Metadata-Version: 2.1
Name: worktoy
Version: 0.99.32
Summary: Collection of Utilities
Author-email: Asger Jon Vistisen <asgerjon2@gmail.com>
Project-URL: Homepage, https://github.com/AsgerJon/WorkToy
Project-URL: Bug Tracker, https://github.com/AsgerJon/WorkToy
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Programming Language :: Python :: 3.13
Classifier: Programming Language :: Python :: Implementation :: CPython
Classifier: License :: OSI Approved :: GNU Affero General Public License v3 or later (AGPLv3+)
Classifier: Operating System :: OS Independent
Classifier: Development Status :: 3 - Alpha
Classifier: Intended Audience :: Developers
Classifier: Natural Language :: English
Classifier: Topic :: Utilities
Requires-Python: >=3.11
Description-Content-Type: text/markdown
License-File: LICENSE

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# WorkToy v0.99.xx

WorkToy collects common utilities. It is available for installation via pip:

```
pip install worktoy
```

Version 0.99.xx is in final stages of development. It will see no new
features, only bug fixes and documentation updates. Upon completion of
tasks given below, version 1.0.0 will be released.
Navigate with the table of contents below.

# Table of Contents

- [WorkToy v0.99.xx](#worktoy-v099xx)
    - [Table of Contents](#table-of-contents)
    - [Installation](#installation)
    - [Usage](#usage)
        - [desc](#worktoydesc)
        - [ezdata](#worktoyezdata)
        - [keenum](#worktoykeenum)
        - [meta](#worktoymeta)
        - [parse](#worktoyparse)
        - [text](#worktoytext)
        - [yolo](#worktoyyolo)
    - [Development](#development)

# Installation

```bash 
pip install worktoy
```

# Usage

# `worktoy.desc`

## Background - The Python Descriptor Protocol

The descriptor protocol in Python allows significant customisation of the
attribute access mechanism. To understand this protocol, consider a class
body assigning an object to a name. During the class creation process,
when this line is reached, the object is assigned to the name. For the
purposes of this discussion, the object is created when this line is
reached, for example:

```python
class PlanePoint:
  """This class represent an integer valued point in the plane. """
  x = Integer(0)
  y = Integer(0)  # Integer is defined below. In practice, classes should 
  #  be defined in dedicated files.
``` 

The above class ´PlanePoint´ owns a pair of attributes. These are
instances of the ´Integer´ class defined below. The ´Integer´ class is a
descriptor and is thus the focus of this discussion.

```python
class Integer:
  """This descriptor class wraps an integer value. More details will be 
  added throughout this discussion."""
  __fallback_value__ = 0
  __default_value__ = None
  __field_name__ = None
  __field_owner__ = None

  def __init__(self, *args) -> None:
    for arg in args:
      if isinstance(arg, int):
        self.__default_value__ = arg
        break
    else:
      self.__default_value__ = self.__fallback_value__

  #  The '__init__' method implemented above makes use of the unusual 
  #  'else' clause at the end of a loop. This clause is executed once after 
  #  the loop has completed. Since it is part of the loop, the 'break' 
  #  keyword applies to it as well as the loop itself. The for loop above 
  #  iterates through the positional arguments and if it encounters an 
  #  'int' argument, it assigns it and issues the 'break'. So if the loop 
  #  completes without hitting the 'break', no 'int' could be found in any 
  #  of the positional arguments. Conveniently, the 'else' block then 
  #  assigns the fallback value.

  def __set_name__(self, owner: type, name: str) -> None:
    """Powerful method called automatically when the class owning the 
    descriptor instance is finally created. It informs the descriptor 
    instance of its owner and importantly, it informs the descriptor of 
    the name by which it appears in the class body. """
    self.__field_name__ = name
    self.__field_owner__ = owner

  def __get__(self, instance: object, owner: type) -> int:
    """Getter-function."""
``` 

## The ``__set_name__`` method

Python 3.6 was released on December 23, 2016. This version introduced
the ``__set_name__`` method, which marks a significant improvement to the
descriptor protocol. It informs instances of descriptor classes of the
class that owns them **and** the name by which they appear in the class
namespace. Much of the functionality found in the ``worktoy.desc`` module
would not be possible without this method.

### The `__get__` method

Consider the code below:

```python
class Descriptor:
  """Descriptor class."""

  def __get__(self, instance: object, owner: type) -> object:
    """Getter-function."""

  def __set_name__(self, owner: type, name: str) -> None:
    """Informs the descriptor instance that the owner is created"""


class OwningClass:
  """Class owning the descriptor."""
  descriptor = Descriptor()


#  At this point in the code, the OwningClass is created, which triggers 
#  the '__set_name__' method on the descriptor instance. 
#  Event 1

if __name__ == '__main__':
  owningInstance = OwningClass()  # Event 2
  print(OwningClass.descriptor)  # Event 3
  print(owningInstance.descriptor)  # Event 4
```

Let us examine each of the four events marked in the above example:

1. **Event 1** - This marks the completion of the class creation process,
   which is described in excruciating detail in later sections. Of
   interest here is the call to the ``__set_name__`` method on the
   descriptor:
   ``Descriptor.__set_name__(descriptor, OwningClass, 'descriptor')``
2. **Event 2** - This marks the creation of an instance of the owning
   class. This event is not of interest to this discussion.
3. **Event 3** - Accessing the descriptor on the OwningClass triggers the
   following function call:
   ``Descriptor.__get__(descriptor, None, OwningClass)``
4. **Event 4** - Accessing the descriptor on an instance of the owning
   class triggers the following function call:
   ``Descriptor.__get__(descriptor, owningInstance, OwningClass)``

The ``__get__`` determines what is returned when the descriptor is
accessed. Please note that this method is what is called every time the
descriptor instance is accessed regardless of how. In the above example,
the following would each result in a call to the ``__get__`` method:

```python
#  Each result in:  Descriptor.__get__(descriptor, None, OwningClass)
OwningClass.descriptor
getattr(OwningClass, 'descriptor')
object.__getattribute__(OwningClass, 'descriptor')
```

The interpreter always refers to the ``__get__`` method. To still allow
access to the descriptor object itself, the common pattern is for the
``__get__`` method to return the descriptor instance when accessed
through the owning class:

```python
class Descriptor:
  """Descriptor class."""

  def __get__(self, instance: object, owner: type) -> object:
    """Getter-function."""
    if instance is None:
      return self
    #  YOLO
```

This author suggests never deviating from this pattern. Perhaps some more
functionality or some hooks may be implemented, but the descriptor
instance itself should always be returned when accessed through the owning
class. When accessed through the instance, the descriptor is free to do
whatever it wants!

### The `__set__` method

The prior section focused on the distinction between accessing on the
class or instance level. The ``__set__`` method defined on the Descriptor
is invoked only when accessed through the instance:

```python
class Descriptor:
  """Descriptor class."""

  #  Code as before
  def __set__(self, instance: object, value: object) -> None:
    """Setter-function."""


if __name__ == '__main__':
  owningInstance = OwningClass()
  owningInstance.descriptor = 69  # Event 1
  print(owningInstance.descriptor)  # Event 2
  OwningClass.descriptor = 420  # Event 3
  print(owningInstance.descriptor)  # Event 4
```

The above code triggers the following function call:

-**Event 1:** ``Descriptor.__set__(descriptor, owningInstance, 7)``
-**Event 2:** ``Descriptor.__get__(descriptor, owningInstance, OwningClass)``
-**Event 3:** This call does not involve the descriptor at all, instead
it simply overwrites the descriptor.
-**Event 4:** The previous event overwrote the descriptor instance so now
it simply returns the value set in Event 3.

Thus, when trying to call ``__set__`` through the owning class, it is
applied to the descriptor object itself. This matches the suggested
implementation of the ``__get__`` method which would return the
descriptor item itself, when accessed through the owning class.

### The ``delete`` method

The most important comment here is this warning: **Do not mistake
``__del__`` and ``__delete__``!** ``__del__`` is a mysterious method
associated with the destruction of an object.

The ``__delete__`` method on the other hand allows instance specific
control over what happens when the ``del`` keyword is used on an
attribute through an instance. If the descriptor class does not
implement it, it will raise an ``AttributeError`` when the interpreter
tries to invoke ``__delete__`` on the descriptor instance. Deleting an
attribute through the owning class does not involve the descriptor at all,
but is managed on the metaclass level. Generally, the descriptor is just
yeeted in this case.

```python
class Descriptor:
  """Descriptor class."""

  #  Code as before
  def __delete__(self, instance: object, ) -> None:
    """Setter-function."""


if __name__ == '__main__':
  owningInstance = OwningClass()
  del owningInstance.descriptor  # event 1
  print(owningInstance.descriptor)  # event 2
```

If a descriptor class does implement the ``__delete__`` method the script
above is expected to trigger the following:

-**Event 1:** ``Descriptor.__delete__(descriptor, owningInstance)``

-**Event 2a:** ``AttributeError: __delete__`` if the descriptor does not
implement the method.

-**Event 2b:** ``AttributeError: 'OwningClass' object has no attribute
'descriptor'!`` if the descriptor does implement the method and allows
deletion to proceed.

-**Event 2c:** A custom implementation of the ``__delete__`` method which
does not allow deletion and thus raises an appropriate exception. In this
case, this author suggests raising a ``TypeError`` to indicate that the
attribute is of a read-only type. This is different than the
``AttributeError`` which generally indicate the absense of the attribute.

If a custom implementation of the ``__delete__`` method is provided, 2b
or 2c as described above should happen, as this is the generally expected
behaviour in Python. Implementing some alternative behaviour might be
cute or something, but when the code is then used elsewhere, the bugs
resulting from this unexpected behaviour are nearly impossible to find.

### Descriptor Protocol Implementations

There are three questions to consider before discussing implementation
details:

1. Is the descriptor class simply a way for owning classes to enhance
   attribute access?
2. Should classes implement the descriptor protocol to define their
   behaviour when owned by other classes?
3. Should a central descriptor class define how one class can own an
   instance of another?

There is certainly a need for classes to specialize access to their
attributes. This is the most common use of the descriptor protocol.
Python itself implements the ``property`` class to provide this control.

When creating a custom class, it seems reasonable to consider that other
classes might own instance of it and to implement descriptor protocol
methods as appropriate. Unfortunately, this is not commonly done meaning
that you can expect to have to own instances of classes that do not
provide for this ownership interaction themselves.

The ``AttriBox`` class provided by the ``worktoy.desc`` module does
implement the descriptor protocol in a way designed to allow one class to
own instances of another without either having to implement anything
related to the descriptor protocol. This class also makes the second
question redundant.

This discussion will now proceed with the following:

1. Usage of the ``property`` class provided by Python.
2. The ``worktoy.desc`` module provides the ``AbstractDescriptor`` class,
   which implements the parts of the descriptor protocol used by both
   ``Field`` and ``AttriBox``.
3. Implementation of the vastly superior ``Field`` class provided by the
   ``worktoy.desc`` module.
   4Usage an examples of the ``AttriBox`` class provided by the
   ``worktoy.desc`` module.

### The `property` class

The `property` class is a built-in class in Python. It allows the use of
a decorator to define getter, setter and deleter functions for a property.
Alternatively, the ``property`` may be instantiated in the class body
with the getter, setter and deleter functions as arguments. The following
example will demonstrate a class owning a number and a name,
demonstrating the two approaches to defining properties.

```python
from __future__ import annotations


class OwningClass:
  """This class uses 'property' to implement the 'name' attribute. """

  __fallback_number__ = 0
  __fallback_name__ = 'Unnamed'
  __inner_number__ = None
  __inner_name__ = None

  def __init__(self, *args, **kwargs) -> None:
    self.__inner_number__ = kwargs.get('number', None)
    self.__inner_name__ = kwargs.get('name', None)
    for arg in args:
      if isinstance(arg, int) and self.__inner_number__ is None:
        self.__inner_number__ = arg
      elif isinstance(arg, str) and self.__inner_name__ is None:
        self.__inner_name__ = arg

  @property
  def name(self) -> str:
    """Name property"""
    if self.__inner_name__ is None:
      return self.__fallback_name__
    return self.__inner_name__

  @name.setter
  def name(self, value: str) -> None:
    """Name setter"""
    self.__inner_name__ = value

  @name.deleter
  def name(self) -> None:
    """Name deleter"""
    del self.__inner_name__

  def _getNumber(self) -> int:
    """Number getter"""
    if self.__inner_number__ is None:
      return self.__fallback_number__
    return self.__inner_number__

  def _setNumber(self, value: int) -> None:
    """Number setter"""
    self.__inner_number__ = value

  def _delNumber(self) -> None:
    """Number deleter"""
    del self.__inner_number__

  number = property(_getNumber, _setNumber, _delNumber, doc='Number')

```

The above example demonstrates the use of the `property` class to enhance
the attribute access mechanism.

### The `AbstractDescriptor` class

The ``AbstractDescriptor`` class provides the ``__set_name__`` method and
delegates accessor functions to the following methods:

- ``__instance_get__``: Getter-function (Required!)
- ``__instance_set__``: Setter-function (Optional)
- ``__instance_del__``: Deleter-function (Optional)

When implementing ``__instance_get__`` to handle a missing value, the
subclass must raise a ``MissingValueException`` passing the instance and
itself to the constructor of it. This missing value situation is one
where no default value is provided and the value has not been set. The
``AbstractDescriptor`` calls ``__instance_get__`` during the ``__set__``
and ``delete__`` methods to collect the old value which is used in the
notification. If it catches such an error during ``__get__``, it raises
an ``AttributeError`` from it.

The ``AbstractDescriptor`` provides descriptors to mark methods to be
notified when the attribute is accessed. The methods are:

- ``ONGET``: Called when the attribute is accessed.
- ``ONSET``: Called when the attribute is set.
- ``ONDEL``: Called when the attribute is deleted.

Both ``Field`` and ``AttriBox`` subclass the ``AbstractDescriptor`` class.
These are discussed below.

### The `Field` class

The ``Field`` class provides descriptors in addition to those implemented
on the ``AbstractDescriptor`` class. These are used by owning classes to
mark accessor methods, much like the ``property`` class. Unlike the
Python ``property`` class, instances of the ``Field`` class must be
defined before the accessor methods in the class body. The decorators
require their field instance to be defined in the lexical scope before
they are available to decorate methods.

Below is an example of a plane point implementing the coordinate
attributes using the ``Field`` class:

```python
from __future__ import annotations
from worktoy.desc import Field


class Point:
  """This class uses the 'Field' descriptor to implement the coordinate
  attributes. """
  __x_value__ = None
  __y_value__ = None

  x = Field()
  y = Field()

  @x.GET
  def _getX(self) -> float:
    return self.__x_value__

  @x.SET
  def _setX(self, value: float) -> None:
    self.__x_value__ = value

  @y.GET
  def _getY(self) -> float:
    return self.__y_value__

  @y.SET
  def _setY(self, value: float) -> None:
    self.__y_value__ = value

  def __init__(self, *args, **kwargs) -> None:
    self.__x_value__ = kwargs.get('x', None)
    self.__y_value__ = kwargs.get('y', None)
    for arg in args:
      if isinstance(arg, int):
        arg = float(arg)
      if isinstance(arg, float):
        if self.__x_value__ is None:
          self.__x_value__ = arg
        elif self.__y_value__ is None:
          self.__y_value__ = arg
          break
    else:
      if self.__x_value__ is None:
        self.__x_value__, self.__y_value__ = 69., 420.
      elif self.__y_value__ is None:

        self.__y_value__ = 420.
```

The ``Field`` class allows classes to implement how attributes are accessed.

### The `AttriBox` class

Where ``Field`` relies on the owning class itself to specify the accessor
functions, the ``AttriBox`` class provides an attribute of a specified
class. This class is not instantiated until an instance of the owning
class calls the ``__get__`` method. Only then will the inner object of
the specified class be created. The inner object is then placed on a
private variable belonging to the owning instance. When the ``__get__``
is next called the inner object at the private variable is returned. When
instantiating the ``AttriBxo`` class, the following syntactic sugar
should be used: ``fieldName = AttriBox[FieldClass](*args, **kwargs)``.
The arguments placed in the parentheses after the brackets are those used
to instantiate the ``FieldClass`` given in the brackets.

Below is an example of a class using the ``AttriBox`` class to implement
a ``Circle`` class. It uses the ``Point`` class defined above to manage
the center of the circle. Notice how the ``Point`` class itself is wrapped
in an ``AttriBox`` instance. The ``area`` attribute is defined using the
``Field`` class and illustrates the use of the ``Field`` class to expose
a value as an attribute. Finally, it used the ``ONSET`` decorator to mark
a method as the validator for the radius attribute. This causes the
method to be hooked into the ``__set__`` method on the ``radius``.

```python
from __future__ import annotations


class Circle:
  """This class uses the 'AttriBox' descriptor to manage the radius and
  center, and it also illustrates a use case for the 'Field' class."""

  radius = AttriBox[float](0)
  center = AttriBox[Point](0, 0)
  area = Field()

  @area.GET
  def _getArea(self) -> float:
    return 3.1415926535897932 * self.radius ** 2

  @radius.ONSET
  def _validateRadius(self, _, value: float) -> None:
    if value < 0:
      e = """Received negative radius!"""
      raise ValueError(e)

  def __init__(self, *args, **kwargs) -> None:
    """Constructor omitted..."""

  def __str__(self) -> str:
    msg = """Circle centered at: (%.3f, %.3f), with radius: %.3f"""
    return msg % (self.center.x, self.center.y, self.radius)


if __name__ == '__main__':
  circle = Circle(69, 420, 1337)
  print(circle)
  circle.radius = 1
  print(circle)
```

Running the code above will output the following:

```terminal
Circle centered at: (69.000, 420.000), with radius: 4.000
Circle centered at: (69.000, 420.000), with radius: 1.000
```

### ``worktoy.desc`` - Summary

As have been demonstrated and explained, the ``worktoy.desc`` module
provides helpful, powerful and flexible implementations of the descriptor
protocol. The ``Field`` allows classes to customize attribute access
behaviour in significant detail. The ``AttriBox`` class provides a way to
set as attribute any class on another class in a single line. As
mentioned briefly, the class contained by the ``AttriBox`` instance is
not instantiated until an instance of the owning class calls the
``__get__`` method. In the following section, the importance of this lazy
instantiation feature will be illustrated with an example involving the
``PySide6`` library.

### PySide6 - Qt for Python

The PySide6 library provides Python bindings for the Qt framework. Despite
involving bindings to a C++ library, the code itself remains Python and
not C++, thank the LORD. Nevertheless, certain errors do not have a
Pythonic representation. The ``AttriBox`` class was envisioned for this
very reason. Its lazy instantiation system prevents something called
'Segmentation Fault'. You can lead a long and happy life not ever
encountering those words again, thanks to the ``AttriBox`` class!

Central to Qt is the main event loop managed by an instance of
``QCoreApplication`` or of a subclass of it. While the application is
running, instances of ``QObject`` provide the actual application
functionality. It is reasonable to regard the ``QObject`` in Qt and the
``object`` object in Python as similar. Every window, every widget, the
running application, managed threads and just about everything else in Qt
is essentially an instance of ``QObject``. Having defined these terms, we
may now discuss the two central rules of Qt:

- Only one instances of ``QCoreApplication`` may be running at any time.
- The first instantiated ``QObject`` must be an instance of the
  ``QCoreApplication`` class.

Instantiating any ``QObject`` before the ``QCoreApplication`` is running
will result in immediate error. Enter the ``AttriBox`` class. The
somewhat inflexible nature of the above rules regains flexibility by
making use of the lazy instantiation provided by the ``AttriBox`` class.

In the following, we will see a simple application consisting of a window
showing a welcome message provided as an instance of the ``QLabel`` class
along with an exit button provided by the ``QPushButton`` class. These
widgets are stacked vertically and are managed by an instance of the
``QVBoxLayout`` class and finally these are managed by an instance of
``QWidget`` which is the parent of the widgets and which owns the layout.
This widget is set as the central widget in the main window. The main
window itself is a subclass of the ``QMainWindow`` class.

```python
import sys
from PySide6.QtWidgets import QApplication, QMainWindow
from PySide6.QtWidgets import QWidget, QLabel, QPushButton, QVBoxLayout
from PySide6.QtCore import QSize
from worktoy.desc import AttriBox


class MainWindow(QMainWindow):
  """This subclass of QMainWindow provides the main application window. """

  baseWidget = AttriBox[QWidget]()
  layout = AttriBox[QVBoxLayout]()
  welcomeLabel = AttriBox[QLabel]()
  exitButton = AttriBox[QPushButton]()

  def initUi(self) -> None:
    """This method sets up the user interface"""
    self.setMinimumSize(QSize(480, 320))
    self.setWindowTitle("Welcome to WorkToy!")
    self.welcomeLabel.setText("""Welcome to WorkToy!""")
    self.exitButton.setText("Exit")
    self.layout.addWidget(self.welcomeLabel)
    self.layout.addWidget(self.exitButton)
    self.baseWidget.setLayout(self.layout)
    self.setCentralWidget(self.baseWidget)

  def initSignalSlot(self) -> None:
    """This method connects the signals and slots"""
    self.exitButton.clicked.connect(self.close)

  def show(self) -> None:
    """This reimplementation calls 'initUi' and 'initSignalSlot' before 
    calling the parent implementation"""
    self.initUi()
    self.initSignalSlot()
    QMainWindow.show(self)


if __name__ == '__main__':
  app = QApplication([])
  window = MainWindow()
  window.show()
  sys.exit(app.exec())

```

The PySide6 library provides Python bindings for the Qt framework. What
is Qt? For the purposes of this discussion, Qt is a framework for
developing professional and high-quality graphical user interfaces.
Entirely with Python. Below is a very simple script that opens an empty
window and nothing more.

```python
import sys
from PySide6.QtWidgets import QApplication, QMainWindow
from PySide6.QtCore import QSize


class MainWindow(QMainWindow):
  def __init__(self, parent=None):
    super().__init__(parent)
    self.setWindowTitle("Hello, World!")
    self.setMinimumSize(QSize(480, 320))


if __name__ == "__main__":
  app = QApplication(sys.argv)
  window = MainWindow()
  window.show()
  sys.exit(app.exec())
```

From here, the window class can be extended to include buttons, text boxes,
and other widgets. Qt provides off-the-shelf widgets for much common use.
These widgets may be subclassed further customizing their appearance or
behaviour. Actually advanced users may even create entirely new widgets
from the ground up. The possibilities are endless.

Before we get carried away, we need to keep one very important quirk in
mind. Qt provides a vast array of classes that all inherit from the
`QObject` class. This class has an odd, but very unforgiving requirement.
No instances of `QObject` may be instantiated without a running
QCoreApplication. This immediately presents a problem to our otherwise
elegant descriptor protocol: We are not permitted to instantiate
instances before the main script runs. Such as during class creation. For
this reason, the `AttriBox` class was created to implement lazy
instantiation! Let us now see how we might create a more advanced
graphical user interface whilst adhering to the `QObject` requirement.

### The `AttriBox` class - Lazy instantiation

```python
from PySide6.QtWidgets import QApplication, QMainWindow, QWidget
from PySide6.QtWidgets import QVBoxLayout, QHBoxLayout, QLabel
from PySide6.QtCore import QSize

from worktoy.desc import AttriBox, THIS


class MainWindow(QMainWindow):
  """Subclass of QMainWindow. This class provides the main window for the 
  application. """

  baseWidget = AttriBox[QWidget](THIS)
  verticalLayout = AttriBox[QVBoxLayout]()
  welcomeLabel = AttriBox[QLabel]()

  def show(self) -> None:
    """Before invoking the parent method, we will setup the window. """
    self.setMinimumSize(QSize(480, 320))
    self.setWindowTitle("WorkToy!")
    self.welcomeLabel.setText("""Welcome to AttriBox!""")
    self.verticalLayout.addWidget(self.welcomeLabel)
    self.baseWidget.setLayout(self.verticalLayout)
    self.setCentralWidget(self.baseWidget)
    QMainWindow.show(self)


if __name__ == "__main__":
  app = QApplication([])
  window = MainWindow()
  window.show()
  app.exec()
```

The above script makes use of the lazy instantiation provided by the
`AttriBox` class. While some readers may have recognized the
similarities between ``Field`` and ``property``, many readers are presently
picking jaws up from the floor, pinching themselves or seeking spiritual
guidance. The `AttriBox` not only implements an enhanced version of the
descriptor protocol, but it does so on a single line, where it even
provides syntactic sugar for defining the class intended for lazy
instantiation. Let us examine ``AttriBox`` in more detail.

### The `AttriBox` class

```python
from PySide6.QtWidgets import QApplication, QMainWindow, QWidget
from PySide6.QtWidgets import QVBoxLayout, QHBoxLayout, QLabel
from PySide6.QtCore import QSize

from worktoy.desc import AttriBox, THIS


class MainWindow(QMainWindow):
  """Subclass of QMainWindow. This class provides the main window for the 
    application. """

  baseWidget = AttriBox[QWidget](THIS)
  #  The above line creates a descriptor at name 'baseWidget' that will 
  #  instantiate a QWidget instance. When the __get__ on the descriptor
  #  tries to retrieve the value it owns, only then will the value be 
  #  instantiated. When instantiating the value, the arguments in the 
  #  parentheses are passed to the constructor of the class. That brings 
  #  us to the 'THIS' token. When instantiating the value, the 'THIS' token
  #  is replaced with the instance of the owning class. This is convenient 
  #  for the 'baseWidget' attribute, as it allows the instance created to 
  #  set its parent to the owning instance.
```

The use case pertaining to the PySide6 library makes great use of the
lazy instantiation. In fact, the motivation that led to the creation of
the ``AttriBox`` class was this need for lazy instantiation.

### ``worktoy.desc.AttriBox`` - Advanced Instantiation

PENDING...
WorkToy v1 will not release until this documentation is complete.

## worktoy.meta - Understanding the Python metaclass

Readers may associate the word **meta** with crime on account of the hype
created around the term **metaverse**. This author hopes readers will
come to associate the word instead with the Python metaclass. The
**'worktoy.meta'** module provides functions and classes allowing a more
streamlined approach to metaclass programming. This documentation
explains the functionality of metaclasses in general and how this module
provides helpful tools.

### Everything is an object!

Python operates on one fundamental idea: Everything is an object.
Everything. All numbers, all strings, all functions, all modules and
everything that you can reference. Even ``object`` itself is an object.
This means that everything supports a core set of attributes and methods
defined on the core ``object`` type.

### Extensions of ``object``

With everything being an object, it is necessary to extend the
functionalities in the core ``object`` type to create new types,
hereinafter classes. This allows objects to share the base ``object``,
while having additional functionalities depending on their class. Python
provides a number of special classes listed below:

- **``object``** - The base class for all classes. This class provides
  the most basic functionalities.
- **``int``** - Extension for integers. The python interpreter uses
  heavily optimized C code to handle integers. This is the case for
  several classes on this list.
- **``float``** - Extension for floating point numbers. This class
  provides a number of methods for manipulating floating point numbers.
- **``list``** - Extension for lists of objects of dynamic size allowing
  members to be of any type. As the amount of data increases, the greater
  the performance penalty for the significant convenience.
- **``tuple``** - Extension for tuples of objects of fixed size. This
  class is similar to the list class, but the size is fixed. This means
  that the tuple is immutable. While this is inflexible, it does allow
  instances to be used as keys in mappings.
- **``dict``** - Extension for mappings. Objects of this class map keys
  to values. Keys be of a hashable type, meaning that ``object`` itself
  is not sufficient. The hashables on this list are: ``int``, ``float``,
  ``str`` and ``tuple``.
- **``set``** - Extension for sets of objects. This class provides a
  number of methods for manipulating sets. The set class is optimized for
  membership testing.
- **``frozenset``** - Provides an immutable version of ``set`` allowing
  it to be used as a key in mappings.
- **``str``** - Extension for strings. This class provides a number of
  methods for manipulating strings. The ``worktoy.text`` module expands
  upon some of these.

To reiterate, everything is an object. Each object belongs to the
``object`` class but may additionally belong to a class that extends the
``object`` class. For example: ``7`` is an object. It is an instance of
``object`` by being an instance of ``int`` which extends ``object``.
Classes are responsible for defining the instantiation of instances
belonging to them. Generally speaking, classes may be instantiated by
calling the class object treating it like a function. Classes may accept
or even require arguments when instantiated.

Before proceeding, we need to talk about functions. Python provides two
builtin extensions of ``object`` that provide standalone objects that
implement functions: ``function`` and ``lambda``. Both of these have
quite unique instantiation syntax and does not follow the conventions we
shall see later in this discussion.

### Defining a ``function``

Python allows the following syntax for creating a function. Please note
that all functions are still objects, and all functions created with the
syntax below belong to the same class ``function``. Unfortunately, this
class cannot be referred to directly. Which is super weird. Anyway, to
create a function, use the following syntax:

```python
def multiplication(a: int, b: int) -> int:
  """This function returns the product of two integers."""
  return a * b
```

#### RANT

The above function implements multiplication. It also provides the
optional features: type hints and a docstring. The interpreter completely
ignores these, but they are very helpful for humans. It is the opinion of
this author that omitting type hints and docstrings is acceptable only
when running a quick test. If anyone except you or God will ever read
your code, it must have type hints and docstrings!

#### END OF RANT

Below is the syntax that invokes the function:

```python
result = multiplication(7, 8)  # result is 56
```

In the function definition, the positional arguments were named ``a`` and
``b``. In the above invocation, the positional arguments were given
directly. Alternatively, they might have been given as keyword arguments:

```python
result = multiplication(a=7, b=8)  # result is 56
tluser = multiplication(b=8, a=7)  # result is 56
```

When keyword arguments are used instead of positional arguments, the
order is irrelevant, but names are required.

### The star ``*`` and double star ``**`` operators

Suppose the function were to be invoked with the numbers from a
list: ``numbers = [7, 8]``, then we might invoke the ``multiplication``
function as follows:

```python
result = multiplication(numbers[0], numbers[1])  # result is 56
```

Imagine the function took more than two arguments. The above syntax would
still work, but would be cumbersome. Enter the star ``*`` operator:

```python
result = multiplication(*numbers)  # result is 56
```

Wherever multiple positional arguments are expected, and we have a list
or a tuple, the star operator unpacks it. This syntax will seem confusing,
but it is very powerful and is used extensively in Python. It is also
orders of magnitude more readable than the equivalent in C++ or Java.

#### RANT

This rant is left as an exercise to the reader

#### END OF RANT

Besides function calls, the star operator conveniently concatenates lists
and tuples. Suppose we have two lists: ``a = [1, 2]`` and ``b = [3, 4]``
we may concatenate them in several ways:

```python
a = [1, 2]
b = [3, 4]
ab = [a[0], a[1], b[0], b[1]]  # Method 1: ab is [1, 2, 3, 4]
ab = a + b  # Method 2: ab is [1, 2, 3, 4]
ab = [*a, *b]  # Method 3: ab is [1, 2, 3, 4]
a.extend(b)  # Method 4 modifies list 'a' in place. 
a = [1, 2, 3, 4]  # a is extended by b

```

Obviously, don't use the first method. The one relevant for the present
discussion is the third, but the second and fourth have merit as well,
but will not be used here. Finally, list comprehension is quite powerful
as well but is the subject for a different discussion.

### The double star ``**`` operator

The single star is to lists and tuples as the double star is to
dictionaries. Suppose we have a dictionary: ``data = {'a': 1, 'b': 2}``
then we may invoke the ``multiplication`` function as follows:

```python   
data = {'a': 1, 'b': 2}
result = multiplication(**data)  # result is 2
```

Like the star operator, the double star operator can be used to
concatenate two dictionaries. Suppose we have two dictionaries:
``A = {'a': 1, 'b': 2}`` and ``B = {'c': 3, 'd': 4}``. These may be
combined in several ways:

```python
A = {'a': 1, 'b': 2}
B = {'c': 3, 'd': 4}
#  Method 1
AB = {**A, **B}  # AB is {'a': 1, 'b': 2, 'c': 3, 'd': 4}
#  Method 2
AB = A | B
#  Method 3 updates A in place
A |= B
A = {'a': 1, 'b': 2}  # Resetting A
#  Method 4 updates A in place
A.update(B)
```

As before, the first method is the most relevant for the present
discussion. Unlike the example with lists, there is not really a method
that is bad like the first method with lists.

In conclusion, the single and double star operators provide powerful
unpacking of iterables and mappings respectively. Each have reasonable
alternatives, but it is the opinion of this author that the star
operators are preferred as they are unique to this use. The plus and
pipe operators are used for addition and bitwise OR respectively. When
the user first sees the plus or the pipe, they cannot immediately infer
that the code is unpacking the operands. Not before having identified the
types of the operands. In contrast, the star in front of an object
without space immediately says unpacking.

#### RANT

If you have ever had the misfortune of working with C++ or Java, you
would know that the syntax were disgusting, but you didn't know the words
for it. The functionalities coded by C++ and Java cannot be inferred
easily. It is necessary to see multiple parts of the code to infer what
functionality is intended. For example, suppose we have a C++ class with
a constructor.

```C++
class SomeClass {
private:
  int _a;
  int _b;
public:
  int a;
  SomeClass(int a, int b) {
      // Constructor code
  }
  int b {
    return _b;
  }
};
```

Find the constructor above. It does not have a name that means "Hello
there, I am a constructor". Instead, it is named the same as the class
itself. So to find the constructor, you need to identify the class name
first then go through the class to find name again. The decision for this
naming makes sense in that it creates something with the name called. But
it significantly reduces readability. The second attack on human dignity
is the syntax for the function definition. Where the class defines the
public variable 'a', the syntax used is not bad. But because the syntax
is identical for the functions, it increases the amount of code required
to infer that a function is being created.

The two examples of nauseating syntax above do not serve any performance
related purpose. Software engineering and development requires the full
cognitive capability of the human brain. Deliberately obscuring code,
reduces the cognitive capacity left over for actual problem-solving. This
syntax is kept in place for no other purpose than gate-keeping.

#### END OF RANT

### The famous function signature: ``def someFunc(*args, **kwargs)``

Anyone having browsed through Python documentation or code may have
marvelled at the function signature: ``def someFunc(*args, **kwargs)``.
The signature means that the function accepts any number of positional
arguments as well as any number of keyword arguments. This allows one
function to accept multiple different argument signatures. While this may
be convenient, the ubiquitous use of this pattern is likely motivated by
the absense of function overloading in native Python. (Foreshadowing...)

### The ``lambda`` function

Before getting back to class instantiation, we will round off this
discussion of functions with the ``lambda`` function. The ``lambda``
function is basically the anonymous function. The syntax of it is
``lambda arguments: expression``. Whatever the expression on the right
hand side of the colon evaluates to is returned by the function. The
``lambda`` function allows inline function definition which is much more
condensed that the regular function definition as defined above. This
allows it to solve certain problems in one line, for example:

```python
fb = lambda n: ('' if n % 3 else 'Fizz') + ('' if n % 5 else 'Buzz') or n
```

Besides flexing, the ``lambda`` function is useful when working with
certain fields of mathematics, requiring implementation of many functions
that fit on one line. Below is an example of a series of functions
implementing Taylor series expansions. This takes advantage of the fact
that many such functions may be distinguished only by a factor mapped
from the term in the series.

```python
factorial = lambda n: factorial(n - 1) * n if n else 1
recursiveSum = lambda F, n: F(n) + (recursiveSum(F, n - 1) if n else 0)
taylorTerm = lambda x, t: (lambda n: t(n) * x ** n / factorial(n))
expTerm = lambda n: 1
sinTerm = lambda n: (-1 if ((n - 1) % 4) else 1) if n % 2 else 0
cosTerm = lambda n: sinTerm(n + 1)
sinhTerm = lambda n: 1 if n % 2 else 0
coshTerm = lambda n: sinhTerm(n + 1)
exp = lambda x, n: recursiveSum(taylorTerm(x, expTerm), n)
sin = lambda x, n: recursiveSum(taylorTerm(x, sinTerm), n)
cos = lambda x, n: recursiveSum(taylorTerm(x, cosTerm), n)
sinh = lambda x, n: recursiveSum(taylorTerm(x, sinhTerm), n)
cosh = lambda x, n: recursiveSum(taylorTerm(x, coshTerm), n)
```

The above collection of functions implement recursive lambda functions to
calculate function values of common mathematical functions including:

- ``exp``: The exponential function.
- ``sin``: The sine function.
- ``cos``: The cosine function.
- ``sinh``: The hyperbolic sine function.
- ``cosh``: The hyperbolic cosine function.

The lambda functions implement Taylor-Maclaurin series expansions at a
given number of terms and then begin by calculating the last term
adding the previous term to it recursively, until the 0th term is reached.
This implementation demonstrates the power of the recursive lambda
function and is not at all flexing.

### Instantiation of classes

Since this discussion includes class instantiations, the previous section
discussing functions will be quite relevant. We left the discussion of
builtin Python classes having listed common ones. Generally speaking,
Python classes have a general syntax for instantiation except for those
listed. Below is the instantiation of the builtin classes.

- **object**: ``obj = object()`` - This creates an object. Not
  particularly useful but does show the general syntax.
- **int**: ``number = 69`` - This creates an integer.
- **float**: ``number = 420.0`` - This creates a float.
- **str**: ``message = 'Hello World!'`` - This creates a string.
- **list**: ``data = [1, 2, 3]`` - This creates a list.
- **tuple**: ``data = (1, 2, 3)`` - This creates a tuple.
- **?**: ``what = (1337)`` - What does this create? Well, you might
  imagine that this creates a tuple, but it does not. The interpreter
  first removes the redundant parentheses and then the evaluation makes
  it an integer. To create a single element tuple, you must add the
  trailing comma: ``what = (1337,)``. This applies to one element tuples,
  as the comma separating the elements of a multi-element tuple
  sufficiently informs the interpreter that this is a tuple. The empty
  tuple requires no commas: ``empty = ()``.
- **set**: ``data = {1, 2, 3}`` - This creates a set.
- **dict**: ``data = {'key': 'value'}`` - This creates a dictionary. If
  the keys are strings, the general syntax may be of greater convenience:
  ``data = dict(key='value')``. Not requiring quotes around the keys.
  Although this syntax does not support non-string keys.
- **?**: ``data = {}`` - What does this create? Does it create an empty
  set or an empty dictionary. This author is not actually aware, and
  recommends instead ``set()`` or ``dict()`` respectively when creating
  empty sets or dictionaries.

Except for ``list`` and ``tuple``, the general class instantiation syntax
may be applied as seen below:

- **int**: ``number = int(69)``
- **float**: ``number = float(420.0)``
- **str**: ``message = str('Hello World!')``
- **dict**: ``data = dict(key='value')`` - This syntax is quite
  reasonable, but is limited to keys of string type.

Now let's have a look at what happens if we try to instantiate ``tuple``,
``list``, ``set`` or ``frozenset`` using the general syntax:

- **list**: ``data = list(1, 2, 3)`` - NOPE! This does not create the
  list predicted by common sense: ``data = [1, 2, 3]``. Instead, we are
  met by the following error message: "TypeError: list expected at most 1
  argument, got 3". Instead, we must use the following syntax:
  ``data = list((1, 2, 3))`` or ``data = list([1, 2, 3])``. Now the
  attentive reader may begin to object, as one of the above require a list
  to already be defined and the other requires the tuple to be defined.
  Let's see how one might instantiate a tuple directly:
- **tuple**: ``data = tuple(1, 2, 3)`` - NOPE! This does not work either!
  We receive the exact same error message as before. Instead, we must use
  one of the following: ``data = tuple((1, 2, 3))``
  or ``data = tuple([1, 2, 3])``. The logically sensitive readers now see
  a significant inconsistency in the syntax: One cannot in fact
  instantiate a tuple nor a list directly without having a list or tuple
  already created. This author suggests that the following syntax should
  be accepted: ``data = smartTuple(1, 2, 3)`` and even:
  ``data = smartList(1, 2, 3)``. Perhaps this author is just being
  pedantic. The existing syntax is not a problem, and it's not like the
  suggested instantiation syntax is used anywhere else in Python.
- **set**: ``data = set(1, 2, 3,)`` This is correct syntax. So this works,
  but the suggested ``smartList`` and ``smartTuple`` functions does not, OK
  sure, makes sense...
- **frozenset**: ``data = frozenset([69, 420])`` - This is correct syntax.

Let us have another look at the instantiations of ``dict`` and of ``set``,
but not ``list`` and ``tuple``.

```python
def newDict(**kwargs) -> dict:
  """This function creates a new dictionary having the key value pairs 
  given by the keyword arguments. """
  return dict(**kwargs)  # Unpacking the keyword arguments creates the dict.


def newSet(*args) -> set:
  """This function creates a new set having the elements given by the 
  positional arguments. """
  return set(args)  # Unpacking the positional arguments creates the set.


def newList(*args) -> list:
  """As long as we don't use the word 'list', we can actually instantiate 
  a list in a reasonable way."""
  return [*args, ]  # Unpacking the positional arguments creates the list.


def newTuple(*args) -> tuple:
  """Same as for list, but remember the hanging comma!"""
  return (*args,)  # Unpacking the positional arguments creates the tuple.
```

### Custom classes

In the previous section, we examined functions and builtin classes. To
reiterate, in the context of this discussion a class is an extension of
``object`` allowing objects to belong to different classes implementing
different extensions of ``object``. This raises a question: What
extension of ``object`` contains ``object`` extensions? If ``7`` is an
instance of the ``int`` extension of ``object``, of what extension is
``int`` and instance. The answer is the ``type``. This extension of
``object`` provides all extensions of ``object``. This implies the
surprising that ``type`` is an instance of itself.

The introduction of the ``type`` class allows us to make the following
insightful statement:

``7`` is to ``int`` as ``int`` is to ``type``. This means that ``type``
is responsible for instantiating new classes. A few readers may now begin
to see where this is going, but before we get there, let us examine how
``type`` creates a new class. In the example below, we create a simple
class and we will examine the exact steps that the ``type`` class takes
during class creation.

```python
from worktoy.desc import AttriBox


class PlanePoint:
  """Class representing a point in the plane """

  x = AttriBox[float]()
  y = AttriBox[float]()

  def __init__(self, *args) -> None:
    """Constructor for the PlanePoint class. """
    floatArgs = [float(arg) for arg in args if isinstance(arg, (int, float))]
    self.x, self.y = [*floatArgs, 0.0, 0.0][:2]

  def __abs__(self, ) -> float:
    """Returns the distance from the origin. """
    return (self.x ** 2 + self.y ** 2) ** 0.5


if __name__ == '__main__':
  P = PlanePoint(69, 420)
```

When the Python interpreter encounters the line beginning with the
reserved keyword ``class``, it creates a new class object, it begins a
new lexical scope and the contents parentheses after the name determine
what happens next. If no such parentheses are present, the default
behaviour is to create a new instance of ``type``, meaning an extension
of ``object``. This starts the following process:

- **namespace**: ``type`` creates a namespace object that the interpreter
  will use to build the new class. This object is simply an empty
  instance of ``dict``.
- **Class Body Execution**: The interpreter goes through the class body
  line by line from top to bottom. When encountering an assignment, it
  updates the namespace accordingly.
- **Class Object Creation**: The interpreter passes the namespace object
  back to ``type`` that creates the new class object. This happens when
  the ``__new__`` method of ``type`` returns.
- **Descriptor Class Notification**: All ``__set_name__`` methods on
  objects owned by the class are notified, receiving the class object as
  the first argument and the name by which the object is assigned to the
  owning class. In the above example, the ``AttriBox`` objects are
  notified: ``PlanePoint.x.__set_name__(PlanePoint, 'x')`` and
  ``PlanePoint.y.__set_name__(PlanePoint, 'y')``.
- **``type.__init__``:** This is the final step before the ``type`` is
  complete and the class object is returned. Please note that the
  interpreter uses highly optimized C code during this whole procedure,
  and the ``type.__init__`` has no C code implementation making it a noop.
- **Class Instantiation**: Once the class object is created, instances of
  the class may now be created. This begins with a call the ``__call__``
  method on the class object. This method is defined by ``type``. If the
  class itself defines ``__call__``, that method is invoked only when an
  instance of the class is called.
- **``type.__call__(cls, *args, **kwargs)``**: This call on the ``type``
  object creates the new instance of the class.
- **``cls.__new__(cls, *args, **kwargs)``**: This method is responsible
  for creating the new instance of the class. Please note that it makes
  use of the ``__new__`` method defined on the class object. This means
  that new classes are able to customize how new instances are created,
  however implementing the ``__init__`` method defined below is more
  common and quite sufficient for most purposes.
- **``cls.__init__(self, *args, **kwargs)``**: When the new instance is
  created, it is passed to the ``__init__`` method on the class. When
  coding custom classes implementing the ``__init__`` method is the most
  convenient way to define how new instances are initialized.

### What is a metaclass?

In the previous section, we examined how ``type`` creates a new class.
What exactly is ``type`` though? ``type`` is an ``object``, but is also
an extension of ``object`` whose instances themselves are extensions of
``object``. But what if we extended ``type``? We can do that because
``type`` itself extends ``object``. This is what a metaclass is. An
extension of the ``type`` extension of ``object``.

Each of the steps in the class creation process described above may be
customized by extending the ``type`` class. Below is a list of the
methods defined on ``type`` that a custom class may override:

- **``__prepare__``**: In the previous
  section when the namespace object was created, this is done by the
  ``__prepare__`` method on the metaclass. The ``type`` implementation of
  ``__prepare__`` returns an empty dictionary. A metaclass can change
  this by prepopulating the items in this dictionary or even return a
  custom namespace object.
- **``__new__``**: This method is responsible for creating the object
  that will be created at the name after the class definition. This is
  where a new class is conventionally created, but this is by no means a
  requirement for a custom metaclass. It is possible to implement a
  metaclass that creates some other object than a new class.
- **``__init__``**: After the metaclass has created the new class object,
  or whatever object is created, it is passed to the ``__init__`` method.
  Please note that this method is called after the ``__set_name__`` has
  been applied to the objects implementing the descriptor protocol. When
  this method returns the new class object is created.

After the metaclass has created the new class and has returned the
``__init__``, the metaclass is still called by the class object under
certain circumstances. Below is a list of methods that on the metaclass
that may be called during class lifetime:

- **``__call__``**: When an instance of the class is called, the
  ``__call__`` method on the metaclass is invoked. By default, the
  ``__new__`` on the created class object is called, and the object
  returned is passed to the ``__init__`` method on the class object. The
  metaclass may override this behaviour.
- **``__instance_check__``**: When the ``isinstance`` function is called,
  the metaclass is called with create class and the instance. Thus, the
  metaclass may specify how classes derived from it determine if an
  instance is an instance of it. For example, a custom metaclass creating
  Numerical classes might recognize instances of ``float`` or ``int`` as
  their own.
- **``__subclass_check__``**: This is the method called when
  ``issubclass`` is called on a class object derived from the metaclass.
  It allows the metaclass to customize what classes it regards as
  subclasses. Similar to the ``__instance_check__``.
- **``__str__``: When printing a class object, the resulting text is
  frequently more confusing than helpful. I defined a class named
  ``TestClass`` in the main script and printed it. The output was:
  ``<class '__main__.TestClass'>``. But suppose we used a custom
  metaclass ``MetaType`` and derived from it a class called ``TestClass``,
  then the default output would be: ``<class '[MODULE].TestClass'>``, but
  it will not make reference to the metaclass. Instead, let us have the
  metaclass improve this output: ``[MODULE].TestClass(MetaType)``.
- **``__iter__`` and ``__next__``**: Conventionally, iterating over an
  object happens on the instance level, and only by implementing the
  iteration protocol on the metaclass level can the class object itself
  become iterable.
- **``__getitem__``**: This method allows a metaclass to define handling
  of ``cls[key]``. Please note that as of Python version 3.9, Python
  classes may implement a method called ``__class_getitem__``, which is
  intended for the same use. In case both the metaclass and the class
  itself implement these classes respectively, the metaclass
  implementation is used and the class version is ignored.
- **``__setitem__``**: This method allows a metaclass to define handling
  of ``cls[key] = value``.

Above is a non-exhaustive list of ``type`` methods that a custom metaclass
may override. Before proceeding, we must discuss the role of the
namespace object. A significant aspect of the custom metaclass is the
ability to provide a custom namespace object.

### Custom Namespace

Going back to the class creation procedure, the interpreter requests a
namespace object from the metaclass. A custom metaclass may reimplement
the ``__prepare__`` method responsible for creating the custom namespace
and have it return an instance of a custom namespace class. Doing so
places a few subtle requirements on this class.

### Preservation of ``KeyError``

When a dictionary is accessed with a key that does not exist, a
``KeyError`` is raised. The interpreter relies on this behaviour to
handle lines in the class body that are not directly assignments
correctly. This is a particularly important requirement because failing
to raise the expected ``KeyError`` will affect only classes that happen
to include a non-assignment line. Below is a list of known situations
that causes the issue:

- **Decorators**: Unless the decorator is a function defined earlier in
  the class body as an instance method able to receive a callable at the
  ``self`` argument, the decorator will cause the issue described. Please
  note that a static method would be able to receive a callable at the
  first position, but the static method decorator itself would cause the
  issue even sooner.
- **Function calls**: If a function not defined previously in the class
  body is called during the class body without being assigned to a name,
  the error will occur.

The issue raises an error message that will not bring attention to the
namespace object. Further, classes will frequently work fine, if they
happen to not include any of the above non-assignments. In summary:
failing to raise the expected error must be avoided at all costs, as it
will cause undefined behaviour without any indication as to the to cause.

### Subclass of ``dict``

After the class body is executed the namespace object is passed to the
``__new__`` method on the metaclass. If the metaclass is intended to
create a new class object, the metaclass must eventually call the
``__new__`` method on the parent ``type`` class. The ``type.__new__``
method must receive a namespace object that is a subclass of ``dict``. It
is only at this stage the requirement is enforced. Thus, it is possible
to use a custom namespace object that is not a subclass of ``dict``, but
then it is necessary to implement functionality in the ``__new__`` method
on the metaclass such that a ``dict`` is passed to the ``type.__new__``
call.

### Required functionalities

Please note that this section pertains only to functionalities whose
absense will cause the interpreter to raise an exception. The
functionalities described here cannot be said to be sufficient for any
degree of functionality. A custom namespace class must additionally
implement whatever functionality is required for its intended purpose.

- **``__getitem__``**: This method must implement this method such that
  if a normal dictionary would raise an error on receiving a key, then
  that error must still be raised. Please note, that the interpreter
  handles this exception silently. Other than this situation, the
  ``__getitem__`` method are otherwise free to do anything it wants.
- **``__setitem__``**: The namespace object must return a callable object
  at name ``__setitem__``, that accepts three positional arguments: the
  namespace instance at the ``self`` argument, as well as the ``key`` and
  the ``value``. As long as a callable is at the name, and it does not
  raise an error upon receiving three arguments, the namespace object can
  do whatever it wants. It does not even have to remember anything.

### Potential functionalities

This section describes functionalities that is certain to preserve all
information received in the class body. This is an enhancement compared
to the default namespace object. It permits the ``__new__`` in the
metaclass access to all information encountered in the class body. As
long as this is satisfied, there is little additional functionality the
namespace object may provide to the ``__new__`` method. Nevertheless,
readers are encouraged to experiment with custom namespace classes beyond
this.

### Custom Metaclass Requirements

This section illustrates the immense flexibility of the custom metaclass,
by just how little is actually required for the interpreter to go through
the class creation process without raising an exception. This author has
found only two requirements for the custom metaclass:

- **Callable**: The object used as ``metaclass`` must be callable.
- **Accept three positional arguments**: As well as being callable, three
  positional arguments are passed to it. As long as doing so does not
  raise an exception, the metaclass is free to do whatever it wants.

And that is all that is required. The metaclass is typically a subclass
of ``type``, but is not required. Conventionally, some kind of class
object is created, but is not required. The metaclass is not even
required to return anything in which case, the ``None`` object will
appear at the given class name. Thus, the custom metaclass can be used to
create new classes, but in reality it can be used to create anything. It
could be used to replace functions defined with the ``def`` keyword.
Readers are encouraged to dream up new uses for the custom metaclass.

The remainder of this documentation focus on the ``worktoy.meta`` module
and the classes and functions defined therein. These focus on the more
conventional applications of the custom metaclass, that is, creation of
classes having functionalities beyond the default Python classes.

## The ``worktoy.meta`` module

### Nomenclature

Before proceeding, let us define terms:

- **``cls``** - A newly created class object
- **``self``** - A newly created object that is an instance of the newly
  created class.
- **``mcls``** - The metaclass creating the new class.
- **``namespace``** - This is where the class body is stored during class
  creation.

### ``AbstractMetaclass`` and ``AbstractNamespace``

These abstract baseclass illustrates an elegant metaclass pattern. The
namespace class records every assignment in the class body, even if a
name is assigned a value for the second time. The namespace class also
implements a method called ``compile`` which returns a regular dictionary
with the items the metaclass should pass on to the ``type.__new__``
method. Without further subclassing, instances of this namespace class,
will provide behaviour indistinguishable from the default behaviour.

The abstract metaclass implements the ``__prepare__`` class method which
returns creates an instance of the abstract namespace class defined above.
In the ``__new__`` method the metaclass retrieves the final namespace
dictionary by calling the ``compile`` method on the namespace object.
With this it calls the ``type.__new__`` method with the thus obtained
namespace object. The class object returned from the call to
``type.__new__`` is returned by the abstract metaclass.

This pair of abstract classes provides a solid pair of baseclasses. The
pattern is convenient, the metaclass instantiates the namespace object.
Without loss of information, the namespace object is returned to the
metaclass. Here the metaclass obtains the final namespace dictionary from
the ``compile`` method on the namespace object.

### Singleton

The singleton term is well understood as a class having only one
instance. Typically, such a class is callable, but instead of creating a
new instance, the same singleton instance is returned. However, when the
singleton class is called the singleton instance will have its
``__init__`` repeated with whatever arguments are passed. This allows the
singleton instance to update itself. If this is undesirable, the
singleton class should itself prevent its ``__init__`` method from
updating values intended to immutable.

``worktoy.meta`` provides a metaclass called ``SingletonMeta`` and a
derived class called ``Singleton``. Custom singleton classes may either
set ``SingletonMeta`` as the metaclass or subclass ``Singleton``. The
metaclass subclasses the ``BaseMetaclass`` discussed below.

### Zeroton

The ``Zeroton`` class is a novelty. What specified the singleton class is
the fact that it has only one instance. The ``Zeroton`` class in contrast
has not even one instance. Such a class is essentially a token. The
purpose of it is to retain itself across multiple modules. Presently, it
finds use in the ``AttriBox`` implementation of the ``worktoy.desc``
module. For more information, readers are referred to the section on
"Advanced Instantiation" in the ``worktoy.desc`` documentation.

### Function overloading in Python

When creating a new class using the default ``type``, only the most
recent assigned value at each name is retained. As such, implementing
overloading of methods in the class body requires a custom metaclass
providing a custom namespace. The ``worktoy.meta`` module provides the
``BaseObject`` class derived from the ``BaseMetaclass``, which implements
function overloading of the methods in the class body. Before
demonstrating the syntactic use of the ``BaseObject`` class, an
explanation of the implementation is provided. To skip directly to the
usage, see section **worktoy.meta.overload - Usage**.

### Background

The main issue with function overloading is that multiple callables are
now present on the same name. Thus, a new step is required to determine
which available implementation to invoke, given the arguments received.
The procedure chosen here is to contain the pairs of type signatures and
callables in a dictionary. When the overloaded function is called, the
type signature of the arguments is determined and used to look up the
appropriate callable in the dictionary, before invoking it with the
argument values. This step does add some overhead, but in testing has not
exceeded 20 %.

### Type Decoration

When a class body is to define multiple callables at the same name, but
with different functions, the ``worktoy.meta.overload`` decorator factory
is used. When calling it with types as positional arguments, it returns a
decorator. When this decorator is called it sets the type signature of
the decorated function at the attribute named
``__overloaded_signature__`` to the type signature given the factory.

### Function Dispatcher

The ``BaseNamespace`` uses a dedicated class called ``Dispatcher`` to
encapsulates the type signature to callable mapping. The ``Dispatcher``
class implements both the descriptor protocol and the ``__call__`` method
allowing it to emulate the behaviour of bounded and unbounded methods as
appropriate. When called it determines the type signature of the
arguments received, resolve the matching callable, invokes it with the
arguments received and returns the return value.

### Namespace Compilation

The ``BaseMetaclass`` implements the pattern described previously, where
the namespace class provides functionality for creating a dictionary to
be used in the ``type.__new__`` method. This ``compile`` method retrieves
the callables encountered during class body execution that were decorated
with by the overload decorator and for each name creates a ``Dispatcher``
instance as described above, which is placed in the final dictionary at
the appropriate name.

### ``worktoy.meta.overload`` - Usage

To make use of the 'overload' functionality in a class definition, import
the ``overload`` decorator factory and the ``BaseObject`` class from the
``worktoy.meta.overload`` module. The ``BaseObject`` class already uses the
``BaseMetaclass`` as the metaclass, provides replacements for
``__init__`` and ``__init_subclass__`` which do not raise exceptions
every time they see an argument, in contrast to ``object.__init__`` and
``object.__init_subclass__``:

```python
from __future__ import annotations

from worktoy.meta import BaseMetaclass


class BaseObject(metaclass=BaseMetaclass):
  """BaseObject provides argument-tolerant implementations of __init__ and
  __init_subclass__ preventing the errors explained in the documentation."""

  def __init__(self, *args, **kwargs) -> None:
    """Why are we still here?"""

  def __init_subclass__(cls, *args, **kwargs) -> None:
    """Just to suffer?"""
```

Implement the custom class as a subclass of ``BaseObject``. In the
function body, provide implementations of the overloaded functions by
reusing the name of the function. Decorate each such function with the
``overload`` decorator factory and provide the type signatures of the
as positional arguments. For example:

```python
from worktoy.meta import overload, BaseObject
from worktoy.desc import AttriBox
from typing import Self


class ComplexNumber(BaseObject):
  """Class representing complex numbers. """

  __fallback_value__ = 0j

  realPart = AttriBox[float]()
  imagPart = AttriBox[float]()

  @overload(int, int)
  def __init__(self, a: int, b: int) -> None:
    self.__init__(float(a), float(b))

  @overload(float, float)
  def __init__(self, a: float, b: float) -> None:
    self.realPart, self.imagPart = a, b

  @overload(complex)
  def __init__(self, z: complex) -> None:
    self.realPart, self.imagPart = z.real, z.imag

  @overload()
  def __init__(self, ) -> None:
    self.__init__(self.__fallback_value__)

  def __abs__(self) -> float:
    return (self.realPart ** 2 + self.imagPart ** 2) ** 0.5

  def __sub__(self, other: Self) -> Self:
    return ComplexNumber(self.realPart - other.realPart,
                         self.imagPart - other.imagPart)

  def __add__(self, other: Self) -> Self:
    return ComplexNumber(self.realPart + other.realPart,
                         self.imagPart + other.imagPart)

  def __eq__(self, other: Self) -> bool:
    return False if abs(self - other) > 1e-08 else True


if __name__ == '__main__':
  z1 = ComplexNumber(69, 420)
  z2 = ComplexNumber(69.0, 420.0)
  z3 = ComplexNumber(69 + 420j)
  print(z1 == z2 == z3)




```
