PEP: 489 Title: Redesigning extension module loading Version: $Revision$ Last-Modified: $Date$ Author: Petr Viktorin , Stefan Behnel , Nick Coghlan Discussions-To: import-sig@python.org Status: Draft Type: Standards Track Content-Type: text/x-rst Created: 11-Aug-2013 Python-Version: 3.5 Post-History: 23-Aug-2013, 20-Feb-2015, 16-Apr-2015 Resolution: Abstract ======== This PEP proposes a redesign of the way in which extension modules interact with the import machinery. This was last revised for Python 3.0 in PEP 3121, but did not solve all problems at the time. The goal is to solve them by bringing extension modules closer to the way Python modules behave; specifically to hook into the ModuleSpec-based loading mechanism introduced in PEP 451. This proposal draws inspiration from PyType_Spec of PEP 384 to allow extension authors to only define features they need, and to allow future additions to extension module declarations. Extensions modules are created in a two-step process, fitting better into the ModuleSpec architecture, with parallels to __new__ and __init__ of classes. Extension modules can safely store arbitrary C-level per-module state in the module that is covered by normal garbage collection and supports reloading and sub-interpreters. Extension authors are encouraged to take these issues into account when using the new API. The proposal also allows extension modules with non-ASCII names. Motivation ========== Python modules and extension modules are not being set up in the same way. For Python modules, the module is created and set up first, then the module code is being executed (PEP 302). A ModuleSpec object (PEP 451) is used to hold information about the module, and passed to the relevant hooks. For extensions, i.e. shared libraries, the module init function is executed straight away and does both the creation and initialization. The initialization function is not passed the ModuleSpec, or any information it contains, such as the __file__ or fully-qualified name. This hinders relative imports and resource loading. In Py3, modules are also not being added to sys.modules, which means that a (potentially transitive) re-import of the module will really try to re-import it and thus run into an infinite loop when it executes the module init function again. Without the FQMN, it is not trivial to correctly add the module to sys.modules either. This is specifically a problem for Cython generated modules, for which it's not uncommon that the module init code has the same level of complexity as that of any 'regular' Python module. Also, the lack of __file__ and __name__ information hinders the compilation of "__init__.py" modules, i.e. packages, especially when relative imports are being used at module init time. Furthermore, the majority of currently existing extension modules has problems with sub-interpreter support and/or interpreter reloading, and, while it is possible with the current infrastructure to support these features, it is neither easy nor efficient. Addressing these issues was the goal of PEP 3121, but many extensions, including some in the standard library, took the least-effort approach to porting to Python 3, leaving these issues unresolved. This PEP keeps backwards compatibility, which should reduce pressure and give extension authors adequate time to consider these issues when porting. The current process =================== Currently, extension modules export an initialization function named "PyInit_modulename", named after the file name of the shared library. This function is executed by the import machinery and must return either NULL in the case of an exception, or a fully initialized module object. The function receives no arguments, so it has no way of knowing about its import context. During its execution, the module init function creates a module object based on a PyModuleDef struct. It then continues to initialize it by adding attributes to the module dict, creating types, etc. In the back, the shared library loader keeps a note of the fully qualified module name of the last module that it loaded, and when a module gets created that has a matching name, this global variable is used to determine the fully qualified name of the module object. This is not entirely safe as it relies on the module init function creating its own module object first, but this assumption usually holds in practice. The proposal ============ The current extension module initialization will be deprecated in favor of a new initialization scheme. Since the current scheme will continue to be available, existing code will continue to work unchanged, including binary compatibility. Extension modules that support the new initialization scheme must export the public symbol "PyModuleExport_", where "modulename" is the name of the module. (For modules with non-ASCII names the symbol name is slightly different, see "Export Hook Name" below.) If defined, this symbol must resolve to a C function with the following signature:: PyModuleExport* (*PyModuleExportFunction)(void) The function must return a pointer to a PyModuleExport structure. This structure must be available for the lifetime of the module created from it – usually, it will be declared statically. The PyModuleExport structure describes the new module, similarly to PEP 384's PyType_Spec for types. The structure is defined as:: typedef struct { int slot; void *value; } PyModuleExport_Slot; typedef struct { const char* doc; int flags; PyModuleExport_Slot *slots; } PyModuleExport; The *doc* member specifies the module's docstring. The *flags* may currently be either 0 or ``PyModule_EXPORT_SINGLETON``, described in "Singleton Modules" below. Other flag values may be added in the future. The *slots* points to an array of PyModuleExport_Slot structures, terminated by a slot with id set to 0 (i.e. ``{0, NULL}``). To specify a slot, a unique slot ID must be provided. New Python versions may introduce new slot IDs, but slot IDs will never be recycled. Slots may get deprecated, but will continue to be supported throughout Python 3.x. A slot's value pointer may not be NULL, unless specified otherwise in the slot's documentation. The following slots are available, and described later: * Py_mod_create * Py_mod_statedef * Py_mod_methods * Py_mod_exec Unknown slot IDs will cause the import to fail with ImportError. .. note:: An alternate proposal is to use PyModuleDef instead of PyModuleExport, re-purposing the m_reload pointer to hold the slots:: typedef struct PyModuleDef { PyModuleDef_Base m_base; const char* m_name; const char* m_doc; Py_ssize_t m_size; PyMethodDef *m_methods; PyModuleExport_Slot* m_slots; /* changed from `inquiry m_reload;` */ traverseproc m_traverse; inquiry m_clear; freefunc m_free; } PyModuleDef; This would simplify both the implementation and the API, at the expense of renaming a member of PyModuleDef, and re-purposing a function pointer as a data pointer. Creation Slots -------------- The following slots affect module creation phase, i.e. they are hooks for ExecutionLoader.create_module. They serve to describe creation of the module object itself. Py_mod_create ............. The Py_mod_create slot is used to support custom module subclasses. The value pointer must point to a function with the following signature:: PyObject* (*PyModuleCreateFunction)(PyObject *spec, PyModuleExport *exp) The function receives a ModuleSpec instance, as defined in PEP 451, and the PyModuleExport structure. It should return a new module object, or set an error and return NULL. This function is not responsible for setting import-related attributes specified in PEP 451 [#pep-0451-attributes]_ (such as ``__name__`` or ``__loader__``) on the new module. There is no requirement for the returned object to be an instance of types.ModuleType. Any type can be used, as long as it supports setting and getting attributes, including at least the import-related attributes. If a module instance is returned from Py_mod_create, the import machinery will store a pointer to PyModuleExport in the module object so that it may be retrieved by PyModule_GetExport (described later). .. note:: If PyModuleDef is used instead of PyModuleExport, the def is stored instead, to be retrieved by PyModule_GetDef. Note that when this function is called, the module's entry in sys.modules is not populated yet. Attempting to import the same module again (possibly transitively), may lead to an infinite loop. Extension authors are advised to keep Py_mod_create minimal, an in particular to not call user code from it. Multiple Py_mod_create slots may not be specified. If they are, import will fail with ImportError. If Py_mod_create is not specified, the import machinery will create a normal module object, as if by calling PyModule_Create. Py_mod_statedef ............... The Py_mod_statedef slot is used to allocate per-module storage for C-level state. The value pointer must point to the following structure:: typedef struct PyModule_StateDef { int size; traverseproc traverse; inquiry clear; freefunc free; } PyModule_StateDef; The meaning of the members is the same as for the corresponding members in PyModuleDef. Specifying multiple Py_mod_statedef slots, or specifying Py_mod_statedef together with Py_mod_create, will cause the import to fail with ImportError. .. note:: If PyModuleDef is reused, this information is taken from PyModuleDef, so the slot is not necessary. Execution slots --------------- The following slots affect module "execution" phase, i.e. they are processed in ExecutionLoader.exec_module. They serve to describe how the module is initialized – e.g. how it is populated with functions, types, or constants, and what import-time side effects take place. These slots may be specified multiple times, and are processed in the order they appear in the slots array. When using the default import machinery, these slots are processed after import-related attributes specified in PEP 451 [#pep-0451-attributes]_ (such as ``__name__`` or ``__loader__``) are set and the module is added to sys.modules. Py_mod_methods .............. This slot's value pointer must point to an array of PyMethodDef structures. The specified methods are added to the module, like with PyModuleDef.m_methods. .. note:: If PyModuleDef is reused this slot is unnecessary, since methods are already included in PyModuleDef. Py_mod_exec ........... The entry in this slot must point to a function with the following signature:: int (*PyModuleExecFunction)(PyObject* module) It will be called to initialize a module. Usually, this amounts to setting the module's initial attributes. The "module" argument receives the module object to initialize. This will always be the module object created from the corresponding PyModuleExport. When this function is called, import-related attributes (such as ``__spec__``) will have been set, and the module has already been added to sys.modules. If PyModuleExec replaces the module's entry in sys.modules, the new object will be used and returned by importlib machinery. (This mirrors the behavior of Python modules. Note that for extensions, implementing Py_mod_create is usually a better solution for the use cases this serves.) The function must return ``0`` on success, or, on error, set an exception and return ``-1``. Legacy Init ----------- If the PyModuleExport function is not defined, the import machinery will try to initialize the module using the "PyInit_" hook, as described in PEP 3121. If the PyModuleExport function is defined, the PyInit function will be ignored. Modules requiring compatibility with previous versions of CPython may implement the PyInit function in addition to the new hook. Modules using the legacy init API will be initialized entirely in the Loader.create_module step; Loader.exec_module will be a no-op. .. XXX: Give example code for a backwards-compatible PyInit based on slots .. note:: If PyModuleDef is reused, implementing the PyInit function becomes easy: * call PyModule_Create with the PyModuleDef (m_reload was ignored in previous Python versions, so the slots array will be ignored). Alternatively, call the Py_mod_create function (keeping in mind that the spec is not available with PyInit). * call the Py_mod_exec function(s). Subinterpreters and Interpreter Reloading ----------------------------------------- Extensions using the new initialization scheme are expected to support subinterpreters and multiple Py_Initialize/Py_Finalize cycles correctly. The mechanism is designed to make this easy, but care is still required on the part of the extension author. No user-defined functions, methods, or instances may leak to different interpreters. To achieve this, all module-level state should be kept in either the module dict, or in the module object's storage reachable by PyModule_GetState. A simple rule of thumb is: Do not define any static data, except built-in types with no mutable or user-settable class attributes. PyModule_GetExport ------------------ To retrieve the PyModuleExport structure used to create a module, a new function will be added:: PyModuleExport* PyModule_GetExport(PyObject *module) The function returns NULL if the parameter is not a module object, or was not created using PyModuleExport. .. note:: This is unnecessary if PyModuleDef is reused: the existing PyModule_GetDef can be used instead. Singleton Modules ----------------- Modules defined by PyModuleDef may be registered with PyState_AddModule, and later retrieved with PyState_FindModule. Under the new API, there is no one-to-one mapping between PyModuleSpec and the module created from it. In particular, multiple modules may be loaded from the same description. This means that there is no "global" instance of a module object. Any C-level callbacks that need access to the module state need to be passed a reference to the module object, either directly or indirectly. However, there are some modules that really need to be only loaded once: typically ones that wrap a C library with global state. These modules should set the PyModule_EXPORT_SINGLETON flag in PyModuleExport.flags. When this flag is set, loading an additional copy of the module after it has been loaded once will return the previously loaded object. This will be done on a low level, using _PyImport_FixupExtensionObject. Additionally, the module will be automatically registered using PyState_AddSingletonModule (see below) after execution slots are processed. Singleton modules can be retrieved, registered or unregistered with the interpreter state using three new functions, which parallel their PyModuleDef counterparts, PyState_FindModule, PyState_AddModule, and PyState_RemoveModule:: PyObject* PyState_FindSingletonModule(PyModuleExport *exp) int PyState_AddSingletonModule(PyObject *module, PyModuleExport *exp) int PyState_RemoveSingletonModule(PyModuleExport *exp) .. note:: If PyModuleDef is used instead of PyModuleExport, the flag would be specified as a slot with NULL value, i.e. ``{Py_mod_flag_singleton, NULL}``. In this case, PyState_FindModule, PyState_AddModule and PyState_RemoveModule can be used instead of the new functions. .. note:: Another possibility is to use PyModuleDef_Base in PyModuleExport, and have PyState_FindModule and friends work with either of the two structures. Export Hook Name ---------------- As portable C identifiers are limited to ASCII, module names must be encoded to form the PyModuleExport hook name. For ASCII module names, the import hook is named PyModuleExport_, where is the name of the module. For module names containing non-ASCII characters, the import hook is named PyModuleExportU_, where the name is encoded using CPython's "punycode" encoding (Punycode [#rfc-3492]_ with a lowercase suffix), with hyphens ("-") replaced by underscores ("_"). In Python:: def export_hook_name(name): try: encoded = b'_' + name.encode('ascii') except UnicodeDecodeError: encoded = b'U_' + name.encode('punycode').replace(b'-', b'_') return b'PyModuleExport' + encoded Examples: ============= =========================== Module name Export hook name ============= =========================== spam PyModuleExport_spam lančmít PyModuleExportU_lanmt_2sa6t スパム PyModuleExportU_zck5b2b ============= =========================== Module Reloading ---------------- Reloading an extension module using importlib.reload() will continue to have no effect, except re-setting import-related attributes. Due to limitations in shared library loading (both dlopen on POSIX and LoadModuleEx on Windows), it is not generally possible to load a modified library after it has changed on disk. Use cases for reloading other than trying out a new version of the module are too rare to require all module authors to keep reloading in mind. If reload-like functionality is needed, authors can export a dedicated function for it. Multiple modules in one library ------------------------------- To support multiple Python modules in one shared library, the library can export additional PyModuleExport* symbols besides the one that corresponds to the library's filename. Note that this mechanism can currently only be used to *load* extra modules, not to *find* them. Given the filesystem location of a shared library and a module name, a module may be loaded with:: import importlib.machinery import importlib.util loader = importlib.machinery.ExtensionFileLoader(name, path) spec = importlib.util.spec_from_loader(name, loader) return importlib.util.module_from_spec(spec) On platforms that support symbolic links, these may be used to install one library under multiple names, exposing all exported modules to normal import machinery. Testing and initial implementations ----------------------------------- For testing, a new built-in module ``_testimportmodexport`` will be created. The library will export several additional modules using the mechanism described in "Multiple modules in one library". The ``_testcapi`` module will be unchanged, and will use the old API indefinitely (or until the old API is removed). The ``_csv`` and ``readline`` modules will be converted to the new API as part of the initial implementation. Possible Future Extensions ========================== The slots mechanism, inspired by PyType_Slot from PEP 384, allows later extensions. Some extension modules exports many constants; for example _ssl has a long list of calls in the form:: PyModule_AddIntConstant(m, "SSL_ERROR_ZERO_RETURN", PY_SSL_ERROR_ZERO_RETURN); Converting this to a declarative list, similar to PyMethodDef, would reduce boilerplate, and provide free error-checking which is often missing. String constants and types can be handled similarly. (Note that non-default bases for types cannot be portably specified statically; this case would need a Py_mod_exec function that runs before the slots are added. The free error-checking would still be beneficial, though.) Another possibility is providing a "main" function that would be run when the module is given to Python's -m switch. For this to work, the runpy module will need to be modified to take advantage of ModuleSpec-based loading introduced in PEP 451. Also, it will be necessary to add a mechanism for setting up a module according to slots it wasn't originally defined with. Implementation ============== Work-in-progress implementation is available in a Github repository [#gh-repo]_; a patchset is at [#gh-patch]_. Previous Approaches =================== Stefan Behnel's initial proto-PEP [#stefans_protopep]_ had a "PyInit_modulename" hook that would create a module class, whose ``__init__`` would be then called to create the module. This proposal did not correspond to the (then nonexistent) PEP 451, where module creation and initialization is broken into distinct steps. It also did not support loading an extension into pre-existing module objects. Nick Coghlan proposed "Create" and "Exec" hooks, and wrote a prototype implementation [#nicks-prototype]_. At this time PEP 451 was still not implemented, so the prototype does not use ModuleSpec. The original version of this PEP used Create and Exec hooks, and allowed loading into arbitrary pre-constructed objects with Exec hook. The proposal made extension module initialization closer to how Python modules are initialized, but it was later recognized that this isn't an important goal. The current PEP describes a simpler solution. References ========== .. [#lazy_import_concerns] https://mail.python.org/pipermail/python-dev/2013-August/128129.html .. [#pep-0451-attributes] https://www.python.org/dev/peps/pep-0451/#attributes .. [#stefans_protopep] https://mail.python.org/pipermail/python-dev/2013-August/128087.html .. [#nicks-prototype] https://mail.python.org/pipermail/python-dev/2013-August/128101.html .. [#rfc-3492] http://tools.ietf.org/html/rfc3492 .. [#gh-repo] https://github.com/encukou/cpython/commits/pep489 .. [#gh-patch] https://github.com/encukou/cpython/compare/master...encukou:pep489.patch Copyright ========= This document has been placed in the public domain.