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The sample codes are like this:

def assign(self, input=None, output=None, param=None, p1=None, p2=None):
    if input:
        self.input = input
    if output:
        self.output = output
    if param:
        self.param = param
    if p1:
        self.p1 = p1
    if p2:
        self.p2 = p2

Though this looks very clear, it suffers if there're 10 parameters for this function. Does anyone have ideas about a more convinient way for this?

share|improve this question
    
As a side note, there's a potential problem with your code: What if you want to actually assign the value None? If that matters, you can get around this by creating a sentinel value (e.g., sentinel = object(), then input=sentinel, output=sentinel, … in the parameters, then check if input is not sentinel instead of if input). – abarnert Mar 10 '13 at 2:42
    
@abarnert I see. Changed into **kwargs way, I don't need to care about sentinel now. – hanfeisun Mar 10 '13 at 2:45
    
No problem. As I said, it's just a "potential problem". If there's no valid false-y value (None, 0, '', [], etc.) you'd ever want to store in your attributes, this is perfectly fine. – abarnert Mar 10 '13 at 2:46
    
I posted an answer for you – eyquem Mar 10 '13 at 22:06
up vote 7 down vote accepted

you can do something like:

def assign(self,**kwargs):
    for k,v in kwargs.items():
        if v:
           setattr(self,k,v)

This is quite simple and suitable for many situations. If you want to maintain a set of keywords which you'll accept and raise TypeError for the rest:

#python2.7 and newer
def assign(self,allowed_kwargs={'foo','bar','baz'},**kwargs):
    if kwargs.keysview() - allowed_kwargs:
        raise TypeError('useful message here...')
    for k in allowed_kwargs:
        setattr(self,k,kwargs[k])

This is somewhat inspect-able as well since the user will see the set of allowed kwargs.

share|improve this answer
    
That's exactly what I need, Thanks mgilson! – hanfeisun Mar 10 '13 at 2:37
1  
Be careful with if v:. This will not set the attribute for any value that is not considered True in python. So obj.assign(a=0, b='', c=[]) will not assign any of those attributes to obj. I think if v is not None: would be safer. – Warren Weckesser Mar 10 '13 at 3:54
    
@WarrenWeckesser -- That's a reasonable point. I answered this way to mirror OP's original code, but it's nice to have this noted here. – mgilson Mar 10 '13 at 3:54
    
With your solution, it is mandatory to pass arguments in the keyworded form. In my answer, it's not. – eyquem Mar 10 '13 at 22:08

Explicit is better than implicit

def assign(self, input=None, output=None, param=None, p1=None, p2=None):

has many advantages over

def assign(self, **kwargs)
  • It is self-documenting
  • A helpful TypeError is raised if an invalid parameter is passed to assign.
  • assign can be called with positional as well as keyword arguments

To its credit, the code the OP posted is entirely explicit, though the if-statements are monotonous. To cut down on the monotony, you could use something like this:

class Foo(object):
    def assign(self, input=None, output=None, param=None, p1=None, p2=None):
        for name in 'input output param p1 p2'.split():
            val = vars()[name]
            if val is not None:
                setattr(self, name, val)

foo = Foo()
foo.assign(p1=123, p2='abc')
share|improve this answer
    
If you want to reproduce his assign function, you should raise a TypeError for any key not in kwargs instead of just skipping it. Also, I think it's more general (e.g., works with __slots__), and probably more explicit, to call setattr instead of self.__dict__.__update. – abarnert Mar 10 '13 at 2:44
    
Decorators are ignored when touching dict directly. So if a person were to use @property and @x.setter for something, this would break that. the setattr call fixes this (like abarnert mentioned.) – BlackVegetable Mar 10 '13 at 2:53
    
@BlackVegetable: Yeah, I was just trying to give one example of when setattr is necessary. There's also custom descriptors, __setattr__, superclasses with some of these same issues, superclasses implemented in C/RPython/Java/.NET with similar issues, … – abarnert Mar 10 '13 at 3:23
    
What do you think of my answer, please ? – eyquem Mar 10 '13 at 22:07
    
@eyquem: I get the sense you are trying to solve a different, more complicated, problem than the one Firegun has asked. I'm not convinced of the validity of the problem, so I am not enthusiastic about the solution. (I like simple things; your solution is too complex.) However, I do like the fact that you've retained an explicit call signature; I've changed my answer because of it. – unutbu Mar 11 '13 at 1:50

One of the great things about python is its interactive interpreter. When you write code like this:

>>> def assign(self, input=None, output=None, param=None, p1=None, p2=None):
...     pass
... 

Its quite easy to figure out how you're supposed to use the function:

>>> help(assign)
Python Library Documentation: function assign in module __main__

assign(self, input=None, output=None, param=None, p1=None, p2=None)

By comparison:

>>> def assign2(self, **kwargs):
...     pass
... 

gives:

>>> help(assign2)
Python Library Documentation: function assign2 in module __main__

assign2(self, **kwargs)

I hope you understand why the first form is preferrable. But you still want to avoid writing everything twice (in the arguments and in the body).

The first question is why are you writing code of this nature? I find it a very common case that I want a class with a heap of attributes that it will carry around, but the set of those attributes is essentially fixed. In the very most common case, those attributes never change for the lifetime of the object; in which case python has a built in helper for exactly that!

>>> import collections
>>> Assignment = collections.namedtuple('Assignment', 'input output param p1 p2')
>>> assign = Assignment(None, None, None, None, None)._replace
>>> assign(p1=10)
Assignment(input=None, output=None, param=None, p1=10, p2=None)
>>> help(Assignment)
Python Library Documentation: class Assignment in module __main__

class Assignment(__builtin__.tuple)
 |  Assignment(input, output, param, p1, p2)
 |  
... SNIP

namedtuple's are regular classes, you can inherit from them to give them special behaviours. they are, unfortunately, immutable, and if you happen to need that, you will need another technique; but you should almost always reach for named tuple first. Otherwise, we can make use of some other magic; we can get all of the local variables, which at function start, includes only the arguments:

>>> class Assignable(object):
...     def assign(self, input=None, output=None, param=None, p1=None, p2=None):
...         _kwargs = vars()
...         _kwargs.pop('self')
...         vars(self).update((attr, value) for attr, value in _kwargs.items() if value is not None)
... 
>>> a = Assignable()
>>> vars(a)
{}
>>> a.assign(p1=6)
>>> vars(a)
{'p1': 6}
>>> a.p1
6

and the help() text is still very helpful!

>>> help(a.assign)
Python Library Documentation: method assign in module __main__

assign(self, input=None, output=None, param=None, p1=None, p2=None) method of __main__.Assignable instance
share|improve this answer
    
Add a docstring '''parameters with default value None are: input, output, param, p1, p2''' and help(assign) will display two lines assign(self, **kwargs) and '''parameters with default value None are: input, output, param, p1, p2''' – eyquem Mar 10 '13 at 19:23
    
I closely studied your proposition of using a namedtuple. I don't think it's so much interesting that it seems at start: 1) a named tuple instance has attributes _fields, _make, _asdict besides the ones that the coder certainly wants as the only attributes for its desired instance, they are superfluous info recorded in the instance. 2) The only useful attribute _replace has a behavior that may be a drawback: it returns an object having a different identity. That may be unwanted in some cases. This point is covered by what you say when evoking that named tuples are immutable. – eyquem Mar 10 '13 at 20:51
    
3) Point 2 was about changing the values of existing attributes. This one is about adding new attributes: no new attribute can be added after creation of a named tuple, the __dict__ of a named tuple can't be changed. It makes the interest of named tuples: "Named tuple instances do not have per-instance dictionaries, so they are lightweight and require no more memory than regular tuples." , but it makes them not very suitable for other tasks than what they are designed for. My opinion. – eyquem Mar 10 '13 at 20:52
    
However, your answer made me think about different subjects and I've upvoted other very interesting answers of you (on locals for ex). – eyquem Mar 10 '13 at 20:52
    
methods which take more than three arguments (other than self) are frequently suspect. The different arguments usually belong together, as a group of related attributes. the way attributes are normally grouped, in python and other languages, is with a class. Passing an instance of a light weight class (as returned by namedtuple) is a particularly concise and descriptive way to hand data around, even when that data will be applied to another, less light class. When I say reach for namedtuple, I don't mean replace the class that owns assign() in this question, only the function. – SingleNegationElimination Mar 10 '13 at 23:23

With mgilson's and unutbu's solutions, the possibility of writing all types of calls is lost.

In my following solution, this possibility is preserved:

class Buu(object):
    def assign(self,
               input=None, output=None,
               param=None,
               p1=None, p2=None,
               **kw):
        for k,v in locals().iteritems():
            if v not in (self,None,kw):
                if v == (None,):
                    setattr(self,k,None)
                else:
                    setattr(self,k,v)
        for k,v in kw.iteritems():
            setattr(self,k,v)

buu = Buu()

buu.assign(None,(None,), p1=[])
print "buu's attributes:",vars(buu)
print

buu.assign(1,p2 = 555, xx = 'extra')
print "buu's attributes:",vars(buu)

result

buu's attributes: {'output': None, 'p1': []}

buu's attributes: {'p2': 555, 'output': None, 'xx': 'extra', 'p1': [], 'input': 1}

By the way, when a coder puts None as default argument for a parameter, it's because he foresees that there will be no case where it will be necessary to pass None as a significant arguments that would really be of influence during the excution.
Hence I think that the point of passing None as real significant argument is a false problem.
However , in the above code, this problem is skirted by using the convention that in case a new attribute with value None must be created, the argument should be (None,).

If someone wants to pass (None,) ???
Seriously ?
Oh heck!

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