# Using `#[derive(Sum)]` The derived `Sum` implementation will allow an iterator of your type to be summed together into a new instance of the type with all the fields added together. Apart from the original types requiring an implementation of `Sum`, it is also required that your type to implements `Add`. So normally you want to derive that one as well. All this is also true for the `Product`, except that then all the fields are multiplied and an implementation of `Mul` is required. This is usually the easiest to implement by adding `#[derive(MulSelf)]`. ## Example usage ```rust # use derive_more::{Add, Sum}; # #[derive(Add, Sum, PartialEq)] struct MyInts(i32, i64); let int_vec = vec![MyInts(2, 3), MyInts(4, 5), MyInts(6, 7)]; assert!(MyInts(12, 15) == int_vec.into_iter().sum()) ``` ## Structs When deriving `Sum` for a struct with two fields its like this: ```rust # use derive_more::{Add, Sum}; # #[derive(Add, Sum)] struct MyInts(i32, i64); ``` Code like this will be generated for the `Sum` implementation: ```rust # use ::core::ops::Add; # struct MyInts(i32, i64); # impl Add for MyInts { # type Output = MyInts; # #[inline] # fn add(self, rhs: MyInts) -> MyInts { # MyInts(self.0.add(rhs.0), self.1.add(rhs.1)) # } # } impl derive_more::Sum for MyInts { #[inline] fn sum>(iter: I) -> Self { iter.fold( MyInts( derive_more::core::iter::empty::().sum(), derive_more::core::iter::empty::().sum(), ), derive_more::core::ops::Add::add, ) } } ``` The trick here is that we get the identity struct by calling sum on empty iterators. This way we can get the identity for sum (i.e. `0`) and the identity for product (i.e. `1`). ## Enums Deriving `Sum` for enums is not supported.