re: Python rushing ahead of Java, I guess one reason would be that colleges have started to adapt python instead of Java mostly, I know now my college teaches python instead of C and Java in the first year
Can someone help me: why does this for loop only go through once? It only adds up the numbers for the first iteration it seems.
for x in range(1,4):
a_yes=0
for locus in reader:
if locus[0] in yes_list:
a_yes+=float(locus[x])
print (a_yes)
>>> data = np.arange(10)
>>> roi = data[-3 - 2:-2]
>>> roi = roi + 10
>>> roi
array([15, 16, 17])
>>> roi = data[-3 - 2:-2]
>>> roi += 10
>>> roi
array([15, 16, 17])
Looks the same. You are probably starting A and B with different roi
This is true for almost any type of collection. This is simply due to the way python treats variables. var1 += var2 is not the same as var1 = var1 + var2 with collections. I'll explain it as far as I understand it, which can certainly be improved, so any edits/criticisms are welcomed.
print("1:"...
> For numbers, += works just as you’d expect. But lists give us another surprise. With lists, “nums = nums+more” will rebind nums to a new list formed by concatentating nums and more. But “nums += more” actually modifies nums in-place, as a mutating operation.
I guess you are saying assign all indexes in my numpy array tthe value of ten which makes sense. The line you wrote: roi = data[-3 - 2:-2] is also confusing
I am watching a tutorial. The author want to create a watermark on the video frame at the lower right corner. The watermark size is 3 pixel wide. He also want to give a margin of 2 pixels.
Electric field due to 3 charges. The black one is a negative charge orbiting the other two positive charges.
\documentclass[pstricks,border=12pt]{standalone}
\usepackage{pst-electricfield}
\begin{document}
\multido{\i=0+15}{24}{%
\begin{pspicture*}(-4,-4)(4,4)
\psElectricfield[Q={[-1 3 \i...
I guess there is no way for me to be sure that is your account though, hmmm. I mean a person could share an account on another site and claim it as their own. I give you the benefit of the doubt.
I have just the one and it has totally stagnated. I need to get back to rep hunting and question answering. I just hang out here all the time when I am on SO now
Is there a mathematical name for this set operation? x = set(a+b for a in y for b in z)
I know that set((a,b) for a in y for b in z) is the Cartesian Product, so maybe I can define it in terms of that... So if there's a name for the set operation x = set(sum(a) for a in y) then I can get what I need
I'm pretty content with traveling forward through time. What's rewinding time gonna do for me except make me experience embarrassing childhood memories again?
@CoolCloud can you explain stackoverflow.com/a/27193976/12502959 as you are someone who use tkinter "self.icon_size.image = self.icon # <== this is were we anchor the img object"
@python_user Today I have used self before an PhotoImage instance and it has worked for me, maybe not always? I am not sure about that case or why the user says it needs to be again kept reference to
Tkinter Label does not show Image is not caused by garbage collection. The OP correctly ensures that the PhotoImage is not prematurely garbage collected, by attaching it to an object with a longer lifetime, in this case self. His actual problem, described at stackoverflow.com/a/35957485/953482, is that his image had an alpha channel that Tkinter didn't understand.
How to put sound and image when click at a button in python? does not attach their PhotoImage to any long-lived object, so they will experience the problem from "Why does Tkinter...". The typical png does not have an alpha channel*, so they will probably not experience the problem from "Tkinter Label does not...".
So your proposal to close "How to put sound..." as a duplicate of "Tkinter Label does not..." is not advised
Closing "How to put sound..." as a duplicate of "Why does Tkinter..." is probably fine though
@Kevin ok this ^ makes sense, melon much, so how did you initially understand the question "both answer the question that I thought was being asked, "?
Whenever I see any tkinter question about PhotoImages not displaying right, I immediately assume that it's a duplicate of "Why does Tkinter..." without actually reading the code. 99% of the time, I'm right, but today I was wrong
You guys seem interested in whether this garbage collection problem is a bug or not. I want to explain my perspective, but first I need to double-check some facts. Please hold.
estimated wait time: between 5 minutes and eight hours
bugs.python.org/issue632323 describes the problem in some detail, and some bigwigs weigh in. TLDR: Guido says it's not a bug, so it's not a bug.
I guess I'd summarize the problem as: three layers of the program make use of the PhotoImage (or BitmapImage, either on), and all of them assume that one of the others is handling the reference counting for them.
At the highest layer, the user creates a PhotoImage and passes it to Label via the image named argument. The user assumes that the Label will keep its arguments alive for as long as it needs them. This is a fairly reasonable assumption, since that's how most classes work.
At the middle layer, the Label class takes configuration options from the user, and hands them to the underlying tcl/tk engine. Like most widgets, Label does not keep track of its own data. Once it hands everything off to tcl before the end of Label.__init__, it can retrieve any information it wants about itself just by asking tcl for it back.
I only tinkered a little with tkinter, but it was enough to teach me that I will always prefer a website over a tkinter app. Just throw some flask together and there you go
At the bottom layer, Tcl receives commands from upper layers and dutifully follows them. If something tells it to allocate space for an image, it does so. If something tells it to deallocate space, it does so. It never garbage collects anything on its own initiative, because it doesn't know what garbage is.
The final piece of the puzzle: The base tkinter.Image class defines a __del__ method that cleans up the image's allocated resources when the image gets collected. This includes telling Tcl to deallocate the space it made for the image data.
Considering that tkinter automagically creates and manages a Tcl interpreter for you under the hood, it seems a bit silly (from the user's perspective) to distinguish between tkinter and Tcl. The user can't have Tkinter without Tcl or Tcl without Tkinter, so it really doesn't matter which one of them keeps the image alive. But one of them should.
I would also like that to be the case. But the bigwigs appear to reject this for two primary reasons: first, changing how it works now would break backwards compatibility. Second, it's a pain in the butt to rewrite every widget class that might take image as a named argument.
I'm pretty skeptical of the claim "Python cannot possibly track all uses of the command". I'm assuming he's referring to all of the tcl/tk commands that accept image parameters. I don't know how many of those there are, but I'm guessing the number is finite, and probably less than, say, a million, so I think Python could track all uses if it monitored all communication from Python to tk.
The "breaking backwards compatibility" argument is also pretty silly. The only people who might get bitten by that change are those who remove the image from their GUI by deleting the last reference to the PhotoImage object. But python makes no guarantees about when it cleans up dead objects, so that's a stupid thing to do anyway.
Perhaps it's wrong to say that I want to define the Kevinian Sum for all kinds of mathematical sets. More specifically, I'm only interested in sets of positive integers that can be constructed from some simple fundamental building blocks.
Definition: a KSet is a kind of set, defined recursively as: the empty set is a KSet. {1} is a KSet. for any positive integer x, {x, x*k, x*k, ...} is a KSet. The union of two KSets is a KSet. The Kevinian Sum of two KSets is a KSet.
My current goal is to come up with a non-recursive definition of a KSet that allows me to efficiently determine whether a convntionally-described set is a KSet or not. For example, is the set of all positive integers not evenly divisble by 3 a kset? What about the set of positive squares?
@Aran-Fey Wow, I really mangled that line. I meant to write {x, 2*x, 3*x, ...}
I know the set of all positive integers not evenly divisible by 3 is a KSet, because you can write it as {1} U {2} U ({3,6,9,...}^{1}) U ({3,6,9} ^ {2}). Where "U" is the union operator, and "^" is the Kevinian Sum.
I'm very keen to discover which kinds of infinite sets are KSets
It's something more complicated than "The only infinite KSets are arithmetic serieses", because "all numbers not divisible by 3" is not an arithmetic series, but it is a KSet.
On the other hand, I suspect it must be simpler than "any series that a turing machine can output, given infinite time and memory". A turing machine can print all the prime numbers, but I don't think the prime numbers are a KSet
Even the set of squares seems out of reach, although I may just be lacking imagination for that one
I thought I had a proof that the powers of two were a KSet, but I seem to have misplaced the cocktail napkin I scribbled it on
The KSum allows to prove that {n} for any n in N is a KSet. {k, n} for any k, n in N is a KSet, because {k, n} = {k} U {n}. You can expand that to {n} U N' where n in N and N' a subset of N.
I guess I need a new definition to properly capture the challenge I'm truly interested in. A "compact KSet" is a KSet that can be constructed using a finite number of steps.
The squares and the primes and all those good sets are all KSets, but I suspect they are not compact KSets.
Since there's only one simple kind of infinite set available in the building blocks of KSets, I wonder if there's some property about it that remains invariant throughout any of the operations you can apply to it. Then if you show that the primes don't satisfy that property, it proves that they can't be a compact KSet.
I'm currently trying an angle of attack like: {x, 2*x, 3*x...} always contains at least one non-prime number. This is still true if you union it with another set.
en.wikipedia.org/wiki/… might be useful here... I'm not quite sure how I'd write it in terms of my system though
en.wikipedia.org/wiki/… gets me pretty close, I think. {x, 2*x, 3*x, ...} has a subset that is an arithmetic progression. If you union it with another set, it still contains an arithmetic progression. If you apply Kevinian Sum to it, it still contains an arithmetic expression.
So all compact infinite KSets contain at least one arithmetic progression. An arithmetic progression always contains at least one composite number. So you can't generate any compact infinite KSet that contains only primes.
Lemma: prove that all arithmetic progressions contain at least one composite number. By definition, an arithmetic progression is expressible as {a, a+d, a+2d, a+3d...} for any constants a and d. For our purposes, a and d are always positive integers. a + ad is a member of the progression, and it is a composite with factors (a, 1+d). □
I'm quite surprised that I figured out primes before I figured out squares. But I bet a similar approach would work.
Perhaps if you can prove that an arithmetic progression can contain at most two positive squares nope, N is an arithmetic progression and it contains all squares. Ignore me.
Maybe "If the first and second elements of a progression are squares, then the third one is not a square"
@Kevin A guy in the Math chat suggests something like "outer product table by addition". That implies that the result preserves the 2D structure of the Cartesian product of the two sets, though.
Reading on quantum computers and qubits I came across the following:
> A classical computer typically approaches a problem by trying out one route, then trying another, and another, until it finds the solution. However, thanks to superposition and entanglement, a quantum computer can simultaneously try all possible routes, meaning it has the ability to process multiple complex calculations
I wish there was a better and more helpful example to understand this. If the state is unknown how is it processing anything at all
There is a great video about this (about an hour long) that finally actually explained it in a way I could understand, and not some hype-hand-wavy stuff. Let me dig it out
My gut says "the computer is capable of processing for the same reason that the cat inside schrodinger's box is capable of thinking". My gut also says this is not a useful explanation. My gut apologizes.
Yeah that's what I'm seeing as well. I fell like I do have some simplcus level understanding of the physics but translating that into mental model of a processor is not easy.
I can sort of understand how one qubit can perform a computation on more than one combination of inputs at the same time. But what I don't understand is why it was always considered newsworthy to publish articles like "stunning six-qubit quantum computer constructed". If going from five to six is revolutionary, then surely you could go from six to twelve just by building more qubits? What are these things made out of, moon rocks?
Are they really big? CERN gets like ten square miles for their collider but we can't spare a couple extra warehouses for the twelve qubit computer team?
FWIW, Peter Shor, who devised Shor's algorithm is a Stack Exchange member. He mostly hangs out on EL&U, but I have interacted with him in comments on Physics a couple of times.
Bruh just make more. Call Elon and tell him they'll make his mars colony 20% cooler, he'll write you a check
Theory: qubits only work properly if you stack them on top of one another, and they keep falling down whenever anyone tries to make a tower of more than 6.
(actual non-joking guess: qubits interfere with one another somehow, so that the inaccuracy of the whole system scales exponentially with the number of qubits)
Every science team needs one dimwitted but ultimately well-meaning jock to occasionally suggest approaches based on metaphors involving football or being prom king
"What if we put a gnarly spiral on those qubits? That always made my game winning passes more accurate" [most important scientist dramatically removes his glasses] "... My God, he's done it"
@MisterMiyagi It definitely is communicated terribly about how "collapse a solution" actually works as a CPU, though. The stuff at the LHC is cutting edge, complicated and exciting, but the communication about it is clear. With Quantum Computing, everyone just talks in the abstract and, frankly, it really does make it seem a fad to me. It's like they think we're all just plebs
So, quantum computing is like the prom, right, where you have, like, all the kiddos dancing and things, y'know, and measurement is, like, saying "folks, Jeff and Carry are prom queen/king".
You can't really tell how much fun your best bro is having until you observe him at the punch line, which is the only place that can maintain any order
The faster the line moves, the harder it is to determine your bro's position
@roganjosh Ah, yeah, comparing a quantum computer to a regular one is a super slippery slope. In a way, Quantum Computer's are incapable of computing anything.
I'm not a physicist but I can buy and follow all the concepts from physics, and then they just leave it there. Well, great, but how is that solving my problem?
But anyway, the guy from Microsoft in the video I posted does a sterling job at explaining it for me, so now I just exist to throw tomatoes at all the other people talking about quantum computing
@Kevin Most of the neutrinos (& antineutrinos) in the universe are moving quite slowly, relative to us. They're the "relic" neutrinos of the CNB, the cosmic neutrino background, which decoupled from the rest of the matter in the universe about 1 second after the Big Bang. They're severely redshifted, so they're now sub-relativistic.
> After the detectors for the project were upgraded in 2012, MINOS refined their initial result and found agreement with the speed of light, with the difference in the arrival time of neutrinos and light of −0.0006% (±0.0012%).
0.9994c, that's practically a casual stroll
I didn't even know particles could go a speed that had a 4 in it
Neutrinos are notoriously bad at interacting with anything, and the slower they are, the smaller is their interaction cross-section. So we might never be able to directly detect the CNB neutrinos. But they get included in cosmological calculations of the energy content of the observable universe.
At ultra-relativistic speeds, we don't bother talking about velocities. Numbers like 0.9994c are just for pop-sci articles. It's more convenient to just talk in terms of energy, or the Lorentz gamma factor, where gamma = 1 / sqrt(1 - v^2/c^2). Eg, something travelling at sqrt(3/4)c has a gamma of 2, which means its kinetic energy equals its rest mass.
Our current best neutrino detectors can't see neutrinos below ~233 keV, which means their gamma is around a million. And even then, we only detect around 1 per billion that pass through the detector.
Is there a standard for what speeds (and/or speed-related measurements) count as "ultrarelativistic", or is it more a subjective thing like "if it's less of a pain in the butt to describe using gamma rather than velocity, it's ultrarelativistic"
Wikipedia says something like "if you pretend the particle has zero rest mass, and your calculations still give you useful results, it's ultrarelativistic"
We're still not quite sure what the neutrino rest mass is, partly because it's so tiny relative to the KE of the neutrinos we can detect. And partly because neutrinos change their flavor.
Because of quantum, a neutrino in a pure flavor state is in a mixed mass state, and conversely, a neutrino in a pure mass state is in a mixed flavor state.
I imagine we can't just plug their velocity into some lorentzy formulas and get their rest mass out, considering our measurements don't rule out a velocity of (1 + a bit)*c
"Says here they have a mass of negative one nanogram. Hmm."
To do that, we need to be able to measure their KE and their velocity with sufficient precision. People are working on that, so our numbers are getting better. Slowly.
Our great grandchildren are going to have some seriously good image quality on their neutrino powered televisions
"When the neutrino ray tube strikes the quantum phosphor array, it emits a superpositioned photon whose wavelength depends on the observer. That's how the same qixel can look red to your left eye, and blue to your right"
For the past decade or so, a group has been claiming that radioactive decay rates are affected by changes in the neutrino flux from the Sun. The concept is plausible, but any such effects should be far smaller than this group claims. Nobody can reproduce their results, and most experts dismiss their claims as due to bad experimental technique. But they keep publishing papers... Young Earth Creationists love them, because they think it invalidates radioactive dating techniques.
I had a course on cv2 and python, I did the first quarter and then due to some exams stopped, then took again, did the first quarter again and while that was over again some exams, so stopped. Now I feel like I should do it again :P
Totally off topic, feel free to ignore: if you respond to conservation in MS Teams and don't '@' anyone do the participants get a notification or might the comment just sit there until someone happens upon it?
MS Teams === theWorst (and yeah, the triple = was deliberate)
I've had calls where everyone can see me and yet I'm irrevocably muted, so they see me have a mini meltdown trying to find the options to rectify the mess, throw my hands up in despair and just leave the meeting
Fantastic with client relations and I'm supposed to be building them cutting-edge tech products. Oh well
Guesstimate, it's at least 50% of meetings where someone can't see the slides or can't speak, or speaks but can't see the other people in the room (because they're still in the lobby, somehow). What a mess.
I had a glitch in a talk the other day on a Teams meeting but it was my brain that glitched. Awkward 60 seconds to say the least. I feel your pain @roganjosh Oh well that was one out of 40 minutes. The rest was good
That's part of the problem with Google. Everything works so well the world became dependent. I try to stay away. Except for Tensorflow and YouTube and .... oh well
@CoolCloud I'm truly amazed by that. I wasn't even exaggerating on my guesstimate. We just have to use MS Teams because they do, and it's a horror show, We often lose 2-3 mins from the start just to actually get people into a functioning position to actually have a meeting
Though, the rest of us fill the time with weird anecdotes, I guess
Other schools nearby uses zoom and I hear them complaining about stuff like these. With Teams its been nearly perfect for us, to get Teams is one of the good decisions the school has taken(surprisingly).
yams! random.choices(...) is running faster in the repl, but slower in prod code, than random.choice(list(itertools.chain.from_iterable([k]*v for k,v in my_frequency_counts.items()))) </rant>
@roganjosh I have a dict: {'a':4, 'b':3, 'c':2}. I want to turn this into effectively random.choice('aaaabbbcc'). That second option expands out the keys of the dict into a list (at least, it does in my sourcecode - I wrote it here correctly)
@inspectorG4dget FWIW for most random generation, I just call into np.random.choice for the max number of iterations I want to try, and so be it if my search algo terminates early. Still quicker
For example, if I want to do something with simulated annealing, I can just create the whole 10k values of temperature and 10k values of random rolls in 1 go
If it converges in 5k iterations, cool. I still won on runtime
I'll need one more piece to be able to use np.random.choice - it requires that my weights sum to 1, for which I'll need to rescale (I simulate a number of days, and on each day, I'll have to choose from the available options). I fear that repeated rescaling would cost me too much
@TheShortestMustacheTheorem first, you need to read the room rules about code blocks that large. Second, read your own question back again to yourself. "from the measured one" err, from where? "Who can figure out" not a fun challenge