Because those types can be coerced, so if we use those types functions will accept less types:
1- a reference to String can be coerced to a str slice. For example create a function:
fn count_wovels(words:&String)->usize{
let wovels_count=words.chars().into_iter().filter(|x|(*x=='a') | (*x=='e')| (*x=='i')| (*x=='o')|(*x=='u')).count();
wovels_count
}
if you pass &str
, it will not be accepted:
let name="yilmaz".to_string();
println!("{}",count_wovels(&name));
// this is not allowed because argument should be &String but we are passing str
// println!("{}",wovels("yilmaz"))
But if that function accepts &str
instead
// words:&str
fn count_wovels(words:&str)->usize{ ... }
we can pass both types to the function
let name="yilmaz".to_string();
println!("{}",count_wovels(&name));
println!("{}",wovels("yilmaz"))
With this, our function can accept more types
2- Similary, a reference to Box &Box[T]
, will be coerced to the reference to the value inside the Box Box[&T]
. for example
fn length(name:&Box<&str>){
println!("lenght {}",name.len())
}
this accepts only &Box<&str>
type
let boxed_str=Box::new("Hello");
length(&boxed_str);
// expected reference `&Box<&str>` found reference `&'static str`
// length("hello")
If we pass &str
as type, we can pass both types
3- Similar relation exists between ref to a Vec and ref to an array
fn square(nums:&Vec<i32>){
for num in nums{
println!("square of {} is {}",num,num*num)
}
}
fn main(){
let nums=vec![1,2,3,4,5];
let nums_array=[1,2,3,4,5];
// only &Vec<i32> is accepted
square(&nums);
// mismatched types: mismatched types expected reference `&Vec<i32>` found reference `&[{integer}; 5]`
//square(&nums_array)
}
this will work for both types
fn square(nums:&[i32]){..}