@AndrasDeak What does that mean??? You assign first a = a[0], and then a[0] = [[]]? But a[0] doesn't exist at first?
No, there's something else going on here:
>>> a=[]
>>> a = a[0]
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
IndexError: list index out of range
>>> a[0] = [[]]
Traceback (most recent call last):
File "<stdin>", line 1, in <module>
IndexError: list assignment index out of range
>>> a = a[0] = [[]]
>>>
This makes 0 sense to me. Both assignments are illegal, but the two assignments at the same time are OK?!?!?!
so here a = [[]]; a[0] = [[]] (but don't take the second literally, this is two times the same array. so a just ends up being an array containing another array that contains a
That's also why if you have an array idx of shape (3, n) that specifies n x, y, and z indices, respectively, you can index with that as arr[tuple(idx)]. Using arr[idx] or arr[idx.tolist()] would trigger fancy indexing, you only get basic indexing for a tuple.
@AndrasDeak In this case, wouldn’t it be equivalent to a = [[]]; a[0] = a?
In any case this is very unintuitive behavior because it is not parsed left to right, nor right to left.
I find the C behavior more intuitive: a = b = c is parsed right to left. So your first get b = c, and then the result of that expression (which is the value of c) is assigned into a. In C++ you can overload assignment to evaluate to something else, which is rather dangerous... So you could end up with b equal to c, but the expression evaluating to 0, and so a = 0.
@CrisLuengo yes, but Andras' version it is obvious how it is generalizable to any number of things that recevie the assignment
"assignment victims"?
I think that was the reason he wrote it that way.
D: if we consider the permutation (n,1,2,3,....,n-1) as a linear map, then the matrices that diagonalize it are bascially the discrete fourier transforms!
Also, coming from C you might be surprised at the behaviour of a == b == c, but at least that's sane. (Unlike some other operator chaining examples...)
C++20 introduces a “spaceship operator”, which is kinda interesting. <=>. It is a comparison operator that returns a number, 0 for equality, the sign indicates which operates is larger.
For a class, default comparison operators are generated based on this result, so you only need to define one comparison operator for your class.
The cool thing is that it also defines, by the return type, whether the class has a total order or a partial order, which generic algorithms can then use to do the right thing.
Herb Sutter, in his proposal for the "spaceship" operator (section 2.2.2, bottom of page 12), says:
Basing everything on <=> and its return type: This model has major advantages, some unique to this proposal compared to previous proposals for C++ and the capabilities of other languages:
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