I was in California during the burning man season. Dude, I was burning just under the sun, no desire to see any burning man. All I wanted to do was cooling down in a pool, having an ice cold drink.
On the other hand, I am totally into this winter camping surviving thing - I watched countless videos on how to surviving multi-days in the wildness when everything else is covered by a foot deep snow.
@Rick No, it's where you surviving alone in the harsh wild environment. As a consequence, you toughen up and get to show contempt towards lesser beings at appropriate times.
People playing Sudoku are just relaxing with a game, not solving constraint satisfaction problems, although bad analysts may not recognize the difference.
I made what I thought was an improvement to the code but found it actually resulted in the program taking longer to complete. Is the array operator [] much more expensive to use compared to arithmetic?
in C#, there is a feature which is a multi-dimensional array for example new object[100, 100]
iterating through the entire array using a fori loop (for (int i = 0; i < arr.length; i++) (but then with 2 nested loops) is a considerable loss in performance
because in the background, it is one big array, and the index is y * xLength + x and that gets evaluated for every iteration
Msvc performs no auto vectorization on unsigned short types, resulting in a 30%+ loss in performance compared to gcc/ICC. In my codes I have to do those paths manually.
I think if you did more real-time processing you'd run into this stuff. That being said, unless it's the internal image processing steps, most fixes to the gui are order of algorithm changes.
Lots of my stuff is real-time processing. I need to process like 100k events per second and generate a visualization every frame for the current state. But it turns out CPUs are really really fast and 100k events is nothing, even if you run expensive algorithms on them.
all sorting algorithms should be - Unless, of course you want to sort by array index :) I can optimize the hell out of any sorting algorithm that is value-independent
What is your understanding of value-independent? Any comparison-based sorting algorithm is value-independent because you don't get access to any values.
@sehe With the comparison function that you are provided with. Some algorithms like quicksort and mergesort can work with that, others like counting sort cannot.
The difference is whether all you have is an operator < to compare elements, or if you can access their value and can for example use the value of an element as an array index.
@Morwenn I was thinking of that immediately. Many of timing-invariant algorithms have the same properties (and no, just padding with a delay often does not do the job, e.g. with side channels)
And sorting network can theoretically offer that kind of advantage, but it's probably easier if they're implemented directly in hardware
I tried to implement the compare & swap for integers in a data-agnostic way and still have differences in benchmark when using the sorting network on shuffled vs. sorted values
@Morwenn IIRC it boils down to having the width of the simd vectors be queryable at runtime and you can then use that to adjust the pointer increment between loops and such
@Morwenn just curious, in what sense? I know that the evolution working group has at some point talked about something to allow for proper abstraction of GPUs etc
Some classes even define their operators as free friend functions inside the class to make sure that they can only be found through ADL and without random implicit conversions
Doesn't work when the objects are not pure Python objects :(
I had to make a function that took a type and returned a type derived from it at some point because I had to avoid multiple inheritance and Python doesn't have templates
class SomeClass(augment_some_type(ParentClass)): ...
where SomeClass actually derived from a type deriving from ParentClass