If I declare some variable, as you note, it's live until the end of the block the let statement is in. If I create a reference, it's lifetime is necessarily constrained to that block. The issue arises if, I do something like this:
Rust has an RFC related to non-lexical lifetimes which has been approved to be implemented in the language for a long time. Recently, Rust's support of this feature has improved a lot and is considered complete.
My question is: what exactly is a non-lexical lifetime?
Yes then what is the real benefit of allowing them ? @Shepmaster Yes but since I am just starting out with Rust most of the code did not make much sense.
@ng.newbie Let's flip the script — can you an example of where NLL has caused you confusion?
In other words, why is this sentence wrong:
> A wonderful thing about non-lexical lifetimes is that once enabled, no one will ever think about them. It will simply become "what Rust does" and things will (hopefully) just work.
let a = 36i32;
let b = &a;
read_intref(b);
add_one(a); //Without NLL, invalid - a is borrowed by b, which is still a live borrow
read_intref(b); //With NLL, invalid - b's lifetime is cut short of it's lexical scope, because it's referent, a is used.
@Zarenor Ok so just correct me if I am wrong: I cannot do read_intref(b); twice because I am mutating a after the first read_intref(b); correct ? So once I mutate `a` the previous reference goes out of scope. Am I correct ?
That's the idea. I'm actually subtly wrong - I put it in the playground - and the borrow is actually extended to the next use of b, making that usage of a still invalid.
But without NLL, the first example would be invalid. Because the borrow b would live until the end of the lexical scope
I'm reading through The Rust Programming Language and have encountered this notation: 0u8.
#![allow(unused_variables)]
fn main() {
let some_u8_value = 0u8;
match some_u8_value {
1 => println!("one"),
3 => println!("three"),
5 => println!("five"),
7 => pri...
If you read the RFC text I linked, they progress through increasingly complicated examples - the more complicated, less contrived examples are the real motivators here - like the one Shep mentioned, where you couldn't retrieve from a map, and store to it.
@ng.newbie it's not a stupid question, but I'm still confused why you are asking it in the first place. I'd still like to know how/why you learned about NLL in the first place and decided to concentrate on it.
As mentioned, NLL basically allows code that was actually safe but the compiler was previously too dumb to realize it.
@ng.newbie It didn't work because there was a mutable reference and an immutable reference in the same lexical scope, and that was disallowed
> As Rust evaluates arguments left to right, that code is equivalent to this:
let arg1 = &mut n; let arg2 = n.get() + 1; Number::set(arg1, arg2);
@Shepmaster Great. I learned about NLL through absolute accident. I ended up writing code from the book with 2 mutable references but forgot to put the println, since I had NLL it actually compiled. Which is what baffled me, since the book said the code was not going to compile. What is irritating me is that Rust only stops me when I use the declared variable and not while declaring them.
@ng.newbie well, the desugaring was not 100% accurate, but that doesn't mean that the original problem wasn't solved by NLL. Just that the original was more subtle.
@ng.newbie There's no problem with the code until you use it.
Similarly, we'd normally say that "Rust doesn't allow uninitialized variables"
but this compiles with no errors:
fn main() {
let foo: String;
}
Because we never make use of the uninitialized variable
There is a warning about an unused variable, though :-)
I would like to return some strings to C via a Rust FFI call. I also would like to ensure they're cleaned up properly.
I'm creating the strings on the Rust side and turning them into an address of an array of strings.
use core::mem;
use std::ffi::CString;
#[no_mangle]
pub extern "C" fn drop_r...
@Shepmaster @Zarenor Thanks for all your help. I guess I have got my head around some of the ways the borrow checker works but I still have a long way to go. I will be back here asking my noob questions soon enough.
I am just amazed the compiler is now generating the entire control flow graph and checking if the borrows are valid are not. makes implementing a Rust compiler a whole lot harder compared to Java or Python
I am learning operator overloading for my own types. like example below i am implementing the add trait from standard library for my own Point type.
impl Add<Point> for Point{
type Output=Point;
fn add(self, point:Point)->Self::Output{
Point{
x:self.x+...