Generics
In functions, you write what type to take as input:
fn return_number(number: i32) -> i32 { println!("Here is your number."); number } fn main() { let number = return_number(5); }
But what if you want to take more than just i32? You can use generics for this. Generics means "maybe one type, maybe another type".
For generics, you use angle brackets with the type inside, like this: <T> This means "any type you put into the function". Usually, generics uses types with one capital letter (T, U, V, etc.), though you don't have to just use one letter.
This is how you change the function to make it generic:
fn return_number<T>(number: T) -> T { println!("Here is your number."); number } fn main() { let number = return_number(5); }
The important part is the <T> after the function name. Without this, Rust will think that T is a concrete (concrete = not generic) type, like String or i8.
This is easier to understand if we write out a type name. See what happens when we change T to MyType:
#![allow(unused)] fn main() { fn return_number(number: MyType) -> MyType { // ⚠️ println!("Here is your number."); number } }
As you can see, MyType is concrete, not generic. So we need to write this and so now it works:
fn return_number<MyType>(number: MyType) -> MyType { println!("Here is your number."); number } fn main() { let number = return_number(5); }
So the single letter T is for human eyes, but the part after the function name is for the compiler's "eyes". Without it, it's not generic.
Now we will go back to type T, because Rust code usually uses T.
You will remember that some types in Rust are Copy, some are Clone, some are Display, some are Debug, and so on. With Debug, we can print with {:?}. So now you can see that we have a problem if we want to print T:
fn print_number<T>(number: T) { println!("Here is your number: {:?}", number); // ⚠️ } fn main() { print_number(5); }
print_number needs Debug to print number, but is T a type with Debug? Maybe not. Maybe it doesn't have #[derive(Debug)], who knows. The compiler doesn't know either, so it gives an error:
error[E0277]: `T` doesn't implement `std::fmt::Debug`
--> src\main.rs:29:43
|
29 | println!("Here is your number: {:?}", number);
| ^^^^^^ `T` cannot be formatted using `{:?}` because it doesn't implement `std::fmt::Debug`
T doesn't implement Debug. So do we implement Debug for T? No, because we don't know what T is. But we can tell the function: "Don't worry, because any type T for this function will have Debug".
use std::fmt::Debug; // Debug is located at std::fmt::Debug. So now we can just write 'Debug'. fn print_number<T: Debug>(number: T) { // <T: Debug> is the important part println!("Here is your number: {:?}", number); } fn main() { print_number(5); }
So now the compiler knows: "Okay, this type T is going to have Debug". Now the code works, because i32 has Debug. Now we can give it many types: String, &str, and so on, because they all have Debug.
Now we can create a struct and give it Debug with #[derive(Debug)], so now we can print it too. Our function can take i32, the struct Animal, and more:
use std::fmt::Debug; #[derive(Debug)] struct Animal { name: String, age: u8, } fn print_item<T: Debug>(item: T) { println!("Here is your item: {:?}", item); } fn main() { let charlie = Animal { name: "Charlie".to_string(), age: 1, }; let number = 55; print_item(charlie); print_item(number); }
This prints:
Here is your item: Animal { name: "Charlie", age: 1 }
Here is your item: 55
Sometimes we need more than one type in a generic function. We have to write out each type name, and think about how we want to use it. In this example, we want two types. First we want to print a statement for type T. Printing with {} is nicer, so we will require Display for T.
Next is type U, and the two variables num_1 and num_2 have type U (U is some sort of number). We want to compare them, so we need PartialOrd. That trait lets us use things like <, >, ==, and so on. We want to print them too, so we require Display for U as well.
use std::fmt::Display; use std::cmp::PartialOrd; fn compare_and_display<T: Display, U: Display + PartialOrd>(statement: T, num_1: U, num_2: U) { println!("{}! Is {} greater than {}? {}", statement, num_1, num_2, num_1 > num_2); } fn main() { compare_and_display("Listen up!", 9, 8); }
This prints Listen up!! Is 9 greater than 8? true.
So fn compare_and_display<T: Display, U: Display + PartialOrd>(statement: T, num_1: U, num_2: U) says:
- The function name is
compare_and_display, - The first type is T, and it is generic. It must be a type that can print with {}.
- The next type is U, and it is generic. It must be a type that can print with {}. Also, it must be a type that can compare (use
>,<, and==).
Now we can give compare_and_display different types. statement can be a String, a &str, anything with Display.
To make generic functions easier to read, we can also write it like this with where right before the code block:
use std::cmp::PartialOrd; use std::fmt::Display; fn compare_and_display<T, U>(statement: T, num_1: U, num_2: U) where T: Display, U: Display + PartialOrd, { println!("{}! Is {} greater than {}? {}", statement, num_1, num_2, num_1 > num_2); } fn main() { compare_and_display("Listen up!", 9, 8); }
Using where is a good idea when you have many generic types.
Also note:
- If you have one type T and another type T, they must be the same.
- If you have one type T and another type U, they can be different. But they can also be the same.
For example:
use std::fmt::Display; fn say_two<T: Display, U: Display>(statement_1: T, statement_2: U) { // Type T needs Display, type U needs Display println!("I have two things to say: {} and {}", statement_1, statement_2); } fn main() { say_two("Hello there!", String::from("I hate sand.")); // Type T is a &str, but type U is a String. say_two(String::from("Where is Padme?"), String::from("Is she all right?")); // Both types are String. }
This prints:
I have two things to say: Hello there! and I hate sand.
I have two things to say: Where is Padme? and Is she all right?