2014-05-03 18:27:38 -04:00
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/*
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2017-06-30 03:22:17 -04:00
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* This file is part of the MicroPython project, http://micropython.org/
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2014-05-03 18:27:38 -04:00
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*
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* The MIT License (MIT)
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*
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py: Automatically provide weak links from "foo" to "ufoo" module name.
This commit implements automatic module weak links for all built-in
modules, by searching for "ufoo" in the built-in module list if "foo"
cannot be found. This means that all modules named "ufoo" are always
available as "foo". Also, a port can no longer add any other weak links,
which makes strict the definition of a weak link.
It saves some code size (about 100-200 bytes) on ports that previously had
lots of weak links.
Some changes from the previous behaviour:
- It doesn't intern the non-u module names (eg "foo" is not interned),
which saves code size, but will mean that "import foo" creates a new qstr
(namely "foo") in RAM (unless the importing module is frozen).
- help('modules') no longer lists non-u module names, only the u-variants;
this reduces duplication in the help listing.
Weak links are effectively the same as having a set of symbolic links on
the filesystem that is searched last. So an "import foo" will search
built-in modules first, then all paths in sys.path, then weak links last,
importing "ufoo" if it exists. Thus a file called "foo.py" somewhere in
sys.path will still have precedence over the weak link of "foo" to "ufoo".
See issues: #1740, #4449, #5229, #5241.
2019-10-21 10:06:34 -04:00
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* Copyright (c) 2013-2019 Damien P. George
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2019-05-14 08:51:57 -04:00
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* Copyright (c) 2014-2015 Paul Sokolovsky
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2014-05-03 18:27:38 -04:00
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*
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* Permission is hereby granted, free of charge, to any person obtaining a copy
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* of this software and associated documentation files (the "Software"), to deal
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* in the Software without restriction, including without limitation the rights
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* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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* copies of the Software, and to permit persons to whom the Software is
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* furnished to do so, subject to the following conditions:
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*
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* The above copyright notice and this permission notice shall be included in
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* all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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* AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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* THE SOFTWARE.
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*/
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2014-01-02 16:30:26 -05:00
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#include <stdlib.h>
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py: Automatically provide weak links from "foo" to "ufoo" module name.
This commit implements automatic module weak links for all built-in
modules, by searching for "ufoo" in the built-in module list if "foo"
cannot be found. This means that all modules named "ufoo" are always
available as "foo". Also, a port can no longer add any other weak links,
which makes strict the definition of a weak link.
It saves some code size (about 100-200 bytes) on ports that previously had
lots of weak links.
Some changes from the previous behaviour:
- It doesn't intern the non-u module names (eg "foo" is not interned),
which saves code size, but will mean that "import foo" creates a new qstr
(namely "foo") in RAM (unless the importing module is frozen).
- help('modules') no longer lists non-u module names, only the u-variants;
this reduces duplication in the help listing.
Weak links are effectively the same as having a set of symbolic links on
the filesystem that is searched last. So an "import foo" will search
built-in modules first, then all paths in sys.path, then weak links last,
importing "ufoo" if it exists. Thus a file called "foo.py" somewhere in
sys.path will still have precedence over the weak link of "foo" to "ufoo".
See issues: #1740, #4449, #5229, #5241.
2019-10-21 10:06:34 -04:00
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#include <string.h>
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2014-01-02 16:30:26 -05:00
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#include <assert.h>
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2022-05-04 21:02:38 -04:00
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#include "py/bc.h"
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2015-01-01 15:27:54 -05:00
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#include "py/objmodule.h"
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#include "py/runtime.h"
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#include "py/builtin.h"
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2014-03-25 10:18:18 -04:00
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2018-12-12 00:50:55 -05:00
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#include "genhdr/moduledefs.h"
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2020-02-25 23:24:09 -05:00
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#if MICROPY_MODULE_BUILTIN_INIT
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STATIC void mp_module_call_init(mp_obj_t module_name, mp_obj_t module_obj);
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#endif
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2015-04-09 18:56:15 -04:00
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STATIC void module_print(const mp_print_t *print, mp_obj_t self_in, mp_print_kind_t kind) {
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2015-01-20 07:47:20 -05:00
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(void)kind;
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2015-11-27 12:01:44 -05:00
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mp_obj_module_t *self = MP_OBJ_TO_PTR(self_in);
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2014-09-08 05:45:23 -04:00
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2016-09-20 20:52:53 -04:00
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const char *module_name = "";
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mp_map_elem_t *elem = mp_map_lookup(&self->globals->map, MP_OBJ_NEW_QSTR(MP_QSTR___name__), MP_MAP_LOOKUP);
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if (elem != NULL) {
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module_name = mp_obj_str_get_str(elem->value);
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}
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2014-09-08 05:45:23 -04:00
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#if MICROPY_PY___FILE__
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// If we store __file__ to imported modules then try to lookup this
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// symbol to give more information about the module.
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2016-09-20 20:52:53 -04:00
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elem = mp_map_lookup(&self->globals->map, MP_OBJ_NEW_QSTR(MP_QSTR___file__), MP_MAP_LOOKUP);
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2014-09-08 05:45:23 -04:00
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if (elem != NULL) {
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2016-09-20 20:52:53 -04:00
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mp_printf(print, "<module '%s' from '%s'>", module_name, mp_obj_str_get_str(elem->value));
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2014-09-08 05:45:23 -04:00
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return;
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}
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#endif
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2016-09-20 20:52:53 -04:00
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mp_printf(print, "<module '%s'>", module_name);
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2014-01-02 16:30:26 -05:00
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}
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2021-07-26 10:38:21 -04:00
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STATIC void module_attr_try_delegation(mp_obj_t self_in, qstr attr, mp_obj_t *dest) {
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#if MICROPY_MODULE_ATTR_DELEGATION
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// Delegate lookup to a module's custom attr method (found in last lot of globals dict).
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mp_obj_module_t *self = MP_OBJ_TO_PTR(self_in);
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mp_map_t *map = &self->globals->map;
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if (map->table[map->alloc - 1].key == MP_OBJ_NEW_QSTR(MP_QSTRnull)) {
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((mp_attr_fun_t)MP_OBJ_TO_PTR(map->table[map->alloc - 1].value))(self_in, attr, dest);
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}
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#else
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(void)self_in;
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(void)attr;
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(void)dest;
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#endif
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}
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2015-04-01 10:10:50 -04:00
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STATIC void module_attr(mp_obj_t self_in, qstr attr, mp_obj_t *dest) {
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2015-11-27 12:01:44 -05:00
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mp_obj_module_t *self = MP_OBJ_TO_PTR(self_in);
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2015-04-01 10:10:50 -04:00
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if (dest[0] == MP_OBJ_NULL) {
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// load attribute
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mp_map_elem_t *elem = mp_map_lookup(&self->globals->map, MP_OBJ_NEW_QSTR(attr), MP_MAP_LOOKUP);
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if (elem != NULL) {
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dest[0] = elem->value;
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2018-10-22 12:34:29 -04:00
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#if MICROPY_MODULE_GETATTR
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} else if (attr != MP_QSTR___getattr__) {
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elem = mp_map_lookup(&self->globals->map, MP_OBJ_NEW_QSTR(MP_QSTR___getattr__), MP_MAP_LOOKUP);
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if (elem != NULL) {
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dest[0] = mp_call_function_1(elem->value, MP_OBJ_NEW_QSTR(attr));
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2021-07-26 10:38:21 -04:00
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} else {
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module_attr_try_delegation(self_in, attr, dest);
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2018-10-22 12:34:29 -04:00
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}
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#endif
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2021-07-26 10:38:21 -04:00
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} else {
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module_attr_try_delegation(self_in, attr, dest);
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2014-12-09 11:19:48 -05:00
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}
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2014-04-08 16:11:49 -04:00
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} else {
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2015-04-01 10:10:50 -04:00
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// delete/store attribute
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mp_obj_dict_t *dict = self->globals;
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if (dict->map.is_fixed) {
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#if MICROPY_CAN_OVERRIDE_BUILTINS
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if (dict == &mp_module_builtins_globals) {
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if (MP_STATE_VM(mp_module_builtins_override_dict) == NULL) {
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2015-11-27 12:01:44 -05:00
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MP_STATE_VM(mp_module_builtins_override_dict) = MP_OBJ_TO_PTR(mp_obj_new_dict(1));
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2015-04-01 10:10:50 -04:00
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}
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dict = MP_STATE_VM(mp_module_builtins_override_dict);
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} else
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#endif
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{
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// can't delete or store to fixed map
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2021-07-26 10:38:21 -04:00
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module_attr_try_delegation(self_in, attr, dest);
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2015-04-01 10:10:50 -04:00
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return;
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}
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}
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if (dest[1] == MP_OBJ_NULL) {
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// delete attribute
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2015-11-27 12:01:44 -05:00
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mp_obj_dict_delete(MP_OBJ_FROM_PTR(dict), MP_OBJ_NEW_QSTR(attr));
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2015-04-01 10:10:50 -04:00
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} else {
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// store attribute
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2015-11-27 12:01:44 -05:00
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mp_obj_dict_store(MP_OBJ_FROM_PTR(dict), MP_OBJ_NEW_QSTR(attr), dest[1]);
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2015-04-01 10:10:50 -04:00
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}
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dest[0] = MP_OBJ_NULL; // indicate success
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2014-04-08 16:11:49 -04:00
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}
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2014-01-09 15:57:50 -05:00
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}
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2014-03-08 10:24:39 -05:00
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const mp_obj_type_t mp_type_module = {
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2014-02-15 11:10:44 -05:00
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{ &mp_type_type },
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2014-02-15 06:34:50 -05:00
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.name = MP_QSTR_module,
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2014-01-07 10:58:30 -05:00
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.print = module_print,
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2015-04-01 10:10:50 -04:00
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.attr = module_attr,
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2014-01-02 16:30:26 -05:00
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};
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mp_obj_t mp_obj_new_module(qstr module_name) {
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2015-12-04 17:09:10 -05:00
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mp_map_t *mp_loaded_modules_map = &MP_STATE_VM(mp_loaded_modules_dict).map;
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mp_map_elem_t *el = mp_map_lookup(mp_loaded_modules_map, MP_OBJ_NEW_QSTR(module_name), MP_MAP_LOOKUP_ADD_IF_NOT_FOUND);
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2014-01-19 17:03:34 -05:00
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// We could error out if module already exists, but let C extensions
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// add new members to existing modules.
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if (el->value != MP_OBJ_NULL) {
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return el->value;
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}
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2014-03-08 10:24:39 -05:00
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// create new module object
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py: Rework bytecode and .mpy file format to be mostly static data.
Background: .mpy files are precompiled .py files, built using mpy-cross,
that contain compiled bytecode functions (and can also contain machine
code). The benefit of using an .mpy file over a .py file is that they are
faster to import and take less memory when importing. They are also
smaller on disk.
But the real benefit of .mpy files comes when they are frozen into the
firmware. This is done by loading the .mpy file during compilation of the
firmware and turning it into a set of big C data structures (the job of
mpy-tool.py), which are then compiled and downloaded into the ROM of a
device. These C data structures can be executed in-place, ie directly from
ROM. This makes importing even faster because there is very little to do,
and also means such frozen modules take up much less RAM (because their
bytecode stays in ROM).
The downside of frozen code is that it requires recompiling and reflashing
the entire firmware. This can be a big barrier to entry, slows down
development time, and makes it harder to do OTA updates of frozen code
(because the whole firmware must be updated).
This commit attempts to solve this problem by providing a solution that
sits between loading .mpy files into RAM and freezing them into the
firmware. The .mpy file format has been reworked so that it consists of
data and bytecode which is mostly static and ready to run in-place. If
these new .mpy files are located in flash/ROM which is memory addressable,
the .mpy file can be executed (mostly) in-place.
With this approach there is still a small amount of unpacking and linking
of the .mpy file that needs to be done when it's imported, but it's still
much better than loading an .mpy from disk into RAM (although not as good
as freezing .mpy files into the firmware).
The main trick to make static .mpy files is to adjust the bytecode so any
qstrs that it references now go through a lookup table to convert from
local qstr number in the module to global qstr number in the firmware.
That means the bytecode does not need linking/rewriting of qstrs when it's
loaded. Instead only a small qstr table needs to be built (and put in RAM)
at import time. This means the bytecode itself is static/constant and can
be used directly if it's in addressable memory. Also the qstr string data
in the .mpy file, and some constant object data, can be used directly.
Note that the qstr table is global to the module (ie not per function).
In more detail, in the VM what used to be (schematically):
qst = DECODE_QSTR_VALUE;
is now (schematically):
idx = DECODE_QSTR_INDEX;
qst = qstr_table[idx];
That allows the bytecode to be fixed at compile time and not need
relinking/rewriting of the qstr values. Only qstr_table needs to be linked
when the .mpy is loaded.
Incidentally, this helps to reduce the size of bytecode because what used
to be 2-byte qstr values in the bytecode are now (mostly) 1-byte indices.
If the module uses the same qstr more than two times then the bytecode is
smaller than before.
The following changes are measured for this commit compared to the
previous (the baseline):
- average 7%-9% reduction in size of .mpy files
- frozen code size is reduced by about 5%-7%
- importing .py files uses about 5% less RAM in total
- importing .mpy files uses about 4% less RAM in total
- importing .py and .mpy files takes about the same time as before
The qstr indirection in the bytecode has only a small impact on VM
performance. For stm32 on PYBv1.0 the performance change of this commit
is:
diff of scores (higher is better)
N=100 M=100 baseline -> this-commit diff diff% (error%)
bm_chaos.py 371.07 -> 357.39 : -13.68 = -3.687% (+/-0.02%)
bm_fannkuch.py 78.72 -> 77.49 : -1.23 = -1.563% (+/-0.01%)
bm_fft.py 2591.73 -> 2539.28 : -52.45 = -2.024% (+/-0.00%)
bm_float.py 6034.93 -> 5908.30 : -126.63 = -2.098% (+/-0.01%)
bm_hexiom.py 48.96 -> 47.93 : -1.03 = -2.104% (+/-0.00%)
bm_nqueens.py 4510.63 -> 4459.94 : -50.69 = -1.124% (+/-0.00%)
bm_pidigits.py 650.28 -> 644.96 : -5.32 = -0.818% (+/-0.23%)
core_import_mpy_multi.py 564.77 -> 581.49 : +16.72 = +2.960% (+/-0.01%)
core_import_mpy_single.py 68.67 -> 67.16 : -1.51 = -2.199% (+/-0.01%)
core_qstr.py 64.16 -> 64.12 : -0.04 = -0.062% (+/-0.00%)
core_yield_from.py 362.58 -> 354.50 : -8.08 = -2.228% (+/-0.00%)
misc_aes.py 429.69 -> 405.59 : -24.10 = -5.609% (+/-0.01%)
misc_mandel.py 3485.13 -> 3416.51 : -68.62 = -1.969% (+/-0.00%)
misc_pystone.py 2496.53 -> 2405.56 : -90.97 = -3.644% (+/-0.01%)
misc_raytrace.py 381.47 -> 374.01 : -7.46 = -1.956% (+/-0.01%)
viper_call0.py 576.73 -> 572.49 : -4.24 = -0.735% (+/-0.04%)
viper_call1a.py 550.37 -> 546.21 : -4.16 = -0.756% (+/-0.09%)
viper_call1b.py 438.23 -> 435.68 : -2.55 = -0.582% (+/-0.06%)
viper_call1c.py 442.84 -> 440.04 : -2.80 = -0.632% (+/-0.08%)
viper_call2a.py 536.31 -> 532.35 : -3.96 = -0.738% (+/-0.06%)
viper_call2b.py 382.34 -> 377.07 : -5.27 = -1.378% (+/-0.03%)
And for unix on x64:
diff of scores (higher is better)
N=2000 M=2000 baseline -> this-commit diff diff% (error%)
bm_chaos.py 13594.20 -> 13073.84 : -520.36 = -3.828% (+/-5.44%)
bm_fannkuch.py 60.63 -> 59.58 : -1.05 = -1.732% (+/-3.01%)
bm_fft.py 112009.15 -> 111603.32 : -405.83 = -0.362% (+/-4.03%)
bm_float.py 246202.55 -> 247923.81 : +1721.26 = +0.699% (+/-2.79%)
bm_hexiom.py 615.65 -> 617.21 : +1.56 = +0.253% (+/-1.64%)
bm_nqueens.py 215807.95 -> 215600.96 : -206.99 = -0.096% (+/-3.52%)
bm_pidigits.py 8246.74 -> 8422.82 : +176.08 = +2.135% (+/-3.64%)
misc_aes.py 16133.00 -> 16452.74 : +319.74 = +1.982% (+/-1.50%)
misc_mandel.py 128146.69 -> 130796.43 : +2649.74 = +2.068% (+/-3.18%)
misc_pystone.py 83811.49 -> 83124.85 : -686.64 = -0.819% (+/-1.03%)
misc_raytrace.py 21688.02 -> 21385.10 : -302.92 = -1.397% (+/-3.20%)
The code size change is (firmware with a lot of frozen code benefits the
most):
bare-arm: +396 +0.697%
minimal x86: +1595 +0.979% [incl +32(data)]
unix x64: +2408 +0.470% [incl +800(data)]
unix nanbox: +1396 +0.309% [incl -96(data)]
stm32: -1256 -0.318% PYBV10
cc3200: +288 +0.157%
esp8266: -260 -0.037% GENERIC
esp32: -216 -0.014% GENERIC[incl -1072(data)]
nrf: +116 +0.067% pca10040
rp2: -664 -0.135% PICO
samd: +844 +0.607% ADAFRUIT_ITSYBITSY_M4_EXPRESS
As part of this change the .mpy file format version is bumped to version 6.
And mpy-tool.py has been improved to provide a good visualisation of the
contents of .mpy files.
In summary: this commit changes the bytecode to use qstr indirection, and
reworks the .mpy file format to be simpler and allow .mpy files to be
executed in-place. Performance is not impacted too much. Eventually it
will be possible to store such .mpy files in a linear, read-only, memory-
mappable filesystem so they can be executed from flash/ROM. This will
essentially be able to replace frozen code for most applications.
Signed-off-by: Damien George <damien@micropython.org>
2021-10-22 07:22:47 -04:00
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mp_module_context_t *o = m_new_obj(mp_module_context_t);
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o->module.base.type = &mp_type_module;
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o->module.globals = MP_OBJ_TO_PTR(mp_obj_new_dict(MICROPY_MODULE_DICT_SIZE));
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2014-03-08 10:24:39 -05:00
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// store __name__ entry in the module
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py: Rework bytecode and .mpy file format to be mostly static data.
Background: .mpy files are precompiled .py files, built using mpy-cross,
that contain compiled bytecode functions (and can also contain machine
code). The benefit of using an .mpy file over a .py file is that they are
faster to import and take less memory when importing. They are also
smaller on disk.
But the real benefit of .mpy files comes when they are frozen into the
firmware. This is done by loading the .mpy file during compilation of the
firmware and turning it into a set of big C data structures (the job of
mpy-tool.py), which are then compiled and downloaded into the ROM of a
device. These C data structures can be executed in-place, ie directly from
ROM. This makes importing even faster because there is very little to do,
and also means such frozen modules take up much less RAM (because their
bytecode stays in ROM).
The downside of frozen code is that it requires recompiling and reflashing
the entire firmware. This can be a big barrier to entry, slows down
development time, and makes it harder to do OTA updates of frozen code
(because the whole firmware must be updated).
This commit attempts to solve this problem by providing a solution that
sits between loading .mpy files into RAM and freezing them into the
firmware. The .mpy file format has been reworked so that it consists of
data and bytecode which is mostly static and ready to run in-place. If
these new .mpy files are located in flash/ROM which is memory addressable,
the .mpy file can be executed (mostly) in-place.
With this approach there is still a small amount of unpacking and linking
of the .mpy file that needs to be done when it's imported, but it's still
much better than loading an .mpy from disk into RAM (although not as good
as freezing .mpy files into the firmware).
The main trick to make static .mpy files is to adjust the bytecode so any
qstrs that it references now go through a lookup table to convert from
local qstr number in the module to global qstr number in the firmware.
That means the bytecode does not need linking/rewriting of qstrs when it's
loaded. Instead only a small qstr table needs to be built (and put in RAM)
at import time. This means the bytecode itself is static/constant and can
be used directly if it's in addressable memory. Also the qstr string data
in the .mpy file, and some constant object data, can be used directly.
Note that the qstr table is global to the module (ie not per function).
In more detail, in the VM what used to be (schematically):
qst = DECODE_QSTR_VALUE;
is now (schematically):
idx = DECODE_QSTR_INDEX;
qst = qstr_table[idx];
That allows the bytecode to be fixed at compile time and not need
relinking/rewriting of the qstr values. Only qstr_table needs to be linked
when the .mpy is loaded.
Incidentally, this helps to reduce the size of bytecode because what used
to be 2-byte qstr values in the bytecode are now (mostly) 1-byte indices.
If the module uses the same qstr more than two times then the bytecode is
smaller than before.
The following changes are measured for this commit compared to the
previous (the baseline):
- average 7%-9% reduction in size of .mpy files
- frozen code size is reduced by about 5%-7%
- importing .py files uses about 5% less RAM in total
- importing .mpy files uses about 4% less RAM in total
- importing .py and .mpy files takes about the same time as before
The qstr indirection in the bytecode has only a small impact on VM
performance. For stm32 on PYBv1.0 the performance change of this commit
is:
diff of scores (higher is better)
N=100 M=100 baseline -> this-commit diff diff% (error%)
bm_chaos.py 371.07 -> 357.39 : -13.68 = -3.687% (+/-0.02%)
bm_fannkuch.py 78.72 -> 77.49 : -1.23 = -1.563% (+/-0.01%)
bm_fft.py 2591.73 -> 2539.28 : -52.45 = -2.024% (+/-0.00%)
bm_float.py 6034.93 -> 5908.30 : -126.63 = -2.098% (+/-0.01%)
bm_hexiom.py 48.96 -> 47.93 : -1.03 = -2.104% (+/-0.00%)
bm_nqueens.py 4510.63 -> 4459.94 : -50.69 = -1.124% (+/-0.00%)
bm_pidigits.py 650.28 -> 644.96 : -5.32 = -0.818% (+/-0.23%)
core_import_mpy_multi.py 564.77 -> 581.49 : +16.72 = +2.960% (+/-0.01%)
core_import_mpy_single.py 68.67 -> 67.16 : -1.51 = -2.199% (+/-0.01%)
core_qstr.py 64.16 -> 64.12 : -0.04 = -0.062% (+/-0.00%)
core_yield_from.py 362.58 -> 354.50 : -8.08 = -2.228% (+/-0.00%)
misc_aes.py 429.69 -> 405.59 : -24.10 = -5.609% (+/-0.01%)
misc_mandel.py 3485.13 -> 3416.51 : -68.62 = -1.969% (+/-0.00%)
misc_pystone.py 2496.53 -> 2405.56 : -90.97 = -3.644% (+/-0.01%)
misc_raytrace.py 381.47 -> 374.01 : -7.46 = -1.956% (+/-0.01%)
viper_call0.py 576.73 -> 572.49 : -4.24 = -0.735% (+/-0.04%)
viper_call1a.py 550.37 -> 546.21 : -4.16 = -0.756% (+/-0.09%)
viper_call1b.py 438.23 -> 435.68 : -2.55 = -0.582% (+/-0.06%)
viper_call1c.py 442.84 -> 440.04 : -2.80 = -0.632% (+/-0.08%)
viper_call2a.py 536.31 -> 532.35 : -3.96 = -0.738% (+/-0.06%)
viper_call2b.py 382.34 -> 377.07 : -5.27 = -1.378% (+/-0.03%)
And for unix on x64:
diff of scores (higher is better)
N=2000 M=2000 baseline -> this-commit diff diff% (error%)
bm_chaos.py 13594.20 -> 13073.84 : -520.36 = -3.828% (+/-5.44%)
bm_fannkuch.py 60.63 -> 59.58 : -1.05 = -1.732% (+/-3.01%)
bm_fft.py 112009.15 -> 111603.32 : -405.83 = -0.362% (+/-4.03%)
bm_float.py 246202.55 -> 247923.81 : +1721.26 = +0.699% (+/-2.79%)
bm_hexiom.py 615.65 -> 617.21 : +1.56 = +0.253% (+/-1.64%)
bm_nqueens.py 215807.95 -> 215600.96 : -206.99 = -0.096% (+/-3.52%)
bm_pidigits.py 8246.74 -> 8422.82 : +176.08 = +2.135% (+/-3.64%)
misc_aes.py 16133.00 -> 16452.74 : +319.74 = +1.982% (+/-1.50%)
misc_mandel.py 128146.69 -> 130796.43 : +2649.74 = +2.068% (+/-3.18%)
misc_pystone.py 83811.49 -> 83124.85 : -686.64 = -0.819% (+/-1.03%)
misc_raytrace.py 21688.02 -> 21385.10 : -302.92 = -1.397% (+/-3.20%)
The code size change is (firmware with a lot of frozen code benefits the
most):
bare-arm: +396 +0.697%
minimal x86: +1595 +0.979% [incl +32(data)]
unix x64: +2408 +0.470% [incl +800(data)]
unix nanbox: +1396 +0.309% [incl -96(data)]
stm32: -1256 -0.318% PYBV10
cc3200: +288 +0.157%
esp8266: -260 -0.037% GENERIC
esp32: -216 -0.014% GENERIC[incl -1072(data)]
nrf: +116 +0.067% pca10040
rp2: -664 -0.135% PICO
samd: +844 +0.607% ADAFRUIT_ITSYBITSY_M4_EXPRESS
As part of this change the .mpy file format version is bumped to version 6.
And mpy-tool.py has been improved to provide a good visualisation of the
contents of .mpy files.
In summary: this commit changes the bytecode to use qstr indirection, and
reworks the .mpy file format to be simpler and allow .mpy files to be
executed in-place. Performance is not impacted too much. Eventually it
will be possible to store such .mpy files in a linear, read-only, memory-
mappable filesystem so they can be executed from flash/ROM. This will
essentially be able to replace frozen code for most applications.
Signed-off-by: Damien George <damien@micropython.org>
2021-10-22 07:22:47 -04:00
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mp_obj_dict_store(MP_OBJ_FROM_PTR(o->module.globals), MP_OBJ_NEW_QSTR(MP_QSTR___name__), MP_OBJ_NEW_QSTR(module_name));
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2014-03-08 10:24:39 -05:00
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// store the new module into the slot in the global dict holding all modules
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2015-11-27 12:01:44 -05:00
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el->value = MP_OBJ_FROM_PTR(o);
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2014-03-08 10:24:39 -05:00
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// return the new module
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2015-11-27 12:01:44 -05:00
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return MP_OBJ_FROM_PTR(o);
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2014-01-02 16:30:26 -05:00
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}
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2014-03-25 10:18:18 -04:00
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/******************************************************************************/
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// Global module table and related functions
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2015-11-27 08:38:15 -05:00
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STATIC const mp_rom_map_elem_t mp_builtin_module_table[] = {
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2019-02-17 22:58:44 -05:00
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#ifdef MICROPY_REGISTERED_MODULES
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// builtin modules declared with MP_REGISTER_MODULE()
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MICROPY_REGISTERED_MODULES
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#endif
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2014-12-09 11:19:48 -05:00
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};
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2017-01-19 18:21:30 -05:00
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MP_DEFINE_CONST_MAP(mp_builtin_module_map, mp_builtin_module_table);
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2020-02-25 23:24:09 -05:00
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// Tries to find a loaded module, otherwise attempts to load a builtin, otherwise MP_OBJ_NULL.
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mp_obj_t mp_module_get_loaded_or_builtin(qstr module_name) {
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// First try loaded modules.
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mp_map_elem_t *elem = mp_map_lookup(&MP_STATE_VM(mp_loaded_modules_dict).map, MP_OBJ_NEW_QSTR(module_name), MP_MAP_LOOKUP);
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2014-03-08 10:24:39 -05:00
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2020-02-25 23:24:09 -05:00
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if (!elem) {
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#if MICROPY_MODULE_WEAK_LINKS
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return mp_module_get_builtin(module_name);
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#else
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// Otherwise try builtin.
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elem = mp_map_lookup((mp_map_t *)&mp_builtin_module_map, MP_OBJ_NEW_QSTR(module_name), MP_MAP_LOOKUP);
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if (!elem) {
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2014-04-05 17:36:42 -04:00
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return MP_OBJ_NULL;
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}
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2014-03-08 10:24:39 -05:00
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2020-02-25 23:24:09 -05:00
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#if MICROPY_MODULE_BUILTIN_INIT
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// If found, it's a newly loaded built-in, so init it.
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mp_module_call_init(MP_OBJ_NEW_QSTR(module_name), elem->value);
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#endif
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#endif
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}
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2014-03-24 18:25:27 -04:00
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2020-02-25 23:24:09 -05:00
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return elem->value;
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2014-01-02 16:30:26 -05:00
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}
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2018-02-20 01:56:58 -05:00
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py: Automatically provide weak links from "foo" to "ufoo" module name.
This commit implements automatic module weak links for all built-in
modules, by searching for "ufoo" in the built-in module list if "foo"
cannot be found. This means that all modules named "ufoo" are always
available as "foo". Also, a port can no longer add any other weak links,
which makes strict the definition of a weak link.
It saves some code size (about 100-200 bytes) on ports that previously had
lots of weak links.
Some changes from the previous behaviour:
- It doesn't intern the non-u module names (eg "foo" is not interned),
which saves code size, but will mean that "import foo" creates a new qstr
(namely "foo") in RAM (unless the importing module is frozen).
- help('modules') no longer lists non-u module names, only the u-variants;
this reduces duplication in the help listing.
Weak links are effectively the same as having a set of symbolic links on
the filesystem that is searched last. So an "import foo" will search
built-in modules first, then all paths in sys.path, then weak links last,
importing "ufoo" if it exists. Thus a file called "foo.py" somewhere in
sys.path will still have precedence over the weak link of "foo" to "ufoo".
See issues: #1740, #4449, #5229, #5241.
2019-10-21 10:06:34 -04:00
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#if MICROPY_MODULE_WEAK_LINKS
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2020-02-25 23:24:09 -05:00
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// Tries to find a loaded module, otherwise attempts to load a builtin, otherwise MP_OBJ_NULL.
|
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mp_obj_t mp_module_get_builtin(qstr module_name) {
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// Try builtin.
|
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mp_map_elem_t *elem = mp_map_lookup((mp_map_t *)&mp_builtin_module_map, MP_OBJ_NEW_QSTR(module_name), MP_MAP_LOOKUP);
|
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if (!elem) {
|
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return MP_OBJ_NULL;
|
py: Automatically provide weak links from "foo" to "ufoo" module name.
This commit implements automatic module weak links for all built-in
modules, by searching for "ufoo" in the built-in module list if "foo"
cannot be found. This means that all modules named "ufoo" are always
available as "foo". Also, a port can no longer add any other weak links,
which makes strict the definition of a weak link.
It saves some code size (about 100-200 bytes) on ports that previously had
lots of weak links.
Some changes from the previous behaviour:
- It doesn't intern the non-u module names (eg "foo" is not interned),
which saves code size, but will mean that "import foo" creates a new qstr
(namely "foo") in RAM (unless the importing module is frozen).
- help('modules') no longer lists non-u module names, only the u-variants;
this reduces duplication in the help listing.
Weak links are effectively the same as having a set of symbolic links on
the filesystem that is searched last. So an "import foo" will search
built-in modules first, then all paths in sys.path, then weak links last,
importing "ufoo" if it exists. Thus a file called "foo.py" somewhere in
sys.path will still have precedence over the weak link of "foo" to "ufoo".
See issues: #1740, #4449, #5229, #5241.
2019-10-21 10:06:34 -04:00
|
|
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}
|
2020-02-25 23:24:09 -05:00
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#if MICROPY_MODULE_BUILTIN_INIT
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// If found, it's a newly loaded built-in, so init it.
|
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mp_module_call_init(MP_OBJ_NEW_QSTR(module_name), elem->value);
|
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#endif
|
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|
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return elem->value;
|
py: Automatically provide weak links from "foo" to "ufoo" module name.
This commit implements automatic module weak links for all built-in
modules, by searching for "ufoo" in the built-in module list if "foo"
cannot be found. This means that all modules named "ufoo" are always
available as "foo". Also, a port can no longer add any other weak links,
which makes strict the definition of a weak link.
It saves some code size (about 100-200 bytes) on ports that previously had
lots of weak links.
Some changes from the previous behaviour:
- It doesn't intern the non-u module names (eg "foo" is not interned),
which saves code size, but will mean that "import foo" creates a new qstr
(namely "foo") in RAM (unless the importing module is frozen).
- help('modules') no longer lists non-u module names, only the u-variants;
this reduces duplication in the help listing.
Weak links are effectively the same as having a set of symbolic links on
the filesystem that is searched last. So an "import foo" will search
built-in modules first, then all paths in sys.path, then weak links last,
importing "ufoo" if it exists. Thus a file called "foo.py" somewhere in
sys.path will still have precedence over the weak link of "foo" to "ufoo".
See issues: #1740, #4449, #5229, #5241.
2019-10-21 10:06:34 -04:00
|
|
|
}
|
|
|
|
#endif
|
|
|
|
|
2018-02-20 01:56:58 -05:00
|
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|
#if MICROPY_MODULE_BUILTIN_INIT
|
2020-02-25 23:24:09 -05:00
|
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STATIC void mp_module_register(mp_obj_t module_name, mp_obj_t module) {
|
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mp_map_t *mp_loaded_modules_map = &MP_STATE_VM(mp_loaded_modules_dict).map;
|
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mp_map_lookup(mp_loaded_modules_map, module_name, MP_MAP_LOOKUP_ADD_IF_NOT_FOUND)->value = module;
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}
|
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STATIC void mp_module_call_init(mp_obj_t module_name, mp_obj_t module_obj) {
|
2018-02-20 01:56:58 -05:00
|
|
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// Look for __init__ and call it if it exists
|
|
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mp_obj_t dest[2];
|
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mp_load_method_maybe(module_obj, MP_QSTR___init__, dest);
|
|
|
|
if (dest[0] != MP_OBJ_NULL) {
|
|
|
|
mp_call_method_n_kw(0, 0, dest);
|
|
|
|
// Register module so __init__ is not called again.
|
|
|
|
// If a module can be referenced by more than one name (eg due to weak links)
|
|
|
|
// then __init__ will still be called for each distinct import, and it's then
|
|
|
|
// up to the particular module to make sure it's __init__ code only runs once.
|
|
|
|
mp_module_register(module_name, module_obj);
|
|
|
|
}
|
|
|
|
}
|
|
|
|
#endif
|
2021-07-26 10:38:21 -04:00
|
|
|
|
|
|
|
void mp_module_generic_attr(qstr attr, mp_obj_t *dest, const uint16_t *keys, mp_obj_t *values) {
|
|
|
|
for (size_t i = 0; keys[i] != MP_QSTRnull; ++i) {
|
|
|
|
if (attr == keys[i]) {
|
|
|
|
if (dest[0] == MP_OBJ_NULL) {
|
|
|
|
// load attribute (MP_OBJ_NULL returned for deleted items)
|
|
|
|
dest[0] = values[i];
|
|
|
|
} else {
|
|
|
|
// delete or store (delete stores MP_OBJ_NULL)
|
|
|
|
values[i] = dest[1];
|
|
|
|
dest[0] = MP_OBJ_NULL; // indicate success
|
|
|
|
}
|
|
|
|
return;
|
|
|
|
}
|
|
|
|
}
|
|
|
|
}
|