I understand Rust doesn't have a garbage collector and am wondering how memory is freed up when a binding goes out of scope.

So in this example, I understand that Rust reclaims the memory allocated to 'a' when it goes out of scope.

    let a = 4

The problem I am having with this, is firstly how this happens, and secondly isn't this a sort of garbage collection? How does it differ from 'typical' garbage collection?


Garbage collection is typically used periodically or on demand, like if the heap is close to full or above some threshold. It then looks for unused variables and frees their memory, depending on the algorithm.

Rust would know when the variable gets out of scope or its lifetime ends at compile time and thus insert the corresponding LLVM/assembly instructions to free the memory.

Rust also allows some kind of garbage collection, like atomic reference counting though.

  • By allocating memory when introducing variables and freeing memory when the memory is no longer needed? I don't really know what you want to say with that. Maybe we have different opinions on what a GC is then. – Ayonix Sep 20 '15 at 9:06
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    His question is how Rust's approach differs from a typical GC. So I explained what a GC is and how Rust does it without a GC. – Ayonix Sep 20 '15 at 9:08
  • Was I wrong in thinking that if you create an object simply with 'let', it would be created on the stack? And no garbage collection would be necesary? If a doesn't allocate something in it's ctor, of course. – Amomum Sep 21 '15 at 20:47
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    doc.rust-lang.org/book/the-stack-and-the-heap.html explains it pretty well. Yes, many things are in the stack but let alone is no sufficient indicator (see Box). I left that out for the sake of simplicity, since the question was asking generally though – Ayonix Sep 21 '15 at 21:04
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    @Amomum Actually Rust doesn't have any anointed new() function like C, they are just static functions, and in particular something like let x = MyStruct::new() creates its object on the stack. The real indicator of heap allocation is Box::new() (or any of the structures that depend on Box). – Mario Carneiro Jul 13 '16 at 9:34

The basic idea of managing resources (including memory) in a program, whatever the strategy, is that the resources tied to unreachable "objects" can be reclaimed. Beyond memory, those resources can be mutex locks, file handles, sockets, database connections...

Languages with a garbage collector periodically scan the memory (one way or another) to find unused objects, release the resources associated with them, and finally release the memory used by those objects.

Rust does not have a GC, how does it manage?

Rust has ownership. Using an affine type system, it tracks which variable is still holding onto an object and, when such a variable goes out of scope, calls its destructor. You can see the affine type system in effect pretty easily:

fn main() {
    let s: String = "Hello, World!".into();
    let t = s;
    println!("{}", s);


<anon>:4:24: 4:25 error: use of moved value: `s` [E0382]
<anon>:4         println!("{}", s);

<anon>:3:13: 3:14 note: `s` moved here because it has type `collections::string::String`, which is moved by default
<anon>:3         let t = s;

which perfectly illustrates that at any point in time, at the language level, the ownership is tracked.

This ownership works recursively: if you have a Vec<String> (i.e., a dynamic array of strings), then each String is owned by the Vec which itself is owned by a variable or another object, etc... thus, when a variable goes out of scope, it recursively frees up all resources it held, even indirectly. In the case of the Vec<String> this means:

  1. Releasing the memory buffer associated to each String
  2. Releasing the memory buffer associated to the Vec itself

Thus, thanks to the ownership tracking, the lifetime of ALL the program objects is strictly tied to one (or several) function variables, which will ultimately go out of scope (when the block they belong to ends).

Note: this is a bit optimistic, using reference counting (Rc or Arc) it is possible to form cycles of references and thus cause memory leaks, in which case the resources tied to the cycle might never be released.

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    "Languages with a Garbage Collector periodically scan the memory (one way or another)". Many do but that is not true in general. Real-time garbage collectors scan incrementally rather than periodically. Reference counting languages like Mathematica don't scan at all. – Jon Harrop Jun 4 '16 at 22:50
  • @JonHarrop: I do not count reference-counting as a complete Garbage Collection mechanism since it must be supplemented to avoid leaking cycles. As for the incremental/periodic difference, it may my poor command of English, but I fail to see how periodic does not cover the incremental case... I think that the "(one way or another)" bit adequately conveys that many varied approaches exist. In any case, if you have a better way of succinctly describing Garbage Collection, please suggest away. I have, however, no intention of launching myself in a full-blown explanation: I am unqualified for it. – Matthieu M. Jun 5 '16 at 10:42
  • "I do not count reference-counting as a complete Garbage Collection mechanism since it must be supplemented to avoid leaking cycles". RC is conventionally regarded as a form of GC. In Mathematica and Erlang, for example, cycles cannot be created by design so RC does not leak. For a high-level perspective, see "A unified theory of garbage collection" cs.virginia.edu/~cs415/reading/bacon-garbage.pdf – Jon Harrop Jun 5 '16 at 16:24
  • @JonHarrop: True, if no cycle is possible then RC cannot leak. – Matthieu M. Jun 5 '16 at 17:41
  • "I fail to see how periodic does not cover the incremental case". Stop the world algorithms would be regarded as periodic whereas tricolor marking is regarded as incremental, for example. They are opposites in this context. – Jon Harrop Jun 7 '16 at 20:14

With a language where you must manually manage memory, the distinction between the stack and the heap becomes critical. Every time you call a function, enough space is allocated on the stack for all variables contained within the scope of that function. When the function returns, the stack frame associated with that function is "popped" off the stack, and the memory is freed for future use.

From a practical standpoint, this inadvertent memory cleaning is used as a means of automatic memory storage that will be cleared at the end of the function's scope.

There is more information available here: https://doc.rust-lang.org/book/the-stack-and-the-heap.html

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    While using the stack is handy, deterministic object lifetimes can still be handled if all values were 'created on the heap'. Thus it is an implementation detail; not necessarily a language strategy. – user2864740 Sep 20 '15 at 8:47
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    You keep using that word. I do not think it means what you think it means. – Swiss Sep 20 '15 at 8:51
  • Means what I wish to express; being the opposite of non-deterministic lifetimes. Make an offer for a better phrase. – user2864740 Sep 20 '15 at 8:55
  • Thanks for the answer, i've give the points to the first one simply because it was submitted first. The information is just as useful and valid. – rix Sep 20 '15 at 9:07
  • @user2864740 Deterministic object lifetimes refers to being able to tell exactly when the object's memory will be cleared once its destructor has been called. It has nothing to do with how that destructor is called in the first place. You keep bringing up the same term repeatedly even though it has no direct significance to the question. – Swiss Sep 20 '15 at 9:09

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