24

From the doc it says:

pub fn new(x: T) -> Box<T>

Allocates memory on the heap and then places x into it.

But "place" is a tricky word. If we write

let arr_boxed = Box::new([0;1000]);

Will the [0;1000] be initialized on the heap in-place?

If we write

let arr = [0;1000];
let arr_boxed = Box::new(arr);

Will the compiler be smart enough to initialize the [0;1000] on the heap in the first place?

0

1 Answer 1

23

Will Box::new() make a copy from stack to heap?

Sometimes. The Rust language does not guarantee this optimization to happen, and seems to leave it up to LLVM to figure this out. Because of this, it doesn't matter at all if you initialize the array first and then pass it, as that is essentially the same thing for the backend.

In practice, performance will depend on the case. The example you gave is actually special, because the data is all zeroes:

pub fn foo() -> Box<[i32; 1000]> {
    return Box::new([0; 1000]);
}

In my testing, the compiler was able to turn that into an allocation + a call to memset on the heap data.

Note: only with optimizations turned on though. In debug mode it will copy.


On the other hand, you might want to initialize your data with a known value:

pub fn bar(v: i32) -> Box<[i32; 1000]> {
    return Box::new([v; 1000]);
}

Much to my horror, the compiler decides to initialize the entire data on the stack, and then call memcpy. (At least it unrolled the fill loop) :). This happens even for really large data like [v; 100000], which will crash your program with a stack overflow. Using a compile time known (non zero) literal like [64; 100000] behaves the same way.


If you really want to make sure, you could do something like this:

pub fn baz(v: i32) -> Box<[i32; 1000]>{
    unsafe {
        let b = std::alloc::alloc(
            std::alloc::Layout::array::<i32>(1000).unwrap_unchecked()
        ) as *mut i32;
        for i in 0..1000 {
            *b.add(i) = v;
        }
        Box::from_raw(b as *mut [i32; 1000])
    }
}

which does the right thing.


A safe version of baz would be:

use std::convert::TryInto;

pub fn quux(v: i32) -> Box<[i32; 1000]> {
    let mut b = Vec::with_capacity(1000);
    b.extend(std::iter::repeat(v).take(1000));
    b.into_boxed_slice().try_into().unwrap()
}

Which the compiler optimizes quite nicely, to essentially the identical assembly as baz.


Even shorter would be

vec![v; 1000].into_boxed_slice().try_into::<Box<[i32; 1000]>>().unwrap()

which is probably the best version.

10
  • 3
    For the last one, you can also add .try_into().unwrap() to get a Box<[i32; 1000]>. The result is identical to the unsafe one! I didn't expect that. godbolt.org/z/aqzqK8jo1
    – drewtato
    Commented Feb 4 at 7:30
  • 5
    quux() could make use of vec! and just return vec![v; 1000].into_boxed_slice(). Commented Feb 4 at 7:40
  • 1
    @user4815162342: You're absolutely right, but for some reason, the compiler decides to optimize that one slightly differently (unroll by 8 instead of 10, fixup at the end), which breaks my argument that the assembly is the same :D.
    – ChrisB
    Commented Feb 4 at 7:44
  • 3
    There's a nightly feature new_uninit which allows creating a Box containing an uninitialized MaybeUninit<T>, then call a safe write function to overwrite the content of the Box and make it a Box<T> at the same time, see play.rust-lang.org/… . Still subject to optimizations, but oh so much safer than baz. Commented Feb 4 at 15:06
  • 1
    You can skip the into_boxed_slice part. Box::<[i32; 1000]>::try_from(vec![0; 1000]).unwrap() works Commented Feb 4 at 17:22

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