company can't be arsed to tackle the actual, substantial problems with the platform, so they keep doing pointless bikeshed work to pretend they are engaged
Reading a paper about how to balance this particular form of binary tree, and everything is explained in terms of Haskell code... https://yoichihirai.com/bst.pdf
I know the very basics of Haskell, but that's not enough to decipher this paper. Might as well have picked brainfuck...
No but seriously, I'd be happy to do that if it's not for the whole paper! - I think there are just a few things you really need to know to understand everything in there. If you're stuck at a specific snippet I could try to break it down and you could see if it helps or not:)
I guess the types and signatures might be a source of confusion?
But don't feel like you have to, I'm just excited to see Haskell, and I'd be happy to if I could pay back even a little bit of all the help you've given me
@AndrasDeak--СлаваУкраїні It's obviously written by a computer scientist, not a mathematician. There's no lemmas and no proofs. There are actually no equations. And it's readable.
Also, the name of the journal (it just says "JFP" in the PDF) turns out to be "Journal of Functional Programming". That explains the Haskell code in it.
Not a whole lot of meta programming, but it certainly is a template, because I need to process images of any data type. It's only the value stored in the tree that uses a templated type, the rest is plain old imperative programming. Oh, the tree is a class, can't get around that one...
There’s a fast algorithm for 8-bit images where you make a histogram of the pixel values within the window, as a quick way to find the median, and then as you move the window, you update the histogram (remove some pixels, add some pixels).
But that is not generic, it doesn’t work well for 16-bit images any more. So I’m using a binary tree to hold these values. Each node also holds the size of the subtree, which makes finding any percentile quick (log(n)).
So now this is fast for any data type, including floating-point.
I'm trying to convert the following code from matlab to c++
function data = process(data)
data = medfilt2(data, [7 7], 'symmetric');
mask = fspecial('gaussian', [35 35], 12);
data = imfilter(data, mask, 'replicate', 'same');
maximum = max(data(:));
data = 1 ./ ( data/maximum ...
So when you have a kernel/structuring element and move it from one position to the next, there are the "front facing" pixels that get added, and the "rear facing" pixels that get removed, right? Does that mean you analyze the shape of the kernels first?
The kernel gets decomposed into lines along the direction where you move the kernel. For each line I just encode the offset (start point) and the length.
@AndrasDeak--СлаваУкраїні advent of code is neat, but I get bored quickly because it’s a toy problem, not an actual problem whose solution will make something in my life better. :)
But right now I’m collecting timing data for number of pixels vs number of lines in the kernel, and whether the direct or the tree-based method is more efficient.
Asking about infinite structures is always entertaining when talking to computer scientists - I remember sitting in a (cs) graph theory course with another math student which was the first course of said lecturer, and I think he didn't enjoy our questions about graphs with an uncountable amount of nodes as much as we did.
@AndrasDeak--СлаваУкраїні I ran the timing on Python, then copy-pasted the values into MATLAB to make the plot. It's just faster for me that way. One day I'll learn to do plots in Python.
@AndrasDeak--СлаваУкраїні I do use Eigen for some things (a C++ linear algebra library). But I don't think Eigen uses BLAS or LAPACK. Maybe optionally? No idea!
I'm happy with the plot I've got. Even if it's not identical for other systems, it'll be close enough. It's not that important to squeeze 100% out of everything. Picking the wrong algorithm near the threshold is not going to make a whole lot of difference. It's the 3x or 4x difference for very small or very large kernels where it matters.
@AndrasDeak--СлаваУкраїні I just realized you could put whole expressions into decorators in python!
from functools import partial, reduce
@lambda f: partial(reduce, f)
def binary_plus(x, y): # not actually binary with the decorator
return x + y
print(binary_plus([12, 14, 3, 15, 7]))
This let's you write a whole lot of new confusing stuff!