有一个不稳定的函数std::intrinsic::type_name可以获取类型的名称，尽管您必须使用Rust的夜间构建(这在稳定的Rust中不太可能工作)。这里有一个例子:

#![feature(core_intrinsics)]

fn print_type_of<T>(_: &T) {
    println!("{}", unsafe { std::intrinsics::type_name::<T>() });
}

fn main() {
    print_type_of(&32.90);          // prints "f64"
    print_type_of(&vec![1, 2, 4]);  // prints "std::vec::Vec<i32>"
    print_type_of(&"foo");          // prints "&str"
}

宏形式允许使用“无处不在”，而函数需要一个对象来解析。

宏表单(一行):

macro_rules! ty {($type:ty) => {std::any::type_name::<$type>()}}

形成的宏观形式:

macro_rules! ty {
    ($type:ty) => {
        std::any::type_name::<$type>()
    };
}

函数形式(借用是为了不破坏已解析的变量):

fn type_of<T>(_: &T) -> &'static str {std::any::type_name::<T>()}

fn type_of<T>(_: &T) -> &'static str {
    std::any::type_name::<T>()
}

例子:

macro_rules! ty {($type:ty) => {std::any::type_name::<$type>()}}
fn type_of<T>(_: &T) -> &'static str {std::any::type_name::<T>()}

struct DontMater<T>(T);

impl<T: std::fmt::Debug> std::fmt::Debug for DontMater<T> {
    fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
        fmt.write_fmt(format_args!("DontMater<{}>({:?})", ty!(T), self.0))
    }
}

fn main() {
    type µ = [Vec<String>; 7];
    println!("{:?}", DontMater(5_usize));
    println!("{:?}", DontMater("¤"));
    println!("{}", ty!(char));
    println!("{:?}", ty!(µ));
    println!("{}", type_of(&DontMater(72_i8)));
    println!("{:?}", type_of(&15_f64));
}

返回:

DontMater<usize>(5)
DontMater<&str>("¤")
char
"[alloc::vec::Vec<alloc::string::String>; 7]"
env_vars::DontMater<i8>
"f64"

我非常喜欢@Coautose之前的回答，但如果有人只想要没有名称空间的类型名称，例如C而不是a::b::C，这里是一个修改后的宏版本，看起来像预期的那样工作:

macro_rules! ty {
    ($type:ty) => {{
        let result = std::any::type_name::<$type>();
        match result.rsplit_once(':') {
            Some((_, s)) => s,
            None => result,
        }
    }};
}

用法:

debug!("Testing type name: {}", ty!(A));

UPD以下不再工作。检查Shubham的答案以作更正。

检查std::intrinsic::get_tydesc<T>()。它现在处于“实验”状态，但如果您只是对类型系统进行了修改，那么它是OK的。

请看下面的例子:

fn print_type_of<T>(_: &T) -> () {
    let type_name =
        unsafe {
            (*std::intrinsics::get_tydesc::<T>()).name
        };
    println!("{}", type_name);
}

fn main() -> () {
    let mut my_number = 32.90;
    print_type_of(&my_number);       // prints "f64"
    print_type_of(&(vec!(1, 2, 4))); // prints "collections::vec::Vec<int>"
}

这是在内部用来实现著名的{:?}格式化程序。

其他一些答案不工作，但我发现typename crate工作。

Create a new project: cargo new test_typename Modify the Cargo.toml [dependencies] typename = "0.1.1" Modify your source code use typename::TypeName; fn main() { assert_eq!(String::type_name(), "std::string::String"); assert_eq!(Vec::<i32>::type_name(), "std::vec::Vec<i32>"); assert_eq!([0, 1, 2].type_name_of(), "[i32; 3]"); let a = 65u8; let b = b'A'; let c = 65; let d = 65i8; let e = 65i32; let f = 65u32; let arr = [1,2,3,4,5]; let first = arr[0]; println!("type of a 65u8 {} is {}", a, a.type_name_of()); println!("type of b b'A' {} is {}", b, b.type_name_of()); println!("type of c 65 {} is {}", c, c.type_name_of()); println!("type of d 65i8 {} is {}", d, d.type_name_of()); println!("type of e 65i32 {} is {}", e, e.type_name_of()); println!("type of f 65u32 {} is {}", f, f.type_name_of()); println!("type of arr {:?} is {}", arr, arr.type_name_of()); println!("type of first {} is {}", first, first.type_name_of()); }

输出结果为:

type of a 65u8  65 is u8
type of b b'A'  65 is u8
type of c 65    65 is i32
type of d 65i8  65 is i8
type of e 65i32 65 is i32
type of f 65u32 65 is u32
type of arr [1, 2, 3, 4, 5] is [i32; 5]
type of first 1 is i32

短篇小说;

fn tyof<T>(_: &T) -> String {
    std::any::type_name::<T>().into()
}

很长的故事;

trait Type {
    fn type_of(&self) -> String;
}

macro_rules! Type {
    ($($ty:ty),*) => {
        $(
            impl Type for $ty {
                fn type_of(&self) -> String {
                    stringify!($ty).into()
                }
            }
        )*
    }
}

#[rustfmt::skip]
Type!(
    u8, i8, u16, i16, u32, i32, i64, u64, i128, String, [()], (), Vec<()>, &u8, &i8, &u16, &i16, &u32, &i32, &i64, &u64, &i128, &str, &[()], &Vec<()>, &() 
    // add any struct, enum or type you want
);

macro_rules! tyof {
    ($var: expr) => {{
        $var.type_of()
    }};
}

fn main() {
    let x = "Hello world!";
    println!("{}", tyof!(x));
    // or
    println!("{}", x.type_of());

    let x = 5;
    println!("{}", tyof!(x));
    // or
    println!("{}", x.type_of());
}