I'm solving a little math problem called the Syracuse problem (3n+1 problem).

Thing is i want my function to work for 2 types, one is u64 the other is a struct that extends the size of u64 by containing 2 u64 that i called U128.

my u64 function looks like this

fn syracuse(n: u64) -> u64 {
    match n % 2 {
        0 => n / 2,
        1 => 3 * n + 1,
        _ => 1,

I've tried implementing a trait to my U128 and u64.

fn syracuse<T>(n: T) -> T where T : Add +Mul+Div+Rem + Basic0123 {
    match n % Basic0123::two() {
        Basic0123::zero() => n / Basic0123::two(),
        Basic0123::one() => Basic0123::three() * n + Basic0123::one(),
        _ => Basic0123::one(),

It doesn't compile, the pattern matching doesn't like this. I'm new to rust and i'm trying to understand if creating a function with generic typing is okay for this problem that only treats 2 different types the DRY way or i should just stick with simply rewriting the function for the U128 type?

  • We're going to need more code than this. We don't have the definition of Basic0123, let alone its implementation; we don't have the definition of that U128 type of yours, you haven't even told us what the error actually is! – Sébastien Renauld Sep 15 '19 at 11:29
  • If you would like some concrete help, please create a MCVE using the Rust playground replicating your problem. This isn't just for clarity, a ton of problems get solved by changing the context of code from the problem you're facing, to a simplified version of the same problem – Sébastien Renauld Sep 15 '19 at 11:30
  • 3
    Finally, I'm not entirely sure why you implemented a U128 yourself since it exists in std since rust 1.26 – Sébastien Renauld Sep 15 '19 at 11:39
  • I didn't know u128 existsed in the std. I'm quite new to rust and stack overflow, i take note to the lack of informations and will do my best the next time i ask a question. :) – Youness Kafia Sep 15 '19 at 13:44
  • It wasn't meant as a telling-off, just as pointers to let people help you faster and more effectively :-) for the integer types (and others), they're all under data types. The main caveat is that pretty much everything exists up to 128-bit size except floats, for IEEE-related reasons – Sébastien Renauld Sep 15 '19 at 13:46

I'm just going to assume most of the stuff in the comments has been dealt with and you're back to using the std::u128 primitive type rather than your own.

The proper way to implement the Syracuse conjecture on a generic type is as follows:

fn syracuse<T>(n: T) -> T
    where T : Copy + Eq + Add<Output = T> + Mul<Output = T> + Div<Output = T> + Rem<Output = T> + From<u32> {

    let zero:T = 0.into();
    match n % 2.into() == zero {
        true => n/(2.into()),
        false => n * (3.into()) + 1.into()

In order of appearance:

  • Copy is required because we did not require Rem on &T, but on T
  • All the Output type specifications are so we do not implicitly change type - an operation on T will always map to T
  • We are requiring Eq so we can compare the result of the remainder
  • We are requiring From<u32> so we can into() every single numerical constant

A working version can be found here

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