#!/usr/bin/python # # Urwid signal dispatching # Copyright (C) 2004-2012 Ian Ward # # This library is free software; you can redistribute it and/or # modify it under the terms of the GNU Lesser General Public # License as published by the Free Software Foundation; either # version 2.1 of the License, or (at your option) any later version. # # This library is distributed in the hope that it will be useful, # but WITHOUT ANY WARRANTY; without even the implied warranty of # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU # Lesser General Public License for more details. # # You should have received a copy of the GNU Lesser General Public # License along with this library; if not, write to the Free Software # Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA # # Urwid web site: https://urwid.org/ from __future__ import annotations import itertools import typing import warnings import weakref from collections.abc import Callable, Collection, Container, Iterable class MetaSignals(type): """ register the list of signals in the class variable signals, including signals in superclasses. """ def __init__(cls, name: str, bases: tuple[type, ...], d: dict[str, typing.Any]) -> None: signals = d.get("signals", []) for superclass in cls.__bases__: signals.extend(getattr(superclass, 'signals', [])) signals = list({x: None for x in signals}.keys()) d["signals"] = signals register_signal(cls, signals) super().__init__(name, bases, d) def setdefaultattr(obj, name, value): # like dict.setdefault() for object attributes if hasattr(obj, name): return getattr(obj, name) setattr(obj, name, value) return value class Key: """ Minimal class, whose only purpose is to produce objects with a unique hash """ __slots__ = () class Signals: _signal_attr = '_urwid_signals' # attribute to attach to signal senders def __init__(self): self._supported = {} def register(self, sig_cls, signals: Container[str]) -> None: """ :param sig_class: the class of an object that will be sending signals :type sig_class: class :param signals: a list of signals that may be sent, typically each signal is represented by a string :type signals: signal names This function must be called for a class before connecting any signal callbacks or emitting any signals from that class' objects """ self._supported[sig_cls] = signals def connect( self, obj, name: str, callback: Callable[..., typing.Any], user_arg: typing.Any = None, *, weak_args: Iterable[typing.Any] = (), user_args: Iterable[typing.Any] = (), ) -> Key: """ :param obj: the object sending a signal :type obj: object :param name: the signal to listen for, typically a string :type name: signal name :param callback: the function to call when that signal is sent :type callback: function :param user_arg: deprecated additional argument to callback (appended after the arguments passed when the signal is emitted). If None no arguments will be added. Don't use this argument, use user_args instead. :param weak_args: additional arguments passed to the callback (before any arguments passed when the signal is emitted and before any user_args). These arguments are stored as weak references (but converted back into their original value before passing them to callback) to prevent any objects referenced (indirectly) from weak_args from being kept alive just because they are referenced by this signal handler. Use this argument only as a keyword argument, since user_arg might be removed in the future. :type weak_args: iterable :param user_args: additional arguments to pass to the callback, (before any arguments passed when the signal is emitted but after any weak_args). Use this argument only as a keyword argument, since user_arg might be removed in the future. :type user_args: iterable When a matching signal is sent, callback will be called. The arguments it receives will be the user_args passed at connect time (as individual arguments) followed by all the positional parameters sent with the signal. As an example of using weak_args, consider the following snippet: >>> import urwid >>> debug = urwid.Text('') >>> def handler(widget, newtext): ... debug.set_text("Edit widget changed to %s" % newtext) >>> edit = urwid.Edit('') >>> key = urwid.connect_signal(edit, 'change', handler) If you now build some interface using "edit" and "debug", the "debug" widget will show whatever you type in the "edit" widget. However, if you remove all references to the "debug" widget, it will still be kept alive by the signal handler. This because the signal handler is a closure that (implicitly) references the "edit" widget. If you want to allow the "debug" widget to be garbage collected, you can create a "fake" or "weak" closure (it's not really a closure, since it doesn't reference any outside variables, so it's just a dynamic function): >>> debug = urwid.Text('') >>> def handler(weak_debug, widget, newtext): ... weak_debug.set_text("Edit widget changed to %s" % newtext) >>> edit = urwid.Edit('') >>> key = urwid.connect_signal(edit, 'change', handler, weak_args=[debug]) Here the weak_debug parameter in print_debug is the value passed in the weak_args list to connect_signal. Note that the weak_debug value passed is not a weak reference anymore, the signals code transparently dereferences the weakref parameter before passing it to print_debug. Returns a key associated by this signal handler, which can be used to disconnect the signal later on using urwid.disconnect_signal_by_key. Alternatively, the signal handler can also be disconnected by calling urwid.disconnect_signal, which doesn't need this key. """ if user_arg is not None: warnings.warn( "Don't use user_arg argument, use user_args instead.", DeprecationWarning, ) sig_cls = obj.__class__ if name not in self._supported.get(sig_cls, ()): raise NameError(f"No such signal {name!r} for object {obj!r}") # Just generate an arbitrary (but unique) key key = Key() signals = setdefaultattr(obj, self._signal_attr, {}) handlers = signals.setdefault(name, []) # Remove the signal handler when any of the weakref'd arguments # are garbage collected. Note that this means that the handlers # dictionary can be modified _at any time_, so it should never # be iterated directly (e.g. iterate only over .keys() and # .items(), never over .iterkeys(), .iteritems() or the object # itself). # We let the callback keep a weakref to the object as well, to # prevent a circular reference between the handler and the # object (via the weakrefs, which keep strong references to # their callbacks) from existing. obj_weak = weakref.ref(obj) def weakref_callback(weakref): o = obj_weak() if o: self.disconnect_by_key(o, name, key) user_args = self._prepare_user_args(weak_args, user_args, weakref_callback) handlers.append((key, callback, user_arg, user_args)) return key def _prepare_user_args( self, weak_args: Iterable[typing.Any] = (), user_args: Iterable[typing.Any] = (), callback: Callable[..., typing.Any] | None = None, ) -> tuple[Collection[weakref.ReferenceType], Collection[typing.Any]]: # Turn weak_args into weakrefs and prepend them to user_args w_args = tuple(weakref.ref(w_arg, callback) for w_arg in weak_args) args = tuple(user_args) or () return (w_args, args) def disconnect( self, obj, name: str, callback: Callable[..., typing.Any], user_arg: typing.Any = None, *, weak_args: Iterable[typing.Any] = (), user_args: Iterable[typing.Any] = (), ) -> None: """ :param obj: the object to disconnect the signal from :type obj: object :param name: the signal to disconnect, typically a string :type name: signal name :param callback: the callback function passed to connect_signal :type callback: function :param user_arg: the user_arg parameter passed to connect_signal :param weak_args: the weak_args parameter passed to connect_signal :param user_args: the weak_args parameter passed to connect_signal This function will remove a callback from the list connected to a signal with connect_signal(). The arguments passed should be exactly the same as those passed to connect_signal(). If the callback is not connected or already disconnected, this function will simply do nothing. """ signals = setdefaultattr(obj, self._signal_attr, {}) if name not in signals: return handlers = signals[name] # Do the same processing as in connect, so we can compare the # resulting tuple. user_args = self._prepare_user_args(weak_args, user_args) # Remove the given handler for h in handlers: if h[1:] == (callback, user_arg, user_args): return self.disconnect_by_key(obj, name, h[0]) def disconnect_by_key(self, obj, name: str, key: Key) -> None: """ :param obj: the object to disconnect the signal from :type obj: object :param name: the signal to disconnect, typically a string :type name: signal name :param key: the key for this signal handler, as returned by connect_signal(). :type key: Key This function will remove a callback from the list connected to a signal with connect_signal(). The key passed should be the value returned by connect_signal(). If the callback is not connected or already disconnected, this function will simply do nothing. """ signals = setdefaultattr(obj, self._signal_attr, {}) handlers = signals.get(name, []) handlers[:] = [h for h in handlers if h[0] is not key] def emit(self, obj, name: str, *args) -> bool: """ :param obj: the object sending a signal :type obj: object :param name: the signal to send, typically a string :type name: signal name :param args: zero or more positional arguments to pass to the signal callback functions This function calls each of the callbacks connected to this signal with the args arguments as positional parameters. This function returns True if any of the callbacks returned True. """ result = False signals = getattr(obj, self._signal_attr, {}) handlers = signals.get(name, []) for key, callback, user_arg, (weak_args, user_args) in handlers: result |= self._call_callback(callback, user_arg, weak_args, user_args, args) return result def _call_callback( self, callback, user_arg: typing.Any, weak_args: Collection[weakref.ReferenceType], user_args: Collection[typing.Any], emit_args: Iterable[typing.Any], ) -> bool: args_to_pass = [] for w_arg in weak_args: real_arg = w_arg() if real_arg is not None: args_to_pass.append(real_arg) else: # de-referenced return False # The deprecated user_arg argument was added to the end # instead of the beginning. args = itertools.chain(args_to_pass, user_args, emit_args, (user_arg,) if user_arg is not None else ()) return bool(callback(*args)) _signals = Signals() emit_signal = _signals.emit register_signal = _signals.register connect_signal = _signals.connect disconnect_signal = _signals.disconnect disconnect_signal_by_key = _signals.disconnect_by_key