For the RHS, there is not much of an issue. the answer here states it well:
We have it working as it usually does in function calls. It expands
the contents of the iterable it is attached to. So, the statement:
elements = *iterable
can be viewed as:
elements = 1, 2, 3, 4,
which is another way for a tuple to be initialized.
Now, for the LHS,
Yes, there are technical reasons for the LHS using a list, as indicated in the discussion around the initial PEP 3132 for extending unpacking
The reasons can be gleaned from the conversation on the PEP(added at the end).
Essentially it boils down to a couple key factors:
- The LHS needed to support a "starred expression" that was not necessarily restricted to the end only.
- The RHS needed to allow various sequence types to be accepted, including iterators.
- The combination of the two points above required manipulation/mutation of the contents after accepting them into the starred expression.
- An alternative approach to handling, one to mimic the iterator fed on the RHS, even leaving implementation difficulties aside, was shot down by Guido for its inconsistent behaviour.
- Given all the factors above, a tuple on LHS would have to be a list first, and then converted. This approach would then just add overhead, and did not invite any further discussion.
Summary: A combination of various factors led to the decision to allow a list on the LHS, and the reasons fed off of each other.
Relevant extract for disallowing inconsistent types:
The important use case in Python for the proposed semantics is when
you have a variable-length record, the first few items of which are
interesting, and the rest of which is less so, but not unimportant.
(If you wanted to throw the rest away, you'd just write a, b, c =
x[:3] instead of a, b, c, *d = x.) It is much more convenient for this
use case if the type of d is fixed by the operation, so you can count
on its behavior.
There's a bug in the design of filter() in Python 2 (which will be
fixed in 3.0 by turning it into an iterator BTW): if the input is a
tuple, the output is a tuple too, but if the input is a list or
anything else, the output is a list. That's a totally insane
signature, since it means that you can't count on the result being a
list, nor on it being a tuple -- if you need it to be one or the
other, you have to convert it to one, which is a waste of time and
space. Please let's not repeat this design bug.
I have also tried to recreate a partially quoted conversation that pertains to the summary above.Source
In argument lists, *args exhausts iterators, converting them to
tuples. I think it would be confusing if *args in tuple unpacking
didn't do the same thing.
This brings up the question of why the patch produces lists, not
tuples. What's the reasoning behind that?
IMO, it's likely that you would like to further process the resulting
sequence, including modifying it.
Well if that's what you're aiming at, then I'd expect it to be more
useful to have the unpacking generate not lists, but the same type you
started with, e.g. if I started with a string, I probably want to
continue using strings::
--additional text snipped off
When dealing with an iterator, you don't know the length in advance,
so the only way to get a tuple would be to produce a list first and
then create a tuple from it.
Yep. That was one of the reasons it was suggested that the *args
should only appear at the end of the tuple unpacking.
couple convos skipped
I don't think that returning the type given is a goal that should be
attempted, because it can only ever work for a fixed set of known
types. Given an arbitrary sequence type, there is no way of knowing
how to create a new instance of it with specified contents.
I'm suggesting, that:
- lists return lists
- tuples return tuples
- XYZ containers return XYZ containers
- non-container iterables return iterators.
How do you propose to distinguish between the last two cases?
Attempting to slice it and catching an exception is not acceptable,
IMO, as it can too easily mask bugs.
But I expect less useful. It won't support "a, *b, c = "
either. From an implementation POV, if you have an unknown object on
the RHS, you have to try slicing it before you try iterating over it;
this may cause problems e.g. if the object happens to be a defaultdict
-- since x[3:] is implemented as x[slice(None, 3, None)], the defaultdict will give you its default value. I'd much rather define
this in terms of iterating over the object until it is exhausted,
which can be optimized for certain known types like lists and tuples.
--Guido van Rossum