95

I want to write a program that will write a file in 2 steps. It is likely that the file may not exist before the program is run. The filename is fixed.

The problem is that OpenOptions.new().write() can fail. In that case, I want to call a custom function trycreate(). The idea is to create the file instead of opening it and return a handle. Since the filename is fixed, trycreate() has no arguments and I cannot set a lifetime of the returned value.

How can I resolve this problem?

use std::io::Write;
use std::fs::OpenOptions;
use std::path::Path;

fn trycreate() -> &OpenOptions {
    let f = OpenOptions::new().write(true).open("foo.txt");
    let mut f = match f {
        Ok(file)  => file,
        Err(_)  => panic!("ERR"),
    };
    f
}

fn main() {
    {
        let f = OpenOptions::new().write(true).open(b"foo.txt");
        let mut f = match f {
            Ok(file)  => file,
            Err(_)  => trycreate("foo.txt"),
        };
        let buf = b"test1\n";
        let _ret = f.write(buf).unwrap();
    }
    println!("50%");
    {
        let f = OpenOptions::new().append(true).open("foo.txt");
        let mut f = match f {
            Ok(file)  => file,
            Err(_)  => panic!("append"),
        };
        let buf = b"test2\n";
        let _ret = f.write(buf).unwrap();
    }
    println!("Ok");
}
1
  • Open this page, Ctrl-F, "Cow", no results?? While you can't return references to variables created in functions, you can use std::borrow::Cow to generalize over owned data and unowned references -- it's a Deref that lets you choose whether a given instance owns or borrows its data. I've found it to be the most reliable way to switch off between returning owned and unowned data. Aug 15, 2021 at 19:41

5 Answers 5

109

The question you asked

TL;DR: No, you cannot return a reference to a variable that is owned by a function. This applies if you created the variable or if you took ownership of the variable as a function argument.

Solutions

Instead of trying to return a reference, return an owned object. String instead of &str, Vec<T> instead of &[T], T instead of &T, etc.

If you took ownership of the variable via an argument, try taking a (mutable) reference instead and then returning a reference of the same lifetime.

In rare cases, you can use unsafe code to return the owned value and a reference to it. This has a number of delicate requirements you must uphold to ensure you don't cause undefined behavior or memory unsafety.

See also:

Deeper answer

fjh is absolutely correct, but I want to comment a bit more deeply and touch on some of the other errors with your code.

Let's start with a smaller example of returning a reference and look at the errors:

fn try_create<'a>() -> &'a String {
    &String::new()
}

Rust 2015

error[E0597]: borrowed value does not live long enough
 --> src/lib.rs:2:6
  |
2 |     &String::new()
  |      ^^^^^^^^^^^^^ temporary value does not live long enough
3 | }
  | - temporary value only lives until here
  |
note: borrowed value must be valid for the lifetime 'a as defined on the function body at 1:15...
 --> src/lib.rs:1:15
  |
1 | fn try_create<'a>() -> &'a String {
  |               ^^

Rust 2018

error[E0515]: cannot return reference to temporary value
 --> src/lib.rs:2:5
  |
2 |     &String::new()
  |     ^-------------
  |     ||
  |     |temporary value created here
  |     returns a reference to data owned by the current function

Is there any way to return a reference from a function without arguments?

Technically "yes", but for what you want, "no".

A reference points to an existing piece of memory. In a function with no arguments, the only things that could be referenced are global constants (which have the lifetime &'static) and local variables. I'll ignore globals for now.

In a language like C or C++, you could actually take a reference to a local variable and return it. However, as soon as the function returns, there's no guarantee that the memory that you are referencing continues to be what you thought it was. It might stay what you expect for a while, but eventually the memory will get reused for something else. As soon as your code looks at the memory and tries to interpret a username as the amount of money left in the user's bank account, problems will arise!

This is what Rust's lifetimes prevent - you aren't allowed to use a reference beyond how long the referred-to value is valid at its current memory location.

See also:

Your actual problem

Look at the documentation for OpenOptions::open:

fn open<P: AsRef<Path>>(&self, path: P) -> Result<File>

It returns a Result<File>, so I don't know how you'd expect to return an OpenOptions or a reference to one. Your function would work if you rewrote it as:

fn trycreate() -> File {
    OpenOptions::new()
        .write(true)
        .open("foo.txt")
        .expect("Couldn't open")
}

This uses Result::expect to panic with a useful error message. Of course, panicking in the guts of your program isn't super useful, so it's recommended to propagate your errors back out:

fn trycreate() -> io::Result<File> {
    OpenOptions::new().write(true).open("foo.txt")
}

Option and Result have lots of nice methods to deal with chained error logic. Here, you can use or_else:

let f = OpenOptions::new().write(true).open("foo.txt");
let mut f = f.or_else(|_| trycreate()).expect("failed at creating");

I'd also return the Result from main. All together, including fjh's suggestions:

use std::{
    fs::OpenOptions,
    io::{self, Write},
};

fn main() -> io::Result<()> {
    let mut f = OpenOptions::new()
        .create(true)
        .write(true)
        .append(true)
        .open("foo.txt")?;

    f.write_all(b"test1\n")?;
    f.write_all(b"test2\n")?;

    Ok(())
}
18
  • 10
    Note: in C++, returning a reference to a stack-local variable is Undefined Behavior; if it appears to work, you are just unlucky. In common situations, the compilers should detect the problem and emit a warning. Sep 21, 2015 at 8:15
  • @MatthieuM. just a warning... how unsafe :-) Although it shows that it's been a few years since I wrote C for a day job, as I never got to see any of those warnings. Nice to see progress in all camps!
    – Shepmaster
    Sep 21, 2015 at 14:20
  • @Shepmaster: You must have been using an old compiler; I'm still stuck on gcc 4.3.2 and I have it! But yes, only a warning. Most C/C++ compilers take a conservative approach: errors are mandated by the Standard, and the rest is done with warnings (with more or less accuracy ...) Sep 21, 2015 at 14:53
  • 1
    @D3181 there is no method called Write. You are looking for write, and you will need to have the trait in scope. Check out the Rust 1.0 / "write a file" section of What's the de-facto way of reading and writing files in Rust 1.x?.
    – Shepmaster
    Apr 24, 2019 at 23:25
  • 1
    @JohnDoe is that not covered in the question linked in the answer?
    – Shepmaster
    Sep 15, 2021 at 17:10
21

Is there any way to return a reference from a function without arguments?

No (except references to static values, but those aren't helpful here).

However, you might want to look at OpenOptions::create. If you change your first line in main to

let  f = OpenOptions::new().write(true).create(true).open(b"foo.txt");

the file will be created if it does not yet exist, which should solve your original problem.

0
16

You can not return a reference pointing to a local variable. You have two alternatives, either return the value or use a static variable.

Here is why:

References are pointers to memory locations. Once functions are executed, local variables are popped off the execution stack and resources are de-allocated. After that point, any reference to a local variable will be pointing to some useless data. Since it is de-allocated, it is not in our program's possession any more and OS may have already given it to another process and our data may have been overwritten.

For the following example, x is created when the function runs and dropped off when the function completes executing. It is local to the function and lives on this particular function's stack. Function's stack holds local variables.

When run is pop off the execution stack, any reference to x, &x, will be pointing to some garbage data. That is what people call a dangling pointer. The Rust compiler does not allow to use dangling pointers since it is not safe.

fn run() -> &u32 {
    let x: u32 = 42;

    return &x;
} // x is dropped here

fn main() {
    let x = run();
}

So, that is why we can not return a reference to a local variable. We have two options: either return the value or use a static variable.

Returning the value is the best option here. By returning the value, you will be passing the result of your calculation to the caller, in Rust's terms x will be owned by the caller. In our case it is main. So, no problem there.

Since a static variable lives as long as the process runs, its references will be pointing to the same memory location both inside and outside the function. No problem there either.

Note: @navigaid advises using a box, but it does not make sense because you are moving readily available data to heap by boxing it and then returning it. It does not solve the problem, you are still returning the local variable to the caller but using a pointer when accessing it. It adds an unnecessary indirection due to de-referencing hence incurring additional cost. Basically you will be using & for the sake of using it, nothing more.

4
  • 9
    return at the end of a block like that is not idiomatic.
    – Shepmaster
    Sep 11, 2019 at 18:36
  • 2
    First answer is unnecessarily verbose, second one is not elaborate enough. return is chosen for the emphasis.
    – snnsnn
    Sep 11, 2019 at 18:40
  • 4
    Despite the non-idiomatic return I found this answer to have the clearest explanation.
    – jla
    Jan 22, 2020 at 2:25
  • This makes a lot more sense. The compiler error message could maybe a bit more obvious. I had a case where I was passing in an owned object, but was returning only references to the now moved object which is going to get dropped at the end of the function. I'm more used to reading the more common "x.foo() borrows x here but x is dropped at the end of the function" Jan 12 at 5:58
13

This is an elaboration on snnsnn's answer, which briefly explained the problem without being too specific.

Rust doesn't allow return a reference to a variable created in a function. Is there a workaround? Yes, simply put that variable in a Box then return it. Example:

fn run() -> Box<u32> {
    let x: u32 = 42;
    return Box::new(x);
} 

fn main() {
    println!("{}", run());
}

code in rust playground

As a rule of thumb, to avoid similar problems in Rust, return an owned object (Box, Vec, String, ...) instead of reference to a variable:

  • Box<T> instead of &T
  • Vec<T> instead of &[T]
  • String instead of &str

For other types, refer to The Periodic Table of Rust Types to figure out which owned object to use.

Of course, in this example you can simply return the value (T instead of &T or Box<T>)

fn run() -> u32 {
    let x: u32 = 42;
    return x;
} 
4
  • 4
    This answer is wrong and misguiding. Why would you box a readily available data then return it. It adds unnecessary indirection and hence cost.
    – snnsnn
    Jan 12 at 6:11
  • @snnsnn the u32 variable is only for demonstration purpose. I already pointed it out at the end of the answer.
    – navigaid
    Jan 12 at 17:46
  • 2
    Even if you box a variable that is suitable for boxing, the example is wrong all the same because references are for passing a reference from outside scope into the function, in other words for borrowing the outer variable, to avoid the clutter of taking in and returning back. Your example is inverts this logic all the way around. It will be confusing for new comers and has no real use case.
    – snnsnn
    Jan 12 at 20:15
  • @snnsnn Allocating value on the heap by Box makes sense if the Box's lifetime is properly long enough. In navigaid's way, Box's lifetime is too short, so it might not make sense as you say. Box should be dropped when the scope ends. So we must use Box::into_raw or Box:from_raw. See here too: stackoverflow.com/questions/66196972/…
    – lechat
    Aug 5 at 18:38
1

Yes! But you have to find a way to extend the lifetime. One way to do is to provide mutable reference to a dummy/default value (&mut T) to the function and then fill/replace the value in the function and then return a reference to that value (&T). This way you can specify the lifetime so that the returned reference get the lifetime of a value outside the function.

Examples:

//&mut T -> &T
fn example2<'a>(life: &'a mut Vec<i32>) -> &'a Vec<i32> {
    *life = vec![1, 2, 3, 4];
    life
}

fn test_example2() {
    //Could also use Vec::new()
    let mut life = Vec::default();
    let res = example2(&mut life);
    println!("{:?}", res)
}

fn test2_example2() {
    let life = &mut Vec::default();
    let res = example2(life);
    println!("{:?}", res)
}

//shows real use case
fn get_check_test_slices2<'a>(
    lifetime: &'a mut Vec<usize>,
    limit: usize,
) -> impl Iterator<Item = (&'a [usize], &'a [usize])> + 'a {
    *lifetime = primes1_iter_bitvec(limit).collect::<Vec<_>>();
    all_test_check_slices(lifetime)
}

Edit: How is that different from just giving &mut T to the function? (asked by Chayim Friedman (see old solution below)): It's basically the same... I lost against the borrow checker previously, and that is why I didn't just use &mut T. But after renewed battles I have finally managed to just use &mut T. Thank you for the insightful question.

Old solution: My solution works by creating a default value before calling the function, which the function later replaces/fills and returns a reference to.

/// Used to return references to values created in a function.
/// fn example<'a>(lt:& 'a mut LifeExtender<Vec<i32>>) -> &'a Vec<i32> {
///     lt.set(vec![1,2,3,4]);
///     lt.get()
/// }
pub struct LifeExtender<T> {
    value: T,
}

impl<T> Default for LifeExtender<T>
where
    T: Default,
{
    /// using T default.
    pub fn default() -> Self {
        Self {
            value: T::default(),
        }
    }
}

impl<T> LifeExtender<T> {
    /// If T doesn't have default.
    pub fn new(value: T) -> Self {
        Self { value }
    }
    /// set value to be returned by reference
    pub fn set(&mut self, new_value: T) {
        self.value = new_value;
    }
    /// Get a reference with lifetime self.
    pub fn get<'a>(&'a self) -> &'a T {
        &self.value
    }
    /// Get a mut reference with lifetime self.
    pub fn get_mut<'a>(&'a mut self) -> &'a mut T {
        &mut self.value
    }
}

fn example<'a>(life: &'a mut LifeExtender<Vec<i32>>) -> &'a Vec<i32> {
    let local_value = vec![1, 2, 3, 4];
    life.set(local_value);
    life.get()
}

//prints: [1,2,3,4]
pub fn test_example() {
    let mut life = LifeExtender::default();
    let res = example(&mut life);
    println!("{:?}", res);
}

//Real example code snippet, where I used this solution: 
fn get_check_slices2<'a>(
    lifetime: &'a mut LifeExtender<Vec<usize>>,
    limit: usize,
) -> impl Iterator<Item = (&'a [usize], &'a [usize])> + 'a {
    lifetime.set(primes1_iter_bitvec(limit).collect::<Vec<_>>());
    all_test_check_slices(lifetime.get())
}
3
  • How is that different from just giving &mut T to the function? May 6 at 6:08
  • I have updated my answer, to answer that question. Often you can just give &mut T to the function. May 6 at 15:56
  • Update: Maybe you can always give &mut T... May 6 at 16:19

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