Today I am thinking about straightedge and compass problems. I have a finite set of starting points, and I want to investigate the points that are reachable using only the straightedge.
If my starting points are four points arranged in a square, I can only reach one additional point: the center of the square. If my starting points are nine points arranged in an evenly spaced 3x3 grid, I believe I can get arbitrarily close to any point on the plane. But if my starting points are, say, arranged in an equaliateral triangle plus a point in the center, I'm not so sure that I can get anywhere.
I could do that if I had both a compass and a straightedge, or a straightedge with distance markings. But I just have the straightedge with no markings.
The first half of the proof is to divide the triangle into four triangles, and then divide each of those triangles into four more triangles. The second half extends each triangle's line segments to infinity and shows that the lines intersect and form yet more triangles
Yes, you can find the midpoints of the original triangle, and from there split it into four triangles. But you can't trivially repeat this process for each new triangle, because you only have the center point of one of them.
Here's a triangle which is not quite equilateral, but please pretend that it is, so you don't hurt its feelings. We've successfully divided it into four smaller triangles.
@Kevin Using a compass, you can extend the triangle to a (skewed) square (whatever that's called in English). From there on you should be able to do the same construction as for the actual square.
If we draw a line through the midpoints of the center triangle, it intersects the top triangle a one of its midpoints. This should be sufficient to divide the top triangle into four triangles, and likewise for the southwest triangle and southeast triangle.
The fact that the midpoint is unique to the original triangle I'm not sure whether the distortion might be inevitable. I can't convince myself it's not
As long as the "center point" is specifically the centroid of the three other points, you can at least divide the starting triangle into four congruent triangles. Getting from four to sixteen is where I'm less certain.
Here's a small visual proof of the "nine points in a grid" case. Starting with the black lines, draw the red lines, then the green line, then the blue line.
@Kevin I assume this implies that you have a specific point in mind before trying to reach it, since you can otherwise just draw intersecting pairs of lines in arbitrary places - yeah?
Doubling the resolution is also possible for the triangular lattice. You can find the midpoint of any line segment by identifying the two triangles that use that segment as a side, and drawing a line through their furthest points.
Miyagi mentioned that you can skew the plane without affecting the integrity of the proof... I wonder if it's always possible to skew a triangle into an equilateral triangle.
if by "skew" you mean any 2-dimensional affine transformation, and by "triangle" you exclude collinear points, then yes, trivially. for example: rotate and scale such that one arbitrary side of the triangle is the line segment from (0,0) to (1,0); shear such that the x-coordinate of the other point is 0.5; scale vertically such that the y-coordinate of the other point is sqrt(3)/2; invert the first step
(first step also requires translation in general, of course)
Could we get a third reopen vote here? The OP added their solution, test data generator and timing code. But sadly also deleted the question, maybe discouraged by getting closed and downvoted. Perhaps they reconsider when reopened.
I am keeping an eye on the "flatten list" question. I'm tempted to half-jokingly tell the answerer that their solution isn't truly "universal" since it won't work on very deeply nested lists or self-referential lists.
I also used to think that when I was new-ish in this room, but then I looked around and noticed it was actually real
@KellyBundy is it? It still says "page not found" unless this is because of caching issues (I did refresh but didn't bother closing/reopening the browser yet)
I have a real language named KevinScript that actually runs and is Turing complete. I also have an imagined fever dream named KevinScript that combines all the worst design decisions conceivable. Hopefully it will never be real.
@KarlKnechtel Ask them for clarification if/when they undelete :-). Their text and example, to me, sound like they want Counter(b) - Counter(a) (after converting a and b to the obvious dicts). Their code pretty much does that, too, although they introduced floats and rounding. But I think the code works as reference/spec.
@Kevin pretty sure we have a canonical for "traverse nested structure and produce a flat result", too
@KellyBundy yes, that's what I figured too (it should perhaps be the named method .subtract in order to allow negative differences, but zeros have to be filtered out).
Normally my phone gives me terrible articles to read but this was quite interesting, especially in light of the KS discussions just earlier; c-style loops in python
They say it's proportional to the phase of the moon and viewing conditions, but I suspect that's a placebo effect and the moon wizards only need to believe in themselves. Nobody tell the moon wizards.
I want to take this moment to assure everyone that, statistically, each statement in rooms/6 has been reviewed by at least one bona fide scientist. Trust rooms/6! Mind the moon wizards!
Kevin is probably quintuple blind reviewed at any time.
Can confirm that I have monthly top ups on my Moon Wizard Spotting training. I'm pretty proficient with the trusty willow branch detection method (which I cannot disclose)
Dowsing branches can be made from willow. Handy that you can use one tool to detect both water and moon wizards. But make sure you know which one it's set to before you go looking.
Eh, it's an old photograph, so I'm basically explaining how to hack an Atari. Modern willow branches come with DRM (Dowsing Rights Management) protection, which I will speak of no further.
If your are happy that it solves your problem (test it?) Then tell the commenter to post as an answer or do it yourself after some reasonable time (not everyone is at a keyboard all the time). You judge what's a reasonable time
Fwiw I leave similar comments and I don't care if they get converted to answers by others. SO discourages answers in comments so there's no reprisal if someone takes it as an answer; I do that knowingly, others might just be formulating ideas. It's your question, though, so do what you think is right.
@sahasrara62 Are you asking if defining a staticmethod and classmethod to the same thing is a bad approach? In the question, it was just used as a demonstration, there is no reason to define both. The first answer answers the question pretty well - use the classmethod, not the staticmethod.
@roganjosh Thanks. It's kind of hard for me to test since I am using a specific version of a library for a reason, but the bug report they linked to is pretty much 100% the issue.
@PaulMcG no not about the methods but creating same class instance using those methods. So usecase of same class new class instance from same class method
What do you mean "same class instance"? When you call a classmethod, there is no instance.
Here is a class that holds a list of ints. You can construct it with some int values. But it also supports a from_string classmethod. You call it as shown.
class IntList:
def __init__(self, *values):
self.contents = [*values]
@classmethod
def from_string(cls, s):
"""s is a string of space-separated ints"""
return cls(*(int(i) for i in s.split()))
ilist = IntList.from_string("1 2 3")
print(ilist.contents)
