I am doing the Rust by Example tutorial which has this code snippet:

// Vec example
let vec1 = vec![1, 2, 3];
let vec2 = vec![4, 5, 6];

// `iter()` for vecs yields `&i32`. Destructure to `i32`.
println!("2 in vec1: {}", vec1.iter()     .any(|&x| x == 2));
// `into_iter()` for vecs yields `i32`. No destructuring required.
println!("2 in vec2: {}", vec2.into_iter().any(| x| x == 2));

// Array example
let array1 = [1, 2, 3];
let array2 = [4, 5, 6];

// `iter()` for arrays yields `&i32`.
println!("2 in array1: {}", array1.iter()     .any(|&x| x == 2));
// `into_iter()` for arrays unusually yields `&i32`.
println!("2 in array2: {}", array2.into_iter().any(|&x| x == 2));

I am thoroughly confused — for a Vec the iterator returned from iter yields references and the iterator returned from into_iter yields values, but for an array these iterators are identical?

What is the use case/API for these two methods?



  • The iterator returned by into_iter may yield any of T, &T or &mut T, depending on the context.
  • The iterator returned by iter will yield &T, by convention.
  • The iterator returned by iter_mut will yield &mut T, by convention.

The first question is: "What is into_iter?"

into_iter comes from the IntoIterator trait:

pub trait IntoIterator 
    <Self::IntoIter as Iterator>::Item == Self::Item, 
    type Item;
    type IntoIter: Iterator;
    fn into_iter(self) -> Self::IntoIter;

You implement this trait when you want to specify how a particular type is to be converted into an iterator. Most notably, if a type implements IntoIterator it can be used in a for loop.

For example, Vec implements IntoIterator... thrice!

impl<T> IntoIterator for Vec<T>
impl<'a, T> IntoIterator for &'a Vec<T>
impl<'a, T> IntoIterator for &'a mut Vec<T>

Each variant is slightly different.

This one consumes the Vec and its iterator yields values (T directly):

impl<T> IntoIterator for Vec<T> {
    type Item = T;
    type IntoIter = IntoIter<T>;

    fn into_iter(mut self) -> IntoIter<T> { /* ... */ }

The other two take the vector by reference (don't be fooled by the signature of into_iter(self) because self is a reference in both cases) and their iterators will produce references to the elements inside Vec.

This one yields immutable references:

impl<'a, T> IntoIterator for &'a Vec<T> {
    type Item = &'a T;
    type IntoIter = slice::Iter<'a, T>;

    fn into_iter(self) -> slice::Iter<'a, T> { /* ... */ }

While this one yields mutable references:

impl<'a, T> IntoIterator for &'a mut Vec<T> {
    type Item = &'a mut T;
    type IntoIter = slice::IterMut<'a, T>;

    fn into_iter(self) -> slice::IterMut<'a, T> { /* ... */ }


What is the difference between iter and into_iter?

into_iter is a generic method to obtain an iterator, whether this iterator yields values, immutable references or mutable references is context dependent and can sometimes be surprising.

iter and iter_mut are ad-hoc methods. Their return type is therefore independent of the context, and will conventionally be iterators yielding immutable references and mutable references, respectively.

The author of the Rust by Example post illustrates the surprise coming from the dependence on the context (i.e., the type) on which into_iter is called, and is also compounding the problem by using the fact that:

  1. IntoIterator is not implemented for [T; N], only for &[T; N] and &mut [T; N] -- it will be for Rust 2021.
  2. When a method is not implemented for a value, it is automatically searched for references to that value instead

which is very surprising for into_iter since all types (except [T; N]) implement it for all 3 variations (value and references).

Arrays implement IntoIterator (in such a surprising fashion) to make it possible to iterate over references to them in for loops.

As of Rust 1.51, it's possible for the array to implement an iterator that yields values (via array::IntoIter), but the existing implementation of IntoIterator that automatically references makes it hard to implement by-value iteration via IntoIterator.

  • 26
    I found this blog post helpful: hermanradtke.com/2015/06/22/… – poy Aug 16 '16 at 3:34
  • >whether this iterator yields values, immutable references or mutable references is context dependent What does it mean and how to deal with that? How one would force iter_mut to yield mutable values, for example? – Dan M. May 2 '19 at 22:32
  • 2
    @DanM.: (1) It means that into_iter picks an implementation based on whether the receiver is a value, reference or mutable reference. (2) There are no mutable values in Rust, or rather, any value is mutable since you have ownership. – Matthieu M. May 3 '19 at 6:38
  • 1
    @Ixx: Thanks that's very useful. I decided to provide a TL;DR at the top of the question to avoid burying the answer in the middle, what do you think? – Matthieu M. May 21 '20 at 10:13
  • 1
    For arrays implementing IntoIter, see also github.com/rust-lang/rust/issues/65798. – Lucas Werkmeister Dec 24 '20 at 11:22

I (a Rust newbie) came here from Google seeking a simple answer which wasn't provided by the other answers. Here's that simple answer:

  • iter() iterates over the items by reference
  • into_iter() iterates over the items, moving them into the new scope
  • iter_mut() iterates over the items, giving a mutable reference to each item

So for x in my_vec { ... } is essentially equivalent to my_vec.into_iter().for_each(|x| ... ) - both move the elements of my_vec into the ... scope.

If you just need to "look at" the data, use iter, if you need to edit/mutate it, use iter_mut, and if you need to give it a new owner, use into_iter.

This was helpful: http://hermanradtke.com/2015/06/22/effectively-using-iterators-in-rust.html

Making this a community wiki so that hopefully a Rust pro can edit this answer if I've made any mistakes.

  • 14
    Thank you... It's hard to see how the accepted answer articulates a distinction between iter and into_iter. – mmw Jan 6 '20 at 17:47
  • 1
    That's exactly what I was looking for! – Cyrusmith Mar 28 '20 at 1:57
  • 1
    This is the good simple answer for the (common?) case where my_vec or whatever you are calling .into_iter() on is in fact a Vec<T>. The other answers are more complicated to also mention that, if you call .into_iter() on other things such as a &Vec<T> or &[] (or equivalently, try to iterate over them in a for ... in ... loop), you might not actually be moving the items into the new scope. (At least, that's my understanding so far...) – betaveros Oct 6 '20 at 17:58
  • 2
    Yeah, "into_iter() iterates over the items, moving them into the new scope" is not always accurate - see the accepted answer for more details. – Michael Dorst Apr 17 at 19:43
  • I wish I could vote for this answer more than once. – Joshua Davis Jul 14 at 2:01

I think there's something to clarify a bit more. Collection types, such as Vec<T> and VecDeque<T>, have into_iter method that yields T because they implement IntoIterator<Item=T>. There's nothing to stop us to create a type Foo<T> if which is iterated over, it will yield not T but another type U. That is, Foo<T> implements IntoIterator<Item=U>.

In fact, there are some examples in std: &Path implements IntoIterator<Item=&OsStr> and &UnixListener implements IntoIterator<Item=Result<UnixStream>>.

The difference between into_iter and iter

Back to the original question on the difference between into_iter and iter. Similar to that others have pointed out, the difference is that into_iter is a required method of IntoIterator which can yield any type specified in IntoIterator::Item. Typically, if a type implements IntoIterator<Item=I>, by convention it has also two ad-hoc methods: iter and iter_mut which yield &I and &mut I, respectively.

What it implies is that we can create a function that receives a type that has into_iter method (i.e. it is an iterable) by using a trait bound:

fn process_iterable<I: IntoIterator>(iterable: I) {
    for item in iterable {
        // ...

However, we can't* use a trait bound to require a type to have iter method or iter_mut method, because they're just conventions. We can say that into_iter is more widely useable than iter or iter_mut.

Alternatives to iter and iter_mut

Another interesting to observe is that iter is not the only way to get an iterator that yields &T. By convention (again), collection types SomeCollection<T> in std which have iter method also have their immutable reference types &SomeCollection<T> implement IntoIterator<Item=&T>. For example, &Vec<T> implements IntoIterator<Item=&T>, so it enables us to iterate over &Vec<T>:

let v = vec![1, 2];

// Below is equivalent to: `for item in v.iter() {`
for item in &v {
    println!("{}", item);

If v.iter() is equivalent to &v in that both implement IntoIterator<Item=&T>, why then does Rust provide both? It's for ergonomics. In for loops, it's a bit more concise to use &v than v.iter(); but in other cases, v.iter() is a lot clearer than (&v).into_iter():

let v = vec![1, 2];

let a: Vec<i32> = v.iter().map(|x| x * x).collect();
// Although above and below are equivalent, above is a lot clearer than below.
let b: Vec<i32> = (&v).into_iter().map(|x| x * x).collect();

Similarly, in for loops, v.iter_mut() can be replaced with &mut v:

let mut v = vec![1, 2];

// Below is equivalent to: `for item in v.iter_mut() {`
for item in &mut v {
    *item *= 2;

When to provide (implement) into_iter and iter methods for a type

If the type has only one “way” to be iterated over, we should implement both. However, if there are two ways or more it can be iterated over, we should instead provide an ad-hoc method for each way.

For example, String provides neither into_iter nor iter because there are two ways to iterate it: to iterate its representation in bytes or to iterate its representation in characters. Instead, it provides two methods: bytes for iterating the bytes and chars for iterating the characters, as alternatives to iter method.

* Well, technically we can do it by creating a trait. But then we need to impl that trait for each type we want to use. Meanwhile, many types in std already implement IntoIterator.


.into_iter() is not implemented for a array itself, but only &[]. Compare:

impl<'a, T> IntoIterator for &'a [T]
    type Item = &'a T


impl<T> IntoIterator for Vec<T>
    type Item = T

Since IntoIterator is defined only on &[T], the slice itself cannot be dropped the same way as Vec when you use the values. (values cannot be moved out)

Now, why that's the case is a different issues, and I'd like to learn myself. Speculating: array is the data itself, slice is only a view into it. In practice you cannot move the array as a value into another function, just pass a view of it, so you cannot consume it there either.

  • IntoIterator is also implemented for &'a mut [T], so it could move the objects out of the array. I think that it is related to the fact that the return struct IntoIter<T> does not have a lifetime argument while Iter<'a, T> does, so the former cannot hold a slice. – rodrigo Jan 12 '16 at 1:05
  • mut means that you can change the values, not that you can move them out. – viraptor Jan 12 '16 at 1:08
  • @rodrigo let mut a = ["abc".to_string()]; a.into_iter().map(|x| { *x }); => "error: cannot move out of borrowed content" – viraptor Jan 12 '16 at 1:13
  • Yeah, I think you are right and values cannot be moved from the array. However, I still think that it should be possible to implement a kind of ArrayIntoIter struct using unsafe Rust, as part of the library... Maybe not worth it, as you should use Vec for those cases anyway. – rodrigo Jan 12 '16 at 1:16
  • so I don't understand... is that the reason that array.into_iter returns &T - because it is doing magic to automatically convert it to &array.into_iter -- and if so, I don't understand what that has to do with moving values or not moving values. Or is it as @rodrigo said, that you get the reference simply because (for some reason) you cannot move values out of arrays? Still very confused. – vitiral Jan 12 '16 at 5:00

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