Unfortunately not. But I try to work on it a few hours every week in my spare time. I think that having an easy and free crate registry is crucial for the adaption of Rust in the commercial space. Companies don't want to share their code publicly on crates.io. My full time job is in the IT security sector. My hope is that by pushing Rust as a safe language, we can close some fundamental design flaws that languages like C/C++ introduced and make software landscape more secure.
Been working through Andrej Karpathy's ML lectures in Rust. The backprop one went pretty well, but I had to learn how to do type indirection and interior mutabilty because of the backprop graph structure. I'm now on the makemore lecture, but having a lot of trouble building the bi-gram model in Burn (the rust native ML framework), because it seems like directly incrementing the tensor values is insanely slow. His example that takes like 10 seconds to run in Python takes two and a half minutes in Rust with Burn, so trying to figure out how to optimize or speed that up.
So far I have only really scratch built backprop. And had severe performance problems with Burn trying to do something it probably wasn't built to do. Once I get further in makemore I should have a better idea.
More progress on the Finite Projective Plane (incidence matrix) generation from last week. There already exists an algorithm to generate boards of order p+1 where p is prime. It is stateless, so with CUDA we can generate huge boards in seconds since all you need is the x, y position and board size. 258x258 under 3s!
However, p+1 isn't the only sequence. It seems by our observations that the fermat numbers also generate valid boards, using our "naïve" algorithm.
Unfortunately 3x3, 5x5, and 17x17 might not contain all the nuggets of generality to find a nice algorithm like the p+1, so we're gonna generate the next up: 257x257. We've been improving the naïve algorithm since it is too slow. (The resulting image would be 65793x65793)
Rather than allocating the 2d boolean grid, we represent where the true elements would be using row and column indexes. This is okay because of the constraint which limits how many true elements can be in a row/column
benefit 1 — less memory usage: "O(2n)" vs O(n²) ((for 257x257: 129MiB vs 4GiB))
benefit 2 — faster column-major lookups (flamegraph spent a lot of time sitting in iterators)
overall speedup: about 2.7x
Speed up index lookup with binary search
The index list is sorted by nature. To exhaustively check a dot is valid, it checks n² spots in 2 lists of size n. Slightly more expensive than the grid given the 2 index lists. Rather than slice::contains, use slice::binary_search(...).is_ok()
overall speedup: about 2.1x
Next steps:
Assume a square grid and exploit its diagonal symmetry to treat row lookups as column lookups
Use multi threading to gain a partial speedup
Essentially if row 1 is 50% completed, row 2 can be up to 50% completed.
I think you get different speeds depending whether the threads and symmetry folds are both row/column major or one is row-major and the other is column-major. My gut says both need to be aligned because there's less waiting involved.
The first index of each index array can be filled by a function. For 257x257 that would remove 8,487,169 checks out of... 2,164,392,321. Not much, but it's basically a free optimization, so might as well!