I mean, surely may be some aversion to "why is this Rust code slower than this one in Whatever", but if they don't even bother making a proper MRE, it's pointless.
> Edit: It was definitely the BigUint that was slowing the whole thing down. Without using BigUint the program finishes in under 2 seconds. Sorry for the confusion I caused.
@Stargateur congratulations on the effort of writing random digits after user :P
unrelatingly, I'm really hyped about this pot-au-feu of beef slow-cooked with stout beer I made yesterday, and I really need to ventilate my emotions. it's really good.
This one's an Intel Core i7-6700HQ @ 2.60 GHz 2.60 GHz, running directly on Windows.
I did change the code a bit to just make it print to stdout instead, then piped it to a file when calling. Not sure how much that would affect the times.
Edit:
It was definitely the BigUint that was slowing the whole thing down. Without using BigUint the program finishes in under 2 seconds.
Sorry for the confusion I caused.
I wrote this prime finding algorithm to compare the speed of Rust and Python. The Rust program runs slower than the equivalen...
Looking at the code right now. This is super weird, no? The maximum number that is dealt with here fits in u32. And the code uses bigints, u128 and f64 to represent all of that. What. Or am I missing something?
I often show people how to write a primality test in Rust with iterators. Just to show off what's possible. E.g. (2..n).all(|d| n % d != 0). But if there was a integer sqrt, that would mean a decently fast version would still be very short and without ugly as casts.
I don't quite know what would make a fast and accurate implementation. If it still involves converting to a float and back, this could hide some heavy ops.
@LukasKalbertodt I used the following some time ago
fn is_prime(n: u64) -> bool {
match n {
_ if n < 2 => false,
_ if n < 4 => true,
_ if n % 2 == 0 || n % 3 == 0 => false,
_ => (5..=(n as f64).sqrt() as u64)
.step_by(6)
.all(|i| n % i != 0 && n % (i + 2) != 0),
}
}
> A much beloved and widely used example showing the elegance and simplicity of lazyfunctional programming represents itself as “The Sieve of Eratosthenes”. This paper showsthat this example isnotthe sieve, and presents an implementation that actually is.
As I mentioned last month, the next step in the Outdated Answers initiative is an exercise for flagging outdated answers. Starting today, you may see temporary prompts on Stack Overflow that ask if an answer is outdated.
The prompts have a chance to appear when the accepted answer is at least 60 ...