I would like to understand how the built-in function property works. What confuses me is that property can also be used as a decorator, but it only takes arguments when used as a built-in function and not when used as a decorator.
This example is from the documentation:
class C:
def __init__(self):
self._x = None
def getx(self):
return self._x
def setx(self, value):
self._x = value
def delx(self):
del self._x
x = property(getx, setx, delx, "I'm the 'x' property.")
property's arguments are getx, setx, delx and a doc string.
In the code below property is used as a decorator. The object of it is the x function, but in the code above there is no place for an object function in the arguments.
class C:
def __init__(self):
self._x = None
#property
def x(self):
"""I'm the 'x' property."""
return self._x
#x.setter
def x(self, value):
self._x = value
#x.deleter
def x(self):
del self._x
How are the x.setter and x.deleter decorators created in this case?
The property() function returns a special descriptor object:
>>> property()
<property object at 0x10ff07940>
It is this object that has extra methods:
>>> property().getter
<built-in method getter of property object at 0x10ff07998>
>>> property().setter
<built-in method setter of property object at 0x10ff07940>
>>> property().deleter
<built-in method deleter of property object at 0x10ff07998>
These act as decorators too. They return a new property object:
>>> property().getter(None)
<property object at 0x10ff079f0>
that is a copy of the old object, but with one of the functions replaced.
Remember, that the #decorator syntax is just syntactic sugar; the syntax:
#property
def foo(self): return self._foo
really means the same thing as
def foo(self): return self._foo
foo = property(foo)
so foo the function is replaced by property(foo), which we saw above is a special object. Then when you use #foo.setter(), what you are doing is call that property().setter method I showed you above, which returns a new copy of the property, but this time with the setter function replaced with the decorated method.
The following sequence also creates a full-on property, by using those decorator methods.
First we create some functions and a property object with just a getter:
>>> def getter(self): print('Get!')
...
>>> def setter(self, value): print('Set to {!r}!'.format(value))
...
>>> def deleter(self): print('Delete!')
...
>>> prop = property(getter)
>>> prop.fget is getter
True
>>> prop.fset is None
True
>>> prop.fdel is None
True
Next we use the .setter() method to add a setter:
>>> prop = prop.setter(setter)
>>> prop.fget is getter
True
>>> prop.fset is setter
True
>>> prop.fdel is None
True
Last we add a deleter with the .deleter() method:
>>> prop = prop.deleter(deleter)
>>> prop.fget is getter
True
>>> prop.fset is setter
True
>>> prop.fdel is deleter
True
Last but not least, the property object acts as a descriptor object, so it has .__get__(), .__set__() and .__delete__() methods to hook into instance attribute getting, setting and deleting:
>>> class Foo: pass
...
>>> prop.__get__(Foo(), Foo)
Get!
>>> prop.__set__(Foo(), 'bar')
Set to 'bar'!
>>> prop.__delete__(Foo())
Delete!
The Descriptor Howto includes a pure Python sample implementation of the property() type:
class Property:
"Emulate PyProperty_Type() in Objects/descrobject.c"
def __init__(self, fget=None, fset=None, fdel=None, doc=None):
self.fget = fget
self.fset = fset
self.fdel = fdel
if doc is None and fget is not None:
doc = fget.__doc__
self.__doc__ = doc
def __get__(self, obj, objtype=None):
if obj is None:
return self
if self.fget is None:
raise AttributeError("unreadable attribute")
return self.fget(obj)
def __set__(self, obj, value):
if self.fset is None:
raise AttributeError("can't set attribute")
self.fset(obj, value)
def __delete__(self, obj):
if self.fdel is None:
raise AttributeError("can't delete attribute")
self.fdel(obj)
def getter(self, fget):
return type(self)(fget, self.fset, self.fdel, self.__doc__)
def setter(self, fset):
return type(self)(self.fget, fset, self.fdel, self.__doc__)
def deleter(self, fdel):
return type(self)(self.fget, self.fset, fdel, self.__doc__)
The documentation says it's just a shortcut for creating read-only properties. So
#property
def x(self):
return self._x
is equivalent to
def getx(self):
return self._x
x = property(getx)
Here is a minimal example of how #property can be implemented:
class Thing:
def __init__(self, my_word):
self._word = my_word
#property
def word(self):
return self._word
>>> print( Thing('ok').word )
'ok'
Otherwise word remains a method instead of a property.
class Thing:
def __init__(self, my_word):
self._word = my_word
def word(self):
return self._word
>>> print( Thing('ok').word() )
'ok'
Below is another example on how #property can help when one has to refactor code which is taken from here (I only summarize it below):
Imagine you created a class Money like this:
class Money:
def __init__(self, dollars, cents):
self.dollars = dollars
self.cents = cents
and a user creates a library depending on this class where he/she uses e.g.
money = Money(27, 12)
print("I have {} dollar and {} cents.".format(money.dollars, money.cents))
# prints I have 27 dollar and 12 cents.
Now let's suppose you decide to change your Money class and get rid of the dollars and cents attributes but instead decide to only track the total amount of cents:
class Money:
def __init__(self, dollars, cents):
self.total_cents = dollars * 100 + cents
If the above mentioned user now tries to run his/her library as before
money = Money(27, 12)
print("I have {} dollar and {} cents.".format(money.dollars, money.cents))
it will result in an error
AttributeError: 'Money' object has no attribute 'dollars'
That means that now everyone who relies on your original Money class would have to change all lines of code where dollars and cents are used which can be very painful... So, how could this be avoided? By using #property!
That is how:
class Money:
def __init__(self, dollars, cents):
self.total_cents = dollars * 100 + cents
# Getter and setter for dollars...
#property
def dollars(self):
return self.total_cents // 100
#dollars.setter
def dollars(self, new_dollars):
self.total_cents = 100 * new_dollars + self.cents
# And the getter and setter for cents.
#property
def cents(self):
return self.total_cents % 100
#cents.setter
def cents(self, new_cents):
self.total_cents = 100 * self.dollars + new_cents
when we now call from our library
money = Money(27, 12)
print("I have {} dollar and {} cents.".format(money.dollars, money.cents))
# prints I have 27 dollar and 12 cents.
it will work as expected and we did not have to change a single line of code in our library! In fact, we would not even have to know that the library we depend on changed.
Also the setter works fine:
money.dollars += 2
print("I have {} dollar and {} cents.".format(money.dollars, money.cents))
# prints I have 29 dollar and 12 cents.
money.cents += 10
print("I have {} dollar and {} cents.".format(money.dollars, money.cents))
# prints I have 29 dollar and 22 cents.
You can use #property also in abstract classes; I give a minimal example here.
The first part is simple:
#property
def x(self): ...
is the same as
def x(self): ...
x = property(x)
which, in turn, is the simplified syntax for creating a property with just a getter.
The next step would be to extend this property with a setter and a deleter. And this happens with the appropriate methods:
#x.setter
def x(self, value): ...
returns a new property which inherits everything from the old x plus the given setter.
x.deleter works the same way.
This following:
class C(object):
def __init__(self):
self._x = None
#property
def x(self):
"""I'm the 'x' property."""
return self._x
#x.setter
def x(self, value):
self._x = value
#x.deleter
def x(self):
del self._x
Is the same as:
class C(object):
def __init__(self):
self._x = None
def _x_get(self):
return self._x
def _x_set(self, value):
self._x = value
def _x_del(self):
del self._x
x = property(_x_get, _x_set, _x_del,
"I'm the 'x' property.")
Is the same as:
class C(object):
def __init__(self):
self._x = None
def _x_get(self):
return self._x
def _x_set(self, value):
self._x = value
def _x_del(self):
del self._x
x = property(_x_get, doc="I'm the 'x' property.")
x = x.setter(_x_set)
x = x.deleter(_x_del)
Is the same as:
class C(object):
def __init__(self):
self._x = None
def _x_get(self):
return self._x
x = property(_x_get, doc="I'm the 'x' property.")
def _x_set(self, value):
self._x = value
x = x.setter(_x_set)
def _x_del(self):
del self._x
x = x.deleter(_x_del)
Which is the same as :
class C(object):
def __init__(self):
self._x = None
#property
def x(self):
"""I'm the 'x' property."""
return self._x
#x.setter
def x(self, value):
self._x = value
#x.deleter
def x(self):
del self._x
Let's start with Python decorators.
A Python decorator is a function that helps to add some additional functionalities to an already defined function.
In Python, everything is an object. Functions in Python are first-class objects which means that they can be referenced by a variable, added in the lists, passed as arguments to another function, etc.
Consider the following code snippet.
def decorator_func(fun):
def wrapper_func():
print("Wrapper function started")
fun()
print("Given function decorated")
# Wrapper function add something to the passed function and decorator
# returns the wrapper function
return wrapper_func
def say_bye():
print("bye!!")
say_bye = decorator_func(say_bye)
say_bye()
# Output:
# Wrapper function started
# bye!!
# Given function decorated
Here, we can say that the decorator function modified our say_bye function and added some extra lines of code to it.
Python syntax for decorator
def decorator_func(fun):
def wrapper_func():
print("Wrapper function started")
fun()
print("Given function decorated")
# Wrapper function add something to the passed function and decorator
# returns the wrapper function
return wrapper_func
#decorator_func
def say_bye():
print("bye!!")
say_bye()
Let's go through everything with a case scenario. But before that, let's talk about some OOP principles.
Getters and setters are used in many object-oriented programming languages to ensure the principle of data encapsulation(which is seen as the bundling of data with the methods that operate on these data.)
These methods are, of course, the getter for retrieving the data and the setter for changing the data.
According to this principle, the attributes of a class are made private to hide and protect them from other code.
Yup, #property is basically a pythonic way to use getters and setters.
Python has a great concept called property which makes the life of an object-oriented programmer much simpler.
Let us assume that you decide to make a class that could store the temperature in degrees Celsius.
class Celsius:
def __init__(self, temperature = 0):
self.set_temperature(temperature)
def to_fahrenheit(self):
return (self.get_temperature() * 1.8) + 32
def get_temperature(self):
return self._temperature
def set_temperature(self, value):
if value < -273:
raise ValueError("Temperature below -273 is not possible")
self._temperature = value
Refactored Code, Here is how we could have achieved it with 'property.'
In Python, property() is a built-in function that creates and returns a property object.
A property object has three methods, getter(), setter(), and delete().
class Celsius:
def __init__(self, temperature = 0):
self.temperature = temperature
def to_fahrenheit(self):
return (self.temperature * 1.8) + 32
def get_temperature(self):
print("Getting value")
return self.temperature
def set_temperature(self, value):
if value < -273:
raise ValueError("Temperature below -273 is not possible")
print("Setting value")
self.temperature = value
temperature = property(get_temperature,set_temperature)
Here,
temperature = property(get_temperature,set_temperature)
could have been broken down as,
# make empty property
temperature = property()
# assign fget
temperature = temperature.getter(get_temperature)
# assign fset
temperature = temperature.setter(set_temperature)
Point To Note:
get_temperature remains a property instead of a method.
Now you can access the value of temperature by writing.
C = Celsius()
C.temperature
# instead of writing C.get_temperature()
We can go on further and not define names get_temperature and set_temperature as they are unnecessary and pollute the class namespace.
The pythonic way to deal with the above problem is to use #property.
class Celsius:
def __init__(self, temperature = 0):
self.temperature = temperature
def to_fahrenheit(self):
return (self.temperature * 1.8) + 32
#property
def temperature(self):
print("Getting value")
return self.temperature
#temperature.setter
def temperature(self, value):
if value < -273:
raise ValueError("Temperature below -273 is not possible")
print("Setting value")
self.temperature = value
Points to Note -
A method that is used for getting a value is decorated with "#property".
The method which has to function as the setter is decorated with "#temperature.setter", If the function had been called "x", we would have to decorate it with "#x.setter".
We wrote "two" methods with the same name and a different number of parameters, "def temperature(self)" and "def temperature(self,x)".
As you can see, the code is definitely less elegant.
Now, let's talk about one real-life practical scenario.
Let's say you have designed a class as follows:
class OurClass:
def __init__(self, a):
self.x = a
y = OurClass(10)
print(y.x)
Now, let's further assume that our class got popular among clients and they started using it in their programs, They did all kinds of assignments to the object.
And one fateful day, a trusted client came to us and suggested that "x" has to be a value between 0 and 1000; this is really a horrible scenario!
Due to properties, it's easy: We create a property version of "x".
class OurClass:
def __init__(self,x):
self.x = x
#property
def x(self):
return self.__x
#x.setter
def x(self, x):
if x < 0:
self.__x = 0
elif x > 1000:
self.__x = 1000
else:
self.__x = x
This is great, isn't it: You can start with the simplest implementation imaginable, and you are free to later migrate to a property version without having to change the interface! So properties are not just a replacement for getters and setters!
You can check this Implementation here
I read all the posts here and realized that we may need a real life example. Why, actually, we have #property?
So, consider a Flask app where you use authentication system.
You declare a model User in models.py:
class User(UserMixin, db.Model):
__tablename__ = 'users'
id = db.Column(db.Integer, primary_key=True)
email = db.Column(db.String(64), unique=True, index=True)
username = db.Column(db.String(64), unique=True, index=True)
password_hash = db.Column(db.String(128))
...
#property
def password(self):
raise AttributeError('password is not a readable attribute')
#password.setter
def password(self, password):
self.password_hash = generate_password_hash(password)
def verify_password(self, password):
return check_password_hash(self.password_hash, password)
In this code we've "hidden" attribute password by using #property which triggers AttributeError assertion when you try to access it directly, while we used #property.setter to set the actual instance variable password_hash.
Now in auth/views.py we can instantiate a User with:
...
#auth.route('/register', methods=['GET', 'POST'])
def register():
form = RegisterForm()
if form.validate_on_submit():
user = User(email=form.email.data,
username=form.username.data,
password=form.password.data)
db.session.add(user)
db.session.commit()
...
Notice attribute password that comes from a registration form when a user fills the form. Password confirmation happens on the front end with EqualTo('password', message='Passwords must match') (in case if you are wondering, but it's a different topic related Flask forms).
I hope this example will be useful
This point is been cleared by many people up there but here is a direct point which I was searching.
This is what I feel is important to start with the #property decorator.
eg:-
class UtilityMixin():
#property
def get_config(self):
return "This is property"
The calling of function "get_config()" will work like this.
util = UtilityMixin()
print(util.get_config)
If you notice I have not used "()" brackets for calling the function. This is the basic thing which I was searching for the #property decorator. So that you can use your function just like a variable.
The best explanation can be found here:
Python #Property Explained – How to Use and When? (Full Examples)
by Selva Prabhakaran | Posted on November 5, 2018
It helped me understand WHY not only HOW.
https://www.machinelearningplus.com/python/python-property/
property is a class behind #property decorator.
You can always check this:
print(property) #<class 'property'>
I rewrote the example from help(property) to show that the #property syntax
class C:
def __init__(self):
self._x=None
#property
def x(self):
return self._x
#x.setter
def x(self, value):
self._x = value
#x.deleter
def x(self):
del self._x
c = C()
c.x="a"
print(c.x)
is functionally identical to property() syntax:
class C:
def __init__(self):
self._x=None
def g(self):
return self._x
def s(self, v):
self._x = v
def d(self):
del self._x
prop = property(g,s,d)
c = C()
c.x="a"
print(c.x)
There is no difference how we use the property as you can see.
To answer the question #property decorator is implemented via property class.
So, the question is to explain the property class a bit.
This line:
prop = property(g,s,d)
Was the initialization. We can rewrite it like this:
prop = property(fget=g,fset=s,fdel=d)
The meaning of fget, fset and fdel:
| fget
| function to be used for getting an attribute value
| fset
| function to be used for setting an attribute value
| fdel
| function to be used for del'ing an attribute
| doc
| docstring
The next image shows the triplets we have, from the class property:
__get__, __set__, and __delete__ are there to be overridden. This is the implementation of the descriptor pattern in Python.
In general, a descriptor is an object attribute with “binding behavior”, one whose attribute access has been overridden by methods in the descriptor protocol.
We can also use property setter, getter and deleter methods to bind the function to property. Check the next example. The method s2 of the class C will set the property doubled.
class C:
def __init__(self):
self._x=None
def g(self):
return self._x
def s(self, x):
self._x = x
def d(self):
del self._x
def s2(self,x):
self._x=x+x
x=property(g)
x=x.setter(s)
x=x.deleter(d)
c = C()
c.x="a"
print(c.x) # outputs "a"
C.x=property(C.g, C.s2)
C.x=C.x.deleter(C.d)
c2 = C()
c2.x="a"
print(c2.x) # outputs "aa"
A decorator is a function that takes a function as an argument and returns a closure. The closure is a set of inner functions and free variables. The inner function is closing over the free variable and that is why it is called 'closure'. A free variable is a variable that is outside the inner function and passed into the inner via docorator.
As the name says, decorator is decorating the received function.
function decorator(undecorated_func):
print("calling decorator func")
inner():
print("I am inside inner")
return undecorated_func
return inner
this is a simple decorator function. It received "undecorated_func" and passed it to inner() as a free variable, inner() printed "I am inside inner" and returned undecorated_func. When we call decorator(undecorated_func), it is returning the inner. Here is the key, in decorators we are naming the inner function as the name of the function that we passed.
undecorated_function= decorator(undecorated_func)
now inner function is called "undecorated_func". Since inner is now named as "undecorated_func", we passed "undecorated_func" to the decorator and we returned "undecorated_func" plus printed out "I am inside inner". so this print statement decorated our "undecorated_func".
now let's define a class with a property decorator:
class Person:
def __init__(self,name):
self._name=name
#property
def name(self):
return self._name
#name.setter
def name(self.value):
self._name=value
when we decorated name() with #property(), this is what happened:
name=property(name) # Person.__dict__ you ll see name
first argument of property() is getter. this is what happened in the second decoration:
name=name.setter(name)
As I mentioned above, the decorator returns the inner function, and we name the inner function with the name of the function that we passed.
Here is an important thing to be aware of. "name" is immutable. in the first decoration we got this:
name=property(name)
in the second one we got this
name=name.setter(name)
We are not modifying name obj. In the second decoration, python sees that this is property object and it already had getter. So python creates a new "name" object, adds the "fget" from the first obj and then sets the "fset".
A property can be declared in two ways.
Creating the getter, setter methods for an attribute and then passing these as argument to property function
Using the #property decorator.
You can have a look at few examples I have written about properties in python.
In the following, I have given an example to clarify #property
Consider a class named Student with two variables: name and class_number and you want class_number to be in the range of 1 to 5.
Now I will explain two wrong solutions and finally the correct one:
The code below is wrong because it doesn't validate the class_number (to be in the range 1 to 5)
class Student:
def __init__(self, name, class_number):
self.name = name
self.class_number = class_number
Despite validation, this solution is also wrong:
def validate_class_number(number):
if 1 <= number <= 5:
return number
else:
raise Exception("class number should be in the range of 1 to 5")
class Student:
def __init__(self, name, class_number):
self.name = name
self.class_number = validate_class_number(class_number)
Because class_number validation is checked only at the time of making a class instance and it is not checked after that (it is possible to change class_number with a number outside of the range 1 to 5):
student1 = Student("masoud",5)
student1.class_number = 7
The correct solution is:
class Student:
def __init__(self, name, class_number):
self.name = name
self.class_number = class_number
#property
def class_number(self):
return self._class_number
#class_number.setter
def class_number(self, class_number):
if not (1 <= class_number <= 5): raise Exception("class number should be in the range of 1 to 5")
self._class_number = class_number
Here is another example:
##
## Python Properties Example
##
class GetterSetterExample( object ):
## Set the default value for x ( we reference it using self.x, set a value using self.x = value )
__x = None
##
## On Class Initialization - do something... if we want..
##
def __init__( self ):
## Set a value to __x through the getter / setter... Since __x is defined above, this doesn't need to be set...
self.x = 1234
return None
##
## Define x as a property, ie a getter - All getters should have a default value arg, so I added it - it will not be passed in when setting a value, so you need to set the default here so it will be used..
##
#property
def x( self, _default = None ):
## I added an optional default value argument as all getters should have this - set it to the default value you want to return...
_value = ( self.__x, _default )[ self.__x == None ]
## Debugging - so you can see the order the calls are made...
print( '[ Test Class ] Get x = ' + str( _value ) )
## Return the value - we are a getter afterall...
return _value
##
## Define the setter function for x...
##
#x.setter
def x( self, _value = None ):
## Debugging - so you can see the order the calls are made...
print( '[ Test Class ] Set x = ' + str( _value ) )
## This is to show the setter function works.... If the value is above 0, set it to a negative value... otherwise keep it as is ( 0 is the only non-negative number, it can't be negative or positive anyway )
if ( _value > 0 ):
self.__x = -_value
else:
self.__x = _value
##
## Define the deleter function for x...
##
#x.deleter
def x( self ):
## Unload the assignment / data for x
if ( self.__x != None ):
del self.__x
##
## To String / Output Function for the class - this will show the property value for each property we add...
##
def __str__( self ):
## Output the x property data...
print( '[ x ] ' + str( self.x ) )
## Return a new line - technically we should return a string so it can be printed where we want it, instead of printed early if _data = str( C( ) ) is used....
return '\n'
##
##
##
_test = GetterSetterExample( )
print( _test )
## For some reason the deleter isn't being called...
del _test.x
Basically, the same as the C( object ) example except I'm using x instead... I also don't initialize in __init - ... well.. I do, but it can be removed because __x is defined as part of the class....
The output is:
[ Test Class ] Set x = 1234
[ Test Class ] Get x = -1234
[ x ] -1234
and if I comment out the self.x = 1234 in init then the output is:
[ Test Class ] Get x = None
[ x ] None
and if I set the _default = None to _default = 0 in the getter function ( as all getters should have a default value but it isn't passed in by the property values from what I've seen so you can define it here, and it actually isn't bad because you can define the default once and use it everywhere ) ie: def x( self, _default = 0 ):
[ Test Class ] Get x = 0
[ x ] 0
Note: The getter logic is there just to have the value be manipulated by it to ensure it is manipulated by it - the same for the print statements...
Note: I'm used to Lua and being able to dynamically create 10+ helpers when I call a single function and I made something similar for Python without using properties and it works to a degree, but, even though the functions are being created before being used, there are still issues at times with them being called prior to being created which is strange as it isn't coded that way... I prefer the flexibility of Lua meta-tables and the fact I can use actual setters / getters instead of essentially directly accessing a variable... I do like how quickly some things can be built with Python though - for instance gui programs. although one I am designing may not be possible without a lot of additional libraries - if I code it in AutoHotkey I can directly access the dll calls I need, and the same can be done in Java, C#, C++, and more - maybe I haven't found the right thing yet but for that project I may switch from Python..
Note: The code output in this forum is broken - I had to add spaces to the first part of the code for it to work - when copy / pasting ensure you convert all spaces to tabs.... I use tabs for Python because in a file which is 10,000 lines the filesize can be 512KB to 1MB with spaces and 100 to 200KB with tabs which equates to a massive difference for file size, and reduction in processing time...
Tabs can also be adjusted per user - so if you prefer 2 spaces width, 4, 8 or whatever you can do it meaning it is thoughtful for developers with eye-sight deficits.
Note: All of the functions defined in the class aren't indented properly because of a bug in the forum software - ensure you indent it if you copy / paste
I want to return to the main function whenever value of a is set to 1 by any of the functions(func1,func2,func3) called in the class. Can anyone help me in solving this?I need to return immediately before calling rest of the functions when value is set. I have attached a code snippet for reference.
class Property:
def __init__(self):
## initializing the attribute
self.a = 0
def __call__(self, val):
self.func1(val)
self.func2(val)
self.func3(val)
def func1(self,value):
if value==20:
self.a = 1
return
print("all okay in func1")
def func2(self,value):
if value==40:
self.a = 1
return
print("all okay in func2")
def func3(self,value):
if value==60:
self.a = 1
return
print("all okay in func3")
def main():
obj = Property()
obj(20)
How's this?
class Property:
def __init__(self):
## initializing the attribute
self.a = 0
def set_a_to_1_and_raise(self):
self.a = 1
throw MyCustomException
def __call__(self, val):
try:
self.func1(val)
self.func2(val)
self.func3(val)
except MyCustomException:
return
def func1(self,value):
if value==20:
self.set_a_to_1_and_raise()
print("all okay in func1")
def func2(self,value):
if value==40:
self.set_a_to_1_and_raise()
print("all okay in func2")
def func3(self,value):
if value==60:
self.set_a_to_1_and_raise()
print("all okay in func3")
Edit: Added #tdelaney's nice suggestion regarding the name of the function self.set_a_to_1_and_raise() to make it obvious that it raises an exception when you call it.
In contrast to my other answer #Copperfield had the suggestion of using the Python #property decorators to do this, which could be handy for some applications. This saves you from having to changing the code where you assign self.a = 1, and it will just "automatically" notice whenever you happen to make such an assignment. It's a bit more "under the hood", i.e. less transparent to readers of the code, but could still be useful:
class Property:
def __init__(self):
## initializing the attribute (Note change to _a, not a)
self._a = 0
def __call__(self, val):
try:
self.func1(val)
self.func2(val)
self.func3(val)
except MyCustomException:
return
def func1(self,value):
if value==20:
self.a = 1
print("all okay in func1")
def func2(self,value):
if value==40:
self.a = 1
print("all okay in func2")
def func3(self,value):
if value==60:
self.a = 1
print("all okay in func3")
#property
def a(self):
return self._a
#a.setter
def a(self, new_value):
self._a = new_value
if self._a == 1:
throw MyCustomException
What is happening here is that we have specified a as a property. On the surface it works just like a normal member variable in how you assign and access it, however with the special #a.setter decorator we can define a custom function that runs whenever you set its value. So here we can make it check what value is being assigned, and throw a MyCustomException if that value is 1, which we can then catch after skipping the functions that you didn't want to run.
I am trying to make a python decorator that adds attributes to methods of a class so that I can access and modify those attributes from within the method itself. The decorator code is
from types import MethodType
class attribute(object):
def __init__(self, **attributes):
self.attributes = attributes
def __call__(self, function):
class override(object):
def __init__(self, function, attributes):
self.__function = function
for att in attributes:
setattr(self, att, attributes[att])
def __call__(self, *args, **kwargs):
return self.__function(*args, **kwargs)
def __get__(self, instance, owner):
return MethodType(self, instance, owner)
retval = override(function, self.attributes)
return retval
I tried this decorator on the toy example that follows.
class bar(object):
#attribute(a=2)
def foo(self):
print self.foo.a
self.foo.a = 1
Though I am able to access the value of attribute 'a' from within foo(), I can't set it to another value. Indeed, when I call bar().foo(), I get the following AttributeError.
AttributeError: 'instancemethod' object has no attribute 'a'
Why is this? More importantly how can I achieve my goal?
Edit
Just to be more specific, I am trying to find a simple way to implement static variable that are located within class methods. Continuing from the example above, I would like instantiate b = bar(), call both foo() and doo() methods and then access b.foo.a and b.doo.a later on.
class bar(object):
#attribute(a=2)
def foo(self):
self.foo.a = 1
#attribute(a=4)
def doo(self):
self.foo.a = 3
The best way to do this is to not do it at all.
First of all, there is no need for an attribute decorator; you can just assign it yourself:
class bar(object):
def foo(self):
print self.foo.a
self.foo.a = 1
foo.a = 2
However, this still encounters the same errors. You need to do:
self.foo.__dict__['a'] = 1
You can instead use a metaclass...but that gets messy quickly.
On the other hand, there are cleaner alternatives.
You can use defaults:
def foo(self, a):
print a[0]
a[0] = 2
foo.func_defaults = foo.func_defaults[:-1] + ([2],)
Of course, my preferred way is to avoid this altogether and use a callable class ("functor" in C++ words):
class bar(object):
def __init__(self):
self.foo = self.foo_method(self)
class foo_method(object):
def __init__(self, bar):
self.bar = bar
self.a = 2
def __call__(self):
print self.a
self.a = 1
Or just use classic class attributes:
class bar(object):
def __init__(self):
self.a = 1
def foo(self):
print self.a
self.a = 2
If it's that you want to hide a from derived classes, use whatever private attributes are called in Python terminology:
class bar(object):
def __init__(self):
self.__a = 1 # this will be implicitly mangled as __bar__a or similar
def foo(self):
print self.__a
self.__a = 2
EDIT: You want static attributes?
class bar(object):
a = 1
def foo(self):
print self.a
self.a = 2
EDIT 2: If you want static attributes visible to only the current function, you can use PyExt's modify_function:
import pyext
def wrap_mod(*args, **kw):
def inner(f):
return pyext.modify_function(f, *args, **kw)
return inner
class bar(object):
#wrap_mod(globals={'a': [1]})
def foo(self):
print a[0]
a[0] = 2
It's slightly ugly and hackish. But it works.
My recommendation would be just to use double underscores:
class bar(object):
__a = 1
def foo(self):
print self.__a
self.__a = 2
Although this is visible to the other functions, it's invisible to anything else (actually, it's there, but it's mangled).
FINAL EDIT: Use this:
import pyext
def wrap_mod(*args, **kw):
def inner(f):
return pyext.modify_function(f, *args, **kw)
return inner
class bar(object):
#wrap_mod(globals={'a': [1]})
def foo(self):
print a[0]
a[0] = 2
foo.a = foo.func_globals['a']
b = bar()
b.foo() # prints 1
b.foo() # prints 2
# external access
b.foo.a[0] = 77
b.foo() # prints 77
While You can accomplish Your goal by replacing self.foo.a = 1 with self.foo.__dict__['a'] = 1 it is generally not recommended.
If you are using Python2 - (and not Python3) - whenever you retrieve a method from an instance, a new instance method object is created which is a wrapper to the original function defined in the class body.
The instance method is a rather transparent proxy to the function - you can retrieve the function's attributes through it, but not set them - that is why setting an item in self.foo.__dict__ works.
Alternatively you can reach the function object itself using: self.foo.im_func - the im_func attribute of instance methods point the underlying function.
Based on other contributors's answers, I came up with the following workaround. First, wrap a dictionnary in a class resolving non-existant attributes to the wrapped dictionnary such as the following code.
class DictWrapper(object):
def __init__(self, d):
self.d = d
def __getattr__(self, key):
return self.d[key]
Credits to Lucas Jones for this code.
Then implement a addstatic decorator with a statics attribute that will store the static attributes.
class addstatic(object):
def __init__(self, **statics):
self.statics = statics
def __call__(self, function):
class override(object):
def __init__(self, function, statics):
self.__function = function
self.statics = DictWrapper(statics)
def __call__(self, *args, **kwargs):
return self.__function(*args, **kwargs)
def __get__(self, instance, objtype):
from types import MethodType
return MethodType(self, instance)
retval = override(function, self.statics)
return retval
The following code is an example of how the addstatic decorator can be used on methods.
class bar(object):
#attribute(a=2, b=3)
def foo(self):
self.foo.statics.a = 1
self.foo.statics.b = 2
Then, playing with an instance of the bar class yields :
>>> b = bar()
>>> b.foo.statics.a
2
>>> b.foo.statics.b
3
>>> b.foo()
>>> b.foo.statics.a
3
>>> b.foo.statics.b
5
The reason for using this statics dictionnary follows jsbueno's answer which suggest that what I want would require overloading the dot operator of and instance method wrapping the foo function, which I am not sure is possible. Of course, the method's attribute could be set in self.foo.__dict__, but since it not recommended (as suggested by brainovergrow), I came up with this workaround. I am not certain this would be recommended either and I guess it is up for comments.
For example:
class Example:
def __init__(self):
self.v = 0
#property
def value(self):
return self.v
#value.setter
def value(self, v):
self.v = v
class SubExample(Example):
pass
Would it be possible to rewrite just the getter to value in SubExample?
You can do so like this
class DoubleExample(Example):
#Example.value.getter
def value(self):
return self.v * 2
o = Example()
o.value = 1
print o.value # prints "1"
p = DoubleExample()
p.value = 1
print p.value # prints "2"
However, this only works if Example is a new-style class (class Example(object):) rather than an old style class (class Example:), as it is in your example code.
Warning: Thomas pointed out in the comments that this method may not behave as expected if you're using multiple inheritance (class Foo(Bar, Baz)).
It isn't possible to override a property's getter in a subclass, no. The property is an object that lives in the class and that holds references to the functions you give it -- if you later redefine the names of those functions, it won't affect the property at all.
What you can do is have the functions your property calls perform indirect calls, like so:
class Example(object):
def __init__(self):
self.v = 0
#property
def v(self):
return self._v_getter()
#v.setter
def v(self, value):
return self._v_setter(value)
def _v_setter(self, value):
self._v = value
class SubExample(Example):
def _v_getter(self):
return 5
>>> se = SubExample()
>>> se.v
5
>>> se._v
0
>>> se.v = 10
>>> se.v
5
>>> se._v
10
Alternatively, you can redefine the entire property in the subclass, by simply defining a new property. You won't have convenient access to the functions or property defined in the parentclass, however, and doing the right thing in the face of multiple inheritance is difficult.
Your question has been answered before:
http://code.activestate.com/recipes/408713-late-binding-properties-allowing-subclasses-to-ove/
http://stackoverflow.com/questions/3393534/python-property-and-method-override-issue-why-subclass-property-still-calls-the
Essentially, instead of using property directly, you have to defer calling the getter so that it will access the one defined in the subclass rather than the one defined in the superclass when you first defined the property. This can be achieved via a lambda:
class Test(object):
def __init__(self):
self.v = 0
def _value(self):
return self.v
def _value_setter(self, v):
self.v = v
value = property(lambda self: self._value(), lambda self, v: self._value_setter(v))
class Test2(Test):
def _value(self):
return self.v + 1
a = Test()
a.value = 2
print a.value # 2
b = Test2()
b.value = 2
print b.value # 4