Take a look at the following simple example:
use std::rc::Rc;
struct MyStruct {
a: i8,
}
fn main() {
let mut my_struct = MyStruct { a: 0 };
my_struct.a = 5;
let my_struct_rc = Rc::new(my_struct);
println!("my_struct_rc.a = {}", my_struct_rc.a);
}
The official documentation of Rc
says:
The type
Rc<T>
provides shared ownership of a value of typeT
, allocated in the heap.
Theoretically it is clear. But, firstly my_struct
is not immediately wrapped into Rc
, and secondly MyStruct
is a very simple type. I can see 2 scenarios here.
- When
my_struct
is moved into theRc
the memory content is literally copied from the stack to the heap. - The compiler is able to resolve that
my_struct
will be moved into theRc
, so it puts it on the heap from the beginning.
If number 1 is true, then there might be a hidden performance bottleneck as when reading the code one does not explicitly see memory being copied (I am assuming MyStruct
being much more complex).
If number 2 is true, I wonder whether the compiler is always able to resolve such things. The provided example is very simple, but I can imagine that my_struct
is much more complex and is mutated several times by different functions before being moved to the Rc
.
Rc::new()
moves the value into the function, and whenever you do this, the value might actually be copied – there's nothing hidden here. The conpiler also might be able to optimise this, but you'll never get a guarantee it will. I recommend not to worry. Copying a value is cheap even for more complex values, and in almost all cases the cost for the allocation will dwarf the cost of the move. There may be some extreme cases where it matters, but they should be exceedingly rare.