/* Type object implementation */ #include "Python.h" #include "structmember.h" #include static PyMemberDef type_members[] = { {"__basicsize__", T_INT, offsetof(PyTypeObject,tp_basicsize),READONLY}, {"__itemsize__", T_INT, offsetof(PyTypeObject, tp_itemsize), READONLY}, {"__flags__", T_LONG, offsetof(PyTypeObject, tp_flags), READONLY}, {"__weakrefoffset__", T_LONG, offsetof(PyTypeObject, tp_weaklistoffset), READONLY}, {"__base__", T_OBJECT, offsetof(PyTypeObject, tp_base), READONLY}, {"__dictoffset__", T_LONG, offsetof(PyTypeObject, tp_dictoffset), READONLY}, {"__mro__", T_OBJECT, offsetof(PyTypeObject, tp_mro), READONLY}, {0} }; static PyObject * type_name(PyTypeObject *type, void *context) { const char *s; if (type->tp_flags & Py_TPFLAGS_HEAPTYPE) { PyHeapTypeObject* et = (PyHeapTypeObject*)type; Py_INCREF(et->name); return et->name; } else { s = strrchr(type->tp_name, '.'); if (s == NULL) s = type->tp_name; else s++; return PyString_FromString(s); } } static int type_set_name(PyTypeObject *type, PyObject *value, void *context) { PyHeapTypeObject* et; if (!(type->tp_flags & Py_TPFLAGS_HEAPTYPE)) { PyErr_Format(PyExc_TypeError, "can't set %s.__name__", type->tp_name); return -1; } if (!value) { PyErr_Format(PyExc_TypeError, "can't delete %s.__name__", type->tp_name); return -1; } if (!PyString_Check(value)) { PyErr_Format(PyExc_TypeError, "can only assign string to %s.__name__, not '%s'", type->tp_name, value->ob_type->tp_name); return -1; } if (strlen(PyString_AS_STRING(value)) != (size_t)PyString_GET_SIZE(value)) { PyErr_Format(PyExc_ValueError, "__name__ must not contain null bytes"); return -1; } et = (PyHeapTypeObject*)type; Py_INCREF(value); Py_DECREF(et->name); et->name = value; type->tp_name = PyString_AS_STRING(value); return 0; } static PyObject * type_module(PyTypeObject *type, void *context) { PyObject *mod; char *s; if (type->tp_flags & Py_TPFLAGS_HEAPTYPE) { mod = PyDict_GetItemString(type->tp_dict, "__module__"); if (!mod) { PyErr_Format(PyExc_AttributeError, "__module__"); return 0; } Py_XINCREF(mod); return mod; } else { s = strrchr(type->tp_name, '.'); if (s != NULL) return PyString_FromStringAndSize( type->tp_name, (int)(s - type->tp_name)); return PyString_FromString("__builtin__"); } } static int type_set_module(PyTypeObject *type, PyObject *value, void *context) { if (!(type->tp_flags & Py_TPFLAGS_HEAPTYPE)) { PyErr_Format(PyExc_TypeError, "can't set %s.__module__", type->tp_name); return -1; } if (!value) { PyErr_Format(PyExc_TypeError, "can't delete %s.__module__", type->tp_name); return -1; } return PyDict_SetItemString(type->tp_dict, "__module__", value); } static PyObject * type_get_bases(PyTypeObject *type, void *context) { Py_INCREF(type->tp_bases); return type->tp_bases; } static PyTypeObject *best_base(PyObject *); static int mro_internal(PyTypeObject *); static int compatible_for_assignment(PyTypeObject *, PyTypeObject *, char *); static int add_subclass(PyTypeObject*, PyTypeObject*); static void remove_subclass(PyTypeObject *, PyTypeObject *); static void update_all_slots(PyTypeObject *); typedef int (*update_callback)(PyTypeObject *, void *); static int update_subclasses(PyTypeObject *type, PyObject *name, update_callback callback, void *data); static int recurse_down_subclasses(PyTypeObject *type, PyObject *name, update_callback callback, void *data); static int mro_subclasses(PyTypeObject *type, PyObject* temp) { PyTypeObject *subclass; PyObject *ref, *subclasses, *old_mro; int i, n; subclasses = type->tp_subclasses; if (subclasses == NULL) return 0; assert(PyList_Check(subclasses)); n = PyList_GET_SIZE(subclasses); for (i = 0; i < n; i++) { ref = PyList_GET_ITEM(subclasses, i); assert(PyWeakref_CheckRef(ref)); subclass = (PyTypeObject *)PyWeakref_GET_OBJECT(ref); assert(subclass != NULL); if ((PyObject *)subclass == Py_None) continue; assert(PyType_Check(subclass)); old_mro = subclass->tp_mro; if (mro_internal(subclass) < 0) { subclass->tp_mro = old_mro; return -1; } else { PyObject* tuple; tuple = PyTuple_Pack(2, subclass, old_mro); Py_DECREF(old_mro); if (!tuple) return -1; if (PyList_Append(temp, tuple) < 0) return -1; Py_DECREF(tuple); } if (mro_subclasses(subclass, temp) < 0) return -1; } return 0; } static int type_set_bases(PyTypeObject *type, PyObject *value, void *context) { int i, r = 0; PyObject *ob, *temp; PyTypeObject *new_base, *old_base; PyObject *old_bases, *old_mro; if (!(type->tp_flags & Py_TPFLAGS_HEAPTYPE)) { PyErr_Format(PyExc_TypeError, "can't set %s.__bases__", type->tp_name); return -1; } if (!value) { PyErr_Format(PyExc_TypeError, "can't delete %s.__bases__", type->tp_name); return -1; } if (!PyTuple_Check(value)) { PyErr_Format(PyExc_TypeError, "can only assign tuple to %s.__bases__, not %s", type->tp_name, value->ob_type->tp_name); return -1; } if (PyTuple_GET_SIZE(value) == 0) { PyErr_Format(PyExc_TypeError, "can only assign non-empty tuple to %s.__bases__, not ()", type->tp_name); return -1; } for (i = 0; i < PyTuple_GET_SIZE(value); i++) { ob = PyTuple_GET_ITEM(value, i); if (!PyClass_Check(ob) && !PyType_Check(ob)) { PyErr_Format( PyExc_TypeError, "%s.__bases__ must be tuple of old- or new-style classes, not '%s'", type->tp_name, ob->ob_type->tp_name); return -1; } if (PyType_Check(ob)) { if (PyType_IsSubtype((PyTypeObject*)ob, type)) { PyErr_SetString(PyExc_TypeError, "a __bases__ item causes an inheritance cycle"); return -1; } } } new_base = best_base(value); if (!new_base) { return -1; } if (!compatible_for_assignment(type->tp_base, new_base, "__bases__")) return -1; Py_INCREF(new_base); Py_INCREF(value); old_bases = type->tp_bases; old_base = type->tp_base; old_mro = type->tp_mro; type->tp_bases = value; type->tp_base = new_base; if (mro_internal(type) < 0) { goto bail; } temp = PyList_New(0); if (!temp) goto bail; r = mro_subclasses(type, temp); if (r < 0) { for (i = 0; i < PyList_Size(temp); i++) { PyTypeObject* cls; PyObject* mro; PyArg_UnpackTuple(PyList_GET_ITEM(temp, i), "", 2, 2, &cls, &mro); Py_DECREF(cls->tp_mro); cls->tp_mro = mro; Py_INCREF(cls->tp_mro); } Py_DECREF(temp); goto bail; } Py_DECREF(temp); /* any base that was in __bases__ but now isn't, we need to remove |type| from its tp_subclasses. conversely, any class now in __bases__ that wasn't needs to have |type| added to its subclasses. */ /* for now, sod that: just remove from all old_bases, add to all new_bases */ for (i = PyTuple_GET_SIZE(old_bases) - 1; i >= 0; i--) { ob = PyTuple_GET_ITEM(old_bases, i); if (PyType_Check(ob)) { remove_subclass( (PyTypeObject*)ob, type); } } for (i = PyTuple_GET_SIZE(value) - 1; i >= 0; i--) { ob = PyTuple_GET_ITEM(value, i); if (PyType_Check(ob)) { if (add_subclass((PyTypeObject*)ob, type) < 0) r = -1; } } update_all_slots(type); Py_DECREF(old_bases); Py_DECREF(old_base); Py_DECREF(old_mro); return r; bail: Py_DECREF(type->tp_bases); Py_DECREF(type->tp_base); if (type->tp_mro != old_mro) { Py_DECREF(type->tp_mro); } type->tp_bases = old_bases; type->tp_base = old_base; type->tp_mro = old_mro; return -1; } static PyObject * type_dict(PyTypeObject *type, void *context) { if (type->tp_dict == NULL) { Py_INCREF(Py_None); return Py_None; } return PyDictProxy_New(type->tp_dict); } static PyObject * type_get_doc(PyTypeObject *type, void *context) { PyObject *result; if (!(type->tp_flags & Py_TPFLAGS_HEAPTYPE) && type->tp_doc != NULL) return PyString_FromString(type->tp_doc); result = PyDict_GetItemString(type->tp_dict, "__doc__"); if (result == NULL) { result = Py_None; Py_INCREF(result); } else if (result->ob_type->tp_descr_get) { result = result->ob_type->tp_descr_get(result, NULL, (PyObject *)type); } else { Py_INCREF(result); } return result; } static PyGetSetDef type_getsets[] = { {"__name__", (getter)type_name, (setter)type_set_name, NULL}, {"__bases__", (getter)type_get_bases, (setter)type_set_bases, NULL}, {"__module__", (getter)type_module, (setter)type_set_module, NULL}, {"__dict__", (getter)type_dict, NULL, NULL}, {"__doc__", (getter)type_get_doc, NULL, NULL}, {0} }; static int type_compare(PyObject *v, PyObject *w) { /* This is called with type objects only. So we can just compare the addresses. */ Py_uintptr_t vv = (Py_uintptr_t)v; Py_uintptr_t ww = (Py_uintptr_t)w; return (vv < ww) ? -1 : (vv > ww) ? 1 : 0; } static PyObject * type_repr(PyTypeObject *type) { PyObject *mod, *name, *rtn; char *kind; mod = type_module(type, NULL); if (mod == NULL) PyErr_Clear(); else if (!PyString_Check(mod)) { Py_DECREF(mod); mod = NULL; } name = type_name(type, NULL); if (name == NULL) return NULL; if (type->tp_flags & Py_TPFLAGS_HEAPTYPE) kind = "class"; else kind = "type"; if (mod != NULL && strcmp(PyString_AS_STRING(mod), "__builtin__")) { rtn = PyString_FromFormat("<%s '%s.%s'>", kind, PyString_AS_STRING(mod), PyString_AS_STRING(name)); } else rtn = PyString_FromFormat("<%s '%s'>", kind, type->tp_name); Py_XDECREF(mod); Py_DECREF(name); return rtn; } static PyObject * type_call(PyTypeObject *type, PyObject *args, PyObject *kwds) { PyObject *obj; if (type->tp_new == NULL) { PyErr_Format(PyExc_TypeError, "cannot create '%.100s' instances", type->tp_name); return NULL; } obj = type->tp_new(type, args, kwds); if (obj != NULL) { /* Ugly exception: when the call was type(something), don't call tp_init on the result. */ if (type == &PyType_Type && PyTuple_Check(args) && PyTuple_GET_SIZE(args) == 1 && (kwds == NULL || (PyDict_Check(kwds) && PyDict_Size(kwds) == 0))) return obj; /* If the returned object is not an instance of type, it won't be initialized. */ if (!PyType_IsSubtype(obj->ob_type, type)) return obj; type = obj->ob_type; if (PyType_HasFeature(type, Py_TPFLAGS_HAVE_CLASS) && type->tp_init != NULL && type->tp_init(obj, args, kwds) < 0) { Py_DECREF(obj); obj = NULL; } } return obj; } PyObject * PyType_GenericAlloc(PyTypeObject *type, int nitems) { PyObject *obj; const size_t size = _PyObject_VAR_SIZE(type, nitems+1); /* note that we need to add one, for the sentinel */ if (PyType_IS_GC(type)) obj = _PyObject_GC_Malloc(size); else obj = PyObject_MALLOC(size); if (obj == NULL) return PyErr_NoMemory(); memset(obj, '\0', size); if (type->tp_flags & Py_TPFLAGS_HEAPTYPE) Py_INCREF(type); if (type->tp_itemsize == 0) PyObject_INIT(obj, type); else (void) PyObject_INIT_VAR((PyVarObject *)obj, type, nitems); if (PyType_IS_GC(type)) _PyObject_GC_TRACK(obj); return obj; } PyObject * PyType_GenericNew(PyTypeObject *type, PyObject *args, PyObject *kwds) { return type->tp_alloc(type, 0); } /* Helpers for subtyping */ static int traverse_slots(PyTypeObject *type, PyObject *self, visitproc visit, void *arg) { int i, n; PyMemberDef *mp; n = type->ob_size; mp = PyHeapType_GET_MEMBERS((PyHeapTypeObject *)type); for (i = 0; i < n; i++, mp++) { if (mp->type == T_OBJECT_EX) { char *addr = (char *)self + mp->offset; PyObject *obj = *(PyObject **)addr; if (obj != NULL) { int err = visit(obj, arg); if (err) return err; } } } return 0; } static int subtype_traverse(PyObject *self, visitproc visit, void *arg) { PyTypeObject *type, *base; traverseproc basetraverse; /* Find the nearest base with a different tp_traverse, and traverse slots while we're at it */ type = self->ob_type; base = type; while ((basetraverse = base->tp_traverse) == subtype_traverse) { if (base->ob_size) { int err = traverse_slots(base, self, visit, arg); if (err) return err; } base = base->tp_base; assert(base); } if (type->tp_dictoffset != base->tp_dictoffset) { PyObject **dictptr = _PyObject_GetDictPtr(self); if (dictptr && *dictptr) { int err = visit(*dictptr, arg); if (err) return err; } } if (type->tp_flags & Py_TPFLAGS_HEAPTYPE) { /* For a heaptype, the instances count as references to the type. Traverse the type so the collector can find cycles involving this link. */ int err = visit((PyObject *)type, arg); if (err) return err; } if (basetraverse) return basetraverse(self, visit, arg); return 0; } static void clear_slots(PyTypeObject *type, PyObject *self) { int i, n; PyMemberDef *mp; n = type->ob_size; mp = PyHeapType_GET_MEMBERS((PyHeapTypeObject *)type); for (i = 0; i < n; i++, mp++) { if (mp->type == T_OBJECT_EX && !(mp->flags & READONLY)) { char *addr = (char *)self + mp->offset; PyObject *obj = *(PyObject **)addr; if (obj != NULL) { Py_DECREF(obj); *(PyObject **)addr = NULL; } } } } static int subtype_clear(PyObject *self) { PyTypeObject *type, *base; inquiry baseclear; /* Find the nearest base with a different tp_clear and clear slots while we're at it */ type = self->ob_type; base = type; while ((baseclear = base->tp_clear) == subtype_clear) { if (base->ob_size) clear_slots(base, self); base = base->tp_base; assert(base); } /* There's no need to clear the instance dict (if any); the collector will call its tp_clear handler. */ if (baseclear) return baseclear(self); return 0; } static void subtype_dealloc(PyObject *self) { PyTypeObject *type, *base; destructor basedealloc; /* Extract the type; we expect it to be a heap type */ type = self->ob_type; assert(type->tp_flags & Py_TPFLAGS_HEAPTYPE); /* Test whether the type has GC exactly once */ if (!PyType_IS_GC(type)) { /* It's really rare to find a dynamic type that doesn't have GC; it can only happen when deriving from 'object' and not adding any slots or instance variables. This allows certain simplifications: there's no need to call clear_slots(), or DECREF the dict, or clear weakrefs. */ /* Maybe call finalizer; exit early if resurrected */ if (type->tp_del) { type->tp_del(self); if (self->ob_refcnt > 0) return; } /* Find the nearest base with a different tp_dealloc */ base = type; while ((basedealloc = base->tp_dealloc) == subtype_dealloc) { assert(base->ob_size == 0); base = base->tp_base; assert(base); } /* Call the base tp_dealloc() */ assert(basedealloc); basedealloc(self); /* Can't reference self beyond this point */ Py_DECREF(type); /* Done */ return; } /* We get here only if the type has GC */ /* UnTrack and re-Track around the trashcan macro, alas */ /* See explanation at end of function for full disclosure */ PyObject_GC_UnTrack(self); ++_PyTrash_delete_nesting; Py_TRASHCAN_SAFE_BEGIN(self); --_PyTrash_delete_nesting; /* DO NOT restore GC tracking at this point. weakref callbacks * (if any, and whether directly here or indirectly in something we * call) may trigger GC, and if self is tracked at that point, it * will look like trash to GC and GC will try to delete self again. */ /* Find the nearest base with a different tp_dealloc */ base = type; while ((basedealloc = base->tp_dealloc) == subtype_dealloc) { base = base->tp_base; assert(base); } /* If we added a weaklist, we clear it. Do this *before* calling the finalizer (__del__), clearing slots, or clearing the instance dict. */ if (type->tp_weaklistoffset && !base->tp_weaklistoffset) PyObject_ClearWeakRefs(self); /* Maybe call finalizer; exit early if resurrected */ if (type->tp_del) { _PyObject_GC_TRACK(self); type->tp_del(self); if (self->ob_refcnt > 0) goto endlabel; /* resurrected */ else _PyObject_GC_UNTRACK(self); } /* Clear slots up to the nearest base with a different tp_dealloc */ base = type; while ((basedealloc = base->tp_dealloc) == subtype_dealloc) { if (base->ob_size) clear_slots(base, self); base = base->tp_base; assert(base); } /* If we added a dict, DECREF it */ if (type->tp_dictoffset && !base->tp_dictoffset) { PyObject **dictptr = _PyObject_GetDictPtr(self); if (dictptr != NULL) { PyObject *dict = *dictptr; if (dict != NULL) { Py_DECREF(dict); *dictptr = NULL; } } } /* Call the base tp_dealloc(); first retrack self if * basedealloc knows about gc. */ if (PyType_IS_GC(base)) _PyObject_GC_TRACK(self); assert(basedealloc); basedealloc(self); /* Can't reference self beyond this point */ Py_DECREF(type); endlabel: ++_PyTrash_delete_nesting; Py_TRASHCAN_SAFE_END(self); --_PyTrash_delete_nesting; /* Explanation of the weirdness around the trashcan macros: Q. What do the trashcan macros do? A. Read the comment titled "Trashcan mechanism" in object.h. For one, this explains why there must be a call to GC-untrack before the trashcan begin macro. Without understanding the trashcan code, the answers to the following questions don't make sense. Q. Why do we GC-untrack before the trashcan and then immediately GC-track again afterward? A. In the case that the base class is GC-aware, the base class probably GC-untracks the object. If it does that using the UNTRACK macro, this will crash when the object is already untracked. Because we don't know what the base class does, the only safe thing is to make sure the object is tracked when we call the base class dealloc. But... The trashcan begin macro requires that the object is *untracked* before it is called. So the dance becomes: GC untrack trashcan begin GC track Q. Why did the last question say "immediately GC-track again"? It's nowhere near immediately. A. Because the code *used* to re-track immediately. Bad Idea. self has a refcount of 0, and if gc ever gets its hands on it (which can happen if any weakref callback gets invoked), it looks like trash to gc too, and gc also tries to delete self then. But we're already deleting self. Double dealloction is a subtle disaster. Q. Why the bizarre (net-zero) manipulation of _PyTrash_delete_nesting around the trashcan macros? A. Some base classes (e.g. list) also use the trashcan mechanism. The following scenario used to be possible: - suppose the trashcan level is one below the trashcan limit - subtype_dealloc() is called - the trashcan limit is not yet reached, so the trashcan level is incremented and the code between trashcan begin and end is executed - this destroys much of the object's contents, including its slots and __dict__ - basedealloc() is called; this is really list_dealloc(), or some other type which also uses the trashcan macros - the trashcan limit is now reached, so the object is put on the trashcan's to-be-deleted-later list - basedealloc() returns - subtype_dealloc() decrefs the object's type - subtype_dealloc() returns - later, the trashcan code starts deleting the objects from its to-be-deleted-later list - subtype_dealloc() is called *AGAIN* for the same object - at the very least (if the destroyed slots and __dict__ don't cause problems) the object's type gets decref'ed a second time, which is *BAD*!!! The remedy is to make sure that if the code between trashcan begin and end in subtype_dealloc() is called, the code between trashcan begin and end in basedealloc() will also be called. This is done by decrementing the level after passing into the trashcan block, and incrementing it just before leaving the block. But now it's possible that a chain of objects consisting solely of objects whose deallocator is subtype_dealloc() will defeat the trashcan mechanism completely: the decremented level means that the effective level never reaches the limit. Therefore, we *increment* the level *before* entering the trashcan block, and matchingly decrement it after leaving. This means the trashcan code will trigger a little early, but that's no big deal. Q. Are there any live examples of code in need of all this complexity? A. Yes. See SF bug 668433 for code that crashed (when Python was compiled in debug mode) before the trashcan level manipulations were added. For more discussion, see SF patches 581742, 575073 and bug 574207. */ } static PyTypeObject *solid_base(PyTypeObject *type); /* type test with subclassing support */ int PyType_IsSubtype(PyTypeObject *a, PyTypeObject *b) { PyObject *mro; if (!(a->tp_flags & Py_TPFLAGS_HAVE_CLASS)) return b == a || b == &PyBaseObject_Type; mro = a->tp_mro; if (mro != NULL) { /* Deal with multiple inheritance without recursion by walking the MRO tuple */ int i, n; assert(PyTuple_Check(mro)); n = PyTuple_GET_SIZE(mro); for (i = 0; i < n; i++) { if (PyTuple_GET_ITEM(mro, i) == (PyObject *)b) return 1; } return 0; } else { /* a is not completely initilized yet; follow tp_base */ do { if (a == b) return 1; a = a->tp_base; } while (a != NULL); return b == &PyBaseObject_Type; } } /* Internal routines to do a method lookup in the type without looking in the instance dictionary (so we can't use PyObject_GetAttr) but still binding it to the instance. The arguments are the object, the method name as a C string, and the address of a static variable used to cache the interned Python string. Two variants: - lookup_maybe() returns NULL without raising an exception when the _PyType_Lookup() call fails; - lookup_method() always raises an exception upon errors. */ static PyObject * lookup_maybe(PyObject *self, char *attrstr, PyObject **attrobj) { PyObject *res; if (*attrobj == NULL) { *attrobj = PyString_InternFromString(attrstr); if (*attrobj == NULL) return NULL; } res = _PyType_Lookup(self->ob_type, *attrobj); if (res != NULL) { descrgetfunc f; if ((f = res->ob_type->tp_descr_get) == NULL) Py_INCREF(res); else res = f(res, self, (PyObject *)(self->ob_type)); } return res; } static PyObject * lookup_method(PyObject *self, char *attrstr, PyObject **attrobj) { PyObject *res = lookup_maybe(self, attrstr, attrobj); if (res == NULL && !PyErr_Occurred()) PyErr_SetObject(PyExc_AttributeError, *attrobj); return res; } /* A variation of PyObject_CallMethod that uses lookup_method() instead of PyObject_GetAttrString(). This uses the same convention as lookup_method to cache the interned name string object. */ static PyObject * call_method(PyObject *o, char *name, PyObject **nameobj, char *format, ...) { va_list va; PyObject *args, *func = 0, *retval; va_start(va, format); func = lookup_maybe(o, name, nameobj); if (func == NULL) { va_end(va); if (!PyErr_Occurred()) PyErr_SetObject(PyExc_AttributeError, *nameobj); return NULL; } if (format && *format) args = Py_VaBuildValue(format, va); else args = PyTuple_New(0); va_end(va); if (args == NULL) return NULL; assert(PyTuple_Check(args)); retval = PyObject_Call(func, args, NULL); Py_DECREF(args); Py_DECREF(func); return retval; } /* Clone of call_method() that returns NotImplemented when the lookup fails. */ static PyObject * call_maybe(PyObject *o, char *name, PyObject **nameobj, char *format, ...) { va_list va; PyObject *args, *func = 0, *retval; va_start(va, format); func = lookup_maybe(o, name, nameobj); if (func == NULL) { va_end(va); if (!PyErr_Occurred()) { Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } return NULL; } if (format && *format) args = Py_VaBuildValue(format, va); else args = PyTuple_New(0); va_end(va); if (args == NULL) return NULL; assert(PyTuple_Check(args)); retval = PyObject_Call(func, args, NULL); Py_DECREF(args); Py_DECREF(func); return retval; } static int fill_classic_mro(PyObject *mro, PyObject *cls) { PyObject *bases, *base; int i, n; assert(PyList_Check(mro)); assert(PyClass_Check(cls)); i = PySequence_Contains(mro, cls); if (i < 0) return -1; if (!i) { if (PyList_Append(mro, cls) < 0) return -1; } bases = ((PyClassObject *)cls)->cl_bases; assert(bases && PyTuple_Check(bases)); n = PyTuple_GET_SIZE(bases); for (i = 0; i < n; i++) { base = PyTuple_GET_ITEM(bases, i); if (fill_classic_mro(mro, base) < 0) return -1; } return 0; } static PyObject * classic_mro(PyObject *cls) { PyObject *mro; assert(PyClass_Check(cls)); mro = PyList_New(0); if (mro != NULL) { if (fill_classic_mro(mro, cls) == 0) return mro; Py_DECREF(mro); } return NULL; } /* Method resolution order algorithm C3 described in "A Monotonic Superclass Linearization for Dylan", by Kim Barrett, Bob Cassel, Paul Haahr, David A. Moon, Keith Playford, and P. Tucker Withington. (OOPSLA 1996) Some notes about the rules implied by C3: No duplicate bases. It isn't legal to repeat a class in a list of base classes. The next three properties are the 3 constraints in "C3". Local precendece order. If A precedes B in C's MRO, then A will precede B in the MRO of all subclasses of C. Monotonicity. The MRO of a class must be an extension without reordering of the MRO of each of its superclasses. Extended Precedence Graph (EPG). Linearization is consistent if there is a path in the EPG from each class to all its successors in the linearization. See the paper for definition of EPG. */ static int tail_contains(PyObject *list, int whence, PyObject *o) { int j, size; size = PyList_GET_SIZE(list); for (j = whence+1; j < size; j++) { if (PyList_GET_ITEM(list, j) == o) return 1; } return 0; } static PyObject * class_name(PyObject *cls) { PyObject *name = PyObject_GetAttrString(cls, "__name__"); if (name == NULL) { PyErr_Clear(); Py_XDECREF(name); name = PyObject_Repr(cls); } if (name == NULL) return NULL; if (!PyString_Check(name)) { Py_DECREF(name); return NULL; } return name; } static int check_duplicates(PyObject *list) { int i, j, n; /* Let's use a quadratic time algorithm, assuming that the bases lists is short. */ n = PyList_GET_SIZE(list); for (i = 0; i < n; i++) { PyObject *o = PyList_GET_ITEM(list, i); for (j = i + 1; j < n; j++) { if (PyList_GET_ITEM(list, j) == o) { o = class_name(o); PyErr_Format(PyExc_TypeError, "duplicate base class %s", o ? PyString_AS_STRING(o) : "?"); Py_XDECREF(o); return -1; } } } return 0; } /* Raise a TypeError for an MRO order disagreement. It's hard to produce a good error message. In the absence of better insight into error reporting, report the classes that were candidates to be put next into the MRO. There is some conflict between the order in which they should be put in the MRO, but it's hard to diagnose what constraint can't be satisfied. */ static void set_mro_error(PyObject *to_merge, int *remain) { int i, n, off, to_merge_size; char buf[1000]; PyObject *k, *v; PyObject *set = PyDict_New(); to_merge_size = PyList_GET_SIZE(to_merge); for (i = 0; i < to_merge_size; i++) { PyObject *L = PyList_GET_ITEM(to_merge, i); if (remain[i] < PyList_GET_SIZE(L)) { PyObject *c = PyList_GET_ITEM(L, remain[i]); if (PyDict_SetItem(set, c, Py_None) < 0) return; } } n = PyDict_Size(set); off = PyOS_snprintf(buf, sizeof(buf), "Cannot create a \ consistent method resolution\norder (MRO) for bases"); i = 0; while (PyDict_Next(set, &i, &k, &v) && off < sizeof(buf)) { PyObject *name = class_name(k); off += PyOS_snprintf(buf + off, sizeof(buf) - off, " %s", name ? PyString_AS_STRING(name) : "?"); Py_XDECREF(name); if (--n && off+1 < sizeof(buf)) { buf[off++] = ','; buf[off] = '\0'; } } PyErr_SetString(PyExc_TypeError, buf); Py_DECREF(set); } static int pmerge(PyObject *acc, PyObject* to_merge) { int i, j, to_merge_size; int *remain; int ok, empty_cnt; to_merge_size = PyList_GET_SIZE(to_merge); /* remain stores an index into each sublist of to_merge. remain[i] is the index of the next base in to_merge[i] that is not included in acc. */ remain = PyMem_MALLOC(SIZEOF_INT*to_merge_size); if (remain == NULL) return -1; for (i = 0; i < to_merge_size; i++) remain[i] = 0; again: empty_cnt = 0; for (i = 0; i < to_merge_size; i++) { PyObject *candidate; PyObject *cur_list = PyList_GET_ITEM(to_merge, i); if (remain[i] >= PyList_GET_SIZE(cur_list)) { empty_cnt++; continue; } /* Choose next candidate for MRO. The input sequences alone can determine the choice. If not, choose the class which appears in the MRO of the earliest direct superclass of the new class. */ candidate = PyList_GET_ITEM(cur_list, remain[i]); for (j = 0; j < to_merge_size; j++) { PyObject *j_lst = PyList_GET_ITEM(to_merge, j); if (tail_contains(j_lst, remain[j], candidate)) { goto skip; /* continue outer loop */ } } ok = PyList_Append(acc, candidate); if (ok < 0) { PyMem_Free(remain); return -1; } for (j = 0; j < to_merge_size; j++) { PyObject *j_lst = PyList_GET_ITEM(to_merge, j); if (remain[j] < PyList_GET_SIZE(j_lst) && PyList_GET_ITEM(j_lst, remain[j]) == candidate) { remain[j]++; } } goto again; skip: ; } if (empty_cnt == to_merge_size) { PyMem_FREE(remain); return 0; } set_mro_error(to_merge, remain); PyMem_FREE(remain); return -1; } static PyObject * mro_implementation(PyTypeObject *type) { int i, n, ok; PyObject *bases, *result; PyObject *to_merge, *bases_aslist; if(type->tp_dict == NULL) { if(PyType_Ready(type) < 0) return NULL; } /* Find a superclass linearization that honors the constraints of the explicit lists of bases and the constraints implied by each base class. to_merge is a list of lists, where each list is a superclass linearization implied by a base class. The last element of to_merge is the declared list of bases. */ bases = type->tp_bases; n = PyTuple_GET_SIZE(bases); to_merge = PyList_New(n+1); if (to_merge == NULL) return NULL; for (i = 0; i < n; i++) { PyObject *base = PyTuple_GET_ITEM(bases, i); PyObject *parentMRO; if (PyType_Check(base)) parentMRO = PySequence_List( ((PyTypeObject*)base)->tp_mro); else parentMRO = classic_mro(base); if (parentMRO == NULL) { Py_DECREF(to_merge); return NULL; } PyList_SET_ITEM(to_merge, i, parentMRO); } bases_aslist = PySequence_List(bases); if (bases_aslist == NULL) { Py_DECREF(to_merge); return NULL; } /* This is just a basic sanity check. */ if (check_duplicates(bases_aslist) < 0) { Py_DECREF(to_merge); Py_DECREF(bases_aslist); return NULL; } PyList_SET_ITEM(to_merge, n, bases_aslist); result = Py_BuildValue("[O]", (PyObject *)type); if (result == NULL) { Py_DECREF(to_merge); return NULL; } ok = pmerge(result, to_merge); Py_DECREF(to_merge); if (ok < 0) { Py_DECREF(result); return NULL; } return result; } static PyObject * mro_external(PyObject *self) { PyTypeObject *type = (PyTypeObject *)self; return mro_implementation(type); } static int mro_internal(PyTypeObject *type) { PyObject *mro, *result, *tuple; int checkit = 0; if (type->ob_type == &PyType_Type) { result = mro_implementation(type); } else { static PyObject *mro_str; checkit = 1; mro = lookup_method((PyObject *)type, "mro", &mro_str); if (mro == NULL) return -1; result = PyObject_CallObject(mro, NULL); Py_DECREF(mro); } if (result == NULL) return -1; tuple = PySequence_Tuple(result); Py_DECREF(result); if (tuple == NULL) return -1; if (checkit) { int i, len; PyObject *cls; PyTypeObject *solid; solid = solid_base(type); len = PyTuple_GET_SIZE(tuple); for (i = 0; i < len; i++) { PyTypeObject *t; cls = PyTuple_GET_ITEM(tuple, i); if (PyClass_Check(cls)) continue; else if (!PyType_Check(cls)) { PyErr_Format(PyExc_TypeError, "mro() returned a non-class ('%.500s')", cls->ob_type->tp_name); Py_DECREF(tuple); return -1; } t = (PyTypeObject*)cls; if (!PyType_IsSubtype(solid, solid_base(t))) { PyErr_Format(PyExc_TypeError, "mro() returned base with unsuitable layout ('%.500s')", t->tp_name); Py_DECREF(tuple); return -1; } } } type->tp_mro = tuple; return 0; } /* Calculate the best base amongst multiple base classes. This is the first one that's on the path to the "solid base". */ static PyTypeObject * best_base(PyObject *bases) { int i, n; PyTypeObject *base, *winner, *candidate, *base_i; PyObject *base_proto; assert(PyTuple_Check(bases)); n = PyTuple_GET_SIZE(bases); assert(n > 0); base = NULL; winner = NULL; for (i = 0; i < n; i++) { base_proto = PyTuple_GET_ITEM(bases, i); if (PyClass_Check(base_proto)) continue; if (!PyType_Check(base_proto)) { PyErr_SetString( PyExc_TypeError, "bases must be types"); return NULL; } base_i = (PyTypeObject *)base_proto; if (base_i->tp_dict == NULL) { if (PyType_Ready(base_i) < 0) return NULL; } candidate = solid_base(base_i); if (winner == NULL) { winner = candidate; base = base_i; } else if (PyType_IsSubtype(winner, candidate)) ; else if (PyType_IsSubtype(candidate, winner)) { winner = candidate; base = base_i; } else { PyErr_SetString( PyExc_TypeError, "multiple bases have " "instance lay-out conflict"); return NULL; } } if (base == NULL) PyErr_SetString(PyExc_TypeError, "a new-style class can't have only classic bases"); return base; } static int extra_ivars(PyTypeObject *type, PyTypeObject *base) { size_t t_size = type->tp_basicsize; size_t b_size = base->tp_basicsize; assert(t_size >= b_size); /* Else type smaller than base! */ if (type->tp_itemsize || base->tp_itemsize) { /* If itemsize is involved, stricter rules */ return t_size != b_size || type->tp_itemsize != base->tp_itemsize; } if (type->tp_weaklistoffset && base->tp_weaklistoffset == 0 && type->tp_weaklistoffset + sizeof(PyObject *) == t_size) t_size -= sizeof(PyObject *); if (type->tp_dictoffset && base->tp_dictoffset == 0 && type->tp_dictoffset + sizeof(PyObject *) == t_size) t_size -= sizeof(PyObject *); return t_size != b_size; } static PyTypeObject * solid_base(PyTypeObject *type) { PyTypeObject *base; if (type->tp_base) base = solid_base(type->tp_base); else base = &PyBaseObject_Type; if (extra_ivars(type, base)) return type; else return base; } static void object_dealloc(PyObject *); static int object_init(PyObject *, PyObject *, PyObject *); static int update_slot(PyTypeObject *, PyObject *); static void fixup_slot_dispatchers(PyTypeObject *); static PyObject * subtype_dict(PyObject *obj, void *context) { PyObject **dictptr = _PyObject_GetDictPtr(obj); PyObject *dict; if (dictptr == NULL) { PyErr_SetString(PyExc_AttributeError, "This object has no __dict__"); return NULL; } dict = *dictptr; if (dict == NULL) *dictptr = dict = PyDict_New(); Py_XINCREF(dict); return dict; } static int subtype_setdict(PyObject *obj, PyObject *value, void *context) { PyObject **dictptr = _PyObject_GetDictPtr(obj); PyObject *dict; if (dictptr == NULL) { PyErr_SetString(PyExc_AttributeError, "This object has no __dict__"); return -1; } if (value != NULL && !PyDict_Check(value)) { PyErr_SetString(PyExc_TypeError, "__dict__ must be set to a dictionary"); return -1; } dict = *dictptr; Py_XINCREF(value); *dictptr = value; Py_XDECREF(dict); return 0; } static PyObject * subtype_getweakref(PyObject *obj, void *context) { PyObject **weaklistptr; PyObject *result; if (obj->ob_type->tp_weaklistoffset == 0) { PyErr_SetString(PyExc_AttributeError, "This object has no __weaklist__"); return NULL; } assert(obj->ob_type->tp_weaklistoffset > 0); assert(obj->ob_type->tp_weaklistoffset + sizeof(PyObject *) <= (size_t)(obj->ob_type->tp_basicsize)); weaklistptr = (PyObject **) ((char *)obj + obj->ob_type->tp_weaklistoffset); if (*weaklistptr == NULL) result = Py_None; else result = *weaklistptr; Py_INCREF(result); return result; } /* Three variants on the subtype_getsets list. */ static PyGetSetDef subtype_getsets_full[] = { {"__dict__", subtype_dict, subtype_setdict, PyDoc_STR("dictionary for instance variables (if defined)")}, {"__weakref__", subtype_getweakref, NULL, PyDoc_STR("list of weak references to the object (if defined)")}, {0} }; static PyGetSetDef subtype_getsets_dict_only[] = { {"__dict__", subtype_dict, subtype_setdict, PyDoc_STR("dictionary for instance variables (if defined)")}, {0} }; static PyGetSetDef subtype_getsets_weakref_only[] = { {"__weakref__", subtype_getweakref, NULL, PyDoc_STR("list of weak references to the object (if defined)")}, {0} }; static int valid_identifier(PyObject *s) { unsigned char *p; int i, n; if (!PyString_Check(s)) { PyErr_SetString(PyExc_TypeError, "__slots__ must be strings"); return 0; } p = (unsigned char *) PyString_AS_STRING(s); n = PyString_GET_SIZE(s); /* We must reject an empty name. As a hack, we bump the length to 1 so that the loop will balk on the trailing \0. */ if (n == 0) n = 1; for (i = 0; i < n; i++, p++) { if (!(i == 0 ? isalpha(*p) : isalnum(*p)) && *p != '_') { PyErr_SetString(PyExc_TypeError, "__slots__ must be identifiers"); return 0; } } return 1; } #ifdef Py_USING_UNICODE /* Replace Unicode objects in slots. */ static PyObject * _unicode_to_string(PyObject *slots, int nslots) { PyObject *tmp = slots; PyObject *o, *o1; int i; intintargfunc copy = slots->ob_type->tp_as_sequence->sq_slice; for (i = 0; i < nslots; i++) { if (PyUnicode_Check(o = PyTuple_GET_ITEM(tmp, i))) { if (tmp == slots) { tmp = copy(slots, 0, PyTuple_GET_SIZE(slots)); if (tmp == NULL) return NULL; } o1 = _PyUnicode_AsDefaultEncodedString (o, NULL); if (o1 == NULL) { Py_DECREF(tmp); return 0; } Py_INCREF(o1); Py_DECREF(o); PyTuple_SET_ITEM(tmp, i, o1); } } return tmp; } #endif static PyObject * type_new(PyTypeObject *metatype, PyObject *args, PyObject *kwds) { PyObject *name, *bases, *dict; static const char *kwlist[] = {"name", "bases", "dict", 0}; PyObject *slots, *tmp, *newslots; PyTypeObject *type, *base, *tmptype, *winner; PyHeapTypeObject *et; PyMemberDef *mp; int i, nbases, nslots, slotoffset, add_dict, add_weak; int j, may_add_dict, may_add_weak; assert(args != NULL && PyTuple_Check(args)); assert(kwds == NULL || PyDict_Check(kwds)); /* Special case: type(x) should return x->ob_type */ { const int nargs = PyTuple_GET_SIZE(args); const int nkwds = kwds == NULL ? 0 : PyDict_Size(kwds); if (PyType_CheckExact(metatype) && nargs == 1 && nkwds == 0) { PyObject *x = PyTuple_GET_ITEM(args, 0); Py_INCREF(x->ob_type); return (PyObject *) x->ob_type; } /* SF bug 475327 -- if that didn't trigger, we need 3 arguments. but PyArg_ParseTupleAndKeywords below may give a msg saying type() needs exactly 3. */ if (nargs + nkwds != 3) { PyErr_SetString(PyExc_TypeError, "type() takes 1 or 3 arguments"); return NULL; } } /* Check arguments: (name, bases, dict) */ if (!PyArg_ParseTupleAndKeywords(args, kwds, "SO!O!:type", kwlist, &name, &PyTuple_Type, &bases, &PyDict_Type, &dict)) return NULL; /* Determine the proper metatype to deal with this, and check for metatype conflicts while we're at it. Note that if some other metatype wins to contract, it's possible that its instances are not types. */ nbases = PyTuple_GET_SIZE(bases); winner = metatype; for (i = 0; i < nbases; i++) { tmp = PyTuple_GET_ITEM(bases, i); tmptype = tmp->ob_type; if (tmptype == &PyClass_Type) continue; /* Special case classic classes */ if (PyType_IsSubtype(winner, tmptype)) continue; if (PyType_IsSubtype(tmptype, winner)) { winner = tmptype; continue; } PyErr_SetString(PyExc_TypeError, "metaclass conflict: " "the metaclass of a derived class " "must be a (non-strict) subclass " "of the metaclasses of all its bases"); return NULL; } if (winner != metatype) { if (winner->tp_new != type_new) /* Pass it to the winner */ return winner->tp_new(winner, args, kwds); metatype = winner; } /* Adjust for empty tuple bases */ if (nbases == 0) { bases = PyTuple_Pack(1, &PyBaseObject_Type); if (bases == NULL) return NULL; nbases = 1; } else Py_INCREF(bases); /* XXX From here until type is allocated, "return NULL" leaks bases! */ /* Calculate best base, and check that all bases are type objects */ base = best_base(bases); if (base == NULL) { Py_DECREF(bases); return NULL; } if (!PyType_HasFeature(base, Py_TPFLAGS_BASETYPE)) { PyErr_Format(PyExc_TypeError, "type '%.100s' is not an acceptable base type", base->tp_name); Py_DECREF(bases); return NULL; } /* Check for a __slots__ sequence variable in dict, and count it */ slots = PyDict_GetItemString(dict, "__slots__"); nslots = 0; add_dict = 0; add_weak = 0; may_add_dict = base->tp_dictoffset == 0; may_add_weak = base->tp_weaklistoffset == 0 && base->tp_itemsize == 0; if (slots == NULL) { if (may_add_dict) { add_dict++; } if (may_add_weak) { add_weak++; } } else { /* Have slots */ /* Make it into a tuple */ if (PyString_Check(slots)) slots = PyTuple_Pack(1, slots); else slots = PySequence_Tuple(slots); if (slots == NULL) { Py_DECREF(bases); return NULL; } assert(PyTuple_Check(slots)); /* Are slots allowed? */ nslots = PyTuple_GET_SIZE(slots); if (nslots > 0 && base->tp_itemsize != 0) { PyErr_Format(PyExc_TypeError, "nonempty __slots__ " "not supported for subtype of '%s'", base->tp_name); bad_slots: Py_DECREF(bases); Py_DECREF(slots); return NULL; } #ifdef Py_USING_UNICODE tmp = _unicode_to_string(slots, nslots); if (tmp != slots) { Py_DECREF(slots); slots = tmp; } if (!tmp) return NULL; #endif /* Check for valid slot names and two special cases */ for (i = 0; i < nslots; i++) { PyObject *tmp = PyTuple_GET_ITEM(slots, i); char *s; if (!valid_identifier(tmp)) goto bad_slots; assert(PyString_Check(tmp)); s = PyString_AS_STRING(tmp); if (strcmp(s, "__dict__") == 0) { if (!may_add_dict || add_dict) { PyErr_SetString(PyExc_TypeError, "__dict__ slot disallowed: " "we already got one"); goto bad_slots; } add_dict++; } if (strcmp(s, "__weakref__") == 0) { if (!may_add_weak || add_weak) { PyErr_SetString(PyExc_TypeError, "__weakref__ slot disallowed: " "either we already got one, " "or __itemsize__ != 0"); goto bad_slots; } add_weak++; } } /* Copy slots into yet another tuple, demangling names */ newslots = PyTuple_New(nslots - add_dict - add_weak); if (newslots == NULL) goto bad_slots; for (i = j = 0; i < nslots; i++) { char *s; tmp = PyTuple_GET_ITEM(slots, i); s = PyString_AS_STRING(tmp); if ((add_dict && strcmp(s, "__dict__") == 0) || (add_weak && strcmp(s, "__weakref__") == 0)) continue; tmp =_Py_Mangle(name, tmp); if (!tmp) goto bad_slots; PyTuple_SET_ITEM(newslots, j, tmp); j++; } assert(j == nslots - add_dict - add_weak); nslots = j; Py_DECREF(slots); slots = newslots; /* Secondary bases may provide weakrefs or dict */ if (nbases > 1 && ((may_add_dict && !add_dict) || (may_add_weak && !add_weak))) { for (i = 0; i < nbases; i++) { tmp = PyTuple_GET_ITEM(bases, i); if (tmp == (PyObject *)base) continue; /* Skip primary base */ if (PyClass_Check(tmp)) { /* Classic base class provides both */ if (may_add_dict && !add_dict) add_dict++; if (may_add_weak && !add_weak) add_weak++; break; } assert(PyType_Check(tmp)); tmptype = (PyTypeObject *)tmp; if (may_add_dict && !add_dict && tmptype->tp_dictoffset != 0) add_dict++; if (may_add_weak && !add_weak && tmptype->tp_weaklistoffset != 0) add_weak++; if (may_add_dict && !add_dict) continue; if (may_add_weak && !add_weak) continue; /* Nothing more to check */ break; } } } /* XXX From here until type is safely allocated, "return NULL" may leak slots! */ /* Allocate the type object */ type = (PyTypeObject *)metatype->tp_alloc(metatype, nslots); if (type == NULL) { Py_XDECREF(slots); Py_DECREF(bases); return NULL; } /* Keep name and slots alive in the extended type object */ et = (PyHeapTypeObject *)type; Py_INCREF(name); et->name = name; et->slots = slots; /* Initialize tp_flags */ type->tp_flags = Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HEAPTYPE | Py_TPFLAGS_BASETYPE; if (base->tp_flags & Py_TPFLAGS_HAVE_GC) type->tp_flags |= Py_TPFLAGS_HAVE_GC; /* It's a new-style number unless it specifically inherits any old-style numeric behavior */ if ((base->tp_flags & Py_TPFLAGS_CHECKTYPES) || (base->tp_as_number == NULL)) type->tp_flags |= Py_TPFLAGS_CHECKTYPES; /* Initialize essential fields */ type->tp_as_number = &et->as_number; type->tp_as_sequence = &et->as_sequence; type->tp_as_mapping = &et->as_mapping; type->tp_as_buffer = &et->as_buffer; type->tp_name = PyString_AS_STRING(name); /* Set tp_base and tp_bases */ type->tp_bases = bases; Py_INCREF(base); type->tp_base = base; /* Initialize tp_dict from passed-in dict */ type->tp_dict = dict = PyDict_Copy(dict); if (dict == NULL) { Py_DECREF(type); return NULL; } /* Set __module__ in the dict */ if (PyDict_GetItemString(dict, "__module__") == NULL) { tmp = PyEval_GetGlobals(); if (tmp != NULL) { tmp = PyDict_GetItemString(tmp, "__name__"); if (tmp != NULL) { if (PyDict_SetItemString(dict, "__module__", tmp) < 0) return NULL; } } } /* Set tp_doc to a copy of dict['__doc__'], if the latter is there and is a string. The __doc__ accessor will first look for tp_doc; if that fails, it will still look into __dict__. */ { PyObject *doc = PyDict_GetItemString(dict, "__doc__"); if (doc != NULL && PyString_Check(doc)) { const size_t n = (size_t)PyString_GET_SIZE(doc); char *tp_doc = PyObject_MALLOC(n+1); if (tp_doc == NULL) { Py_DECREF(type); return NULL; } memcpy(tp_doc, PyString_AS_STRING(doc), n+1); type->tp_doc = tp_doc; } } /* Special-case __new__: if it's a plain function, make it a static function */ tmp = PyDict_GetItemString(dict, "__new__"); if (tmp != NULL && PyFunction_Check(tmp)) { tmp = PyStaticMethod_New(tmp); if (tmp == NULL) { Py_DECREF(type); return NULL; } PyDict_SetItemString(dict, "__new__", tmp); Py_DECREF(tmp); } /* Add descriptors for custom slots from __slots__, or for __dict__ */ mp = PyHeapType_GET_MEMBERS(et); slotoffset = base->tp_basicsize; if (slots != NULL) { for (i = 0; i < nslots; i++, mp++) { mp->name = PyString_AS_STRING( PyTuple_GET_ITEM(slots, i)); mp->type = T_OBJECT_EX; mp->offset = slotoffset; if (base->tp_weaklistoffset == 0 && strcmp(mp->name, "__weakref__") == 0) { add_weak++; mp->type = T_OBJECT; mp->flags = READONLY; type->tp_weaklistoffset = slotoffset; } slotoffset += sizeof(PyObject *); } } if (add_dict) { if (base->tp_itemsize) type->tp_dictoffset = -(long)sizeof(PyObject *); else type->tp_dictoffset = slotoffset; slotoffset += sizeof(PyObject *); } if (add_weak) { assert(!base->tp_itemsize); type->tp_weaklistoffset = slotoffset; slotoffset += sizeof(PyObject *); } type->tp_basicsize = slotoffset; type->tp_itemsize = base->tp_itemsize; type->tp_members = PyHeapType_GET_MEMBERS(et); if (type->tp_weaklistoffset && type->tp_dictoffset) type->tp_getset = subtype_getsets_full; else if (type->tp_weaklistoffset && !type->tp_dictoffset) type->tp_getset = subtype_getsets_weakref_only; else if (!type->tp_weaklistoffset && type->tp_dictoffset) type->tp_getset = subtype_getsets_dict_only; else type->tp_getset = NULL; /* Special case some slots */ if (type->tp_dictoffset != 0 || nslots > 0) { if (base->tp_getattr == NULL && base->tp_getattro == NULL) type->tp_getattro = PyObject_GenericGetAttr; if (base->tp_setattr == NULL && base->tp_setattro == NULL) type->tp_setattro = PyObject_GenericSetAttr; } type->tp_dealloc = subtype_dealloc; /* Enable GC unless there are really no instance variables possible */ if (!(type->tp_basicsize == sizeof(PyObject) && type->tp_itemsize == 0)) type->tp_flags |= Py_TPFLAGS_HAVE_GC; /* Always override allocation strategy to use regular heap */ type->tp_alloc = PyType_GenericAlloc; if (type->tp_flags & Py_TPFLAGS_HAVE_GC) { type->tp_free = PyObject_GC_Del; type->tp_traverse = subtype_traverse; type->tp_clear = subtype_clear; } else type->tp_free = PyObject_Del; /* Initialize the rest */ if (PyType_Ready(type) < 0) { Py_DECREF(type); return NULL; } /* Put the proper slots in place */ fixup_slot_dispatchers(type); return (PyObject *)type; } /* Internal API to look for a name through the MRO. This returns a borrowed reference, and doesn't set an exception! */ PyObject * _PyType_Lookup(PyTypeObject *type, PyObject *name) { int i, n; PyObject *mro, *res, *base, *dict; /* Look in tp_dict of types in MRO */ mro = type->tp_mro; /* If mro is NULL, the type is either not yet initialized by PyType_Ready(), or already cleared by type_clear(). Either way the safest thing to do is to return NULL. */ if (mro == NULL) return NULL; assert(PyTuple_Check(mro)); n = PyTuple_GET_SIZE(mro); for (i = 0; i < n; i++) { base = PyTuple_GET_ITEM(mro, i); if (PyClass_Check(base)) dict = ((PyClassObject *)base)->cl_dict; else { assert(PyType_Check(base)); dict = ((PyTypeObject *)base)->tp_dict; } assert(dict && PyDict_Check(dict)); res = PyDict_GetItem(dict, name); if (res != NULL) return res; } return NULL; } /* This is similar to PyObject_GenericGetAttr(), but uses _PyType_Lookup() instead of just looking in type->tp_dict. */ static PyObject * type_getattro(PyTypeObject *type, PyObject *name) { PyTypeObject *metatype = type->ob_type; PyObject *meta_attribute, *attribute; descrgetfunc meta_get; /* Initialize this type (we'll assume the metatype is initialized) */ if (type->tp_dict == NULL) { if (PyType_Ready(type) < 0) return NULL; } /* No readable descriptor found yet */ meta_get = NULL; /* Look for the attribute in the metatype */ meta_attribute = _PyType_Lookup(metatype, name); if (meta_attribute != NULL) { meta_get = meta_attribute->ob_type->tp_descr_get; if (meta_get != NULL && PyDescr_IsData(meta_attribute)) { /* Data descriptors implement tp_descr_set to intercept * writes. Assume the attribute is not overridden in * type's tp_dict (and bases): call the descriptor now. */ return meta_get(meta_attribute, (PyObject *)type, (PyObject *)metatype); } Py_INCREF(meta_attribute); } /* No data descriptor found on metatype. Look in tp_dict of this * type and its bases */ attribute = _PyType_Lookup(type, name); if (attribute != NULL) { /* Implement descriptor functionality, if any */ descrgetfunc local_get = attribute->ob_type->tp_descr_get; Py_XDECREF(meta_attribute); if (local_get != NULL) { /* NULL 2nd argument indicates the descriptor was * found on the target object itself (or a base) */ return local_get(attribute, (PyObject *)NULL, (PyObject *)type); } Py_INCREF(attribute); return attribute; } /* No attribute found in local __dict__ (or bases): use the * descriptor from the metatype, if any */ if (meta_get != NULL) { PyObject *res; res = meta_get(meta_attribute, (PyObject *)type, (PyObject *)metatype); Py_DECREF(meta_attribute); return res; } /* If an ordinary attribute was found on the metatype, return it now */ if (meta_attribute != NULL) { return meta_attribute; } /* Give up */ PyErr_Format(PyExc_AttributeError, "type object '%.50s' has no attribute '%.400s'", type->tp_name, PyString_AS_STRING(name)); return NULL; } static int type_setattro(PyTypeObject *type, PyObject *name, PyObject *value) { if (!(type->tp_flags & Py_TPFLAGS_HEAPTYPE)) { PyErr_Format( PyExc_TypeError, "can't set attributes of built-in/extension type '%s'", type->tp_name); return -1; } /* XXX Example of how I expect this to be used... if (update_subclasses(type, name, invalidate_cache, NULL) < 0) return -1; */ if (PyObject_GenericSetAttr((PyObject *)type, name, value) < 0) return -1; return update_slot(type, name); } static void type_dealloc(PyTypeObject *type) { PyHeapTypeObject *et; /* Assert this is a heap-allocated type object */ assert(type->tp_flags & Py_TPFLAGS_HEAPTYPE); _PyObject_GC_UNTRACK(type); PyObject_ClearWeakRefs((PyObject *)type); et = (PyHeapTypeObject *)type; Py_XDECREF(type->tp_base); Py_XDECREF(type->tp_dict); Py_XDECREF(type->tp_bases); Py_XDECREF(type->tp_mro); Py_XDECREF(type->tp_cache); Py_XDECREF(type->tp_subclasses); /* A type's tp_doc is heap allocated, unlike the tp_doc slots * of most other objects. It's okay to cast it to char *. */ PyObject_Free((char *)type->tp_doc); Py_XDECREF(et->name); Py_XDECREF(et->slots); type->ob_type->tp_free((PyObject *)type); } static PyObject * type_subclasses(PyTypeObject *type, PyObject *args_ignored) { PyObject *list, *raw, *ref; int i, n; list = PyList_New(0); if (list == NULL) return NULL; raw = type->tp_subclasses; if (raw == NULL) return list; assert(PyList_Check(raw)); n = PyList_GET_SIZE(raw); for (i = 0; i < n; i++) { ref = PyList_GET_ITEM(raw, i); assert(PyWeakref_CheckRef(ref)); ref = PyWeakref_GET_OBJECT(ref); if (ref != Py_None) { if (PyList_Append(list, ref) < 0) { Py_DECREF(list); return NULL; } } } return list; } static PyMethodDef type_methods[] = { {"mro", (PyCFunction)mro_external, METH_NOARGS, PyDoc_STR("mro() -> list\nreturn a type's method resolution order")}, {"__subclasses__", (PyCFunction)type_subclasses, METH_NOARGS, PyDoc_STR("__subclasses__() -> list of immediate subclasses")}, {0} }; PyDoc_STRVAR(type_doc, "type(object) -> the object's type\n" "type(name, bases, dict) -> a new type"); static int type_traverse(PyTypeObject *type, visitproc visit, void *arg) { int err; /* Because of type_is_gc(), the collector only calls this for heaptypes. */ assert(type->tp_flags & Py_TPFLAGS_HEAPTYPE); #define VISIT(SLOT) \ if (SLOT) { \ err = visit((PyObject *)(SLOT), arg); \ if (err) \ return err; \ } VISIT(type->tp_dict); VISIT(type->tp_cache); VISIT(type->tp_mro); VISIT(type->tp_bases); VISIT(type->tp_base); /* There's no need to visit type->tp_subclasses or ((PyHeapTypeObject *)type)->slots, because they can't be involved in cycles; tp_subclasses is a list of weak references, and slots is a tuple of strings. */ #undef VISIT return 0; } static int type_clear(PyTypeObject *type) { PyObject *tmp; /* Because of type_is_gc(), the collector only calls this for heaptypes. */ assert(type->tp_flags & Py_TPFLAGS_HEAPTYPE); #define CLEAR(SLOT) \ if (SLOT) { \ tmp = (PyObject *)(SLOT); \ SLOT = NULL; \ Py_DECREF(tmp); \ } /* The only field we need to clear is tp_mro, which is part of a hard cycle (its first element is the class itself) that won't be broken otherwise (it's a tuple and tuples don't have a tp_clear handler). None of the other fields need to be cleared, and here's why: tp_dict: It is a dict, so the collector will call its tp_clear. tp_cache: Not used; if it were, it would be a dict. tp_bases, tp_base: If these are involved in a cycle, there must be at least one other, mutable object in the cycle, e.g. a base class's dict; the cycle will be broken that way. tp_subclasses: A list of weak references can't be part of a cycle; and lists have their own tp_clear. slots (in PyHeapTypeObject): A tuple of strings can't be part of a cycle. */ CLEAR(type->tp_mro); #undef CLEAR return 0; } static int type_is_gc(PyTypeObject *type) { return type->tp_flags & Py_TPFLAGS_HEAPTYPE; } PyTypeObject PyType_Type = { PyObject_HEAD_INIT(&PyType_Type) 0, /* ob_size */ "type", /* tp_name */ sizeof(PyHeapTypeObject), /* tp_basicsize */ sizeof(PyMemberDef), /* tp_itemsize */ (destructor)type_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ type_compare, /* tp_compare */ (reprfunc)type_repr, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ (hashfunc)_Py_HashPointer, /* tp_hash */ (ternaryfunc)type_call, /* tp_call */ 0, /* tp_str */ (getattrofunc)type_getattro, /* tp_getattro */ (setattrofunc)type_setattro, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC | Py_TPFLAGS_BASETYPE, /* tp_flags */ type_doc, /* tp_doc */ (traverseproc)type_traverse, /* tp_traverse */ (inquiry)type_clear, /* tp_clear */ 0, /* tp_richcompare */ offsetof(PyTypeObject, tp_weaklist), /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ type_methods, /* tp_methods */ type_members, /* tp_members */ type_getsets, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ offsetof(PyTypeObject, tp_dict), /* tp_dictoffset */ 0, /* tp_init */ 0, /* tp_alloc */ type_new, /* tp_new */ PyObject_GC_Del, /* tp_free */ (inquiry)type_is_gc, /* tp_is_gc */ }; /* The base type of all types (eventually)... except itself. */ static int object_init(PyObject *self, PyObject *args, PyObject *kwds) { return 0; } /* If we don't have a tp_new for a new-style class, new will use this one. Therefore this should take no arguments/keywords. However, this new may also be inherited by objects that define a tp_init but no tp_new. These objects WILL pass argumets to tp_new, because it gets the same args as tp_init. So only allow arguments if we aren't using the default init, in which case we expect init to handle argument parsing. */ static PyObject * object_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { if (type->tp_init == object_init && (PyTuple_GET_SIZE(args) || (kwds && PyDict_Check(kwds) && PyDict_Size(kwds)))) { PyErr_SetString(PyExc_TypeError, "default __new__ takes no parameters"); return NULL; } return type->tp_alloc(type, 0); } static void object_dealloc(PyObject *self) { self->ob_type->tp_free(self); } static PyObject * object_repr(PyObject *self) { PyTypeObject *type; PyObject *mod, *name, *rtn; type = self->ob_type; mod = type_module(type, NULL); if (mod == NULL) PyErr_Clear(); else if (!PyString_Check(mod)) { Py_DECREF(mod); mod = NULL; } name = type_name(type, NULL); if (name == NULL) return NULL; if (mod != NULL && strcmp(PyString_AS_STRING(mod), "__builtin__")) rtn = PyString_FromFormat("<%s.%s object at %p>", PyString_AS_STRING(mod), PyString_AS_STRING(name), self); else rtn = PyString_FromFormat("<%s object at %p>", type->tp_name, self); Py_XDECREF(mod); Py_DECREF(name); return rtn; } static PyObject * object_str(PyObject *self) { unaryfunc f; f = self->ob_type->tp_repr; if (f == NULL) f = object_repr; return f(self); } static long object_hash(PyObject *self) { return _Py_HashPointer(self); } static PyObject * object_get_class(PyObject *self, void *closure) { Py_INCREF(self->ob_type); return (PyObject *)(self->ob_type); } static int equiv_structs(PyTypeObject *a, PyTypeObject *b) { return a == b || (a != NULL && b != NULL && a->tp_basicsize == b->tp_basicsize && a->tp_itemsize == b->tp_itemsize && a->tp_dictoffset == b->tp_dictoffset && a->tp_weaklistoffset == b->tp_weaklistoffset && ((a->tp_flags & Py_TPFLAGS_HAVE_GC) == (b->tp_flags & Py_TPFLAGS_HAVE_GC))); } static int same_slots_added(PyTypeObject *a, PyTypeObject *b) { PyTypeObject *base = a->tp_base; int size; if (base != b->tp_base) return 0; if (equiv_structs(a, base) && equiv_structs(b, base)) return 1; size = base->tp_basicsize; if (a->tp_dictoffset == size && b->tp_dictoffset == size) size += sizeof(PyObject *); if (a->tp_weaklistoffset == size && b->tp_weaklistoffset == size) size += sizeof(PyObject *); return size == a->tp_basicsize && size == b->tp_basicsize; } static int compatible_for_assignment(PyTypeObject* old, PyTypeObject* new, char* attr) { PyTypeObject *newbase, *oldbase; if (new->tp_dealloc != old->tp_dealloc || new->tp_free != old->tp_free) { PyErr_Format(PyExc_TypeError, "%s assignment: " "'%s' deallocator differs from '%s'", attr, new->tp_name, old->tp_name); return 0; } newbase = new; oldbase = old; while (equiv_structs(newbase, newbase->tp_base)) newbase = newbase->tp_base; while (equiv_structs(oldbase, oldbase->tp_base)) oldbase = oldbase->tp_base; if (newbase != oldbase && (newbase->tp_base != oldbase->tp_base || !same_slots_added(newbase, oldbase))) { PyErr_Format(PyExc_TypeError, "%s assignment: " "'%s' object layout differs from '%s'", attr, new->tp_name, old->tp_name); return 0; } return 1; } static int object_set_class(PyObject *self, PyObject *value, void *closure) { PyTypeObject *old = self->ob_type; PyTypeObject *new; if (value == NULL) { PyErr_SetString(PyExc_TypeError, "can't delete __class__ attribute"); return -1; } if (!PyType_Check(value)) { PyErr_Format(PyExc_TypeError, "__class__ must be set to new-style class, not '%s' object", value->ob_type->tp_name); return -1; } new = (PyTypeObject *)value; if (!(new->tp_flags & Py_TPFLAGS_HEAPTYPE) || !(old->tp_flags & Py_TPFLAGS_HEAPTYPE)) { PyErr_Format(PyExc_TypeError, "__class__ assignment: only for heap types"); return -1; } if (compatible_for_assignment(new, old, "__class__")) { Py_INCREF(new); self->ob_type = new; Py_DECREF(old); return 0; } else { return -1; } } static PyGetSetDef object_getsets[] = { {"__class__", object_get_class, object_set_class, PyDoc_STR("the object's class")}, {0} }; /* Stuff to implement __reduce_ex__ for pickle protocols >= 2. We fall back to helpers in copy_reg for: - pickle protocols < 2 - calculating the list of slot names (done only once per class) - the __newobj__ function (which is used as a token but never called) */ static PyObject * import_copy_reg(void) { static PyObject *copy_reg_str; if (!copy_reg_str) { copy_reg_str = PyString_InternFromString("copy_reg"); if (copy_reg_str == NULL) return NULL; } return PyImport_Import(copy_reg_str); } static PyObject * slotnames(PyObject *cls) { PyObject *clsdict; PyObject *copy_reg; PyObject *slotnames; if (!PyType_Check(cls)) { Py_INCREF(Py_None); return Py_None; } clsdict = ((PyTypeObject *)cls)->tp_dict; slotnames = PyDict_GetItemString(clsdict, "__slotnames__"); if (slotnames != NULL && PyList_Check(slotnames)) { Py_INCREF(slotnames); return slotnames; } copy_reg = import_copy_reg(); if (copy_reg == NULL) return NULL; slotnames = PyObject_CallMethod(copy_reg, "_slotnames", "O", cls); Py_DECREF(copy_reg); if (slotnames != NULL && slotnames != Py_None && !PyList_Check(slotnames)) { PyErr_SetString(PyExc_TypeError, "copy_reg._slotnames didn't return a list or None"); Py_DECREF(slotnames); slotnames = NULL; } return slotnames; } static PyObject * reduce_2(PyObject *obj) { PyObject *cls, *getnewargs; PyObject *args = NULL, *args2 = NULL; PyObject *getstate = NULL, *state = NULL, *names = NULL; PyObject *slots = NULL, *listitems = NULL, *dictitems = NULL; PyObject *copy_reg = NULL, *newobj = NULL, *res = NULL; int i, n; cls = PyObject_GetAttrString(obj, "__class__"); if (cls == NULL) return NULL; getnewargs = PyObject_GetAttrString(obj, "__getnewargs__"); if (getnewargs != NULL) { args = PyObject_CallObject(getnewargs, NULL); Py_DECREF(getnewargs); if (args != NULL && !PyTuple_Check(args)) { PyErr_SetString(PyExc_TypeError, "__getnewargs__ should return a tuple"); goto end; } } else { PyErr_Clear(); args = PyTuple_New(0); } if (args == NULL) goto end; getstate = PyObject_GetAttrString(obj, "__getstate__"); if (getstate != NULL) { state = PyObject_CallObject(getstate, NULL); Py_DECREF(getstate); if (state == NULL) goto end; } else { PyErr_Clear(); state = PyObject_GetAttrString(obj, "__dict__"); if (state == NULL) { PyErr_Clear(); state = Py_None; Py_INCREF(state); } names = slotnames(cls); if (names == NULL) goto end; if (names != Py_None) { assert(PyList_Check(names)); slots = PyDict_New(); if (slots == NULL) goto end; n = 0; /* Can't pre-compute the list size; the list is stored on the class so accessible to other threads, which may be run by DECREF */ for (i = 0; i < PyList_GET_SIZE(names); i++) { PyObject *name, *value; name = PyList_GET_ITEM(names, i); value = PyObject_GetAttr(obj, name); if (value == NULL) PyErr_Clear(); else { int err = PyDict_SetItem(slots, name, value); Py_DECREF(value); if (err) goto end; n++; } } if (n) { state = Py_BuildValue("(NO)", state, slots); if (state == NULL) goto end; } } } if (!PyList_Check(obj)) { listitems = Py_None; Py_INCREF(listitems); } else { listitems = PyObject_GetIter(obj); if (listitems == NULL) goto end; } if (!PyDict_Check(obj)) { dictitems = Py_None; Py_INCREF(dictitems); } else { dictitems = PyObject_CallMethod(obj, "iteritems", ""); if (dictitems == NULL) goto end; } copy_reg = import_copy_reg(); if (copy_reg == NULL) goto end; newobj = PyObject_GetAttrString(copy_reg, "__newobj__"); if (newobj == NULL) goto end; n = PyTuple_GET_SIZE(args); args2 = PyTuple_New(n+1); if (args2 == NULL) goto end; PyTuple_SET_ITEM(args2, 0, cls); cls = NULL; for (i = 0; i < n; i++) { PyObject *v = PyTuple_GET_ITEM(args, i); Py_INCREF(v); PyTuple_SET_ITEM(args2, i+1, v); } res = PyTuple_Pack(5, newobj, args2, state, listitems, dictitems); end: Py_XDECREF(cls); Py_XDECREF(args); Py_XDECREF(args2); Py_XDECREF(slots); Py_XDECREF(state); Py_XDECREF(names); Py_XDECREF(listitems); Py_XDECREF(dictitems); Py_XDECREF(copy_reg); Py_XDECREF(newobj); return res; } static PyObject * object_reduce_ex(PyObject *self, PyObject *args) { /* Call copy_reg._reduce_ex(self, proto) */ PyObject *reduce, *copy_reg, *res; int proto = 0; if (!PyArg_ParseTuple(args, "|i:__reduce_ex__", &proto)) return NULL; reduce = PyObject_GetAttrString(self, "__reduce__"); if (reduce == NULL) PyErr_Clear(); else { PyObject *cls, *clsreduce, *objreduce; int override; cls = PyObject_GetAttrString(self, "__class__"); if (cls == NULL) { Py_DECREF(reduce); return NULL; } clsreduce = PyObject_GetAttrString(cls, "__reduce__"); Py_DECREF(cls); if (clsreduce == NULL) { Py_DECREF(reduce); return NULL; } objreduce = PyDict_GetItemString(PyBaseObject_Type.tp_dict, "__reduce__"); override = (clsreduce != objreduce); Py_DECREF(clsreduce); if (override) { res = PyObject_CallObject(reduce, NULL); Py_DECREF(reduce); return res; } else Py_DECREF(reduce); } if (proto >= 2) return reduce_2(self); copy_reg = import_copy_reg(); if (!copy_reg) return NULL; res = PyEval_CallMethod(copy_reg, "_reduce_ex", "(Oi)", self, proto); Py_DECREF(copy_reg); return res; } static PyMethodDef object_methods[] = { {"__reduce_ex__", object_reduce_ex, METH_VARARGS, PyDoc_STR("helper for pickle")}, {"__reduce__", object_reduce_ex, METH_VARARGS, PyDoc_STR("helper for pickle")}, {0} }; PyTypeObject PyBaseObject_Type = { PyObject_HEAD_INIT(&PyType_Type) 0, /* ob_size */ "object", /* tp_name */ sizeof(PyObject), /* tp_basicsize */ 0, /* tp_itemsize */ (destructor)object_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_compare */ object_repr, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ object_hash, /* tp_hash */ 0, /* tp_call */ object_str, /* tp_str */ PyObject_GenericGetAttr, /* tp_getattro */ PyObject_GenericSetAttr, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_BASETYPE, /* tp_flags */ PyDoc_STR("The most base type"), /* tp_doc */ 0, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ object_methods, /* tp_methods */ 0, /* tp_members */ object_getsets, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ 0, /* tp_descr_get */ 0, /* tp_descr_set */ 0, /* tp_dictoffset */ object_init, /* tp_init */ PyType_GenericAlloc, /* tp_alloc */ object_new, /* tp_new */ PyObject_Del, /* tp_free */ }; /* Initialize the __dict__ in a type object */ static int add_methods(PyTypeObject *type, PyMethodDef *meth) { PyObject *dict = type->tp_dict; for (; meth->ml_name != NULL; meth++) { PyObject *descr; if (PyDict_GetItemString(dict, meth->ml_name) && !(meth->ml_flags & METH_COEXIST)) continue; if (meth->ml_flags & METH_CLASS) { if (meth->ml_flags & METH_STATIC) { PyErr_SetString(PyExc_ValueError, "method cannot be both class and static"); return -1; } descr = PyDescr_NewClassMethod(type, meth); } else if (meth->ml_flags & METH_STATIC) { PyObject *cfunc = PyCFunction_New(meth, NULL); if (cfunc == NULL) return -1; descr = PyStaticMethod_New(cfunc); Py_DECREF(cfunc); } else { descr = PyDescr_NewMethod(type, meth); } if (descr == NULL) return -1; if (PyDict_SetItemString(dict, meth->ml_name, descr) < 0) return -1; Py_DECREF(descr); } return 0; } static int add_members(PyTypeObject *type, PyMemberDef *memb) { PyObject *dict = type->tp_dict; for (; memb->name != NULL; memb++) { PyObject *descr; if (PyDict_GetItemString(dict, memb->name)) continue; descr = PyDescr_NewMember(type, memb); if (descr == NULL) return -1; if (PyDict_SetItemString(dict, memb->name, descr) < 0) return -1; Py_DECREF(descr); } return 0; } static int add_getset(PyTypeObject *type, PyGetSetDef *gsp) { PyObject *dict = type->tp_dict; for (; gsp->name != NULL; gsp++) { PyObject *descr; if (PyDict_GetItemString(dict, gsp->name)) continue; descr = PyDescr_NewGetSet(type, gsp); if (descr == NULL) return -1; if (PyDict_SetItemString(dict, gsp->name, descr) < 0) return -1; Py_DECREF(descr); } return 0; } static void inherit_special(PyTypeObject *type, PyTypeObject *base) { int oldsize, newsize; /* Special flag magic */ if (!type->tp_as_buffer && base->tp_as_buffer) { type->tp_flags &= ~Py_TPFLAGS_HAVE_GETCHARBUFFER; type->tp_flags |= base->tp_flags & Py_TPFLAGS_HAVE_GETCHARBUFFER; } if (!type->tp_as_sequence && base->tp_as_sequence) { type->tp_flags &= ~Py_TPFLAGS_HAVE_SEQUENCE_IN; type->tp_flags |= base->tp_flags & Py_TPFLAGS_HAVE_SEQUENCE_IN; } if ((type->tp_flags & Py_TPFLAGS_HAVE_INPLACEOPS) != (base->tp_flags & Py_TPFLAGS_HAVE_INPLACEOPS)) { if ((!type->tp_as_number && base->tp_as_number) || (!type->tp_as_sequence && base->tp_as_sequence)) { type->tp_flags &= ~Py_TPFLAGS_HAVE_INPLACEOPS; if (!type->tp_as_number && !type->tp_as_sequence) { type->tp_flags |= base->tp_flags & Py_TPFLAGS_HAVE_INPLACEOPS; } } /* Wow */ } if (!type->tp_as_number && base->tp_as_number) { type->tp_flags &= ~Py_TPFLAGS_CHECKTYPES; type->tp_flags |= base->tp_flags & Py_TPFLAGS_CHECKTYPES; } /* Copying basicsize is connected to the GC flags */ oldsize = base->tp_basicsize; newsize = type->tp_basicsize ? type->tp_basicsize : oldsize; if (!(type->tp_flags & Py_TPFLAGS_HAVE_GC) && (base->tp_flags & Py_TPFLAGS_HAVE_GC) && (type->tp_flags & Py_TPFLAGS_HAVE_RICHCOMPARE/*GC slots exist*/) && (!type->tp_traverse && !type->tp_clear)) { type->tp_flags |= Py_TPFLAGS_HAVE_GC; if (type->tp_traverse == NULL) type->tp_traverse = base->tp_traverse; if (type->tp_clear == NULL) type->tp_clear = base->tp_clear; } if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_CLASS) { /* The condition below could use some explanation. It appears that tp_new is not inherited for static types whose base class is 'object'; this seems to be a precaution so that old extension types don't suddenly become callable (object.__new__ wouldn't insure the invariants that the extension type's own factory function ensures). Heap types, of course, are under our control, so they do inherit tp_new; static extension types that specify some other built-in type as the default are considered new-style-aware so they also inherit object.__new__. */ if (base != &PyBaseObject_Type || (type->tp_flags & Py_TPFLAGS_HEAPTYPE)) { if (type->tp_new == NULL) type->tp_new = base->tp_new; } } type->tp_basicsize = newsize; /* Copy other non-function slots */ #undef COPYVAL #define COPYVAL(SLOT) \ if (type->SLOT == 0) type->SLOT = base->SLOT COPYVAL(tp_itemsize); if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_WEAKREFS) { COPYVAL(tp_weaklistoffset); } if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_CLASS) { COPYVAL(tp_dictoffset); } } static void inherit_slots(PyTypeObject *type, PyTypeObject *base) { PyTypeObject *basebase; #undef SLOTDEFINED #undef COPYSLOT #undef COPYNUM #undef COPYSEQ #undef COPYMAP #undef COPYBUF #define SLOTDEFINED(SLOT) \ (base->SLOT != 0 && \ (basebase == NULL || base->SLOT != basebase->SLOT)) #define COPYSLOT(SLOT) \ if (!type->SLOT && SLOTDEFINED(SLOT)) type->SLOT = base->SLOT #define COPYNUM(SLOT) COPYSLOT(tp_as_number->SLOT) #define COPYSEQ(SLOT) COPYSLOT(tp_as_sequence->SLOT) #define COPYMAP(SLOT) COPYSLOT(tp_as_mapping->SLOT) #define COPYBUF(SLOT) COPYSLOT(tp_as_buffer->SLOT) /* This won't inherit indirect slots (from tp_as_number etc.) if type doesn't provide the space. */ if (type->tp_as_number != NULL && base->tp_as_number != NULL) { basebase = base->tp_base; if (basebase->tp_as_number == NULL) basebase = NULL; COPYNUM(nb_add); COPYNUM(nb_subtract); COPYNUM(nb_multiply); COPYNUM(nb_divide); COPYNUM(nb_remainder); COPYNUM(nb_divmod); COPYNUM(nb_power); COPYNUM(nb_negative); COPYNUM(nb_positive); COPYNUM(nb_absolute); COPYNUM(nb_nonzero); COPYNUM(nb_invert); COPYNUM(nb_lshift); COPYNUM(nb_rshift); COPYNUM(nb_and); COPYNUM(nb_xor); COPYNUM(nb_or); COPYNUM(nb_coerce); COPYNUM(nb_int); COPYNUM(nb_long); COPYNUM(nb_float); COPYNUM(nb_oct); COPYNUM(nb_hex); COPYNUM(nb_inplace_add); COPYNUM(nb_inplace_subtract); COPYNUM(nb_inplace_multiply); COPYNUM(nb_inplace_divide); COPYNUM(nb_inplace_remainder); COPYNUM(nb_inplace_power); COPYNUM(nb_inplace_lshift); COPYNUM(nb_inplace_rshift); COPYNUM(nb_inplace_and); COPYNUM(nb_inplace_xor); COPYNUM(nb_inplace_or); if (base->tp_flags & Py_TPFLAGS_CHECKTYPES) { COPYNUM(nb_true_divide); COPYNUM(nb_floor_divide); COPYNUM(nb_inplace_true_divide); COPYNUM(nb_inplace_floor_divide); } } if (type->tp_as_sequence != NULL && base->tp_as_sequence != NULL) { basebase = base->tp_base; if (basebase->tp_as_sequence == NULL) basebase = NULL; COPYSEQ(sq_length); COPYSEQ(sq_concat); COPYSEQ(sq_repeat); COPYSEQ(sq_item); COPYSEQ(sq_slice); COPYSEQ(sq_ass_item); COPYSEQ(sq_ass_slice); COPYSEQ(sq_contains); COPYSEQ(sq_inplace_concat); COPYSEQ(sq_inplace_repeat); } if (type->tp_as_mapping != NULL && base->tp_as_mapping != NULL) { basebase = base->tp_base; if (basebase->tp_as_mapping == NULL) basebase = NULL; COPYMAP(mp_length); COPYMAP(mp_subscript); COPYMAP(mp_ass_subscript); } if (type->tp_as_buffer != NULL && base->tp_as_buffer != NULL) { basebase = base->tp_base; if (basebase->tp_as_buffer == NULL) basebase = NULL; COPYBUF(bf_getreadbuffer); COPYBUF(bf_getwritebuffer); COPYBUF(bf_getsegcount); COPYBUF(bf_getcharbuffer); } basebase = base->tp_base; COPYSLOT(tp_dealloc); COPYSLOT(tp_print); if (type->tp_getattr == NULL && type->tp_getattro == NULL) { type->tp_getattr = base->tp_getattr; type->tp_getattro = base->tp_getattro; } if (type->tp_setattr == NULL && type->tp_setattro == NULL) { type->tp_setattr = base->tp_setattr; type->tp_setattro = base->tp_setattro; } /* tp_compare see tp_richcompare */ COPYSLOT(tp_repr); /* tp_hash see tp_richcompare */ COPYSLOT(tp_call); COPYSLOT(tp_str); if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_RICHCOMPARE) { if (type->tp_compare == NULL && type->tp_richcompare == NULL && type->tp_hash == NULL) { type->tp_compare = base->tp_compare; type->tp_richcompare = base->tp_richcompare; type->tp_hash = base->tp_hash; } } else { COPYSLOT(tp_compare); } if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_ITER) { COPYSLOT(tp_iter); COPYSLOT(tp_iternext); } if (type->tp_flags & base->tp_flags & Py_TPFLAGS_HAVE_CLASS) { COPYSLOT(tp_descr_get); COPYSLOT(tp_descr_set); COPYSLOT(tp_dictoffset); COPYSLOT(tp_init); COPYSLOT(tp_alloc); COPYSLOT(tp_is_gc); if ((type->tp_flags & Py_TPFLAGS_HAVE_GC) == (base->tp_flags & Py_TPFLAGS_HAVE_GC)) { /* They agree about gc. */ COPYSLOT(tp_free); } else if ((type->tp_flags & Py_TPFLAGS_HAVE_GC) && type->tp_free == NULL && base->tp_free == _PyObject_Del) { /* A bit of magic to plug in the correct default * tp_free function when a derived class adds gc, * didn't define tp_free, and the base uses the * default non-gc tp_free. */ type->tp_free = PyObject_GC_Del; } /* else they didn't agree about gc, and there isn't something * obvious to be done -- the type is on its own. */ } } static int add_operators(PyTypeObject *); int PyType_Ready(PyTypeObject *type) { PyObject *dict, *bases; PyTypeObject *base; int i, n; if (type->tp_flags & Py_TPFLAGS_READY) { assert(type->tp_dict != NULL); return 0; } assert((type->tp_flags & Py_TPFLAGS_READYING) == 0); type->tp_flags |= Py_TPFLAGS_READYING; #ifdef Py_TRACE_REFS /* PyType_Ready is the closest thing we have to a choke point * for type objects, so is the best place I can think of to try * to get type objects into the doubly-linked list of all objects. * Still, not all type objects go thru PyType_Ready. */ _Py_AddToAllObjects((PyObject *)type, 0); #endif /* Initialize tp_base (defaults to BaseObject unless that's us) */ base = type->tp_base; if (base == NULL && type != &PyBaseObject_Type) { base = type->tp_base = &PyBaseObject_Type; Py_INCREF(base); } /* Initialize the base class */ if (base && base->tp_dict == NULL) { if (PyType_Ready(base) < 0) goto error; } /* Initialize ob_type if NULL. This means extensions that want to be compilable separately on Windows can call PyType_Ready() instead of initializing the ob_type field of their type objects. */ if (type->ob_type == NULL) type->ob_type = base->ob_type; /* Initialize tp_bases */ bases = type->tp_bases; if (bases == NULL) { if (base == NULL) bases = PyTuple_New(0); else bases = PyTuple_Pack(1, base); if (bases == NULL) goto error; type->tp_bases = bases; } /* Initialize tp_dict */ dict = type->tp_dict; if (dict == NULL) { dict = PyDict_New(); if (dict == NULL) goto error; type->tp_dict = dict; } /* Add type-specific descriptors to tp_dict */ if (add_operators(type) < 0) goto error; if (type->tp_methods != NULL) { if (add_methods(type, type->tp_methods) < 0) goto error; } if (type->tp_members != NULL) { if (add_members(type, type->tp_members) < 0) goto error; } if (type->tp_getset != NULL) { if (add_getset(type, type->tp_getset) < 0) goto error; } /* Calculate method resolution order */ if (mro_internal(type) < 0) { goto error; } /* Inherit special flags from dominant base */ if (type->tp_base != NULL) inherit_special(type, type->tp_base); /* Initialize tp_dict properly */ bases = type->tp_mro; assert(bases != NULL); assert(PyTuple_Check(bases)); n = PyTuple_GET_SIZE(bases); for (i = 1; i < n; i++) { PyObject *b = PyTuple_GET_ITEM(bases, i); if (PyType_Check(b)) inherit_slots(type, (PyTypeObject *)b); } /* Sanity check for tp_free. */ if (PyType_IS_GC(type) && (type->tp_flags & Py_TPFLAGS_BASETYPE) && (type->tp_free == NULL || type->tp_free == PyObject_Del)) { /* This base class needs to call tp_free, but doesn't have * one, or its tp_free is for non-gc'ed objects. */ PyErr_Format(PyExc_TypeError, "type '%.100s' participates in " "gc and is a base type but has inappropriate " "tp_free slot", type->tp_name); goto error; } /* if the type dictionary doesn't contain a __doc__, set it from the tp_doc slot. */ if (PyDict_GetItemString(type->tp_dict, "__doc__") == NULL) { if (type->tp_doc != NULL) { PyObject *doc = PyString_FromString(type->tp_doc); PyDict_SetItemString(type->tp_dict, "__doc__", doc); Py_DECREF(doc); } else { PyDict_SetItemString(type->tp_dict, "__doc__", Py_None); } } /* Some more special stuff */ base = type->tp_base; if (base != NULL) { if (type->tp_as_number == NULL) type->tp_as_number = base->tp_as_number; if (type->tp_as_sequence == NULL) type->tp_as_sequence = base->tp_as_sequence; if (type->tp_as_mapping == NULL) type->tp_as_mapping = base->tp_as_mapping; if (type->tp_as_buffer == NULL) type->tp_as_buffer = base->tp_as_buffer; } /* Link into each base class's list of subclasses */ bases = type->tp_bases; n = PyTuple_GET_SIZE(bases); for (i = 0; i < n; i++) { PyObject *b = PyTuple_GET_ITEM(bases, i); if (PyType_Check(b) && add_subclass((PyTypeObject *)b, type) < 0) goto error; } /* All done -- set the ready flag */ assert(type->tp_dict != NULL); type->tp_flags = (type->tp_flags & ~Py_TPFLAGS_READYING) | Py_TPFLAGS_READY; return 0; error: type->tp_flags &= ~Py_TPFLAGS_READYING; return -1; } static int add_subclass(PyTypeObject *base, PyTypeObject *type) { int i; PyObject *list, *ref, *new; list = base->tp_subclasses; if (list == NULL) { base->tp_subclasses = list = PyList_New(0); if (list == NULL) return -1; } assert(PyList_Check(list)); new = PyWeakref_NewRef((PyObject *)type, NULL); i = PyList_GET_SIZE(list); while (--i >= 0) { ref = PyList_GET_ITEM(list, i); assert(PyWeakref_CheckRef(ref)); if (PyWeakref_GET_OBJECT(ref) == Py_None) return PyList_SetItem(list, i, new); } i = PyList_Append(list, new); Py_DECREF(new); return i; } static void remove_subclass(PyTypeObject *base, PyTypeObject *type) { int i; PyObject *list, *ref; list = base->tp_subclasses; if (list == NULL) { return; } assert(PyList_Check(list)); i = PyList_GET_SIZE(list); while (--i >= 0) { ref = PyList_GET_ITEM(list, i); assert(PyWeakref_CheckRef(ref)); if (PyWeakref_GET_OBJECT(ref) == (PyObject*)type) { /* this can't fail, right? */ PySequence_DelItem(list, i); return; } } } static int check_num_args(PyObject *ob, int n) { if (!PyTuple_CheckExact(ob)) { PyErr_SetString(PyExc_SystemError, "PyArg_UnpackTuple() argument list is not a tuple"); return 0; } if (n == PyTuple_GET_SIZE(ob)) return 1; PyErr_Format( PyExc_TypeError, "expected %d arguments, got %d", n, PyTuple_GET_SIZE(ob)); return 0; } /* Generic wrappers for overloadable 'operators' such as __getitem__ */ /* There's a wrapper *function* for each distinct function typedef used for type object slots (e.g. binaryfunc, ternaryfunc, etc.). There's a wrapper *table* for each distinct operation (e.g. __len__, __add__). Most tables have only one entry; the tables for binary operators have two entries, one regular and one with reversed arguments. */ static PyObject * wrap_inquiry(PyObject *self, PyObject *args, void *wrapped) { inquiry func = (inquiry)wrapped; int res; if (!check_num_args(args, 0)) return NULL; res = (*func)(self); if (res == -1 && PyErr_Occurred()) return NULL; return PyInt_FromLong((long)res); } static PyObject * wrap_inquirypred(PyObject *self, PyObject *args, void *wrapped) { inquiry func = (inquiry)wrapped; int res; if (!check_num_args(args, 0)) return NULL; res = (*func)(self); if (res == -1 && PyErr_Occurred()) return NULL; return PyBool_FromLong((long)res); } static PyObject * wrap_binaryfunc(PyObject *self, PyObject *args, void *wrapped) { binaryfunc func = (binaryfunc)wrapped; PyObject *other; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); return (*func)(self, other); } static PyObject * wrap_binaryfunc_l(PyObject *self, PyObject *args, void *wrapped) { binaryfunc func = (binaryfunc)wrapped; PyObject *other; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); if (!(self->ob_type->tp_flags & Py_TPFLAGS_CHECKTYPES) && !PyType_IsSubtype(other->ob_type, self->ob_type)) { Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } return (*func)(self, other); } static PyObject * wrap_binaryfunc_r(PyObject *self, PyObject *args, void *wrapped) { binaryfunc func = (binaryfunc)wrapped; PyObject *other; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); if (!(self->ob_type->tp_flags & Py_TPFLAGS_CHECKTYPES) && !PyType_IsSubtype(other->ob_type, self->ob_type)) { Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } return (*func)(other, self); } static PyObject * wrap_coercefunc(PyObject *self, PyObject *args, void *wrapped) { coercion func = (coercion)wrapped; PyObject *other, *res; int ok; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); ok = func(&self, &other); if (ok < 0) return NULL; if (ok > 0) { Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } res = PyTuple_New(2); if (res == NULL) { Py_DECREF(self); Py_DECREF(other); return NULL; } PyTuple_SET_ITEM(res, 0, self); PyTuple_SET_ITEM(res, 1, other); return res; } static PyObject * wrap_ternaryfunc(PyObject *self, PyObject *args, void *wrapped) { ternaryfunc func = (ternaryfunc)wrapped; PyObject *other; PyObject *third = Py_None; /* Note: This wrapper only works for __pow__() */ if (!PyArg_UnpackTuple(args, "", 1, 2, &other, &third)) return NULL; return (*func)(self, other, third); } static PyObject * wrap_ternaryfunc_r(PyObject *self, PyObject *args, void *wrapped) { ternaryfunc func = (ternaryfunc)wrapped; PyObject *other; PyObject *third = Py_None; /* Note: This wrapper only works for __pow__() */ if (!PyArg_UnpackTuple(args, "", 1, 2, &other, &third)) return NULL; return (*func)(other, self, third); } static PyObject * wrap_unaryfunc(PyObject *self, PyObject *args, void *wrapped) { unaryfunc func = (unaryfunc)wrapped; if (!check_num_args(args, 0)) return NULL; return (*func)(self); } static PyObject * wrap_intargfunc(PyObject *self, PyObject *args, void *wrapped) { intargfunc func = (intargfunc)wrapped; int i; if (!PyArg_ParseTuple(args, "i", &i)) return NULL; return (*func)(self, i); } static int getindex(PyObject *self, PyObject *arg) { int i; i = PyInt_AsLong(arg); if (i == -1 && PyErr_Occurred()) return -1; if (i < 0) { PySequenceMethods *sq = self->ob_type->tp_as_sequence; if (sq && sq->sq_length) { int n = (*sq->sq_length)(self); if (n < 0) return -1; i += n; } } return i; } static PyObject * wrap_sq_item(PyObject *self, PyObject *args, void *wrapped) { intargfunc func = (intargfunc)wrapped; PyObject *arg; int i; if (PyTuple_GET_SIZE(args) == 1) { arg = PyTuple_GET_ITEM(args, 0); i = getindex(self, arg); if (i == -1 && PyErr_Occurred()) return NULL; return (*func)(self, i); } check_num_args(args, 1); assert(PyErr_Occurred()); return NULL; } static PyObject * wrap_intintargfunc(PyObject *self, PyObject *args, void *wrapped) { intintargfunc func = (intintargfunc)wrapped; int i, j; if (!PyArg_ParseTuple(args, "ii", &i, &j)) return NULL; return (*func)(self, i, j); } static PyObject * wrap_sq_setitem(PyObject *self, PyObject *args, void *wrapped) { intobjargproc func = (intobjargproc)wrapped; int i, res; PyObject *arg, *value; if (!PyArg_UnpackTuple(args, "", 2, 2, &arg, &value)) return NULL; i = getindex(self, arg); if (i == -1 && PyErr_Occurred()) return NULL; res = (*func)(self, i, value); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_sq_delitem(PyObject *self, PyObject *args, void *wrapped) { intobjargproc func = (intobjargproc)wrapped; int i, res; PyObject *arg; if (!check_num_args(args, 1)) return NULL; arg = PyTuple_GET_ITEM(args, 0); i = getindex(self, arg); if (i == -1 && PyErr_Occurred()) return NULL; res = (*func)(self, i, NULL); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_intintobjargproc(PyObject *self, PyObject *args, void *wrapped) { intintobjargproc func = (intintobjargproc)wrapped; int i, j, res; PyObject *value; if (!PyArg_ParseTuple(args, "iiO", &i, &j, &value)) return NULL; res = (*func)(self, i, j, value); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_delslice(PyObject *self, PyObject *args, void *wrapped) { intintobjargproc func = (intintobjargproc)wrapped; int i, j, res; if (!PyArg_ParseTuple(args, "ii", &i, &j)) return NULL; res = (*func)(self, i, j, NULL); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } /* XXX objobjproc is a misnomer; should be objargpred */ static PyObject * wrap_objobjproc(PyObject *self, PyObject *args, void *wrapped) { objobjproc func = (objobjproc)wrapped; int res; PyObject *value; if (!check_num_args(args, 1)) return NULL; value = PyTuple_GET_ITEM(args, 0); res = (*func)(self, value); if (res == -1 && PyErr_Occurred()) return NULL; else return PyBool_FromLong(res); } static PyObject * wrap_objobjargproc(PyObject *self, PyObject *args, void *wrapped) { objobjargproc func = (objobjargproc)wrapped; int res; PyObject *key, *value; if (!PyArg_UnpackTuple(args, "", 2, 2, &key, &value)) return NULL; res = (*func)(self, key, value); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_delitem(PyObject *self, PyObject *args, void *wrapped) { objobjargproc func = (objobjargproc)wrapped; int res; PyObject *key; if (!check_num_args(args, 1)) return NULL; key = PyTuple_GET_ITEM(args, 0); res = (*func)(self, key, NULL); if (res == -1 && PyErr_Occurred()) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_cmpfunc(PyObject *self, PyObject *args, void *wrapped) { cmpfunc func = (cmpfunc)wrapped; int res; PyObject *other; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); if (other->ob_type->tp_compare != func && !PyType_IsSubtype(other->ob_type, self->ob_type)) { PyErr_Format( PyExc_TypeError, "%s.__cmp__(x,y) requires y to be a '%s', not a '%s'", self->ob_type->tp_name, self->ob_type->tp_name, other->ob_type->tp_name); return NULL; } res = (*func)(self, other); if (PyErr_Occurred()) return NULL; return PyInt_FromLong((long)res); } /* Helper to check for object.__setattr__ or __delattr__ applied to a type. This is called the Carlo Verre hack after its discoverer. */ static int hackcheck(PyObject *self, setattrofunc func, char *what) { PyTypeObject *type = self->ob_type; while (type && type->tp_flags & Py_TPFLAGS_HEAPTYPE) type = type->tp_base; if (type->tp_setattro != func) { PyErr_Format(PyExc_TypeError, "can't apply this %s to %s object", what, type->tp_name); return 0; } return 1; } static PyObject * wrap_setattr(PyObject *self, PyObject *args, void *wrapped) { setattrofunc func = (setattrofunc)wrapped; int res; PyObject *name, *value; if (!PyArg_UnpackTuple(args, "", 2, 2, &name, &value)) return NULL; if (!hackcheck(self, func, "__setattr__")) return NULL; res = (*func)(self, name, value); if (res < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_delattr(PyObject *self, PyObject *args, void *wrapped) { setattrofunc func = (setattrofunc)wrapped; int res; PyObject *name; if (!check_num_args(args, 1)) return NULL; name = PyTuple_GET_ITEM(args, 0); if (!hackcheck(self, func, "__delattr__")) return NULL; res = (*func)(self, name, NULL); if (res < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_hashfunc(PyObject *self, PyObject *args, void *wrapped) { hashfunc func = (hashfunc)wrapped; long res; if (!check_num_args(args, 0)) return NULL; res = (*func)(self); if (res == -1 && PyErr_Occurred()) return NULL; return PyInt_FromLong(res); } static PyObject * wrap_call(PyObject *self, PyObject *args, void *wrapped, PyObject *kwds) { ternaryfunc func = (ternaryfunc)wrapped; return (*func)(self, args, kwds); } static PyObject * wrap_richcmpfunc(PyObject *self, PyObject *args, void *wrapped, int op) { richcmpfunc func = (richcmpfunc)wrapped; PyObject *other; if (!check_num_args(args, 1)) return NULL; other = PyTuple_GET_ITEM(args, 0); return (*func)(self, other, op); } #undef RICHCMP_WRAPPER #define RICHCMP_WRAPPER(NAME, OP) \ static PyObject * \ richcmp_##NAME(PyObject *self, PyObject *args, void *wrapped) \ { \ return wrap_richcmpfunc(self, args, wrapped, OP); \ } RICHCMP_WRAPPER(lt, Py_LT) RICHCMP_WRAPPER(le, Py_LE) RICHCMP_WRAPPER(eq, Py_EQ) RICHCMP_WRAPPER(ne, Py_NE) RICHCMP_WRAPPER(gt, Py_GT) RICHCMP_WRAPPER(ge, Py_GE) static PyObject * wrap_next(PyObject *self, PyObject *args, void *wrapped) { unaryfunc func = (unaryfunc)wrapped; PyObject *res; if (!check_num_args(args, 0)) return NULL; res = (*func)(self); if (res == NULL && !PyErr_Occurred()) PyErr_SetNone(PyExc_StopIteration); return res; } static PyObject * wrap_descr_get(PyObject *self, PyObject *args, void *wrapped) { descrgetfunc func = (descrgetfunc)wrapped; PyObject *obj; PyObject *type = NULL; if (!PyArg_UnpackTuple(args, "", 1, 2, &obj, &type)) return NULL; if (obj == Py_None) obj = NULL; if (type == Py_None) type = NULL; if (type == NULL &&obj == NULL) { PyErr_SetString(PyExc_TypeError, "__get__(None, None) is invalid"); return NULL; } return (*func)(self, obj, type); } static PyObject * wrap_descr_set(PyObject *self, PyObject *args, void *wrapped) { descrsetfunc func = (descrsetfunc)wrapped; PyObject *obj, *value; int ret; if (!PyArg_UnpackTuple(args, "", 2, 2, &obj, &value)) return NULL; ret = (*func)(self, obj, value); if (ret < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_descr_delete(PyObject *self, PyObject *args, void *wrapped) { descrsetfunc func = (descrsetfunc)wrapped; PyObject *obj; int ret; if (!check_num_args(args, 1)) return NULL; obj = PyTuple_GET_ITEM(args, 0); ret = (*func)(self, obj, NULL); if (ret < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * wrap_init(PyObject *self, PyObject *args, void *wrapped, PyObject *kwds) { initproc func = (initproc)wrapped; if (func(self, args, kwds) < 0) return NULL; Py_INCREF(Py_None); return Py_None; } static PyObject * tp_new_wrapper(PyObject *self, PyObject *args, PyObject *kwds) { PyTypeObject *type, *subtype, *staticbase; PyObject *arg0, *res; if (self == NULL || !PyType_Check(self)) Py_FatalError("__new__() called with non-type 'self'"); type = (PyTypeObject *)self; if (!PyTuple_Check(args) || PyTuple_GET_SIZE(args) < 1) { PyErr_Format(PyExc_TypeError, "%s.__new__(): not enough arguments", type->tp_name); return NULL; } arg0 = PyTuple_GET_ITEM(args, 0); if (!PyType_Check(arg0)) { PyErr_Format(PyExc_TypeError, "%s.__new__(X): X is not a type object (%s)", type->tp_name, arg0->ob_type->tp_name); return NULL; } subtype = (PyTypeObject *)arg0; if (!PyType_IsSubtype(subtype, type)) { PyErr_Format(PyExc_TypeError, "%s.__new__(%s): %s is not a subtype of %s", type->tp_name, subtype->tp_name, subtype->tp_name, type->tp_name); return NULL; } /* Check that the use doesn't do something silly and unsafe like object.__new__(dict). To do this, we check that the most derived base that's not a heap type is this type. */ staticbase = subtype; while (staticbase && (staticbase->tp_flags & Py_TPFLAGS_HEAPTYPE)) staticbase = staticbase->tp_base; if (staticbase->tp_new != type->tp_new) { PyErr_Format(PyExc_TypeError, "%s.__new__(%s) is not safe, use %s.__new__()", type->tp_name, subtype->tp_name, staticbase == NULL ? "?" : staticbase->tp_name); return NULL; } args = PyTuple_GetSlice(args, 1, PyTuple_GET_SIZE(args)); if (args == NULL) return NULL; res = type->tp_new(subtype, args, kwds); Py_DECREF(args); return res; } static struct PyMethodDef tp_new_methoddef[] = { {"__new__", (PyCFunction)tp_new_wrapper, METH_KEYWORDS, PyDoc_STR("T.__new__(S, ...) -> " "a new object with type S, a subtype of T")}, {0} }; static int add_tp_new_wrapper(PyTypeObject *type) { PyObject *func; if (PyDict_GetItemString(type->tp_dict, "__new__") != NULL) return 0; func = PyCFunction_New(tp_new_methoddef, (PyObject *)type); if (func == NULL) return -1; if (PyDict_SetItemString(type->tp_dict, "__new__", func)) { Py_DECREF(func); return -1; } Py_DECREF(func); return 0; } /* Slot wrappers that call the corresponding __foo__ slot. See comments below at override_slots() for more explanation. */ #define SLOT0(FUNCNAME, OPSTR) \ static PyObject * \ FUNCNAME(PyObject *self) \ { \ static PyObject *cache_str; \ return call_method(self, OPSTR, &cache_str, "()"); \ } #define SLOT1(FUNCNAME, OPSTR, ARG1TYPE, ARGCODES) \ static PyObject * \ FUNCNAME(PyObject *self, ARG1TYPE arg1) \ { \ static PyObject *cache_str; \ return call_method(self, OPSTR, &cache_str, "(" ARGCODES ")", arg1); \ } /* Boolean helper for SLOT1BINFULL(). right.__class__ is a nontrivial subclass of left.__class__. */ static int method_is_overloaded(PyObject *left, PyObject *right, char *name) { PyObject *a, *b; int ok; b = PyObject_GetAttrString((PyObject *)(right->ob_type), name); if (b == NULL) { PyErr_Clear(); /* If right doesn't have it, it's not overloaded */ return 0; } a = PyObject_GetAttrString((PyObject *)(left->ob_type), name); if (a == NULL) { PyErr_Clear(); Py_DECREF(b); /* If right has it but left doesn't, it's overloaded */ return 1; } ok = PyObject_RichCompareBool(a, b, Py_NE); Py_DECREF(a); Py_DECREF(b); if (ok < 0) { PyErr_Clear(); return 0; } return ok; } #define SLOT1BINFULL(FUNCNAME, TESTFUNC, SLOTNAME, OPSTR, ROPSTR) \ static PyObject * \ FUNCNAME(PyObject *self, PyObject *other) \ { \ static PyObject *cache_str, *rcache_str; \ int do_other = self->ob_type != other->ob_type && \ other->ob_type->tp_as_number != NULL && \ other->ob_type->tp_as_number->SLOTNAME == TESTFUNC; \ if (self->ob_type->tp_as_number != NULL && \ self->ob_type->tp_as_number->SLOTNAME == TESTFUNC) { \ PyObject *r; \ if (do_other && \ PyType_IsSubtype(other->ob_type, self->ob_type) && \ method_is_overloaded(self, other, ROPSTR)) { \ r = call_maybe( \ other, ROPSTR, &rcache_str, "(O)", self); \ if (r != Py_NotImplemented) \ return r; \ Py_DECREF(r); \ do_other = 0; \ } \ r = call_maybe( \ self, OPSTR, &cache_str, "(O)", other); \ if (r != Py_NotImplemented || \ other->ob_type == self->ob_type) \ return r; \ Py_DECREF(r); \ } \ if (do_other) { \ return call_maybe( \ other, ROPSTR, &rcache_str, "(O)", self); \ } \ Py_INCREF(Py_NotImplemented); \ return Py_NotImplemented; \ } #define SLOT1BIN(FUNCNAME, SLOTNAME, OPSTR, ROPSTR) \ SLOT1BINFULL(FUNCNAME, FUNCNAME, SLOTNAME, OPSTR, ROPSTR) #define SLOT2(FUNCNAME, OPSTR, ARG1TYPE, ARG2TYPE, ARGCODES) \ static PyObject * \ FUNCNAME(PyObject *self, ARG1TYPE arg1, ARG2TYPE arg2) \ { \ static PyObject *cache_str; \ return call_method(self, OPSTR, &cache_str, \ "(" ARGCODES ")", arg1, arg2); \ } static int slot_sq_length(PyObject *self) { static PyObject *len_str; PyObject *res = call_method(self, "__len__", &len_str, "()"); long temp; int len; if (res == NULL) return -1; temp = PyInt_AsLong(res); len = (int)temp; Py_DECREF(res); if (len == -1 && PyErr_Occurred()) return -1; #if SIZEOF_INT < SIZEOF_LONG /* Overflow check -- range of PyInt is more than C int */ if (len != temp) { PyErr_SetString(PyExc_OverflowError, "__len__() should return 0 <= outcome < 2**31"); return -1; } #endif if (len < 0) { PyErr_SetString(PyExc_ValueError, "__len__() should return >= 0"); return -1; } return len; } /* Super-optimized version of slot_sq_item. Other slots could do the same... */ static PyObject * slot_sq_item(PyObject *self, int i) { static PyObject *getitem_str; PyObject *func, *args = NULL, *ival = NULL, *retval = NULL; descrgetfunc f; if (getitem_str == NULL) { getitem_str = PyString_InternFromString("__getitem__"); if (getitem_str == NULL) return NULL; } func = _PyType_Lookup(self->ob_type, getitem_str); if (func != NULL) { if ((f = func->ob_type->tp_descr_get) == NULL) Py_INCREF(func); else { func = f(func, self, (PyObject *)(self->ob_type)); if (func == NULL) { return NULL; } } ival = PyInt_FromLong(i); if (ival != NULL) { args = PyTuple_New(1); if (args != NULL) { PyTuple_SET_ITEM(args, 0, ival); retval = PyObject_Call(func, args, NULL); Py_XDECREF(args); Py_XDECREF(func); return retval; } } } else { PyErr_SetObject(PyExc_AttributeError, getitem_str); } Py_XDECREF(args); Py_XDECREF(ival); Py_XDECREF(func); return NULL; } SLOT2(slot_sq_slice, "__getslice__", int, int, "ii") static int slot_sq_ass_item(PyObject *self, int index, PyObject *value) { PyObject *res; static PyObject *delitem_str, *setitem_str; if (value == NULL) res = call_method(self, "__delitem__", &delitem_str, "(i)", index); else res = call_method(self, "__setitem__", &setitem_str, "(iO)", index, value); if (res == NULL) return -1; Py_DECREF(res); return 0; } static int slot_sq_ass_slice(PyObject *self, int i, int j, PyObject *value) { PyObject *res; static PyObject *delslice_str, *setslice_str; if (value == NULL) res = call_method(self, "__delslice__", &delslice_str, "(ii)", i, j); else res = call_method(self, "__setslice__", &setslice_str, "(iiO)", i, j, value); if (res == NULL) return -1; Py_DECREF(res); return 0; } static int slot_sq_contains(PyObject *self, PyObject *value) { PyObject *func, *res, *args; int result = -1; static PyObject *contains_str; func = lookup_maybe(self, "__contains__", &contains_str); if (func != NULL) { args = PyTuple_Pack(1, value); if (args == NULL) res = NULL; else { res = PyObject_Call(func, args, NULL); Py_DECREF(args); } Py_DECREF(func); if (res != NULL) { result = PyObject_IsTrue(res); Py_DECREF(res); } } else if (! PyErr_Occurred()) { result = _PySequence_IterSearch(self, value, PY_ITERSEARCH_CONTAINS); } return result; } #define slot_mp_length slot_sq_length SLOT1(slot_mp_subscript, "__getitem__", PyObject *, "O") static int slot_mp_ass_subscript(PyObject *self, PyObject *key, PyObject *value) { PyObject *res; static PyObject *delitem_str, *setitem_str; if (value == NULL) res = call_method(self, "__delitem__", &delitem_str, "(O)", key); else res = call_method(self, "__setitem__", &setitem_str, "(OO)", key, value); if (res == NULL) return -1; Py_DECREF(res); return 0; } SLOT1BIN(slot_nb_add, nb_add, "__add__", "__radd__") SLOT1BIN(slot_nb_subtract, nb_subtract, "__sub__", "__rsub__") SLOT1BIN(slot_nb_multiply, nb_multiply, "__mul__", "__rmul__") SLOT1BIN(slot_nb_divide, nb_divide, "__div__", "__rdiv__") SLOT1BIN(slot_nb_remainder, nb_remainder, "__mod__", "__rmod__") SLOT1BIN(slot_nb_divmod, nb_divmod, "__divmod__", "__rdivmod__") static PyObject *slot_nb_power(PyObject *, PyObject *, PyObject *); SLOT1BINFULL(slot_nb_power_binary, slot_nb_power, nb_power, "__pow__", "__rpow__") static PyObject * slot_nb_power(PyObject *self, PyObject *other, PyObject *modulus) { static PyObject *pow_str; if (modulus == Py_None) return slot_nb_power_binary(self, other); /* Three-arg power doesn't use __rpow__. But ternary_op can call this when the second argument's type uses slot_nb_power, so check before calling self.__pow__. */ if (self->ob_type->tp_as_number != NULL && self->ob_type->tp_as_number->nb_power == slot_nb_power) { return call_method(self, "__pow__", &pow_str, "(OO)", other, modulus); } Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } SLOT0(slot_nb_negative, "__neg__") SLOT0(slot_nb_positive, "__pos__") SLOT0(slot_nb_absolute, "__abs__") static int slot_nb_nonzero(PyObject *self) { PyObject *func, *args; static PyObject *nonzero_str, *len_str; int result = -1; func = lookup_maybe(self, "__nonzero__", &nonzero_str); if (func == NULL) { if (PyErr_Occurred()) return -1; func = lookup_maybe(self, "__len__", &len_str); if (func == NULL) return PyErr_Occurred() ? -1 : 1; } args = PyTuple_New(0); if (args != NULL) { PyObject *temp = PyObject_Call(func, args, NULL); Py_DECREF(args); if (temp != NULL) { if (PyInt_CheckExact(temp) || PyBool_Check(temp)) result = PyObject_IsTrue(temp); else { PyErr_Format(PyExc_TypeError, "__nonzero__ should return " "bool or int, returned %s", temp->ob_type->tp_name); result = -1; } Py_DECREF(temp); } } Py_DECREF(func); return result; } SLOT0(slot_nb_invert, "__invert__") SLOT1BIN(slot_nb_lshift, nb_lshift, "__lshift__", "__rlshift__") SLOT1BIN(slot_nb_rshift, nb_rshift, "__rshift__", "__rrshift__") SLOT1BIN(slot_nb_and, nb_and, "__and__", "__rand__") SLOT1BIN(slot_nb_xor, nb_xor, "__xor__", "__rxor__") SLOT1BIN(slot_nb_or, nb_or, "__or__", "__ror__") static int slot_nb_coerce(PyObject **a, PyObject **b) { static PyObject *coerce_str; PyObject *self = *a, *other = *b; if (self->ob_type->tp_as_number != NULL && self->ob_type->tp_as_number->nb_coerce == slot_nb_coerce) { PyObject *r; r = call_maybe( self, "__coerce__", &coerce_str, "(O)", other); if (r == NULL) return -1; if (r == Py_NotImplemented) { Py_DECREF(r); } else { if (!PyTuple_Check(r) || PyTuple_GET_SIZE(r) != 2) { PyErr_SetString(PyExc_TypeError, "__coerce__ didn't return a 2-tuple"); Py_DECREF(r); return -1; } *a = PyTuple_GET_ITEM(r, 0); Py_INCREF(*a); *b = PyTuple_GET_ITEM(r, 1); Py_INCREF(*b); Py_DECREF(r); return 0; } } if (other->ob_type->tp_as_number != NULL && other->ob_type->tp_as_number->nb_coerce == slot_nb_coerce) { PyObject *r; r = call_maybe( other, "__coerce__", &coerce_str, "(O)", self); if (r == NULL) return -1; if (r == Py_NotImplemented) { Py_DECREF(r); return 1; } if (!PyTuple_Check(r) || PyTuple_GET_SIZE(r) != 2) { PyErr_SetString(PyExc_TypeError, "__coerce__ didn't return a 2-tuple"); Py_DECREF(r); return -1; } *a = PyTuple_GET_ITEM(r, 1); Py_INCREF(*a); *b = PyTuple_GET_ITEM(r, 0); Py_INCREF(*b); Py_DECREF(r); return 0; } return 1; } SLOT0(slot_nb_int, "__int__") SLOT0(slot_nb_long, "__long__") SLOT0(slot_nb_float, "__float__") SLOT0(slot_nb_oct, "__oct__") SLOT0(slot_nb_hex, "__hex__") SLOT1(slot_nb_inplace_add, "__iadd__", PyObject *, "O") SLOT1(slot_nb_inplace_subtract, "__isub__", PyObject *, "O") SLOT1(slot_nb_inplace_multiply, "__imul__", PyObject *, "O") SLOT1(slot_nb_inplace_divide, "__idiv__", PyObject *, "O") SLOT1(slot_nb_inplace_remainder, "__imod__", PyObject *, "O") SLOT1(slot_nb_inplace_power, "__ipow__", PyObject *, "O") SLOT1(slot_nb_inplace_lshift, "__ilshift__", PyObject *, "O") SLOT1(slot_nb_inplace_rshift, "__irshift__", PyObject *, "O") SLOT1(slot_nb_inplace_and, "__iand__", PyObject *, "O") SLOT1(slot_nb_inplace_xor, "__ixor__", PyObject *, "O") SLOT1(slot_nb_inplace_or, "__ior__", PyObject *, "O") SLOT1BIN(slot_nb_floor_divide, nb_floor_divide, "__floordiv__", "__rfloordiv__") SLOT1BIN(slot_nb_true_divide, nb_true_divide, "__truediv__", "__rtruediv__") SLOT1(slot_nb_inplace_floor_divide, "__ifloordiv__", PyObject *, "O") SLOT1(slot_nb_inplace_true_divide, "__itruediv__", PyObject *, "O") static int half_compare(PyObject *self, PyObject *other) { PyObject *func, *args, *res; static PyObject *cmp_str; int c; func = lookup_method(self, "__cmp__", &cmp_str); if (func == NULL) { PyErr_Clear(); } else { args = PyTuple_Pack(1, other); if (args == NULL) res = NULL; else { res = PyObject_Call(func, args, NULL); Py_DECREF(args); } Py_DECREF(func); if (res != Py_NotImplemented) { if (res == NULL) return -2; c = PyInt_AsLong(res); Py_DECREF(res); if (c == -1 && PyErr_Occurred()) return -2; return (c < 0) ? -1 : (c > 0) ? 1 : 0; } Py_DECREF(res); } return 2; } /* This slot is published for the benefit of try_3way_compare in object.c */ int _PyObject_SlotCompare(PyObject *self, PyObject *other) { int c; if (self->ob_type->tp_compare == _PyObject_SlotCompare) { c = half_compare(self, other); if (c <= 1) return c; } if (other->ob_type->tp_compare == _PyObject_SlotCompare) { c = half_compare(other, self); if (c < -1) return -2; if (c <= 1) return -c; } return (void *)self < (void *)other ? -1 : (void *)self > (void *)other ? 1 : 0; } static PyObject * slot_tp_repr(PyObject *self) { PyObject *func, *res; static PyObject *repr_str; func = lookup_method(self, "__repr__", &repr_str); if (func != NULL) { res = PyEval_CallObject(func, NULL); Py_DECREF(func); return res; } PyErr_Clear(); return PyString_FromFormat("<%s object at %p>", self->ob_type->tp_name, self); } static PyObject * slot_tp_str(PyObject *self) { PyObject *func, *res; static PyObject *str_str; func = lookup_method(self, "__str__", &str_str); if (func != NULL) { res = PyEval_CallObject(func, NULL); Py_DECREF(func); return res; } else { PyErr_Clear(); return slot_tp_repr(self); } } static long slot_tp_hash(PyObject *self) { PyObject *func; static PyObject *hash_str, *eq_str, *cmp_str; long h; func = lookup_method(self, "__hash__", &hash_str); if (func != NULL) { PyObject *res = PyEval_CallObject(func, NULL); Py_DECREF(func); if (res == NULL) return -1; h = PyInt_AsLong(res); Py_DECREF(res); } else { PyErr_Clear(); func = lookup_method(self, "__eq__", &eq_str); if (func == NULL) { PyErr_Clear(); func = lookup_method(self, "__cmp__", &cmp_str); } if (func != NULL) { Py_DECREF(func); PyErr_SetString(PyExc_TypeError, "unhashable type"); return -1; } PyErr_Clear(); h = _Py_HashPointer((void *)self); } if (h == -1 && !PyErr_Occurred()) h = -2; return h; } static PyObject * slot_tp_call(PyObject *self, PyObject *args, PyObject *kwds) { static PyObject *call_str; PyObject *meth = lookup_method(self, "__call__", &call_str); PyObject *res; if (meth == NULL) return NULL; res = PyObject_Call(meth, args, kwds); Py_DECREF(meth); return res; } /* There are two slot dispatch functions for tp_getattro. - slot_tp_getattro() is used when __getattribute__ is overridden but no __getattr__ hook is present; - slot_tp_getattr_hook() is used when a __getattr__ hook is present. The code in update_one_slot() always installs slot_tp_getattr_hook(); this detects the absence of __getattr__ and then installs the simpler slot if necessary. */ static PyObject * slot_tp_getattro(PyObject *self, PyObject *name) { static PyObject *getattribute_str = NULL; return call_method(self, "__getattribute__", &getattribute_str, "(O)", name); } static PyObject * slot_tp_getattr_hook(PyObject *self, PyObject *name) { PyTypeObject *tp = self->ob_type; PyObject *getattr, *getattribute, *res; static PyObject *getattribute_str = NULL; static PyObject *getattr_str = NULL; if (getattr_str == NULL) { getattr_str = PyString_InternFromString("__getattr__"); if (getattr_str == NULL) return NULL; } if (getattribute_str == NULL) { getattribute_str = PyString_InternFromString("__getattribute__"); if (getattribute_str == NULL) return NULL; } getattr = _PyType_Lookup(tp, getattr_str); if (getattr == NULL) { /* No __getattr__ hook: use a simpler dispatcher */ tp->tp_getattro = slot_tp_getattro; return slot_tp_getattro(self, name); } getattribute = _PyType_Lookup(tp, getattribute_str); if (getattribute == NULL || (getattribute->ob_type == &PyWrapperDescr_Type && ((PyWrapperDescrObject *)getattribute)->d_wrapped == (void *)PyObject_GenericGetAttr)) res = PyObject_GenericGetAttr(self, name); else res = PyObject_CallFunction(getattribute, "OO", self, name); if (res == NULL && PyErr_ExceptionMatches(PyExc_AttributeError)) { PyErr_Clear(); res = PyObject_CallFunction(getattr, "OO", self, name); } return res; } static int slot_tp_setattro(PyObject *self, PyObject *name, PyObject *value) { PyObject *res; static PyObject *delattr_str, *setattr_str; if (value == NULL) res = call_method(self, "__delattr__", &delattr_str, "(O)", name); else res = call_method(self, "__setattr__", &setattr_str, "(OO)", name, value); if (res == NULL) return -1; Py_DECREF(res); return 0; } /* Map rich comparison operators to their __xx__ namesakes */ static char *name_op[] = { "__lt__", "__le__", "__eq__", "__ne__", "__gt__", "__ge__", }; static PyObject * half_richcompare(PyObject *self, PyObject *other, int op) { PyObject *func, *args, *res; static PyObject *op_str[6]; func = lookup_method(self, name_op[op], &op_str[op]); if (func == NULL) { PyErr_Clear(); Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } args = PyTuple_Pack(1, other); if (args == NULL) res = NULL; else { res = PyObject_Call(func, args, NULL); Py_DECREF(args); } Py_DECREF(func); return res; } static PyObject * slot_tp_richcompare(PyObject *self, PyObject *other, int op) { PyObject *res; if (self->ob_type->tp_richcompare == slot_tp_richcompare) { res = half_richcompare(self, other, op); if (res != Py_NotImplemented) return res; Py_DECREF(res); } if (other->ob_type->tp_richcompare == slot_tp_richcompare) { res = half_richcompare(other, self, _Py_SwappedOp[op]); if (res != Py_NotImplemented) { return res; } Py_DECREF(res); } Py_INCREF(Py_NotImplemented); return Py_NotImplemented; } static PyObject * slot_tp_iter(PyObject *self) { PyObject *func, *res; static PyObject *iter_str, *getitem_str; func = lookup_method(self, "__iter__", &iter_str); if (func != NULL) { PyObject *args; args = res = PyTuple_New(0); if (args != NULL) { res = PyObject_Call(func, args, NULL); Py_DECREF(args); } Py_DECREF(func); return res; } PyErr_Clear(); func = lookup_method(self, "__getitem__", &getitem_str); if (func == NULL) { PyErr_SetString(PyExc_TypeError, "iteration over non-sequence"); return NULL; } Py_DECREF(func); return PySeqIter_New(self); } static PyObject * slot_tp_iternext(PyObject *self) { static PyObject *next_str; return call_method(self, "next", &next_str, "()"); } static PyObject * slot_tp_descr_get(PyObject *self, PyObject *obj, PyObject *type) { PyTypeObject *tp = self->ob_type; PyObject *get; static PyObject *get_str = NULL; if (get_str == NULL) { get_str = PyString_InternFromString("__get__"); if (get_str == NULL) return NULL; } get = _PyType_Lookup(tp, get_str); if (get == NULL) { /* Avoid further slowdowns */ if (tp->tp_descr_get == slot_tp_descr_get) tp->tp_descr_get = NULL; Py_INCREF(self); return self; } if (obj == NULL) obj = Py_None; if (type == NULL) type = Py_None; return PyObject_CallFunction(get, "OOO", self, obj, type); } static int slot_tp_descr_set(PyObject *self, PyObject *target, PyObject *value) { PyObject *res; static PyObject *del_str, *set_str; if (value == NULL) res = call_method(self, "__delete__", &del_str, "(O)", target); else res = call_method(self, "__set__", &set_str, "(OO)", target, value); if (res == NULL) return -1; Py_DECREF(res); return 0; } static int slot_tp_init(PyObject *self, PyObject *args, PyObject *kwds) { static PyObject *init_str; PyObject *meth = lookup_method(self, "__init__", &init_str); PyObject *res; if (meth == NULL) return -1; res = PyObject_Call(meth, args, kwds); Py_DECREF(meth); if (res == NULL) return -1; if (res != Py_None) { PyErr_SetString(PyExc_TypeError, "__init__() should return None"); Py_DECREF(res); return -1; } Py_DECREF(res); return 0; } static PyObject * slot_tp_new(PyTypeObject *type, PyObject *args, PyObject *kwds) { static PyObject *new_str; PyObject *func; PyObject *newargs, *x; int i, n; if (new_str == NULL) { new_str = PyString_InternFromString("__new__"); if (new_str == NULL) return NULL; } func = PyObject_GetAttr((PyObject *)type, new_str); if (func == NULL) return NULL; assert(PyTuple_Check(args)); n = PyTuple_GET_SIZE(args); newargs = PyTuple_New(n+1); if (newargs == NULL) return NULL; Py_INCREF(type); PyTuple_SET_ITEM(newargs, 0, (PyObject *)type); for (i = 0; i < n; i++) { x = PyTuple_GET_ITEM(args, i); Py_INCREF(x); PyTuple_SET_ITEM(newargs, i+1, x); } x = PyObject_Call(func, newargs, kwds); Py_DECREF(newargs); Py_DECREF(func); return x; } static void slot_tp_del(PyObject *self) { static PyObject *del_str = NULL; PyObject *del, *res; PyObject *error_type, *error_value, *error_traceback; /* Temporarily resurrect the object. */ assert(self->ob_refcnt == 0); self->ob_refcnt = 1; /* Save the current exception, if any. */ PyErr_Fetch(&error_type, &error_value, &error_traceback); /* Execute __del__ method, if any. */ del = lookup_maybe(self, "__del__", &del_str); if (del != NULL) { res = PyEval_CallObject(del, NULL); if (res == NULL) PyErr_WriteUnraisable(del); else Py_DECREF(res); Py_DECREF(del); } /* Restore the saved exception. */ PyErr_Restore(error_type, error_value, error_traceback); /* Undo the temporary resurrection; can't use DECREF here, it would * cause a recursive call. */ assert(self->ob_refcnt > 0); if (--self->ob_refcnt == 0) return; /* this is the normal path out */ /* __del__ resurrected it! Make it look like the original Py_DECREF * never happened. */ { int refcnt = self->ob_refcnt; _Py_NewReference(self); self->ob_refcnt = refcnt; } assert(!PyType_IS_GC(self->ob_type) || _Py_AS_GC(self)->gc.gc_refs != _PyGC_REFS_UNTRACKED); /* If Py_REF_DEBUG, _Py_NewReference bumped _Py_RefTotal, so * we need to undo that. */ _Py_DEC_REFTOTAL; /* If Py_TRACE_REFS, _Py_NewReference re-added self to the object * chain, so no more to do there. * If COUNT_ALLOCS, the original decref bumped tp_frees, and * _Py_NewReference bumped tp_allocs: both of those need to be * undone. */ #ifdef COUNT_ALLOCS --self->ob_type->tp_frees; --self->ob_type->tp_allocs; #endif } /* Table mapping __foo__ names to tp_foo offsets and slot_tp_foo wrapper functions. The offsets here are relative to the 'PyHeapTypeObject' structure, which incorporates the additional structures used for numbers, sequences and mappings. Note that multiple names may map to the same slot (e.g. __eq__, __ne__ etc. all map to tp_richcompare) and one name may map to multiple slots (e.g. __str__ affects tp_str as well as tp_repr). The table is terminated with an all-zero entry. (This table is further initialized and sorted in init_slotdefs() below.) */ typedef struct wrapperbase slotdef; #undef TPSLOT #undef FLSLOT #undef ETSLOT #undef SQSLOT #undef MPSLOT #undef NBSLOT #undef UNSLOT #undef IBSLOT #undef BINSLOT #undef RBINSLOT #define TPSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ {NAME, offsetof(PyTypeObject, SLOT), (void *)(FUNCTION), WRAPPER, \ PyDoc_STR(DOC)} #define FLSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC, FLAGS) \ {NAME, offsetof(PyTypeObject, SLOT), (void *)(FUNCTION), WRAPPER, \ PyDoc_STR(DOC), FLAGS} #define ETSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ {NAME, offsetof(PyHeapTypeObject, SLOT), (void *)(FUNCTION), WRAPPER, \ PyDoc_STR(DOC)} #define SQSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ ETSLOT(NAME, as_sequence.SLOT, FUNCTION, WRAPPER, DOC) #define MPSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ ETSLOT(NAME, as_mapping.SLOT, FUNCTION, WRAPPER, DOC) #define NBSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, WRAPPER, DOC) #define UNSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, WRAPPER, \ "x." NAME "() <==> " DOC) #define IBSLOT(NAME, SLOT, FUNCTION, WRAPPER, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, WRAPPER, \ "x." NAME "(y) <==> x" DOC "y") #define BINSLOT(NAME, SLOT, FUNCTION, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, wrap_binaryfunc_l, \ "x." NAME "(y) <==> x" DOC "y") #define RBINSLOT(NAME, SLOT, FUNCTION, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, wrap_binaryfunc_r, \ "x." NAME "(y) <==> y" DOC "x") #define BINSLOTNOTINFIX(NAME, SLOT, FUNCTION, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, wrap_binaryfunc_l, \ "x." NAME "(y) <==> " DOC) #define RBINSLOTNOTINFIX(NAME, SLOT, FUNCTION, DOC) \ ETSLOT(NAME, as_number.SLOT, FUNCTION, wrap_binaryfunc_r, \ "x." NAME "(y) <==> " DOC) static slotdef slotdefs[] = { SQSLOT("__len__", sq_length, slot_sq_length, wrap_inquiry, "x.__len__() <==> len(x)"), /* Heap types defining __add__/__mul__ have sq_concat/sq_repeat == NULL. The logic in abstract.c always falls back to nb_add/nb_multiply in this case. Defining both the nb_* and the sq_* slots to call the user-defined methods has unexpected side-effects, as shown by test_descr.notimplemented() */ SQSLOT("__add__", sq_concat, NULL, wrap_binaryfunc, "x.__add__(y) <==> x+y"), SQSLOT("__mul__", sq_repeat, NULL, wrap_intargfunc, "x.__mul__(n) <==> x*n"), SQSLOT("__rmul__", sq_repeat, NULL, wrap_intargfunc, "x.__rmul__(n) <==> n*x"), SQSLOT("__getitem__", sq_item, slot_sq_item, wrap_sq_item, "x.__getitem__(y) <==> x[y]"), SQSLOT("__getslice__", sq_slice, slot_sq_slice, wrap_intintargfunc, "x.__getslice__(i, j) <==> x[i:j]\n\ \n\ Use of negative indices is not supported."), SQSLOT("__setitem__", sq_ass_item, slot_sq_ass_item, wrap_sq_setitem, "x.__setitem__(i, y) <==> x[i]=y"), SQSLOT("__delitem__", sq_ass_item, slot_sq_ass_item, wrap_sq_delitem, "x.__delitem__(y) <==> del x[y]"), SQSLOT("__setslice__", sq_ass_slice, slot_sq_ass_slice, wrap_intintobjargproc, "x.__setslice__(i, j, y) <==> x[i:j]=y\n\ \n\ Use of negative indices is not supported."), SQSLOT("__delslice__", sq_ass_slice, slot_sq_ass_slice, wrap_delslice, "x.__delslice__(i, j) <==> del x[i:j]\n\ \n\ Use of negative indices is not supported."), SQSLOT("__contains__", sq_contains, slot_sq_contains, wrap_objobjproc, "x.__contains__(y) <==> y in x"), SQSLOT("__iadd__", sq_inplace_concat, NULL, wrap_binaryfunc, "x.__iadd__(y) <==> x+=y"), SQSLOT("__imul__", sq_inplace_repeat, NULL, wrap_intargfunc, "x.__imul__(y) <==> x*=y"), MPSLOT("__len__", mp_length, slot_mp_length, wrap_inquiry, "x.__len__() <==> len(x)"), MPSLOT("__getitem__", mp_subscript, slot_mp_subscript, wrap_binaryfunc, "x.__getitem__(y) <==> x[y]"), MPSLOT("__setitem__", mp_ass_subscript, slot_mp_ass_subscript, wrap_objobjargproc, "x.__setitem__(i, y) <==> x[i]=y"), MPSLOT("__delitem__", mp_ass_subscript, slot_mp_ass_subscript, wrap_delitem, "x.__delitem__(y) <==> del x[y]"), BINSLOT("__add__", nb_add, slot_nb_add, "+"), RBINSLOT("__radd__", nb_add, slot_nb_add, "+"), BINSLOT("__sub__", nb_subtract, slot_nb_subtract, "-"), RBINSLOT("__rsub__", nb_subtract, slot_nb_subtract, "-"), BINSLOT("__mul__", nb_multiply, slot_nb_multiply, "*"), RBINSLOT("__rmul__", nb_multiply, slot_nb_multiply, "*"), BINSLOT("__div__", nb_divide, slot_nb_divide, "/"), RBINSLOT("__rdiv__", nb_divide, slot_nb_divide, "/"), BINSLOT("__mod__", nb_remainder, slot_nb_remainder, "%"), RBINSLOT("__rmod__", nb_remainder, slot_nb_remainder, "%"), BINSLOTNOTINFIX("__divmod__", nb_divmod, slot_nb_divmod, "divmod(x, y)"), RBINSLOTNOTINFIX("__rdivmod__", nb_divmod, slot_nb_divmod, "divmod(y, x)"), NBSLOT("__pow__", nb_power, slot_nb_power, wrap_ternaryfunc, "x.__pow__(y[, z]) <==> pow(x, y[, z])"), NBSLOT("__rpow__", nb_power, slot_nb_power, wrap_ternaryfunc_r, "y.__rpow__(x[, z]) <==> pow(x, y[, z])"), UNSLOT("__neg__", nb_negative, slot_nb_negative, wrap_unaryfunc, "-x"), UNSLOT("__pos__", nb_positive, slot_nb_positive, wrap_unaryfunc, "+x"), UNSLOT("__abs__", nb_absolute, slot_nb_absolute, wrap_unaryfunc, "abs(x)"), UNSLOT("__nonzero__", nb_nonzero, slot_nb_nonzero, wrap_inquirypred, "x != 0"), UNSLOT("__invert__", nb_invert, slot_nb_invert, wrap_unaryfunc, "~x"), BINSLOT("__lshift__", nb_lshift, slot_nb_lshift, "<<"), RBINSLOT("__rlshift__", nb_lshift, slot_nb_lshift, "<<"), BINSLOT("__rshift__", nb_rshift, slot_nb_rshift, ">>"), RBINSLOT("__rrshift__", nb_rshift, slot_nb_rshift, ">>"), BINSLOT("__and__", nb_and, slot_nb_and, "&"), RBINSLOT("__rand__", nb_and, slot_nb_and, "&"), BINSLOT("__xor__", nb_xor, slot_nb_xor, "^"), RBINSLOT("__rxor__", nb_xor, slot_nb_xor, "^"), BINSLOT("__or__", nb_or, slot_nb_or, "|"), RBINSLOT("__ror__", nb_or, slot_nb_or, "|"), NBSLOT("__coerce__", nb_coerce, slot_nb_coerce, wrap_coercefunc, "x.__coerce__(y) <==> coerce(x, y)"), UNSLOT("__int__", nb_int, slot_nb_int, wrap_unaryfunc, "int(x)"), UNSLOT("__long__", nb_long, slot_nb_long, wrap_unaryfunc, "long(x)"), UNSLOT("__float__", nb_float, slot_nb_float, wrap_unaryfunc, "float(x)"), UNSLOT("__oct__", nb_oct, slot_nb_oct, wrap_unaryfunc, "oct(x)"), UNSLOT("__hex__", nb_hex, slot_nb_hex, wrap_unaryfunc, "hex(x)"), IBSLOT("__iadd__", nb_inplace_add, slot_nb_inplace_add, wrap_binaryfunc, "+"), IBSLOT("__isub__", nb_inplace_subtract, slot_nb_inplace_subtract, wrap_binaryfunc, "-"), IBSLOT("__imul__", nb_inplace_multiply, slot_nb_inplace_multiply, wrap_binaryfunc, "*"), IBSLOT("__idiv__", nb_inplace_divide, slot_nb_inplace_divide, wrap_binaryfunc, "/"), IBSLOT("__imod__", nb_inplace_remainder, slot_nb_inplace_remainder, wrap_binaryfunc, "%"), IBSLOT("__ipow__", nb_inplace_power, slot_nb_inplace_power, wrap_binaryfunc, "**"), IBSLOT("__ilshift__", nb_inplace_lshift, slot_nb_inplace_lshift, wrap_binaryfunc, "<<"), IBSLOT("__irshift__", nb_inplace_rshift, slot_nb_inplace_rshift, wrap_binaryfunc, ">>"), IBSLOT("__iand__", nb_inplace_and, slot_nb_inplace_and, wrap_binaryfunc, "&"), IBSLOT("__ixor__", nb_inplace_xor, slot_nb_inplace_xor, wrap_binaryfunc, "^"), IBSLOT("__ior__", nb_inplace_or, slot_nb_inplace_or, wrap_binaryfunc, "|"), BINSLOT("__floordiv__", nb_floor_divide, slot_nb_floor_divide, "//"), RBINSLOT("__rfloordiv__", nb_floor_divide, slot_nb_floor_divide, "//"), BINSLOT("__truediv__", nb_true_divide, slot_nb_true_divide, "/"), RBINSLOT("__rtruediv__", nb_true_divide, slot_nb_true_divide, "/"), IBSLOT("__ifloordiv__", nb_inplace_floor_divide, slot_nb_inplace_floor_divide, wrap_binaryfunc, "//"), IBSLOT("__itruediv__", nb_inplace_true_divide, slot_nb_inplace_true_divide, wrap_binaryfunc, "/"), TPSLOT("__str__", tp_str, slot_tp_str, wrap_unaryfunc, "x.__str__() <==> str(x)"), TPSLOT("__str__", tp_print, NULL, NULL, ""), TPSLOT("__repr__", tp_repr, slot_tp_repr, wrap_unaryfunc, "x.__repr__() <==> repr(x)"), TPSLOT("__repr__", tp_print, NULL, NULL, ""), TPSLOT("__cmp__", tp_compare, _PyObject_SlotCompare, wrap_cmpfunc, "x.__cmp__(y) <==> cmp(x,y)"), TPSLOT("__hash__", tp_hash, slot_tp_hash, wrap_hashfunc, "x.__hash__() <==> hash(x)"), FLSLOT("__call__", tp_call, slot_tp_call, (wrapperfunc)wrap_call, "x.__call__(...) <==> x(...)", PyWrapperFlag_KEYWORDS), TPSLOT("__getattribute__", tp_getattro, slot_tp_getattr_hook, wrap_binaryfunc, "x.__getattribute__('name') <==> x.name"), TPSLOT("__getattribute__", tp_getattr, NULL, NULL, ""), TPSLOT("__getattr__", tp_getattro, slot_tp_getattr_hook, NULL, ""), TPSLOT("__getattr__", tp_getattr, NULL, NULL, ""), TPSLOT("__setattr__", tp_setattro, slot_tp_setattro, wrap_setattr, "x.__setattr__('name', value) <==> x.name = value"), TPSLOT("__setattr__", tp_setattr, NULL, NULL, ""), TPSLOT("__delattr__", tp_setattro, slot_tp_setattro, wrap_delattr, "x.__delattr__('name') <==> del x.name"), TPSLOT("__delattr__", tp_setattr, NULL, NULL, ""), TPSLOT("__lt__", tp_richcompare, slot_tp_richcompare, richcmp_lt, "x.__lt__(y) <==> x x<=y"), TPSLOT("__eq__", tp_richcompare, slot_tp_richcompare, richcmp_eq, "x.__eq__(y) <==> x==y"), TPSLOT("__ne__", tp_richcompare, slot_tp_richcompare, richcmp_ne, "x.__ne__(y) <==> x!=y"), TPSLOT("__gt__", tp_richcompare, slot_tp_richcompare, richcmp_gt, "x.__gt__(y) <==> x>y"), TPSLOT("__ge__", tp_richcompare, slot_tp_richcompare, richcmp_ge, "x.__ge__(y) <==> x>=y"), TPSLOT("__iter__", tp_iter, slot_tp_iter, wrap_unaryfunc, "x.__iter__() <==> iter(x)"), TPSLOT("next", tp_iternext, slot_tp_iternext, wrap_next, "x.next() -> the next value, or raise StopIteration"), TPSLOT("__get__", tp_descr_get, slot_tp_descr_get, wrap_descr_get, "descr.__get__(obj[, type]) -> value"), TPSLOT("__set__", tp_descr_set, slot_tp_descr_set, wrap_descr_set, "descr.__set__(obj, value)"), TPSLOT("__delete__", tp_descr_set, slot_tp_descr_set, wrap_descr_delete, "descr.__delete__(obj)"), FLSLOT("__init__", tp_init, slot_tp_init, (wrapperfunc)wrap_init, "x.__init__(...) initializes x; " "see x.__class__.__doc__ for signature", PyWrapperFlag_KEYWORDS), TPSLOT("__new__", tp_new, slot_tp_new, NULL, ""), TPSLOT("__del__", tp_del, slot_tp_del, NULL, ""), {NULL} }; /* Given a type pointer and an offset gotten from a slotdef entry, return a pointer to the actual slot. This is not quite the same as simply adding the offset to the type pointer, since it takes care to indirect through the proper indirection pointer (as_buffer, etc.); it returns NULL if the indirection pointer is NULL. */ static void ** slotptr(PyTypeObject *type, int offset) { char *ptr; /* Note: this depends on the order of the members of PyHeapTypeObject! */ assert(offset >= 0); assert(offset < offsetof(PyHeapTypeObject, as_buffer)); if (offset >= offsetof(PyHeapTypeObject, as_sequence)) { ptr = (void *)type->tp_as_sequence; offset -= offsetof(PyHeapTypeObject, as_sequence); } else if (offset >= offsetof(PyHeapTypeObject, as_mapping)) { ptr = (void *)type->tp_as_mapping; offset -= offsetof(PyHeapTypeObject, as_mapping); } else if (offset >= offsetof(PyHeapTypeObject, as_number)) { ptr = (void *)type->tp_as_number; offset -= offsetof(PyHeapTypeObject, as_number); } else { ptr = (void *)type; } if (ptr != NULL) ptr += offset; return (void **)ptr; } /* Length of array of slotdef pointers used to store slots with the same __name__. There should be at most MAX_EQUIV-1 slotdef entries with the same __name__, for any __name__. Since that's a static property, it is appropriate to declare fixed-size arrays for this. */ #define MAX_EQUIV 10 /* Return a slot pointer for a given name, but ONLY if the attribute has exactly one slot function. The name must be an interned string. */ static void ** resolve_slotdups(PyTypeObject *type, PyObject *name) { /* XXX Maybe this could be optimized more -- but is it worth it? */ /* pname and ptrs act as a little cache */ static PyObject *pname; static slotdef *ptrs[MAX_EQUIV]; slotdef *p, **pp; void **res, **ptr; if (pname != name) { /* Collect all slotdefs that match name into ptrs. */ pname = name; pp = ptrs; for (p = slotdefs; p->name_strobj; p++) { if (p->name_strobj == name) *pp++ = p; } *pp = NULL; } /* Look in all matching slots of the type; if exactly one of these has a filled-in slot, return its value. Otherwise return NULL. */ res = NULL; for (pp = ptrs; *pp; pp++) { ptr = slotptr(type, (*pp)->offset); if (ptr == NULL || *ptr == NULL) continue; if (res != NULL) return NULL; res = ptr; } return res; } /* Common code for update_slots_callback() and fixup_slot_dispatchers(). This does some incredibly complex thinking and then sticks something into the slot. (It sees if the adjacent slotdefs for the same slot have conflicting interests, and then stores a generic wrapper or a specific function into the slot.) Return a pointer to the next slotdef with a different offset, because that's convenient for fixup_slot_dispatchers(). */ static slotdef * update_one_slot(PyTypeObject *type, slotdef *p) { PyObject *descr; PyWrapperDescrObject *d; void *generic = NULL, *specific = NULL; int use_generic = 0; int offset = p->offset; void **ptr = slotptr(type, offset); if (ptr == NULL) { do { ++p; } while (p->offset == offset); return p; } do { descr = _PyType_Lookup(type, p->name_strobj); if (descr == NULL) continue; if (descr->ob_type == &PyWrapperDescr_Type) { void **tptr = resolve_slotdups(type, p->name_strobj); if (tptr == NULL || tptr == ptr) generic = p->function; d = (PyWrapperDescrObject *)descr; if (d->d_base->wrapper == p->wrapper && PyType_IsSubtype(type, d->d_type)) { if (specific == NULL || specific == d->d_wrapped) specific = d->d_wrapped; else use_generic = 1; } } else if (descr->ob_type == &PyCFunction_Type && PyCFunction_GET_FUNCTION(descr) == (PyCFunction)tp_new_wrapper && strcmp(p->name, "__new__") == 0) { /* The __new__ wrapper is not a wrapper descriptor, so must be special-cased differently. If we don't do this, creating an instance will always use slot_tp_new which will look up __new__ in the MRO which will call tp_new_wrapper which will look through the base classes looking for a static base and call its tp_new (usually PyType_GenericNew), after performing various sanity checks and constructing a new argument list. Cut all that nonsense short -- this speeds up instance creation tremendously. */ specific = (void *)type->tp_new; /* XXX I'm not 100% sure that there isn't a hole in this reasoning that requires additional sanity checks. I'll buy the first person to point out a bug in this reasoning a beer. */ } else { use_generic = 1; generic = p->function; } } while ((++p)->offset == offset); if (specific && !use_generic) *ptr = specific; else *ptr = generic; return p; } /* In the type, update the slots whose slotdefs are gathered in the pp array. This is a callback for update_subclasses(). */ static int update_slots_callback(PyTypeObject *type, void *data) { slotdef **pp = (slotdef **)data; for (; *pp; pp++) update_one_slot(type, *pp); return 0; } /* Comparison function for qsort() to compare slotdefs by their offset, and for equal offset by their address (to force a stable sort). */ static int slotdef_cmp(const void *aa, const void *bb) { const slotdef *a = (const slotdef *)aa, *b = (const slotdef *)bb; int c = a->offset - b->offset; if (c != 0) return c; else return a - b; } /* Initialize the slotdefs table by adding interned string objects for the names and sorting the entries. */ static void init_slotdefs(void) { slotdef *p; static int initialized = 0; if (initialized) return; for (p = slotdefs; p->name; p++) { p->name_strobj = PyString_InternFromString(p->name); if (!p->name_strobj) Py_FatalError("Out of memory interning slotdef names"); } qsort((void *)slotdefs, (size_t)(p-slotdefs), sizeof(slotdef), slotdef_cmp); initialized = 1; } /* Update the slots after assignment to a class (type) attribute. */ static int update_slot(PyTypeObject *type, PyObject *name) { slotdef *ptrs[MAX_EQUIV]; slotdef *p; slotdef **pp; int offset; init_slotdefs(); pp = ptrs; for (p = slotdefs; p->name; p++) { /* XXX assume name is interned! */ if (p->name_strobj == name) *pp++ = p; } *pp = NULL; for (pp = ptrs; *pp; pp++) { p = *pp; offset = p->offset; while (p > slotdefs && (p-1)->offset == offset) --p; *pp = p; } if (ptrs[0] == NULL) return 0; /* Not an attribute that affects any slots */ return update_subclasses(type, name, update_slots_callback, (void *)ptrs); } /* Store the proper functions in the slot dispatches at class (type) definition time, based upon which operations the class overrides in its dict. */ static void fixup_slot_dispatchers(PyTypeObject *type) { slotdef *p; init_slotdefs(); for (p = slotdefs; p->name; ) p = update_one_slot(type, p); } static void update_all_slots(PyTypeObject* type) { slotdef *p; init_slotdefs(); for (p = slotdefs; p->name; p++) { /* update_slot returns int but can't actually fail */ update_slot(type, p->name_strobj); } } /* recurse_down_subclasses() and update_subclasses() are mutually recursive functions to call a callback for all subclasses, but refraining from recursing into subclasses that define 'name'. */ static int update_subclasses(PyTypeObject *type, PyObject *name, update_callback callback, void *data) { if (callback(type, data) < 0) return -1; return recurse_down_subclasses(type, name, callback, data); } static int recurse_down_subclasses(PyTypeObject *type, PyObject *name, update_callback callback, void *data) { PyTypeObject *subclass; PyObject *ref, *subclasses, *dict; int i, n; subclasses = type->tp_subclasses; if (subclasses == NULL) return 0; assert(PyList_Check(subclasses)); n = PyList_GET_SIZE(subclasses); for (i = 0; i < n; i++) { ref = PyList_GET_ITEM(subclasses, i); assert(PyWeakref_CheckRef(ref)); subclass = (PyTypeObject *)PyWeakref_GET_OBJECT(ref); assert(subclass != NULL); if ((PyObject *)subclass == Py_None) continue; assert(PyType_Check(subclass)); /* Avoid recursing down into unaffected classes */ dict = subclass->tp_dict; if (dict != NULL && PyDict_Check(dict) && PyDict_GetItem(dict, name) != NULL) continue; if (update_subclasses(subclass, name, callback, data) < 0) return -1; } return 0; } /* This function is called by PyType_Ready() to populate the type's dictionary with method descriptors for function slots. For each function slot (like tp_repr) that's defined in the type, one or more corresponding descriptors are added in the type's tp_dict dictionary under the appropriate name (like __repr__). Some function slots cause more than one descriptor to be added (for example, the nb_add slot adds both __add__ and __radd__ descriptors) and some function slots compete for the same descriptor (for example both sq_item and mp_subscript generate a __getitem__ descriptor). In the latter case, the first slotdef entry encoutered wins. Since slotdef entries are sorted by the offset of the slot in the PyHeapTypeObject, this gives us some control over disambiguating between competing slots: the members of PyHeapTypeObject are listed from most general to least general, so the most general slot is preferred. In particular, because as_mapping comes before as_sequence, for a type that defines both mp_subscript and sq_item, mp_subscript wins. This only adds new descriptors and doesn't overwrite entries in tp_dict that were previously defined. The descriptors contain a reference to the C function they must call, so that it's safe if they are copied into a subtype's __dict__ and the subtype has a different C function in its slot -- calling the method defined by the descriptor will call the C function that was used to create it, rather than the C function present in the slot when it is called. (This is important because a subtype may have a C function in the slot that calls the method from the dictionary, and we want to avoid infinite recursion here.) */ static int add_operators(PyTypeObject *type) { PyObject *dict = type->tp_dict; slotdef *p; PyObject *descr; void **ptr; init_slotdefs(); for (p = slotdefs; p->name; p++) { if (p->wrapper == NULL) continue; ptr = slotptr(type, p->offset); if (!ptr || !*ptr) continue; if (PyDict_GetItem(dict, p->name_strobj)) continue; descr = PyDescr_NewWrapper(type, p, *ptr); if (descr == NULL) return -1; if (PyDict_SetItem(dict, p->name_strobj, descr) < 0) return -1; Py_DECREF(descr); } if (type->tp_new != NULL) { if (add_tp_new_wrapper(type) < 0) return -1; } return 0; } /* Cooperative 'super' */ typedef struct { PyObject_HEAD PyTypeObject *type; PyObject *obj; PyTypeObject *obj_type; } superobject; static PyMemberDef super_members[] = { {"__thisclass__", T_OBJECT, offsetof(superobject, type), READONLY, "the class invoking super()"}, {"__self__", T_OBJECT, offsetof(superobject, obj), READONLY, "the instance invoking super(); may be None"}, {"__self_class__", T_OBJECT, offsetof(superobject, obj_type), READONLY, "the type of the instance invoking super(); may be None"}, {0} }; static void super_dealloc(PyObject *self) { superobject *su = (superobject *)self; _PyObject_GC_UNTRACK(self); Py_XDECREF(su->obj); Py_XDECREF(su->type); Py_XDECREF(su->obj_type); self->ob_type->tp_free(self); } static PyObject * super_repr(PyObject *self) { superobject *su = (superobject *)self; if (su->obj_type) return PyString_FromFormat( ", <%s object>>", su->type ? su->type->tp_name : "NULL", su->obj_type->tp_name); else return PyString_FromFormat( ", NULL>", su->type ? su->type->tp_name : "NULL"); } static PyObject * super_getattro(PyObject *self, PyObject *name) { superobject *su = (superobject *)self; int skip = su->obj_type == NULL; if (!skip) { /* We want __class__ to return the class of the super object (i.e. super, or a subclass), not the class of su->obj. */ skip = (PyString_Check(name) && PyString_GET_SIZE(name) == 9 && strcmp(PyString_AS_STRING(name), "__class__") == 0); } if (!skip) { PyObject *mro, *res, *tmp, *dict; PyTypeObject *starttype; descrgetfunc f; int i, n; starttype = su->obj_type; mro = starttype->tp_mro; if (mro == NULL) n = 0; else { assert(PyTuple_Check(mro)); n = PyTuple_GET_SIZE(mro); } for (i = 0; i < n; i++) { if ((PyObject *)(su->type) == PyTuple_GET_ITEM(mro, i)) break; } i++; res = NULL; for (; i < n; i++) { tmp = PyTuple_GET_ITEM(mro, i); if (PyType_Check(tmp)) dict = ((PyTypeObject *)tmp)->tp_dict; else if (PyClass_Check(tmp)) dict = ((PyClassObject *)tmp)->cl_dict; else continue; res = PyDict_GetItem(dict, name); if (res != NULL) { Py_INCREF(res); f = res->ob_type->tp_descr_get; if (f != NULL) { tmp = f(res, /* Only pass 'obj' param if this is instance-mode super (See SF ID #743627) */ (su->obj == (PyObject *) su->obj_type ? (PyObject *)NULL : su->obj), (PyObject *)starttype); Py_DECREF(res); res = tmp; } return res; } } } return PyObject_GenericGetAttr(self, name); } static PyTypeObject * supercheck(PyTypeObject *type, PyObject *obj) { /* Check that a super() call makes sense. Return a type object. obj can be a new-style class, or an instance of one: - If it is a class, it must be a subclass of 'type'. This case is used for class methods; the return value is obj. - If it is an instance, it must be an instance of 'type'. This is the normal case; the return value is obj.__class__. But... when obj is an instance, we want to allow for the case where obj->ob_type is not a subclass of type, but obj.__class__ is! This will allow using super() with a proxy for obj. */ /* Check for first bullet above (special case) */ if (PyType_Check(obj) && PyType_IsSubtype((PyTypeObject *)obj, type)) { Py_INCREF(obj); return (PyTypeObject *)obj; } /* Normal case */ if (PyType_IsSubtype(obj->ob_type, type)) { Py_INCREF(obj->ob_type); return obj->ob_type; } else { /* Try the slow way */ static PyObject *class_str = NULL; PyObject *class_attr; if (class_str == NULL) { class_str = PyString_FromString("__class__"); if (class_str == NULL) return NULL; } class_attr = PyObject_GetAttr(obj, class_str); if (class_attr != NULL && PyType_Check(class_attr) && (PyTypeObject *)class_attr != obj->ob_type) { int ok = PyType_IsSubtype( (PyTypeObject *)class_attr, type); if (ok) return (PyTypeObject *)class_attr; } if (class_attr == NULL) PyErr_Clear(); else Py_DECREF(class_attr); } PyErr_SetString(PyExc_TypeError, "super(type, obj): " "obj must be an instance or subtype of type"); return NULL; } static PyObject * super_descr_get(PyObject *self, PyObject *obj, PyObject *type) { superobject *su = (superobject *)self; superobject *new; if (obj == NULL || obj == Py_None || su->obj != NULL) { /* Not binding to an object, or already bound */ Py_INCREF(self); return self; } if (su->ob_type != &PySuper_Type) /* If su is an instance of a (strict) subclass of super, call its type */ return PyObject_CallFunction((PyObject *)su->ob_type, "OO", su->type, obj); else { /* Inline the common case */ PyTypeObject *obj_type = supercheck(su->type, obj); if (obj_type == NULL) return NULL; new = (superobject *)PySuper_Type.tp_new(&PySuper_Type, NULL, NULL); if (new == NULL) return NULL; Py_INCREF(su->type); Py_INCREF(obj); new->type = su->type; new->obj = obj; new->obj_type = obj_type; return (PyObject *)new; } } static int super_init(PyObject *self, PyObject *args, PyObject *kwds) { superobject *su = (superobject *)self; PyTypeObject *type; PyObject *obj = NULL; PyTypeObject *obj_type = NULL; if (!PyArg_ParseTuple(args, "O!|O:super", &PyType_Type, &type, &obj)) return -1; if (obj == Py_None) obj = NULL; if (obj != NULL) { obj_type = supercheck(type, obj); if (obj_type == NULL) return -1; Py_INCREF(obj); } Py_INCREF(type); su->type = type; su->obj = obj; su->obj_type = obj_type; return 0; } PyDoc_STRVAR(super_doc, "super(type) -> unbound super object\n" "super(type, obj) -> bound super object; requires isinstance(obj, type)\n" "super(type, type2) -> bound super object; requires issubclass(type2, type)\n" "Typical use to call a cooperative superclass method:\n" "class C(B):\n" " def meth(self, arg):\n" " super(C, self).meth(arg)"); static int super_traverse(PyObject *self, visitproc visit, void *arg) { superobject *su = (superobject *)self; int err; #define VISIT(SLOT) \ if (SLOT) { \ err = visit((PyObject *)(SLOT), arg); \ if (err) \ return err; \ } VISIT(su->obj); VISIT(su->type); VISIT(su->obj_type); #undef VISIT return 0; } PyTypeObject PySuper_Type = { PyObject_HEAD_INIT(&PyType_Type) 0, /* ob_size */ "super", /* tp_name */ sizeof(superobject), /* tp_basicsize */ 0, /* tp_itemsize */ /* methods */ super_dealloc, /* tp_dealloc */ 0, /* tp_print */ 0, /* tp_getattr */ 0, /* tp_setattr */ 0, /* tp_compare */ super_repr, /* tp_repr */ 0, /* tp_as_number */ 0, /* tp_as_sequence */ 0, /* tp_as_mapping */ 0, /* tp_hash */ 0, /* tp_call */ 0, /* tp_str */ super_getattro, /* tp_getattro */ 0, /* tp_setattro */ 0, /* tp_as_buffer */ Py_TPFLAGS_DEFAULT | Py_TPFLAGS_HAVE_GC | Py_TPFLAGS_BASETYPE, /* tp_flags */ super_doc, /* tp_doc */ super_traverse, /* tp_traverse */ 0, /* tp_clear */ 0, /* tp_richcompare */ 0, /* tp_weaklistoffset */ 0, /* tp_iter */ 0, /* tp_iternext */ 0, /* tp_methods */ super_members, /* tp_members */ 0, /* tp_getset */ 0, /* tp_base */ 0, /* tp_dict */ super_descr_get, /* tp_descr_get */ 0, /* tp_descr_set */ 0, /* tp_dictoffset */ super_init, /* tp_init */ PyType_GenericAlloc, /* tp_alloc */ PyType_GenericNew, /* tp_new */ PyObject_GC_Del, /* tp_free */ };