The Slice Type
Slices let you reference a contiguous sequence of elements in a collection rather than the whole collection. A slice is a kind of reference, so it does not have ownership.
Here’s a small programming problem: write a function that takes a string of words separated by spaces and returns the first word it finds in that string. If the function doesn’t find a space in the string, the whole string must be one word, so the entire string should be returned.
Let’s work through how we’d write the signature of this function without using slices, to understand the problem that slices will solve:
fn first_word(s: &String) -> ?
The first_word
function has a &String
as a parameter. We don’t want ownership, so this is fine. But what should we return? We don’t really have a way to talk about part of a string. However, we could return the index of the end of the word, indicated by a space. Let’s try that, as shown in Listing 4-7.
Filename: src/main.rs
fn first_word(s: &String) -> usize {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return i;
}
}
s.len()
}
fn main() {}
Listing 4-7: The first_word
function that returns a byte index value into the String
parameter
Because we need to go through the String
element by element and check whether a value is a space, we’ll convert our String
to an array of bytes using the as_bytes
method:
fn first_word(s: &String) -> usize {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return i;
}
}
s.len()
}
fn main() {}
Next, we create an iterator over the array of bytes using the iter
method:
fn first_word(s: &String) -> usize {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return i;
}
}
s.len()
}
fn main() {}
We’ll discuss iterators in more detail in Chapter 13. For now, know that iter
is a method that returns each element in a collection and that enumerate
wraps the result of iter
and returns each element as part of a tuple instead. The first element of the tuple returned from enumerate
is the index, and the second element is a reference to the element. This is a bit more convenient than calculating the index ourselves.
Because the enumerate
method returns a tuple, we can use patterns to destructure that tuple. We’ll be discussing patterns more in Chapter 6. In the for
loop, we specify a pattern that has i
for the index in the tuple and &item
for the single byte in the tuple. Because we get a reference to the element from .iter().enumerate()
, we use &
in the pattern.
Inside the for
loop, we search for the byte that represents the space by using the byte literal syntax. If we find a space, we return the position. Otherwise, we return the length of the string by using s.len()
:
fn first_word(s: &String) -> usize {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return i;
}
}
s.len()
}
fn main() {}
We now have a way to find out the index of the end of the first word in the string, but there’s a problem. We’re returning a usize
on its own, but it’s only a meaningful number in the context of the &String
. In other words, because it’s a separate value from the String
, there’s no guarantee that it will still be valid in the future. Consider the program in Listing 4-8 that uses the first_word
function from Listing 4-7.
Filename: src/main.rs
fn first_word(s: &String) -> usize {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return i;
}
}
s.len()
}
fn main() {
let mut s = String::from("hello world");
let word = first_word(&s); // word will get the value 5
s.clear(); // this empties the String, making it equal to ""
// word still has the value 5 here, but there's no more string that
// we could meaningfully use the value 5 with. word is now totally invalid!
}
Listing 4-8: Storing the result from calling the first_word
function and then changing the String
contents
This program compiles without any errors and would also do so if we used word
after calling s.clear()
. Because word
isn’t connected to the state of s
at all, word
still contains the value 5
. We could use that value 5
with the variable s
to try to extract the first word out, but this would be a bug because the contents of s
have changed since we saved 5
in word
.
Having to worry about the index in word
getting out of sync with the data in s
is tedious and error prone! Managing these indices is even more brittle if we write a second_word
function. Its signature would have to look like this:
fn second_word(s: &String) -> (usize, usize) {
Now we’re tracking a starting and an ending index, and we have even more values that were calculated from data in a particular state but aren’t tied to that state at all. We have three unrelated variables floating around that need to be kept in sync.
Luckily, Rust has a solution to this problem: string slices.
String Slices
A string slice is a reference to part of a String
, and it looks like this:
fn main() {
let s = String::from("hello world");
let hello = &s[0..5];
let world = &s[6..11];
}
Rather than a reference to the entire String
, hello
is a reference to a portion of the String
, specified in the extra [0..5]
bit. We create slices using a range within brackets by specifying [starting_index..ending_index]
, where starting_index
is the first position in the slice and ending_index
is one more than the last position in the slice. Internally, the slice data structure stores the starting position and the length of the slice, which corresponds to ending_index
minus starting_index
. So in the case of let world = &s[6..11];
, world
would be a slice that contains a pointer to the byte at index 6 of s
with a length value of 5.
Figure 4-6 shows this in a diagram.
Figure 4-6: String slice referring to part of a String
With Rust’s ..
range syntax, if you want to start at index zero, you can drop the value before the two periods. In other words, these are equal:
#![allow(unused)]
fn main() {
let s = String::from("hello");
let slice = &s[0..2];
let slice = &s[..2];
}
By the same token, if your slice includes the last byte of the String
, you can drop the trailing number. That means these are equal:
#![allow(unused)]
fn main() {
let s = String::from("hello");
let len = s.len();
let slice = &s[3..len];
let slice = &s[3..];
}
You can also drop both values to take a slice of the entire string. So these are equal:
#![allow(unused)]
fn main() {
let s = String::from("hello");
let len = s.len();
let slice = &s[0..len];
let slice = &s[..];
}
Note: String slice range indices must occur at valid UTF-8 character boundaries. If you attempt to create a string slice in the middle of a multibyte character, your program will exit with an error. For the purposes of introducing string slices, we are assuming ASCII only in this section; a more thorough discussion of UTF-8 handling is in the “Storing UTF-8 Encoded Text with Strings” section of Chapter 8.
With all this information in mind, let’s rewrite first_word
to return a slice. The type that signifies “string slice” is written as &str
:
Filename: src/main.rs
fn first_word(s: &String) -> &str {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return &s[0..i];
}
}
&s[..]
}
fn main() {}
We get the index for the end of the word in the same way as we did in Listing 4-7, by looking for the first occurrence of a space. When we find a space, we return a string slice using the start of the string and the index of the space as the starting and ending indices.
Now when we call first_word
, we get back a single value that is tied to the underlying data. The value is made up of a reference to the starting point of the slice and the number of elements in the slice.
Returning a slice would also work for a second_word
function:
fn second_word(s: &String) -> &str {
We now have a straightforward API that’s much harder to mess up, because the compiler will ensure the references into the String
remain valid. Remember the bug in the program in Listing 4-8, when we got the index to the end of the first word but then cleared the string so our index was invalid? That code was logically incorrect but didn’t show any immediate errors. The problems would show up later if we kept trying to use the first word index with an emptied string. Slices make this bug impossible and let us know we have a problem with our code much sooner. Using the slice version of first_word
will throw a compile-time error:
Filename: src/main.rs
fn first_word(s: &String) -> &str {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return &s[0..i];
}
}
&s[..]
}
fn main() {
let mut s = String::from("hello world");
let word = first_word(&s);
s.clear(); // error!
println!("the first word is: {}", word);
}
Here’s the compiler error:
$ cargo run
Compiling ownership v0.1.0 (file:///projects/ownership)
error[E0502]: cannot borrow `s` as mutable because it is also borrowed as immutable
--> src/main.rs:18:5
|
16 | let word = first_word(&s);
| -- immutable borrow occurs here
17 |
18 | s.clear(); // error!
| ^^^^^^^^^ mutable borrow occurs here
19 |
20 | println!("the first word is: {}", word);
| ---- immutable borrow later used here
For more information about this error, try `rustc --explain E0502`.
error: could not compile `ownership` due to previous error
Recall from the borrowing rules that if we have an immutable reference to something, we cannot also take a mutable reference. Because clear
needs to truncate the String
, it needs to get a mutable reference. The println!
after the call to clear
uses the reference in word
, so the immutable reference must still be active at that point. Rust disallows the mutable reference in clear
and the immutable reference in word
from existing at the same time, and compilation fails. Not only has Rust made our API easier to use, but it has also eliminated an entire class of errors at compile time!
String Literals Are Slices
Recall that we talked about string literals being stored inside the binary. Now that we know about slices, we can properly understand string literals:
#![allow(unused)]
fn main() {
let s = "Hello, world!";
}
The type of s
here is &str
: it’s a slice pointing to that specific point of the binary. This is also why string literals are immutable; &str
is an immutable reference.
String Slices as Parameters
Knowing that you can take slices of literals and String
values leads us to one more improvement on first_word
, and that’s its signature:
fn first_word(s: &String) -> &str {
A more experienced Rustacean would write the signature shown in Listing 4-9 instead because it allows us to use the same function on both &String
values and &str
values.
fn first_word(s: &str) -> &str {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return &s[0..i];
}
}
&s[..]
}
fn main() {
let my_string = String::from("hello world");
// `first_word` works on slices of `String`s, whether partial or whole
let word = first_word(&my_string[0..6]);
let word = first_word(&my_string[..]);
// `first_word` also works on references to `String`s, which are equivalent
// to whole slices of `String`s
let word = first_word(&my_string);
let my_string_literal = "hello world";
// `first_word` works on slices of string literals, whether partial or whole
let word = first_word(&my_string_literal[0..6]);
let word = first_word(&my_string_literal[..]);
// Because string literals *are* string slices already,
// this works too, without the slice syntax!
let word = first_word(my_string_literal);
}
Listing 4-9: Improving the first_word
function by using a string slice for the type of the s
parameter
If we have a string slice, we can pass that directly. If we have a String
, we can pass a slice of the String
or a reference to the String
. This flexibility takes advantage of deref coercions, a feature we will cover in the “Implicit Deref Coercions with Functions and Methods” section of Chapter 15. Defining a function to take a string slice instead of a reference to a String
makes our API more general and useful without losing any functionality:
Filename: src/main.rs
fn first_word(s: &str) -> &str {
let bytes = s.as_bytes();
for (i, &item) in bytes.iter().enumerate() {
if item == b' ' {
return &s[0..i];
}
}
&s[..]
}
fn main() {
let my_string = String::from("hello world");
// `first_word` works on slices of `String`s, whether partial or whole
let word = first_word(&my_string[0..6]);
let word = first_word(&my_string[..]);
// `first_word` also works on references to `String`s, which are equivalent
// to whole slices of `String`s
let word = first_word(&my_string);
let my_string_literal = "hello world";
// `first_word` works on slices of string literals, whether partial or whole
let word = first_word(&my_string_literal[0..6]);
let word = first_word(&my_string_literal[..]);
// Because string literals *are* string slices already,
// this works too, without the slice syntax!
let word = first_word(my_string_literal);
}
Other Slices
String slices, as you might imagine, are specific to strings. But there’s a more general slice type, too. Consider this array:
#![allow(unused)]
fn main() {
let a = [1, 2, 3, 4, 5];
}
Just as we might want to refer to a part of a string, we might want to refer to part of an array. We’d do so like this:
#![allow(unused)]
fn main() {
let a = [1, 2, 3, 4, 5];
let slice = &a[1..3];
assert_eq!(slice, &[2, 3]);
}
This slice has the type &[i32]
. It works the same way as string slices do, by storing a reference to the first element and a length. You’ll use this kind of slice for all sorts of other collections. We’ll discuss these collections in detail when we talk about vectors in Chapter 8.
Summary
The concepts of ownership, borrowing, and slices ensure memory safety in Rust programs at compile time. The Rust language gives you control over your memory usage in the same way as other systems programming languages, but having the owner of data automatically clean up that data when the owner goes out of scope means you don’t have to write and debug extra code to get this control.
Ownership affects how lots of other parts of Rust work, so we’ll talk about these concepts further throughout the rest of the book. Let’s move on to Chapter 5 and look at grouping pieces of data together in a struct
.