I'm doing it like:
def set_property(property,value): def get_property(property):
object.property = value value = object.property
I'm new to Python, so i'm still exploring the syntax, and i'd like some advice on doing this.
Try this: Python Property
The sample code is:
class C(object): def __init__(self): self._x = None @property def x(self): """I'm the 'x' property.""" print("getter of x called") return self._x @x.setter def x(self, value): print("setter of x called") self._x = value @x.deleter def x(self): print("deleter of x called") del self._x c = C() c.x = 'foo' # setter called foo = c.x # getter called del c.x # deleter called
What's the pythonic way to use getters and setters?
The "Pythonic" way is not to use "getters" and "setters", but to use plain attributes, like the question demonstrates, and
del for dereferencing (but the names are changed to protect the innocent... builtins):
value = 'something' obj.attribute = value value = obj.attribute del obj.attribute
If later, you want to modify the setting and getting, you can do so without having to alter user code, by using the
class Obj: """property demo""" # @property def attribute(self): # implements the get - this name is *the* name return self._attribute # @attribute.setter def attribute(self, value): # name must be the same self._attribute = value # @attribute.deleter def attribute(self): # again, name must be the same del self._attribute
(Each decorator copies and updates the prior property object, so note that you should probably use the same name for each set, get, and delete function/method.)
After defining the above, the original setting, getting, and deleting is the same:
obj = Obj() obj.attribute = value the_value = obj.attribute del obj.attribute
You should avoid this:
def set_property(property,value): def get_property(property):
Firstly, the above doesn't work, because you don't provide an argument for the instance that the property would be set to (usually
self), which would be:
class Obj: def set_property(self, property, value): # don't do this ... def get_property(self, property): # don't do this either ...
Secondly, this duplicates the purpose of two special methods,
Thirdly, we also have the
getattr builtin functions.
setattr(object, 'property_name', value) getattr(object, 'property_name', default_value) # default is optional
@property decorator is for creating getters and setters.
For example, we could modify the setting behavior to place restrictions the value being set:
class Protective(object): @property def protected_value(self): return self._protected_value @protected_value.setter def protected_value(self, value): if acceptable(value): # e.g. type or range check self._protected_value = value
In general, we want to avoid using
property and just use direct attributes.
This is what is expected by users of Python. Following the rule of least-surprise, you should try to give your users what they expect unless you have a very compelling reason to the contrary.
For example, say we needed our object's protected attribute to be an integer between 0 and 100 inclusive, and prevent its deletion, with appropriate messages to inform the user of its proper usage:
class Protective(object): def __init__(self, start_protected_value=0): self.protected_value = start_protected_value @property def protected_value(self): return self._protected_value @protected_value.setter def protected_value(self, value): if value != int(value): raise TypeError("protected_value must be an integer") if 0 <= value <= 100: self._protected_value = int(value) else: raise ValueError("protected_value must be " + "between 0 and 100 inclusive") @protected_value.deleter def protected_value(self): raise AttributeError("do not delete, protected_value can be set to 0")
>>> p1 = Protective(3) >>> p1.protected_value 3 >>> p1 = Protective(5.0) >>> p1.protected_value 5 >>> p2 = Protective(-5) Traceback (most recent call last): File "<stdin>", line 1, in <module> File "<stdin>", line 3, in __init__ File "<stdin>", line 15, in protected_value ValueError: protectected_value must be between 0 and 100 inclusive >>> p1.protected_value = 7.3 Traceback (most recent call last): File "<stdin>", line 1, in <module> File "<stdin>", line 17, in protected_value TypeError: protected_value must be an integer >>> p1.protected_value = 101 Traceback (most recent call last): File "<stdin>", line 1, in <module> File "<stdin>", line 15, in protected_value ValueError: protectected_value must be between 0 and 100 inclusive >>> del p1.protected_value Traceback (most recent call last): File "<stdin>", line 1, in <module> File "<stdin>", line 18, in protected_value AttributeError: do not delete, protected_value can be set to 0
Yes they do.
.deleter make copies of the original property. This allows subclasses to properly modify behavior without altering the behavior in the parent.
class Obj: """property demo""" # @property def get_only(self): return self._attribute # @get_only.setter def get_or_set(self, value): self._attribute = value # @get_or_set.deleter def get_set_or_delete(self): del self._attribute
Now for this to work, you have to use the respective names:
obj = Obj() # obj.get_only = 'value' # would error obj.get_or_set = 'value' obj.get_set_or_delete = 'new value' the_value = obj.get_only del obj.get_set_or_delete # del obj.get_or_set # would error
I'm not sure where this would be useful, but the use-case is if you want a get, set, and/or delete-only property. Probably best to stick to semantically same property having the same name.
Start with simple attributes.
If you later need functionality around the setting, getting, and deleting, you can add it with the property decorator.
Avoid functions named
get_... - that's what properties are for.
Check out the
@attribute.setter helps you to not only use the "pythonic" way but also to check the validity of attributes both while creating the object and when altering it.
class Person(object): def __init__(self, p_name=None): self.name = p_name @property def name(self): return self._name @name.setter def name(self, new_name): if type(new_name) == str: #type checking for name property self._name = new_name else: raise Exception("Invalid value for name")
By this, you actually 'hide'
_name attribute from client developers and also perform checks on name property type. Note that by following this approach even during the initiation the setter gets called. So:
p = Person(12)
Will lead to:
Exception: Invalid value for name
>>>p = person('Mike') >>>print(p.name) Mike >>>p.name = 'George' >>>print(p.name) George >>>p.name = 2.3 # Causes an exception
You can use accessors/mutators (i.e.
@property) or not, but the most important thing is to be consistent!
If you're using
@property to simply access an attribute, e.g.
class myClass: def __init__(a): self._a = a @property def a(self): return self._a
use it to access every* attribute! It would be a bad practice to access some attributes using
@property and leave some other properties public (i.e. name without an underscore) without an accessor, e.g. do not do
class myClass: def __init__(a, b): self.a = a self.b = b @property def a(self): return self.a
self.b does not have an explicit accessor here even though it's public.
Similarly with setters (or mutators), feel free to use
@attribute.setter but be consistent! When you do e.g.
class myClass: def __init__(a, b): self.a = a self.b = b @a.setter def a(self, value): return self.a = value
It's hard for me to guess your intention. On one hand you're saying that both
b are public (no leading underscore in their names) so I should theoretically be allowed to access/mutate (get/set) both. But then you specify an explicit mutator only for
a, which tells me that maybe I should not be able to set
b. Since you've provided an explicit mutator I am not sure if the lack of explicit accessor (
@property) means I should not be able to access either of those variables or you were simply being frugal in using
*The exception is when you explicitly want to make some variables accessible or mutable but not both or you want to perform some additional logic when accessing or mutating an attribute. This is when I am personally using
@attribute.setter (otherwise no explicit acessors/mutators for public attributes).
Lastly, PEP8 and Google Style Guide suggestions:
PEP8, Designing for Inheritance says:
For simple public data attributes, it is best to expose just the attribute name, without complicated accessor/mutator methods. Keep in mind that Python provides an easy path to future enhancement, should you find that a simple data attribute needs to grow functional behavior. In that case, use properties to hide functional implementation behind simple data attribute access syntax.
On the other hand, according to Google Style Guide Python Language Rules/Properties the recommendation is to:
Use properties in new code to access or set data where you would normally have used simple, lightweight accessor or setter methods. Properties should be created with the
The pros of this approach:
Readability is increased by eliminating explicit get and set method calls for simple attribute access. Allows calculations to be lazy. Considered the Pythonic way to maintain the interface of a class. In terms of performance, allowing properties bypasses needing trivial accessor methods when a direct variable access is reasonable. This also allows accessor methods to be added in the future without breaking the interface.
Must inherit from
objectin Python 2. Can hide side-effects much like operator overloading. Can be confusing for subclasses.
You can use the magic methods
class MyClass: def __init__(self, attrvalue): self.myattr = attrvalue def __getattribute__(self, attr): if attr == "myattr": #Getter for myattr def __setattr__(self, attr): if attr == "myattr": #Setter for myattr
Be aware that
__getattribute__ are not the same.
__getattr__ is only invoked when the attribute is not found.