@12944qwerty it's useful as unless told otherwise it will automatically add a new line for you so you don't have to remember to do f.write(some_string + '\n').... and you don't have to worry about converting to str, so you could do something like: print(*[1, 'bob', 3.14], file=f) and you'll get 1 bob 3.14\n written

I got the logic without 'parsing' to work, but it has some bugs. It works all perfect when you press equals after each result. Chaining wont work. pastebin.com/AQhhMPni

Still lots of pending work, to fix the floats and so on

But even if you don't, bind the two function calls I mentioned once at the top to some meaningful names. Calling those get methods each time is both inefficient (well, technically) and clutters up your code.

I already told you this once so next time you do this I'll just make snarky remarks

I have been working on a project that involves downloading files. I have been tasked to create a report of how many downloads per file. Here is my code:
reports.py
def dataset_download(request):
download = DataSet.objects.annotate(numdownload=Count('name'),)
return render(reques...

@duhaime I executed some commands on the container and saw that the font is there through the container's CLI (using fc-list). I notice that if I manually change the font family name con the SVG xml from "Druk-WideSuper" to "Druk Wide Super" (as the font family name shows up through the CLI) it works and the text is preserved when doing the conversion. But don't understand why this happens since when I run the script locally without modifying the SVG font family name it works.

But that was a manual attempt to see if works, still figuring out how to unblock this

@NIKHILCHANDRAROY Same way you call any object method. If you have a DataSet instance named foobar, then do foobar.increment_numdownload()

@AndrasDeak Really it's just a coincidental overlap of terminology, I think. I was trying to express a line in 2d space as the equation P(t) = U*t + V*(1-t), for vector U and V and scalar t. If you imagine t as time, then P is like a particle that passes through V at t=0, and V at t=1. I wondered whether I could plug in a point that P doesn't pass through, and solve for t. I suspect the result would be an imaginary number.

TLDR: I invented imaginary time, but it already exists in special relativity and quantum mechanics.

t = P-V/(U-V) is tricky to solve in the general case since division isn't defined for vectors. But it is defined for complex numbers*, so maybe you can do some isomorphism handwaving and get a meaningful numerical result anyway.

(*this difference is confusing to me, because prior to an hour ago, I thought 2d vectors and complex numbers were essentially just different names for the same concept)

Here's what I've patched together from google and guessing. One of the useful features of vectors is that all(?) of its operators are invariant with respect to both rotation and scale. complex multiplication is neither, so adopting it would mean giving up some very nice qualities for a not very useful operation.

Or perhaps it's a bit judgy to call it "not very useful", for the same reason you shouldn't yell at a screwdriver for being bad at pounding in nails.

And "scalar multiplication" involves a scalar and a vector. Dot product involves two vectors but the result is not a vector. So from that list only addition is similar to complex multiplication.

I bet using a tessellating equilateral triangle pattern is optimal if you have exactly enough points to fill the hexagon. I don't know what you would do for Ns that don't satisfy that requirement

Hi All, Sorry for interrupting between you people I am learning machine learning and recently tried cnn for digit recognition and I tried my model on real time images as said in this article https://yash-kukreja-98.medium.com/recognizing-handwritten-digits-in-real-life-images-using-cnn-3b48a9ae5e3

but the problem is at last I am not getting the ouput of images in the order which was given for ex: if image is 0 5 2 2 and it is predicting correctly but getting o/p as 0 2 5 -- can anyone help me

Looks like _, contours, _ = cv2.findContours(thresh.copy(), cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE) is responsible for separating the digits in the source image into individual digit images. I wonder if it's possible to sort the contours collection based on an x coordinate of its bounding box.

Something like contours.sort(key=lambda c: cv2.boundingRect(c)[0])

Disclaimer: this will probably only give nice results if you're sure the source image has exactly one horizontal line of digits. A lined notebook page full of numbers will still give you haphazardly ordered results.

If you're saying "where in my code should I put contours.sort(key=lambda c: cv2.boundingRect(c)[0])?", try putting it right after _, contours, _ = cv2.findContours(thresh.copy(), cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)

Can't you just copy-paste that guy's Sinkhorn function definition?

... after verifying that there are no licensing concerns of course? <_<

Currently squinting at en.wikipedia.org/wiki/Sinkhorn%27s_theorem trying to figure out how diagonal matrix pairs give you cool springy dots. I think I'm missing about three layers of abstraction.

Now that I've shaved a yak or two, I can look at formalizing my idea about vector spaces... Aaaaand I've just noticed that dot product and scalar projection are two different things. Well, that only doubles my workload...

cbg guys, I have a quick question, does inserting at the end of a list using seq.insert(len(seq), 'foo') also take O(n) or does it work like seq.append - O(1) for a special case? wiki.python.org/moin/TimeComplexity shows its linear for all

I agree with the wiki's analysis that it is O(N) in the average case and O(N) in the amortized worst case. In other words, it's O(N) if you're inserting to the middle of the list or the beginning of the list. AFAICT it has no comment on its best case scenario, when you insert at the end of the list.

TLDR: inserting on the end is O(1) unless list.resize hits a caching hiccup or something

append can also hit the same caching hiccup in the same kinds of situations, so I'll be bold and say they're equally efficient

You can ignore a lot of the boilerplate, since most big O analysis only requires you to look at the structure of loops. But in any case here is a moderately faithful translation into Python.

None in Python is a real object that takes up space in memory, and has attributes, and a type, and all that good stuff. null is a special value indicating that a pointer or reference does not refer to a valid object. It's hard to explain in terms of Python because Python does not have a native concept of "pointer" or "reference" in the same way C does

I am guessing this will probably be covered if I watch a basic C tutorial, I did learn C but it was in high school, pointers was an "optional component" you can skip and still clear the course

It's all rather academic anyway since you can't get your hands on null in Python unless you're doing cool stuff with the C API. And if you are, then hopefully you know enough C to know what null is.

A basic C tutorial would probably give you an understanding of the practical uses of null. It might gloss over the gritty theoretical bits until you get to intermediate tutorials.

@Kevin I haven't watched the play yet... but ummm... thinking this is going to be a horrible set of cards to play against: youtube.com/watch?v=mI57LfwUono