add examples from Rust By Example

examples built into 3 separate binaries
2025-01-07 06:45:25 +00:00 · 2022-06-26 19:11:30 +05:30 · 2022-06-26 19:11:30 +05:30 · 3a4936d455
commit 3a4936d455
parent f82934a703
3 changed files with 306 additions and 0 deletions
--- a/src/bin/example1.rs
+++ b/src/bin/example1.rs
@ -0,0 +1,146 @@
 #![allow(dead_code)]
 use std::mem;
 // https://doc.rust-lang.org/rust-by-example/primitives.html
 fn example1 () {
    // Variables can be type annotated.
    let logical: bool = true;
    let a_float: f64 = 1.0;  // Regular annotation
    let an_integer   = 5i32; // Suffix annotation
    // Or a default will be used.
    let default_float   = 3.0; // `f64`
    let default_integer = 7;   // `i32`
    // A type can also be inferred from context
    let mut inferred_type = 12; // Type i64 is inferred from another line
    inferred_type = 4294967296i64;
    // A mutable variable's value can be changed.
    let mut mutable = 12; // Mutable `i32`
    mutable = 21;
 }
 // https://doc.rust-lang.org/rust-by-example/primitives/literals.html
 fn example1b() {
    // Integer addition
    println!("1 + 2 = {}", 1u32 + 2);
    // Integer subtraction
    println!("1 - 2 = {}", 1i32 - 2);
    // TODO ^ Try changing `1i32` to `1u32` to see why the type is important
    // Short-circuiting boolean logic
    println!("true AND false is {}", true && false);
    println!("true OR false is {}", true || false);
    println!("NOT true is {}", !true);
    // Bitwise operations
    println!("0011 AND 0101 is {:04b}", 0b0011u32 & 0b0101);
    println!("0011 OR 0101 is {:04b}", 0b0011u32 | 0b0101);
    println!("0011 XOR 0101 is {:04b}", 0b0011u32 ^ 0b0101);
    println!("1 << 5 is {}", 1u32 << 5);
    println!("0x80 >> 2 is 0x{:x}", 0x80u32 >> 2);
    // Use underscores to improve readability!
    println!("One million is written as {}", 1_000_000u32);
 }
 // https://doc.rust-lang.org/rust-by-example/primitives/tuples.html
 // Tuples can be used as function arguments and as return values
 fn reverse(pair: (i32, bool)) -> (bool, i32) {
    // `let` can be used to bind the members of a tuple to variables
    let (integer, boolean) = pair;
    (boolean, integer)
 }
 // The following struct is for the activity.
 #[derive(Debug)]
 struct Matrix(f32, f32, f32, f32);
 fn example1c() {
    // A tuple with a bunch of different types
    let long_tuple = (1u8, 2u16, 3u32, 4u64,
                      -1i8, -2i16, -3i32, -4i64,
                      0.1f32, 0.2f64,
                      'a', true);
    // Values can be extracted from the tuple using tuple indexing
    println!("long tuple first value: {}", long_tuple.0);
    println!("long tuple second value: {}", long_tuple.1);
    // Tuples can be tuple members
    let tuple_of_tuples = ((1u8, 2u16, 2u32), (4u64, -1i8), -2i16);
    // Tuples are printable
    println!("tuple of tuples: {:?}", tuple_of_tuples);
    // But long Tuples cannot be printed
    // let too_long_tuple = (1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13);
    // println!("too long tuple: {:?}", too_long_tuple);
    // TODO ^ Uncomment the above 2 lines to see the compiler error
    let pair = (1, true);
    println!("pair is {:?}", pair);
    println!("the reversed pair is {:?}", reverse(pair));
    // To create one element tuples, the comma is required to tell them apart
    // from a literal surrounded by parentheses
    println!("one element tuple: {:?}", (5u32,));
    println!("just an integer: {:?}", (5u32));
    //tuples can be destructured to create bindings
    let tuple = (1, "hello", 4.5, true);
    let (a, b, c, d) = tuple;
    println!("{:?}, {:?}, {:?}, {:?}", a, b, c, d);
    let matrix = Matrix(1.1, 1.2, 2.1, 2.2);
    println!("{:?}", matrix);
 }
 // This function borrows a slice
 fn analyze_slice(slice: &[i32]) {
    println!("first element of the slice: {}", slice[0]);
    println!("the slice has {} elements", slice.len());
 }
 fn example1d() {
    // Fixed-size array (type signature is superfluous)
    let xs: [i32; 5] = [1, 2, 3, 4, 5];
    // All elements can be initialized to the same value
    let ys: [i32; 500] = [0; 500];
    // Indexing starts at 0
    println!("first element of the array: {}", xs[0]);
    println!("second element of the array: {}", xs[1]);
    // `len` returns the count of elements in the array
    println!("number of elements in array: {}", xs.len());
    // Arrays are stack allocated
    println!("array occupies {} bytes", mem::size_of_val(&xs));
    // Arrays can be automatically borrowed as slices
    println!("borrow the whole array as a slice");
    analyze_slice(&xs);
    // Slices can point to a section of an array
    // They are of the form [starting_index..ending_index]
    // starting_index is the first position in the slice
    // ending_index is one more than the last position in the slice
    println!("borrow a section of the array as a slice");
    analyze_slice(&ys[1 .. 4]);
 }
 fn main() {
    example1();
    example1b();
    example1c();
    example1d();
 }
--- a/src/bin/example2.rs
+++ b/src/bin/example2.rs
@ -0,0 +1,160 @@
 #![allow(dead_code)]
 use std::mem;
 // https://doc.rust-lang.org/rust-by-example/custom_types/structs.html
 #[derive(Debug)]
 struct Person {
    name: String,
    age: u8,
 }
 // A unit struct
 struct Unit;
 // A tuple struct
 struct Pair(i32, f32);
 // A struct with two fields
 struct Point {
    x: f32,
    y: f32,
 }
 // Structs can be reused as fields of another struct
 struct Rectangle {
    // A rectangle can be specified by where the top left and bottom right
    // corners are in space.
    top_left: Point,
    bottom_right: Point,
 }
 fn example2() {
    // Create struct with field init shorthand
    let name = String::from("Peter");
    let age = 27;
    let peter = Person { name, age };
    // Print debug struct
    println!("{:?}", peter);
    // Instantiate a `Point`
    let point: Point = Point { x: 10.3, y: 0.4 };
    // Access the fields of the point
    println!("point coordinates: ({}, {})", point.x, point.y);
    // Make a new point by using struct update syntax to use the fields of our
    // other one
    let bottom_right = Point { x: 5.2, ..point };
    // `bottom_right.y` will be the same as `point.y` because we used that field
    // from `point`
    println!("second point: ({}, {})", bottom_right.x, bottom_right.y);
    // Destructure the point using a `let` binding
    let Point { x: left_edge, y: top_edge } = point;
    let _rectangle = Rectangle {
        top_left: Point { x: left_edge, y: top_edge },
        bottom_right: bottom_right,
        // struct instantiation is an expression too
    };
    // Instantiate a unit struct
    let _unit = Unit;
    // Instantiate a tuple struct
    let pair = Pair(1, 0.1);
    // Access the fields of a tuple struct
    println!("pair contains {:?} and {:?}", pair.0, pair.1);
    // Destructure a tuple struct
    let Pair(integer, decimal) = pair;
    println!("pair contains {:?} and {:?}", integer, decimal);
 }
 // https://doc.rust-lang.org/rust-by-example/custom_types/enum.html
 // Create an `enum` to classify a web event. Note how both
 // names and type information together specify the variant:
 // `PageLoad != PageUnload` and `KeyPress(char) != Paste(String)`.
 // Each is different and independent.
 enum WebEvent {
    // An `enum` may either be `unit-like`,
    PageLoad,
    PageUnload,
    // like tuple structs,
    KeyPress(char),
    Paste(String),
    // or c-like structures.
    Click { x: i64, y: i64 },
 }
 // A function which takes a `WebEvent` enum as an argument and
 // returns nothing.
 fn inspect(event: WebEvent) {
    match event {
        WebEvent::PageLoad => println!("page loaded"),
        WebEvent::PageUnload => println!("page unloaded"),
        // Destructure `c` from inside the `enum`.
        WebEvent::KeyPress(c) => println!("pressed '{}'.", c),
        WebEvent::Paste(s) => println!("pasted \"{}\".", s),
        // Destructure `Click` into `x` and `y`.
        WebEvent::Click { x, y } => {
            println!("clicked at x={}, y={}.", x, y);
        },
    }
 }
 fn example2b() {
    let pressed = WebEvent::KeyPress('x');
    // `to_owned()` creates an owned `String` from a string slice.
    let pasted  = WebEvent::Paste("my text".to_owned());
    let click   = WebEvent::Click { x: 20, y: 80 };
    let load    = WebEvent::PageLoad;
    let unload  = WebEvent::PageUnload;
    inspect(pressed);
    inspect(pasted);
    inspect(click);
    inspect(load);
    inspect(unload);
 }
 // https://doc.rust-lang.org/rust-by-example/custom_types/enum/c_like.html
 // enum with implicit discriminator (starts at 0)
 enum Number {
    Zero,
    One,
    Two,
 }
 // enum with explicit discriminator
 enum Color {
    Red = 0xff0000,
    Green = 0x00ff00,
    Blue = 0x0000ff,
 }
 fn example2c() {
    // `enums` can be cast as integers.
    println!("zero is {}", Number::Zero as i32);
    println!("one is {}", Number::One as i32);
    println!("roses are #{:06x}", Color::Red as i32);
    println!("violets are #{:06x}", Color::Blue as i32);
 }
 fn main() {
    println!("Hello World! This is an APE built with Rust.");
    example2();
    example2b();
    example2c();
    0;
 }
--- a/src/bin/hello_world.rs
+++ b/src/bin/hello_world.rs