I can't believe nobody's said this before, but it seems to me Python just wants you to **write your own simple, mutable class instead of using a **`namedtuple`

whenever you need the "`namedtuple`

" to be mutable.

## Quick summary

*Just jump straight down to ***Approach 5** below. It's short and to-the-point, and by far the best of these options.

## Various, detailed approaches:

## Approach 1 (good): simple, callable class with `__call__()`

Here is an example of a simple `Point`

object for `(x, y)`

points:

```
class Point():
def __init__(self, x, y):
self.x = x
self.y = y
def __call__(self):
"""
Make `Point` objects callable. Print their contents when they
are called.
"""
print("Point(x={}, y={})".format(self.x, self.y))
```

Now use it:

```
p1 = Point(1,2)
p1()
p1.x = 7
p1()
p1.y = 8
p1()
```

Here is the output:

```
Point(x=1, y=2)
Point(x=7, y=2)
Point(x=7, y=8)
```

This is pretty similar to a `namedtuple`

, except it is fully mutable, unlike a `namedtuple`

. Also, a `namedtuple`

isn't callable, so to see its contents, just type the object instance name withOUT parenthesis after it (as `p2`

in the example below, *instead of* as `p2()`

). See this example and output here:

```
>>> from collections import namedtuple
>>> Point2 = namedtuple("Point2", ["x", "y"])
>>> p2 = Point2(1, 2)
>>> p2
Point2(x=1, y=2)
>>> p2()
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
TypeError: 'Point2' object is not callable
>>> p2.x = 7
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
AttributeError: can't set attribute
```

## Approach 2 (better): use `__repr__()`

in place of `__call__()`

I just learned you can use `__repr__()`

in place of `__call__()`

, to get more `namedtuple`

-like behavior. Defining the `__repr__()`

method allows you to define "the 'official' string representation of an object" (see the official documentation here). Now, just calling `p1`

is the equivalent of calling the `__repr__()`

method, and you get identical behavior to the `namedtuple`

. Here is the new class:

```
class Point():
def __init__(self, x, y):
self.x = x
self.y = y
def __repr__(self):
"""
Obtain the string representation of `Point`, so that just typing
the instance name of an object of this type will call this method
and obtain this string, just like `namedtuple` already does!
"""
return "Point(x={}, y={})".format(self.x, self.y)
```

Now use it:

```
p1 = Point(1,2)
p1
p1.x = 7
p1
p1.y = 8
p1
```

Here is the output:

```
Point(x=1, y=2)
Point(x=7, y=2)
Point(x=7, y=8)
```

## Approach 3 (better still, but a little awkward to use): make it a callable which returns an `(x, y)`

tuple

The original poster (OP) would also like something like this to work (see his comment below my answer):

```
x, y = Point(x=1, y=2)
```

Well, for simplicity, let's just make this work instead:

```
x, y = Point(x=1, y=2)()
# OR
p1 = Point(x=1, y=2)
x, y = p1()
```

While we are at it, let's also condense this:

```
self.x = x
self.y = y
```

...into this (source where I first saw this):

```
self.x, self.y = x, y
```

Here is the class definition for all of the above:

```
class Point():
def __init__(self, x, y):
self.x, self.y = x, y
def __repr__(self):
"""
Obtain the string representation of `Point`, so that just typing
the instance name of an object of this type will call this method
and obtain this string, just like `namedtuple` already does!
"""
return "Point(x={}, y={})".format(self.x, self.y)
def __call__(self):
"""
Make the object callable. Return a tuple of the x and y components
of the Point.
"""
return self.x, self.y
```

Here are some test calls:

```
p1 = Point(1,2)
p1
p1.x = 7
x, y = p1()
x2, y2 = Point(10, 12)()
x
y
x2
y2
```

I won't show pasting the class definition into the interpreter this time, but here are those calls with their output:

```
>>> p1 = Point(1,2)
>>> p1
Point(x=1, y=2)
>>> p1.x = 7
>>> x, y = p1()
>>> x2, y2 = Point(10, 12)()
>>> x
7
>>> y
2
>>> x2
10
>>> y2
12
```

## Approach 4 (best so far, but a lot more code to write): make the class also an iterator

By making this into an iterator class, we can get this behavior:

```
x, y = Point(x=1, y=2)
# OR
x, y = Point(1, 2)
# OR
p1 = Point(1, 2)
x, y = p1
```

Let's get rid of the `__call__()`

method, but to make this class an iterator we will add the `__iter__()`

and `__next__()`

methods. Read more about these things here:

- https://treyhunner.com/2018/06/how-to-make-an-iterator-in-python/
- How to build a basic iterator?
- https://docs.python.org/3/library/exceptions.html#StopIteration

Here is the solution:

```
class Point():
def __init__(self, x, y):
self.x, self.y = x, y
self._iterator_index = 0
self._num_items = 2 # counting self.x and self.y
def __repr__(self):
"""
Obtain the string representation of `Point`, so that just typing
the instance name of an object of this type will call this method
and obtain this string, just like `namedtuple` already does!
"""
return "Point(x={}, y={})".format(self.x, self.y)
def __iter__(self):
return self
def __next__(self):
self._iterator_index += 1
if self._iterator_index == 1:
return self.x
elif self._iterator_index == 2:
return self.y
else:
raise StopIteration
```

And here are some test calls and their output:

```
>>> x, y = Point(x=1, y=2)
>>> x
1
>>> y
2
>>> x, y = Point(3, 4)
>>> x
3
>>> y
4
>>> p1 = Point(5, 6)
>>> x, y = p1
>>> x
5
>>> y
6
>>> p1
Point(x=5, y=6)
```

## Approach 5 (USE THIS ONE) (*Perfect!--best and cleanest/shortest approach*): make the class an iterable, with the `yield`

generator keyword

Study these references:

- https://treyhunner.com/2018/06/how-to-make-an-iterator-in-python/
- What does the "yield" keyword do?

Here is the solution. It relies on a fancy "iterable-generator" (AKA: just "generator") keyword/Python mechanism, called `yield`

.

Basically, the first time an iterable calls for the next item, it calls the `__iter__()`

method, and stops and returns the contents of the first `yield`

call (`self.x`

in the code below). The next time an iterable calls for the next item, it picks up where it last left off (just after the first `yield`

in this case), and looks for the next `yield`

, stopping and returning the contents of that `yield`

call (`self.y`

in the code below). Each "return" from a `yield`

actually returns a "generator" object, which is an iterable itself, so you can iterate on it. Each new iterable call for the next item continues this process, starting up where it last left off, just after the most-recently-called `yield`

, until no more `yield`

calls exist, at which point the iterations are ended and the iterable has been fully iterated. Therefore, once this iterable has called for two objects, both `yield`

calls have been used up, so the iterator ends. The end result is that calls like this work perfectly, just as they did in Approach 4, but with *far less code to write!*:

```
x, y = Point(x=1, y=2)
# OR
x, y = Point(1, 2)
# OR
p1 = Point(1, 2)
x, y = p1
```

**Here is the solution** (a part of this solution can also be found in the treyhunner.com reference just above). **Notice how short and clean this solution is!**

Just the class definition code; no docstrings, so you can truly see how short and simple this is:

```
class Point():
def __init__(self, x, y):
self.x, self.y = x, y
def __repr__(self):
return "Point(x={}, y={})".format(self.x, self.y)
def __iter__(self):
yield self.x
yield self.y
```

With descriptive docstrings:

```
class Point():
def __init__(self, x, y):
self.x, self.y = x, y
def __repr__(self):
"""
Obtain the string representation of `Point`, so that just typing
the instance name of an object of this type will call this method
and obtain this string, just like `namedtuple` already does!
"""
return "Point(x={}, y={})".format(self.x, self.y)
def __iter__(self):
"""
Make this `Point` class an iterable. When used as an iterable, it will
now return `self.x` and `self.y` as the two elements of a list-like,
iterable object, "generated" by the usages of the `yield` "generator"
keyword.
"""
yield self.x
yield self.y
```

Copy and paste the exact same test code as used in the previous approach (Approach 4) just above, and you will get *the exact same output as above as well!*

## References:

- https://docs.python.org/3/library/collections.html#collections.namedtuple
- Approach 1:
- What is the difference between
`__init__`

and `__call__`

?

- Approach 2:
- https://www.tutorialspoint.com/What-does-the-repr-function-do-in-Python-Object-Oriented-Programming
- Purpose of
`__repr__`

method?
- https://docs.python.org/3/reference/datamodel.html#object.__repr__

- Approach 4:
- *****[EXCELLENT!] https://treyhunner.com/2018/06/how-to-make-an-iterator-in-python/
- How to build a basic iterator?
- https://docs.python.org/3/library/exceptions.html#StopIteration

- Approach 5:
- See links from Approach 4, plus:
- *****[EXCELLENT!] What does the "
`yield`

" keyword do?

- What is the meaning of single and double underscore before an object name?

`namedtuple`

s, it appears you have no need to be able to reference the attributes by index, i.e. so`p[0]`

and`p[1]`

would be alternate ways to reference`x`

and`y`

respectively, correct?5more comments