Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Look at the following example

point = (1, 2)
size = (2, 3)
color = 'red'

class Rect(object):
    def __init__(self, x, y, width, height, color):

It would be very tempting to call:

Rect(*point, *size, color)

Possible workarounds would be:

Rect(point[0], point[1], size[0], size[1], color)

Rect(*(point + size), color=color)

Rect(*(point + size + (color,)))

But why is Rect(*point, *size, color) not allowed, is there any semantic ambiguity or general disadvantage you could think of?

EDIT: Specific Questions

Why are multiple *arg expansions not allowed in function calls?

Why are positional arguments not allowed after *arg expansions?

share|improve this question
Duplicate of stackoverflow.com/questions/1419046/… –  Andreas Jung Jun 17 '11 at 14:58
@Sentinel I don't think it's duplicate of that one. –  JBernardo Jun 17 '11 at 15:02
This question is not a duplicate of that one. This question is about unpacking tuples into an argument list and the other is about getting additional positional and keyword arguments in a function. –  murgatroid99 Jun 17 '11 at 15:02
If this is strictly a philosophical question, about, "why isn't Python this way", I would point you to PEP20, the Zen of Python (python.org/dev/peps/pep-0020). In particular, "Explicit is better than implicit." and "Flat is better than nested." –  ironchefpython Jun 17 '11 at 15:13

5 Answers 5

up vote 8 down vote accepted

As far as I know, it was a design choice, but there seems to be a logic behind it.

EDIT: the *args notation in a function call was designed so you could pass in a tuple of variables of an arbitrary length that could change between calls. In that case, having something like f(*a, *b, c) doesn't make sense as a call, as if a changes length all the elements of b get assigned to the wrong variables, and c isn't in the right place either.

Keeping the language simple, powerful, and standardized is a good thing. Keeping it in sync with what actually goes on in processing the arguments is also a very good thing.

Think about how the language unpacks your function call. If multiple *arg are allowed in any order like Rect(*point, *size, color), note that all that matters to properly unpack is that point and size have a total of four elements. So point=(), size=(1,2,2,3), andcolor='red') would allow Rect(*point, *size, color) to work as a proper call. Basically, the language when it parses the *point and *size is treating it as one combined *arg tuple, so Rect(*(point + size), color=color) is more faithful representation.

There never needs to be two tuples of arguments passed in the form *args, you can always represent it as one. Since assignment of parameters is only dependent on the order in this combined *arg list, it makes sense to define it as such.

If you can make function calls like f(*a, *b), the language almost begs to allow you to define functions with multiple *args in the parameter list, and those couldn't be processed. E.g.,

 def f(*a, *b): 
     return (sum(a), 2*sum(b))

How would f(1,2,3,4) be processed?

I think this is why for syntactical concreteness, the language forces function calls and definitions to be in the following specific form; like f(a,b,x=1,y=2,*args,**kwargs) which is order dependent.

Everything there has a specific meaning in a function definition and function call. a and b are parameters defined without default values, next x and y are parameters defined with default values (that could be skipped; so come after the no default parameters). Next, *args is populated as a tuple with all the args filled with the rest of the parameters from a function call that weren't keyword parameters. This comes after the others, as this could change length, and you don't want something that could change length between calls to affect assignment of variables. At the end **kwargs takes all the keyword arguments that weren't defined elsewhere. With these concrete definitions you never need to have multiple *args or **kwargs.

share|improve this answer
Thanks for the update. –  Chris Jun 17 '11 at 16:21
Allowing multiple * unpacking in function calls now sounds somehow inelegant! However I am still not absolutely convinced why positional arguments after *arg should be disallowed (in calling as well as in definition). –  Chris Jun 17 '11 at 16:25
@Chris: If you treat *args as a construct for passing in a tuple of changing length (e.g., sometimes it will be length 2, sometimes length 3), you see how having non-keyword arguments come after arguments of variable length, there's a big risk of the arguments at the end of the call appearing out of place. Python is trying to keep you out of trouble. –  dr jimbob Jun 17 '11 at 16:32

I'm not going to speak to why multiple tuple unpacking isn't part of Python, but I will point out that you're not matching your class to your data in your example.

You have the following code:

point = (1, 2)
size = (2, 3)
color = 'red'

class Rect(object):
    def __init__(self, x, y, width, height, color):
        self.x = x
        self.y = y
        self.width = width
        self.height = height
        self.color = color

but a better way to express your Rect object would be as follows:

class Rect:
    def __init__(self, point, size, color):
        self.point = point
        self.size = size
        self.color = color

r = Rect(point, size, color)

In general, if your data is in tuples, have your constructor take tuples. If your data is in a dict, have your constructor take a dict. If your data is an object, have your constructor take an object, etc.

In general, you want to work with the idioms of the language, rather than try to work around them.

EDIT Seeing how popular this question is, I'll give you an decorator that allows you to call the constructor however you like.

class Pack(object):

    def __init__(self, *template):
        self.template = template

    def __call__(self, f):
        def pack(*args):
            args = list(args)
            for i, tup in enumerate(self.template):
                if type(tup) != tuple:
                for j, typ in enumerate(tup):
                    if type(args[i+j]) != typ:
                    args[i:i+j+1] = [tuple(args[i:i+j+1])]
        return pack    

class Rect:
    @Pack(object, (int, int), (int, int), str)
    def __init__(self, point, size, color):
        self.point = point
        self.size = size
        self.color = color

Now you can initialize your object any way you like.

r1 = Rect(point, size, color)
r2 = Rect((1,2), size, color)
r3 = Rect(1, 2, size, color)
r4 = Rect((1, 2), 2, 3, color)
r5 = Rect(1, 2, 2, 3, color)

While I wouldn't recommend using this in practice (it violates the principle that you should have only one way to do it), it does serve to demonstrate that there's usually a way to do anything in Python.

share|improve this answer
Often, you want to have the choice to pass in either tuples or separate parameters. This solution gives an easier way to allow both variants, but the constrcutor call Rect((x, y), (width, height), color) is still a bit cumbersome. Moreover, the length of the tuples is not automatically checked. (+1 for a good point) –  Sven Marnach Jun 17 '11 at 15:14
Fair enough, my example is poorly chosen in that sense. And your argument could be read like: "Because there is no big need, there are better alternatives". –  Chris Jun 17 '11 at 15:17
@Sven Marnach: And Rect((x, y), (width, height), color) will no longer be possible in Python 3.x, see PEP-3113. –  Chris Jun 17 '11 at 15:19
@sven If you're looking for runtime checking of input parameters, you should be doing that with an annotation on the constructor. If you're looking for compile-time checking of input parameters, Java is ----> that way. –  ironchefpython Jun 17 '11 at 15:19
@Chris defining a function with automatic tuple unpacking is removed in PEP 3113. Calling functions with tuples as parameters is still allowed (and encouraged) –  ironchefpython Jun 17 '11 at 15:21

*point says that you are passing in a whole sequence of items - something like all the elements in a list, but not as a list.

In this case, you cannot limit how many elements are being passed in. Therefore, there is no way for the interpreter to know which elements of the sequence are part of *points and which are of *size

For example, if you passed the following as input: 2, 5, 3, 4, 17, 87, 4, 0, can you tell me, which of those numbers are represented by *points and which by *size? This is the same problem that the interpreter would face as well

Hope this helps

share|improve this answer
This doesn't answer my question, it rather answers why you can't define a method like def foo(*point, *size, color) but that's a completely different problem. When you pass Rect(0, 1, 2, 3, 'red') the behaviour is completely defined. And passing Rect(2, 5, 3, 4, 17, 87, 4, 0, 'red') would raise a TypeError (too many arguments). –  Chris Jun 17 '11 at 15:08
Sorry, I must have misunderstood –  inspectorG4dget Jun 17 '11 at 15:09

Python is full of these subtle glitches. For example you can do:

first, second, last = (1, 2, 3)

And you can't do:

first, *others = (1, 2, 3)

But in Python 3 you now can.

Your suggestion probably is going to be suggested in a PEP and integrated or rejected one day.

share|improve this answer

Well, in Python 2, you can say:

point = 1, 2
size = 2, 3
color = 'red'

class Rect(object):
    def __init__(self, (x, y), (width, height), color):

Then you can say:

a_rect= Rect(point, size, color)

taking care that the first two arguments are sequences of len == 2.
NB: This capability has been removed from Python 3.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.