunningMain(tstate->interp); assert(!PyErr_Occurred()); session->running = 0; } // Switch back. assert(session->prev_tstate != NULL); if (session->prev_tstate != session->init_tstate) { assert(session->own_init_tstate); session->own_init_tstate = 0; PyThreadState_Clear(tstate); PyThreadState_Swap(session->prev_tstate); PyThreadState_Delete(tstate); } else { assert(!session->own_init_tstate); } session->prev_tstate = NULL; session->init_tstate = NULL; } #ifndef NDEBUG static int _session_is_active(_PyXI_session *session) { return (session->init_tstate != NULL); } #endif static void _propagate_not_shareable_error(_PyXI_session *session) { if (session == NULL) { return; } PyInterpreterState *interp = _PyInterpreterState_GET(); if (PyErr_ExceptionMatches(_get_not_shareable_error_type(interp))) { // We want to propagate the exception directly. session->_error_override = _PyXI_ERR_NOT_SHAREABLE; session->error_override = &session->_error_override; } } static void _capture_current_exception(_PyXI_session *session) { assert(session->error == NULL); if (!PyErr_Occurred()) { assert(session->error_override == NULL); return; } // Handle the exception override. _PyXI_errcode *override = session->error_override; session->error_override = NULL; _PyXI_errcode errcode = override != NULL ? *override : _PyXI_ERR_UNCAUGHT_EXCEPTION; // Pop the exception object. PyObject *excval = NULL; if (errcode == _PyXI_ERR_UNCAUGHT_EXCEPTION) { // We want to actually capture the current exception. excval = PyErr_GetRaisedException(); } else if (errcode == _PyXI_ERR_ALREADY_RUNNING) { // We don't need the exception info. PyErr_Clear(); } else { // We could do a variety of things here, depending on errcode. // However, for now we simply capture the exception and save // the errcode. excval = PyErr_GetRaisedException(); } // Capture the exception. _PyXI_error *err = &session->_error; *err = (_PyXI_error){ .interp = session->init_tstate->interp, }; const char *failure; if (excval == NULL) { failure = _PyXI_InitError(err, NULL, errcode); } else { failure = _PyXI_InitError(err, excval, _PyXI_ERR_UNCAUGHT_EXCEPTION); if (failure == NULL && override != NULL) { err->code = errcode; } } // Handle capture failure. if (failure != NULL) { // XXX Make this error message more generic. fprintf(stderr, "RunFailedError: script raised an uncaught exception (%s)", failure); err = NULL; } // a temporary hack (famous last words) if (excval != NULL) { // XXX Store the traceback info (or rendered traceback) on // _PyXI_excinfo, attach it to the exception when applied, // and teach PyErr_Display() to print it. #ifdef Py_DEBUG // XXX Drop this once _Py_excinfo picks up the slack. PyErr_Display(NULL, excval, NULL); #endif Py_DECREF(excval); } // Finished! assert(!PyErr_Occurred()); session->error = err; } PyObject * _PyXI_ApplyCapturedException(_PyXI_session *session) { assert(!PyErr_Occurred()); assert(session->error != NULL); PyObject *res = _PyXI_ApplyError(session->error); assert((res == NULL) != (PyErr_Occurred() == NULL)); session->error = NULL; return res; } int _PyXI_HasCapturedException(_PyXI_session *session) { return session->error != NULL; } int _PyXI_Enter(_PyXI_session *session, PyInterpreterState *interp, PyObject *nsupdates) { // Convert the attrs for cross-interpreter use. _PyXI_namespace *sharedns = NULL; if (nsupdates != NULL) { sharedns = _PyXI_NamespaceFromDict(nsupdates, NULL); if (sharedns == NULL && PyErr_Occurred()) { assert(session->error == NULL); return -1; } } // Switch to the requested interpreter (if necessary). _enter_session(session, interp); _PyXI_errcode errcode = _PyXI_ERR_UNCAUGHT_EXCEPTION; // Ensure this thread owns __main__. if (_PyInterpreterState_SetRunningMain(interp) < 0) { // In the case where we didn't switch interpreters, it would // be more efficient to leave the exception in place and return // immediately. However, life is simpler if we don't. errcode = _PyXI_ERR_ALREADY_RUNNING; goto error; } session->running = 1; // Cache __main__.__dict__. PyObject *main_mod = PyUnstable_InterpreterState_GetMainModule(interp); if (main_mod == NULL) { errcode = _PyXI_ERR_MAIN_NS_FAILURE; goto error; } PyObject *ns = PyModule_GetDict(main_mod); // borrowed Py_DECREF(main_mod); if (ns == NULL) { errcode = _PyXI_ERR_MAIN_NS_FAILURE; goto error; } session->main_ns = Py_NewRef(ns); // Apply the cross-interpreter data. if (sharedns != NULL) { if (_PyXI_ApplyNamespace(sharedns, ns, NULL) < 0) { errcode = _PyXI_ERR_APPLY_NS_FAILURE; goto error; } _PyXI_FreeNamespace(sharedns); } errcode = _PyXI_ERR_NO_ERROR; assert(!PyErr_Occurred()); return 0; error: assert(PyErr_Occurred()); // We want to propagate all exceptions here directly (best effort). assert(errcode != _PyXI_ERR_UNCAUGHT_EXCEPTION); session->error_override = &errcode; _capture_current_exception(session); _exit_session(session); if (sharedns != NULL) { _PyXI_FreeNamespace(sharedns); } return -1; } void _PyXI_Exit(_PyXI_session *session) { _capture_current_exception(session); _exit_session(session); } /*********************/ /* runtime lifecycle */ /*********************/ PyStatus _PyXI_Init(PyInterpreterState *interp) { PyStatus status; // Initialize the XID registry. if (_Py_IsMainInterpreter(interp)) { _xidregistry_init(_get_global_xidregistry(interp->runtime)); } _xidregistry_init(_get_xidregistry(interp)); // Initialize exceptions (heap types). status = _init_not_shareable_error_type(interp); if (_PyStatus_EXCEPTION(status)) { return status; } return _PyStatus_OK(); } // _PyXI_Fini() must be called before the interpreter is cleared, // since we must clear some heap objects. void _PyXI_Fini(PyInterpreterState *interp) { // Finalize exceptions (heap types). _fini_not_shareable_error_type(interp); // Finalize the XID registry. _xidregistry_fini(_get_xidregistry(interp)); if (_Py_IsMainInterpreter(interp)) { _xidregistry_fini(_get_global_xidregistry(interp->runtime)); } }