Why does Rust have String and str? What are the differences between String and str? When does one use String instead of str and vice versa? Is one of them getting deprecated?


String is the dynamic heap string type, like Vec: use it when you need to own or modify your string data.

str is an immutable1 sequence of UTF-8 bytes of dynamic length somewhere in memory. Since the size is unknown, one can only handle it behind a pointer. This means that str most commonly2 appears as &str: a reference to some UTF-8 data, normally called a "string slice" or just a "slice". A slice is just a view onto some data, and that data can be anywhere, e.g.

  • In static storage: a string literal "foo" is a &'static str. The data is hardcoded into the executable and loaded into memory when the program runs.
  • Inside a heap allocated String: String dereferences to a &str view of the String's data.
  • On the stack: e.g. the following creates a stack-allocated byte array, and then gets a view of that data as a &str:

    use std::str;
    let x: &[u8] = &[b'a', b'b', b'c'];
    let stack_str: &str = str::from_utf8(x).unwrap();

In summary, use String if you need owned string data (like passing strings to other threads, or building them at runtime), and use &str if you only need a view of a string.

This is identical to the relationship between a vector Vec<T> and a slice &[T], and is similar to the relationship between by-value T and by-reference &T for general types.

1 A str is fixed-length; you cannot write bytes beyond the end, or leave trailing invalid bytes. Since UTF-8 is a variable-width encoding, this effectively forces all strs to be immutable in many cases. In general, mutation requires writing more or fewer bytes than there were before (e.g. replacing an a (1 byte) with an ä (2+ bytes) would require making more room in the str). There are specific methods that can modify a &str in place, mostly those that handle only ASCII characters, like make_ascii_uppercase.

2 Dynamically sized types allow things like Rc<str> for a sequence of reference counted UTF-8 bytes since Rust 1.2. Rust 1.21 allows easily creating these types.

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    "sequence of UTF-8 bytes (of unknown length)" - is this out of date? The docs say "A &str is made up of two components: a pointer to some bytes, and a length." – mrec Oct 10 '16 at 16:23
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    It's not out of date (that representation has been fairly stable), just a little imprecise: it isn't statically known, unlike, say, [u8; N]. – huon Oct 12 '16 at 6:07
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    @mrec it's unknown at compile time, assumptions about it size can not be made, for example, when creating a stack frame. Thus why it's often treated as a reference, which a reference is a known size at compile time, which is the size of a pointer. – Sekhat Feb 20 '17 at 11:17
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    Update: Rc<str> and Arc<str> are now usable via the standard library. – Centril Mar 25 '18 at 14:02
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    @cjohansson Statically allocated objects are normally stored neither on the heap, nor the stack, but in their own region of memory. – Brennan Vincent Aug 9 '19 at 17:05

I have a C++ background and I found it very useful to think about String and &str in C++ terms:

  • A Rust String is like a std::string; it owns the memory and does the dirty job of managing memory.
  • A Rust &str is like a char* (but a little more sophisticated); it points us to the beginning of a chunk in the same way you can get a pointer to the contents of std::string.

Are either of them going to disappear? I do not think so. They serve two purposes:

String keeps the buffer and is very practical to use. &str is lightweight and should be used to "look" into strings. You can search, split, parse, and even replace chunks without needing to allocate new memory.

&str can look inside of a String as it can point to some string literal. The following code needs to copy the literal string into the String managed memory:

let a: String = "hello rust".into();

The following code lets you use the literal itself without copy (read only though)

let a: &str = "hello rust";
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    like a string_view? – Abhinav Gauniyal Jan 23 '18 at 17:21
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    Yes like string_view but intrinsic to the language and properly borrow checked. – locka Feb 5 at 9:34

str, only used as &str, is a string slice, a reference to a UTF-8 byte array.

String is what used to be ~str, a growable, owned UTF-8 byte array.

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  • Technically, what used to be ~str is now Box<str> – jv110 Apr 18 '18 at 17:41
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    @jv110: no, because ~str was growable while Box<str> is not growable. (That ~str and ~[T] were magically growable, unlike any other ~-object, was exactly why String and Vec<T> were introduced, so that the rules were all straightforward and consistent.) – Chris Morgan Apr 20 '18 at 4:27

They are actually completely different. First off, a str is nothing but a type level thing; it can only be reasoned about at the type level because it's a so-called dynamically-sized type (DST). The size the str takes up cannot be known at compile time and depends on runtime information — it cannot be stored in a variable because the compiler needs to know at compile time what the size of each variable is. A str is conceptually just a row of u8 bytes with the guarantee that it forms valid UTF-8. How large is the row? No one knows until runtime hence it can't be stored in a variable.

The interesting thing is that a &str or any other pointer to a str like Box<str> does exist at runtime. This is a so-called "fat pointer"; it's a pointer with extra information (in this case the size of the thing it's pointing at) so it's twice as large. In fact, a &str is quite close to a String (but not to a &String). A &str is two words; one pointer to a the first byte of a str and another number that describes how many bytes long the the str is.

Contrary to what is said, a str does not need to be immutable. If you can get a &mut str as an exclusive pointer to the str, you can mutate it and all the safe functions that mutate it guarantee that the UTF-8 constraint is upheld because if that is violated then we have undefined behaviour as the library assumes this constraint is true and does not check for it.

So what is a String? That's three words; two are the same as for &str but it adds a third word which is the capacity of the str buffer on the heap, always on the heap (a str is not necessarily on the heap) it manages before it's filled and has to re-allocate. the String basically owns a str as they say; it controls it and can resize it and reallocate it when it sees fit. So a String is as said closer to a &str than to a str.

Another thing is a Box<str>; this also owns a str and its runtime representation is the same as a &str but it also owns the str unlike the &str but it cannot resize it because it does not know its capacity so basically a Box<str> can be seen as a fixed-length String that cannot be resized (you can always convert it into a String if you want to resize it).

A very similar relationship exists between [T] and Vec<T> except there is no UTF-8 constraint and it can hold any type whose size is not dynamic.

The use of str on the type level is mostly to create generic abstractions with &str; it exists on the type level to be able to conveniently write traits. In theory str as a type thing didn't need to exist and only &str but that would mean a lot of extra code would have to be written that can now be generic.

&str is super useful to be able to to have multiple different substrings of a String without having to copy; as said a String owns the str on the heap it manages and if you could only create a substring of a String with a new String it would have to copied because everything in Rust can only have one single owner to deal with memory safety. So for instance you can slice a string:

let string: String   = "a string".to_string();
let substring1: &str = &string[1..3];
let substring2: &str = &string[2..4];

We have two different substring strs of the same string. string is the one that owns the actual full str buffer on the heap and the &str substrings are just fat pointers to that buffer on the heap.

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std::String is simply a vector of u8. You can find its definition in source code . It's heap-allocated and growable.

#[derive(PartialOrd, Eq, Ord)]
#[stable(feature = "rust1", since = "1.0.0")]
pub struct String {
    vec: Vec<u8>,

str is a primitive type, also called string slice. A string slice has fixed size. A literal string like let test = "hello world" has &'static str type. test is a reference to this statically allocated string. &str cannot be modified, for example,

let mut word = "hello world";
word[0] = 's';

str does have mutable slice &mut str, for example: pub fn split_at_mut(&mut self, mid: usize) -> (&mut str, &mut str)

let mut s = "Per Martin-Löf".to_string();
    let (first, last) = s.split_at_mut(3);
    assert_eq!("PER", first);
    assert_eq!(" Martin-Löf", last);
assert_eq!("PER Martin-Löf", s);

But a small change to UTF-8 can change its byte length, and a slice cannot reallocate its referent.

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In easy words, String is datatype stored on heap (just like Vec), and you have access to that location.

&str is a slice type. That means it is just reference to an already present String somewhere in the heap.

&str doesn't do any allocation at runtime. So, for memory reasons, you can use &str over String. But, keep in mind that when using &str you might have to deal with explicit lifetimes.

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    somewhere in heap — that is not completely accurate. – Shepmaster Apr 19 '18 at 17:15
  • What I meant was that str is view of already present String in heap. – 00imvj00 Apr 19 '18 at 17:20
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    I understand that's what you meant, and I'm saying that isn't completely accurate. The "heap" isn't a required part of the statement. – Shepmaster Apr 19 '18 at 17:25

For C# and Java people:

  • Rust' String === StringBuilder
  • Rust's &str === (immutable) string

I like to think of a &str as a view on a string, like an interned string in Java / C# where you can't change it, only create a new one.

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    The biggest difference between Java/C# strings and Rust strings is that Rust guarentees the string to be correct unicode, as such getting the third charactor in a string requires more thought than just "abc"[2]. (Given we live in a multi-lingual world, this is a good thing.) – Squirrel Mar 19 '19 at 4:32
  • This is incorrect. The topic of mutability is already addressed in the top-voted answer; please read it to learn more. – Shepmaster Apr 28 '19 at 12:52

Here is a quick and easy explanation.

String - A growable, ownable heap-allocated data structure. It can be coerced to a &str.

str - is (now, as Rust evolves) mutable, fixed-length string that lives on the heap or in the binary. You can only interact with str as a borrowed type via a string slice view, such as &str.

Usage considerations:

Prefer String if you want to own or mutate a string - such as passing the string to another thread, etc.

Prefer &str if you want to have a read-only view of a string.

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  • This is incorrect. The topic of mutability is already addressed in the top-voted answer; please read it to learn more. – Shepmaster Apr 28 '19 at 12:51

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