CHATLAB and Talktave

8:37 AM

@CrisLuengo I think a = b = c = x is just sugar for a = x; b = x; c = x

9:04 AM

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

so you have an infinite recursion.

2 hours later…

10:36 AM

@CrisLuengo almost what flawr said. a = b = c is sugar for tmp = c; a = tmp; b = tmp; del tmp

So you get t = [[]]; a = t; a[0] = t which is the same result as a = []; a.append(a). Python can handle containers that contain themselves.

So you evaluate the rightmost expression then assign that from left to right to each target

@flawr these are lists, not arrays

11:08 AM

@AndrasDeak maybe I'll remember some day

11:58 AM

hmm, this has passed under my radar until now

In [86]: np.s_[3:6, 15:20]
Out[86]: (slice(3, 6, None), slice(15, 20, None))

I'm pretty sure I could have used that, maybe in the recent past

12:13 PM

can you use this tuple directly as an index?

that's the point, yes :)

arr[a, b, c] is the same as arr[(a, b, c)] for any expression, at least as far as numpy is concerned (it might even be a more general python thing)

yeah, because __getitem__ probably gets a single argument

12:36 PM

ooh

1:13 PM

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.

1:41 PM

@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!

1:59 PM

@CrisLuengo yes, but the result will be the same: a list that contains itself

@CrisLuengo yes, but also you never have to know this for sane use cases

just like these gems:

n [101]: d = {}
     ...: for k, d[k] in enumerate('potato'):
     ...:     pass
     ...:

In [102]: d
Out[102]: {0: 'p', 1: 'o', 2: 't', 3: 'a', 4: 't', 5: 'o'}

Just because I know how that works doesn't mean that any code should look like that.

@AndrasDeak beautiful!

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...)

2:39 PM

such as

In [118]: 42 in [42] is True
Out[118]: False

(that's a pitfall)

3:04 PM

In [124]: 42 in [42] in [[42]]
Out[124]: True

Ander Biguri

staph the brainfuck

all that is cursed python

@AndrasDeak I don't think I want to understand how Python chains operators. I'll just stick to using lots and lots of parentheses.

Oh it's very simple. a op b op c is sugar for (a op b) and (b op c) etc. the pitfall is that in chains, when it shouldn't.

Sane chaning cases let you do 3 <= x < 42 and it does what you'd want it to do in math

a is b is c also defines an equivalence relation, although this is something that probably doesn't come up too often as a use case

when you start mixing operators or have in in there it gets messy and buggy

3:25 PM

@AndrasDeak I know this is true for comparison operators, but not for arithmetic operators. So is and in do this too? I think that’s a mistake...

@CrisLuengo I meant comparison operators. But also is and in, and I agree it's a mistake.

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.

yeah, I read about that

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.

I suspect the compiler can do some tricks to make it almost no additional effort to implement the remaining comparison operators

in python the dispatch would be comparatively expensive