Everything I'm reading about it seems like a windows issue. I don't really have experience with Docker on windows so I'm probably not the best person to help
I dont have any books, i was given a website and my teacher is basically making me self teach myself in the middle of the program, ive asked for help and hes a dcad teacher i dont think he really knows much of cs himself. — Cody Phillips39 secs ago
@coldspeed there's no easy way? :/ I know json won't support this unless I base64 encode this. I'm pretty sure yaml will complain too, but I'm reluctant to bring out a whole another beast just to handle this
I don't know what "relational binary blobs" means. You could just save the repr of those bytes strings, but the base64 version will generally be more compact. How big are these blobs, on average? Do they have any human-readable content, or other structure?
Do you mean the JSON output will get LZMA compressed? I guess that's fine, although you'd get better compression by compressing the binary data before it's converted to base64.
@coldspeed Ironically, "too broad" can work, if they haven't posted an attempt, or an outline of an attempt. But if it's a giant code dump without a clear explanation of what it does that's wrong, then it's "unclear".
@Aran-Fey this is for deep learning model applications. Lots of hip new papers/frameworks use this for distributed training on large RDDs for convnet architectures
yes you can technically stream multipart data, but both ways are equally "idiomatic"
Now whenever I say something is something, I will get disagreements, but I am speaking purely from ethos
@OneRaynyDay I've just been browsing the Numpy / SciPy docs, learning about .npz & .npy. I see that there's scipy.sparse.save_npz for saving sparse arrays, and it has a compression option. That ought to give you much better compression than plain numpy.savez_compressed.
OTOH, if you're going to LZMA-compress the final JSON anyway it's probably better to use scipy.sparse.save_npz in uncompressed mode. It'll be faster, and using 2 similar compression algorithms (like zip & LZMA) on the same data is rarely worthwhile.
I recommend using nested dicts to cache your alertfile and eventfile pairs. Since a folder may or may not contain the file pairs, when it does, it should use the '.' key to store a dict of the file pairs in this folder, like this:
cache = {
'.': {'alertfile': 'alert content', 'eventfile': 'e...
@AndrasDeak "you may expect numpy.int(3) to give you a numpy int" I certainly did. I assumed it was a C int, that is an int of the native machine word size. I didn't suspect that it was an alias for Python int. Coincidentally, I used it recently in my fern generator. That was the 1st time I'd used it though, I normally use an int with the size in its name.
@overexchange This is a fresh question... but I guess you're asking about the answer. A nested dict lets you search the directory tree structure. If you don't need that, then use a flat dict, or even just a list of paths. And instead of storing the paths in string form you could use the Path object from the pathlib module.
Edited the code in an old answer of mine from x = 0; while True: ... x += 1 to for x in itertools.count(): but I suspect this will reduce its upvoteworthiness because the less clueful readers will not know what it does
I could explain what it does, but I don't want to.
Maybe it will be a wash because half of the less clueful readers will think "gee this code must be real good because I don't understand it, here's an upvote"
The important thing is that the reader can copy-paste the code and it will do the needful. The specifics aren't all that important.
I remember once when someone posted a hard-to-understand recursive code for something and I posted what I thought was a clearer iterative version, but recursive guy got all the upboats. :-(
Irritated that first comment got two upvotes despite being syntactically and logically incorrect
>>> file = "charged"
>>> not file.startswith('hydrophobic') or not file.startswith('charged')
True
>>> file = "hydrophobic"
>>> not file.startswith('hydrophobic') or not file.startswith('charged')
True
>>> file = "coconuts"
>>> not file.startswith('hydrophobic') or not file.startswith('charged')
True
Should I write a Unit Test or try/catch block for every bug/error I find and fix? This question is probably not worth making an actual thread on SO for, but it's something that bugs me a bit
a lot of the bugs I find in my code are things I can just... fix. (For example, I just ran into a bug where a field was a smallint, and the value in said field went over the allowed limit)
(The fix is just to change it from a smallint to regular int.; I did not realize the value could go so high)
Is it worth writing a unit test for this error, even though I fixed it? Or putting the offending bit of code in a try/catch block?
I don't really know when to use unit tests
because all of the offending bits of code seem to be pretty well fixable
This (bad structure, I mean) just happened to me yesterday -- I was having to mock out too many things because a function was both doing calculations and requesting data. Eventually I realized it was time to separate things more cleanly, and now both code and tests are in better shape.
so when there are a lot of things that can go wrong with something that's relatively simple, does one write a unit test for all of them? consider this smallint example: in the future, it could be the case that this integer even goes beyond my increased limits (though I think this is unlikely), so I will write a test for that
but what about cases where the thing returned isn't an integer? (and other such permutations of "this could go wrong")
The module I'm looking at right now has about 400 lines of code and has 716 lines of tests, because it's very, very important that it get the numbers right. In other cases, I just do a simple sanity check on output values.
ok, good. it is good to know that the thing that i saw as a problem is not a problem (unit tests being relatively large), but just the way things work. That actually helps me a lot
thanks @Kevin @DSM :)
this helps put me in the right mindset for testing
(sorry to be kind of obtuse; i've had a lot of coding experience, but i've never dealt w/ unit testing before)
Remember thought, we don't write tests for the sake of writing tests, we write tests to make sure the code does what it's supposed to. The nature and depth of tests we write should scale with the nature of the problem we're working with.
what if i'm interacting with, say, an outside server/code-that-i-have-nothing-to-do-with. do i write unit tests to ensure the response from said server is appropriate (so, said tests would fail if something goes bunk on the other side?)
or do i restrict them as much as possible to dealings within my own code?
A unit test typically tests a function in isolation. Testing whether you're successfully interacting with an outside service is often called an "integration" test.
Again, it depends. If your code is well-separated and mostly side effect-free, sometimes 'testing' a function is just designing a list of inputs and outputs to handle standard and corner cases.
So I'm pretty sure PIL image instances only compare equal to themselves, and this bothers me
Browsing around SO I see a couple approaches for determining whether two images contain the exact same pixel data, but most of it requires iterating completely over both images
Which seems wasteful if you'd prefer to bail out as soon as you find a mismatch
I wrote my own terminate-as-early-as-possible algorithm but it calls .load() on both images at the beginning so I'm pretty sure it's still doing a complete pass on the backend
This has been complaining corner with your designated complainer, Kevin
from .umath import *
from .numerictypes import *
from . import fromnumeric
from .fromnumeric import *
from . import arrayprint
from .arrayprint import *
extend_all(fromnumeric)
extend_all(umath)
extend_all(numerictypes)
extend_all(arrayprint)
it may be due to the extend_all which needs to have been defined before the extend_all calls before which the star imports must have had happened. Then again they may have put the whole thing on top complete with function def and star imports, I don't have enough python knowledge to tell
@Kevin really really interesting footage of a huge crab predating on an ophiuroid (brittle star) from last night's Okeanos feed youtu.be/z90J89qa26Q?t=28m25s
Interesting that reversed objects aren't subscriptable.
Oh, I was going to say "... Since the argument to reversed must support subscripting" but actually it can be a sequence or an object that implements __reversed__
I guess that makes sense if you've got a collection object that has worse-than-O(1) indexing, like collections.deque
And which has O(N) iteration from either end. So... basically just deque.
Yes they did, it's just that "people" meant "your parents / grandma" and it was in the form of fwd: fwd: FWD: fwd: RE: fwd: re: fwd: SOO FUNNYYY!!!!!!111!!
Anyone else dislike mixing text and code with f-strings like print(f"The acronym for your phrase is {acronym(words)}.")? It took me a second to figure out that there's a function call in that line (in addition to the print call)
Would've been more readable as print("The acronym for your phrase is {}.".format(acronym(words)) IMO
Well, f-strings let you mix code and text, so you better get used to it. ;) OTOH, I agree that it can make it hard to read, so I prefer to put long leading or trailing text outside the f-string. So print('start', f'{thing}', 'stop') rather than print(f'start {thing} stop')
@Kevin Reading general PDFs is a lot harder than writing a single image as a PDF, which just needs a little bit of wrapping around an embedded image file. However, reading PDF is easier than reading PostScript, since you need a full PostScript language interpreter for that.
That's partly why PDF was invented: it's a simplified version of PostScript that's not a full Turing-complete language, and it makes no attempt to be human-readable.