I have a value and I want to store that value and a reference to something inside that value in my own type:

struct Thing {
    count: u32,
}

struct Combined<'a>(Thing, &'a u32);

fn make_combined<'a>() -> Combined<'a> {
    let thing = Thing { count: 42 };

    Combined(thing, &thing.count)
}

Sometimes, I have a value and I want to store that value and a reference to that value in the same structure:

struct Combined<'a>(Thing, &'a Thing);

fn make_combined<'a>() -> Combined<'a> {
    let thing = Thing::new();

    Combined(thing, &thing)
}

Sometimes, I'm not even taking a reference of the value and I get the same error:

struct Combined<'a>(Parent, Child<'a>);

fn make_combined<'a>() -> Combined<'a> {
    let parent = Parent::new();
    let child = parent.child();

    Combined(parent, child)
}

In each of these cases, I get an error that one of the values "does not live long enough". What does this error mean?

  • 6
    Note - this is an attempt at creating a canonical question for this common problem. For example, I would hope that stackoverflow.com/q/32298278/155423 and stackoverflow.com/q/32209391/155423 could be marked as duplicates of this one (and probably more). It's my hope that we can use this question and answer to point to. – Shepmaster Aug 30 '15 at 19:08
  • For the latter example, a definition of Parent and Child could help... – Matthieu M. Aug 31 '15 at 6:32
  • @MatthieuM. I debated that, but decided against it based on the two linked questions. Neither of those questions looked at the definition of the struct or the method in question, so I thought it would be best to mimic that to that people can more easily match this question to their own situation. Note that I do show the method signature in the answer. – Shepmaster Aug 31 '15 at 14:25
up vote 140 down vote accepted

Let's look at a simple implementation of this:

struct Parent {
    count: u32,
}

struct Child<'a> {
    parent: &'a Parent,
}

struct Combined<'a> {
    parent: Parent,
    child: Child<'a>,
}

impl<'a> Combined<'a> {
    fn new() -> Self {
        let p = Parent { count: 42 };
        let c = Child { parent: &p };

        Combined { parent: p, child: c }
    }
}

fn main() {}

This will fail with the slightly cleaned up error:

error: `p` does not live long enough
  --> src/main.rs:17:34
   |
17 |         let c = Child { parent: &p };
   |                                  ^
   |
note: reference must be valid for the lifetime 'a as defined
      on the block at 15:21...
  --> src/main.rs:15:22
   |
15 |     fn new() -> Self {
   |                      ^
note: ...but borrowed value is only valid for the block suffix
      following statement 0 at 16:37
  --> src/main.rs:16:38
   |
16 |         let p = Parent { count: 42 };
   |                                      ^

To completely understand this error, you have to think about how the values are represented in memory and what happens when you move those values. Let's annotate Combined::new with some hypothetical memory addresses that show where values are located:

let p = Parent { count: 42 };
// `p` lives at address 0x1000 and takes up 4 bytes
// The value of `p` is 42 
let c = Child { parent: &p };
// `c` lives at address 0x1010 and takes up 4 bytes
// The value of `c` is 0x1000

Combined { parent: p, child: c }
// The return value lives at address 0x2000 and takes up 8 bytes
// `p` is moved to 0x2000
// `c` is ... ?

What should happen to c? If the value was just moved like p was, then it would refer to memory that no longer is guaranteed to have a valid value in it. Any other piece of code is allowed to store values at memory address 0x1000. Accessing that memory assuming it was an integer could lead to crashes and/or security bugs, and is one of the main categories of errors that Rust prevents.

This is exactly the problem that lifetimes prevent. A lifetime is a bit of metadata that allows you and the compiler to know how long a value will be valid at its current memory location. That's an important distinction, as it's a common mistake Rust newcomers make. Rust lifetimes are not the time period between when an object is created and when it is destroyed!

As an analogy, think of it this way: During a person's life, they will reside in many different locations, each with a distinct address. A Rust lifetime is concerned with the address you currently reside at, not about whenever you will die in the future (although dying also changes your address). Every time you move it's relevant because your address is no longer valid.

It's also important to note that lifetimes do not change your code; your code controls the lifetimes, your lifetimes don't control the code. The pithy saying is "lifetimes are descriptive, not prescriptive".

Let's annotate Combined::new with some line numbers which we will use to highlight lifetimes:

{                                    // 0
    let p = Parent { count: 42 };    // 1
    let c = Child { parent: &p };    // 2
                                     // 3
    Combined { parent: p, child: c } // 4
}                                    // 5

The concrete lifetime of p is from 1 to 4, inclusive (which I'll represent as [1,4]). The concrete lifetime of c is [2,4], and the concrete lifetime of the return value is [4,5]. It's possible to have concrete lifetimes that start at zero - that would represent the lifetime of a parameter to a function or something that existed outside of the block.

Note that the lifetime of c itself is [2,4], but that it refers to a value with a lifetime of [1,4]. This is fine as long as the referring value becomes invalid before the referred-to value does. The problem occurs when we try to return c from the block. This would "over-extend" the lifetime beyond its natural length.

This new knowledge should explain the first two examples. The third one requires looking at the implementation of Parent::child. Chances are, it will look something like this:

impl Parent {
    fn child(&self) -> Child { ... }
}

This uses lifetime elision to avoid writing explicit generic lifetime parameters. It is equivalent to:

impl Parent {
    fn child<'a>(&'a self) -> Child<'a> { ... }
}

In both cases, the method says that a Child structure will be returned that has been parameterized with the concrete lifetime of self. Said another way, the Child instance contains a reference to the Parent that created it, and thus cannot live longer than that Parent instance.

This also lets us recognize that something is really wrong with our creation function:

fn make_combined<'a>() -> Combined<'a> { ... }

Although you are more likely to see this written in a different form:

impl<'a> Combined<'a> {
    fn new() -> Combined<'a> { ... }
}

In both cases, there is no lifetime parameter being provided via an argument. This means that the lifetime that Combined will be parameterized with isn't constrained by anything - it can be whatever the caller wants it to be. This is nonsensical, because the caller could specify the 'static lifetime and there's no way to meet that condition.

How do I fix it?

The easiest and most recommended solution is to not attempt to put these items in the same structure together. By doing this, your structure nesting will mimic the lifetimes of your code. Place types that own data into a structure together and then provide methods that allow you to get references or objects containing references as needed.

There is a special case where the lifetime tracking is overzealous: when you have something placed on the heap. This occurs when you use a Box<T>, for example. In this case, the structure that is moved contains a pointer into the heap. The pointed-at value will remain stable, but the address of the pointer itself will move. In practice, this doesn't matter, as you always follow the pointer.

The rental crate or the owning_ref crate are ways of representing this case, but they require that the base address never move. This rules out mutating vectors, which may cause a reallocation and a move of the heap-allocated values.

More information

After moving p into the struct, why is the compiler not able to get a new reference to p and assign it to c in the struct?

While it is theoretically possible to do this, doing so would introduce a large amount of complexity and overhead. Every time that the object is moved, the compiler would need to insert code to "fix up" the reference. This would mean that copying a struct is no longer a very cheap operation that just moves some bits around. It could even mean that code like this is expensive, depending on how good a hypothetical optimizer would be:

let a = Object::new();
let b = a;
let c = b;

Instead of forcing this to happen for every move, the programmer gets to choose when this will happen by creating methods that will take the appropriate references only when you call them.


There's one specific case where you can create a type with a reference to itself. You need to use something like Option to make it in two steps though:

#[derive(Debug)]
struct WhatAboutThis<'a> {
    name: String,
    nickname: Option<&'a str>,
}

fn main() {
    let mut tricky = WhatAboutThis {
        name: "Annabelle".to_string(),
        nickname: None,
    };
    tricky.nickname = Some(&tricky.name[..4]);

    println!("{:?}", tricky);
}

This does work, in some sense, but the created value is highly restricted - it can never be moved. Notably, this means it cannot be returned from a function or passed by-value to anything. A constructor function shows the same problem with the lifetimes as above:

fn creator<'a>() -> WhatAboutThis<'a> {
    // ...
}
  • 1
    Is something like this (is.gd/wl2IAt) considered idiomatic? Ie, to expose the data via methods instead of the raw data. – Peter Hall Jan 4 '16 at 22:05
  • 2
    @PeterHall sure, it just means that Combined owns the Child which owns the Parent. That may or may not make sense depending on the actual types that you have. Returning references to your own internal data is pretty typical. – Shepmaster Jan 4 '16 at 22:42
  • What is the solution to the heap problem? – derekdreery Nov 14 '16 at 11:25
  • @derekdreery perhaps you could expand on your comment? Why is the entire paragraph talking about the owning_ref crate insufficient? – Shepmaster Nov 14 '16 at 13:57
  • I haven't looked at the owning_ref crate, but "The owning_ref crate is a way of representing this case, but requires that the address never move" made me think it's not possible to use this in all situations. I'll try to figure it out better by playing with owning_ref – derekdreery Nov 15 '16 at 12:11

A slightly different issue which causes very similar compiler messages is object lifetime dependency, rather than storing an explicit reference. An example of that is the ssh2 library. When developing something bigger than a test project, it is tempting to try to put the Session and Channel obtained from that session alongside each other into a struct, hiding the implementation details from the user. However, note that the Channel definition has the 'sess lifetime in its type annotation, while Session doesn't.

This causes similar compiler errors related to lifetimes.

One way to solve it in a very simple way is to declare the Session outside in the caller, and then for annotate the reference within the struct with a lifetime, similar to the answer in this Rust User's Forum post talking about the same issue while encapsulating SFTP. This will not look elegant and may not always apply - because now you have two entities to deal with, rather than one that you wanted!

Turns out the rental crate or the owning_ref crate from the other answer are the solutions for this issue too. Let's consider the owning_ref, which has the special object for this exact purpose: OwningHandle. To avoid the underlying object moving, we allocate it on the heap using a Box, which gives us the following possible solution:

use ssh2::{Channel, Error, Session};
use std::net::TcpStream;

use owning_ref::OwningHandle;

struct DeviceSSHConnection {
    tcp: TcpStream,
    channel: OwningHandle<Box<Session>, Box<Channel<'static>>>,
}

impl DeviceSSHConnection {
    fn new(targ: &str, c_user: &str, c_pass: &str) -> Self {
        use std::net::TcpStream;
        let mut session = Session::new().unwrap();
        let mut tcp = TcpStream::connect(targ).unwrap();

        session.handshake(&tcp).unwrap();
        session.set_timeout(5000);
        session.userauth_password(c_user, c_pass).unwrap();

        let mut sess = Box::new(session);
        let mut oref = OwningHandle::new_with_fn(
            sess,
            unsafe { |x| Box::new((*x).channel_session().unwrap()) },
        );

        oref.shell().unwrap();
        let ret = DeviceSSHConnection {
            tcp: tcp,
            channel: oref,
        };
        ret
    }
}

The result of this code is that we can not use the Session anymore, but it is stored alongside with the Channel which we will be using. Because the OwningHandle object dereferences to Box, which dereferences to Channel, when storing it in a struct, we name it as such. NOTE: This is just my understanding. I have a suspicion this may not be correct, since it appears to be quite close to discussion of OwningHandle unsafety.

One curious detail here is that the Session logically has a similar relationship with TcpStream as Channel has to Session, yet its ownership is not taken and there are no type annotations around doing so. Instead, it is up to the user to take care of this, as the documentation of handshake method says:

This session does not take ownership of the socket provided, it is recommended to ensure that the socket persists the lifetime of this session to ensure that communication is correctly performed.

It is also highly recommended that the stream provided is not used concurrently elsewhere for the duration of this session as it may interfere with the protocol.

So with the TcpStream usage, is completely up to the programmer to ensure the correctness of the code. With the OwningHandle, the attention to where the "dangerous magic" happens is drawn using the unsafe {} block.

A further and a more high-level discussion of this issue is in this Rust User's Forum thread - which includes a different example and its solution using the rental crate, which does not contain unsafe blocks.

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